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Vou. 66

mee LETIN OF I

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Southern California « :

Be cemy of Sciences:

LOS ANGELES, CALIFORNIA

CONTENTS

Additional Notes on Snakes Taken in and Near Joshua Tree National.
Monument, California. Richard B. Loomis and Robert C.
Stephens

Studies of the Blood of Ascidia Nigra (Savigny). Total Blood Cell
Counts, Differential Blood Cell Counts, and Hematocrit Values.

CAL GARD

No. 1

ES Abe VIZ | Dinesh cA am SNM eA Se 23

Self-Regulatory Growth in the Green Alga Eniteromorpha Prolifera
Formae. Andrew Kier and Eric S. Todd

A New Species of Neofungella (Bryozoa, Stenolaemata) from South-
ern California. William C. Banta

An Endocranial Cast of the Miocene Dog, Jomarctus, from the Fossil
Beds of Barstow, California. George E. Jakway and Jerry T:
Clement “ 3

Notes on Paracimbocera Robusta Vandyke (Coleoptera: Curcu-
lionidae). Elbert L. Sleeper and Sandra L. Jenkins

The Pupa of Rhaphiomidas terminatus Cazier (Diptera: Apio-
ceridae). Charles L. Hogue

Elasipod Holothurians of Antarctica I. Genus Amperima Pawson
1965. Candido PR Agatep

Underwater Sounds Associated with Aggressive Behavior in Defense
of Territory by the Pinfish, Lagodon rhomboides. David K.
Caldwell

Issued April 11, 1967

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ACADEMY OF SCIENCES

VoL. 66 January-Marcu, 1967 No. 1

ADDITIONAL NOTES ON SNARES TAKEN IN AND NEAR
JOSHUA TREE NATIONAL MONUMENT, CALIFORNIA?

RicHArD B. Loomis

Department of Biology
California State College at Long Beach
Long Beach, California 90804
and
Rospert C. STEPHENS

E] Camino College
Los Angeles, California

INTRODUCTION

This is the second report of snakes found within or near the present
boundary of Joshua Tree National Monument, and it includes 284
specimens belonging to 20 species. Among the 24 known subspecies,
three, Leptotyphlops humilis cahuilae, Pituophis melanoleucus
affinis, and Tantilla eiseni transmontana, are reported from the
Monument for the first time. The distribution of each species and
intergradation of subspecies within the Monument are discussed.
The origin and composition of the snake fauna are analyzed, includ-
ing the role of the Monument upland (pinyon plant belt) im the
patterns of occurrence.

In a recent publication on the vertebrates of the Monument, Mil-
ler and Stebbins (1964) listed 19 species of snakes including two
rattlesnakes, Crotalus atrox and Crotalus scutulatus, based on speci-
mens which we are reporting below in greater detail.

ACKNOWLEDGMENTS

We wish to thank the following persons who helped us assemble
these snakes. Superintendent William R. Supernaugh generously

1Studies and field work upon which this paper is based were supported by a
Public Health Service Research Grant (AI-3407) from the National Institute of
Allergy and Infectious Diseases and a grant from the National Park Service.
Contribution from the Department of Biology, California State College at Long
Beach, California.

2 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

allowed us to study the flora and fauna and to collect snakes in
Joshua Tree National Monument, and Mr. James R. Youse, Park
Naturalist, Mr. William Berseth, Mr. Thomas Meier and other resi-
dent naturalists and rangers enthusiastically assisted us. For numer-
ous snakes and aid in the field studies, our appreciation is extended
to Dr. Dennis G. Rainey and Dr. Elbert L. Sleeper and to these and
other students all of the Department of Biology, California State Col-
lege at Long Beach: Bettye Byrne, J ulius C. Geest, Alan R. Hardy,
H. Stevan Logsdon, Norman G. Puckett, Ronald E. Somerby, and
William J. Wrenn. Certain specimens were borrowed from the Uni-
versity of California, Berkeley, Museum of Vertebrate Zoology
through the courtesy of Dr. Robert C. Stebbins.

ACCOUNTS OF SPECIES AND SUBSPECIES

The records of the snakes are listed from southeast to northwest.
Unless otherwise stated, the specimens are from the Monument.
When the year is not listed, the records are from 1961 through 1965.

The numbers in parentheses represent catalogue numbers in the
Herpetological collection of California State College at Long Beach
(CSCLB) except for those from the Museum of Vertebrate Zoology
(MVZ) University of California, Berkeley.

Leptotyphlops humilis humilis Baird and Girard
Southwestern Blind Snake

Specimens examined.—Total 5: ADJACENT TO MONUMENT,
San Bernardino County: Twentynine Palms, summer, 1960 (999),
26 May 1961 (988), 17 June (1002), 19 July (1000), and 1 Aug.
1962 (1001).

All of these specimens were brought to Monument Headquarters
by residents of Twentynine Palms. Two adults were captured by cats
and one tiny blind snake (1001) with a total length of 126 mm was
found alive but trapped in the web of a black widow spider. Although
this subspecies of blind snake has not been taken within the Monu-
ment, two examples were found less than one-half mile from the
boundary at an elevation of 2000 feet in habitats which extend into
the Monument.

Leptotyphlops humilis cahuilae Klauber
Desert Blind Snake
Specimens examined.—Total 6: Riverside County: 0.6 and 1 mi. N.
Cottonwood Spring entrance (=6 mi. S Cottonwood Spring) 30

California snakes 3

April 1965, AOR (1522, 1523). ADJACENT TO MONUMENT,
Riverside County: 5.5 mi. N Desert Center, 900 ft., 31 May, DOR
(1003); Thousand Palms Oasis, 14 April 1951 (1067), 20 May,
DOR (1069); 3 mi. NE Thousand Palms Oasis, 25 March 1960, DOR
(1068).

The following characteristics of CSCLB 1523, a female, seem
typical of the subspecies L. h. cahuilae (Klauber, 1940a): total
length 278 mm; mid-dorsal scale count 295, from rostral to tail spine
(but not including either); 5 rows of mid-dorsal scales faintly pig-
mented with light brown dots; remaining scales cream, without
dark pigment.

The two Desert Blind Snakes, taken just imside the southern
boundary, represent the first records from the Monument. This
locality, at 1800 feet, is below the mouth of Cottonwood Pass in the
Colorado Desert, and the vegetation includes Chuparosa, Belo-
perone californica, Paloverde, Cercidium floridum, Ironwood,
Olneya tesota, Ocotillo, Fouquieria splendens, Creosote Bush, Larrea
divaricata, and Brittle-bush, Encelia farinosa. They were found
alive on the road several minutes apart one hour after sunset, on a
dark night, air temperature 75°F, by Eric Fisher and Tom Aufdem-
berg, students from California State College at Long Beach.

Other localities listed above are all below 1000 feet in the Colo-
rado Desert.

Lichanura trivirgata gracia kKlauber

Desert Rosy Boa

Specimens examined.—Total 12, AOR unless otherwise noted:
Riverside County: 3.9 to 0.3 mi. S Cottonwood Spring Y, 2300-3000
ft., 12 April, DOR (798), 3 June (772), 12 June (770); Fried Liver
Wash, 7 April, DOR (799); Pinto Y, 23 June (776); Jumbo Rocks,
4000 ft., 10 July (773-4); 1 mi. W Hidden Valley, 4200 ft., 21 July
(775); Long Canyon, 4 mi. N, 1.5 mi. W of S boundary, 8 April.
under rock (799). ADJACENT TO MONUMENT, Riverside
County: 1 mi. E Cactus City (=8 mi. W of S entrance), 18 June,
DOR (771); Fanhill Road, 4 mi. NNE Thousand Palms Oasis, 7
April (778). San Bernardino County: 3.3 mi. S Twentynine Palms
entrance, 3200 ft., 5 May (777).

All but one of these boas were found on the road at night. An adult
female (779), found at midday coiled under a rock in Long Canyon,
seems to approach the coastal subspecies in the generally gray

4 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

ground color and the pronounced serrations of the distinct reddish
body stripes.

The other examples have distinct reddish stripes which are espe-
cially well-defined and straight edged on the specimens from the
Cottonwood Spring area.

Arizona elegans candida Klauber
Mohave Glossy Snake
Figure 1

Specimens examined.—Total 11, AOR unless otherwise noted: Aiver-
side County: 3.6 mi. to 0.4 mi. SE White Tank Campground, 2800-
3600 ft., 11 June (645), 15 Sept. (660), 5 May, DOR (658-9), 13
June (685); 3.6 mi. W Jumbo Rocks, 25 Aug. (659); Queen Valley
between Big Tree and Jumbo Rocks, 4 May, DOR (680); Lost Horse
Valley Ranger Station, 28 April, DOR (679) ; Lower Covington Flat,
2 Aug., can trap D-3 (681) and 4 Aug., can trap A-13 (1531). AD-
JACENT TO MONUMENT, San Bernardino County: La Contenta
Road, 1 mi. N Monument boundary at Covington Flats entrance, 7
April (663).

Additional record.—One: Riverside County: Lower Covington
Flat, Study Plot, can B-2, 16 June, released.

Examination of all available specimens of Arizona elegans taken
in or near the Monument, including those previously reported as
Arizona elegans eburnata by Loomis and Stephens (1962:31), re-
veals the presence of the subspecies A. e. candida, as well as A. e.
eburnata, in the Monument. The western upland, above 3500 feet
elevation, is inhabited by A. e. candida whereas A. e. eburnata
occurs at lower elevations throughout the rest of the Monument.
Intergrades have been found where the two subspecies come into
contact, especially in valleys which extend up into the upland (see
Fig. 1).

The presence of A. e. candida in the Monument seems to repre-
sent a relict population, completely or almost completely surrounded
by A. e. eburnata. A possible connection between the Monument
population of A. e. candida with the typical A. e. candida of the
western Mohave Desert may occur in the area from the northwest
corner of the Monument northwestward along the northeastern
slopes of the San Bernardino and San Gabriel Mountains at higher
elevations. Klauber (1946:370) states that “The specimens of Apple
and Lucerne Valleys are evidently eburnata, yet two specimens
from the Morongo Valley and west of Twentynine Palms have the

California snakes 5

paired preoculars typical of candida. For the present I have con-
sidered them intergrades:’ We have plotted two of the localities listed
by Klauber (1946:363), from 14 and 18 miles west of Twentynine
Palms. They are from the area below 3500 feet where A. e. candida
seems to be replaced entirely or almost completely by A. e. eburnata.
The specimens have not been examined. Miller and Stebbins (1964:
415) report specimens resembling A. e. candida from 3 miles east of
Yucca Valley, near Joshua Tree, and Juniper Flat, which are con-
sistent with our observations. They indicate that specimens from
near [wentynine Palms, Fortynine Palms, and Pinto Basi are A. e.
eburnata.

Tanner and Jorgensen (1963:24) report Arizona elegans candida
from the Nevada Test Site in Nye County, Nevada, based on seven
specimens. This would seem to indicate that the subspecies A. e.
candida also occurs farther to the northwest than reported by Klau-
ber (1946:372). Whether these two peripheral populations present-
ly have any direct contact with the population in the western
Mohave Desert is unknown, but A. e. eburnata is present through-
out much of the lower eastern Mohave Desert. It would appear that
A. e. eburnata has extended its range into the lower elevations of the
eastern and central parts of the Mohave Desert and A. e. candida
occurs Only in the higher peripheral western two-thirds of this
desert.

In the Monument, we have seen no evidence of typical specimens
of the coastal A. e. occidentalis Blanchard, or of intergrades with
either A. e. eburnata or A. e. candida.

Arizona elegans eburnata Klauber
Desert Glossy Snake
Figure 1

Specimens examined.—Total 25, AOR unless otherwise noted: River-
side County: 1 mi. N Old Dale Junction, 23 June, DOR (662) ; 7.5
mi. NW Old Dale Junction, 21 Sept., DOR (671) ; 0.5 mi. SW Cholla
Cactus Garden, 12 May (661); 2.5 mi. NW Cholla Cactus Garden,
3 June (667) and 21 Sept. (682); 4.9 mi. NW Cholla Cactus Gar-
den, 24 May (683). ADJACENT TO MONUMENT, Riverside
County: 5.4 mi. NE Desert Center, 29 May (684) ; 3 mi. W, 1 mi. N
Desert Center, 28 April (570); 1 mi. NE Indio, 31 May 1957 (695):

3 mi. NE Indio, Sept. 1956 (690); Thousand Palms, 23 May 1956
(696), 20 Oct. 1956 (686); 3-4 mi. E Thousand Palms, 20 April

6
JOSHUA TREE NATIONAL MONUMENT

STATUTE MILES
@ @ Arizona elegans candida
WZZA Probable range in monument

O Arizona elegans eburnata

O-@ Arizona elegans candida x Ae eburnata

° Ss 10

STATUTE MILES

Pituophis melanoleucus deserticola

Pituophis melanoleucus affinis

California snakes 7

1956 (698), 1 June 1956 (693, 697); 4 mi. NW Thousand Palms,
8 May 1960 DOR (699) ; 4-5 mi. S Desert Hot Springs, 25 May 1957
(687), 31 May 1957 (688), 2 June 1959 (692): the following two
are considered intergrades with A. e. candida; 7 mi. S, 12 mi. E
Desert Hot Springs, on Dillon Road, 8 May 1960, DOR (689); and
1.5 mi. N Desert Hot Springs, 26 May 1957, DOR (691). San Ber-
nardino County: 1.6 mi. S ‘Twentynine Palms entrance to Monu-
ment, 5 May (669). ADJACENT TO MONUMENT, San Bernar-
dino County: 1.1 mi. S Monument Headquarters, Twentynine Palms,
19 July (676); 0.1 mi. N Twentynine Palms entrance, 25 Aug.
(655); 5 mi. E Twentynine Palms, 1 July (664).

Additional records.—Total 6: San Bernardino County: 1.9 mi. S
Twentynine Palms entrance, 5 May, discarded. ADJACENT TO
MONUMENT (after Klauber, 1946:363); Riverside County: Des-
ert Center; 5 mi. E Shavers Summit; Indio: San Bernardino Coun-
ty: Twentynine Palms, 14 and 18 mi. W ‘Twentynine Palms.”

Chionactis occipitalis occipitalis (Hallowell)
Mohave Shovel-nosed Snake

Specimens examined.—'lotal 23: Riverside County: 0.5 mi. N Pinto
Wash Well, 1100 feet, 26 April (844, 847); 0.5 mi. S to 8.3 mi. N
Old Dale Junction, 2500 feet, all AOR, 6 May (833), 3 June (838),
16 June (840), 30 June (841), 15 Sept. (839), and 21 Sept. (832);

Figure 1. Distribution of Arizona elegans in and near the Monument. The solid
and half black circles represent Arizona elegans candida; solid circle is specimen
with more than 9 scale rows across middorsal body blotch and/or 2-1 or 2-2 pre-
oculars; half solid circle is specimen with 9 scale rows across the middorsal body
blotch. The shaded area represents the probable range of candida in the Monu-
ment. Open circles represent Arizona elegans eburnata, with less than 9 scale
rows across middorsal body blotch and preoculars 1-1. Each presumed inter-
grade between candida and eburnata is shown as a circle and cross; the open
circle is a specimen with 8 or less scale rows across the middorsal body blotch
but with preoculars 2-1 or 2-2; the half solid circle is a specimen with preoculars
1-1 and 9 scale rows across the middorsal body blotch.

Figure 2. Distribution of Pituophis melanoleucus in and near the Monument.
Solid circles represent P m. deserticola and solid triangles are localities for Pm.
affinis. The range of deserticola extends northward and affinis is found to the
south of the Monument.

*Klauber (1946:363) states “Some of the succeeding localities in the San Ber-
nardino County list may represent candida—eburnata intergrades; these locali-
ties are along the Mojave River, between Barstow and Victorville, from the Apple
and Lucerne Valleys, and near Twentynine Palms.’

8 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Long Canyon mouth at S boundary, 25 May (1173); ADJACENT
TO MONUMENT, 2-8 mi. NW Desert Center, 24-29 May (845-6,
849, 851-3), 15 June (854) and 12 July (848). San Bernardino
County, ADJACENT TO MONUMENT: all DOR, 15-22.7 mi. E
Twentynine Palms, 26-27 April (842-3), 17 June (834); 0.2, 1 and
7 mi. NE Morongo Valley, 1 July (835-7).

All of the above specimens were taken on the roads except for
those from Pinto Wash Well and Long Canyon which were found
in buried can traps.

Hypsiglena torquata deserticola ‘Yanner
Desert Night Snake

Specimens examined.—Total 11, AOR unless otherwise noted: River-
side County: 1.9 mi. S Old Dale Junction, 2800 ft., 3 June (1058);
2.4 mi. NW Old Dale Junction, 31 March (1063); 1.6 mi. NW
Cholla Cactus Garden, 3 June (1059); 0.5 mi. N Pinto Y, 25 Aug.
(1060) ; 6 mi. E Pinto Y, 6 July (1065); Lower Covington Flat, 22
June, can trap A-17 (1064); Long Canyon, 3 May, under rock
(1066); ADJACENT TO MONUMENT, 7 mi. N, 3 mi. W Desert
Center, 18 April (1484). San Bernardino County: Indian Cove,
3000 ft., 22 April, under rock (1057); ADJACENT TO MONU-
MENT, 0.5 mi. N Yucca Valley Airport, under fallen Joshua trees,
24 March 1958 (1061-2).

All examples listed above and those reported by Loomis and
Stephens (1962:31) are assigned to the subspecies deserticola. The
pattern of the head and neck consists of a dark brown median spot
which touches the parietal or the first scale row behind it, and ex-
pands posteriorly to rarely touch or nearly touch the dark lateral
stripes on the nape. These broad lateral blotches extend uninter-
rupted from the eye along the neck well beyond the posterior mar-
gin of the median spot. Most of the specimens have a generally
grayish coloration, although several examples have yellowish tan
blotches. This color and other slight differences in pattern led to the
suggestion that one specimen (from White Tank) might possess
certain characteristics typical of the coastal subspecies H. t. klaubert.
Re-examination of this and all other specimens from the Monument
failed to reveal any specimens which possessed features that could be
considered as approaching or typical of the coastal subspecies. Mil-
ler and Stebbins (1965:423) indicate that one specimen from 6
miles west of Yucca Valley seems to have some traits of H. t. Alauberi.

California snakes 9

This locality is farther west than any of our records and would seem
to add another example of intergradation in the Morongo Valley
area.

Lampropeltis getulus californiae (Blainville )
California Kingsnake

Specimens examined.—Total 3: Riverside County: 1 mi. S Pinto Y,
12 July, AOR (735); Sheep Pass Camp, 2 July, DOR, (1534). AD-
JACENT TO MONUMENT, San Bernardino County: 2 mi. S Para-
dise Valley, 30 Sept. AOR (734).

Only the banded phase of this rarely encountered snake has been
found.

Masticophis flagellum piceus (Cope)
Red Racer

Specimens examined .— Total 18, AOR unless otherwise noted: River-
side County: Lost Palms Canyon, 26 May, dried specimen (1172);
Cottonwood Spring, 16 July, DOR (1533), 0.3 mi. S Old Dale Junc-
tion, 19 April (816); 2.8 mi. NW Old Dale Junction, 4 May (827);
Pleasant Valley, 1 July, DOR (1532), 2.2 mi. S White Tank, 14 Oct.
(823); White Tank Campground, 30 April (812); Squaw ‘Tank, 9
June (820); Lost Horse Valley, 16 May (814) ; 2 mi. N Salton View,
27 May (1486); Lower Covington Flat, 26 June (813); Long Can-
yon, 4 mi. N Monument boundary, 9 April (829). San Bernardino
County: 2 mi. S Twentynine Palms entrance, 12 Oct. (825) and 27
April (817); 0.4-2 mi. SE Joshua Tree entrance, 12 Aug. (821), 22
Sept. (824); ADJACENT TO MONUMENT, ‘Twentynine Palms,
30 Aug. (822); and 2 mi. S Paradise Valley, 21 July (815).

Additional Records.—Total 2, DOR and discarded: Riverside
County: 1.3 mi. S Cottonwood Spring Y, 10 May, and 0.6 mi. SE
Cholla Cactus Garden, 11 Aug.

This snake has a wide distribution in the Monument and seems to
be most abundant at higher elevations, between 2500 and 4500 feet.

The specimen taken at Squaw ‘Tank was observed devouring an
adult Side-blotched Lizard, Uta stansburiana.

Masticophis lateralis lateralis (Hallowell)
California Striped Racer

Specimens examined.—Total 2: Riverside County: Upper Covington
Flat, 4960 ft., 5 May (755). San Bernardino County: Lower Coving-
ton Flat, 6 May, AOR (754).

10 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Phyllorhynchus decurtatus perkinsi Klauber
Western Leaf-nosed Snake

Specimens examined.—Total 22, AOR unless otherwise noted: River-
side County: 2.4 to 0.4 mi. S Cottonwood Spring Y, June (1027,
1031, 1040), July (1033); 3.3 to 2 mi. S Old Dale Junction, June
(1025), July (1488); 0.7 to 6 mi. NW Old Dale Junction, May
(1029, 1030, 1038), Aug. (1035-6, 1042), July (1487); 4.4 mi. SE
Cholla Cactus Garden, 3 May (1043); 5.7 and 4.5 mi. SE Pinto Y,
June (1032, 1041); 0.6 mi. N Pinto Y, 12 July (1034); Long Can-
yon at S boundary, 1633 ft., in buried can, 5 May (1144), 13 June
(1044), 12 July (1049), 11 Aug. (1050). ADJACENT TO MONU-
MENT, San Bernardino County: Twentynine Palms, 6 May, DOR
(1039).

Additional Records.—Total 5, all AOR and released: Riverside
County: 3.1 and 1.8 mi. S Cottonwood Spring Y, June (2); 0.7 and
4.7 mi. NW Old Dale Junction, June (2). San Bernardino County:
3.3 mi. S Twentynine Palms entrance, 26 May (1).

Among the snakes, only the Sidewinder has been more frequently
collected in the Monument. Eighteen of the twenty-five Leaf-nosed
Snakes were taken in May and June.

Pituophis melanoleucus affinis Hallowell
Sonoran Gopher Snake
Figure 2

Specimens examined .—Total 2: Riverside County: Porcupine Wash,
2 mi. NW Old Dale Junction, 2375 ft., 18 April 1964, DOR (1489) ;
ADJACENT TO MONUMENT: 1 mi. SW Hayfield Pumping Sta-
tion, 1400 ft., 24 May 1963, AOR (797).

Examination of our specimens of Gopher Snakes taken in or ad-
jacent to the Monument reveals that only two specimens represent
the subspecies affinis. The only specimen from the Monument is an
adult male (1489) with 53 body and 17 tail blotches. The entire
snake is pale yellow with brown blotches which are bordered by a
thin black line on the neck, and become dark brown to black on the
tail. There are light blotches on the neck but they are not surrounded
by black as found in P m. deserticola. The ventrals number 234,
subcaudals 70, total length approximately 1231 mm, tail 187 mm.
A soft mid-body area from poor preservation prevents an accurate
body measurement.

California snakes 14

The specimen is from the southern part of the Monument ap-
proximately 12 miles north of the southern boundary and only nine
miles southeast of the southernmost record for P m. deserticola
from Cholla Cactus Garden. Both localities are shown on the map
(Fig. 2) at the edge of the Pinto Basin, and presumably these two
subspecies meet and intergrade within this hot dry basin. However,
our specimen of P m. affinis shows little evidence of the features
characteristic of P m. deserticola, and more closely resembles typical
examples of P m. affinis from southern California and southern
Arizona. The other specimen taken near the southern boundary is
an adult female possessing 60 body and 15 tail blotches, with no
evidence of light neck blotches surrounded by black, which is typical
of P m. deserticola. The ratio of tail to total length is .120, which is
close to the average of .125 in P m. affinis (Klauber, 1947:42-43),
but far below the average of .136 in adult female P m. deserticola
(Klauber, 194:7:32).

Pituophis melanoleucus deserticola Stejneger
Great Basin Gopher Snake
Figure 2

Specimens examined.—Total 12, DOR unless otherwise noted: Aiver-
side County: Cholla Cactus Garden, 23 March (796), 23 Nov.
(995); 1.5 mi. W, 2.5 mi. S Pinto Peak, 8 May 1953 (MVZ 59561) ;
2.5 mi. S White Tank Campground, 3200 ft., 15 Sept. (790) ; 1.5 mi.
NW White Tank, 18 Oct. 1945 (MVZ 1704) ; Pinto Y, 5 May, AOR
(793), 30 May (794); Queen Valley, 4250 ft., 10 April 1951 (MVZ
52514) Lower Covington Flat, Plot A in buried can, 4600 ft., 20
Oct. (791); Upper Covington Flat, Big Tree area, 5000 ft., 11 July,
caught near fallen Joshua tree limb (789). San Bernardino County:
4-5 mi. N Pinto Y, 30 Sept. (996), 16 Oct. (795).

All of these specimens seem to represent typical P m. deserticola.
The southernmost specimens from Cholla Cactus Garden possess
distinct light neck blotches surrounded by dark coloration. In addi-
tion, the tail to total length ratio of a young male (total length, 685)
is .142 which approaches that of P m. deserticola (average .148 im
males) as listed by Klauber (1947:32).

The specimens listed above and those reported previously by
Loomis and Stephens (1962:33) are plotted on Figure 2.

12 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Rhinocheilus lecontei lecontei Baird and Girard
Western Long-nosed Snake

Specimens examined.—Total 4, all DOR: Riverside County: 1 mi.
and 2 mi. N Cottonwood Spring Y, Sept. (763-4). ADJACENT TO
MONUMENT, San Bernardino County: 2 mi. S Twentynine Palms,
26 June (762); 1.2 mi. S town of Joshua Tree, 11 Aug. (761).

With the exception of one example from near Cottonwood Spring,
all of the long-nosed snakes from the Monument have the clarus
color pattern. We follow Shannon and Humphrey (1963: 153-160)
who consider R. I. clarus Klauber a synonym of A. 1. lecontet.

Salvadora hexalepis hexalepis Cope
Desert Patch-nosed Snake
Figure 3

Specimens examined.—Total 5, DOR unless otherwise noted: River-
side County: 0.6 mi. S of Cottonwood Spring Y, 28 April (720);
Cottonwood Spring Y, 11 May (721); 3 mi. and 0.3 mi. S Old Dale
Junction, 10 May (723) and 14 March (725) ; S end Wilson Canyon,
19 April (719), intergrades with S. h. mojavensis.

Seven specimens of the Western Patch-nosed Snake from the
southern part of the Monument, from Old Dale Junction southward
beyond Cottonwood Spring, including two reported by Loomis and
Stephens (1962:34), all belong to the subspecies hexalepis. These
specimens have lateral stripes as dark as the dorsal stripes and they
come together to form a solid dark anterior stripe several scale rows
wide extending from the head well back on the neck. The scalation
is typical of this subspecies, with 1-1 (5); 1-2 (1); to 2-2 (1 speci-
men) supralabials in contact with eye.

The specimens from Wilson Canyon and White ‘Tank (Loomis
and Stephens, 1962:34) seem to represent intergrades with S. h.
mojavensis. The head scalation is typical of S. h. hexalepis, whereas
the pattern approaches that of S. h. mojavensis.

Salvadora hexalepis mojavensis Bogert
Mohave Desert Patch-nosed Snake
Figure 3

Specimens examined.—Total 10, DOR unless otherwise noted: River-
side County: Queen Valley, 0.5 mi. E Sheep Pass, 25 May (1214);
Lost Horse Valley Ranger Station, 5 April (722); ADJACENT TO

California snakes 13

MONUMENT: 8 mi. N Indio, 8 April 1960 (729). San Bernardino
County: 6.1 mi. S Twentynine Palms, 19 July (716); between
Joshua Tree entrance and Lost Horse Valley Ranger Station, 12
April (718). ADJACENT TO MONUMENT, San Bernardino
County: 40 mi. E, 4 mi. S Twentynine Palms, 5 April (727) ; 0.1 mi.
N Joshua Tree entrance, 4 May (728); 0.1, 0.2 and 0.6 mi. N Monu-
ment entrance to Lower Covington Flat, 9 April (715), 4 May
(724), and 20 Oct. (717).

We are assigning these specimens to the subspecies mojavensis
on the basis of the color pattern and scalation. Only two of the speci-
mens examined have no supralabials in contact with the eye and
most of them have 1-1 supralabials in contact with the eye. How-
ever, the pattern seems to be more typical of the Mohave subspecies
in having the lateral stripes lighter than the dorsal dark lines, or
with both lines faint or obscure. The area of intergradation between
S. h. mojavensis and S. h. hexalepis probably occurs along the entire
southern margin of the upland part of the Monument, and some
northern individuals also seem to be intermediate, as illustrated on
the distribution map (Fig. 3).

A single specimen (729) from 8 miles north of Indio is a typical
example of S. h. mojavensis. Although this locality is in the Coa-
chella Valley, it is at the base of the Little San Bernardino Moun-
taims where S. h. mojavensis occurs in the Monument. Bogert (1945:
9) states that “In the southwestern corner of the range mojavensis
ranges as far south as Twentynine Palms and a specimen (no longer
extant) from Quail Springs near the summit of the Little San Ber-
nardino Mountains was quite typical in pattern and scalation. The
escarpment of the south is steep, however, and all patch-nosed
snakes taken in Coachella Valley in Riverside County are referable
to S. h. hexalepis’ This is the only example of Salvadora hexalepis
which we have seen from the Coachella Valley northwest of Indio
and we believe that it is uncommon in this low hot desert.

Tantilla eiseni transmontana Klauber

Desert Black-headed Snake

Specimen examined.—One: Riverside County: Long Canyon, + mi.
N mouth, 2800 ft., 25 May 1963 (1070).

A dried example of the black-headed snake was found by Dr. E. L.
Sleeper in a buried can trap at the head of a small canyon which
connects to Long Canyon. Although some characteristics are not

14 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

116
-—
JOSHUA TREE NATIONAL MONUMENT

Ss

STATUTE MILES

d\.| 8 Salvadora hexalepis hexalepis

@ Salvadora hexalepis mojavensis

@* Salvadora hexalepis hexalepis x Sh.mojavensis

116

|
4 JOSHUA TREE NATIONAL MONUMENT

YUCCA TWENTYNINE PALMS

VALLEY ae H Old Dale 1268"
a) ot

I SAN BERNARDINO CQ.
RIVERSIDE CO. ©

Sunrise Pinto Wash
‘well We

i!

1000'
joel

EAGLE (MTN

/

unction

ee 1c Old Dale 7J

DESERT
CENTER

5
STATUTE MILES
& Crotalus atrox
@ Crotalus scutulatus scutulatus

® Crotalus viridis helleri

California snakes 15

discernible, the following can be determined: scale rows 15; ven-
trals 188; caudals 67 + tip; anal plate divided; postoculars 2 on left
side, snout-vent length 166, tail 51 mm. These characteristics are
similar to those reported for the desert subspecies 7! e. transmontana
(Klauber, 1943:71-74).

This is the first record of occurrence in the Monument, although
Miller and Stebbins (1965:424-5) report Tantilla eiseni (no sub-
species designation) from Lower Covington Flat, elevation 4500 ft.,
only 10 miles east of our Long Canyon locality.

Specimens are also available from Whitewater Canyon, approxi-
mately 11 airline miles to the west.

Trimorphodon vandenburghi Klauber
California Lyre Snake

Specimens examined.—Total 9, DOR unless otherwise noted: Aiver-
side County: Cottonwood Canyon, 2 Feb. (746) ; Cottonwood Spring
Y, 2.3 mi. S, 2600 ft., 5 May (742), 1 mi. S, 2900 ft., 20 May (738)
and 12 June AOR (739); 2.8 mi. NW Cholla Cactus Garden, 2700
ft., 12 April (744) ; 1.6 mi. NW Jumbo Rock, 4100 ft., 15 Sept., AOR
(741); Lost Horse Valley Ranger Station, 4200 ft., 2 July, in rocks
(740); ADJACENT TO MONUMENT: 3 mi. W, 4 mi. N Desert
Center, 1000 ft., 5 April (734) and 26 April (746).

All of the specimens taken alive were discovered after dark. The
example from Lost Horse Valley Ranger Station was found in the
rocks eating an adult Fence Lizard, Sceloporus occidentalis. The
records from 4100 to 4200 feet seem to represent the highest known
collecting stations for this species. Klauber (1940b:176) lists 2800
feet as the highest elevation from which he collected this species.

The above specimens agree with the description of 7! vanden-
burghi in the high number of dorsal blotches, 5 males average 34.4
(range 34-36), 4 females average 41 (range 38-45), but five of the
nine specimens (56%) have divided anal plates. The divided anal
plate is characteristic of T. lambda and the high percentage among

Figure 3. Distribution of Salvadora hexalepis in and near the Monument. The
inverted triangle represents each specimen of S. h. hexalepis, the upright triangle
is S. h. mojavensis, and each diamond symbol represents a supposed intergrade,
with the lower half black if closer to hexalepis and the upper half black if more
nearly resembling mojavensis. The 3500 foot contour line is shown.

Figure 4. Distribution of three species of rattlesnakes, Crotalus atrox, triangles;
Crotalus s. scutulatus, circles; and Crotalus viridis helleri, squares. The 4000
foot contour line is shown.

16 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

our specimens seems to indicate that T vandenburghi is a subspecies
of T. lambda.

Our two females from near Desert Center extend the known range
of vandenburghi 30 miles to the east from the previous easternmost
record (Loomis and Stephens, 1962:34). They both have divided
anal plates, but the high dorsal blotch counts of 41 and 45 more
closely approach vandenburghi even though this is only 55 miles
west of the nearest locality of T. lambda in the Riverside Mountains
(Klauber, 1940:187).

Crotalus atrox Baird and Girard
Western Diamond Rattlesnake
Figure 4

Specimens examined.—Total 14, AOR unless otherwise noted: River-
side County: Pinto Wash Well, 1000 ft., 28 April 1962 (966); 18
Aug. 1962 (967), 6 Oct. 1963, shed skin (1171); mouth of Cotton-
wood Canyon, 2 Sept. 1963, DOR (968); 2.9 mi. S Cottonwood
Spring Y, 2500 ft., 28 July 1961, female (957) and her 8 young
(958-965) born 30 Aug. 1961; ADJACENT TO MONUMENT, 5.3
mu. N Desert Center, 14 April 1963 (997); and 1.5 mi. E, 3 mi. N
Indio, 26 Nov. 1957 (1174).

These are the first Western Diamond Rattlesnakes to be reported
from the Monument, and include the specimens mentioned by Mil-
ler and Stebbins (1964:428). They were collected along the south-
ern boundary of the Monument at elevations below 2500 feet in the
Sonoran Desert.

Crotalus cerastes Hallowell
Sidewinder

Specimens examined .— Total 44: Riverside County: Pinto Wash Well
area, 24 May (944) and 12 July (949) ; Cottonwood Spring Y to 2.8
mi, N; June (884-5; 912), July, (8935, 895), Dee: GEteH)) Ss eantio
Basin, 2.5 mi. S Old Dale Junction to 2.56 mi. NW Cholla Cactus
Garden, April (891, 902-4, 945), May (508, 881, 906-7, 910, 916,
936-8, 941, 1529,30), June (881-2, 917, 924), July (892, 894, 896-
901), Aug. (913-4), Sept. (915, 946). San Bernardino County: 6
mi. S ‘Twentynine Palms Monument Headquarters, 29 April (889-
890); Twentynine Palms Headquarters, 30 May (909); Indian
Cove, 5 May (905).

Geest (in manuscript) had determined that Crotalus cerastes
cerastes is found in suitable habitats below 4000 feet throughout the

California snakes 17

central and eastern parts of the Monument, whereas C. c. laterore-
pens Klauber, which occurs in the Coachella Valley is anticipated
but has not been found in the Monument. The ranges of these two
subspecies do not seem to meet in or near the Monument.

Crotalus mitchelli pyrrhus Cope
Southwestern Speckled Rattlesnake

Specimens examined.—Total 25: Riverside County: 1 mi. S Pinto
Wash Well, 1000 ft., 2 May, AOR (1481); 4.8 mi. S to Cottonwood
Spring, 2500-3000 ft., 21 May, DOR (982), 22 June (993), 4 Aug.,
AOR (1536), 18 Aug., DOR (989) and 5 Sept., DOR (991); Lost
Palms Oasis, 18 May (1527-8), 18 June (1526); 5.7 mi. SW Pinto
Y, 30 June, AOR (987); Wilson Canyon, 23 June, DOR (1490);
Pinyon Well, 3800 ft., 19 March (984); Lost Horse Valley Ranger
Station, 4300 ft., 14 June (983); Hidden Valley Nature Trail, 4200
ft., 31 May (1479). ADJACENT TO MONUMENT, Riverside
County: 8 mi. W of S entrance, 25 May, AOR (988) 14 mi. N Indio,
18 May 1957, AOR (1211); 3 mi. NE Thousand Palms Oasis, 3
May, DOR (1212). San Bernardino County: Indian Cove, 15 May
(990, 992, 994); 4 mi. S, 4 mi. E Joshua Tree, 25 May (1480);
Upper Covington Flat, Furela Point, 5400 ft., 4 June (985) ; Lower
Covington Flat, 1 mi. S Monument Birance: 13 July, AOR (981);
ADJACENT TO MONUMENT, ‘Twentynime Palms, 20 June
(1535), and 0.4 mi. N Covington Flats entrance, 5 May, AOR (986).

The speckled rattlesnake has the greatest altitudinal range of any
rattlesnake having been found at the highest (5400 feet) and the
lowest (1000 feet) parts of the Monument. It is most common in the
vicinity of rocks and seems to be absent only from the extensive
gravelly and sandy areas at lower elevations which are some dis-
tance from large rocks. Eighteen of these 25 rattlesnakes were taken
in May and June.

Crotalus ruber ruber Cope
Red Diamond Rattlesnake

Specimen examined.—One: ADJACENT TO MONUMENT, Avwer-
side County: 5.4 mi. NW (airline) Desert Hot Springs, 1800 ft., 25
May 1964, AOR (1525).

This rattlesnake was captured on the Twentynine Palms High-
way approximately six miles west of the western boundary of the
Monument near the mouth of Morongo Valley. Although no speci-
mens are available, verbal reports from park rangers of red rattle-

18 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

snakes seen in the western part of the Monument may refer to this
species.

This is another coastal snake which probably reaches its eastern
limit of distribution in or just east of the Morongo Valley.

Crotalus scutulatus scutulatus (Kennicott)
Mohave Rattlesnake
Figure 4

Specimens examined.—Total 2: San Bernardino County: Black Rock
Spring, 4 Oct. 1962, AOR (1145); ADJACENT TO MONUMENT:
3 mi. N Monument entrance to Lower Covington Flat on La Con-
tenta Road, 28 April 1962, AOR (1051).

The specimen from Black Rock Spring represents the first Mo-
have Rattlesnake found in the Monument. The locality is in the
northwestern corner of the Monument which is considered as part.
of the Mohave Desert. These are the specimens mentioned by Mil-
ler and Stebbins (1964:427). The lack of additional records from
seemingly suitable habitats which have been extensively investi-
gated indicates either it is absent or extremely rare in other parts of
the Monument.

The known ranges of Crotalus scutulatus and Crotalus atrox do
not come into contact in the Monument, or in any other part of
California, although they are sympatric over much of the southern
half of Arizona (Klauber, 1956).

Crotalus viridis helleri Meek
Southern Pacific Rattlesnake
Figure 4

Specimens examined.—Total 3: Riverside County: Jumbo Rocks
Campground entrance, 24 Aug., AOR (1492) ; below Lower Coving-
ton Flat Camp, 27 June (956). San Bernardino County: Lower
Covington Flat, 0.2 mi. N County Line, 4700 ft., 23 May, AOR
(1482).

Discussion

The snakes of the Monument can be arranged into three categories
based on geographic distribution: (1) those which are widespread
and occur in both coastal and desert areas throughout southern Cali-
fornia (12 species); (2) snakes found only in the deserts (5 species) ;
and (3) snakes only in coastal areas (2 species).

California snakes 19

Seven of the widespread species are represented by a single sub-
species found throughout the Monument, although they are more
common at moderate elevations, above 2000 feet and below 4000
feet, in the Yucca plant belt: Lichanura trivirgata gracia, Hypsig-
lena torquata deserticola, Lampropeltis getulus californiae, Masti-
cophis flagellum piceus, Rhinocheilus 1. lecontei, Trimorphodon
vandenburghi and Crotalus mitchelli pyrrhus. The first subspecies
apparently interbreeds with the coastal subspecies in the Morongo
Valley area. Tantilla eiseni is known only from two areas, and seems
to be limited to small isolated populations.

The other five widespread species are represented in or near the
Monument by two subspecies: one being the subspecies of the Mo-
have Desert, and the other representing the geographic race of the
Colorado Desert (the subdivision of the Sonoran Desert in Califor-
nia). Leptotyphlops humilis humilis is in the Mohave (and certain
coastal areas of southern California) and L. h. cahuilae occurs
throughout the Colorado Desert. Pituophis melanoleucus deserticola
is common in the central upland area and northward into the Mo-
have Desert, whereas P m. affinis occurs in the southern part of the
Monument, and their ranges meet in the Pinto Basin (Fig. 2).
Arizona elegans candida which occurs in the upland area (mostly
above 3500 feet), is the subspecies of the Mohave Desert, whereas
Arizona elegans eburnata is at lower elevations throughout the
creosote bush plant belt (Fig. 1). Salvadora hexalepis mojavensis
occurs in and adjacent to the Pinyon Belt to the north, whereas S. h.
hexalepis is found in the southern part of the Monument (Fig. 3).

Of the five species limited to the desert, Chionactis o. occipitalis
and Phyllorhynchus decurtatus perkinsi each is represented by a
single widespread subspecies. The Sidewinder, Crotalus cerastes is
represented by two subspecies, C. c. laterorepens in the Coachella
Valley (not yet taken in the Monument) and C. c. cerastes found
throughout most of the Monument in suitable habitats below 4000
feet. Their ranges do not seem to meet within the Monument. The
other two desert species, both rattlesnakes, each has a limited distri-
bution within the Monument. Crotalus atrox has been found along
the southern boundary within the Sonoran Desert, at elevations
below 2500 feet, and Crotalus s. scutulatus is known only from the
northwestern Mohave area, at elevations between 3500 and 4000
feet (Fig. 4).

Finally, the two coastal species, Masticophis lateralis lateralis and
Crotalus viridis helleri, have been taken only at scattered localities

20 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

above 4000 feet in chaparral and pinyon-juniper plant associations
(pinyon plant belt of Miller and Stebbins, 1964). One additional
coastal species, Crotalus r. ruber has been taken in the Morongo
Valley and may occur in the Monument.

The Morongo Valley, a low desert pass which separates the pin-
yon plant belt of the Monument (Little San Bernardino Mountains,
and adjacent plateau) from the pinyon belt of the coastal range of
the San Bernardino Mountains, seems to represent a route of dis-
persal for certain desert species, and is a partial barrier for other
snakes. It is an area of contact between several subspecies which
have both coastal and desert races. Intergradation is known between
Leptotyphlops h. humilis and L. h. cahuilae, (Klauber, 1940a: 137),
Pituophis melanoleucus annectens and Pm. deserticola (Klauber,
1947:35, 37), Lichanura trivirgata roseofusca and L. t. gracia, and
Hypsiglena torquata klauberi and H. t. deserticola (Miller and
Stebbins, 1964).

The presence of the upland piyon area with suitable habitats for
coastal forms seems to be of relatively recent origin. Axelrod (1950:
236) states that near the close of the Pliocene, “mountain ranges
were elevated several thousand feet on the coastal side of the present
desert region, and the Mohave province was likewise elevated, per-
haps 1000 feet or more. It was also during this mountain-building
episode that the San Bernardino Mountains and adjacent ranges to
the eastward along the present boundary of the Mohave and Sono-
ran Deserts were uplifted to essentially their present heights. Thus
the topographic features which now define the Mohave and Sonoran
Desert regions in California assumed their present outlines as Mo-
havia was broken up into these subprovinces at the close of the
Cenozoic.’

If a species of snake has a coastal and desert race, in no instance
is the coastal subspecies in the Monument. The absence of the coastal
subspecies seems to have been due to the failure of coastal subspecies
to reach higher suitable areas (pinyon-chaparral) which are of
relatively recent origin. Both the presence of unsuitable interven-
ing habitats in Morongo Valley and one or more desert subspecies
already well-established throughout the Monument area would be
sufficient to exclude the coastal races. Only two coastal species
(Masticophis lateralis and Crotalus viridis) have become estab-
lished in the upland pinyon belt, and these are large active snakes
which lack subspecies in the Mohave and Sonoran deserts.

The continuous range of mountains from the San Bernardino

California snakes 21

Mountains southeastward through the Little San Bernardino, Hexie.
Cottonwood and Eagle mountains and the adjacent uplands repre-
sents a barrier for both plants and animals which are characteristi-
cally restricted to the low deserts. Low desert species and subspecies
which have been found up to, but not beyond, this mountain barrier
are: Crotalus atrox, Crotalus cerastes laterorepens, Leptotyphlops
humilis cahuilae, and Tantilla eiseni transmontana. Crotalus ruber
ruber, a coastal species which enters the desert in San Diego County
and southward, also has not been found in or beyond this range of
mountains.

LITERATURE CITED

AXELROD, DANIEL A.

1950. Evolution of desert vegetation in western North America. Studies in Late
Tertiary paleobotany. Contrib. Paleo. Carnegie Inst. Wash., 590:215-306.

BOGERT, CHARLES M.

1945. Two additional races of the Patch-nosed Snake, Salvadora hexalepis. Amer.
Mus. Novitates, 1285: 1-14, 10 figs.

KLAUBER, LAURENCE M.

1940a. The worm snakes of the genus Leptotyphlops in the United States and
northern Mexico. Trans. San Diego Soc. Nat. Hist., 9(18):87-162, pl. 6,
figs. 1-8, maps 1-2.

1940b. The lyre snakes (genus Trimorphodon), of the United States. Trans. San
Diego Soc. Nat. Hist.,9(19): 163-194, 1 pl., map.

1943. A desert subspecies of the snake Tanztilla eiseni. Trans. San Diego Soc. Nat.
Hist., 10(5):71-74.

1946. The glossy snake, Arizona, with descriptions of new subspecies. Trans. San
Diego Soc. Nat. Hist., 10(17):311-398, 2 pls., 1 fig., map.

1947. Classification and ranges of the gopher snakes of the genus Pituophis im
the western United States. Bull. Zool. Soc. San Diego, 22: 1-81, 6 figs.

1956. Rattlesnakes, their habits, life histories, and influence on mankind. Berke-
ley: Univ. Calif. Press, 2 vols., pp. xxix + 1476.

LOOMIS, RICHARD B. and ROBERT C. STEPHENS

1962. Records of snakes from Joshua Tree National Monument, California, Bull.
So. Calif. Acad. Sci., 61(1):29-36.

MILLER, ALDEN H. and ROBERT C. STEBBINS

1964. The lives of desert animals in Joshua Tree National Monument. Berkeley:
Univ. Calif. Press, pp. vi + 452, 7 pls., 141 figs.

22 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967
SHANNON, FREDERICK A. and FRANCES L. HUMPHREY

1963. Analysis of color pattern polymorphism in the snake, Rhinocheilus lecontei.
Herpetologica, 19(3):153-160, 3 figs.

TANNER, WILMER W. and CLIVE D. JORGENSEN

1963. Reptiles of the Nevada Test Site. Brigham Young Univ. Sci. Bull., 3(3):1-
31, 12 figs.

STUDIES OF THE BLOOD OF ASCIDIA NIGRA

(SAVIGNY). I. TOTAL BLOOD CELL COUNTS,

DIFFERENTIAL BLOOD CELL COUNTS, AND
HEMATOCRIT VALUES

James A. VALLEE, JR.

Department of Biology
California State College
Long Beach, California

INTRODUCTION

The blood of Ascidia nigra has been studied by several investigators.
George (1930, 1939) and Fulton (1920) presented a detailed de-
scription of the blood cells. Hecht (1918) studied the general physi-
ology of the blood. More recently Andrew (1961, 1962) has studied
living blood cells of A. nigra using a phase-contrast microscope. Ful-
ton (1920) gave dierential cell counts. However, they were based
upon a classification which is no longer accepted, and did not demon-
strate the individual variation which occurs. Total blood cell counts
and hematocrit values are not to be found in the literature. It was
therefore desirable to investigate these topics as a study preliminary
to an investigation of the biochemistry and physiology of the blood
of A. nigra.

Fndean (1955) studying the blood cells of Pyura stolonifera found
a great deal of variation in the haemocytometer counts. ‘Twelve ani-
mals showed a range of 18,250 to 68,200 cells per mm,’ with a mean
of 37,000 cells per mm.* Webb (1939) found 64,000 cells per mm*
in the blood of Phallusia mammillata.

MATERIALS AND METHODS

Animals were collected from sea walls on Key Biscayne, Florida,
and placed in an aquarium with running sea water. Although A.
nigra survives in an aquarium for several weeks, the animals were
generally used within two or three days. Total blood cell counts were
obtained as follows: the test of the animal was removed from the re-
gion of the heart and visceral vessel. This procedure causes the ag-
glutmation of the blood cells throughout the circulatory system.
However, if the animal is left undisturbed for a period of 15 to 20
minutes the agglutination process reverses and the blood returns to
its normal condition (This phenomenon will be reported upon in de-

23

24, Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

TABLE 1
Blood Cell Counts in Ascidia nigra

Tunicate No. of Cells per mm?
1 62,830
2 79,390
3 38,640
4. 54,120
5 58,180
6 54,680
i 45 280
8 67,880
9 4.4..72.0
10 31,660
Average 53,338

tail in a later paper). One ml of blood was then removed from the
visceral vessel, using a tuberculin syringe. This blood sample was
delivered into a vial containing one ml of 0.02 M cysteine in phos-
phate buffer (pH 6.7) made isotonic with sea water by the addition
of NaCl. Cysteine prevents the agglutination of the blood cells in the
sample. The sample was diluted 1:9 with a dilute solution of neutral
red in sea water to stain the cells. Two drops of the sample were then
placed in a haemocytometer. The cells in one mm* of sample were
counted, and the number obtained multiplied by 20 to correct for
dilution, thus obtaining the number of cells in one mm* of undi-
luted sample. Blood cell counts were thus obtained for ten animals.

The percentage (by volume) of the blood occupied by blood cells
was also determined. The animals were prepared as described above.
One-fourth ml of 0.05 M cysteine in isotonic phosphate buffer was
drawn into a tuberculin syringe. Then 0.75 ml of blood was with-
drawn from the visceral vessel of the tunicate, introduced into a
hematocrit tube and centrifuged for ten minutes. The percentage of
cells in the sample was then read off the tube and multiplied by 4/3
to correct for dilution with cysteme, thus obtaining the percentage of
cells in the blood.

Studies on tunicate blood 25

Differential blood cell counts were obtained as follows: with a tu-
berculin syringe, one ml of blood was removed from an animal pre-
pared as described above. The sample was then placed in a vial with
one ml of 0.02M cysteine. One-fifth ml of a dilute solution of
methylene blue and neutral red in sea water was then added to 0.2
mi of the blood sample. This aided in differentiating the various cell
types. A wet slide preparation was then made and the number of the
various types of cells in a 470X field counted. Several fields (300 to
500 cells) were counted for each of the animals studied, and the per-
centages of the various cell types calculated.

OBSERVATIONS AND RESULTS

The total blood cell counts for ten animals are given in Table 1.
There is considerable variation from one animal to another, the
counts ranging from 31,660 to 79,390 cells per mm’, with an average
of 54,340 cells per mm‘*. As can be seen in ‘Table 2, the cells occupy
1.6 to 2.5 per cent of the blood volume, the average being 2.0 per cent.

The results of the differential cell counts are given in ‘Table 3.
George’s classification is followed as closely as possible. However,
the modern term vanadocyte is used instead of the term green cell.

TABLE 2

Hematocrit Values in Ascidia nigra

Tunicate Per Cent Cells

af LS
2 1.6
3 oft
4 2.3
5 1.6
6 2.0
if QRS
8 lo
9 ed
10 25

Average 9.0

26 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Also George’s amoeboid compartment cells are called vacuolated
amoebocytes, a term which more accurately expresses the nature of
the cell. Occasionally small spherical cells staining with methylene
blue were found. These “spherical cells” were not described by
George. As can be seen in Table 3, the vanadocytes comprise about
61% of the blood cells while vanadocytes, vacuolated amoebocytes,
and signet ring cells together account for 90% of the blood cells. It
can also be seen that the differential cell counts vary from one animal
to another, especially with regard to signet ring cells and morula
cells.

DIscussION

Very little information on total cell counts of tunicate blood is
available. Two figures were found: 64,000 cells per mm* in Phallusia
mammillata (Webb, 1939), and 37,000 cells per mm* in Pyura
stolonifera (Endean, 1955). Ascidia nigra with an average of 53,000 ©
cells per mm, is intermediate between Phallusia mammillata and
Pyura stolonifera. Endean showed that the blood of Pyura stolonifera
varied from 18,250 to 68,200 cells per mm*. The blood cell counts of
Ascidia nigra varied from 32,000 to 79,000 cells per mm*. Endean
also estimated that the blood cells comprised about one per cent of
the blood volume of Pyura stolonifera. The blood cells of Ascidia
nigra were found to account for two per cent of the blood volume.
Although there is a great deal of variation in the concentration of the

TABLE 3
Differential Cell Counts in Ascidia nigra

Percentages
Cell Type Tunicate 1 2 3 4: 5 average
Vanadocy tes 60.1 63.7 56.4 63.2 62.7 61.2
Vacuolated amoebocytes 5.5 5.3 11.5 6.1 10.9 7.9
Signet ring cells 233 DO) 14.3 27.0 17.4 20.9
Morula cells 3.3 3.3 9.0 0.0 21 3.5
Coarsely granular amoebocytes 4.4 3.5 6.1 3.0 4.8 4.4
Blue cells 1.4 0.5 2.0 0.4 0.7 1.0
Spherical cells 1.4: 0.2 0.2 0.0 0.2 0.4:
Orange cells 0.2 0.4 0.4 0.4 0.2 0.3

Finely granular amoebocytes 0.7 0.5 0.2 0.0 1.2 0.5

Studies on tunicate blood 27

blood cells in both species, it appears that Ascidia nigra has about
twice the concentration of blood cells as Pyura stolonifera.

The differential cell counts of the present study agree quite well
with those of Fulton (1920). He found that the green, orange, and
blue cells made up 60%, 1 to 2% and 2 to 3% of the blood cells
respectively. Corresponding values in the present study are: 61.2%,
0.3%, and 1.0%. Finely granular amoebocytes, signet ring cells, and
morula cells were found by Fulton (1920) to account for 1%, 20%,
and 1.2% of the blood cells, compared to 0.5%, 20.9%, and 3.5% in
the present study. He also found that vacuolated amoebocytes and
coarsely granular amoebocytes made up 10% and 5% of the blood
cells respectively, compared to 7.9% and 4.4% in the present study.

It should be pointed out that the coarsely granular amoebocyte and
the vacuolated amoebocyte appear to be distinctly different cell types,
and should not be grouped together as suggested by Andrew (1961).

The “spherical cell” mentioned above has no equivalent in either
George’s or Fulton’s classification. It was only rarely seen, and may
have been missed by earlier workers. As can be seen in Table 3, when
the morula cells are more abundant than usual, the signet ring cell
percentage is below normal, and when the signet ring cells are more
abundant than usual the morula cell percentage is below normal.
This observation provides some support for Andrew’s (1961) idea
that signet ring cells develop into morula cells.

SUMMARY
(1) The concentration of cells in the blood of Ascidia nigra was
found to range from 31,700 to 79,400 cells per mm*. The average
count was 53,300 cells per mm‘.

(2) The blood cells comprise an average of 2.0% of the blood volume.

(3) Differential blood cell counts were obtained. Sixty-one per cent
of the blood cells were vanadocytes.

ACKNOWLEDGMENT

I wish to thank Dr. Charles E. Lane for his advice, and the use of
equipment, without which the present study would not have been
possible.

LITERATURE CITED
ANDREW, W.
1961. Phase microscopic studies of living blood cells of the tunicates under nor-
mal and experimental conditions, with a description of a new type of
motile cell appendage. Quart. J. Micr. Sci., 102:89-105.

28 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

1962. Cells of the blood and coelomic fluids of tunicates and echinoderms. Amer.
Zool., 2:285-297.

ENDEAN, R.

1955. Studies of the blood and tests of some Australian ascidians. I. The blood of
Pyura stolonifera Heller. Aust. J. Mar. Freshw. Res., 6:35-39.

FULTON, J. E

1920. The blood of Ascidia atra Lesueur; with special reference to pigmentation
and phagocytosis. Acta Zoologica Stockholm, 1:381-433.

GEORGE, W. C.

1930. The histology of the blood of some Bermuda ascidians. J. Morph. Physiol.,

49: 385-413.

1939. A comparative study of the blood of tunicates. Quart. J. Micr. Sct., 81:391-
499.

HECHT, S.

1918. The physiology of Ascidia atra Lesueur. III. The blood system. Amer. J. -
Physiol., 45:157-187.
WEBB, D. A.

1939. Observations on the blood of certain ascidians, with special reference to the
biochemistry of vanadium. J. Exp. Biol., 16:499-532.

SELF-REGULATORY GROWTH IN THE GREEN ALGA
ENTEROMORPHA PROLIFERA FORMAE?

ANDREW KIER AND FRic S. Topp

Department of Biological Sciences
University of California
Santa Barbara, California 93106

INTRODUCTION

The green alga Enteromorpha prolifera is widely distributed along
temperate Pacific and Atlantic coasts, often occurring as dense mats
in estuaries and marine backwaters (Carter, 1932; Hedgpeth, 1957),
where it is highly tolerant of extreme ranges of temperature and
salmity (Biebl, 1956).

As a result of pollution caused by large quantities of rotting En-
teromorpha in the campus lagoon of the University of California,
Santa Barbara, we initiated the present study to determine: (1) the
conditions responsible for lagoon blooms of the alga, (2) pertinent
information concerning its life history and structure, and (3) the
mechanisms involved in the bloom declines.

MATERIALS AND MrtrHops

This lagoon covers 27.4 acres and has a maximum depth of 6 feet. Its
level is maintained mostly by seawater flowing from the adjacent
marine laboratory (University of California, Santa Barbara). Dur-
mg a recent hydrobiological study of the lagoon the following weekly
measurements were made: water temperature (with a thermistor) ;
salmity (induction salinometer); dissolved oxygen (galvanic cell
oxygen analyzer); dissolved orthophosphate (stannous chloride
method—Wooster and Rakestraw, 1951); and transparency (secchi
disc).

The area covered by mats of Enteromorpha and the widgeon grass
Ruppia maritima was traced twice a month on standard maps of the
lagoon. The traced area was cut out and weighed, so that the percent
surface cover could be determined. The Enteromorpha crop was
measured only when it appeared on the surface as a mat. The mat
cover was estimated by observing distances of mats from a series of
marker buoys, and from natural features such as surface snags and

1This work was supported by National Science Foundation Institutional Grant
GU706, to the University of California, Santa Barbara.

29

20 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

small coves. This method best showed relative increases of the super-
ficial expanse of the algal mat, rather than its absolute percentage of
lagoon cover. Square meter samples of the drifting mats were air-
dried and weighed to estimate biomass of the floatmg crop. Observa-
tions of its ecology and life history were made weekly.

Light intensity measurements were made in May and June on
clear and overcast days on the surface of the algal mats, immediately
under the mats and in open water at 2.5 cm. depth.

To compare chlorophyll concentrations in the algal bed, one-gram
(wet weight) samples gathered from the surface of the mat and at
5 cm. depth were ground in acetone for 2 minutes; the extraction
was then filtered through Number 1 Whatman paper and was
measured for color intensity with a Klett colorimeter fitted with a
No. 66 red filter. Gas composition in the bladder-like thallus was
determined from 5 samples in the late morning on overcast days
drawn with a syringe from submerged bladders with a Scholander —
microgasometric analyzer.

RESULTS

During the study period April, 1964, to September, 1965, the water
temperature constantly decreased from 29°C in the summer to 13°C
in the winter and increased again to 28°C the following summer
(Fig. 1). The salinity increased through the first summer to 45%,
then decreased during the winter rains to 12%. by late March and
steadily increased again the following summer. The surface water
remained saturated with oxygen throughout the year but bottom
water fluctuated between 0 and 10 ml/I dependent on wind and
photosynthetic activity. Phosphate concentrations of the marine
laboratory effluent entering the lagoon were about one u-gram atom/
liter; those of the lagoon were consistently high, around 13 u-gram
atom/liter. Transparency fluctuated sporadically, ranging from 8
inches in April, 1964, to 50 inches in May, 1965. Enteromorpha
growth was also sporadic, heavy blooms occurring in January and
June of 1964, February of 1965, and March of 1966 (we were unable
to gather quantitative data for the January 1964 bloom and the
March bloom of 1966). A heavy bloom of the widgeon grass Ruppia
maritima occurred in late spring and in the summer of 1965, com-
pletely displacmg Enteromorpha, which continued to bloom in the
nearby Goleta Slough. The mean weight of 5 samples of the air-dried
algal mat was 272 grams per square meter. This represented during
one peak bloom a floating biomass of about 4.4 x 10° kilograms (dry

Green algal growth 31

°C

; 50 PRUPPIA
ae Va
F8 7
zo Le
$3 eine, oe
a —— =. aa
x Oo ee =o S <——— e.
a , i ~~ *ENTEROMORPHA
Z 50 ee
ae SS Wh
ae —~ i :
ze 2
zs i =e WZ =<
& — —e—__| re
ww = ‘
P
<a
x,
w
a
=
Ww
E

OXYGEN SALINITY
mi/t eo

pH

RUS
8

jh-atoms/!

PO

APR MAY JUN JUL AUG SEPT OCT NOV DEC JAN FEB MAR APR
1964 1965

Figure 1. Distribution of mean monthly values (abscissa) of various environ-
mental parameters (along ordinate) of the University of California, Santa Bar-
bara Lagoon. Note the correlation of the measure of water transparency with
extent of plant blooms.

weight). Light readings taken immediately below floating mats were
always less than 1% of those taken on the mat surface where values
ranged from 75 to 100 milliamps. Readings taken in open water at a
sumilar depth (2.5 cm.) ranged from 20% to 50% of surface read-
ings.

The acetone extraction of samples taken from below the algal mat
measured 53 chlorophyll units/milliliter (Harvey, 1934) while that
from the mat surface measured 7 chlorophyl units/milliliter.

The trapped gas contained up to 40% oxygen and 3.5% carbon
dioxide.

Lire History

The thallus of E. prolifera is but two cells thick, although as much
as 15 cm. wide. This allows the eventual formation of a gas bladder

22 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

as the two cell layers separate. As the thallus grows, continued ver-
tical cleavage (broadening) without horizontal cleavage (thicken-
ing) lengthens and broadens the bladder.

Initially, in clear water, the thalli begin to grow on the lagoon
bottom. Gas accumulates in the thalli, buoying them up. The process
is self-accelerating: the higher the thalli rise off the bottom, the more
light is available for photosynthesis, and the faster the buoyant gas
is produced. That carbon dioxide is trapped in high concentration
might also facilitate growth. The process continues until the thalli
float on the surface in convoluted masses. Descending from these
twisted bladders to the lagoon bottom are long filaments containing
little or no gas. Extensive areas on the lagoon surface are thereby
covered with a mat which attains a thickness often of 7 to 8 cm.
While the surface of this mat is exposed to extremes of temperature
and radiation, it shades the dark, cool layer below. The photosyn-
thesizing algal mat causes supersaturation of the surrounding water ~
with oxygen. We found this condition to extend at times throughout
the night.

After floatmg for two or three weeks, the mat breaks away from
the dying filaments which attach it. Still living, the mat is blown
over the surface by the wind. It eventually dies, sinks and decom-
poses. Only a very narrow margin of living alga remains for a while
in the shallows around the edge of the lagoon.

Discussion

Attempts to correlate cycles of algal bloom and decline with the
gradual annual physical and chemical cycles failed.

Dissolved oxygen maxima follow, rather than precede, algal
blooms. Strong winds frequently overturned the oxygen-depleted
bottom water (July, September, and November, 1964; January,
February, March, May, June and July, 1965), providing high levels
of oxygen. The only relationship between algal blooms and oxygen
levels is the increase in oxygen due to increased photosynthetic
activity.

Blooms occurred during salinity maximums and minimums, pre-
cluding any possibility of a strict dependence upon such conditions.
The continuous excess of phosphates eliminates it as a possible bloom
initiator. Occurring throughout the year, the blooms are independent
of a night-length cycle.

Only the water transparency curve could be correlated with that

Green algal growth 33

of algal growth. Each bloom was preceded by a period of rapidly
clearing water. The interval of several weeks between clearing of
the water and a noticeable increase in algal surface cover constituted
the time required for the filaments to reach the surface and form the
spreading mat. A rapid clearing of the water also preceded the
spring-1965 Ruppia maritima bloom. Because it is a benthic plant,
it is logical that its initial growth would be dependent upon light.

Upon formation of the surface mats, new growth below apparent-
ly ceases because the amount of light penetrating the mats is greatly
reduced (to less than 1% of the surface light). The plant partially
compensates for this by increasing its chlorophyl content of the
lower parts of the mat (the contrast between the light green surface
of the mat and the dark green below is striking). Even with this
chromatic adaptability, however, lower portions of the mat eventu-
ally die. Carter (1933) observed that the lower portions of Entero-
morpha mats were “unhealthy” and Stewart (1958) described
sumilar conditions in the subcanopy of Ruppia maritima. Ruppia,
being a vascular plant, however, may tolerate lower light intensities
over much of its surface for longer periods than Enteromorpha. The
deterioration of the trailing filaments then results in the detachment
of the mat from the bottom, allowing wind and wave action to break
it up. The abnormal exposure to intense insolation probably hastens
the death of the algal mat (Doty, 1957). Decay increases water
turbidity from particulate debris and pigmented products of decom-
position, thereby preventing any new algal growth.

Of the observed environmental parameters, only increasing tur-
bidity appeared to inhibit Enteromorpha proliferation. Ruppia, how-
ever, continued to spread under turbid conditions probably because
of its vascularity. Under normal conditions of tidal flux Enteromor-
pha may never create polluted conditions of massive decomposition,
although in the relatively stable lagoon it contributes significantly
to eutrophization. Here heavy growth proceeds until reduced light
available to the vital sub-surface component causes rapid destruction
of the entire population.

ACKNOWLEDGMENTS

We thank Chancellor Vernon I. Cheadle of the University of Califor-
nia, Santa Barbara for his continued support of the lagoon study; Dr.
Alfred W. Ebeling and Dr. Joseph Connell for criticizing the manu-
script; Dr. Michael Neushul for his assistance in identifying lagoon
plants; and Mr. David Valentine for his technical aid.

34, Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

LITERATURE CITED
BIEBL, R.
1956. Zellphysiologisch-okologische Untersuchungen an Enteromorpha clathrata
(Roth) Greville. Bericht der deutschen botanischen Gesellschaft (Berlin),
69:75-86.

CARTER, N.
1932. A comparative study of the alga flora of two salt-marshes. I. J. Ecology,
20:341-370.

1933. A comparative study of the alga flora of two salt-marshes. II. J. Ecology,
21:128-208.

DOTY, M. S.

1957. Rocky intertidal surfaces. In: J. W. Hedgpeth (Ed.) Treatise on marine
ecology and paleoecology (1:Ecology). Geological Soc. Amer., Memoir
67:535-586.

HARVEY, H. W.

1934. Measurement of phytoplankton population. J. Mar. Biol. Assn., United
Kingdom, 19:761-773.

HEDGPETH, J. W.

1957. Estuaries and lagoons. II. Biological aspects. In: J. W. Hedgpeth (Ed.)
Treatise on marine ecology and paleoecology (1:Ecology). Geological Soc.
Amer., Memoir 67:693-729.

STEWART, H. B.

1958. Sedimentary reflections of depositional environment in San Miguel La-
goon, Baja California. Bull. Amer. Assn. Petroleum Geologists, 42(11):
2567-2618.

WOOSTER, W. S. and RAKESTRAW, N. W.

1951. The estimation of dissolved phosphate in seawater. J. Mar. Res., 10(1):91-
100.

A NEW SPECIES OF NEOFUNGELLA (BRYOZOA,
STENOLAEMATA) FROM SOUTHERN CALIFORNIA

WituiaAm C. BANTA

Allan Hancock Foundation
University of Southern California
Los Angeles, California 90007

In his monograph on the Heteroporidae, Borg (1933:259) erected a
new genus, Neofungella, to accommodate the peculiar antarctic spe-
cies, Heteropora claviformis Waters, 1904. Borg comments (p. 260)
that the characters of the species ally it more closely to the fossil gen-
era Multicresis d’Orbigny, 1852:1073, and Fungella von Hagenow,
1851:37, than to the recent genus Heteropora Blainville, 1830. The
discovery of a new member of the genus Neofungella from southern
California is of interest in view of the scattered distributions of the
fossil genera.

Neofungella californica, new species
Figures 1 to 3

Holotype: Deposited at the Allan Hancock Foundation, Univer-
sity of Southern California, Los Angeles; AHF number 662, col-
lected 26 March, 1966, from Bird Rock, Santa Catalina Island, Los
Angeles County, California, at a depth of 30 meters by Mr. Ronald
McPeak.

Paratype: Abundant material deposited at the Allan Hancock
Foundation, the United States National Museum, and the British
Museum (Natural History).

Description: The colonies are pure white, biscuit-shaped or mush-
room-shaped, and measure from one to 2 centimeters in diameter.
Figure 1 shows a capitate colony rising from a constricted base,
though most of the specimens are somewhat smaller, more nearly
hemispherical, and directly encrust the substrate. The colonies, when
examined in thin section, are clearly multilaminar, each successive
layer spreading wider than the preceding one.

The gymnocyst of the autozoecia is irregularly hexagonal, 0.10 to
0.12 mm in diameter, and may bear pronounced apertural processes,
especially in the younger regions of the zoarium (Fig. 2). Kenozoe-
cia, which are slightly less abundant than the autozoecia, are scat-
tered irregularly over the surface of the colony; m thin longitudinal

35

36 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Figures 1 to 3. Neofungella californica, new species. Fig. 1, zoarium. Fig. 2, aper-
tures, showing decoration of the gymnocyst. Fig. 3, oecium of the holotype speci-
men. The area around the oeciostome has been shaded to show the sculpturing of
the cancelli and oeciostome; the area to the right of the shaded region shows the
outlines of the cancelli; the punctations of the oecium are shown on the right and
left; the remainder of the cecium is shown in outline.

New Southern California Bryozoan 37

(vertical) section, the kenozoecia can be seen to represent the proxi-
mal ends of developing autozoecia (see Borg, 1933:266). The gym-
nocyst is granular, even in the youngest zoecia, and may be devel-
oped into tiny spinules which project into the aperture (Fig. 2).

The remarkable oecium branches dichotomously, ramifying be-
tween the zoecia. As in Neofungella claviformis, the exposed surface
is covered with a delicate framework of cancelli closely adherent to
the minutely punctate oecium (Fig. 3).

The oeciostome is thin, delicate, widely flarmg, and measures 0.17
mm. wide by 0.155 mm long; it is delicately striated longitudinally
and radially (Fig. 3).

Remarks: Neofungella californica agrees well with the generic
description given by Borg (1933:259). Though it is primarily en-
crusting and convex, it occasionally becomes capitate. The auto-
zoecia are at least as abundant as the kenozoecia, and open on both
the peduncle and capitum. The structure of the oecium agrees closely
with the description given by Borg (1933:267-271). It differs, how-
ever from the only previously-described member of the genus, Neo-
fungella claviformis (Waters) in the following three characters: (1)
the oecium branches dichotomously in J. californica, but not in N.
claviformis; (2) the oeciostome is erect, flared, and prominent in JV.
californica, but shorter in N. claviformis (see Borg, 1933, plate I,
fig. 2); (3) the diameter of the apertures of NV. californicus is only
half that of NV. claviformis, (0.19 mm to 0.22 mm). The above com-
parisons were drawn from specimens of NV. claviformis from the col-
lections of the New Zealand Oceanographic Institute (Wellington),
Endeavour station number A527 (Ross Sea, Antarctic, 500 fath-
oms). The collections were placed at my disposal through the kind-
ness of Mr. John S. Bullivant of the Allan Hancock Foundation.

ACKNOWLEDGMENTS

I am grateful to Mr. John S. Bullivant for the loan of valuable
specimens, Mr. Ronald H. McPeak for the location and collection of
the type material, and to Mr. Kristian Fauchald for his critical read-
ing of the manuscript. Contribution no. 291 of the Allan Hancock
Foundation.

LITERATURE CITED

BLAINVILLE, H. M. D.
1830. Zoophytes. Dictionnaire des sciences naturelles. 60. Paris and Strasbourg.

38 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

BORG, FOLKE
1933. A revision of the recent Heteroporidae. Zoologiska Bidrag fran Uppsala,
15:253-349)

HAGENOW, FE VON

1851. Die Bryozoen der Maastrichter Kreidebildung. Cassel.

D’ORBIGNY, A.

1852. Paléontologie frangaise. Terrains crétacés, 5. Bryozoaires. Paris.
WATERS, ARTHUR WILLIAM

1904. Bryozoa. In Résultats du Voyage du S. Y. Belgica, Zoologie, pp. 1-113.

AN ENDOCRANIAL CAST OF THE MIOCENE DOG,
TOMARCTUS, FROM THE FOSSIL BEDS
OF BARSTOW, CALIFORNIA

GeorGE E. JAKWAY AND JERRY T. CLEMENT

Department of Zoology
California State College at Los Angeles
5151 State College Drive
Los Angeles, California 90032

An endocranial cast of Tomarctus (CSCLA 207) was recovered
from the Barstow Fossil Beds of the Mojave Desert of California. This
cast shows the shape and extent of the cranial cavity characteristic
of canids. The volume of the brain of an animal is not disclosed
by its endocranial cast (Edinger, 1948), but the cranial bones lie in
such close proximity to the neural tissue that impressions of the gyri
and sulci can be studied, and evidence of the superficial cerebral
vascularization can be seen. Fragments of the tympanic bullae are
the only osseous remains. During identification of the cast, plaster
endocranial casts of Recent mongrel dogs were made for comparative

study.

Locality: The specimen was obtained from the Northwest corner of
the Southwest quarter of Section 14, T. 11 N, R. 2 W of San Bernar-
dino County, California. Elevation was approximately 3800 feet.
The cast was lying in unconsolidated sediment one-third the way
down a rocky ridge. Therefore the fossil may have been redeposited
from a higher topographic level. However, the locality is within the
upper part of the type Barstow formation (Richard H. Tedford, pers.
comm. )

The fauna from these deposits is of late Miocene age, characterized
from the Barstow area by such mammalian forms as Aelurodon,
Tomarctus, Canis, a machaerodont, Lepus, Merychippus, Procame-
lus, Dromomeryx, and Merycodus (Merriam, 1919).

Description: The descriptions and diagrams of Adrianovy and Mer-
ing (1959) facilitated the description of the cast. The cast (Fig. 1)
measures 63.6 mm. from the anterior tip of the olfactory lobe to the
posterior extremity of the vermis. It is 50.5 mm. wide at its widest
point, the temporal lobes. Height is greatest at the temporal lobes, 37
mm. There is extensive cerebellar exposure dorsally, measuring 13.6
mim. from the posterior terminus of the longitudinal fissure to the

39

40 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Figure 1. Dorsal view of an endocranial cast of Tomarctus.

posterior extremity of the vermis. The cerebrum does not extend
over the cerebellum, indicating a more primitive condition than
comparable Recent forms. The medulla oblongata is oval in cross-
section and flattened dorso-ventrally. The cerebellum is not as broad

Miocene Dog 41

or as high as the cerebrum. The right cerebellar hemisphere and
vermis are better molded than the left, and foldings are apparent on
these parts. The caudad facies are at a 90° angle to the horizontal,
and the dorsal surface of the vermis is at 20° angle from the hori-
zontal. There is no open space between the cerebrum and cerebellum,
except that space occupied by the tentorium. The tuber and declive
form a prominent medial mass, with a greater height than width.
The paramedian lobes of the hemispheres possess a large protuber-
ance.

The cerebral hemispheres are slightly flattened dorso-ventrally, as
compared to Recent canids. They are narrower anteriorly, being
widest at the temporal region, at the posterior curve of the suprasyl-
vian sulcus. The frontal lobes are broadened at an outward swelling
of the coronal gyri. The sulci of the cerebrum are long, curved, and
unbranched. Most prominent dorsally are the long unbroken lateral
sulci, merging anteriorly with the elliptical coronal sulci. The ecto-
lateral sulci extend forward about half the length of the lateral sulci,
and suprasylvian sulci curve out of a lateral half circle to run paral-
lel to the lateral sulci where the ectolateral terminate, and extend
forward to follow parallel to the coronal sulci, the anterior section
ending in an upward curve. The ectosylvian sulci curve in a tight
semicircle about the sylvian fissure. Anteriorly the cast is marked by
two depressions in the prefrontal area that appear to be invagina-
tions that occurred during formation. An endolateral sulcus is faintly
visible on the right side.

Ventraily, the olfactory lobes are unpreserved beyond the basal
portion. The ventral aspect is not preserved beyond the anterior
extent of the prefrontal lobes. The ventral raphe, optic nerves, hy-
pophysis, interpeduncular fossa, cerebral peduncles, pons varolii, and
pyramids are represented. Bone fragments of the tympanic bullae
are imbedded lateral to the brain stem.

Some evidence of vascularization is preserved. Laterally the
arteria cerebri media branch across the lateral, ectolateral, suprasyl-
vian, and ectosylvian sulci. Dorsally, the venus cerebri superior
media is found near the sagittal line, with branches spreading across
the brain to the lateral gyri.

Identification: The cast was compared with several casts of mam-
malian brains and diagrams and descriptions of carnivore endo-
cranial casts (Piveteau, 1961) to determine which family the cast
represented. Notable features considered were its long lateral and

42 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

half-circle suprasylvian sulci, and the extensive cerebellar exposure.
Plaster casts representing several canids were compared with the
cast from Barstow. Measurements of these casts are shown in Table
1. Casts of Canis andersoni, Urocyon californicus, Canis dirus, and

SPA ee
Brain cast measurements of Canids
(All measurements in millimeters) .

Greatest Greatest Greatest Cerebral
Length Height Width Cortical Length
Urocyon californicus 5915 32 40.5 53
Canis dirus 101 66.5 70 94.
Canis latrans 84 4.7 58 79
Canis andersoni 79 44. 53 72

Canis latrans in the Los Angeles County Museum of Natural History
collection from Rancho La Brea tar pits were used. The brain cast of
the fox, Urocyon californicus (UC 12263), was relatively small
and elongate, and possessed the same carnivore fissures as the Bar-
stow specimen, but much less prominent. The coyote, Canis latrans
orcutti (LACM 3200-7), resembles the fossil in the pattern of gyri
and sulci, although the size was 11% times greater. The Canis dirus
(LACM 2300-83) cast lacked the characteristic lateral fissures dor-
sally, and appeared proportionately greater dorso-ventrally. The
fissures of the cast of Canis andersoni (no number) were compara-
ble, although less cerebellar area was exposed beneath the cerebral
hemispheres. The endocranial cast shows closer morphological
affinity to Canis than to Urocyon.

Three canid genera are described from the Miocene Barstow fossil
beds; Aelurodon, Tomarctus, and Canis (Merriam, 1919). The speci-
men was comparable to the cranial cavity of a partial skull of Zo-
marctus (UCR 10480) from the Barstow fossil beds (UCR Loc.
V5201). The partial skull of Zomarctus includes portions of the left
maxilla bearing the roots of P, P; and fragmented P,-M., zygomatic
arch, frontal, parietal, and occipital bones. The frontal, parietal, and
occipital fragments have been mended to form the medial section of
the cranial roof. The left half of the superior nuchal crest is present,
the sagittal crest extends forward along the parietals, and anteriorly
part of the frontals and superior orbital protuberance are present.
Laterally, the cranial roof extends to the coronal and suprasylvian

Miocene Dog 43

gyri of the brain cast when superimposed upon it. Clay impressions
were taken from the interior of the cranium, and the fissures were
found to be similar in pattern and size to the cast, and the cast closely
approximates the cranial cavity of the partial skull. Because both
the cast and partial skull were obtained from localities within the
area of the type section of the Barstow formation, coveal age is a
possibility. Identification of species is not possible for the partial
skull because of the fragmentary condition of the teeth.

Tomarctus, as reported by Merriam (1938b), is a genus that is
intermediate between Aelurodon and Canis. This form is of middle
and late Miocene age from western North America. The generic
description is from a skull and dentition from the Middle Miocene of
Oregon.

Comparison with Recent canids: Plaster endocranial casts of seven
mongrel dogs were made for comparison to correlate brain size
(length, width, and height relationships) to skull shape and body
size. The dogs varied from about 10 lbs. to 70 Ibs. in weight.

The skulls of these were compared in thickness and texture. The
smaller skulls exhibited thin smooth bone tissue, with the sutures
closed but unfused. The shape of the head was brachycephalic, with
a globe-like cranium and short face. The maxillae were reduced and
the nasal bridge curved inward. The brain filled the entire cranium,
resulting in a reduction of the olfactory lobe and nasal sinuses. In
comparison, the skulls of the larger dogs were thick and rough, with
a tendency to develop crests on the parietal and occipital regions. A
sagittal crest was prominent. The brain cavity was restricted to a
region at the posterior of the skull. Although the small dogs possessed
globular skulls and the large dogs possessed elongated skulls, the
cranial cavity, as determined by casting, varied only slightly m size
and proportion (see Table 2).

The skulls of the dogs vary in size as all the bones were enlarged
in the larger dogs, but the proportions were not the same. ‘Table 3
shows the greatest variability in the nasals and maxillae, which gave
the larger dogs longer muzzles. Cranial breadth varied little.

The plaster casts had substantially narrower ranges of variation.
Skull measurements of dogs vary greatly in size and proportion;
brain cast measurements are less variable and fail to give an accurate
indication of skull size and shape. Although brachycephalic dogs
exhibit a marked tendency to have a disnmopoThonaely high skull,
there was no trend in this direction in regard to brain shape.

AA Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967
TABLE 2.

Brain cast measurements of mongrel dogs and Jomarctus
(All measurements in millimeters).

Greatest Greatest Greatest Cerebral
Length Height Width Cortical Length
il 63 44 54 54:
9. 64: 45 52 54
So 63 44: 50 50
4. 63 42 50 51
5. 55 38 48 47
6. 61 43 51 54:
le 58 40 50 49
Tomarctus 63 37 50 51

Of the domestic dogs studied, all had brains of similar size regard- —
less of their skull and body size so that the smaller dogs had propor-
tionately larger brains than did the larger dogs. Weidenreich (1941 )
reports that the larger the brain in proportion to the skull, the shorter
the face and the thinner the cranial bones. It is as if a limited amount
of bone tissue has been stretched to encase the brain. The large
skulls, having a relatively small brain case, are characterized by
heavy crested bone tissue.

The shape of canid brains seems to have changed little since the
late Miocene, as indicated by comparisons of the fossil cast with
representatives of Recent canids. The cerebellum is slightly more

TABLE 3.
Skull measurements of seven mongrel dogs
(All measurements in millimeters).

il. D, 3. 4:, 5. 6. ie
Greatest Length 173 170 140 137 125 112 111
Occipito-nasal Length 151 146 124: 124 117 99 97
Zygomatic Breadth 95 95 83 82 92 66 68
Postorbital Breadth 36 36 42 34 33 42 34:
Cranial Breadth 58 55 52 59 51 53 51
Cranial Depth 85 66 63 57 58 54. 52
Cranial Height 63 56 56 48 51 t+ 4.4:
Nasal Length 64 56 47 47 45 37 37

rr

Miocene Dog 45

exposed dorsally in Jomarctus, and the entire cast appears com-
pressed dorso-ventrally. These comparisons reveal an increased
development of the cerebral cortex, both in height and posterior
extent since the Miocene.

ACKNOWLEDGMENTS

The authors express their appreciation to Dr. Richard H. Tedford of
the University of California at Riverside (UCR) and Dr. J. R. Mac-
donald of the Los Angeles County Museum of Natural History
(LACM) for the loan of specimens from those collections. Drs.
Velma J. Vance and Louis W. Stearns critically read the manuscript.

LITERATURE CITED

ADRIANOY, O. S., and T. A. MERING
1959. Atlas of the Canine Brain. Trans. by E. Ignatieff, Brain Institute Academy
of Medical Sciences, Moscow, USSR, 349 p.

EDINGER, T.
1948. Evolution of the horse brain. Geol. Soc. Amer. Memoir, 25: 1-174.

MERRIAM, J. C.
1913. Notes on the canid genus Tephrocyon. Univ. Calif. Publ., Geol. Sci., 7: 359-
BID

1919. Tertiary mammalian faunas of the Mojave Desert. Univ. Calif. Publ., Geol.
Sci., 11: 437-585.

PIVETEAU, JEAN
1961. Traite de Paleontologie, Tome VI. Volume I. Paris, pp. 806-818.

WEIDENREICH, FE

1941. The brain and its role in the phylogenetic transformation of the human
skull. Trans. Amer. Phil. Soc., 31: 321-442.

NOTES ON PARACIMBOCERA ROBUSTA VANDYKE
(COLEOPTERA: CURCULIONIDAE)*

ELBert L. SLEEPER AND SANDRA L. JENKINS

Department of Biology
California State College at Long Beach
Long Beach, California 90804

Cimbocera robusta VanDyke was described (1935:2) from seven
specimens as follows: California, San Diego Co., Mason Valley,
April 1, 1928, holotype (CAS, Ent. 3918) ¢, allotype, and 2 92 9
paratypes, and California, San Diego Co., San Fillipe (sic!) Valley,
March 27, 1934, 3 9 9? paratypes. Ting (1940:140) placed this
species in the genus Paracimbocera Van Dyke. Since that time it
seems no other specimens were collected. Repeated trips to the type
locality by the senior author were unsuccessful in locating more ~
specimens.

During progress of the research conducted by Staff and students of
California State College at Long Beach in Joshua Tree National
Monument (JINM) many interesting entomological specimens
have been collected. On March 2, 1963, a rather large member of the
genus Paracimbocera was taken. In April 1963, more specimens
were taken. Positive identification was made by comparing these
specimens with the holotype of Cimbocera robusta.

On March 2, 1963, a single specimen was taken by beating miscel-
laneous vegetation in the Northwest Fork, Long Canyon, JTNM,
San Bernardino Co., California. Again on April 7 to 8, 1963, two
more examples were taken in a similar manner. On April 8, 1963, a
single example was encountered in a pitfall trap m Cholla Fork,
Long Canyon, JI'NM, Riverside Co. The trap was located at the edge
of a sandy wash beneath an overhanging cliff. A specific plant host
could not be determined because of the method of collection. Both of
the areas are in the Pinyon-Juniper Plant Community of Munz &
Keck (1959). The dominant vegetation is Pinus monophylla Torr.
& Frem., Yucca schidigera Rozel Ortgies, Quercus turbinella Greene,
Arctostaphylos canescens Eastw., Acacia greggi Gray, Franseria
dumosa Gray, Hymenoclea salsola T: & G., Larrea divaricata Coy.,
Juniperus californica Carr., Prosopis juliflora (Sw) DC., Nolina

'The research in Pleasant Valley, Joshua Tree National Monument, was sup-
ported, in part, by Grant I.G. 212.57, Long Beach California State College
Foundation.

40

On Paracimbocera robusta 47

parryi Wats., Opuntia basilaris Engelm. & Bigel., and Ephedra
nevadensis S. Wats.

Shortly after the authors initiated studies in the Pleasant Valley
area of JITNM this species was again encountered in traps of various
types. A total of 30 specimens has been collected in JTNM since the
aforementioned records. ‘Twenty-three were taken from an area 0.7
miles NW of the Quail Guzzler, JIINM, on seven different occasions.
They were collected in traps of two sorts, a pitfall trap and a buried
bait trap. Examples were also collected by beating miscellaneous
vegetation and by individually taking them from the.roots and tips
of Ephedra nevadensis.

The following table lists the dates, number of individuals, and
methods of collecting.

Date No. of Method of Collection
Individuals
IV-30-65 1 Pitfall trap
1 Buried bait trap
V-30-65 1 Buried bait trap
VI-29-65 2 Sweeping miscellaneous vegetation
II1-26-66 1 Sweeping Ephedra nevadensis
IV- 7-66 12 Sweeping E. nevadensis
V-13-66 2 Sweeping E. nevadensis
2 Buried bait traps
IV-29-66 1 Sweeping E. nevadensis

The remaining seven individuals of Paracimbocera robusta were
collected at two other localities in JINM. On April 6, 1966, an
example was taken from Ephedra nevadensis at Pinyon Wells Can-
yon area (0.3 mi. above Pinyon Wells). There are also two records of
P. robusta in the Fried Liver Wash area. On March 11, 1966, five
examples were taken from the roots and tips of EZ. nevadensis and
on April 8, 1966, another was taken from E. nevadensis.

The three areas are considered to be in different plant communi-
ties according to Munz and Keck (1959): Quail Guzzler of the
Joshua Tree Woodland Community, Pmyon Wells a transition be-
tween Joshua Tree Woodland and Pinyon-Juniper Community and
Fried Liver Wash of the Creosote Scrub Community. Miller and
Stebbins (1964) have divided JINM into three plant belts: the
Creosote, Yucca and Pinyon Plant Belts. Considering their classifi-
cation, these areas fall into the Yucca Belt.

48 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

However, it is interesting to note that there are certain dominant
plants common to all three areas. These are Yucca brevifolia Engelm.
& Wats., Larrea divaricata, Hymenoclea salsola, Ephedra nevaden-
sis, Yucca schidigera, Opuntia echinocarpa Engelm. & Bigel.,
Opuntia basilaris, and Salazaria mexicanus Torr. Of these, E.
nevadensis is the only plant host with which P robusta was definitely
found to be associated. Also whenever P robusta was collected from
traps, E. nevadensis was always in close proximity to the trap
localities. Numerous examples taken from Ephedra nevadensis were
feeding at the time of collecting. This represents the first host record
for this species and only the second record of a host plant for the
genus. Paracimbocera artemesiae ‘ling has been recorded from
Artemesia sp.

LITERATURE CITED

MILLER, A. H. and R. C. STEBBINS
1964. The lives of desert animals in Joshua Tree National Monument. Univ. Calif.
Press, 452 p., illus.

MUNZ, P A. and DAVID D. KECK
1959. A California flora. Berkeley and Los Angeles: Univ. Calif. Press, 1681 p.

TING, P. C.

1940. Revisional notes concerned with Cimbocera and related genera (Coleoptera:
Curculionidae). Bull. So. Calif. Acad. Sci., 39:128-157, illus.

VAN DYKE, E. CG.

1935. New species of North American weevils in the family Curculionidae, sub-
family Brachyrhininae, II. Pan-Pac. Ent., 11:1-10.

THE PUPA OF RHAPHIOMIDAS TERMINATUS CAZIER
(DIPTERA: APIOCERIDAE)

CHARLES L. HoGue

Los Angeles County Museum of Natural History
Los Angeles, California 90007

The immature stages and biologies of only two species of Apio-
ceridae are known at present. Both of these belong in the genus
Apiocera and are only partially complete. For the seacoast-inhabit-
ing Australian A. maritima, English (1947) describes and figures
the egg, larva and pupa and Cazier (1963) provides photographs and
descriptions of the egg and first instar larva of A. painteri. In view of
the great paucity of knowledge for this family of flies, I deem it ap-
propriate to make known the discovery of the pupa of a species of
Rhaphiomidas, a genus for which there is no previous published in-
formation regarding immatures.

The specimens upon which the following notes, figures and de-
scription are based were given to me, and deposited in the entomo-
logical collection of the Los Angeles County Museum of Natural
History (CLH 154), by Mr. Carl Hall who collected them in his back
yard at 664 35th Street, Manhattan Beach, California. Mr. Hall
noticed the adult fly, a male, emerging from the pupa which lay on
flat, sandy ground near an open cage provided for a pet desert tor-
toise. The terrain is flat at the location and borders the landward
edge of a sand dune separating the property from the ocean, which
is approximately three-fifths of a mile to the west. Mr. Hall relates
as never before having seen another pupa, larva or adult which
could have been an apiocerid in his yard and, therefore, could give
no Clues regarding the species’ breeding habits. The time of the fly’s
emergence and collection was mid-August, 1965.

DEsCRIPTION OF THE PUPAL EXUVIAE

The salient characters are shown well in Figures 1 to 3. The fol-
lowing features are worthy of descriptive note:

Size (abdomen slightly curved caudad producing a small error in
measurement of length): length 30 mm.; breadth at abdominal
segment three, 7 mm.

Integument well sclerotized, texture rugose, color medium brown.

Head armed with four pairs of prominent, heavily sclerotized
stout spines: the three anterior pairs fused onto a common protuber-

49

Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

5O

l . Lateral view.

rminatus

idas ter

1om

Figure 1, Pupal exuviae of Rhaph

Pupa of Raphiomidas terminatus 51

Figure 2. Cephalic and thoracic portions of pupal exuviae of Rhaphiomidas
terminatus. Frontal view, positions of leg and mouthpart sheaths reconstructed.

Figure 3, Terminal abdominal segment of pupal exuviae of Rhaphiomidas ter-
minatus. Frontal view.

52 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

ance situated diagonally on the front of the face between the eyes;
the fourth pair single and situated on the vertex between the eyes
and directed cephalodorsad. Mouthparts sheaths very long (corre-
sponding to elongate proboscis of adult), nearly extending to the tips
of the anterior leg sheaths.

Thorax with prominent caudally directed spine at base of wing
sheath. Arrangement, shapes and sizes of leg sheaths as figured (Fig.
1 shows these structures in their actual positions after disarrange-
ment by the emerging adult; in Fig. 2 an attempt has been made to
reconstruct this part of the pupal anatomy, returning the disrupted
elements to their normal status). Tips of leg sheaths extending be-
tween and separating tips of wing sheaths.

Abdomen with eight apparent segments. Each segment except the
first and last with prominent rectangular lateral lobe bearing a
bilobed spiracle near the center; the anterior-most spiracle displaced
cephalad. Segments as above each ringed caudally with a single
straight row of subequal, short, sharply pointed, bristle-like spines;
the spines of segment 1 absent dorso-laterad and larger than those
described above dorsad and laterad.

Terminal abdominal segment apically armed with a quadrant of
caudally directed spines; a pair of small tubercles mid-ventrad;
bristle-like spines and spiracles absent.

ACKNOWLEDGMENTS

The figures were rendered by Mrs. Evie Templeton, Exhibitions
Division, Los Angeles County Museum of Natural History. I wish
also to acknowledge the assistance of Dr. Mont Cazier, Arizona State
University, for confirming my identification of the specimen.

NorEs ON A SECOND RHAPHIOMIDAS PUPA

Upon learning of the discovery of the R. terminatus pupa, Dr.
Cazier sent me a pupal case of a second Rhaphiomidas species, which
he and an assistant (J. M. Davidson) found 2 mi. south of Cronise
Dry Lake, San Bernardino Co., California, 3 May 1966. The head
case is entirely missing but the remaining structures indicate a
species very Closely allied to terminatus, possibly acton Coquillett
or maehleri Cazier judging from the locality. According to Cazier,
“The pupal case was partially covered with sand in an area of mostly
sand and mesquite:’ The specimen is preserved in his collection at
Tempe.

Pupa of Raphiomidas terminatus 53

LITERATURE CITED
CAZIER, M. A.
1963. The description and bionomics of a new species of Apiocera, with notes on
other species (Diptera: Apioceridae). Wasmann J. Biol., 21: 205-234.
ENGLISH, K. M. I.

1947. Notes on the morphology and biology of Apiocera maritima Hardy
(Diptera: Apioceridae). Proc. Linn. Soc. New South Wales, 71: 296-302.

ELASIPOD HOLOTHURIANS OF ANTARCTICA
I. GENUS AMPERIMA PAWSON 1965

Canpipo P AGATEP

Allan Hancock Foundation
University of Southern California
Los Angeles, California 90007

INTRODUCTION

The USNS Eltanin, laboratory ship of the United States Antarctic
Research Program of the National Science Foundation, began in-
tensive investigation of Antarctic waters in 1962. Leaving from
Valparaiso, Chile, July 5, the ship carried out considerable sampling
between 20° and 130° W. longitude, representing ten cruises (4 to
13) of which six are presented here. The six cruises covered an area
bounded by 35° W. longitude and 120° W. longitude with all the 15.
stations at 55° S. latitude (Fig. 1). These six cruises comprise 623
stations, 15 of which revealed species not only of the genus Ammpe-
rima but of several other genera of benthic elasipod holothurians.
Specimens were taken by a five- or ten-foot Blake Trawl fitted with
a net with a mesh opening of 1% inch (1.25 cm.) or by a rock dredge.

Species of the genus Amperima (=Periamma Perrier, 1896) have
been recorded from waters of the Indo-Pacific Oceans. A new species
of the genus, Amperima tui Pawson (1965a), was collected recently
North of New Zealand and another species Amperima naresi
(Theel) was reported from the Sunda Trench (Hansen, 1956).

Most species of Amperima live in depths of over 3000 meters
(Madsen, 1953). The deepest, however, was collected at about 7160
meters in the Sunda Trench by the Galathea Expedition (Hansen,
1956) and the new species described by Pawson (1965b) was taken
at about 1120 meters. Eltanin specimens were procured from depths
between about 131 and 4450 meters.

MATERIALS AND METHODS

A total of 163 specimens representing three species of the genus,
one new to science, are here discussed. These specimens were col-
lected south of the Antarctic Convergence in South Pacific Ocean.

Calcareous spicules were studied in slide preparations of portions
of skin taken from different parts of the body; i.e., the dorsal and
ventral sides, the tentacles and tubefeet. These portions of skin were
placed in 100% ethyl alcohol for about five minutes and then trans-

54

55

Antarctic holothurians

‘pa}do]]09 a1eM suLTINYO[OY prpodiseye stats SuoTze}S Sutmoys deyy “7 947

406
1SOM

9g

UL

56 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

ferred to toluene until cleared. Permount was used for permanent
mounts.

The abbreviations AHF, USC and USNS stand for Allan Hancock
Foundation, University of Southern California and United States
Naval Ship.

Class HOLOTHUROIDEA
Order ELASIPODIDA
Family Elpididae Theel 1882

Amperima Pawson 1965 = Periamma Perrier, 1896 (see Pawson,
1965 for reasons) ; Scotoplanes Theel, 1882 (in part) and Penta-
gone Theel, 1882 (in part).

Diagnosis: Body oval to elongated. Tentacles ten, surrounding
mouth, Anterior part of dorsal surface provided with a transverse
row of papillae united at their bases and followed, oftentimes, by a
few rudimentary processes. Ventral surface, on each side, carries a
number of tubefeet distributed either along entire sides or restricted
to only posterior half of body. Calcareous deposits include C-shaped
bodies, three-armed spicules, and straight and curved rods.

Type species: Amperima roseum (Perrier, 1896).

Remarks: The genus Amperima is cosmopolitan. It consists of seven
species, five of which are known from the Indo-Pacific Oceans.

Amperima robustum (Theel) 1882

Scotoplanes robustum Theel, 1882, p. 35-36; pl. VI, figs. 1-3; pl.
XXXIV, figs. 6 and 7.

Material examined:

AHF, USC Eltanin station 393; Atlantic Ocean Drake Passage and
Scotia Sea; Lat. 57°57’4”—58°43'1” S., Long. 55°57’8” 55°47
9” W.; December 28, 1962; depth 4008 meters; 1 specimen.

AHP, USC Eltanin station 413; North East of Drake Passage; Lat.
627077 62 0797'S.) ong) 555778) — 55 247. NV al anavrcigyapl,
1963; depth 1,153 meters; 3 specimens.

AHF, USC Eltanin station 430; Moore Bay, Farlane Strait; Lat.
62°38'4”—62°40'8” S., Long. 59°36’5”—59°2317 W.; January
7, 1963; depth 1,409 meters; 28 specimens.

AHF’, USC Eltanin 474; Ushuaia Harbor, Argentina; Lat. 55°56’
0°90 2477S, Longy 4442757445210 Vet rlebruciaygalios
1963; depth 3,486 meters; 5 specimens.

Antarctic holothurians 57

Description: Body elongate, about twice as long as broad; mouth
ventral; anus dorsal. Tentacles with smooth circular ends. Dorsal
surface slightly convex, ventral surface almost flat. On anterior part
of dorsal surface a transverse lobe with four distinct projections with
central pair slightly larger than other two. Two very small processes
shortly behind the base of lobe. Ventral margins with eleven pairs of
tubefeet restricted to posterior half of body. Tubefeet discrete, de-
creasing in size toward posterior end of body.

Calcareous deposits largely dissolved but (in some animals) traces
of the deposits can still be found consisting of three types: spinous
three-armed bodies, C-shaped spicules, and curved and straight rods.
C-shaped and three-armed bodies in the body wall while rods found
in terminal ends of tentacles and tubefeet.

Calcareous ring similar to that of other species of Amperima.
Skin smooth, thin, and soft. Color in alcohol light brown.

Remarks: Specimens are similar, in both external and internal
aspects, to Theel’s (1882) species.

Distribution: The above species is found in the Indo-Pacific Oceans.

Amperima naresi (Theel)
Figures 2 and 3

Peniagone naresi Theel, 1882, p. 47-49; pl. IX, figs. 1-2; pl.
XXXIII, fig. 15.
Periamma nares Hansen, 1956, p. 38-40; figs. 7 and 9.

Material examined:

AHF, USC Eltanin station 35, North end of Peru-Chile Trench,
Lat. 8°23’0”—8°21’0” S., Long. 81°03’1”—81°04'1” W,; July
8, 1962; depth 4,240 meters; 21 specimens.

AHF, USC Eltanin station 469; Ushuaia Harbor, Argentina;
Lat. 55°01’5”—55°10'5” S., Long. 44:°20'5” —44°23/0” W.; Jan-
uary 12, 1963; depth 3,623 meters; 5 specimens.

AHF, USC Eltanin station 525; Weddell Sea, Antarctic Circle;
Lat. 66°22’6”—66°20'4” S., Long. 45°48’7”—45°51’7” W.; Feb-
ruary 27, 1963; depth 4,204 meters; 7 specimens.

AHF, USC Eltanin station 511; Weddell Sea, Antarctic Circle; Lat.
63°09’7”—63°17'5” S., Long. 45°04’2”—45°01’5” W.; February
24, 1963; depth 2,010 meters; 1 specimen.

AHF, USC Eltanin station 529; Eastern Pacific, Antarctic Basin;

58 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Lat. 63°03’/1”—63°0’ S., Long. 49°10’5”—49°20'0” W.; March
3-4, 1963; depth 2,941 meters; 5 specimens.

AHF, USC Eltanin station 995; Eastern Bransfield Straits, South
West of Elephant Island; Lat. 61°57’—61°52’5” S., Long. 55°
53/0”—55°47'/0” W.; March 14, 1964; depth 2,562 meters; 12
specimens.

Description: Material from station 35: Body very elongate, almost
cylindrical in shape. Largest specimen about 60 mm. long, 25 mm.

broad; smallest about 25 mm. long, 10 mm. broad. Mouth anterior,

subreatiell anus terminal, posterodorsal. ‘Tentacles of about equal
length, terminal discs with small retractile processes, marginal
processes largest. Dorsal surface strongly vaulted, ventral surface
slightly convex, with four papillae (Fig. 2A) about 15 mm. from
anterior end of body. Papillae united at base, in a transverse curved
row. Iwo central papillae, (about 8 mm.) larger than outer papillae
(4 to 6 mm.). Three to four mm. posterior to lateral papillae a pair
of very small processes about 2 mm. long. Midventral radius naked,
lateral radii each with a single row of eight to ten small conical
tubefeet. First anterior pair, in largest specimen, located 15 to 22
mm. from crown of tentacles. Tubefeet present on posterior two
thirds of body with last two pairs at posterior end united at base
while others separated from each other.

Skin very soft, thin, translucent. Color in alcohol usually brown
to light brown, occasionally somewhat greenish.

Integument with numerous, crowded calcareous deposits, com-
prising large and small spinous cross-shaped spicules, spinous three-
armed bodies, curved, straight, and irregularly branched rods, and
small, short C-shaped rods. C-shaped spicules varying in shape and
degree of curvature, thickly scattered in all parts of body. Regular
C-form with enlarged central part and a single process (Fig. 2C)
most abundant. S- and Y-shaped bodies also occasionally present in
body (Figs. 2B, D).

One specimen in station 469 has dorsal surface vaulted with an
extremely large transverse lobe (Fig. 3A) on anterior part of body,
its upper margin missing but might possibly possess four small pro-
jections. Behind base of lobe two small processes. Ventral surface
slightly convex.

Elements in tubefeet and tentacles, except those at their distal
extremities, similar to those found in body but smaller. At tips of
tubefeet and tentacles some straight spinous rods (Figs. 2G, H, L,

Antarctic holothurians 59

Figure 2. Amperima naresi (Theel). A. Side view, X3; B-D. Variations of the
C-shaped deposits from the body wall, X40; E-E Three-armed deposits from the
body wall, X40; G-H, L-M. Rods deposits from the ends of both tentacles and
tubefeet, X-40; I-K. Branched rods deposits from the body wall, X40.

60 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Figure 3. Amperima naresi (Theel). A. Side view, X214; B-C, E. Branched rods
deposits from the body wall, X40; F, H. Cross-shaped deposits from the body
wall, X40; G. Ventral view, X214.

Antarctic holothurians 61

M) present. Three-armed (Figs. 2E, F) and cross-shaped (Figs. 3D,
F, H) bodies, branched and irregularly branched rods (Figs. 2C,
I-K; Figs. 3B, C, E) more scattered; both three-armed and cross-
shaped deposits sometimes with ends of arms branched.

Calcareous ring a delicate network. One single large, oval Polian
vesicle. Intestine forming an elongated loop occupying most of body
cavity. This loop connected to lateral interradi by strong thread-
like muscles. Rectum attached to lateral interradii and to right
ventral interradius of venter.

Longitudinal muscles thick, light green in alcohol. Circular mus-
cles strongly developed. Gonad made up of large, single fascicle
which gives rise to bundles of small, oval close-set caeca. Genital
duct opens to exterior adjacent to stone canal, about 4 mm., poste-
rior to base of tentacles on anterior part of dorsal surface.

Material from stations 469, 511, 525, 529, and 995: Body oval to
globular. Largest specimen about 75 mm. long, 45 mm. broad;
smallest about 25 mm. long, 18 mm. broad. Tentacles provided with
large terminal discs with numerous retractable processes on surfaces
and around margins. Dorsal surface convex; ventral side nearly flat.
Anterior part of dorsal surface with four papillae, their ends appear-
ing only on upper margin of a well developed transverse lobe. ‘Two
to four mm. posterior to second lateral papillae a pair of rudimen-
tary processes. Along each ventrolateral margin a single row of
nine tubefeet (Fig. 3G).

Color in alcohol usually brown to purple, rarely yellowish white.
Calcareous deposits consist mostly of small spimous triradiate bodies,
unbranched and irregularly branched spicules and C-shaped rods.

Remarks: The latter description shows peculiarities of the speci-
mens which make them slightly different from animals in station
35. Size and formation of the dorsal papillae is one of distinct differ-
ences among the described specimens but this is not unusual in this
particular species. The same variation in size and shape of the velum
were observed by Hansen (1956) in the “Galathea” collection.

Distribution: The species is known from both the Indian and Pacific
Oceans.
Amperima velacula, new species

Figures 4, 5, and 6

Holotype: AHF 1966-10, 1 specimen (50 m. long.); USC Eltanin
station 480; South Scotia Ridge; Lat. 58°06’—58°10’ S., Long.
44°55'5”—44°47" W.; February 15, 1963; depth 2,837 meters.

62 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Paratypes: AHF 1966-10, 3(25-50 mm.) ; USC Eltanin station. 913;
Mid-Pacific, Antarctic Basin; Lat. 65°48’—65°39’ S., Long.
115°—114°55’ W;; January 1, 1964; depth 4,773 meters.

AHF 1966-10 25 mm.; USC Eltanin station 411; South West of
Elephant Island, South Shetland Island, Antarctic; Lat. 61°18’
—61'°19’5” S., Long: 56°08%5/—56°1072” W.; January 101963;
depth 131 meters.

Additional material:

AHF 25 mm.; USC Eltanin station 579; South Georgia Island;
Lat. 57°19’—57°29’2” S., Long. 23°08’5”—23°10'2” W.; April
21, 1963; depth 4,538 meters.

AHF 7(18-28 mm.); USC Eltanin 913; Mid-Pacific, Antarctic
Basin; Lat. 65°48’—65°39’ S., Long. 115°—114°55’ W;; Janu-
ary 1, 1964; depth 4,773 meters.

AHF 25 mm.; USC Eltanin station 1,135; South Pacific Ocean;.
Lat. 66°17’—66°19’3” S., Long. 98°28’5”—98°37’5” W.; June
9, 1964; depth 4,630 meters.

AHF 5(18-25 mm.); USC Eltanin station 1146; Bellingshausen
Sea; Lat. 65°56’—65°54’ S., Long. 112°30’—112°56’ W.; June
14, 1964; depth 4,850 meters.

AHF 51 (5-30 mm.); USC Eltanin station 1148; Bellingshausen
Sea; Lat. 65°14’3”—65°25’3” S., Long. 117°295”—117°29" W.;
June 15, 1964; depth 4,850 meters

AHF 6(20-30 mm.); USC Eltanin station 411; South West of
Elephant Island, South Shetland Island, Antarctic; Lat. 61°18’
=—61°19%7 S., Long. 56°08/57—56" 10727 W.; January 1eel963;
depth 131 meters.

Diagnosis: Amperima velacula is characterized by the following
features: deposits of various forms; e.g., cross-shaped bodies, four-
armed spicules, irregularly branched rods, and numerous 0-shaped
spicula. Tubefeet 9 to 10 on each side. Dorsal papillae 6, of which the
distal ends of 4 appear only on upper margin of a well developed
transverse lobe and the other two placed either immediately be-
hind the base or attached to base of ridge.

Description: Body shape from globular to elongated oval. Largest
specimen about 50 mm. long and about 25 mm. broad at widest
part; smallest specimen about 10 mm. long and about 5 mm. in
breadth. Mouth anterior, subventral; anus posterodorsal. Two most
ventral tentacles slightly shorter than rest. Size of discoidal ends

Antarctic holothurians 63

of tentacles varies with size of animals. Tentacles discs with minute
retractable processes on surface and around margins. Dorsal sur-
face convex; ventral surface slightly flat. On anterior section of
dorsal surface a thin transverse ridge bearing on upper margin four
papillae (Fig. 4A); two central papillae slightly larger than other
two. Distance of ridge from anterior end of body varies from about
4 to 10 mm. Posterior to base of ridge a rudimentary pair of proc-
esses. These processes sometimes attached at base of ridge and some-
times slightly behind it. Ridge of papillae measures about 2 to 4mm.
long and about 3 to 6 mm. broad. Midventral radius naked, ventro-
lateral radii each with a single row of 9 to 10 small, conical tubefeet.
Anterior and some posterior tubefeet distinctly separated from each
other while those near and around posterior end closely set and
sometimes joined at base.

Skin thin, soft, and translucent. Of 76 specimens investigated, 58
possess, aside from smal] regular C-shaped elements, numerous mi-
nute 0-shaped bodies (Fig. 4E). These bodies thickly distributed in
all parts of body except at ends of both tentacles and tubefeet. Aver-
age size of these spicules about 0.015 mm. in diameter. Remaining
specimens lack 0-shaped deposits but possess regular C-shaped ele-
ments (Fig. 41), have an average size of about 0.07 mm. In all
specimens occasional S-shaped and Y-shaped bodies (Figs. 4F, G)
also present in both dorsal and ventral sides. Rare, small wheels
(Fig. 4C) with nine to eleven spokes usually present in ventral
skin. In both dorsal and ventral sides, large, spinous triradiate (Figs.
4B, D) spicules thinly scattered, their arms mostly slender and long,
straight and curved. One or two of some three-armed bodies bi-
furcated and usually one arm longer than other. Other deposits,
cross-shaped (Fig. 5C) and three-armed (Fig. 5B), their arms short
and very broad with extremely large spines heavily distributed along
sides. Deposits with irregular spinous arms (Figs. 5A, D) occasion-
ally present in body. Aside from spinous three-armed spicules,
smooth, small ones present in inner part of skin. These smooth
bodies very thinly scattered in integument. Branched, straight, and
curved rods (Figs. 5A, B, E, F) including four-armed (Fig. 5G) ele-
ments present in tentacles. Branched and curved rods with large,
irregularly distributed spine with arms of branched rods scattered
more or less along sides and ends. Tubefeet, deposits similar to those
in tentacles but much longer and more slender curved rods with
smaller spines (Figs. 6C, D, E). Beside these rods few irregular
triradiate (Fig. 6F) spicules found too.

64 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

G

Figure 4. Amperima velacula, new species. A. Side view, X5; B-D. Three-armed
deposits from the body wall, X40; C. Wheel deposit from the ventral skin, X40;
E-H. Variations of the C-shaped deposits from the body wall, X40.

Antarctic holothurians 65

Figure 5. Amperima velacula, new species. A, D. Branched rods deposits from
the body wall, X40; B. Three-armed deposit from the body wall, X40; C. Cross-
shaped deposit from the body wall, X40; E-G. Branched and four-armed deposits
from the ends of the tentacles, X40.

66 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Figure 6. Amperima velacula, new species. A-B. Rods deposits from the ends of
the tentacles, X40; C-E. Rods deposits from the ends of the Tubefeet, X40.

Antarctic holothurians 67

A single, elongated, white transparent Polian vesicle present.
Gonad made up of single, large bundle provided with numerous
small caeca. Genital duct opens adjacent to opening of stone canal
_ between crown of tentacles and base of transverse lobe.

Large intestine with single loop, occupying posterior half of body
cavity and supported by string-lke bands individually attached in
Jateral interradiu. Rectum connected to both left and right sides of
ventral surface by tiny muscles. Longitudinal muscles ye lomach
and well developed, circular muscles weak.

Remarks: Amperima robustum (Theel) resembles A. velacula in
nature of calcareous elements and number of dorsal papillae, but
the species differ distmctly in the followmg respects: A. robustum
has deposits composed of three-armed bodies; straight, curved and
branched rods and regular C-shaped spicules while A. velacula has,
aside from the above types of deposits, cross-shaped and four-armed
spicules and other deposits with four or more irregular arms. In
tubefeet, the former has 22 restricted to only the posterior half of
the body while the latter has 18 to 20 distributed to about two-thirds
from posterior end of body. The dorsal papillae of A. robustum are
distinct and somewhat conical in shape projecting clearly from a
very low ridge while those in A. velacula are vestigial and only
their pomted tips appear on upper margin of a broad lobe. This lobe
appears serrated at the place where the processes project.

Kolga furcata Herouard (1902) is somewhat similar with the
specimens described here in number and shape of dorsal papillae,
but &. furcata differs significantly in that it has 8 to 9 tubefeet along
each of its ventrolateral margins while A. velacula has 9 to 10. In
calcareous deposits, the former has mostly straight, curved and
branched rods and few three-armed bodies. The latter, on the other
hand, has more other types of elements besides the above forms
discussed in the preceding presentation.

The sporadic presence of wheel spicules is not unusual in various
other elasipodid. Ikman (1925) made a study of their nature and
found them to be juvenile in character, hence, no consideration
should be given as to their presence or absence when classifying
such animals.

Distribution: The new species, being found in the Pacific Ocean, 1s
possibly also present in the Indian Ocean. In the study of the generic
content of the Tertiary and Recent echmoderm fauna of New Zea-
land and Australia, Fell (1953) found that Australia and New

68 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

Zealand have many characteristics at the generic level in common
with those elements found from the regions of Northern Indian and
Pacific Oceans.
Origin of name: from the Latin words, vela=vail and cula=little.
Velacula=little vail.
ACKNOWLEDGMENTS

For access to the specimens I am grateful to Dr. Jay M. Savage and
Dr. John L. Mohr, University of Southern California. I am also
thankful to Dr. David L. Pawson, Division of Echinoderms, Smith-
sonian Institution, United States National Museum and Dr. Russell
Zimmer, University of Southern California, for their helpful advice;
to Mrs. Melba C. Caldwell for reviewing the manuscript, and to
Mrs. Aurora O. Agatep for the drawings. I would like to thank
the Department of Biological Sciences and the Allan Hancock Foun-
dation, University of Southern California, for the use of the labora-
tory equipment. This work was supported by the National Science
Foundation (G-19497).

LITERATURE CITED

FELL, H. B.

1953. The origin and migrations of Australian echinoderm faunas since the
Mesozoic. Trans. Royal Soc. New Zealand Zool., 81 (2) :245-255.

HANSEN, B.

1956. Holothurioidea from depths exceeding 6000 meters. Galathea Report
2:33-53.

HEROUARD, E.

1902. Holothuries. Resultats des Compagnes Scientifiques, 18-21:1-55, pls. 1-8.

IKMAN, E.

1925. Holothurian. Further Zoological Results of The Swedish Antarctic Expedi-
tion 1901-1903, 1:1-192.

MADSEN, EF J.

1953. Holothurioidea. Swedish Deep-sea Expedition. 2:152-173.

PAWSON, D. L.

1965a. The Bathyal Holothurians of the New Zealand Region. Victoria Univ. of
Wellington, Zool. Publ. No. 36, 36 pp., pls. I-VI.

1965b. Some Echinozoans from North of New Zealand. Trans. Royal Soc. New
Zealand Zool., 5:215-224, figs. 1 & 2.

THEEL, H.

1882. Holothurioidea. Report on the Scientific Results of the Exploring Voyage
of H. M. S. Challenger 1873-76. Zoology 4 (Pt. 2):1-176.

2

UNDERWATER SOUNDS ASSOCIATED WITH AGGRESSIVE
BEHAVIOR IN DEFENSE OF TERRITORY BY
THE PINFISH, LAGODON RHOMBOIDES

Davip K. CALDWELL

Los Angeles County Museum of Natural History
Los Angeles, California 90007
and
ME .Ba C, CALDWELL

Allan Hancock Foundation
University of Southern California
_Los Angeles, California 90007

The pinfish, Lagodon rhomboides (Linnaeus), a member of the fam-
ily Sparidae, is probably one of the most common nonpelagic fishes
along the mainland shores of the southeastern United States in vege-
tated, inshore, open marine habitats (Caldwell, 1957: 79). As fur-
ther discussed by Caldwell (p. 147 f.), some, but not all, of this species
are often highly territorial and frequently display considerable en-
ergy in the defense of their territory. The defense, usually by the
larger fish of a group, consists of a vigorous chasing of the intruder
by the defender, and special vigor is directed toward other pinfish
that invade the territory. Rarely, if ever, are other fishes, or inverte-
brates, attacked. The territory seems usually to consist of a patch of
bottom vegetation, an area around a rock of other piece of detritus,
or even a patch of clear bottom. While the water immediately over
the territory is defended for some distance, a section of open water in
itself apparently is not defended as a territory. This territorial de-
fense, seen both in captive and wild animals, is often most obvious to
the casual observer from the surface on sunny days when the swiftly-
moving fish (either those chasing or the ones being chased) turn on
their sides in their. maneuvers so that the light reflects off their sil-
very sides.

Underwater sound production is being investigated extensively
today and a concerted attempt is being made to catalog and identify
sounds of biological origin. As the following sounds made by the pin-
fish may contribute heavily to the total sound produced im certain
areas, they are discussed and figured, and the concurrent behavior
described.

On June 21, 1965, while recording various captive marine verte-
brates at Florida’s Gulfarium, Fort Walton Beach, we noticed consid-
erable activity in a tank of several hundred gallons capacity con-

69

70 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

taining approximately 50 locally-caught pinfish ranging in size from
about 4 to 7 inches (about 10 to 18 cm.) in total length. In defense of
territories consisting of small rocks on the bottom of the tank, several
of the larger fishes were actively chasing other pinfish of different
sizes which invaded or strayed into their realms. At 8 p.m., with the
tank brightly lighted by overhead artificial lights, we began to record
and found that sharp “clicking” sounds were being made in the tank
which could positively be correlated with the pinfish chases. These
sounds were of three general types, all very similar to our ears and
on spectrographic analysis (Figs. 1 to 3). The most common of the

l2

FREQ. (kHz)
oO NM A O

O 0.1: Or
TIME (SEC.)

Figure 1. Rapid-onset, broad-band “clicking” sound produced underwater appar-
ently by the defending pinfish, Lagodon rhomboides, during an aggressive action
in defense of territory. (Effective filter bandwidth 600 cycles).

sounds consisted of one sharp click (Fig. 1), and in a 13-minute re-
cording session 36 of these were clearly heard. The other two types

Pinfish sound production 7A

of sounds (Figs. 2 and 3) consisted of two of these sharp clicks made
close together, with the second click in the pair having its greatest
mitial energy at either a slightly higher or slightly lower frequency
than the first. In the same 13-minute recording session we heard 22
of these double clicks. Never were more than two clicks heard in
rapid sequence.

l2

lO
8

FREQ. (kHz)
Ow AO

O Oa Oi2 y OS
TIME (SEC.)

Figure 2. Double “click” sound made under the same conditions as described for
Figure 1. The second click of the pair has its greatest initial energy at a slightly
higher frequency than the first. (Effective filter bandwidth 600 cycles)

While all of these sounds seemed loud on the recorded tape, it can
be seen from the figures that the bulk of the energy is at a rather low
frequency (about one to 4 kHz), with the greatest initial energy at
about 2 to 3 kHz, but that harmonics extend beyond 12 kHz (actually
to about 20 kHz).

72 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

2

FREQ. (kHz)
On BO

O O17 O02
TIME (SEC.)

Figure 3. Double “‘click’’ sound made under the same conditions as described for
Figure 1. The second click of the pair has its greatest initial energy at a slightly
lower frequency than the first. (Effective filter bandwidth 600 cycles)

Production of the sound almost certainly is accomplished by the
snapping of the well-armed jaws of the territory defender as it chases,
and presumably nips at, the invader. While the action was too fast
for us to be sure if the chasing fish actually nipped at its victim, it
was our impression from the action that such actually was the case.
If so, the strong anterior incisor teeth of the pinfish (Fig. 4; and
Caldwell, 1957: fig. 19), and possibly to some lesser extent the heavy
molariform teeth along the sides of the jaws behind the incisors,
would certainly, when sharply snapped togethe-, be sufficiently hard
to produce the recorded sound. Also, such a sharp-onset sound as that
recorded and illustrated in the sound spectrograms would be expected
from such a sound-producing mechanism as the teeth.

Pinfish sound production 73

Tavolga (1965: 17) associated the pinfish sounds made out of water
and discussed by Burkenroad (1931: 21) in a category which he
termed “stridulatory sounds” Fish (1954: 44), m noting the only
other American sparid sound production that we have seen reported,

Figure 4. Strong anterior incisor teeth of a pinfish, Lagodon rhomboides, approxi-
mately six inches in total length. Upper, anterior view; Lower, left lateral view.

74, Bulletin So. Calif. Academy Sciences / Vol. 66, No. 1, 1967

also recorded “toothy noises” which she called stridulatory, as did
Tavolga in citing her paper. She did not make reference to pinfish,
but studied instead the closely-related northern scup, Stenotomus
chrysops (Linnaeus), and also attributed most of their “toothy”
sound production to their strong anterior incisor teeth.

As previously mentioned, because of their great abundance and
the frequency with which this territorial behavior occurs, pinfish
should be considered as a likely major source of noise in the habitats
which they most often frequent. However, unlike many noise-
makers, which often engage in this activity mostly at night, pinfish
are inactive in the dark and thus engage in their territorial defense
behavior almost exclusively during the day (or under strong artifi-
cial light, as in the case of the captives we studied at night).

RECORDING EQUIPMENT

The sounds reported here were recorded with an Atlantic Research
Corporation model LC-57 hydrophone with a special preamplifier
built for the system by William W. Sutherland of the Lockheed-
California Company, Burbank, and a Uher model 4000 Report-S tape
recorder operating at a tape speed of 7.5 inches (19 cm.) per second.
At this tape speed, the recorder had a flat response of 40 to 20,000
cycles per second. The Sonagrams (sound spectrograms) were pre-
pared on a Kay Sona-Graph model 662A Sound Spectrograph Ana-
lyzer calibrated from 85 to 6000 cps. When the recorded tape speed
is reduced by half, and then fed into the analyzer, the response of
the latter is mcreased to 12,000 cps.

ACKNOWLEDGMENTS
We wish to thank J. B. Siebenaler, General Manager of the Gulf-

arium, for his enthusiastic support of our research by allowing us
free access to the Gulfarium facilities. Financial support which per-
mitted the present study and report came in part from the Museum
Associates of the Los Angeles County Museum of Natural History
and grants from the National Science Foundation (GB-1189) and
the National Institute of Mental Health (MH-07509-01 ).

LITERATURE CITED

BURKENROAD, MARTIN D.
1931. Notes on the sound-producing marine fishes of Louisiana. Copeia, 1931 (1):
20-28.

Pinfish sound production 75

CALDWELL, DAVID Kk.

1957. The biology and systematics of the pinfish, Lagodon rhomboides (Linnaeus).
Bull. Florida State Mus., Biol. Sci., 2(6):77-173.

- FISH, MARIE POLAND

1954. The character and significance of sound production among fishes of the
western North Atlantic. Bull. Bingham Oceanogr. Coll., 14(3):1-109.

TAVOLGA, WILLIAM N.

1965. Review of marine bio-acoustics. State of the art: 1964. U. S. Naval Training
Device Center, Port Washington, New York, Technical Report: NAV-
TRADEVCEN 1212-1, v + 100 p.

Pe

—_

Southern California
Academy of Sciences

OFFICERS OF THE ACADEMY

MEAN ASC Wet ctarey ars, slain ces sa. oe chatera, eteis 6S sfeial oec'd vole bie eels + ota President

MeV Vel lacirIApeIVIOEEIS ©. cccyelcls cs Gicleece os Gee ties we ese ee First Vice President

Wreesares A, Mclanohimn . 2.5.2.0... . ee. e eee eee Second Vice President

EMR PELOZAITC! fe tres. castles sea peicec civ cine ssatescceerss Secretary

MPMETISSERIBEPOESCLGUS occ icla oi <a s Sic is cele se ecie ne shee slee ede seees Treasurer

oo Die AS (CHG I 72) UMS Oe ee eee Editor
DIRECTORS

Philip A. Adams Jules Crane Jay M. Savage

Russell E. Belous Charles A. McLaughlin Elbert L. Sleeper

David K. Caldwell William J. Morris Andrew Starrett

Henry E. Childs Charles E. Rozaire

ADVISORY BOARD

Shelton P Applegate Richard Etheridge John L. Mohr
James R. Dixon Donald Lowrie Donald J. Reish
James WV. Dole J. R. Macdonald David L. Walkington

The following past presidents are automatically members of the Advisory
Board: John A. Comstock, Theodore Downs, Hildegarde Howard, Richard B.
Loomis, W. Dwight Pierce, Kenneth E. Stager, Richard H. Swift, Fred S.
Truxal, Louis C. Wheeler, John A. White, Sherwin E Wood.

STANDING COMMITTEES

Finances Membership

Charles A. McLaughlin, Chairman Russell E. Belous, Chairman
Publications Conservation

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SPECIAL COMMITTEES

Fellows Nominating

Fred S. Truxal, Chairman Andrew Starrett, Chairman
Constitutional Revision Program

William J. Morris, Chairman Philip A. Adams, Chairman
AAAS Award

John L. Mohr, Chairman

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BULLETIN OFLIBRARY

Southern Californiaw + 1357
Academy of SEICN Cee epoch

BOTAN
LOS ANGE BES. CALI FORNIA

Vou. 66 Aprit-June, 1967 Tae a Ngo

CONTENTS

Otoliths and Other Fish Remains from a Long Beach, California,
Pliocene Deposit. John E. Fitch and Roger D. Reimer 77

Notes on the Early Stages of the Barberry Geometrid Moths, Genus
Coryphista, and the Description of a new Subspecies of C.
meadii (Jepidoptera). John Adams Comstock 92

Notes on the Life History of Philotes rita elvirae (Lepidoptera;
Lycaenidae). John Adams Comstock and Christopher Henne .. 99

Description of a New Subgenus of Osmia (Hymenoptera; Mega-
chilidae). Roy R. Snelling 103

Gill Structure in the Caecilian Genus Gymnopis. Marvallee H.

109

Studies of the Blood of Ascidia nigra (Savigny). II. Vanadocyte Ag-
elutination and Its Effect upon the Heart. James A. Vallee, Jr. 117

Recent Records of Water Birds in the Desert. Richard C. Banks ... 125

Late-Pleistocene Deformation in the Lime-Kiln Canyon Area, San-
ta Susana Mountains. James E. Slosson and John T. Barnhart 129

Holothurians of the Genera Elpidia and Kolga from the Canadian
Basin of the Arctic Ocean. Candido P. Agaiep

Some Life History Data on Several Species of Common Spiders
from the Jackson Hole Area of Wyoming. Donald C. Lowrie .. 142

In Memoriam, Dr. W. Dwight Pierce

Issued June 30, 1967

INSTRUCTIONS FOR AUTHORS

Contributions to the BULLETIN may be in any of the fields of science, by any
member of the Academy. Acceptance of papers will be determined by the amount
and character of new information and the form in which it is presented. Articles
must not duplicate, in any substantial way, material that is published elsewhere.
Manuscripts that do not conform to BULLETIN style will be returned to the
author. All manuscripts will be handled through an appointed editorial board
working in cooperation with the Editor. Send all manuscripts to: Dr. Donald J.
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BULLETIN OF THE SOUTHERN CALIFORNIA
ACADEMY OF SCIENCES

_ Vou. 66 ApriL-JUNE, 1967 No. 2

OTOLITHS AND OTHER FISH REMAINS FROM A>
LONG BEACH, CALIFORNIA, PLIOCENE DEPOSIT

Joun E. Fire?

California Department of Fish and Game
Terminal Island, California 90731

and
Rocer D. REIMER

Los Angeles County Museum of Natural History
Los Angeles, California 90007

Historically, southern California has been blessed with rich outcrops
of Pliocene and Pleistocene fossil assemblages, but the ever-increas-
ing press of human encroachment is making rapid inroads toward
the ultimate destruction of this heritage. Almost daily, long-standing
fossil deposits are buried, carried away, or otherwise lost in the proc-
ess of freeway and other road construction, in the development of
vast housing tracts, complex shopping centers and industrial sites,
and because of the cut-and-fill techniques employed to dispose of
much of the refuse discarded by today’s populace. Although all of
these activities go hand-in-hand with an expanding human popula-
tion, and are considered symbolic of progress, most paleontologists
would take exception with using the word “progress” to describe the
systematic destruction of fossil deposits, including many type locali-
ties, and the opportunity to study the past.

One consolation lies in the fact that “new” fossil deposits are ex-
posed by earth-gouging equipment almost as frequently as “old”
deposits are destroyed. Unfortunately, because one measure of prog-
gress in construction is the amount of earth that can be moved during
a given 24-hour period, few of these new deposits are exposed for
more than an hour, a day, or perhaps a week. In addition, only a

1Research Associate, Los Angeles County Museum of Natural History.

77

78 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

small percentage of these are reported to anyone who is interested in
sampling them, or in a position to do so.

During construction of the San Diego Freeway (Interstate 405)
through Long Beach in 1963, Reimer observed a procession of fast-
moving trucks hauling fossiliferous dirt. He traced these vehicles
back to their loading area, and found the source of the fossiliferous
dirt was the bottom of a 37-foot deep pit on the south side of the San
Diego Freeway where it was crossed by Cherry Avenue. At the time
of discovery (July 26), only the south portion of the pit remained
undisturbed, and it was from this exposure that Reimer removed
about a 300-pound field sample on July 26, 27, and 28 after construc-
tion crews had departed each day—the only time he was permitted to
enter the area.

The sample was presented to the Los Angeles County Museum of
Natural History where George P. Kanakoff, Curator of Invertebrate
Paleontology, supervised the washing, screening, and removal of
fossils. The site was designated LACMIP 423, and according to
Kanakoff (pers. commun.), the matrix was composed of shells, dark
gray sand, and silt. The gray color, from the high biotite content, had
been imparted to most of the otoliths and other fossils. The presence
of Tresus paharoanus (Conrad) among the mollusks, as well as other
invertebrate species that never have been known to occur in Pleisto- -
cene deposits, indicated the material was of Pliocene origin—prob-
ably representing the top of the Upper Pliocene.

The fish remains found in this deposit were from 32 species (at
least) belonging to 19 families. Sharks and rays were identified from
29 teeth and 7 caudal “stings;’ while teleost remains comprised 1,230
otoliths and 3 miscellaneous bony fragments (‘Table 1).

SYSTEMATIC ACCOUNT
Isuridae—mako sharks

Carcharodon carcharias (Linnaeus) —white shark

The white shark inhabits temperate and subtropical waters of all
world seas. It is known in the eastern Pacific from fewer than 100
individuals captured between Alaska and Mazatlan, Mexico. A large
specimen for our coast might be 12 to 15 feet long, although white
sharks have been reported (unreliably) to attain 35 feet. This species
probably is responsible for most of California’s unprovoked shark
attacks, usually made in relatively shallow water near shore.
Material: one tooth.

Fossil fish remains

TABLE 1

79

List of Fish Remains Found in a Long Beach, California, Pliocene
Deposit (Freeway Cut near Signal Hill)

Type and number of remains found

Scientific name Common name teeth otoliths other
ELASMOBRANCHS
Carcharhinus spp. requiem sharks 9
Carcharodon carcharias white shark 1
Galeorhinus zyopterus soupfin shark 3
Myliobatis californicus bat stingray 14
Sphyrna sp. hammerhead shark 1
Triakis semifasciata leopard shark 1
Urolophus halleri round stingray ie
TELEOSTS
Artedius notospilotus bonehead sculpin 1
Atherinopsis californiensis _jacksmelt 1
Citharichthys sordidus Pacific sanddab i
Citharichthys stigmaeus speckled sanddab 24.
Citharichthys spp. sanddabs 9
Cymatogaster aggregata shiner perch 10
Electrona rissot chubby flashlightfish 2
Engraulis mordax northern anchovy 1
Genyonemus lineatus white croaker 687
Lepidogobius lepidus bay goby 6
Lyopsetta exilis slender sole 1
Merluccius productus Pacific hake 8
Microgadus proximus Pacific tomcod 1
Otophidium scrippsae basketweave cusk-eel 105
Otophidium taylori spotted cusk-eel 45
Otophidium spp. cusk-eels 12
Paralichthys californicus California halibut 3
Parophrys vetulus English sole 1
Porichthys myriaster specklefin midshipman 1
Porichthys notatus plainfin midshipman 14
Roncador stearnsi spotfin croaker 15
Sebastodes spp. rockfish 37
Seriphus politus queenfish 271
unidentified teleosts Dar Sian
*stings

**vertebra, skull fragment, and fin spine
f¢too wom or fragmented to identify to species

tembiotocid otoliths

Carcharhinidae—requiem sharks

Carcharhinus spp.—requiem sharks, species undetermined.

At least four species of sharks belonging to this genus have been
captured off southern Calfornia at one time or another during the

80 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

past 30 or 40 years, but these and several other species do not occur
abundantly north of about Magdalena Bay, Baja California. Some
species of requiem sharks may attain lengths of 15 feet, but others
may never exceed 5. Because of the confusion among taxonomists
regarding speciation, we have not attempted to identify the teeth
from this deposit beyond the generic level.

Material: 9 teeth.

Galeorhinus zyopterus Jordan and Gilbert—soupfin shark

Soupfin sharks are abundant between British Columbia and about
Magdalena Bay, Baja California. Females occur principally south of
Point Conception, and males north of there. They may be caught in
water as shallow as 100 feet, but most are found deeper than that. A
614-foot female (about maximum) may weigh as much as 100
pounds.
Material: 3 teeth.

Triakidae—smoothhounds

Triakis semifasciata Girard—leopard shark

The leopard shark has been caught between Oregon and Cape San
Lucas, as well as in the northern Gulf of California. Typically they
inhabit shallow areas where the bottom is sandy or sandy-mud. A
5-footer is large, but they may reach 7 feet. The jaws of this species
contain approximately 400 teeth.
Material: one tooth.

Sphyrnidae—hammerhead sharks
Sphyrna sp.—hammerhead shark, species undetermined.

Three species of these tropical sharks have been recorded from our
waters in modern times, but they are rarely seen north of about
Magdalena Bay except during periods of oceanic warming up-coast
from there. The largest hammerheads may reach 15 feet, but those
observed off California seldom exceed 8. Because of inadequate
knowledge of their dentition, we have not attempted to identify the
tooth from this deposit to species.

Material: one tooth.
Myliobatidae—eagle rays
Myhobatis californicus Gill—bat stingray

Bat stingrays range from Oregon to Magdalena Bay, occurring in

shallow bays, along the mainland coast, and around offshore islands.

Fossil fish remains 81

A record specimen weighed 209 pounds, but dividuals exceeding
50 pounds are rare. Because their heavy, plate-like teeth are large
and easily recognized, few escape detection in fossil deposits.
- Material: 14 teeth.
Dasyatidae—stingrays

Urolophus halleri Cooper—round stingray

Round stingrays have been captured between Humboldt Bay,
California, and Panama, but they are not abundant north of about
Ventura, California. They are especially fond of shallow bays,
sloughs, and estuaries, but also abound on the outer coast where the
bottom is not rocky. Although it is difficult, if not umpossible, to dis-
tinguish the caudal sting of Urolophus from that of Myliobatis cali-
fornicus or a juvenile Dasyatis, we are identifying the stings from
this deposit as bemg from round stingrays because they are so much
more abundant in a shallow, sandy habitat than the others. Round
stingray teeth are minute, and will not be retamed by 20-mesh
screens (the smallest used for this deposit), so the absence of their
teeth was not unexpected.
Material: 7 “stings?”

Engraulidae—anchovies

Engraulis mordax Girard—northern anchovy

Northern anchovies range from British Columbia to Magdalena
Bay and from the surf zone offshore for 100 miles or more. They
usually are seen in schools at or near the surface, but there is evidence
that great quantities of large, adult anchovies live at depths of 600
to 800 feet. Individuals are reported to attain lengths of 9 inches,
but a 7-inch fish could be considered quite large.
Material: one otolith (Fig. 4), 4.0 mm long, showing two winter

annuli and a wide summer zone at the margin.

Myctophidae—lanternfishes

Electrona rissoi (Cocco) —chubby flashlightfish

The chubby flashlightfish is a bathypelagic species that apparently
lives 1,000 feet or more beneath the surface. It has rarely been
caught off California, although a great deal of midwater trawling has
been done in areas where it should occur. There is some question re-
garding the validity of the name rissoz for the form that inhabits the
eastern Pacific, but the otoliths from this deposit match perfectly
those removed from an inch-long individual caught off our coast.
Material: two otoliths (Fig. 11), the largest being 3.5 mm long.

82 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

Gadidae—cods

Microgadus proximus (Girard) —Pacific tomcod

The Pacific tomcod ranges from about Morro Bay north to Alaska.
It seems to prefer depths of 200 feet or more, but at times pier and
skiff fishermen catch great quantities in shallow water. They are
reported to reach lengths of 12 inches, but no weights are available
for such a fish. A 101/4,-inch female weighed just a bit under 6 ounces.
This is the only species found in this deposit whose range during
modern times fails to extend south to the latitude of Long Beach.

Material: one broken otolith 3.5 mm long (Fig. 9).

Merlucciidae—hakes
Merluccius productus (Ayres )—Pacific hake
Pacific hake range from Alaska to the southern tip of Baja Cali-
fornia, and offshore for 350 miles or more. Sometimes they are found
in shallow water near shore, but mostly they travel in dense schools
near the bottom in water deeper than 600 feet. They are said to reach
lengths of 3 feet, but a 30-inch fish is rare; a 26-inch female weighed
slightly more than 4 pounds.
Material: eight badly worn otoliths (Fig. 12), the largest fragment
being 7.3 mm long.

Bothidae—lefteyed flounders
Paralichthys californicus (Ayres) —California halibut
California halibut have been captured between Alsea, Oregon, and
Magdalena Bay, but they are not abundant north of San Francisco.
They live on the bottom, usually in water shallower than 200 feet,
often in the surf zone and in coastal bays and estuaries. A 5-foot, 72-
pound female seems to be a record size.

Material: 3 otoliths, the largest being 9.3 mm long (Fig. 20).

Citharichthys sordidus (Girard) —Pacific sanddab

Pacific sanddabs are said to range from southern Alaska to about
Magdalena Bay, but reports of the species in central and southern
Baja California need to be verified. The maximum size reported for
the Pacific sanddab (16 inches and 2 pounds) also is subject to ques-
tion; a 12-inch female, the largest of several thousand recently exam-
ined, weighed less than 10 ounces. The otoliths of C. sordidus are

Fossil fish remains 83

easily distinguished from those of the other two Californian sand-
dabs because of a sharp notch in the antero-dorsal margin.
Material: 7 otoliths, 4.4 to 6.6 mm long (Fig. 17).

Citharichthys stigmaeus Jordan and Gilbert—speckled sanddab
Speckled sanddabs range along the coast from southeastern Alaska.
to Sebastian Viscaino Bay, Baja California, usually in water shal-
lower than 200 feet, and often just outside the surf zone. A large
individual might be 5 inches long and weigh less than an ounce.
Their otoliths are easily distinguished (if m good condition) from
those of the other two Californian sanddabs because of their straight
margins.
Material: 24 otoliths, 1.9 to 3.4mm long (Fig. 14).

Citharichthys spp.—sanddabs, species undetermined.

Several sanddab otoliths were too badly worn or fragmented to
identify beyond the generic level.
Material: 9 otoliths identifiable to genus but not to species.

Pleuronectidae—righteyed flounders

Lyopsetta exilis (Jordan and Gilbert) —slender sole

Slender soles are abundant in depths of 400 to 800 feet or more be-
tween Alaska and Cedros Island, Baja California. They are less
abundant in shallower water, but sometimes they do occur in 150
feet or less. A large individual might exceed 12 inches in length, but
probably would not weigh more than 3 or 4 ounces.
Material: one otolith 2.9 mm long (Fig. 21).

Parophrys vetulus Girard—English sole

The English sole ranges from Alaska to Cedros Island, Baja Cali-
fornia, usually migrating inshore to spawn but living in deep water
most of the remaining time. They prefer sandy mud or muddy bot-
tom areas, and off southern California are most abundant at depths
greater than 30 fathoms. A large English sole might reach 21 inches
and 2 pounds or slightly more. The otoliths of P vetulus are difficult
to distinguish from those of two other flatfishes, Hopsetta jordani and
Lepidopsetta bilineata, without a careful comparison.
Material: one otolith 4.8 mm long (Fig. 19).

Atherinidae—silversides
Atherinopsis californiensis Girard—jacksmelt
Jacksmelt are found between northern Oregon and about Magda-

84 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

Fossil fish remains 85

lena Bay, usually near the surface in relatively shallow water both
in bays and along the outer coast. They are reported to reach 22 in-
ches but no weight is available for such a fish; a 1612-inch female
weighed about 1 pound 3 ounces.

Material: one otolith 5.2 mm long (Fig. 3).

Sciaenidae—croakers
Genyonemus lineatus (Ayres )—white croaker

White croakers are abundant on sandy or sandy-mud bottoms be-
tween Vancouver Island and Magdalena Bay. They usually travel
in loose aggregations just above the bottom, and are equally at home
in shallow water or in 600 feet. A 1414-inch fish, which is large for
a white croaker, weighed 1.4 pounds. Their otoliths were the most
abundantly found fish remains in this deposit.

Material: 687 otoliths 2.4 to 10.5 mm long (Fig. 5).

Seriphus politus Ayres—queentfish

Queenfish have been reported between Yaquina Bay, Oregon, and
San Juanico Bay, Baja California, in much the same habitat as the
white croaker, except that they seem to prefer staying above the
bottom mstead of on it. A 12-inch fish, about as large as they grow,

Figure 1. Inner face, right sagitta of Cymatogaster aggregata, 5.4mm long.
Figure 2. Inner face, left sagitta of Roncador stearnsi, 5.7 mm long.

Figure 3. Inner face, right sagitta of Atherinopsis californiensis, 5.2 mm long.
Figure 4. Inner face, left sagitta of Engraulis mordax, 4.0 mm long.

Figure 5. Inner face, left sagitta of Genyonemus lineatus, 7.3 mm long.
Figure 6. Inner face, right sagitta of Artedius notospilotus, 6.0 mm long.
Figure 7. Inner face, left sagitta of Lepidogobius lepidus, 3.1 mm long.

Figure 8. Inner face, left sagitta of Seriphus politus, 6.8 mm long.

Figure 9. Inner face, left sagitta (central part) of Microgadus proximus, 3.5 mm
segment.

Figure 10. Inner face, right sagitta (rostrum missing) of Sebastodes sp., 7.5 mm
long.

Figure 11. Inner face, right sagitta of Electrona rissoi, 3.5 mm long.

Figure 12. Inner face, left sagitta (posterior half) of Merluccius productus, 7.3
mm long.

Figure 13. Inner face, left saggita of Otophidium scrippsae, 6.0 mm long.
Figure 14. Inner face, left sagitta of Citharichthys stigmaeus, 3.4 mm long.
Figure 15. Inner face, left sagitta of Porichthys myriaster, 5.7 mm long.
Figure 16. Inner face, left sagitta of Otophidium taylori, 6.9 mm long.

Figure 17. Inner face, left sagitta of Citharichthys sordidus, 5.5 mm long.
Figure 18. Inner face, right sagitta of Porichthys notatus, 4.6 mm long.
Figure 19. Inner face, left sagitta of Parophrys vetulus, 4.8 mm long.

Figure 20. Inner face, right sagitta of Paralichthys californicus, 9.3 mm long.
Figure 21. Inner face, right sagitta of Lyopsetta exilis, 2.9 mm long.

Photographs by Jack W. Schott

86 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

weighed just over 10 ounces. Their otoliths were the second most
abundantly found fish remains in this deposit.
Material: 271 otoliths, 3.0 to 9.3 mm long (Fig. 8).

Roncador stearnsi (Steindachner )—spotfin croaker

Spotfin croakers range from about Point Conception to San Juan-
ico Bay, usually along sandy beaches and in coastal bays and estu-
aries where depths do not exceed about 60 feet. A 26%-inch spotfin
caught at Ensenada in 1959 weighed 1014 pounds, a near record size
for the species.
Material: 15 otoliths, 3.9 to 11.1 mm long (Fig. 2).

Embiotocidae—surfperches
Cymatogaster aggregata Gibbons—shiner perch
Shiner perch are extremely abundant in shallow water throughout .
much of their known range: Port Wrangel, Alaska, to Santo ‘Tomas
Point, Baja California. They have been trawled from 400 feet of
water, but are most abundant at depths shallower than 50 feet. They
apparently are restricted to the mainland coast; those around the off-
shore islands have been given the name C. gracilis. A 7-inch long
pregnant female weighing about 3 ounces contained 16 young which
were almost 2 inches long each; no larger shiner perch has been
reported.
Material: 10 otoliths, 3.2 to 5.5 mm long (Fig. 1).

Embiotocid perch not identified to species.

‘Two otoliths, unmistakably from embiotocids, were too badly worn
to be identified to species. The “wear” appeared to be the result of
digestive action from being in the stomach of some predator, rather
than from abrasion.

Scorpaenidae—rockfishes
Sebastodes spp.—rockfish, species undetermined.

Fifty-two members of the genus Sebastodes inhabit the waters of
California. Some of these live exclusively over rocky bottoms, others
inhabit areas of sandy or sandy-mud bottom. Some live out their en-
tire adult lives in relatively shallow water near shore, but others re-
main in deep water offshore. Some attain lengths of 36 inches and
weights in excess of 35 pounds, while others never reach 8 inches and
4 ounces. ‘The otoliths of most of these species can be distinguished
one from the other if they are from adult fish and if they are not

Fossil fish remains 87

worn or broken. Such characters as length and shape of rostrum, con-
figuration of posterior end, angle of taper, depth of sulcus, and num-
ber of growth zones (annuli) for otolith size are helpful for deter-
mining species or species-complex. All of the rockfish otoliths from
this deposit were too worn and fragmentary to identify to species.

Material: 3 otoliths, probably representing three species (Fig. 10).

Cottidae—sculpins

Artedius notospilotus Girard—bonehead sculpin

The bonehead sculpin ranges from about Puget Sound to Ense-
nada, usually at depths shallower than 150 feet where the bottom is
sand or sandy mud. A large female taken in Santa Monica Bay in
1961 was slightly shorter than 7 inches and weighed about 31%
ounces. Otoliths of cottids usually are abundant in fossil deposits
(Fitch, unpublished data), but because of their small size they are
difficult to find without the aid of a microscope. Unless in near-
perfect condition, identification to species is impossible.

Material: one otolith 6.0 mm long (Fig. 6).

Gobiidae—gobies

Lepidogobius lepidus (Girard) —bay goby

This small fish is fairly common in quiet, shallow waters between
northern Vancouver Island and about Ensenada. They seem to prefer
areas shallower than 60 feet but occasional individuals are trawled
in 250 to 300 feet. A large specimen might be 5 inches long and
weigh one ounce.
Material: 6 otoliths, 2.0 to 3.1 mm long (Fig. 7).

Batrachoididae—toadfishes
Porichthys myriaster Hubbs and Schultz—specklefin midshipman

Specklefin midshipmen range from about Point Conception to
Magdalena Bay. They often seek out rocky intertidal areas for
spawning, but at other times they can be found in 300 feet or more.
They prefer firm mud or muddy bottoms to other habitat types ex-
cept during spawning and “nesting” A 19-inch male weighed slight-
ly less than 4 pounds, possibly a record length and weight.
Material: one otolith 5.7 mm long (Fig. 15).

Porichthys notatus Girard—plainfin midshipman
Plainfin midshipmen are among the half-dozen most abundant

88 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

species in trawl catches made in depths of 300 to 750 feet. They are
found in most areas between southeastern Alaska and Cedros Island
where the bottom is muddy. During spawning and “nesting” they
often move into intertidal areas, but during other periods they may
range into 1,200 feet of water.

Material: 14 otoliths 3.3 to 5.2 mm long (Fig. 18).

Ophidiidae—cusk-eels
Otophidium scrippsae Hubbs—basketweave cusk-eel

The range of O. scrippsae is relatively restricted compared with
other species found in this deposit: Point Conception to about Turtle
Bay, Baja California. Divers report that they prefer a habitat of small
rocks and cobbles, hiding under and among these during daylight
hours and moving out into sandy areas at night. A large individual
might be 12 inches long and weigh about 5 ounces. The basketweave.
cusk-eel typically inhabits shallower depths than the spotted cusk-
eel. The otoliths of O. scrippsae are easily distinguished from those of
O. taylori, if they are in good condition, by their expanded antero-
dorsal margin and their concave to flat inner face anteriorly.

Material: 105 otoliths 3.4 to 6.8 mm long (Fig. 13).

Otophidium taylori (Girard) —spotted cusk-eel

The spotted cusk-eel has habits similar to those of O. scrippsae, but
seems to prefer living in deeper water: typically 60 to 800 feet. They
range from about Humboldt Bay to San Cristobal Bay, Baja Califor-
nia. A large individual caught in deep water off San Pedro in 1960
was 1444 inches long and weighed almost 10 ounces. The otoliths
are more tear-drop shaped than those of O. scrippsae.

Material: 45 otoliths 2.6 to 8.1 mm long (Fig. 16).

Otophidium spp.—cusk-eels, species undetermined.

‘Twelve cusk-eel otoliths were too badly fragmented to identify to
species.

Discussion

The assortment of fish remains found in this deposit, with but two
exceptions, was typical of a shallow-water, coastal fauna similar to
what one would find at the same latitude today (Fig. 22). The oto-
liths of Electrona rissoi, a deepwater species, are difficult to explain
in a shallow-water deposit, but since they have been found in several
other southern California Pliocene and Pleistocene deposits (Fitch,

Fossil fish remains 89

ence ctesrenopucrus Lp 2
Sy eh? |
: ‘

GENYONEMUS LINEATUS
CITHARICHTHYS STIGMAEUS
74 AT ~~ ENGRAULIS MORDAX Sy
MT ARTEDIUS NOTOSPILOTUS
OTOPHIDIUM TAYLORI

: Y

LONG BEACH
Signal Hill locality

LYOPSETTA EXILIS - \ ss
PARODY WEIL ) PORICHTHYS MYRIASTER Yj
GITHARICHTFYSSORDIDUS SERIPHUS POLITUS RONCADOR STEARNSI
Menipocomtchtcrints PARALICHTHYS CALIFORNICUS OTOPHIDIUM SCRIPPSAE

ATHERINOPSIS CALIFORNIENSIS

EQUATOR

gure 22. Present-day distributions of the 20 non-bathypelagic teleost fishes iden-
ied from the Long Beach, California Pliocene deposit (LACMIP 423, lat. 33°
5’ N.). Drawing by Walter Thomsen.

wpublished data), they apparently were more abundant during
wrehistoric” times than today, and may have had different habits
so. Another possibility is that the fish were picked up and eaten
7 gulls or other sea birds working over deep water, and transported
ioreward in the digestive tract of the bird. Fish otoliths will pass
rough a number of fish-eating birds and suffer little or no damage
om digestive action (Martini, 1964), and many lanternfishes, in-
uding close relatives of Electrona rissoi (e.g., Electrona subaspera
the Antarctic) undergo diurnal migrations which make them vul-
rable to surface-feeding birds. A final possibility is that Electrona
ssoi suffered a mass mortality and drifted into shallow water before
sintegrating; such a lanternfish die-off has been reported for Tarle-
nbeania crenularis in Monterey Bay (Aughtry, 1953).

The otolith of the tomcod, Microgadus proximus, would seem
be the only mcongruous fish remain in the deposit, but otoliths of
‘is species too have been encountered in several other southern Cali-
rnia Pliocene and Pleistocene deposits (Fitch, unpublished data).
is entirely possible that a foot-thick bed of potential fossils (mol-
scan remains, fish otoliths, shark teeth, crustacean parts, etc.) will

90 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

accumulate on the floor of the ocean for 100 years or more before
some “catastrophe” occurs to cover and preserve the layer. In this
case, the fish fauna of a single bed or layer within a deposit would
reflect distributional anomalies that had occurred during the period.
Fishes are notorious for reflecting short-duration (e.g., weekly,
monthly, or annual) temperature changes (Fitch, 1966a; Radovich,
1961) that would not be apparent from an examination of the mol-
luscan fauna, since mollusks are so much less motile than fishes.

Many of the otoliths in this deposit were in poor condition, appar-
ently having been eroded by digestive action while in the stomach
of some predatory fish, mammal, or bird. Growth zones were appar-
ent on many of the otoliths that had not been damaged by digestive
action, but the margins of these did not indicate that a catastrophe
had caused the demise of the fauna. Some otolith margins indicated
summer mortality; others indicated fall, winter, or spring as the
period of death. Thus, it is assumed that this accumulation of fish
remains represented normal deposition over a considerable number
of years.

Obviously, the 32 species of fish we have reported did not repre-
sent the entire fauna. Additional sampling unquestionably would
have yielded a number of additional species and families, but since
the site was covered by many tons of dirt three days after its discov-
ery, additional sampling was not possible. Recently Fitch (1966b)
has shown that many small otoliths are missed entirely when ex-
amining fossiliferous screenings with the naked eye, such as was
done with the material from this deposit. Careful examination of the
washed screenings under the microscope possibly would have
doubled the number of otoliths found and may have added 10 to 15
species, but at this late date one can only speculate. Certainly micro-
scopic examination is warranted for other “lost” deposits where only
a small field sample has been salvaged.

ACKNOWLEDGMENTS

This study was supported in part by a research grant (GB-1244)
from the National Science Foundation. In addition, George P. Kana-
koff, as Curator of Invertebrate Paleontology, Los Angeles County
Museum of Natural History, supervised the several student volun-
teers and other Museum personnel who washed, screened, and sorted
the sample. Each of these deserves to be thanked by name for his con-
tribution to this study, so if we fail to mention anyone, it is not in-

Fossil fish remains Q1

tentional and we hope we will be forgiven. In alphabetical order they
were: John E. Fitch, Jr., Nick Furjanick, Suzanne Grizet, Louis Ma-
rinkovich, Peter Oringer, Sherry Parkhurst, Robert Rashkin, Wil-
liam Warner, and Barbara Weeks. Fimally, Jack W. Schott, San
Pedro, took the excellent otolith photographs; Walter Thomsen,
Long Beach, produced the fish distribution map; and Mrs. Loretta
Morris, San Pedro, typed the manuscript and its revisions.

LITERATURE CITED

AUGHTRY, ROBERT H.
1953. A note on mass mortality of the myctophid fish Tarletonbeania crenularis.
Copeia, 1953 (3):190-192.

FITCH, JOHN E.

1966a. A marine catfish, Bagre panamensis (Gill), added to the fauna of Califor-
nia, and other anomalous fish occurrences off southern California in 1965.
Calif. Fish and Game, 52(3) :214-215.

1966b. Additional fish remains, mostly otoliths, from a Pleistocene deposit at
Playa del Rey, California. Los Angeles County Mus., Cont. in Sct., 119:1-
16.

MARTINI, ERLEND
1964. Otolithen in Gewollen der Raubseeschwalbe (Hydroprogne caspia). Bonner
Zoologische Beitradge, 15(1&2):59-71.

RADOVICH, JOHN

1961. Relationships of some marine organisms of the northeast Pacific to water
temperatures, particularly during 1957 through 1959. Calif. Dept. Fish and
Game, Fish Bull., 112:1-62.

NOTES ON THE EARLY STAGES OF THE BARBERRY
GEOMETRID MOTHS, GENUS CORYPHISTA, AND THE
DESCRIPTION OF A NEW SUBSPECIES
OF C. MEADII (LEPIDOPTERA )

Joun ApAams ComsTocK

1373 Crest Road
Del Mar, California 92014

Several forms of the moths now included in the genus Coryphista
were originally described in other genera, such as Triphosa, Phi-
lereme and Scotosia.

The first to be named was Scotosia meadi, by Packard (1874: 41)
who published it, “from three males, Colorado, August 23, T. L.
Mead’ In his original description it is spelled meadit.

Packard (1876: 176) for some unaccountable reason described —
Philereme meadiata, listing his own species, Scotosia meadii as a
synonym. According to rule, his meadiata becomes the synonym.
Dyar (1902: 276) lists it correctly as Coryphista meadii.

Edwards (1885: 50) described what he thought was a new species,
Triphosa badiaria. His type was a female from Shasta County, Call-
fornia. This proved to be the dimorphic form badiaria of Coryphista
meadil.

Strecker (1899: 11) named Philereme optimata from one female
taken near Seattle, Washington, and two examples, male and female,
taken by Bruce in Colorado. Optimata proved to be synonymous with
Cory phista meadii f. badiaria.

Munroe (1954: 282) named an eastern subspecies Coryphista
meadi atlantica, and clarified certain points concerning this variable
moth. This was followed in the same publication by MacKay (1954)
with a well illustrated paper on its life history.

In 1935 the late Commander Charles M. Dammers of Riverside,
California, reared numerous examples of the moth on “Mahonia
aquifolium” (now Berberis aquifolium Pursh.), and made colored
illustrations of the larva and pupa which were not published.

Later, in June of 1940, while in Santa Rosa, California, I was able
to obtain eggs and larvae of C. meadii, and made notes, but no draw-
ings.

My real interest in Coryphista came alive im the spring of 1965,
in Del Mar, when an infestation of larvae threatened to defoliate
bushes of Berberis pinnata Lag., in my garden.

Q2

Barberry moths 93

I reared the local colony continuously from February to Septem-
ber. The result was a series of imagos, all uniformly darker than all
other examples of typical meadii I had seen. A small number only
showed tendency toward the form badiaria.

I mailed examples to Drs. Munroe and Rindge, requesting their
opinions. Specimens were also sent to Carl W. Kirkwood of Summer-
land, California, and to Lloyd M. Martin, of the Los Angeles County
Museum of Natural History. The responses were most cooperative.
Munroe sent me examples of C. meadii and badiaria from British
Columbia, and paratypes of his Coryphista atlantica from Ottawa,
Ontario, for comparison, hinting (77 Jitt., June 8, 1964) that, if sea-
sonal variation could be ruled out, it “may well be that your popu-
lation represents a distinct race or subspecies: He suggested caution
on the basis of the great variability in the species, but admitted that
mine were “darker than the material we have from British Colum-
bia, Washington, Oregon, and the Bay region of California”

Dr. Rindge evidenced his never-failing helpfulness in stating that
“your examples from Del Mar, California, are darker than, and less
conspicuously marked than other western populations of meadu.
While I have not dissected any of the four specimens you sent me,
it does seem likely that you do have a valid subspecies”’

The responses from Kirkwood and Martin were of similar import,
in addition to which they gave valuable information on the range
of Coryphista meadit.

From this it would seem that the typical insect ranges from British
Columbia southward and southeastward through the Cordilleras of
North America to Arizona and California. In the Baja California
border area the very dark (smoky) race occurs. For this dark race I
propose herein the subspecific name fumosa.

Along the eastern seaboard, from Ontario, Canada, southward—
possibly as far as Georgia, the subspecies atlantica ranges.

How far westward atlantica extends is yet to be determined but
probably it occurs in a gradually modifying form to the Rocky
Mountain foothills where it becomes typical meadii. The type lo-
cality of meadii is Colorado.

In order to determine its possible great plains distribution a study
should be made of the plant genus Berberis. The holly-like species of
this are exclusively the food plant of Coryphista.

My drawings, photographs and notes on the life history of Cory-
phista meadii fumosa will supplement to some extent the account of
the life history of C. atlantica by Margaret MacKay.

04, Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

These figures will facilitate a description of the new subspecies,
since comparison with the other forms will save wordy details.

Coryphista meadii fumosa, new subspecies

Figures 1, D and E

Holotype male (Fig. 1 D).

Ground color of upper surfaces of both wings, sooty black, with
occasional slight irregular mottlings. The only distinct line on each
wing is the serrated narrow black line along the base of the fringes,

D E

Figure 1. Geometrid Moths of the genus Coryphista, A. Coryphista meadit
(Packard), Seton Lake, Lillooet, British Columbia, Canada, June 15, 1926, J.
McDunnough. Det. E. G. Munroe. 1964. B. Coryphista meadii badiaria (Hy.
Edw). Seton Lake, Lillooet, British Columbia, Canada, June 21, 1926. J. Mc-
Dunnough. Det. E. G. Munroe. 1964. C. Coryphista meadii atlantica Munroe.
Paratype. Ottawa, Ontario, Canada, July 30, 1952. W. Krivda. No. 6132. D. Cory-
phista meadii subsp. furnosa Comst., new subspecies. Holotype male. Del Mar,
California, August 2, 1964. Ex pupa. The example is somewhat smaller than
average males, but was chosen for its perfect condition. The average male
measures approximately 32 mm., apex to apex of forewing. E. Coryphista meadii
subsp. fumosa Comst., new subspecies. Allotype female. Del Mar, California,
September 15, 1964. Ex pupa.

Barberry moths 05

and a slight darkening of the veins with a few light spots, seen best
with a lens. On the forewing the costal margin is black. A black spot
occurs at the outer edge of the cell. Near the outer inferior angle of
the primary there is a faintly defined white spot. Near the outer
margin of the secondaries there is a faint suggestion of a simuous
line. Otherwise there are none of the transverse wavy or crenulate
lines which are such a distinctive feature of typical meadii.

The underside of the wings in the male holotype are a uniform
gray-brown. The black spot at the outer end of the cell is very dis-
tinct, and larger than it is superiorly.

Head, thorax and abdomen, unicolorous with the wings.

Allotype female (Fig. 1 E).

Ground color of all surfaces, similar to that of the male, but with
the female it is overlaid by several indistinct black blotches and dots.
Along the costal margin of primaries these black blotches are inter-
spersed with a few lighter brown areas. The white dot on inner angle
of forewing is somewhat more conspicuous than in the male. The
serrated marginal black line is interrupted at its point of contact with
each vein by a minute whitish dot.

On the secondaries internal to the serrated marginal line is a
sinuous line paralleling it, which is light in color (nearly gray-
white). Along the inner margin of secondaries there is a suggestion
of a few transverse lines, but these fade out at about the M-1 median
nervule.

Other than these features, the sexes are alike. With the high de-
gree of variation in this species it is frequently difficult to distinguish
the sexes without dissection.

DIsTRIBUTION OF TYPES AND PARATYPES

Holotype and allotype deposited in the Los Angeles County Mu-
seum of Natural History. 18 paratypes will be distributed between
the Los Angeles County Museum of Natural History, the Canadian
National Collection, the American Museum of Natural History and
the United States National Museum.

METAMORPHOSIS

The life history of typical Coryphista meadii was briefly recorded
by Dyar (1902) under the title Cory phista badiaria Hy. Edw. At that
time he did not realize that badiaria was a dimorphic form of meadit.

96 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

His specimens were reared on Berberis repens Lindl., taken from
“various places in the foothills of the Rocky Mountains; back of
Golden and Boulder, Colorado and in the Platte Canyon”

My reared material was all from Del Mar, California.

Egg: (Fig. 2, A and B)
A flattened oval; length, 0.75 mm.; width at widest end, 0.50
mm., at narrow end approximately 0.35 mm. Surface covered by a

network of raised walls enclosing hexagonal cells.
Color, glistening light yellow. Eggs collected Feb. 23, 1964 hatched

in five days.
Larva, First Instar: (Fig. 2 C).

Head, yellow; ocelli, black. Mouth parts brownish. Body, translu-
cent light yellow with occasionally a slight greenish tinge.

ee ae oe
> ae as ee xP

%
s

~
<<
&

Figure 2. Egg, larva and pupa of Coryphista meadii fumosa, new subspecies A
and B, Ege, highly magnified. C. First instar larva, enlarged. D. Final (4th)
instar larva, dorsal aspect, enlarged. E. Pupa, ventral aspect, enlarged. F Caudal
segment and cremaster, enlarged.

All figures reproduced from water color drawings by the author.

Barberry moths O7

Posture when resting, body in a complete loop, the head and cauda
close together, more exaggerated even than in our figure.

Measurements were approximately those given by Margaret Mac-
Kay (1954) for C. meadii atlantica.

Second instar:

Length, 4 to 5 mm. Head width, 0.65 mm.

Color of head, light orange. Ocelli, nearly black.

The body color completely different from 1st instar. The dorsum
has a wide band of brown to blackish, lighter along its center, dark-
ening towards the margins; central area with a paired middorsal
Ime of light yellow. Spiracular area with a wide longitudinal white
band, narrowing at each segmental juncture, bulging outwardly at
the middle of each segment. This band takes on a yellow tinge near
head and cauda.

Legs, spotted black and yellow. Prolegs and anal prolegs, pre-
dominantly yellow.

Third instar:

Length of larva not measured, but considerable disparity in in-
dividuals was noted.

Head width, 1.1 mm. Ocelli, black. Mouth paris tinged with
brown. Color of head, glistening yellow.

Body: Cervical shield, dark yellow. Along the dorsum, a wide
band of reddish-brown, margined with black. Throughout the length
of this band there are four narrow, barely discernible yellow stripes,
faintly margined with gray. Spiracularly, a longitudinal wide yellow
band, lobulated, expanding in the area of each spiracle, and con-
tracting on segmental junctures. This band is conspicuous only from
the 4th to 8th segments. It narrows toward the head and there be-
comes pink. On the 9th to 11th segments it becomes pink. In the
center of each lobulated portion the black spiracles are conspicuous.

Legs, black proximally and translucent distally. Prolegs, pink.
Venter, light yellow.

Fourth Instar: (Fig. 2D).

Length ranging from 9 mm. to 20 mm. Head width approximately
1.4 mm.

The dorsal aspect of this final instar is accurately shown in the
figure. There is generally little difference from that of the preceding
instar. The wide stigmatal band extends the entire length of the
body, and its lower margin tends to become pinkish.

98 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

The four longitudinal middorsal white stripes are more clearly

defined.

Pupa: (Fig. 2 E).

Eight examples examined. Length, 10 to 13.8 mm. Width, 3.2 to
4.2 mm. Fusiform, the head rounded. Eyes, oval, protruding ven-
trally, length, 0.8 mm.

Body, red-brown. Texture, predominantly granular. Antennae
and maxillae reaching to wing tips. Spiracles, small, dark, and rela-
tively inconspicuous.

Cremaster (Fig. 2 F); black, pyramidal; length, 0.5 mm., termi-
nating in a pair of black spurs, pointing caudo-laterally. There are
three small yellow hooklets on each side of the pyramidal cremasteric
body.

All specimens were reared on Berberis pinnata Lag.

A dipterous parasite, Madremyia saundersii (Will.) was recovered |
from some of the pupae.

LITERATURE CITED

DYAR, HARRISON G.
1902a. A list of North American Lepidoptera and key to the literature of this
order of insects. Bull. U.S. Natl. Mus., 52: 1-xix + 1-723.

1902b. Life histories of North American Geometridae. XX XV. Psyche, 9: 396.

EDWARDS, HENRY
1885. New species of California moths. Entomologica Americana, 1(3): 49-50.

MACKAY, MARGARET RAE
1954. The egg and larva of Coryphista meadi atlantica Munroe (Lepidoptera:
Geometridae). Canadian Entomol., 86(6): 284-288.

MUNROE, EUGENE
1954. The eastern North American subspecies of the Barberry Geometrid
(Lepidoptera). Canadian Entomol., 86(6): 282-283.

PACKARD, ALPHEUS S.

1874. Descriptions of new North American Phalaenidae. Sizth Ann. Rept. of
Trustees of the Peabody Acad. Sci., for 1873: 39-53.

1876. A monograph of the Geometrid moths. In E V. Hayden, Report of the
United States Geological Survey of the Territories, 10: 1-607, 13 pls.

STRECKER, HERMAN
1899. Lepidoptera, Rhopaloceres and Heteroceres, indigenous and exotic. Supple-
ment No. 2. Reading, Penna.: Printed for the author. 11 p.

NOTES ON THE LIFE HISTORY OF PHILOTES RITA
ELVIRAE (Lepidoptera; Lycaenidae)

JoHN Apams ComsTock

1373 Crest Road
Del Mar, California

AND

CHRISTOPHER HENNE

Pearblossom, California

The rare and elusive little “blue.” described and illustrated by Mat-
toni (1966) as Philotes rita elvirae, is known to only a few of the
rugged collectors who have ranged the desert areas of southern Cali-
fornia.

The type series was taken by Christopher Henne in a desert wash
about 3.5 miles southwest of Pearblossom, Los Angeles County, Cali-
fornia; elevation 3400 feet. The butterflies may be taken on the wing
from July to September, in a narrow belt northward from Little Rock
in the Juniper Hills area, S.W. of Pearblossom to Walker Pass sum-
mit, Mammoth Camp, and Bishop. They are associated with a late-
blooming “wild buckwheat,’ Eriogonum plumatella D. & H.

The female deposits her eggs smgly, each deep in the flower of the
Eriogonum. Eggs laid September 16 to 20, hatched September 28 to
31, 1964.

Ecc: (Ficures 1 A anp B)

Diameter, 0.5 mm. Height, 0.25 mm.

Color, pale green. Form, echinoid, with the top deeply depressed.
The surface is covered with a network of minute hexagonal pits, sur-
rounded by raised white walls. This network extends across the floor
of the micropylar depression, in the center of which is a minute,
barely discernible micropyle. The emerging larva exits from the side
of the egg, leaving most of the shell intact.

Larva, First INstTar:

Described from a single example, two days after hatching. Length,
0.9mm. Width approximately 0.1 mm.

Head, jet black. Body cylindrical, not tapering toward cauda.
Color, light yellow-green.

Two longitudinal rows of short translucent setae occur, one on each
side of the middorsal area. Another row of setae of the same char-

99

100 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

acter occurs dorsolaterally. There are apparently additional setae
lateroinferiorly, but the single larva could not be sacrificed to allow
closer handling and definition of details.

Most of the larvae subsequently received at our Del Mar labora-
tory died, probably as a result of foodplant substitution. They did
not take normally to our coastal E. fasciculatum. However, many
were reared to maturity at our desert laboratory where their normal
foodplant, the flowers of Eriogonum plumatella, was readily procur-
able.

Larva OF 6 MM LENGTH: (FicurE 1 C)

Greatest width, 2 mm. Probably in penultimate instar. Form, the
usual lycaenid slug-like character, but with the segments protrud-
ing, as shown in the illustration.

Head, jet black, and completely retracted when at rest.

Body, ground color, ivory-white, slightly tinged with green. A
middorsal discontinuous line, formed of pinkish-brown dashes. A
dorsolateral line of curved brownish-pink dashes from the 3rd to

Reproduced from water color drawing by John A. Comstock.

Figure 1. Life history of Philotes rita elvirae. All figures enlarged. A. Egg, top
view. B. Egg, side view. C. Larva, dorsal surface. D. Pupa, ventral surface.

Philotes life history notes 1014

11th segments, the caudalmost bearing a large speckled brownish
oval spot middorsally. Legs, black. Prolegs concolorous with body;
crochets, brown. The body surface encrusted with minute white

stubby knobs or setae.

MatTurRE Larva:

The single surviving example in our Del Mar laboratory was ob-
viously somewhat less than normal size as a result of semi-starvation
and unnatural thermal environment. Its measurements were very
little in excess of those for the penultimate instar.

In color and markings it also approximated the prior instar except
for a slightly stronger clarification of the pinkish-brown lines and
dashes.

Normal pupation occurs among small flat pebbles and dried
branches near the base of the foodplant. Our single example in Del
Mar pupated in the Eriogonum blossom.

Pupa: (Ficure 1 D)

Length, 4.5 mm. Greatest width, 2.5 mm. Two pupae reared under
normal desert environment by Henne measured: length, 6 mm,
greatest width, 3.5 mm. Form, robust.

Color, at first a delicate green; later, uniform orange-yellow. Eyes
not prominent. Head, evenly rounded. Antennae reaching to wing
margins; much wider in distal one-fourth, where they cover over
and obscure the maxillae. Body surface rugose to finely granular.
Segmental Imes narrow and indistinct. They have been purposely
slightly intensified in the drawing. Spiracles small, slightly darker
than the ground. No knobs or spines on the caudal tip, except for a
few short minute yellow spicules, which serve as anchorage for the
cast-off larval skin.

Two California lepidopterists have recently published papers on
the Philotes enoptes and P. rita subspecies which have expanded and
clarified our understanding of the complex. Langston (1964) gave
special emphasis to the species occurring in the central coastal area
of California. He named two new subspecies, P. enoptes bayensis, and
P. enoptes tildent, Mattoni (1966) discussed the subspecies P. rita
coloradensis and P. rita alvirae. The last one of these is discussed, and
its early stages illustrated in this contribution. It is hoped that these
combined efforts will prompt other lepidopterists to carry along fur-
ther the study of extensions in range, specificity of food slesris and
metamorphoses.

102 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

LITERATURE CITED
LANGSTON, ROBERT L.
1964. Philotes of central coastal California. J. Lepidopt. Soc., 17 (4) :201-224,
6 figs.

MATTONI, R. H. T:
1966. Distribution and pattern of variation in Philotes rita. J. Res. Lepidopt.,

4(2):81-102, 7 figs. (for 1965).

DESCRIPTION OF A NEW SUBGENUS OF OSMIA
(Hymenoptera: Megachilidae)

Roy R. SNELLING

Los Angeles County Museum of Natural History
Los Angeles, California 90007

When Sinha (1958) revised the New World subgenera of Osmia
he erected the subgenus Euthosmia to accommodate three poorly
known western species, O. glauca (Fowler), O. nemoris Sandhouse,
and O. claremontensis Michener. Since only the first was known
from both sexes it was selected as the type species; the other two
species were known only from the males. Of necessity, the delinea-
tion of the female characteristics was based solely on O. glauca.

Since the publication of Sinha’s work I have been able to associate
a female with O. nemoris. This female proved to be the species de-
scribed as O. seclusa Sandhouse, which Sinha had included in Monz-
losmia as an anomalous species. The evidence for this association 1s
twofold. First, both O. nemoris and O. seclusa occur abundantly to-
gether over a wide area of the western United States, appearing
together at the same season and frequenting the same flowers. Both
species have an unusually long seasonal flight; in the San Joaquin
Valley of California where I have observed this species for over ten
years, I have found that the emergence begins in mid-March and the
species remains abundant until mid-June. Second, a series of cells
provisioned by a female in a burrow in soil yielded both males (O.
nemoris) and females (O. seclusa). There is, therefore, no doubt
that O. seclusa Sandhouse (1924) = O. nemoris Sandhouse (1924)
(NEW SYNONYMY) ; both names were proposed in the same paper
with O. nemoris having page priority.

As pointed out above, the female was believed by Sinha to be an
anomalous member of Monilosmia. The male, however, because of
the transverse, rather than strongly convex, apical margin of the
second sternite, cannot be placed in that subgenus. The female, with
quadridentate mandibles and a distinct clypeal brush, equally well
cannot be placed in Euthosmia. Any attempt to force this species
into any of the existing subgenera would only break down the estab-
lished, and useable, characters on which these are based. Accord-
ingly, the following new subgenus is proposed for O. nemoris.

103

104 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

Subgenus Mystacosmia, New subgenus’
Type species: Osmia nemoris Sandhouse, 1924.

Diagnosis: Closely related to the subgenera Euthosmia and Chal-
cosmia. Principal features of the males are: moderate size; median
flagellar segments no more than 1.5 times as long as wide; inner
margins of eyes converging anteriorly; inpunctate band of clypeal
margin of moderate width; hypostomal carina distinctly elevated
behind angle; hind basitarsus not toothed; with head in dorsal view,
all ocelli anterior to line drawn between posterior margins of eyes;
metasomal sterna II to IV with appressed posteriorly directed hairs,
marginal hairs on these sterna convergent toward midline; meta-
somal terga II to V with subapical pubescent fasciae (frequently
worn). The female may be recognized by the following combination
of characters: mandibles quadridentate, with transverse ridge near
base; tufts of orange hair arising from beneath clypeal margin; genal
area distinctly wider than eye in profile; clypeal punctures con-
tiguous; anterior clypeal margin not thickened or greatly modified;
metasomal terga II to V punctate to apical margins or with extremely
narrow impunctate margin; subapical pubescent fasciae present on
terga II to V; scopa black.

Male. Body length 8 to 11 mm. Pubescence white. Mandible
slender, bidentate, upper tooth oblique, widest basally, constricted
just distad of base. Eyes wider than genae, inner margins distinctly
convergent below. Clypeal apex crenulate, with moderately wide
impunctate apical band; a brush of even, regularly spaced hairs
arising from beneath clypeal margin. Scape about as long as follow-
ing three antennal segments combined; median flagellar segments
about 1.5 times as long as wide. Hypostomal carina strongly raised
behind angle. Second and third segments of middle tarsus not swol-
len; hind basitarsus not toothed, gradually widened toward apex.
Strigilus as described by Sinha for Euthosmia. Metasomal terga II
to V with narrow to moderately broad impunctate bands along apical
margins, with subapical pubescent faciae; tergum VI medially pro-
longed, without emargination at middle of apical margin; tergum
VII produced apically, mid-apex deeply emarginate, forming two
sharp teeth. Metasomal sterna II to V truncate to weakly convex
along apical margin; sternum VI with apical margin broadly sub-
triangular; sternum VIII with basal half triangular and base

'Mystax, -akos (Gr., hair on upper lip, moustache) + Osmia.

New subgenus of Osmia

Figure 1. Osmia (Mystacosmia) nemoris Sandhouse: a-c, sternites VI, VII, VIII,
respectively, of male; d, male genitalia, left side dorsal aspect, right side ventral

aspect; e, male face, right side denuded; f, female face, right side denuded. Figures
by Ruth DeNicola Snelling.

106 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

strongly acuminate, distal half with median projection. Gonocoxite
slightly tapering from base to angulation.

Female. Body length 8 to 12 mm. Scopa black. Pubescence pale,
except for fuscous hairs present on the legs. Metasomal terga with
subapical pubescent fasciae. Mandible wide, slightly constricted
distad of base, gradually widened to quadridentate apex which is a
little wider than constriction; transverse ridge present basally.
Clypeus contiguously punctate, apical truncation somewhat longer
than distance from end of truncation to lateral angle of clypeus; a
tuft of orange bristles arising on each side of mid line from beneath
clypeal margin. Inner eye margins slightly converging below; eyes
in profile much narrower than genae. Hypostomal carina sharply
elevated a short distance behind angle. Hind basitarsus about three
times as long as wide, rounded apically; hind tibial spurs almost
straight apically; apical segments of front tarsi with a number of
long, glistening, white bristles which are abruptly spatulate at the
tips. Strigilus with apical spine of malus shorter than in male, inner
margin of velum concave. Scopa dense, covering most of sterna II to
WA

As far as known at the present time this subgenus includes only
the type species.

The third species which Sinha included in Euthosmia was O. clare-
montensis Michener. Although superficially similar to O. nemoris
several important characters exclude it from Mystacosmia; at the
same time, I do not feel that O. claremontensis should be retained in
Euthosmia. An important feature of this species which Sinha over-
looked is that the hind basitarsus has a distinct spine; Sandhouse
(1939) mentions the presence of this spine, and specimens available
to me agree in this character. The second metasomal sternum of O.
claremontensis has a very poorly indicated median concavity, while
the third sternum has a distinct, deep median emargination. Eu-
thosmia, as redefined below on the basis of the single species, O.
glauca, has the margin of both the second and third sterna broadly
truncate without any trace of a median emargination. The clypeal
truncation of O. glauca is feebly, but distinctly, bisinuate; in O. clare-
montensis it is slightly convex, without a trace of sinuation. In O.
glauca, the metasomal terga are without subapical pubescent fasciae
and the apical impunctate band is narrow. Distinct subapical pubes-
cent fasciae are present on metasomal terga II to V, and the apical
impunctate band is broader in O. claremontensis. The median flagel-

New subgenus of Osmia 107

lar segments are about 1.9 times as long as broad. In my opinion re-
taining O. claremontensis in Euthosmia would make an accurate
characterization of that subgenus almost impossible. I suggest that
this species be left unassigned until the discovery of the female,
which may clarify its relationships.

The present restriction of the subgenus Euthosmia to its type
species necessitates the following restatement of the male characters
of that subgenus:

Male. Body length 4 to 6 mm. Pubescence white. Mandibles as
described by Sinha. Eye wider than genal area, inner margins
strongly converging below. Clypeus densely covered with erect hairs
arising from fine contiguous punctures, apex truncate, margin feebly
bismuate, with narrow impunctate apical band. Antennal scape sub-
equal to following three segments combined, median flagellar seg-
ments about 1.9 times as long as wide, flagellum extending back to
apex of thorax. Hypostomal carina low and of uniform height
throughout. Legs and wings as described by Sinha. Metasomal terga
with narrow impunctate apical bands, without apical or subapical
pubescent fasciae; tergum VI not medially prolonged, without mid-
apical emargination; tergum VII produced, medially emarginate;
sternum IT not produced over base of III, margin truncate or feebly
convex; sternum III without median emargination; erect hairs of
sterna II—IV sparse, evenly distributed, with trace of defined cluster
along midline; sternum V without median emargination; remain-
ing abdominal characters as noted by Sinha.

The removal of the two aberrant species from Euthosmia has made
it possible to place that subgenus on a more acceptable basis. Of
course, this fact also necessitates a rearrangement of Sinha’s chart
(1958:218) of primitive versus derived characters. His character No.
27 in Euthosmia must now be changed from “O;’ (“some species spe-
cialized, and others generalized”’) to “X;’ (all species specialized),
with the result that Euthosmia exhibits 24 generalized and 5 spe-
cialized characters. Mystascosmia has a combination of 19 general-
ized and 10 specialized criteria, placing it closest to Trichinosmia
which has a formula of 18-11. This is also close to Chalcosmia with
17 generalized and 10 specialized.

The third couplet of Sinha’s key to the males of the Nearctic sub-
genera may be modified to accommodate Mystacosmia as follows:

3(2) Genal area wider than greatest width of eye; pubescence
white and black intermixed; hypostomal carina high; an-

108 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

tennal socket with upper mesal margin more strongly de-
veloped than rest of margin ................ Cephalosmia
Genal area narrower than greatest width of eye; pubescence
white; hypostomal carina variable; antennal socket with
margin uniformly developed throughout ............... 3"

3’(3) Median flagellar segments 1.5 times as long as broad; apical
portion of metasomal tergum VI prolonged over VII; an-
tenon chy pealymanreimkerentllate tet ere Mystacosmia
Median flagellar segments 1.9 times as long as broad; apical
margin of metasomal tergum VI evenly convex not conspicu-
ously prolonged over VII; anterior clypeal border simple
Re an eee ihe iar CL on ea NS i eh RS Euthosmia

The key to the females may be modified to differentiate between
Monilosmia and Mystacosmia thus:

8(6) Hypostomal carina high, abruptly reduced near angle, form-
ing a tooth; genal area wider than eye; clypeal truncation
usually longer than margin from end of truncation to lateral
angle of clypeus’ ci. fo a5 ois ee hes oe 8
Hypostomal carina low, not abruptly reduced near angle;
genal area as wide as eye; clypeal truncation usually equal
to margin from end of truncation to lateral angle of clypeus
Pe ene Oe aan Rae STO Tee Ss 4 Chenosmia

8’(8) Mandible with transverse ridge near base and clypeal margin
unmodified; anterior distitarsi with long, erect spatulate
bristles; metasomal terga with subapical pubescent fasciae
PAC es Pann en VN ee Np bead Danes Heel Es mat Mystacosmia

Mandible without transverse ridge near base, or if ridge
present, then apical clypeal margin modified, and/or black
pubescence present on thorax and metasomal terga,; spatulate
bristles absent from anterior distitarsi; subapical pubescent
fasciae usually absent from metasomal terga .... Monilosmia

LITERATURE CITED

MICHENER, C. D.
1936. New Californian Osmiinae. Bull. So. Calif. Acad. Sci., 35:84-93.

SANDHOUSE, G. A.
1924. Bees of the genus Osmia in the collection of the California Academy of
Sciences. Proc. Calif. Acad. Sci., ser. 4, 13:341-372.

1939. The North American bees of the genus Osmia. Mem. Ent. Soc. Wash.
1:1-167.
SINHA, R.N.

1958. A subgeneric revision of the genus Osmia in the Western Hemisphere. Univ.
Fans. Sci. Bull., 39:211-261.

)

GILL STRUCTURE IN THE CAECILIAN GENUS GYMNOPIS

MarvaLEE H. WaxKE

Department of Biological Sciences
University of Illinois, Chicago Circle
Chicago, Illinois 60680

Dunn (1942) reported that gills are absent in Gymnopis and Coch-
ran (1961:16) stated that gills are not known for members of the
genus. Some indication of gills has been found in all other New
World caecilian genera. Rhinatrema (Noble, 1927; Parker, 1934),
Siphonops (Goeldi, 1899), Chthonerpeton (Parker and Wettstein,
1929; Parker, 1956; Parker and Dunn, 1964) and Typhlonectes
(Peters, 1874, 1875; Sarasins, 1887-90) all have gilled embryos;
slits, but not gills, have been reported in young Caecilia (Tschudi,
1845).

An adult female Gymnopis multiplicata proxima with oviducal
embryos (CRE 132 in the University of Southern California Costa
Rican collections) was collected at Zent, Limon Province, Costa
Rica, on 5 May, 1958. The adult is 367 mm. total length, has 117
primary annuli, 98 secondary annuli, an invisible eye, a well ossified
skull with the eye and tentacular groove roofed by bone, the normal
adult dentition, and is dark grey dorsally with a cream colored
venter (in preservation). The embryos were found to have trira-
mous, filamented gills. Of the four embryos, all developig im the
left oviduct, the posteriormost (53.5 mm. total length) has no gills;
of two lying side by side anteriorly a 54-mm. specimen has the left
gill in a normal position and the right held only by a long strand of
connective tissue; the 45-mm. embryo beside it has well developed
gills on both sides of the head; the anteriormost embryo (52 mm.)
also has a pair of well developed gills. The embryos have 110 to 117
primary annuli, secondaries distinguishable only on the posterior
quarter of the body, the eyes covered by skin but well pigmented, an
open tentacular groove, larval teeth as described for the species by
Taylor (1955) and Parker and Dunn (1964), and large melano-
phores scattered over an otherwise unpigmented skin. There is no
sign of an egg membrane.

‘Two females collected at Los Diamantes, Limon Province, Costa
Rica, 17 June, 1962, carried embryos 80 to 84 mm. in length. ‘Two
embryos lay in each oviduct of a 412-mm. female and three in the
left, two in the right of a 430-mm. adult. The adults have 117 and
119 primary annuli and 99 and 100 secondary annuli respectively.

109

110. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

The embryos have 109 to 117 primary annuli and 90 to 96 secondary
annuli, the eye and tentacular groove roofed, though the eye is still
slightly visible, and a reduced number of deciduous teeth. Colora-
tion is similar to that of the smaller embryos. Gills are not present
in any of the Los Diamantes embryos.

Figure 1. Left side of head and gills of 52-mm. Gymnopis embryo. 12 x.
Line = 1 mm.

External morphology of the gill: The head and left gill of the 52-mm.
specimen are shown in Figure 1. The gills originate 5.4 mm. from the
anterior tip of the head and 2.0 mm. from the posterior end of the
mouth. Measurements were made with a vernier caliper. The right
gill has three fringed rami arising from a short stump attached to the
head. The central ramus is nearly twice as long (3.7 mm.) as the
upper and lower (2.0 mm. and 1.9 mm., respectively). The central
ramus arises from a stout base (0.6 mm. wide and 0.5 mm. long).
This ramus has four filaments (1.2 to 1.7 mm. long) at regular m-
tervals along its lower side, a terminal tuft of three filaments (all
0.8 mm.) distally, and two filaments (1.1 and 1.2 mm.) on its upper
side. The upper ramus bears four dorsal filaments (all 1.4 mm.), a
terminal tuft of four filaments (0.6 to 0.7 mm.) and two ventral
filaments (0.5 to 1.0 mm.). The lower ramus has two dorsal fila-
ments (both 0.75 mm.); the terminal tuft is broadly united with
short free filament ends (all 0.2 mm.); the ramus has four ventral
filaments (all 1.0 mm.). The rami of the left gill measured 2.0 mm.,
3.3 mm., and 1.8 mm., uppermost listed first. The upper ramus has
three dorsal filaments (1.2 to 1.4 mm.), an end tuft of three fila-
ments (0.5 to 0.7 mm.), and two ventral filaments (all 1.0 mm.).
The central ramus has four dorsal filaments (1.2 to 1.8 mm.); the
terminal group of filaments is somewhat united with three free ends
(all 0.5 mm.) ; there are four ventral filaments (1.2 to 1.6 mm.). The

Gill structure in Gymnopis 144

lower ramus has two dorsal filaments (0.75 to 1.2 mm.), four end
filaments broadly united with short free ends (all 0.2 mm.), and
three ventral filaments (all 1.0 mm.). Neither side has an open gill
slit.

Microscopic anatomy of the gill: Serial sections of the head and gill
area of the 54-mm. embryo were made and stained with Azan or
hematoxylin-eosin by standard procedures. The gills at the stage of
development examined are little more than simuses containing red
blood cells. Together with the tissue structure, the sinusoidal nature
of the gills indicates degeneration of the structure and imminent loss.
There is neither cartilaginous nor bony gill support, though a ven-
trally located hyobranchial apparatus is present. Fibrous connective
tissue follows the epithelial layer only into the base of the gill (see
Fig. 2). The gill ramus is formed by a stratified epithelial layer one
or two cells thick; the layer is continuous with the epithelium of the
head. The central part of each ramus is a vacuity filled with red blood
cells. The filaments are formed by outpocketings of the epithelial
layer. Several of the filaments close to the base of each ramus are
also hollow and contain red blood cells; those smaller or further
away are usually solid epithelial tissue. The ventral side of some
rami and the filaments of the terminal tuft have a peripheral third
layer of free-ended columnar epithelial cells. Three arterial arches
pass through the base of the gill and are contained within the con-
nective tissue of the head. These do not have channels into the rami,
but pockets in the outer layer of the arch and the curve of the vessels
into and from the gill base indicate that they vascularize the gills.
Some hint of their fate is offered by Peters (1875) and Wiedersheim
(1879), who mentioned scars of one or two blood vessels in the
epidermis, once connected to the aortic arch of each side.

A relatively large outpocketing of connective tissue into the head
epithelium is located on the side of the head above the gill in Gym-
nopis. The structure is also present in a gill-less 80-mm. embryo that
has thickened head epidermis with the connective tissue reduced to
a thin layer between epidermis and head musculature. Apparently
the “flap” does not act as an operculum or structure later enclosing
the gill. A mass of connective tissue is present at the area of previous
gill attachment in the oviducal 80-mm. specimen; the mass forms a
conspicuous external bulge on the side of the head. At birth, usually
100 mm. or greater in length (Taylor, 1955), there is no evidence of
gills, the connective tissue mass, nor the more dorsal connective
tissue outpocketing.

112 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

LN

ZN

Figure 2. Transverse section through right gill of 5.4mm. Gymnopis embryo.
85 x. C=connective tissue; E=epithelium; I=interhyoideus muscle; M=mesen-
chyme; S=gill sinus; V=vascular arch. Line = 1 mm.

Gill structure in Gymnopis 113

Discussion: Published reports on the development of caecilian gills
treat primarily the Old World genera Ichthyophis and Hypogeophis.
Miller (1835) reported the occurrence of gills on an Ichthyophis
glutinosus larva, and the Sarasins (1887-90) briefly discussed the
morphology of Ichthyophis gills. They reported that the gills are
vascularized layers of connective tissue outlined by epithelium. Gill
slits are open, and cartilaginous support (a visceral arch) is present
for each of the three layers. Brauer (1899) studied the external anat-
omy of the developmental sequence of two species of Hypogeophis.
He described the development of triramous, filamented gills from
three knobs on each side of the head of the embryo. In a detailed
discussion of the development of the visceral clefts and pouches, and
their derivatives, Marcus (1908) reported on the external mor-
phology and histology of the gills of Hypogeophis rostratus. He
thoroughly discussed the relationships of the primary germ layers
to gill development, traced development from button-like processes
on the outer side of the visceral arches, and analyzed the cellular
structure of the gills at each stage of development. Marcus stated
that the gill filaments form in sequence, proximal to distal, as out-
pocketings of the gill tissue. He considered the vascular pattern to be
one of loops from the aortic arches; the loops anastomose as develop-
ment proceeds. Marcus also analyzed the pattern of gill degenera-
tion and loss.

The gills of Gymnopis multiplicata proxima described above are
at a late stage in development. Degeneration of the gill structure is
apparent, and the gills probably would have been lost very shortly.
It has long been assumed that caecilian gills are resorbed by the
embryo or larva (Sarasins, 1887-90; Brauer, 1899; Parker and Dunn,
1964). Marcus (1908) commented on his initial doubt of the Sara-
sins’ idea of gill resorption (p. 716), but then claims to be able to
confirm Sarasins’ and Brauer’s suppositions that the gills are re-
sorbed. The Gymnopis material is apparently very near the last
stage of gill degeneration reported by Marcus in Hypogeophis. The
Gymnopis gill agrees in having joined terminal filaments, evidence
to Marcus of the “youngest” filaments being the first to undergo a
regressive metamorphosis; the structure of the “formed elements” is
becoming indistinct; blood cells are found in stages of degeneration;
once distinct blood vessels have anastomosed, probably contributing
to the formation of the sinuses. Marcus stated that he could not carry
the process further but that it was absolutely sure: the gills are not
stripped, but resorbed. My material seems to agree quite closely with

114 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

Marcus’ last reported stage. In this material the left gill of the spec-
imen examined in microscopic section is held to the head only by a
long single anterior strand of epithelium. This condition was first
observed as the embryo lay undisturbed in the oviduct. The remain-
ing gill structure distal to the strand is in the same state of degenera-
tion as that listed above. However, the epithelium of the posterior
part of the head almost covers the original attachment point of the
gill. The gill, then, might fall off upon completion of the epithelial
layer beneath it. The Sarasins observed in gill-less embryos “sprouts”
that they thought were internal gills, but that Marcus considered
to be rudiments of the points of origin of the external gill rami.
These are present in the 54-mm. gill-less Gymnopis embryo. Their
presence cannot be considered evidence regarding means of gill loss,
since they might remain however the gills are lost. The evidence
presented by Marcus and my own observations favor the hypothesis
but do not conclusively prove that caecilian gills are reabsorbed. It
remains possible that the gill, at least im Gymnopis m. proxima, 1s
sloughed off.

Attempts have been made to correlate gill structure with the evolu-
tionary pattern in caecilians by Parker (1956), who discussed the
significance of the presence of a deciduous fetal dentition, the type
of gill structure, and other features. He found that the specialized
dentition occurs only in viviparous (i.e., live-bearing) genera in
both the New and Old World. In attempting to correlate this feature
with other characters, Parker noted that if the dentition is representa-
tive of a natural phylogenetic assemblage, it cuts across systematic
arrangements based on other characters. According to Parker, the
gills of American caecilians are single and plate-like (see also Parker
and Wettstein, 1929, on Chthonerpeton and Peters, 1874, 1875, and
the Sarasins, 1887-90, on Typhlonectes) and those of the African
caecilians are triaxial and plumose. It must be assumed that he
referred only to the genera known to be viviparous, since the em-
bryos of the oviparous New World genera Rhinatrema (Noble, 1927)
and Siphonops (Goeldi, 1899) had been figured earlier with tri-
ramus, filamented gills. The genus Gymmnopis is live bearing, has a
deciduous fetal dentition, and has triramous, plumose gills like those
of the Old World genera. If, as is usually assumed, the New World
and Old World caecilians each form a separate cluster of related
genera that is only distantly related to the members of the other
geographic unit, the gill structure does not seem to be of particular
value in interpreting phylogeny.

Gill structure in Gymnopis 115

ACKNOWLEDGMENTS

I thank Dr. Jay M. Savage, University of Southern California, for
critically reading the manuscript. Histological work was supported
by NSF Grant GB 3868 to David B. Wake, University of Chicago.

LITERATURE CITED

COCHRAN, DORIS
1961. The amphibians of the world. Garden City, New York: Doubleday & Co.,
Inc., 99 p.

DUNN, E. R.
1942. The American caecilians. Bull. Mus. Comp. Zool., Harvard Coll., 91 (6):
439-540.

GOELDI, E.A.
1899. Uber die Entwicklung von Siphonops annulatus. Zoologische Jahrbiicher
Systematik, 12: 170-173.

MARCUS, H.
1908. Beitrage zur Kenntnis der Gymnophionen. I. Uber das Schlundspalten-
gebeit. Archiv fiir mikroskopische Anat., 71: 695-744.

MULLER, J.
1835 Uber die Keimenlocher der jungen Caecilia hypocyanea. Archiv fiir Anat-
ome, Physiologie und wissenschaftliche Medicin, 1835: 391-397.

NOBLE, G. K.
1927. The value of life history data in the study of the evolution of the Am-
phibia. Ann. N.Y. Acad. Sci., 30: 31-128.

PARKER, H. W.

1934. Reptiles and amphibians from southern Ecuador. Ann. Mag. Nat. Hist.,
10 (14): 264-273.

1956. Viviparous caecilians and amphibian phylogeny. Nature, 178: 250-252.

AND E. R. DUNN

1964. Dentitional metamorphosis in the Amphibia. Copeia, 1964 (1): 75-86.

AnD O. WETTSTEIN

1929. A new caecilian from southern Brazil. Ann. Mag. Nat. Hist., 10 (4): 594-
596.

PETERS, W.

1874. Uber die Entwicklung der Caecilien und besonders der Caecilia compressi-
cauda. Monatsberichte Akademie der Wissenschaften, Berlin, 1874: 45-49.

1875. Uber die Entwicklung der Caecilien. Monatsberichte Akademie der Wissen-
schaften, Berlin, 1875: 483-486.

SARASIN, P. and E
1887-1890. Entwicklung tiber Anatomie des Ichthyophis. In Ergebnisse natur-
wissenschaftlicher Forschungen auf Ceylon, vol. 4: 153-263.

116 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

TAYLOR, E. H.
1955. Additions to the known herpetological fauna of Costa Rica with comments

on other species. Univ. Kansas Sci. Bull., 37 (13): 499-575.

TSCHUDI, J. J.
1845. Reptilium conspectus quae in Republica Peruana reperiuntur et pleraque

observata vel collecta sunt in itinere a Dr. J. J. de Tschudi. Archiv fiir
Naturgeschichte, 11: 149-170.

WIEDERSHEIM, R.

1879. Die Anatomie der Gymnophionen. Jena: Verlag von Gustav Fischer,
i-vii, 1-101; 9 plates.

STUDIES OF THE BLOOD OF ASCIDIA NIGRA
(SAVIGNY). TU. VANADOCYTE AGGLUTINATION
AND ITS EFFECT UPON THE HEART.

JAMEs A. VALLEE, JR.

Department of Biology
California State College
Long Beach, California

INTRODUCTION

The agglutination of the blood cells of Ascidia nigra was first de-
scribed by Hecht (1918). He showed that agitation of A. nigra caused
the blood cells to agglutinate, and that the agglutination process nor-
mally reversed itself after fifteen or twenty minutes. He theorized
that agglutination was caused by the secretion of some substance into
the blood, while Fulton (1920) suggested that this substance was
secreted by the blood cells. It was found by the present author that the
heart responded to agitation and agglutination in a characteristic
manner. In the present paper vanadocyte agglutination, and its effect
upon the heart will be described and discussed, especially with regard
to the theories put forth to explain the reversal of direction of the
heart beat.

Tt is well known that the tunicate heart undergoes a periodic re-
versal in the direction of the heart beat, beating for a short time in the
advisceral direction, pausing and then beating in the abvisceral direc-
tion. The heart of Ascidia nigra was studied in some detail by Hecht
(1918), who reported that the heart showed a greater number of
beats during the advisceral phase than during the abvisceral phase
(z.é., 24 abvisceral beats compared to 37 advisceral beats.) There has
been a considerable difference of opinion as to the cause of the reversal
of the direction of the heart beat. Two theories have been proposed:
(1) the pacemaker theory, and (2) the back-pressure theory. Hay-
wood and Moon (1950) support the back-pressure theory, suggesting
that the blood is pumped into one side of the circulatory system faster
than it can pass through the network of blood sinuses. As a result, a
back-pressure is built up causing the heart to stop beating. However,
Millar (1952) found that periodic reversals in the direction of the
heart beat still took place in the isolated heart of Ciona intestinalis,
and therefore stated that the back-pressure theory was untenable.
Krijgsman (1956) also discounted the back-pressure theory. He felt
that there were two myogenic pacemakers, one at each end of the

117

118 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

heart, and proposed a theory to explain reversal. He suggested that a
metabolite might stimulate a sensory mechanism associated with the
pacemakers, causing them to contract. However, the sensory mech-
anism would then become fatigued and cease responding to the
metabolite. As a result the pacemaker would stop functioning and
the pacemaker at the opposite end of the heart would take over.
Krijgsman (1956) pointed out that there is as yet no adequate ex-
planation for the refilling of the tunicate heart. He assumed that
there must be sufficient blood pressure on the “venous” side of the
circulatory system to force blood into the heart.

MATERIALS AND METHODS

Animals were collected from sea walls on Key Biscayne, Florida,
and placed in an aquarium with running sea water.

Blood pressure measurements were made in the visceral vessel. —
To do this a piece of capillary tubing 1.5 mm in diameter was drawn
out to a fine tip and bent 90°. The fine-tipped end of the capillary was
gently inserted into the horizontal visceral vessel, and the height to
which the blood rose in the vertical part of the capillary was meas-
ured (this requires about 1% of the tunicates blood volume). The
capillary was calibrated in millimeters, and corrected for the effects
of capillarity.

To record the heartbeat a kymograph and ink-writing lever system
was used. The lever was pivoted in the center. The pen at one end
was counterbalanced by a fire polished glass weight suspended by a
thread from the other end. The glass weight rested gently on the
pericardium so that each contraction wave passing along the heart
caused the glass weight, and thus the pen, to move. The kymograph
was run at a speed of 5.181 cm per minute.

OBSERVATIONS AND RESULTS

The blood pressure of Ascidia nigra is shown in ‘Table 1, the aver-
age blood pressure being 4.2 mm of mercury. It should also be
pointed out that this blood pressure remained unchanged, even dur-
ing the short pause in the heartbeat which characterizes the reversal
of the heartbeat. The pericardial fluid is also under considerable pres-
sure. When the pericardium is punctured and the pericardial fluid
allowed to escape, the heart no longer contracts.

Observation of the heart of A. nigra showed that there are a
greater number of beats during the advisceral phase than during the

Studies on tunicate blood 119

abvisceral phase, as reported by Hecht (1918). For example, during
a period of twelve reversals in the direction of the heartbeat there
were an average of 20.5 systoles in the abvisceral phase and 32.5
beats in the advisceral phase, at 25°C. However, there is a great deal
of variation, and the heart may beat 70 or 80 times before reversal.
The pulse rate averaged 24 beats per minute in both directions.

| | min. |
wy ab. prrer

pene
Figure 1. kymograph record of the heart of Ascidia nigra.

Figure 1 is a kymograph recording of the normal heartbeat. The
vertical bars were added to indicate the reversal in the direction of
the heartbeat. It can be seen that there is normally a two- to four-
second pause between the time the heart stops beating in one direc-
tion and starts beating in the other. It is also interesting to note that
the shape of the recording of the advisceral heartbeat differs from
that of the abvisceral heartbeat. This is because the contraction wave
of the advisceral heartbeat approaches the kymograph weight from
a direction opposite that of the abyisceral heartbeat. Figure 2 is a
kymograph recording of the heartbeat of a tunicate just after the
animal has been agitated by grasping its siphons with a pair of for-
ceps. This causes the pulse rate to decrease considerably, only five
beats being recorded during the first minute of the record. However,
the reversal of the direction of the heartbeat takes place much more

120 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

| | min. |
ab. ad. ab.

At OUT OC STD Oe. WOO er)

Figure 2. Kymograph record of the heart of an agitated animal (Ascidia nigra).

often, reversing four times in the first 1.5 minutes of the record,
twice the normal rate of reversal. The prolonged advisceral phase has
no special significance, since such prolonged phases were found to
occur occasionally under both normal and experimental conditions.
To obtain the kymograph record shown in Figure 3, the pressure of
the glass weight resting on the heart was increased until the heart
beating in the advisceral direction could just force blood past this
block. Although this block was about three cm from the advisceral
pacemaker, it resulted in a marked decrease in the pulse rate of the
heart in the advisceral phase. The first three or four advisceral heart-
beats occur much less frequently. The advisceral phase is also shorter
than the abvisceral phase of a normal heart, although not as short as
that of an agitated animal. The abvisceral heart rate was normal be-
cause in this direction the stronger beat was able to pump blood past
the block without difficulty.

In addition to its effect upon the heart, agitation of the animal also
caused the agglutination of the blood cells. When the test of the ani-
mal is scraped or rubbed, clumps of blood cells become apparent in
the blood vessels of the test. Unagglutinated blood is almost colorless,
but after agglutination the blood appears to be bright yellow, the

Studies on tunicate blood 1214

yellow color of the vanadocytes being much more apparent when the
cells are clumped together in small aggregates. As this “agglutinated
blood” is carried from the test to the heart, by way of the test vessel,
the blood cells in the heart immediately agglutinate, and within one
or two minutes the blood cells of the entire circulatory system agglu-
timate. The large aggregates of blood cells, thus formed, occlude
many of the smaller blood sinuses, interfering with the circulation.
Often agglutinated blood cells completely occlude these smuses over
a wide area. However, if the animal is left undisturbed for a period
of twenty to thirty minutes the agglutinated cell clusters dissociate,
liberating trapped cells, and free circulation is re-established.

| |_ min. |

dd. ab.
—_— 1) eeeeoDODOD™@™D>@D@OMm— ___

ab. ad

ab

Figure 3. Kymograph record of mechanically blocked heart of Ascidia nigra.

It should be emphasized that the test of Ascidia nigra is a complex,
living structure, containing cells and supplied with an extensive net-
work of blood vessels. Blood vessels approach the free surface of the
test. Thus, even gentle stroking of the surface of the test causes the
blood vessels to rupture, resulting in the appearance of many spots of
yellow blood on the surface of the test.

Thus, it may be stated that agitation of the animal results first in
the rupturing of the blood vessels of the test, followed by the agglu-
tination of the blood cells throughout the circulatory system, which is
in turn followed by a reduced pulse rate and an increased frequency
of the reversal of the direction of the heartbeat.

Observations of agglutinated blood under the microscope showed
that not all of the blood cells take part in the agglutination process.

122 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

Only the vanadocytes were seen actively to agglutinate. A few color-
less cells were trapped in the clumps of vanadocytes. However, most
of the colorless cells, orange cells, and blue cells remained free and
unageglutinated while almost all of the vanadocytes were aggluti-
nated.

DiIscuSssION

It was pointed out above that the blood pressure within the vis-
ceral vessel remains the same (about 4.2 mm Hg) while the heart is
beating in the advisceral direction, durimg the short pause in the
heartbeat that occurs when the heartbeat reverses direction, and
while the heart is beating in the abvisceral direction. There is no
detectable increase in the blood pressure at each contraction of the
heart, and there is no detectable drop in the blood pressure when the
heart stops beating. The method used was sensitive to a change in
pressure of 0.1 mm of Hg. Furthermore, when the blood in the vis-
ceral vessel is flowing toward the heart, it has the same blood pres-
sure that it has when it is flowing away from the heart. Thus, the
“venous” pressure is nearly equal to the “arterial” pressure. It
should also be recalled that the heart of A. nigra is a very thin mus-
cular membrane. It is so weak, that if the pericardium is punctured,
releasing the pressure of the pericardial fluid on the heart, the heart
is unable to contract against the pressure of the blood within it.

TABLE 1
Blood Pressure in Ascidia nigra
Tunicate mm Blood mm Hg
1 58 4.4:
Y 57 4.3
3 54. 4.1
Average 56 4.2

In vertebrates the blood pressure is determined, among other fac-
tors, by the degree of constriction or dilation of the arterioles, and by
the cardiac output. Tunicates lack arterioles, and, as seen above, the
blood pressure is unaffected by cardiac output. Therefore, it seems
most likely that the blood pressure observed is caused by the general
muscle tone of the animal. That is, by contracting the muscles of the
mantle, etc., the pressure within the circulatory system is brought up

Studies on tunicate blood 123

to 4.2 mm Hg. Since the circulatory system lacks valves, the pressure
is transmitted throughout the hydrodynamic system. This explains
why the “venous” and “arterial” pressures are nearly equal. This
also explains why the pressure is maintained when the heart is not
beating. The heart, in the relaxed state, is “inflated” with blood un-
der this 4.2 mm Hg pressure. The heart cannot contract against this
pressure on its own. However, with the aid of the pressure of the
pericardial fluid the heart can contract. The pressure of the pericar-
dial fluid is obviously less than 4.2 mm Hg, since the blood “inflates”
the heart against the pressure of the pericardial fluid. However, it
was not possible to measure this pressure directly.

The contraction of the heart apparently provides only enough
pressure to overcome the frictional resistance of the blood against the
walls of the blood vessels and sinuses. This requires very little pres-
sure. Even in vertebrates the resistance to flow is negligible until the
arterioles are reached (Fulton, 1950). Since ascidians lack arterioles
and capillaries, it is readily understandable that the weak peristaltic
wave of the heart provides enough pressure to circulate the blood
through the open circulatory system. The blood pressure of 4.2 mm
Hg probably serves to keep the blood smuses open, thus insuring the
free circulation of the blood. It also keeps the heart dilated, except
where the contraction wave occurs. Thus the filling portion of the
cardiac cycle is due to the general muscle tone forcing blood into the
heart, not to the residual blood pressure resulting from the previous
contraction, as suggested by Krijgsman (1956).

It should also be pointed out that the absence of any pressure drop
in the visceral vessel during the reversal in the direction of the heart-
beat would seem to be evidence against the “backpressure” theory of
heartbeat reversal. The theory implies that the blood pressure in the
visceral vessel should increase during the advisceral phase and drop
after reversal of the heartbeat. However, no such increase or subse-
quent drop was observed.

The kymograph records show that when the animal is agitated,
thus causing the agglutination of the blood cells, the pulse rate slows
markedly, while the rate of heartbeat reversal increases. Supporters
of the backpressure theory would state that the agglutinated vana-
docytes, which occlude the smaller blood smuses, cause a more rapid
build up of the backpressure, which in turn inhibits the pulse rate
and causes more frequent reversals of the heart. Furthermore, when
the heart is blocked by additional weight on it the pulse rate slows.
All this would seem to be evidence for the backpressure theory, and

124. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

it may well be that the theory does apply in animals with ageluti-
nated vanadocytes. If pressure on the pacemakers stimulates them to
fire, the increase in the blood pressure resulting from the pumping of
blood against occluded blood sinuses might fatigue the sensory
mechanism of the pacemakers more rapidly, resulting in a slower
pulse and more frequent heart reversals. That is, a more rapid accom-
modation of the sensory mechanism of the pacemaker may take
place. However, it must be emphasized that no such increase in blood
pressure occurs in the normal animal during the course of either the
advisceral or abvisceral phase. Thus, if the backpressure theory ap-
plies at all, it would seem to be limited to tunicates with vanadocytes
in the agglutinated condition.

SUMMARY

(1) Kymograph records of the heart of normal and agitated A. nigra _
were obtained. Agitation caused the pulse rate to decrease and
the frequency of reversal to increase.

(2) The blood pressure of A. nigra is 4.2 mm Hg.

(3) The heart and circulatory system are discussed.

ACKNOWLEDGMENTS

I wish to thank Dr. Charles E. Lane for his advice, and the use of
equipment, without which the present study would not have been
possible.

LITERATURE CITED
FULTON, J. E

1920. The blood of Ascidia atra Lesueur; with special reference to pigmentation
and phagocytosis. Acta Zoologica Stockholm, 1:381-433.

1950. A textbook of physiology. Philadelphia: W. B. Saunders Co., 1258 p.

HAYWOOD, C. A., and H. P MOON
1950. The mechanism of the blood vascular system of Ascidiella aspersa. J. Exp.
Biol., 27:14-28.

HECHT, S.

1918. The physiology of Ascidia atra Lesueur. III. The blood system. Amer. J.
Physiol. 45 (3) :157-187.

KRIJGSMAN, B. J.

1956. Contractile and pacemaker mechanisms of the heart of tunicates. Biol.
Rev., 31:288-312.

MILLAR, R. H.
1952. Reversal of the heart-beat in tunicates. Nature, 170:851-852.

RECENT RECORDS OF WATER BIRDS IN THE DESERT

RicHARD C. Banxs!

San Diego Natural History Museum
San Diego, California

In the early part of 1966, several reports of the occurrence of strictly
aquatic birds in the desert of San Diego and Imperial counties, Cali-
fornia, were brought to my attention. While each record is of inter-
est individually, the number of independent reports and the number
of birds involved suggest that more than a casual straying from a
normal flight path or migratory pattern is involved. I want to thank
Maurice Getty, Naturalist at Anza-Borrego Desert State Park, for
donating specimens found in Borrego Valley and for forwarding re-
ports from park rangers. R. Guy McCaskie helped in drawing other
records together and made valuable suggestions. I also wish to thank
those mentioned below for permission to report their observations.
Unless otherwise noted, localities are in San Diego County, Califor-
nia, and dates are in 1966.

Gavia immer, Common Loon.

Robert R. Prather found a loon in the town of Ocotillo, Imperial
County, on April 20, following a severe windstorm. He picked it up
and released it the next day at the Salton Sea National Wildlife Ref-
uge, of which he was at that time Manager. Prather reported (in
litt.) that the bird was apparently in good health, and was gone from
the release area the following day.

This species of loon is not common on the Salton Sea, the only
large body of water in interior southern California (McCaskie, pers.
comm.). There are few records in the Gulf of California (Fried-
mann, Griscom, and Moore, 1950). Phillips, Marshall, and Monson
(1964), however, noted that it is “sometimes common in April” on
the Colorado River. In all probability, the bird found at Ocotillo had
been blown off its course and grounded by the strong winds.

Branta canadensis, Canada Goose.

Mr. Carruthers, of La Jolla, California, reported in considerable
detail the occurrence of one of these birds im sparsely vegetated bad-
land country near Arroyo Seco del Diablo in Anza-Borrego Desert

1Present address: Bureau of Sport Fisheries and Wildlife; U.S. National Mu-
seum, Washington, D. C.

126 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

State Park. On the afternoon of January 14, he saw the bird standing
in the desert, far from any water. There were some green plants
emerging from the ground, but the bird was not observed feeding.
Mr. Carruthers approached to within 150 to 100 yards of the bird,
which then flew about 50 yards. This was repeated. On Mr. Car-
ruthers’ third approach the bird flew farther and over a ridge. The
bird did not appear to be mjured in any way.

Banta nigricans, Black Brant.

On April 1, a flock of 12 to 15 brant were seen on a stream in Coy-
ote Canyon, north of Borrego Valley, by a park ranger. Getty found
a dead brant in Borrego Valley on April 2. On April 3, Jay Shepard
found two brant on San Felipe Creek at Scissors Crossing; these birds
were captured and were banded and released in Mission Bay, San
Diego.

There have been several recent records of brant wintering in the ~
northern Gulf of California and appearing as spring migrants at the
Salton Sea (Nowak and Monson, 1965; Reynolds, 1966). To my
knowledge the present records offer the first information concern-
ing the route taken from the normal range on the Pacific coast to the
newly exploited inland habitats. It is possible that a new migratory
pattern is being established by brant that enter the Gulf of California
from the south, find themselves trapped at the northern end, and are
forced to fly overland to the Pacific or to northern breeding grounds.

Anas platyrhynchos, Mallard.

A dead mallard in Borrego Valley was reported to Getty by a park
visitor on April 2, but the report could not be verified.

Aythya affinis, Lesser Scaup.

Getty reported that a ranger found a dead scaup near Vallecito in
early April. On April 3, a scaup was captured at Angelina Spring in
Grapevine Canyon. The bird was unable to fly more than a few feet
at a time, and died shortly after capture.

Melanitta perspicillata, Surf Scoter.

Getty found one of these birds in Borrego Valley on April 2, and
reported that a ranger had found one near Vallecito about the same
time. Shepard found one near Scissors Crossing on April 3. There are
three other records of this species from interior San Diego County:
Julian, La Puerta (=Mason) Valley (Grinnell and Miller, 1944:90),

Records of water birds 127

and Jacumba (Sams and Stott, 1959:10). Grinnell and Miller (1944)
interpreted inland occurrences of this species as suggesting an over-
land route of migration from wintering grounds in the Gulf of Cali-
fornia to the Pacific coast.

DiscussIon

The records of the common loon and the Canada goose stand apart
from the others reported here in time, and at least the former can be
explained by circumstances (a windstorm) immediately preceding
the occurrence. It is interesting that the brant, mallard, scaup, and
scoter all were found within a short period in early April, and that
most of them were found dead or dying. Although the time of the
occurrences is within the normal migratory period for these water-
fowl, there is no ready explanation for their appearance on the desert
floor.

Robert R. Prather reported (in /itt.) that fowl cholera was rather
widespread in California in early April, and that the disease affected
some waterfowl in the Imperial Valley. The brant found in Borrego
Valley was submitted to Dr. H. C. Johnstone, Veterinary Pathologist,
Office of the County Veterinarian, San Diego County, who examined
it for cholera. Dr. Johnstone reported (zm /itt.): ““There was no evi-
dence of fowl cholera in this specimen, and bacteriological cultures
were negative for this organism. On autopsy, the bird showed exten-
sive visceral gout (retention of urates )?’ The bird had been frozen for
some 10 weeks prior to examination, however, and Dr. D. J. Thack-
rey, of the same office, noted that failure of the causative organism of
fowl cholera to culture was not necessarily significant.

Dr. Thackrey also indicated that gout could have been responsible
for the bird’s death. This condition is a result of a deficiency in pro-
tei metabolism, and may be caused by an excess of protein in the
diet or by a poor quality protein. In this respect, it is interesting that
the normal food of brant along the coast is sea lettuce, Ulva, but brant
on the Salton Sea have been reported feeding on bulrush, Scirpus
tuberosus or robustus (Nowak and Monson, 1965; Reynolds, 1966).
A comparison of the nutrient qualities of Ulva and Scirpus might
prove to be enlightening.

128 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967
LITERATURE CITED

FRIEDMANN, H., L. GRISCOM, and R. T. MOORE
1950. Distributional check-list of the birds of Mexico. Part 1. Pac. Coast Avifauna
no. 29, 202 p.

GRINNELL, J., and A. H. MILLER
1944. The distribution of the birds of California. Pac. Coast Avifauna no. 27,

608 p.

NOWAK, J. H., and G. MONSON
1965. Black brant summering at Salton Sea. Condor, 67 (4) :357.

PHILLIPS, A., J. MARSHALL, and G. MONSON
1964. The birds of Arizona. Tucson: Univ. Ariz. Press, 212 p.

REYNOLDS, F L.
1966. Recent sightings of black brant (Branta nigricans) in the Salton Sea area
of southern California. Calif. Fish and Game, 52(2):118.

SAMS, J. R., and K. STOTT, JR.
1959. Birds of San Diego County, California: An annotated check-list. Occ. Pap.
San Diego Soc. Nat. Hist. no. 10, 49 p.

LATE-PLEISTOCENE DEFORMATION IN THE LIME-
KILN CANYON AREA, SANTA SUSANA MOUNTAINS

JAMEs E. SLosson AND JoHN T. BARNHART

Los Angeles Valley College
Van Nuys, California

INTRODUCTION

The Santa Susana Mountains, located in the western portion of the
Transverse Range, are a part of the regional east-west structural
trend along the southern side of the Ventura Basin. This basin is a
highly folded and faulted synclinorium extending westward from
the San Gabriel Mountains to beyond the Santa Barbara Channel
Islands which contains a thick section of sediments ranging from
Cretaceous to Recent in age.

Along the southern flank of the mountains, two large canyons,
Limekiln and Aliso, reflect recent movements along the Santa Su-
sana fault.

Previous investigators reported that Late-Pleistocene movements
of the Santa Susana fault are reflected in the distribution, altitudes,
and relationships of the terraces formed in this area during Late
Pleistocene.

This study was undertaken to distinguish the phases of move-
ments of the Santa Susana fault and discern the stratigraphic rela-
tionships associated with these phases. Movement times must be con-
sidered relative because material is lacking for determination of ab-
solute dates.

Gero.Locic History

Sediments encountered in this area range from Miocene to Late
Pleistocene-Recent m age and include the Topanga, Modelo, ‘Tows-
ley, Pico, and Saugus formations. Nearly all beds are separated by
unconformities which reflect a marginal oscillating environment in
the old Miocene-Pliocene depositional basin. The strata of Pleistocene
age suggest brackish water, minor encroachments of the marginal
seas In areas receiving terrestrial deposits, or minor depressions near
an old shoreline (Jennings, 1957). In Upper Pleistocene times the
seas completely withdrew and only terrestrial deposits were laid
down. The San Gabriel Mountains have been proposed as a possible
source for some of these Pleistocene beds (Jennings, 1957).

Overlying the Saugus formation are two Pleistocene terraces, the
oldest being best exposed in Horse Flats and the youngest best seen

129

130 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

Santa Susana : San Gobriel Mtns.
°

“p Son Fernando
dure

Santa Monica Mtns.

Angeles eS

Area of

~

!
!

above map \
Woes)

Figure 1. Regional map of southern California showing the location of Limekiln
Canyon area.

in Aliso Canyon. The older terrace (Terrace I) is composed of sand,
silt and gravel, with the gravel being white, angular, siliceous frag-
ments of the Modelo formation. The younger terrace (Terrace II) is
almost entirely of shale fragments in a matrix of reddish brown sand,
silt and clay. Jennings (1957) believes that these represent a flood
plain deposit, loosely cemented with calcium carbonate.
Structurally apparent in this region is the Santa Susana fault
which has moved in a southerly direction as two imbricate thrust
plates, as a result of Pleistocene folding in the eastern Ventura Basin.

Late-Pleistocene deformation 131

Gouge along the thrust plate and brecciation of the Modelo shale in-
dicates the movements of these plates at extremely shallow depths
north of this area. Several high angle and reverse faults occur at
angles to and near the front of the thrust. Two well-developed anti-
clines, two synclines, and a minor anticline strike northwest-south-
east across Aliso and Limekiln canyons.

The Santa Susana thrust is exposed as two separate plates: the
upper and lower plates. The movement has been directed slightly
west of south in several independent pulses, sometimes at slightly
different angles. The upper plate which comes to the surface about
one-half to three-fourths mile to the north of the lower plate is about
700 feet thick at this point. This plate has Topanga, Modelo, Towsley,
and Pico formations thrust southward over Miocene and Pliocene
Modelo and Saugus of Plio-Pleistocene age. North of the area near
the head of Aliso Canyon, the fault plane is folded along the Aliso
anticline. About one-half mile north of the anticline, the upper plate
dips north and is truncated by younger movement of the lower thrust
plate (Jennings, 1957).

In this area, the lower plate has a thickness of about 1,500 feet,
with Modelo through Saugus formations thrust over Pleistocene
Saugus formation and post-Saugus terrace deposits. Displacement of
the lower plate of 8,000 feet toward the south has been cited by Haz-
zard (1944), with combined displacement of the two faults have been
reported to be 15,000 feet (Jennings, 1957). Both plates intersect the
surface at angles between 21° and 35° but steepen to about 60° in
depth. They intersect in depth north of this area and east of Lime-
kiln Canyon; only the lower plate continues into this area.

DEFORMATION OF TERRACES

The post-Saugus Pleistocene terraces in this area have been in
places intensely deformed by the movements of the Santa Susana
thrust. The oldest terrace (Terrace I), which is upper Pleistocene,
is best exposed in Horse Flats and along the southwest edge of the
lower thrust. This terrace represents the flood-plain deposits which
were being shed by the risig upper plate north of this area. The re-
lief created by this upper plate was the greatest of the two plates.
Thrusting movement ceased temporarily and the terrace became
well indurated, bemg cemented with calcium carbonate. This ce-
mentation by ground water was augmented by abundant tufa-
forming waters which were being transported to surface along bur-

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Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

132

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Late-Pleistocene deformation 133

ied faults. Many tufa deposits were formed just after the deposition
of ‘Terrace I as evidenced by implaced vent tubes still remaining in
the tilted terraces. After a short interval, movement was again acti-
vated and the lower thrust broke through to the surface southerly
from the upper plate. This plate involved only the Modelo, Towsley,
and Pico formations with maximum movement being nearly hori-
zontal. Erosion of this plate contributed Modelo detritus to its flood-
plain deposits with additional debris being derived from Terrace I.
This thrusting period was short-lived as only 30 feet of material was
deposited in the vicinity of Horse Flats and farther south. The area
of deposition was considered to have been essentially flat in the region
to Horse Flats as Terrace I, which still remains here, has only a
slight southerly dip. Owing to the movement of the lower plate, the
Modelo formation in the nose of the thrust displays dips of 75° to 80°
and abruptly terminates against the Saugus formation.

About one mile west of Limekiln Canyon, a rotated block of Sau-
gus formation and overlying Terrace I has been tilted vertically in
front of the advancing thrust. Brecciation of the block lends difficulty
to distinguishing whether it represents a single block or two blocks
with Terrace I trapped in between.

The time that has lapsed since the deposition of Terrace II was
somewhat shorter than the interval between Terraces I and II. Rem-
nants of Terrace II still remain, and recent erosion has not exten-
sively damaged the tilted block. It is proposed in this report that a
third, very slight movement has occurred in which Terrace II has
been tilted. West of Limekiln Canyon, Terrace I is topographically
higher in places than ‘Terrace II. A third pulse or continued move-
ment during post-Terrace IT age would be required to account for this.

CoNCLUSIONS

The Limekiln Canyon area demonstrates Late Pleistocene, if not
Recent, movements of the Santa Susana thrust along the southern
flank of the Santa Susana Mountains. The thrusting here is accom-
plished in two plates which were not synchronous in time. Erosion of
the older upper plate produced Terrace I and, subsequently, the ex-
posure of the lower plate was reflected in deposition of Terrace I. The
effects of the thrusting are apparent in brecciation and tilting of the
affected strata.

The interval since the deposition of Terrace II is considered short
since the terrace is thinner than Terrace I. There is indicated a post-

134 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

Terrace II younger or recurrent movement of the lower thrust which
has deformed and tilted this terrace, possibly within the last 10,000
years.

LITERATURE CITED

HAZZARD, J. C.
1944. Some features of Santa Susana Thrust, vicinity of Aliso Canyon Field,

Los Angeles County, California, Amer. Assoc. Petroleum Geologists Bull.,
28:1780-1781.

JENNINGS, R. A.

1957. Geology of the southeastern part of Oat Mountain Quadrangle and adja-
cent parts of the San Fernando Quadrangle. Unpublished M. A. Thesis,
University of California, Los Angeles, 105 p.

HOLOTHURIANS OF THE GENERA ELPIDIA AND KOLGA
FROM THE CANADIAN BASIN OF THE ARCTIC OCEAN

Canpipo P AGATEP

Allan Hancock Foundation
University of Southern Cal’fornia
Los Angeles, California 90007

A number of bottom samples taken from the drifting ice station
Arlis II (Arctic Research Laboratory Ice Station 2) as it drifted
across the Arctic Basin included representatives of two genera of
elasipodid holothurians, E/pidia and Kolga. These specimens were
found at two stations: 298 (Shirley) and 380 (Brusca), in the Cana-
dian Basin, a subdivision of the Arctic Basin. At station 298 the sixty-
four specimens found appear to be the typical subspecies of E/pidia
glacialis Theel and the fifty-seven animals from station 380 are
Kolga hyalina Danielssen and Koren. These animals were collected
by the use of a Menzies Trawl (Menzies, 1964) which employs a net
with mesh opening of about 0.5 mm.

Specimens are deposited in the collections of the Allan Hancock
Foundation, University of Southern California, Los Angeles, Cali-
fornia.

Elpidia glacialis glacialis Hansen 1956
Figures 1 and 2

Hansen 1956, pp. 34-38, fig. 1-6.

Material examined: Station 298 (Shirley) Arctic Basin, Lat. N.
84°21’7”, Long. E. 170°48’, depth 3175 meters, sixty-four com-
plete specimens.

Description: Specimens ovate, slightly more than twice as long as
broad, length ranging from 8 to 15 mm. Body semicircular in cross
section. Mouth located anteroventrally, surrounded by ten small
tentacles, the ends of which have two large retractable processes on
outer margins; processes in most of specimens are clearly visible on
five dorsal tentacles. Anus posterior. Dorsal surface convex, tapering
slightly towards posterior; ventral surface flat. Dorsal surface with
three pairs of well developed papillae (Fig. 1 A). Ona 15 mm.-long
specimen members of first pair of papillae, located at anterior end,
over 3 mm. in length; those of second pair, just behind level of first
pair of tubefeet are smallest, 2 mm.; last pair lie between levels of
the third and fourth pairs of intermediate tubefeet. In an 8 mm.

135

136 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

specimen dorsal papillae almost half as long as in 15 mm. specimen.
Lengths of dorsal papillae also correspond to size of animal. Dorsal
papillae were luminescent when specimens were freshly collected
(Delton Shirley, pers. comm.). Midventral radius naked, while
ventrolateral surface carries four pairs of tubefeet of which two
middle pairs larger than first and last pairs.

Skin rough, transparent. Color in alcohol white.

Calcareous deposits in integument small rods of varying length
which have four arms near center, one from each side, and two very
short processes projecting outward (Figs. 1 B and C). Main rods
long and more or less straight while arms short. Some spicules lack
shorter processes while a few large spicules have an extra process on
either end of main rod (Fig. 1 C).

Calcareous ring corresponds closely to the description by Theel
(1882), bemg composed of five spicules each with four pairs of |
bilaterally symmetrical arms. They surround gullet with ends of
outer arms joined together and inner arms lying side by side with
arm of adjacent spicule, forming a delicate network (Fig. 1 D).
Single polian vesicle oval, transparent. Gonad composed of slightly
long branching tubules.

Remarks: All sixty-four specimens in the collection have the same
number and position of the dorsal papillae. Theel’s (1876) specimen
taken between Australia and Antarctica has three pairs of dorsal
papillae, the second pair situated at the middle while the first and
third pairs are located near both ends of the dorsal surface. Although
Theel (1876) considered the small number of dorsal papillae in his
specimen to be insignificant variation from the “typical” form of
E. glacialis, Hansen (1956) subsequently recognized this form as a
subspecies, on the basis of much additional material. Elpidia glacialis
sundensis Hansen has three pairs of dorsal papillae arranged in the
same manner as that of the above specimen (Fig. 1 F). Elpidia
glacialis glacialis Hansen (Fig. 2 A) has three to five pairs, two or
four near the anterior end of the body and one near the posterior end.
Elpidia glacialis solomonensis Hansen, however, has spicules closely
similar to those of specimens described in this paper, but otherwise
differs in having six to eight pairs of dorsal papillae (Fig. 2 E).
Elpidia glacialis theeli Hansen (Fig. 2 D) and Elpidia glacialis
kermadecensis Hansen (Fig. 2 A) differ from the specimens de-
scribed above both in the number and arrangement of the dorsal
papillae and shape of the spicules.

Specimens collected near the Kara Sea (Schorygin, 1948) have

Arctic holothurians 137

E F

0.5mm 5mm

Figure. 1. 5 mm. for whole animals only; 0.5 mm. for spicules only. A. Elpidia
glacialis glacialis, Arctic Basin, showing dorsal aspect; B-C. E. g. glacialis, spicules
from body wall; D. E. g. glacialis, calcareous ring; E. E. g. sundensis, Sunda
Trench, showing spicule from body wall (taken from Galathea Report); FE E. g.
sundensis, dorsal aspect.

138 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

@F®@
@r@
one
@F®
Cx@
@x®@
O ©
@x@

5mm o.5mm

Figure 2. 5 mm. for whole animals only; 0.5 mm. for spicules only. A. Elpidia
glacialis kermadecensis, Kermadee Trench, showing dorsal aspect; B. E. g. ker-
madecensis, spicule from body wall (taken from Galathea Report); C. E. g. solo-
monensis, New Britain Trench, showing spicule from body wall (taken from
Galathea Report); D. E. g. theeli, Tasman Sea, showing dorsai aspect; E. E. g.
solomonensis, dorsal aspect; E E. g. theeli, spicule from body wall (taken from
Galathea Report).

Arctic holothurians , 139

four pairs of dorsal papillae, three pairs on the anterior and one pair
near the posterior end. In another collection taken in the Kurile-
Kamchatka Trench (Diakonov, 1955) specimens have four pairs of
dorsal papillae equi-distant from each other, two pairs anterior and
two pairs posterior. Schorygin’s are similar to E. glacialis glacialis,
Diakonov’s to E. glacialis kermadecensis.

Variation of the dorsal papillae of E. glacialis of the “Ingolf” and
“Godthaab” collections has been thoroughly studied by Heding
(1942). The “Ingolf” specimens collected from the deep water of the
Norwegian Sea and together with specimens from “Godthaab”
station 54 occupied in the deep parts of Baffin Bay have normally
four pairs of dorsal papillae, three pairs on the anterior and one pair
on the posterior end. Heding (1940) has shown further, in his study
of the “Valdivia” specimens taken in 24°35’3” N, 17°47” W, that
the animals agree in number and arrangement of the dorsal papillae
with those of the “Ingolf” collections. Theel (1876) reported that
the specimens collected by the Swedish Arctic Expedition from the
Kara Sea have four pairs of dorsal papillae arranged in the same
manner as those specimens of Schorygin and Diakonov.

Heding (1942) observed that there is distinct variation in the
number and arrangement of the dorsal papillae of EL. glacialis be-
tween the two above collections and also with the depth at which
the animals live. Specimens taken from shallow water or close to
shore, as specimens from the Baffin Bay, have five pairs, four an-
teriorly and one posteriorly. However, animals collected from deep
water of Baffin Bay usually have four to five pairs of dorsal papillae,
three to four anterior and one posterior.

It is interesting to note that none of the specimens from the “God-
thaab” collections taken from the deep water in Baffin Bay show the
characteristics of the Arlis II specimens. The same is true for speci-
mens collected from the Kara Sea which were described by Theel
(1876) and animals taken from the Barent and Kara Sea (Schorygin,
1948).

The differences between the specimens of Arlis II and those of the
previously described subspecies of Elpidia glacialis are imsufficient
to warrant a separate subspecific status. It is, therefore, the best
course to refer these specimens to the subspecies glacialis as they are
similar to one another. To accommodate these animals, it is necessary
to amend the number of dorsal papillae in the key of Elpidia glacialis
glacialis from the original 3 to 4 and 1, to 2 to 4 and 1 respectively.
The key to the subspecies would be as follows (Hansen, 1956):

140 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

A. Dorsal papillae large, body vaulted.

1. Dorsal papillae divided into an anterior and a posterior
group, with 2 to 4 and 1 pairs respectively. 72 =a. -
1.) SER eee ae Elpidia glacialis glacialis Hansen 1956: 38.

2. Three pairs of dorsal papillae, placed on the head, the mid
part, and the hind part of the body, respectively. ........
Ee oh Soo ea Elpidia glacialis sundensis Hansen 1956: 35.

B. Dorsal papillae small and regularly distributed; body depressed.
I. Spicules with very high vertical apophyses.

3. 5 to7 pairs of dorsal papillae, with violet spots. .........
Reh eee Mente Near 2 Elpidia glacialis theeli Hansen 1956: 37.

II. Spicules with low vertical apophyses.
45) 4: tol pamsjot dorsalspapillaes = 9) 5-4)
pies cht Elpidia glacialis kermadecensis Hansen 1956: 36.
5. Ostors pamsiot dorsal papillaew 3 .= 0a eee
ar cee eae Elpidia glacialis solomonensis Hansen 1956: 35.

Kolga hyalina Danielssen and Koren

Danielssen and Koren, 1882, pp. 3-20, Tab. I, fig. I-II, Tab. I, fig.
12-25, Tab. III, fig. 26-30.
Theel 1882, p. 3.

Material examined: Station 380 (Brusca) Arctic Basin, Lat. 80°37’

4’'N, Long. 173°14’ E, depth 2850 meters, fifty-seven specimens.
Description: Body elongated oval, about three times as long as broad;
mouth anteroventral; anus posterodorsal. Tentacles ten, with termi-
nal parts divided into four knobs; each knob divided into two smaller
processes.

Dorsal surface convex with three pairs of closely set papillae in
shghtly curved row on anterior margin; center pair slightly larger
than others. Ventral surface flat, with fourteen pairs of tubefeet ar-
ranged symmetrically along sides.

Calcareous ring and calcareous deposits are described by Daniels-
sen and Koren (1882) and Theel (1882). Color in alcohol white.

Remarks: This species is distributed not only in the Arctic Gcean
(Theel, 1882; Danielssen and Koren, 1882) but also the Antarctic
Ocean as collected by the Eltanin, station 913, Lat. 65°48-65° 38’ S,
115°00-114°55’ W, depth 4473 meters and station 1148, Lat. 65°
14/3”-65°25'37 S, Long. 117°29'5”-117°29" W, depth 4850:

Arctic holothurians 141
ACKNOWLEDGMENTS

For access to the specimens described in this paper, I am grateful
to Dr. John L. Mohr, principal investigator, University of Southern
California. I wish to thank Dr. David L. Pawson, Division of
Echinoderms, United States National Museum and Dr. Bent Hansen,
Zoological Museum, Universitetsparken, Copenhagen, Denmark for
their help and advice. I am grateful to Mr. Stephen R. Geiger, Uni-
versity of Southern California, for his helpful advice, to Messrs.
Delton Shirley and Gary Brusca who collected the specimens and to
Mr. A. Charles Gross for technical assistance. Work was supported
by a contract NONR 228(19), NR 307-270 between the office of
Naval Research, Department of the Navy and the University of
Southern California, Los Angeles, California and by a grant
(G-19497) from the National Science Foundation.

LITERATURE CITED

DANIELSSEN, D. C. and J. KOREN
1882. Holothurioidea. Norwegian North-Atlantic Expedition 1876-1878, 4: 94 p.

DIAKONOY, A. M.
1955. Echinodermata. Observational Data of the Scientific Research Drifting Sta-
tion of 1950-1951, 2: Sec. 4, p. 24.

HANSEN, B.
1956. Holothurioidea from depths exceeding 6000 meters. Galathea Report,
2: 33-35.

HEDING, S. G.
1940. Holothurien II. Wissenschaftliche Ergebnisse der deutschen Tiefsee-Ex-
pedition.

1942. Holothurioidea II. Danish Ingolf Expedition, 4: 1-39.

MENZIES, R. J.

1964. Improved technique for benthic trawling at depths greater than 2000
meters. In Biology of the Antarctic Seas, Antarctic Research Series, 1: 93-
109. Amer. Geophysical Union, Publ. 1190 (Washington).

SCHORYGIN, A. A.
1948. Echinodermata. Fauna and Flora of the Northern Seas of the U.S.S.R.
Moskva, Gosurdarstvennoe isdatelstvo Sovetskkaia Nauka, pp. 465-495.

THEEL, H.
1876. Memoire sur |’Elpidia, nouveau genre d’Holothuries. Svenska vetenskap-
sakademien Handlinger, n. f., 14: 3-30.

1882. Holothurioidea. Report on the Scientific Results of the Exploring Voyage of
H.M.S. Challenger 1873-76, Zoology 4 (Pt. 2): 1-176.

SOME LIFE HISTORY DATA ON SEVERAL SPECIES OF
COMMON SPIDERS FROM THE JACKSON HOLE
AREA OF WYOMING

Donaup C. Lowrie

Department of Zoology, California State College
5151 State College Drive
Los Angeles, California 90032

During the summer of 1950, a study of the spiders of the Grand Teton
National Park area was carried out, Lowrie and Gertsch (1955),
including a study of the spiders of the herbaceous vegetation of the
region by means of sweeping the vegetation with an insect net and
using sampling units of 50 strokes. In addition, data from collecting
besides the 50 stroke sweeps were included. On further examining the
data it became apparent that some information on life history could
be gleaned in the cases of several species which were common.
enough to provide good data. Collecting was done fairly regularly
during about twelve weeks of the summer period. These data were
separated into six periods of two weeks each. The percent of speci-
mens in each of three categories was determined for each of these
periods (Table 2). These categories were the following: adults, im-
matures of all but the first few instars and immatures of the first few
instars—too immature to determine their sex. Though 10,000 sweeps
were made (200 samples of fifty strokes of the sweep net each—
approximately 4 cubic feet of herbaceous stratum space) they were
not made equally in each of the two week periods. They varied as
will be seen in Table 1 from 14 to 61 per two week period. Neverthe-
less, the proportion of individuals in each of the categories in each
of the periods is indicative if not always conclusive.

Pityohyphantes cristatus Chamberlin and Ivie, of the family
Linyphiidae, as may be seen from Table 1 was a common species
with a total of 149 specimens collected. It is a woods species which
builds an inverted bowl-shaped sheet web beneath which it hangs
most of the time. It is found rarely in places other than the shady,
moist depths of spruce-fir and other mid and low altitude forested
areas. The young apparently hatch sometime in mid-June (Table 2)
as the first young appear about that time and until early July mamly
adults are collected. By August the adults are nearly all females
probably because the males all die off by late July (actually after
early July very few were found). This is a species which is restricted
mainly to lower altitudes below about 9,000 feet partly because the

142

Spider life history data 143
TABLE 1. Number of specimens of each species collected.

No. of

50-stroke Misu- Pityohy- Tetra- Tetra- Tibellus Par-

3 5 mena phantes gnatha gnatha paral- dosa

Two-week period Units vatia cristatus laboriosa versicolor lelus __ tristis
I June 11-24 DY) 4 15 34 10 7 10
II June 25-July 8 26 12 38 17 9 11 17
III July 9-22 61 24: 14 29 9 1 18
IV July 23-Aug.5 48 36 43 43 19 61 10
V_ Aug. 5-19 29 48 29 47 7 25 21
VI Aug. 20-Sept.2 14 4 10 50 16 44. 9
Totals 200 128 149 217 70 149 85

coniferous forests are not extensive above that altitude in the Tetons.
The general shift of the population from adults to very immature, to
penultimate forms, to adults indicates a fairly clear picture of young
produced in the mid-June period through the mid-August period
with a preponderance of adults beginning to appear in the last week
of August.

Misumena vatia (Clerck), of the family Thomisidae, is the only
yellow crab spider (subfamily Misumeninae) to be found in the
Tetons. Of the other genera, Misumenops and Misumenoides and
other species of Misuwmena, only this holarctic species M. vatia has
been found in the Tetons. Table 2 indicates that the young are born
in late June and mature during July and August. By the end of
August the adults again predominate and apparently pass the win-
ter in hibernation to appear again when the flowers blossom in the
early spring. No adults were found from mid-July until mid-August.
However, only six adults were collected indicating that these heavier
forms move off onto sturdier vegetation, are capable of resisting the
sweeping net, or have an extremely low density. In support of the last
hypothesis it should be mentioned that careful hand examination of
many flowers showed that the number of adults was actually quite
low. They are found mainly crawling on the yellow flowers of
Berberis, Ranunculus, Potentilla, Solidago, Arnica, Wyethia and
Senecio where they ambush butterflies and other insects which come
to the flower heads for nectar. A total of 128 individuals was found
in sweeping of the vegetation at the lower altitudes.

Dondale (1961) indicates this as a biennial species in Nova Scotia.
My data would not preclude that interpretation but since virtually
mature specimens were found by the late August period it would
seem that in the Tetons they may mature in one season.

144. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

TABLE 2. Percent of specimens of each species in each age class.
(A—adult males and females; I—-immature males and females;
Y—immatures too young to determine their sex)

Coll. Period Misumenavatia Pityohyphantes cristatus Tibellus parallelus

A I yi A I ¥ A I ay.

I 75 25 0 80 0 20 0 14 86

Il 8 17 75 45 0 55 27 0 73

Ill + 13 83 21 43 36 0 100 0

IV 0 28 72 30 20 50 Z 34 64+

V 0 63 37 20 10 70 4 + 92

VI 25 75 0 40 40 20 5 61 34

Totals 5 38 57 37 14 49 5 34+ 61

Coll. Period Tetragnathalaboriosa Tetragnathaversicolor Pardosa tristis

A I M A I wv A I By

I 0 97 3 0 70 30 100 0 0

Il 6 82 12 0 80 20 59 18 23
Ill 70 30 0 44 55 89 11 0
IV 93 5 2 70 5 25 90 10 0
V 24 4 74 100 0 82 18 0

VI 18 4 78 6 0 94 67 22, 11
Totals 36 28 36 36 28 36 81 ie 5

Tetragnatha laboriosa Hentz, of the family Tetragnathidae, is
probably the most abundant spider in Jackson Hole as well as in
many places in the United States. It builds its web in the drier herba-
ceous vegetation of meadows and open areas in woods. Over two hun-
dred specimens have been collected in sweepings. Few were found
above 9,000 ft. Practically all of the specimens collected prior to the
second week in July were nearly adult (Table 2). For the next four
weeks over 70% of the specimens collected were adults and cocoons
were being laid during this period. By the week of August 6th, newly
emerged young were the predominant specimens (74% or more of
catch). Sexable immatures were still not very abundant indicating
that they either grow markedly during the rest of the fall period
before hibernating or else during the next spring.

Letragnatha versicolor Walckenaer is a spider of very moist woods
elsewhere in the United States, with the bulk of specimens being
found in webs stretched directly over streams. In the Tetons it may be
found in slightly drier situations often some distance away from the
actual stream but still in moist habitats. Over one hundred specimens

Spider life history data 145

were collected and their life cycle seems to follow closely that of 7:
laboriosa (Table 2). The main change is that they mature a week or
two later, im mid-July rather than early July.

Tibellus parallelus (C. L. Koch), of the family Thomisidae, is the
fifth species collected in enough abundance to warrant conclusions
as to its life cycle. A total of 165 specimens was collected in the
quantitative and general collecting but only eleven of these were
adults for the same reasons noted above. It is a protectively colored
and behaved roving species common on stems of monocots in moist
areas, though not restricted to the grass-like forms. It would seem to
mature in fall or early spring with eggs laid the latter part of June.
Young are in abundance by mid-July and seem to reach a peak by
late August or September when most of them can be classified as well-
developed immatures. The departure from the trend shown by the
July 9 to 20 collections is insignificant as only one specimen was col-
lected then because sweeping was done in areas not frequented by the
species. In addition, it should be noted that only about 20 specimens
were collected during the first six weeks, so more sweeping of habi-
tats in which they would be found during spring and early summer
must be done.

Besides these species, trends in life cycles of several species may be
noted though enough specimens were not collected to give as clearcut
results. The agelenid Agelenopsis utahensis (Chamberlin and Ivie)
seems to mature in late summer by mid-July or later. The argiopid
Araneus patagiatus (Clerck) becomes adult by early August, as
seems to be true of Araniella displicata (Hentz), the salticid Evarcha
hoyi (Peckham) and possibly also Metaphidippus nigromaculatus
(Keyserling). The linyphiud Microlinyphia bonita (Chamberlin and
Ivie) is mature by mid-June and possibly overwinters as an adult.
Presumably the eggs are laid shortly after early July but collecting
data are not clear on this point. One ground-inhabiting species,
Pardosa tristis Thorell of the family Lycosidae, was found and col-
lected in enough numbers to determine its life history. This is an
ecologically widespread species tolerant of a variety of conditions and
varying enough that it was collected extensively and with a mini-
mum of bias. Table 2 indicates that young emerge by the end of June
and continue to be common into September. Adults, including fe-
males with egg cases, were found as late as collecting was done, in
early September. The high percentage of young during early July

indicates that they were leaving their mothers at this time and mov-

146 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 2, 1967

ing out onto the vegetation alone. The presence of very immature
specimens again towards the end of the period may indicate a second
brood though more collecting will be essential for determining this.

ACKNOWLEDGMENTS

I would like to acknowledge the grant-in-aid awarded me in 1950
by the New York Zoological Society which partially defrayed the
expenses of the study. Of great value also were the facilities of the
N. Y¥. Zoological Society’s Biological Research Station at Moran,
Wyoming, which are now maintained by the University of Wyom-
ing. Though the basic work reported here was done in 1950, the use
of the Research Station for some corroborative work since then is also
acknowledged. Finally, I would like to thank Dr. W. J. Gertsch for
verification of the identification of some of the spiders herein studied.

LITERATURE CITED

DONDALE, C. D.
1961. Life histories of some common spiders from trees and shrubs in Nova
Scotia. Canadian J. Zool., 39:777-787.

LOWRIE, D. C. and W. J. GERTSCH
1955. A list of the spiders of the Grand Teton Park Area, with descriptions of
some new North American Spiders. Amer. Mus. Novitates, 1736:1-29.

gn FWemoriam

Dr. W. Dwicut PIERCE

Born: November 16, 1881, Champaign, Illinois
Married: 1904
Died: April 29, 1967, Los Angeles, California

Offices held in Southern California Academy of Sciences:

President— 1943-1944:
Treasurer— 1948-1964

Elected to Fellow in 1946.

Member of the Board of Directors, Advisory Board, and
Honorary Life Member.

(See Bulletin, Volume 63, page 204, 1964.)

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Academy of Sciences

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LOS ANGELES, CALIFORNIA

Cosa TUChI UrZIDST

VoL. 66 Juty-SEPTEMBER, 1967 No. 3

CONTENTS

E. YALE Dawson MemoriAL NUMBER

E. Yale Dawson, 1918-1966. John S. Garth

Studies in the Foliose Red Algae of the Pacific Coast II. Schizy-
menia. Isabella A. Abboti

Contrast between the Pioneer Populating Process on Land and
Shore. Maxwell S. Doty

Growth and Development of Sciadophycus stellatus Dawson. M.
Neushul, J. Scott, A. L. Dahl and D. Olsen

New Genera in the Rhodomelaceae from the Central Pacific.
George J. Hollenberg

Issued October 26, 1967

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VoL. 66 JuLy-SEPTEMBER, 1967 No. 3

E. YALE DAWSON! ?
1918 -1966
Joun S. GartTH

Dr. Elmer Yale Dawson was born in Creston, Iowa, on March 31,
1918. At the age of four he moved with his family to Long Beach,
California, where he attended public schools. Guided by discerning
science teachers, members of the local Agassiz Club, the Lorquin
Entomological Society, and the Cactus and Succulent Society, Yale

1Editor’s Note: A symposium honoring the late Dr. E. Yale Dawson was held
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Naturalists on the campus of California State College at Long Beach. The papers
presented at this meeting were assembled for this issue of the Bulletin in
memorial to Dr. Dawson. The organization of the symposium and collection of
these papers was largely through the efforts of Dr. Isabelle A. Abbott. Dr. John
S. Garth was a close associate of Dr. Dawson and was asked to prepare the
obituary.

2Contribution No. 305 from the Allan Hancock Foundation.

149

150 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

developed successive interests in butterflies, cacti, and, on matricu-
lating at the University of California, in marine algae. He gradu-
ated from Berkeley in 1940 and obtained his Ph.D. just two years
later, in 1942, as the last student of the late Dr. William A. Setchell,
from whom he inherited a magnificent phycological library that
greatly facilitated his later work.

World War II, while interrupting his professional career with
a brief stint in the Camouflage Battalion of the Engineering Corps
as a private, later provided congenial employment as research asso-
ciate at the Scripps Institution of Oceanography while serving as
Lieutenant and Captain in the Army Air Corps. Coming to the
Allan Hancock Foundation of the University of Southern California
as research associate in 1945, he quickly built up the algal collec-
tions obtained on early Hancock Expeditions by Dr. William R.
Taylor, and was made associate professor in 1952. In 1955 he left
the Hancock Foundation and during the next three years served as
associate marine biologist for the University of Hawaii, as con-
sultant for the California Water Pollution Board, and as research
associate in botany and associate editor at the Los Angeles County
Museum. In 1958, at the instigation of Mr. Palmer T. Beaudette,
he left the Museum to become vice president and research director
of the Beaudette Foundation for Biological Research at Solvang,
California, which he served until 1962. While at Solvang he edited
the Pacific Naturalist, established the [Santa Ynez] Valley Mu-
seum of Natural History, and taught a summer course at U. C.
Santa Barbara at Goleta.

Dr. Dawson returned to the Allan Hancock Foundation as pro-
fessor of biology in 1962, then became director of the San Diego
Natural History Museum in 1963 and Curator of Cryptogams at
the Smithsonian Institution (U.S. National Museum) in 1965,
where in a year’s time he increased the Museum’s phycological col-
lections from 25,000 to 40,000 specimens. Meanwhile, he found
time to serve as Secretary for the Americas of the Charles Darwin
Foundation, an international body responsible under UNESCO for
maintaining a biological station in the Galapagos Islands.

Active field work was the basis for all of Yale Dawson’s scientific
research. Before finishing high school in 1936 he had traversed
the length of Baja California several times with his father. His
interest in the Gulf of California region was advanced by partici-
pation in Hancock expeditions of the Velero III in 1940 and of the
Velero IV in 1949 and 1954, and by an overland expedition to west

E. Yale Dawson 151

Mexico in 1946. In 1953 he was a member of the Volcano Expedi-
tion to San Benedicto Island and participated in research in Viet
Nam; in 1955 he made an algalogical survey of Eniwetok Atoll
in the Marshall Islands. He was a member of the Machris Bra-
zilian Expedition in 1956, the Palmyra Atoll Expedition in 1957,
and of the Stella Polaris Expedition to Panama in 1958. He ex-
tended his travels to Ecuador and the Galapagos Islands in 1960, to
northern and central Peru in 1962 and 1963, and was a member
of the Galapagos International Scientific Project in 1964. He was
diving for algae in the Red Sea at Hurgata, Egypt, between at-
tendance at an International Congress of Oceanography at Moscow
and anticipated attendance at the Pacific Science Congress in
Tokyo, when he met his untimely death by drowning on June 22,
1966. He is survived by his wife, Maxine Christianson, whom he
married in 1942, and by two daughters, Dawn Carol and Renée.

Dr. Dawson’s courses in marine botany, given at the University
of Southern California, the Institute of Tropical Biology, Costa Rica,
the University of California, Santa Barbara, Humboldt State Col-
lege, Arcata, and the University of Arizona, were models of organi-
zation. He had a talent for making difficult subjects highly compre-
hensible. His interest in involving young students in various aspects
of biology is responsible for the careers of Max Hommersand in
phycology and of David Fork in plant physiology. He was a major
influence in the decisions of M. Neushul, C. J. Dawes, and A. C.
Mathiesen to work in marine botany. His field guides, “How to
know the Seaweeds,” and “How to know the Cacti,” did much to
popularize these subjects. His recent textbook in Marine Botany, in
the words of one reviewer, “will probably remain unchallenged in
the field for a long time.” His professional papers, many of which
he illustrated personally, were of high quality and one of them,
his “Marine Red Algae of Pacific Mexico,” won him the Darbaker
Prize of the Botanical Society of America in 1963. He was a mem-
ber of Phi Beta Kappa, Sigma Xi, a member and fellow of the
Southern California Academy of Sciences, the American Associa-
tion for the Advancement of Science, the Botanical Society of
America, the Cactus and Succulent Society, the Phycological So-
ciety, the International Association of Plant Taxonomy, the Inter-
national Organization of Succulent Plants, the Japanese Phycologi-
cal Society, the British Phycological Society, and a corresponding
member of the Mexican Natural History Society. He served as
president of the Western Society of Naturalists in 1963.

152 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

These bare facts fail to convey an adequate impression of E. Yale
Dawson as a man of inexhaustible energy and contagious enthusi-
asm for any cause that he espoused. If he had a failing, it was that
where he led few dared to follow, at least at the pace he set for
himself. He believed in justice based on simple logic, and never
compromised with the truth. He met physical misfortune with
fortitude, and refused to let personal discomfort interfere with his
work. He was active in civic enterprises, and took pride in bringing
the quaint town of Santa Ynez abreast of the 20th Century. As a
Presbyterian elder he found no insurmountable obstacle between
science and religion, and was available to teach a Sunday School
class or preach a lay sermon. His wife and daughters frequently
accompanied him on collecting expeditions, and to them he im-
parted his love of nature and for nature’s children, the creatures

of the wild.—John S. Garth

PUBLICATIONS OF E. YALE DAWSON

1936. Cactus collecting in mafiana land. Jour. Cactus & Succ. Soc. Amer., 7:
115-117, 139-141.

1941. Binghamia, the alga, versus Binghamia, the cactus. Proc. Nat. Acad. Sci.,
27: 376-381 (with W. A. Setchell).

Field observations on the algae of the Gulf of California. Hancock Pac.
Exped., 3: 115-119.

A review of the genus Rhodymenia with descriptions of new species. Ibid.,
33 12321810

1943. A jeweled memory. Desert Pl. Life, 15 (10): 157.

1944. Review of “Marine algae of the Monterey Peninsula.” J. N.Y. Bot. Gard.,
45: 192.

Binghamia, cactus or seaweed. Desert Pl. Life, 16: 45.
Dorvanthes, Spear Lily. Ibid., 16: 56-68.

The marine algae of the Gulf of California. Hancock Pac. Exped., 3:
189-464.

Japsonia saves for a dry time. Nature Mag., 37: 328.
Botanizing on the desert coast of Sonora. Desert Pl. Life, 16: 69-71.
Botanizing in an open boat. J. N.Y. Bot. Gard., 45: 126-132.

1945.

1946.

1947.

1948.

E. Yale Dawson 153

Army Cactophile. Desert Pl]. Life, 16: 88-89.
A giant xerophilous asclepiad. Ibid., 16: 190-201.
Brushfire. Westways, 36 (10).

A prolific aloe brings hummingbirds. Desert Pl. Life, 16: 124.
New Laurenciae from southern California Madrono, 7: 233-240.

A new parasitic red alga from southern California. Bull. Torrey Bot. Club,
71: 655-657.

Some ethnobotanical notes on the Seri Indians. Desert Pl. Life, 16:
132-138.

Some butterflies of the mountains of Eastern Arizona. Entomol. News,
55: 253-257 (with B. Blevins).

Elephant trees in California. Desert Pl. Life, 17: 20-23.

An annotated list of the marine algae and marine grasses of San Diego
County, California. Occas. Papers San Diego Nat. Hist. Soc., 7: 1-87.
(Reprinted with corrections, May 1952.)

Notes on Pacific Coast marine algae, I. Bull. So. Calif. Acad. Sci. 43:
95-101.

Some new and unreported sublittoral algae from Cedros Island, Mexico.
Ibid., 43: 102-112.

Introduction to Salicornia. Desert Pl. Life, 17: 36-43.
The savage Seris of Sonora. Sci. Monthly, 60: 193-202, 261-268.

Notes on Pacific Coast marine algae, II. Bull. So. Calif. Acad. Sci. 44:
22-27.

Notes on Pacific Coast marine algae, III. Madrono, 8: 93-97.

Marine algae associated with upwelling along the northwestern Coast of
Baja California, Mexico. Bull. So. Calif. Acad. Sci., 44: 57-71.

New and unreported marine algae from southern California and north-
western Mexico. Ibid., 44: 75-91.

A guide to the literature and distributions of the marine algae of the
Pacific Coast of North America. Mem. So. Calif. Acad. Sci., 3: 1-134.

Lista de las algas marinas de la costa pacifica de México. Rey. Soc. Mex.
Hist. Nat., 7: 167-215.

Review of “Brazil, orchid of the tropics.” Amer. Nat., 80: 147.
Observations from Lower California. Desert Pl. Life, 18: 150-151.

Cacti enroute in Mexico, I, II. Ibid., 19: 8-11, 56-58.

New cacti of southern Mexico. Occas. Papers Hancock Found., No. 1: 1-53.

154

Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967
Two new Mammillarias of Puebla and Oaxaca, Mexico. Ibid., No. 2: 57-69
(with R. T. Craig).
Noche de flores. Desert Pl. Life, 20: 26-27.

A new variety of Mammillaria scrippsiana. J. Cactus Succ. Soc. Amer., 20:
126-127 (with R. T. Craig).

Cacti in the herbarium of the Allan Hancock Foundation. Ibid., 20:
147-148.

Review of Echinocereus pacificus (Engelm.) B. and R. Desert Plant Life,
20 (10): 151-159, 7 figs.

1948-49. A naturalist’s diary on the Mexican west coast, I-VI. Ibid., 20 (11-12),

1949.

1950.

OSE

21 (1-4).

Contributions toward a marine flora of the islands off Southern California.
Occas. Papers Hancock Found. No. 8: 1-57.

Studies of northeast Pacific Gracilariaceae. Ibid., No. 9: 1-105.

Resultados preliminares de un reconocimiento de las algas marinas de
la costa pacifica de México. Rev. Soc. Mex. Hist. Nat., 9: 215-255.

A new Echinocereus from Pacific Baja California. Desert Pl. Life, 21:
89-94.

Cactus at the water’s edge. Ibid., 21: 51-52.
Adventures with cacti on the island of Cuba. Ibid., 21: 101-106.

Notes on Pacific Coast marine algae, IV. Amer. J. Bot., 37: 149-158.

Notes on some Pacific Mexican Dictyotaceae. Bull. Torrey Bot. Club., 77:
83-93.

Notes on Pacific Coast marine algae, V. Amer. J. Bot., 37: 337-344.

A review of Ceramium along the Pacific Coast of North America with
special reference to its Mexican representatives. Farlowia, 4: 113-138.

A giant new Codium from Pacific Baja California. Bull. Torrey Bot. Club,
77: 298-300.

A note on the vegetation of a new coastal upwelling area of Baja Calli-
fornia. J. Mar. Res., 9: 65-68.

On the status of the brown alga, Dictyota binghamiae J. G. Agardh.
Wasmann J. Biol., 8: 267-269.

A further study of upwelling and associated vegetation along Pacific
Baja California, Mexico. J. Mar. Res., 10: 39-58.

1950-52. Some results of twenty years of cactus research by Curt Backeberg.

Edited and indexed by E. Y. Dawson. J. Cactus Succ. Soc. Amer., 22:
181-190; 23: 13-20, 45-52, 81-88, 117-124, 149-156, 181-188; 24: 13-22.

1952.

1953.

1954.

E. Yale Dawson 155

Leptocladia—both cactus and alga. Desert Pl. Life, 23: 90.
Contraband. Ibid., 24: 43-46.

Pilocereus polygonus—new to Cuba. Cactus Succ. J. Amer., 24: 46-47
(with H. G. Rush).

Mammillarias of the islands off northwestern Baja California, Mexico.
Ibid., 24: 76-84 (with George Lindsay).

Circulation within Bahia Vizcaino, Baja California, and its effects on the
marine vegetation. Amer. J. Bot., 39: 425-432.

Field observations on some cacti of Oaxaca and Puebla, Mexico. Desert
Pl. Life, 24: 52-58.

Notes on Neobuxbaumia. J. Cactus Succ. Soc. Amer., 24: 167-173.

Marine red algae of Pacific Mexico. Pt. 1. Bangiales to Corallinaceae
subf. Corallinoideae. Hancock Pac. Exped., 17: 1-239.

Oceanographic Institute of Nhatrang, Viet Nam. Science, 118: 3.

On the occurrence of Gracilariopsis in the Atlantic and Caribbean. Bull.
Torrey Bot. Club, 80: 314-316.

Preliminary results of a marine algal reconnaissance of the Pacific Mexi-
can Coast. Seventh Pacific Science Congress, 5: 43-47.

A summary of recent marine algal investigations along Pacific Mexico
with a synopsis of the literature, synonymy and distributions of the
recorded species. Rev. Soc. Mex. Hist. Nat., 13: 97-197.

Notes on Pacific Coast marine algae, VI. Wasmann J. Biol. 11: 323-351.

Marine vegetation in the vicinity of the Institut Océanographique de Nha
Trang, Viet Nam. Pacific Sci., 8: 372-469.

Marine red algae of Pacific Mexico. Pt. 2. Cryptonemiales (cont.). Han-
cock Pac. Exped., 17: 240-398.

Notes on tropical Pacific marine algae. Bull. So. Calif. Acad. Sci., 53: 1-7.

Some distributional patterns represented by the marine algae of Nhatrang
Bay, Viet Nam. pp. 80-81, in Eighth Pacific Science Congress, Abstracts
of Papers. Univ. Philippines Pres, Quezon City.

Cactus oaxacensis in Jalisco. Cactus Succ. J. of Amer., 26: 71-72.

A summary of recent marine algal investigations along Pacific Mexico
with a synopsis of the literature, synonymy and distributions of the re-
corded species. Reprinted 1954 with corrections, index pagination and
addenda from Rev. Soc. Mex. Hist., Nat., 13: 97-197.

The marine flora of Isla San Benedicto following the volcanic eruption
of 1952-53. Hancock Found. Publ., Occ. Papers, No. 16: 1-25.

A monstrose Selenicereus from Cuba. (with H. G. Rush) Cactus Succ.
J. Amer., 26: 180-181.

156

1955.

1957.

1958.

Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967
Line drawings and accompanying text, In, The Seaweed Story, Calif. Fish
and Game, pp. 1-19.

Marine algae from Palmyra Island with special reference to the feeding
habits and toxicology of reef fishes. Hancock Found. Pub., Occ. Paper,
No. 17: 1-39. (with A. A. Aleem and B. W. Halstead).

A preliminary working key to the living species of Dermatolithon. Essays
in the Natural Sciences in honor of Captain Allan Hancock, pp. 271-277.

Univ. Southern California Press.

. Some distribution patterns represented by the marine algae of Nhatrang

Bay, Viet Nam. Eighth Pac. Sci. Congr., Proc., 3: 489-492.

Some marine algae of the southern Marshall Islands. Pacific Sci., 10:
25-66.
How to know the Seaweeds. 198 pp. Wm. C. Brown Co., Dubuque, Iowa.

The marine flora of San Benedicto Island, Mexico, following the volcanic
eruption of 1952-53. VIIIe Congrés International de Botanique, pp. 157-
158. Paris.

The Machris Brazilian Expedition. Botany: General. Los Angeles County
Museum Cont. in Sci. No. 2: 1-20.

An annotated list of marine algae from Eniwetok Atoll. Marshall Islands.
Pacific Sci., 11: 92-132.

The Machris Brazilian Expedition. Botany: Phanerogamae, various
smaller families (edited by E. Yale Dawson). Los Angeles County Mu-
seum Cont. in Sci., No. 7: 1-18.

Notes on eastern Pacific Insular marine algae. Los Angeles County Mu-
seum Cont. in Sci., No. 8: 1-8.

The Machris Brazilian Expedition. Botany: A new columnar cactus from
Goias. Los Angeles County Museum Cont. Sci., No. 10: 1-8.

An arctic Alaskan kelp bed. Arctic, 10: 45-52. (with John L. Mohr and
Norman J. Wilimovsky).

Marine algae of the Pacific Costa Rican gulfs. Los Angeles County Mu-
seum Cont. Sci. No. 15: 1-28.

Benthic marine vegetation (pp. 1-36 in, A preliminary report on the
biology of the Continental Shelf of southern California, submitted to the
California State Water Pollution Control Board by the Allan Hancock
Foundation) multilith.

Notes on Pacific Coast marine algae, VII. Bull. So. Calif. Acad. Sci., 57:
65-80.

A new gigartinoid Grateloupia (red alga) from Hawaii. Pacific Nat., 1 (1):
1-5, 1 pl.

1959.

1960.

1961.

E. Yale Dawson 157

Marine algae from the 1958 cruise of the Stella Polaris in the Gulf of
California. Los Angeles Co. Mus. Contr. Sci., No. 27: 1-39.

Changes in Palmyra Atoll and its vegetation through the activities of Man,
1913-1958. Pacific Nat., 1(2): 1-52.

William H. Harvey’s report on the marine algae of the United States north
Pacific Exploring Expedition of 1853-56 (edited). Pacific Nat. 1(5): 1-40.
Some marine algae from Canton Atoll. Atoll Res. Bull., No. 65:1-6.

Some algae from Clipperton Island and the Danger Islands. Pacific Nat.,
1(7): 1-8.

A primary report on the benthic marine flora of southern California (pp.
169-264 in, Oceanographic survey of the continental shelf area of southern
California, submitted to the California State Water Pollution Control
Board by the Allan Hancock Foundation) multilith.

Field notes from the 1959 eastern Pacific Cruise of the Stella Polaris.
Pacific Nat., 1 (13): 1-24, 16 figs. (with P. T. Beaudette).

Seaweeds associated with kelp beds along southern California and north-
western Mexico. Pacific Nat., 1 (14): 1-81. 43 pls. (with M. Neushul and
R. D. Wildman).

Production of antibacterial substances by benthic tropical marine algae.
J. Bacteriology, 79: 459-460. (with Mary Belle Allen).

New records of sublittoral marine plants from Pacific Baja California.
Pacific Nat., 1(19): 1-30. (with M. Neushul and R. D. Wildman).

New records of marine algae from Mexico and Central America. Pacific

Nat., 1(20): 31-52.

Marine red algae of Pacific Mexico. Part III. Cryptonemiales, Corallin-
aceae subf. Melobesioideae. Pacific Nat., 2: 1-126.

Marine botanist in El Salvador. Beaudette Found. News Letter October,
1960: 6-8.

Lead photograph, in, I. Mackenzie Lamb, Complex Primitives: The red
Alga group. Natural History, 69(3): 16-17.

The status of marine botanical exploration along North Pacific Latin
America. Beaudette Found. News Letter, Jan. 1961: 6-12.

A review of the ecology, distributions, and affinities of the benthic flora of
Baja California and vicinity. Systematic Zool., 9: 93-100.

Marine red algae of Pacific Mexico. Part IV. Gigartinales. Pacific Nat.,
2: 189-343.

A guide to the literature and distributions of Pacific benthic algae from
Alaska to the Galapagos Islands. Pacific Sci., 15: 370-461.

Rim of the Reef. Natural Hist., 70: 8-17, ill.

Plantas marinas de la zona de las mareas de El Salvador. Pacific Nat.,

2(8): 388-461.

158

1962.

1963.

Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

A new Gracilariopsis from Southern California. Bull. Res. Council Israel,
Botany 10D: 34-36.

Marine red algae of Pacific Mexico. Part VII. Ceramiales. Hancock Pac.
Exped., 26: 1-208.

Un clave ilustrada de las algas marinas de la costa Pacifica de America
Central. Pacific Nat., 3: 167-231.

On the supply of teaching materials for marine biology classes. Beaudette
Found. News Letter Jan. 1962: 6-8.

New taxa of benthic Red, Green and Brown algae published since De Toni
1889, 1895, 1924, respectively, as compiled from the Dawson algal library.

Contribution from the Beaudette Foundation. 105 pp. (mimeographed).

The Darwin Research Station on the Galapagos Islands. Beaudette Foun-
dation. News Letter, April 1962: 5-7.

Cacti of the Galapagos Islands and of Coastal Ecuador. Cactus Succ. J. 34:
67-74: (4) 99-105.

Benthic marine exploration of Bahia de San Quintin, Baja California,
1960-61. Marine and marsh vegetation. Pacific Nat., 3: 275-280.

On the recognition of a second species of the genus Pelagophycus. Bull.
~», Calif. Acad. Sci., 61: 153-160.

The giants of Galapagos. Natural History, 71: 52-57.

Additions to the marine flora of Nicaragua and Costa Rica. Pac. Nat., 3:
375-395.

The Machris Brazilian Expedition. Botany: Various families, (coordinated
by E. Y. Dawson). Los Angeles Co. Mus. Contr. Sci., No. 63: 1-9.

How to know the cacti. Wm. Brown Co., Dubuque, Iowa. 158 pp.

Marine red algae of Pacific Mexico. Part VI. Rhodymeniales. Nova
Hedwigia, 5: 437-476.

Rim of the Reef (revised). Smithsonian Report for 1962: 365-373.

Directory of instructional programs and facilities for the marine sciences
on the Pacific coast, summer 1963, edition. 20 pp. privately printed Jan.
27, 1963, Solvang, Calif.

Additional note on Jasminocereus howellii. J. Cactus Succ. Soc. Amer.
35:42.

Observations and experiments on the food habits of California sea hares
of the genus Aplysia. Pacific Sci., 17: 102-105.

Revision of the genus Neodawsonia by Helia Bravo H. & T. H. Mac-
Dougall, translated and annotated by E. Y. Dawson from Anales del
Instituto de Biologia 29(2): 73-87, J. Cactus Succ. Soc. Amer., 35: 107-116.

Ecological paradox of Coastal Peru. Natural History, Oct. 1963: 32-37.

1964.

1965.

1966.

E. Yale Dawson 159
New records of marine algae from the Galapagos Islands. Pacific Nat., 4:
1-23.

Marine Red algae of Pacific Mexico, Part 8. Ceramiales, Dasyaceae,
Rhodomelaceae. Nova Hedwigia, 6: 401-481.

A review of Yendo’s jointed coralline algae of Port Renfrew, Vancouver

Island. Nova Hedwigia, 7: 537-543.

The seaweeds of Peru. Nova Hedwigia, 13: 1-111. (with C. Acleto and
N. Foldvick).

Botanical Guide to the fabulous San Diego Zoo. 16 pp. San Diego.

The structure and reproduction of the red alga Chondria nidifica Harvey.
Trans. San Diego Soc. Nat. Hist., 13: 286-299. (with Bilgin Tozun.)

Note on variability and range in the elk kelp Pelagophycus. Trans. San
Diego So. Nat. Hist., 13: 393-307. (with B. C. Parker.)

An eastern Pacific member of Yamadaia (Corallinaceae) from the San
Juan Islands, Washington. Nova Hedwigia, 8: 1-4. (with R .L. Steele.)

Seaweed drift on Torrey Pines Beach, pp. 28-29, in Torrey Pines State
Reserve, ed. T. Whitaker. La Jolla, Calif.

Further studies of Opuntia in the Galapagos Archipelago. Cactus Succ.
J. 37(5): 135-148.

Marine algae in the vicinity of Humboldt State College, Humboldt County,
California. 76 pp. Humboldt State College, Arcata, Calif.

An undescribed Melocactus? in the Galapagos Islands. Cactus Succ. J., 37:
126.

Non-calcareous marine algae from California Miocene deposits. Nova

Hedwigia, 10: 273-295. (with B. C. Parker.)

Naturally—in the Santa Ynez Valley (Valley Oak). April in the beautiful
Santa Ynez Valley 1(1): 16.

Naturally—in the Santa Ynez Valley (Miocene seaweeds). May in the
beautiful Santa Ynez Valley 1(2): 6-7.

Naturally—in the Santa Ynez Valley (California condor). Ibid., in the
beautiful Santa Ynez Valley 1(4): 11.

Naturally—in the Santa Ynez Valley (Pacific Terrapin). Ibid., 1(5): 23.

Naturally—in the Santa Ynez Valley (yellow-billed magpie). Ibid.,
1(7): 8.

Naturally—in the Santa Ynez Valley (Chaparral fire plants). Ibid.,
1(8): 6.

Naturally—in the Santa Ynez Valley (Ramalina reticulata). Ibid.,
1(9): 29.

Time of my life, part 1. Cactus Succ. J. 38: 15-18.

160 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Naturally—in the Santa Ynez Valley (opossum). January in the beauti-
ful Santa Ynez Valley, 1(10): 29.

Naturally—in the Santa Ynez Valley (Deer Tick). Ibid., 1(11): 30.
Chapt. VIII and Table IX, Intertidal Algae, in An Oceanographic and
biological survey of the southern California mainland shelf. State of
California Water Quality Control Board Publ. 27.

The Cacti of California. 80 pp. Univ. California Press.

Marine Botany, an introduction. 371 pp. Holt, Rinehart & Winston, Inc.
Seashore plants of southern California. Univ. Calif. Press. 96 pp.
(Posthumous. )

Seashore plants of northern California. Univ. Calif. Press. 96 pp.
(Posthumous. )

Marine Algae in the vicinity of Puerto Penasco, Sonora, Mexico. Gulf of
California Field Guide Series No. 1. Univ. Ariz., 57 pp. (Posthumous.)
New Records of Marine Algae from Anacapa Island, California. Nova
Hedwigia. 12: 173-187. (with M. Neushul) (Posthumous.)

New Records of Marine Algae from the Gulf of California. Arizona Acad..
Sci. J., 4: 55-56. (Posthumous. )

In Press. Cacti in the Galapagos Islands, with special reference to their relations
with tortoises.

Living Snow of the Andes. Natural History.

STUDIES IN THE FOLIOSE RED ALGAE OF THE PACIFIC
COAST II.

Schizymenia

IsaABELLA A. Aspott!

Hopkins Marine Station, Stanford University, Pacific Grove, California

INTRODUCTION

Schizymenia (Nemastomaceae, Gigartinales) contains few, but
poorly understood species with respect to internal vegetative struc-
ture, and reproductive morphology. In broadest terms, and assum-
ing that the criteria used by Kylin (1956) are definitive, the genus
may be circumscribed as follows: blade-like thalli which possess
gland cells in the cortex, produce carpospores toward the exterior
of the thallus, i.e., the base of the cystocarp lies deep in the medulla,
and nearly all cells of the cystocarp become carpospores. All of the
species in this paper conform to these criteria. Other characters
can also be used 1) there are only weakly developed (or none)
sterile filaments around the cystocarp, and 2) a weakly defined pore
(carpostome) above the slightly raised carpospore mass. The shape
and size of the blades, and their internal vegetative structure may
serve to distinguish species.

This paper is one of three which seeks to clarify the status of
various foliose red algae of the Pacific coast (the Cryptonemiaceae
have been submitted for publication and the folicse Dumontiaceae
and Kallymeniaceae are in preparation).

There are now three species of Schizymenia reported for the
Pacific coast of North America: Schizymenia coccinea Harvey
(1862) from the San Juan archipelago, Washington; Schizymenia
pacifica (Kylin) Kylin (1932), whose type locality is Friday Har-
bor (San Juan archipelago) Washington; and S. epiphytica

1Grateful acknowledgment is made to the US-Japan Cooperative Science Pro-
gram (Grant No. GF-219) for financial support which permitted comparison
of eastern and western Pacific specimens and to the Office of Naval Research,
Contract N 00014-67-A-0112-0022. I wish to thank the curators of the Farlow
Herbarium of Harvard University; the University of Washington, the Uni-
versity of California (Berkeley), the California Academy of Sciences and the
Hancock herbarium of the University of Southern California for the con-
tinued loan of specimens. Thanks are also due Emeritus Professors Yukio
Yamada and Jun Tokida of Hokkaido University for their kindness in making
Japanese specimens available to me. The continuing interest of and repeated
collections sent to me by my colleagues Maxwell S. Doty, Richard E. Norris,
Michael Neushul, and Wheeler J. North are especially appreciated.

161

162 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

(Setchell and Lawson) Smith and Hollenberg (1943) from the
region of Monterey, California. S. coccinea has been transferred
(Abbott, 1967, in press) to Halymenia; S. epiphytica should be
included in this genus with question as both the female and asexual
reproductive structures are aberrant for this genus. The entity
known for a long time in Japan as Schizymenia dubyi is included
within the circumscription of S. pacifica, thus extending the distri-
bution of this variable species not only well into the upper Gulf
of California on the eastern side of the Pacific but also on both
the Japan Sea and Pacific Ocean sides of Japan to Kyushu.

Two new species, S. dawsonit and S. borealis are added, and a
transfer is made from Aeodes, giving a total of five species for the
Pacific coast.

Key to the Species

1. Thalli nearly circular, up to 2 meters in diameter ........ QD
1 halls broadly lanceolate! to.coxndate. 44. c. 5 see eee 3
2. Blade fleshy, about 1 mm thick, medulla up to

1OFtimes tthe thickness of thexcontexe | es eee S. borealis
2. Blade thin, less than 0.5 mm thick, medulla

twice the*thickmess of the cortex. >...) 526. oe S. ecuadoreana

3. Thalli common intertidal, although occurring
subtidally, purplish to brownish to

orange-red int Colom 24-3. ee S. pacifica
3. Vhalli subtidal:only 2.030022... 0 4 on eee 4:
4. Surface of thallus rough, wrinkled, or puckered;

NWAlulayZ Old ALE wLe ica Sioa Cala eee eee gee S. epiphytica

4. Surface of thallus smooth, almost waxy, blades
broadly cordate, with cruciate tetrasporangia ..... S. dawsonii

Schizymenia pacifica (Kylin) Kylin (Figs. 1-3).

Kylin 1932, p. 10. Basionym: Turnerella pacifica Kylin, 1925,
Oa al, Janes. 14

Schizymenia pacifica Kylin. Smith, 1944, p. 258, pl. 60, Fig. 4;
pl. 61, Fig. 1. Doty, 1947, p. 176. Dawson, 1961, p. 199, pl. 3,
lainey, 1/8 jolla

Schizymenia dubyi of Harvey, 1862, p. 174. S. dubyi of Yamada,
1928, p. 532, Fig. 24. Okamura, 1933, p. 10, pl. 307, Figs. 1-6;
pl. 308, Fig. 12. Nagai, 1941, p. 177; Tokida 1954 p. 171;

Studies on Schizymenia 163

Figures 1-3. Schizymenia pacifica. 1. Two thalli showing differences in habit
due to differing environment, the one in front being from an exposed area, the
other from a relatively calm area. x 1/6 natural size. 2. Transverse section of
a young blade showing cellular structure of cortex and medulla, gland cells
and tetrasporangia. 3. Transverse section of a specimen from Maizuru (Central
Japan). This figure should be compared with fig. 4, plate 60 in Smith (1944).
Both show characteristic vegetative structure of older thalli.

Figure 4. Opuntiella californica. Transverse section to show differences in form
and arrangement of medullary and cortical tissues as well as shape of gland
cells between this genus and Schizymenia.

164 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Tokida and Masaki, 1959, p. 87, Figs. 1-9. Non S. dubyi (Chau-
vin) J. Agardh of Europe.

Sarcophyllis californica of Setchell and Gardner, 1903, p. 354.
Non S. californica J. Agardh. (But not S. californica of Setchell
and Gardner, Phycotheca Boreali-Americana 395 in Herb.
G. M. Smith which is a species of Jridaea.)

Thalli annual, growing in groups, usually saxicolous; up to 70 cm
tall, but mostly 25-30 cm tall by 15-30 cm wide, brownish red
(Rocellin purple—Ridgway?—in young thalli, to Neutral Red and
Dark Indian Red—Ridgway—in older thalli); if epiphytic (on
Cystoseira) orange-red (Indian Red to Haematite Red—Ridgway ).
Blades slippery to touch especially when young, appearing like
tanned leather when adult and dried. Blades ovate-lanceolate when
young, becoming broad-lanceolate, or more commonly cordate, pro-
vided with a small fleshy holdfast and with or without a stipe.
Margins entire especially when young, or subtidal specimens and
those from calm situations sometimes falcate and margins slightly
undulate; those from exposed areas deeply split and usually with
irregular margins.

Thalli 250-400 , in cross-section, with a filamentous cortex
30-90 ». wide on each side; 6-15 cells wide, cells of the outer cortex
deeply pigmented, sometimes the outermost 4-5 of them arranged
in very straight rows; inner cortical cells colorless, highly granular;
medulla of predominantly periclinal filaments of nearly uniform
width, and a few anticlinal filaments. Obovate or pyriform gland
cells, 10-20 » in diameter, prominent in fresh material, difficult
to see in dried material unless stained. Both the diameter of the
cross section and number of medullary filaments present vary in
relation to age of the thallus, 1.e., thalli with mature tetrasporangia
or carpospores are thicker than those without mature reproductive
elements.

Tetrasporangia 30 x 50 », cruciately divided (occasionally irreg-
ularly divided), scattered over the surface of the thallus except in
basal portions. Cystocarps small, about 200 » in diameter, raising
the cortex only slightly, numerous, scattered over the surface in
small clusters, giving the fertile blade a roughness like fine sand-
paper. Cystocarps in section 150-180 » in diameter with several

?R. Ridgway (1912), Color Standards and Color Nomenclature. Published by
the Author, Washington, D.C. contains 53 colored plates and 1115 named colors,
and is a standard color reference used by zoologists and mycologists.

Studies on Schizymenia 105

gonimolobes, maturing in sequence. Carpospores 30-45 x 15-20 p,
arranged in tightly adpressed groups, discharging through an un-
modified carpostome. No sterile tissue surrounding the carpospore
mass. Spermatangia 4-5 », diam., formed superficially and covering
the thallus surface, giving it a lighter color.

Distribution: In the western portion of its range, on both the
Japan Sea and Pacific Ocean sides of Japan from Fukuoka pref.
(Kyushu Island) to the Okhotsk Sea and Pacific sides of Hokkaido;
Saghalien; Kuriles; the Aleutian Islands; Alaska; British Colum-
bia; Vancouver Island, the San Juan archipelago (Friday Harbor,
the type locality) common in Oregon; scarce in northern and
southern California but very common in central California; mostly
subtidal from the Pacific side of Baja California, into the upper
Gulf of California (Angel de la Guarda Island).

Although tetrasporangia were described and figured for the Japa-
nese Schizymenia dubyi by Okamura (1933, pl. 10; pl. 307, Fig. 3),
and described by Smith (1944, p. 258) for S. pacifica, and re-
described for the Japanese specimens by Tokida and Masaki (1959),
they are still unknown (Gayral, 1966) in the European S. dubyi,
except for the figure of Newton (1931) in which they are shown
to be zonately divided. Tetrasporophytes are as common as cysto-
carpic thalli in S. pacifica.

The eastern and western Pacific populations of S. pacifica differ
very little from each other in internal vegetative and reproductive
morphology, and the whole range of external characters may be
seen in each of them. The North American specimens may be taller
and larger thalli but this comparison may be possible only because
there is a larger number of specimens in the western herbaria than
in the eastern ones. In fact, in Central California it would be diffi-
cult to collect at any rocky point without encountering specimens
of this species, where as they were rarely seen in my field trips
in Japan.*

In central California, S. pacifica occurs from the lower midtidal
level to 60 ft. subtidally. Except for the simple blades of the subtidal
specimens, no other constant differences have been observed be-
tween them and the intertidal specimens, which are commonly
dissected.

The features which distinguish S. pacifica from other foliose red

3Specimens which I have examined from the Herbaria cited in the acknowledg-

ments are annotated by me, and should be referred to when critically studying
these species.

166 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

algae are the commonly brownish-red color and fleshiness of ma-
ture thalli, and in section, the gland cells, the random occurrence
of periclinal and anticlinal medullary filaments and the very large
size of carpospores (twice or more larger in size than those of
Halymenia species, for example).

Schizymenia epiphytica (Setchell and Lawson) Smith and Hollen-
berg (Fig. 9). Smith and Hollenberg, 1943, p. 221, Figs. 28-30.
Smith, 1944, p. 258, pl. 60, Figs. 2-3. Basionym: Peyssoneliopsis
epiphytica Setchell and Lawson in Setchell 1905, p. 63.

Thalli up to 40 cm tall, orbicular in shape, from a small fleshy
holdfast, usually estipitate, reddish-blue in color when fresh, drying
to blackish, never sticking to paper. Blades usually occurring singly,
but sometimes several attached together; margins with a crisp, -
raised edge especially in older thalli. Older thalli also frequently
harsh to touch, and wrinkled. Gland cells ellipsoidal when young,
becoming globose 45-125 » diam. when older.

Cross-section 150-300 », cortex 25-35 wu thick on each side, with
relatively few medullary filaments. Tetrasporangia arranged in
nemathecia near the outer margins of the blade, tetrasporangia
zonately divided, 10-14 » by 50-60 ». Tetrasporangia said to arise
from auxiliary cell (making this a species with a short-cycle life
history and no free-living tetrasporophytes).

Distribution: Subtidally near Whidbey Island, Washington;
from —1.0 ft. tide level to 80-100 ft. depth in the region of Carmel,
California; cast ashore at San Simeon, California; at 100 ft. depth
off Punta Santo Tomas in northern Pacific Mexico. Frequently
cast ashore near Pacific Grove, California (type locality).

Peyssoneliopsis epiphytica is a name attached to the nemathecia
easily seen in adult blades of what is now called Schizymenia
epiphytica. Although Smith and Hollenberg (1943) indicate a
connection between a presumed auxiliary cell and the nemathecia
bearing zonately divided tetrasporangia, the evidence is not con-
clusive that the connection is direct. In discussing the anomalous
life cycle thus implied, they indicated some dissatisfaction and
raised the question of the possibility of this being a species of
Opuntiella (a genus having zonate tetrasporangia and gland cells;
see Fig. 4), but decided in favor of Schizymenia. My own examina-
tions of this species have not given a further clue as to the relation-
ship of this species. Until further definitive studies are made, it

Studies on Schizymenia 167

Figures 5-6. Schizymenia dawsonii. Fig. 5. Habit of tetrasporangial thallus
(top); spermatangial thallus (left) and cystocarpic thallus (right). x 1/3 natural
size. Fig. 6. Transverse section showing cortical and medullary layers. Note sec-
retory cells on some of the filaments.

168 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

seems best to leave S. epiphytica in Schizymenia although noting
that it has characteristics not in keeping with the remaining species.

Schizymenia dawsonil sp. nov.
(Figures 5-6)
Thallus laminiformis, usque ad 30 p alt., usque ad 25 cm. lat.,
cordatus, caeruleo-roseus. Stipes 2-5 mm alt., 2-3 mm lat. Plantae
cystocarpicae simplices, plantae tetrasporicae semel fissae (c. 2/3
altitudinis thalli); plantae spermatangiales profunde bis-ter fissae
(c. 7% altitudinis thalli). Margines leves ad crispos.

Sectiones 250-300 ». diam., medulla 5-8 plo areas corticales occu-
pans. Cortex bene definitus, e 5-6 ordinibus cellularum arcte con-
tiguarum constans. Medulla e filamentis periclinalibus laxe ordi-
natis, omni 4-6 , lat., irregulariter ordinato, composita. Glandicel-
lulae inconspicuae, 4 x 8-12 4. Cystocarpi vix emergentes, 200-400 p
lat. per aliquote filamenta sterilia circumdati, et ostiolum parvum
habentes. Spermatangia 2-3 », omnino superficialia, in maculis
latis in sperficie thalli sita. Tetrasporangia sparsa, 28-36 x 36 pu
cruciate divisa.

Locus typi: in littore loci Punto Santo Tomas, Pacific Mexico
dicti, 27-33 metrorum profunde subter mari colens, a Wheeler J.
North, m. Dec. d. 26, 1964 lectus.

Thallus blade-like, up to 30 cm high, up to 25 cm broad, cordate,
of a bluish-rose (Dahlia Carmine—Ridgway ). Stipe 2-5 mm high,
2-3 mm wide. Cystocarpic plants simple, tetrasporic plants cleft
once (about 2/3 of the thallus height); spermatangial plants cleft
deeply 2-3 times (about 7% of the thallus height). Margins smooth
to crisp.

Sections 250-300 » in thickness, the medulla occupying 5-8 times
the cortical areas. Cortex well-defined, of 5-6 rows of closely packed
cells, the inner ones sometimes star-shaped. Medulla of loosely ar-
ranged mostly periclinal filaments, each 4-6 » wide, showing no
particular arrangement. Gland cells inconspicuous, 4 x 8-12 , in
the outer cortex. Cystocarps barely emergent, 200-400 » in width
(wider than tall), surrounded by a few sterile filaments, and with
a small carpostome. Spermatangia 2-3 ., wholly superficial, in wide
patches on the thallus surface. Tetrasporangia scattered, 28-36 x
36 p, cruciately divided.

Type specimen: Abbott 3260 (cystocarpic) in Herb. G. M. Smith;
isotypes in herbaria of Wheeler North, Maxwell S. Doty, Uni-
versity of California (Berkeley), Smithsonian Institution; collected

Studies on Schizymenia 169

off Punta Santo Tomas, Pacific Mexico in 27-33 meters by Wheeler
J. North, December 26, 1964. Other specimens: off Bird Rock, La
Jolla (San Diego County, California) in 41 meters; off Imperial
Beach, (San Diego County, California) in about 10 meters; off
Papalote Bay, Pacific Mexico in 33 meters. All collected by Wheeler
J. North.

Schizymenia dawsonii shows two features which no other species
of Schizymenia demonstrates: 1) a broad, well-defined cordate blade
and 2) tetrasporophytes whose cordate blades are deeply cleft once
and spermatangial thalli deeply cleft 2 or 3 times. These features
also distinguish this species from all other foliose red algae on the
Pacific coast. In color, the blades are most like those of Halymenia
californica, but the shape of the blades differ as do the reproductive
and vegetative structures.

Schizymenia dawsonii is named in honor and dedicated to the
memory of Elmer Yale Dawson (1918-1966) whose studies on
Pacific coast algae are testimony of our indebtedness to him.

Schizymenia borealis sp. nov.
(Figures 7-8)

Thallus membranaceus succulentusque, basi cordata, cum aut sine
stipite, lamina matura latissime undulata corrugataque, fusco-
brunneo-rubra. Laminae iuvenes duplo longiores quam latae, ma-
turae, et in sitibus subaestualibus usque ad 2 m. diam. Sectiones
980-1200 » diam., medulla usque ad 10 plo diam. regionum corti-
calium. Cortex exterior e 6-7 ordinibus cellularum compositus,
stratis 1-2 interioribus ad medullam arcte stipatam abruptius term1-
nantibus. Glandicellulae inconspicuae, in sectionibus tinctis optime
visae, 25 x 9-12 » (usque, autem, ad 25 1 long.).

Cystocarpi 150-200 » diam. superficieum thalli vix elevantes,
filamentis sterilibus in basi paucissimus. Carposporae arcte appres-
sae. Carpostomium ut porus parum mutatus visum. Spermatangia
non visa. Tetrasporangia 40-80 x 20-30 1, irregularieter cruciate ad
irregulariter zonate divisa, super thallum sparsa.

Locus typi. in littore loci Blakely Island, San Juan Archipelago,
Washington dicti, 13 metrorum in altiudine subter mari colens.
A Michael Neushul, m. Sept. d. 20, 1962 lectus.

Thallus saxicolous, membranous, fleshy, the base cordate, with
or without a stipe, the mature blade very broadly undulate and
ruffled, dark brownish red in color. When young, blades twice as
long as broad, when mature and in subtidal situations as large as

170 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Figures 7-8. Schizymenia borealis. Fig. 7. Habit of a portion of a thallus (torn
at left), which measured 1.8 meters in diameter, showing also a basal portion
(lower right) also torn away from thallus. x 1/6 natural size. Fig. 8. Transverse
section showing relationship of medullary and cortical tissues, the latter with
gland cells and irregularly divided tetrasporangia.

2 meters in diameter. Sections 980-1200 » in thickness, the medulla
up to 10 times the thickness of the cortical regions. Outer cortex
of 6-7 rows of cells, the inner 1-2 layers terminating rather abruptly
to a tightly packed medulla. Gland cells inconspicuous, best seen
in stained sections, 25 x 9-12 » (but up to 25 » long).

Cystocarps 150-200 » in diameter, scarcely raising the thallus
surface, with very few sterile filaments at the base. Carpospores
closely appressed. Carpostome a small little-modified pore. Sperma-
tangia not seen. Tetrasporangia 40-80 x 20-30 », irregularly cruci-
ately to irregularly zonately divided; scattered over the thallus.

Type specimen: Abbott 3253, cystocarpic, in G. M. Smith her-
barium collected off Blakely Island, San Juan Archipelago, Wash-
ington in 13 meters by Michael Neushul, Sept. 20, 1962. Other

Studies on Schizymenia 171

specimens from the same area, and from Table Island, San Juan
Island, and cast ashore on the west coast of Whidbey Island, Wash-
ington (University of Washington herbarium; University of Cali-
fornia, Berkeley; G. M. Smith herbarium; University of California,
Santa Barbara).

With a diameter of up to 2 meters, Schizymenia borealis is one
of the largest red algae recorded. While meeting the requirements
set out by Kylin (1956) for the genus, this species is not entirely
similar to other species in this genus in the structure of the cortex.
The outer cortical layer (of 6-7 rows of cells) terminates in loosely
branched filaments, as opposed to rather compact, closely branched
cell rows seen in other species. In this character, S. borealis 1s more
like older thalli of Halymenia californica. The general aspect of this
outer cortex may be termed as untidy since all the ultimate cells
do not reach a given level but are uneven in their growth, whereas
other species can be characterized as having neat ultimate cells, all
of them reaching a given level.

When young, the thalli are broadly lanceolate with a nearly
square base arising from a short, slender stipe which is apparently
lost as it is not seen in older specimens. The thalli are apparently
cast loose and float subtidally for some time in the quieter portions
of Puget Sound. (Neushul, personal communication). In the
Monterey Peninsula area, other foliose red algae which have be-
come loose from the substratum have been tagged and are known
to grow appreciably for several months while floating.

This species is named for its northern occurrence.

Schizymenia ecuadoreana (Taylor) Abbott, comb. nov.
(Figures 10-11)
Basionym: Aeodes ecuadoreana Taylor, 1945, p. 202.

Thalli from a small holdfast to 75 cm tall, or more, and about as
broad, rose red (Light Corinthian red—Ridgway) when dry, thin,
but fleshy in texture, the margin undulate, slightly sinuate to
deeply ruffled, and with broad indefinite lobes.

Sections 90-150 , in thickness, with a narrow cortex of 4-5 rows
of cells; medulla with a few refractive cells in the periclinally di-
rected filaments. Gland cells few, 5-9 « in diameter. Cystocarps
150-250 » in diameter, noticeably bulging out the thallus, with a
small carpostome; carpospores 18 x 30 » in tight clusters. Few
sterile filaments around the cystocarp.

172 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967
fig. 10

SSS QS |

Figure 9. Schizymenia epiphytica. Transverse section to show similarities and
differences in construction between this and other species.

Figure 10. Schizymenia ecuadoreana. Habit of a portion of a thallus, the re-
mainder torn away. Although possibly as large as S. borealis, this is a much
thinner and more delicate blade. x 1/5 natural size.

Figure 11. Schizymenia ecuadoreana. Transverse section of cystocarp, repre-
sentative of all cystocarps of Schizymenia, showing large, flattened carpospores
arranged in gonimolobes of varying stages of maturation.

Studies on Schizymenia 173

Distribution: Galapagos Archipelago: dredged off Post Office Bay,
Isla Santa Maria; off Cartago Bay, Albermarle Is. (in Herb. AHF
59965 as Halymenia sp., det. W. R. Taylor).

Schizymenia ecuadoreana seems to be of the dimensions of
S. borealis, also a subtidal species. It differs by having thinner, more
delicate blades, by the compactness of the cortex, and the few
medullary filaments some of the cells of which are highly refrac-
tive (a feature characteristic of Cryptonemia species). This species
does not resemble in structure either Aeodes nitidissima J. Agardh,
the type species of Aeodes from New Zealand, nor Aeodes gardneri
Kylin from the Friday Harbor area. S. ecwadoreana lacks anticlinal
medullary filaments characteristic of Halymenia and has the fe-
male reproductive structures of the Nemastomaceae.

LITERATURE CITED

DAWSON, E. Y.
1961. Marine red algae of Pacific Mexico, Part IV. Gigartinales. Pacific Nat. 2:
191-341.

DOTY, M. S.
1947. The marine algae of Oregon, Part II. Rhodophyta. Farlowia 3: 159-215.

GAYRAL, PAULETTE
1966. Les algues des cotes Francaises. 632 pp. Deren et Cie. Paris.

HARVEY, W. H.
1862. Notice of collection of algae made on the Northwest coast of North
America ... Linn. Soc. (Bot.) J. 6: 157-177.

KYLIN, H.

1925. The marine red algae in the vicinity of the biological station at Friday
Harbor, Wash. Lunds Univ. Arsskr., N. F. 21: 1-87. 47 figures.

1932. Die Florideenordnung Gigartinales. Lunds Univ. Arsskr., N. F. 28: 1-88.

1956. Die Gattungen der Rhodophyceen. Lund: CWK Gleerups. xv + 673 pp.

NAGAT, M.
1941. Marine algae of the Kurile Islands II. Hokk. Imp. Univ. Fac. Agri Pap. 46:
139-310.

NEWTON, LILY
1931. A handbook of the British Seaweeds. Brit. Museum (N. H.) London.
478 pp.

OKAMURA, K.
1933. Icones of Japanese Algae. Author, Tokyo, 7: 1-116.

SETCHELL, W. A.
1905. Parasitic Florideae of California. Nuova Notarisia, 16: 59-63.

174. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

SETCHELL, W. A. AND N. L. GARDNER
1903. Algae of Northwestern America. Uniy. Calif. Publ. Bot., 1: 165-418.

SMITH, G. M.
1944. Marine Algae of the Monterey Peninsula, California. Stanford: Stanford
Univ. Press. vii + 622 pp.

SMITH, G. M. AND G. J. HOLLENBERG
1943. On some Rhodophyceae from the Monterey Peninsula, California. Amer.
J. Bot. 30: 211-222.

TAYLOR, W. R.
1945. Pacific marine algae of the Allan Hancock Expeditions to the Galapagos
Islands. Allan Hancock Pacific Exped., 12: 1-528.

TOKIDA, J.
1954. Marine algae of southern Saghalien. Hokkaido Univ. Fac. Fish. Mem. 2:
1-264.

TOKIDA, J. AND T. MASAKI

1959. Studies on the reproductive organs of red algae. III. On the structure and
development of female organs in Schizymenia dubyi, Gymnogongrus
flabelliformis, and Rhodymenia pertusa. Hokkaido Univ. Fac. Fish., Bull.
10: 87-96.

YAMADA, Y.
1928. Marine algae of Mutsu Bay and Adjacent Waters II. Sci. Rept. Tohoku
Imp. Univ., ser. 4 (Biol.). 3: 497-534.

CONTRAST BETWEEN THE
PIONEER POPULATING PROCESS
ON LAND AND SHORE?

MAxwe.zt S. Dory

Botany Department, University of Hawaii, Honolulu, Hawai

INTRODUCTION

The east rift of the volcano, Kilauea, (Fig. 1) on the Island of
Hawaii erupted in 1955 and sent streams of lava into the sea. As the
lava fields cooled and the pioneer communities became established
on them, an opportunity thus was provided both to record these
pioneer events as they took place and to experimentally test various
hypotheses. The purpose of the present article is to present some of
the results of this observation and experimentation and some of the
inferences drawn.

The oldest prehistoric lava rock lands and shores of Hawaii bear
slow-to-change populations that are nearly in equilibrium with the
environment. For the present work, such populations are considered
to represent climax communities, and the present work is conceived
primarily as a study of the initial events leading toward such climax
communities. The first populants to appear on a new surface are
designated pioneer colonizers and, if through ecesis they form an
enduring community, they are accepted as having formed, thus on
the new surface, pioneer communities.

Most studies of the pioneer population process on lava have been
concerned with the rate in reference to the type of surface, ash, a’a
or pahoehoe (e.g., Forbes, 1912; Wentworth, 1938; Egeler, 1941,
1963; Tagawa, 1963; Skottsberg, 1930, 1941; Robyns & Lamb,
1939), the collection of dust or debris (Forbes, 1912; Eggler, 1941),
moisture (Robyns & Lamb, 1939; Eggler, 1963), the availability of
disseminules (Griggs, 1933; Rigg, 1914; Eggler, 1963; Tagawa,
1966), or nitrogen (Griggs, 1933; Tezuka, 1961; Eggler, 1963). It
is well known (e.g., Tagawa, 1965) that as seral progression takes
place a species first increases and then decreases in abundance. Also
the idea is widely held (e.g., Whitford, 1949; Tagawa, 1965) that
order, non-random distribution, contagiousness or overdispersion,

1Financial support for this work has come largely from NSF grant G-1992 and
AEC contract AT (04-3) -235.

175

176 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

tends to appear out of the at first random distribution of the ele-
ments in a population.

Factors in population development on new lava surfaces that have
not been studied much are age of the lava; its inherent physical or
chemical nature, heat and stability. Actually the above authors and
biological studies of others on lava surfaces have been almost en-
tirely concerned with events on land related timewise to scores
of years.

There are few studies of the above-mentioned phenomena begin-
ning with the still hot lava flows and covering their first few years.
Such studies are especially rare for marine sites. While Martin
(1913) and Rigg (1914) did consider the marine environment,
they described only the destruction of vegetations by the volcanic
events. The late Dr. E. Yale Dawson was one of the first to compare
the marine vegetations appearing on new lava with the mature
vegetations and, also, with the vegetations on old lava denuded by
the volcanic events. This he did some nine months after the erup-
tion at San Benedicto Island in the Revillagigedo Islands at 20 deg.
North Latitude, off the west coast of Mexico.

The results of four sets of observations or experiments are con-
sidered here. They were begun on the 1955 Hawaiian lava flows as
they cooled. Two sets are from the intertidal region and are paired,
respectively, with two similar situations from the terrestrial habitat.
One of these two contrasting sets of phenomena concerns the results
of population experiments in reference to the age and chemical
nature of the substratum. The second concerns the population proc-
ess principally in reference to the cooling of the lava flows and,
especially in the intertidal region, the stabilization of their surfaces.

The historic lavas of Hawaii are (Macdonald, 1949) olivinaceous
basalts and are generally black in contrast to many of the older
prehistoric lavas, which are brown. Lava reaches the place where
it solidifies and cools under different conditions of pressure, tem-
perature and movement such that locally several lava types may
be formed which are superficially quite different from one another.
This was true of the 1955 lava that was poured out onto the surface.
However, it has been recognized (Macdonald & Katsura, 1961) that
the 1955 lava types are all very much alike from the chemist’s point
of view. Macdonald (1959:55) analyzed three samples of the 1955
lavas where they had entered the sea and decided there was no
evidence, contrary to some beliefs, that lava was altered in its chem-
ical nature by having been cooled in sea water.

Pioneer Populating Processes a7

PIONEER POPULATION IN RESPECT TO

CHEMICALLY DIFFERING SUBSTRATA
Experimentally the common different types of 1955 lava, including
those described in Table I and those of different age and nature
mentioned above, were exposed to seeding in uniform habitats. The
experiments were carried out on land and in the intertidal region
or subtidally within a meter of the lowest level to which the tides
recede. For experimental exposures on land, the different types of
lava were placed on a concrete walkway in a glass house mist room
and seeded densely but randomly with a mixtures of disseminules
of the organisms reported upon below. For the experimental expo-
sures in the sea, similar chunks of the different lava types were set
in concrete poured in wooden boxes, the corners of which were
reinforced with iron. This preparation was placed on the reef at
Waikiki in Honolulu where the water was about a half meter deep
at low tide. Several somewhat similar experimental embeddings
were made in concrete poured in sifu on intertidal lava shores of
both historic and prehistoric ages.

At various intervals the experimentally exposed rocks for both
the marine and terrestrial studies were observed and the popula-
tions on them noted. Throughout, observation indicated the vari-
ations in light, temperature and air or sea-water were random and
slight within different portions of any one experimental area or
set of experimental lava chunks. These environmental variations
were not correlated with the population events. The experiments
were not carried on long enough to permit observing the results
beyond the pioneer population stages.

The marine situation can be dismissed quick!y. Throughout, in
all cases, very much the same populations developed on all surfaces
exposed in a given environment, even including the concrete, wood
and iron used to facilitate the experimental exposure of the different
lava types.

In regard to the terrestrial situation a much more complex result
was obtained. Native lore in Hawaii includes “everybody knows
that red volcanic cinders are better for such crops as orchids than
black.” Evidence for this of an experimental nature is slight. In
reference to rate of population some lava types are thought to be-
come more quickly populated. However, the environment is so often
different in the natural situations that reliable conclusions cannot
be drawn from field observations alone. With these things in mind,
the mist-room experiment mentioned above was carried out.

178 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

To initiate this experiment, a non-sterile mixture of powdered
leaflets, sporangia and spores of Nephrolepis exaltata (a fern) was
scattered over the arranged rocks in the spray room. Growth was
allowed to go on with at least weekly observation. Obviously a ran-
dom assortment of the almost ubiquitous Scytonema hofmannii (a
blue-green alga), Campylopus exasperatus (a moss) along with
Phyllanthus niruri and Euphorbia hirta and E. glomerifera (both
genera of flowering plants) was eventually seeded onto the rocks if
not actually planted at the same time inadvertently. All of these
organisms are common on lava substrata in the 1955 lava flow area.

In this experiment, the three rock types used can be taken to
represent (but remotely, indeed) “soils” formed as lava flows decay
and change with respect to the oxidation state of the iron in them
and the solubility or leachability of their minerals increases. One
might say this was a series leading from a freshly exposed lithosol
toward a more mature lateritic soil, 7.e., a series leading from the
black dense crystalline rocks (BC) to the black low-density glassy
rock (BG) and on to the red low-density glassy rocks (RG).

TABLE I
Measurements of pioneer communities on lava ty pes

The different olivinaceous basalt rock types used from the 1955
lava flows were: “BC,” black crystalline dense; “BG,” black glassy
hight weight; and “RG,” red glassy light weight. Scytonema hof-
mannil was most of the algae; Nephrolepis exaltata most of the
fern; and Phyllanthus amarus, Euphorbia hirta and E. glomerifera
most of the flowering plants listed as “all others.”

Milligrams per square centimeter
of upper horizontal surface

Rock Density, Dry Chl. Total Total Organism or
type approx. wt. —a chl. pigs. total for all
BC 2.9 — 79 3.02 3.06 Algae
01 01 02 Fern
— — — All others
02 .80 3.04: 3.09 Total
BG RO — 58 2.17 2.26 Algae
18 SS} 26 Fern
1 .09 12 All others
17 87 2.19 2.34 Total
RG 13 ae AT 1.31 1.37 Algae
sl 34 34 Fern
At oll 19 All others

.96 off Ih 1.81 1.90 Total

Pioneer Populating Processes 179

s ; ™ KIL_STUDY
oo f SITE

& KANAILI
{STUDY SITE

KAUELEAU
STUDY SITE HILO
(16-10) HAWAII

KILAUEA o

Figure 7. Map of the 1955 lava flows from the east flank of the volcano, Kilauea,
on the Island of Hawaii, i.e., the shaded area on the inset. The principal study
sites are indicated as are the dates in 1955 when the flow stopped moving at its
seaward end. Isohyets show as dotted lines with the rainfall in inches. Topo-
graphic contours are shown as thin solid lines with the elevations in feet.

The results after ten months of growth are summarized in Table
I, related to the ‘“‘area”’ of rock used. The area was determined from
the vertically cast shadow of the particular rock concerned. The
lava is extremely porous and irregularly so; this makes the measure-
ment of surface area very difficult and makes the removal of the
microscopic pioneer organisms next to impossible on any quanti-
tative basis. For this latter reason, pigment content of the rocks and
their populations was determined by a modification of the Creitz
& Richards (1955) technique and used as a measure of the popula-
tions obtaining.

In gross aspect (Fig. 2) the populations on the different rock
types were strikingly different at the close of the experiment. Flow-
ering plants dominated the red rocks with but a few ferns and very
little apparent algal material. Ferns dominated the black glassy

180 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

rocks with but very few flowering plants and only a little algal
material. The black crystalline rocks were dominated by algal coat-
ings with very little else present.

Among the quantitative results measured (Table I) and quali-
tative observations, five conspicuous relationships to the series of
rock types, BC, BG to RG, are evident. 1) The most obvious gross
aspect was (Fig. 2) the shift from a blue-green algal population, to
a fern population, and to the situation where flowering plants were
dominant. This is in correlation with what one can observe less
well on the same sort of rocks in the field, and which field obser-
vation led us to this experiment done under uniform glass-house
conditions. These results are also in line with the observation of the
seral events in the field: 7.e., 2) the organisms that first form a
community are the algae, then the ferns and lastly the flowering
plants. It is also, 3), in line with the degree of development of pri-
mary producers to be expected on a series of soil types leading from —
lithosols to lateritic soil. Finally, 4) the dry weight increases and,
5) the pigment total quantities decrease through the series (while
there were several rocks in each other category only one BG rock
survived the viscisitudes of experimental science; thus confidence
in the values given for this rock type is low).

The closed nature of the algal community and gradually less
closed natures of the fern and flowering plant populations may
explain the gradual reduction in plant pigments through the series.
In time, as a closed cover would be more nearly achieved in nature,
the pigment standing crops of the fern and flowering plant com-
munities might have come to exceed that of the algae. Otherwise,
one must give consideration to the idea that the ferns, and in turn
the flowering plants, are more efficient in the conversion of photo-
synthate to accumulated material (dry weight) or are more effi-
cient in their use of the chlorophyll molecule than are the algae.
Perhaps there is some truth in all of these possibilities.

PIONEER POPULATION IN RESPECT TO
PHYSICALLY DIFFERING SUBSTRATA

In the field the time course of pioneer community establishment
was followed on the 1955 lava flows themselves. In respect to their
mitial stages, while not realized at the time, it became likely that
slow cooling of the rock on Jand and the change toward a stable
surface in the sea were the most conspicuous physical influences.
In the discussion that follows, the related events leading to the

Pioneer Populating Processes 181

pioneer marine communities are discussed first and then the events
leading to the pioneer terrestrial communities.

Marine Pioneer Communities

Community establishment was studied only insofar as macro-
scopic algae were concerned by following events on the 1955 inter-
tidal lava flow surfaces (Fig. 1) for ten years. While there is almost
explosive boiling of sea water as the hot lava reaches the sea, the
surface is soon cool and within a month densely populated with
algae. The algal populations on nearby prehistoric flows, kept under
observation as control surfaces, underwent a seasonal progressive
set of changes, but otherwise, except for catastrophic events, the
events were not the same as those on the 1955 surfaces. Since this
work is published elsewhere (Doty, in press) in some detail only
sufficient detail is given below to provide a basis for the discussion
to follow.

As commonly reported elsewhere (e.g., Northcraft, 1948; Fahey
& Doty, 1949; Fahey, 1953; Dawson, 1954), on the 1955 flows the
most.conspicuous and first element to appear as a macroscopic
pioneer populant is Enteromorpha followed by other genera such
as Ectocarpus, Cladophora and Polysiphonia. These same genera
are the first populants on all surfaces newly exposed to the sea, e.g.,
on boat hulls of various compositions, on prehistoric lava and on
historic lavas as well. Dawson (1954) made a particular note of
this in respect to the populations on old lava nine months after the
previous populations had been removed by pumice scouring. Also
the same organisms are the pioneers despite the time of year the
above chemically and physically different surfaces are exposed
either as a result of catastrophic events or as pioneer exposure
events. These latter are not much different in this case but the
terms are used here to distinguish between the case where an
advanced population is destroyed by catastrophic events and the
pioneer organisms reappear, and the case where the substratum is
newly brought into the sea, the pioneer exposure events. This latter
occurs whether rocks from the shore are placed in the sea for the
first time, or whether lava flows into the sea.

The pioneer colonizers first appear over a wider range than that
in which they mature. The immature thalli form dense coatings
on the rocks with the individual thalli almost adjacent like the hair
in a fur. As time goes on, and as these thalli mature, they become
reduced in their vertical range and sharply restricted in their up-

182 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Ui

an Sg ot en a AS ( . a. .
er i = Na ee gps L 7

Figure 2. Selective vegetation of 3 different lava types illustrated by a photo-
graph of the populations that developed on them in a spray room following
random seeding. A black crystalline rock such as that in the right hand may
remain nearly barren or become covered with algal growths; one that is black
but glassy, as in the case of the other hand-held example, can be expected to
become dominated by ferns; and red glassy lava, such as that on the ground
directly below the right hand, can be expected to become dominated by flowering
plants.

ward and downward limits, disappear from some parts of their
ultimate range and, as mature thalli, release reproductory struc-
tures where they still persist as tufts separated a few centimeters
from each other. The pioneers are replaced in time by slower-
growing and later-appearing algae.

Zonation on these lava flows arises in time as a result of the seral
processes such as described above. In the intertidal region zonation
is seen as different bands one above the other, each with narrow
vertical and relatively wide horizontal limits and each dominated
by different organisms. As a rule several such bands or zones can
be seen at low tide on a vertical shore. Doty (in press) describes this
process as it occurs on the 1955 lava flows and it need suffice here

Pioneer Populating Processes 183

STN
Cea

DRY AIR

ORY AIR

WET AIR

ORY AIR

WET AIR

A Cc D
Figure 3. The putative relationship between rain and the cooling of a molten
lava flow. During the phase labeled “C” the constantly moist warm surface
becomes relatively densely populated with a polyglot vegetation that cannot
exist earlier (“A”) on the hotter rock or later (“E”’) on the intermittently very
dry rock. This flush of vegetation is characteristic of lava flows and is followed
by the changes that lead to a soil and vegetation normal to the climate of the
region. During the stages represented by “D,” the transition from “C” to “E,”
the pioneer communities become established and, depending upon the physical
nature of the substratum, may display considerable vertical zonation by the
time the stage represented by “E” is reached.

to say that as the sere moves along, the communities and zones
become more discrete and more stable in their content and place
on the shore.

Terrestrial Pioneer Communities

Events on lava flows leading to establishment of the pioneer com-
munity on land are very different timewise from the marine area
events and, of course, different in respect to the organisms con-
cerned. When the lava first stops flowing (Fig. 3A) and for perhaps
a week afterwards, the surface is over 100 deg. C. Rain falling is
instantly converted to steam. Any spores or seeds falling on the
surface would be killed by the high temperature and nothing grows.
When rain falls, such an area is immediately cloaked in a fog bank.
When there is no rain, the air is clear immediately and there is no
lingering of steaming or fog. While the general idea of moisture
availability has been considered by many, the role of the heat in
the flow itself has not, 1t seems. Perhaps this is because so few ecolo-
gists have had the opportunities so often readily available in recent

184 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

years in Hawaii to begin their studies while the surface of the flow
is still liquid and very hot.

The observation is commonly made that when plants do appear
there is a first flush of vegetation that dies out and it is a long time,
then, before communities and a consistently advancing sere appear.
At Kamaili* (Fig. 1) on the 1955 lava flows numerous observa-
tions were made of this phenomenon. For example, among the first
of the macroscopic populants there appeared Erechtites valeriani-
folia, an almost ubiquitous herbaceous composite (plant) over
much of the world. Nine months after the flow had stopped, on the
10 square meter study site, 21 plants were found. Though many of
these bloomed, only three were found alive 2 months later in Feb-
ruary, 1956; only one in March, and in May fourteen months after
the flow had stopped all were gone. In July perhaps in connection
with an unusually moist period, 10 seedlings of Erechtites had
appeared, but these were all gone by November and none appeared
again during the study. This phenomenon was cbserved elsewhere
on the flows from this eruption and in the case of other plants as
well, e.g., in the case of Nephrolepis exaltata and Metrosideros poly-
morpha, respectively, the most common fern and tree in the area.

The casual observation that, after sitting on the sun-hot dry rocks
at Kamaili, one would find cameras, notebooks and pants wet on
the underside led the author to consider this water problem further.
This phenomenon two and a half years after the flow had stopped
was apparently caused by hot air saturated with water coming
out of the flow, but on such a hot clear sunny day no fog was
formed as the air cooled and was wafted away diluted by the pass-
ing breeze. While formerly fog was an almost constant feature of
this site, and for two years appeared with each rain shower, its ap-
pearance during the last part of this period was associated with only
a few nearby spots and eventually even then only with heavy rain.
By 1960, for some few years no steaming had been observed under
any conditions. The duration and the nature of these events and
phenomena, summarized in Figure 3, are widely variable. Varia-
tions in time as well as in the return of water to the air and the
surface phenomena described depend on the rainfall in the district
and the physical properties of the lava surface itself. From all ob-

*MacDonald (1959) gives a detailed pictorial account of the origin of the flow
as a crack among the cucumber plants in a garden and development of this site
in his Plates 10 through 15. Doty and Mueller-Dombois (1966) include more of
the biological details related to the ideas derived from the study of this site.

Pioneer Populating Processes 185

servations combined, including some made on the 1965 lava flow
that covered the floor of Napau Crater in Hawai Volcanoes Na-
tional Park, I am led to the following explanation of this commonly
observed initial-flush phenomena as observed in Hawaii.

About two weeks after the flow had stopped moving (Fig. 3B)
the 100 deg. C temperature level is not on the surface but a few
centimeters below the surface. Fog is produced immediately with
each rain shower and it persists for successively longer periods for
a given amount of rainfall as more heat is transferred, thus, out
of the flow surface and the 100 deg. C level falls more and more
deeply within the flow. The steam must repeatedly sterilize the
surface; though during dry spells the surface temperature may fall
to biologically tolerable levels. Spilling water on the surface at
this stage produces a surprising explosion of steam which may turn
into a small fog cloud if the humidity is high enough or, if the
humidity or water volume is low, there may be only a violent hiss
as the water is converted to steam which in turn dissolves in the
air without forming fog. Peck ef al. (1964) describes the temporary
lowering of the temperature near the surface by rainfall and cooling
water pumped into drill holes and, also, the rates at which tem-
peratures have been measured to fall in the 1963 eruptive lava
nearby from the same volcano, Kilauea. Also, the scale- or sand-like
products of exfoliation that can be seen on the surfaces by this
time may at least in part be enhanced by this reaction with water.

Likewise the time lapsing before the next, the first biotic, stages
(Fig. 3C) may vary but often the first biotic stages appear within
3 months. At this time the 100 deg. C level is sufficiently far down
in the rock that only fog or water-saturated hot air returns to the
surface following a rain. Rain falling on the flow percolates to the
level where it is converted to steam and rises. However, most of
it condenses and percolates again to the hot region below. This
recycling process, from which in this stage some water vapor gets
into the air as fog, keeps the moisture and temperature conditions
on the surface between biologically tolerable limits and identifiable
populants appear. As related elsewhere, the first are most com-
monly blue-green algae which are, like Scytonema hofmannii
the most common among them, tolerant of wide ranges of tempera-
ture and moisture.

Previous stages (represented by Figs. 3A and 3B) are character-
ized by the lava surfaces being barren and dry and by fog produc-
tion ceasing almost as soon as a rain ceases. The stage represented

186 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

es ER CLINKER LAYER

Sa]

E_——_——]SllA=A==_==Ea_aaa=
SSS

RECENT | 2 MASSIVE LAYERE=
FLOW : = =

PREHISTORIC
LAND
SURFACE

RIOTS SCYTONEMA (ALGA)

iii STEREOCAULON (LICHEN )

vepiereriaer CAMPYLOPUS (MOSS )
NEPHROLEPIS (FERN )

Figure 4. A section through a recent a’a lava flow, on the left, overlaying a
prehistoric well developed soil. The upper clinker layer is that which would
eventually give rise to a new soil layer with a climax vegetation on it. At the
right is illustrated the arrangement of the pioneer communities to be expected
on the lava flows at the lower elevations in Hawaii.

by Figure 3C is characterized by the appearance of blue-green
algae, by the surface remaining moist longer after a shower and
by the slower appearance and longer persistence of steaming or fog
production after a shower has passed.

As the stage represented by Figure 3C wears on, mosses appear
and, in the shade, liverworts and ferns. Primary leaves of Nephro-
lepis exaltata and unidentifiable dicotyledons were found at the
Halekamahina site at about 200 feet elevation on August 15, 1955,
five months after the eruption but they did not mature. Colonies
of flowering plants come to thrive rooting in cracks and the crevices
between folds of lava. They are a wide variety in Hawaii varying in
time of appearance, in just what species appear and in just what
population densities obtain. Their success may be promoted by the
earlier-mentioned exfoliated fine material accumulated by gravi-
tation or as Eggler suggested (1941) by wind. Scytonema hofmannii
is always preeminent among the algae. It has been observed to be
infested with fungi at this time. Campylopus species (Miller, 1960)
are preeminent among the mosses and Nephrolepis exaltata is the

Pioneer Populating Processes 187

fern with but rare exceptions. Spathoglottis plicata (an orchid),
the Erechtites and the Metrosideros, both mentioned above, are pre-
eminent among the plants.

As the next stage (Fig. 3D) draws on, the abundance of vege-
tational elements wanes. Fog production in this stage (Fig. 3D) is
much less and in time comes to appear only after the heaviest of
showers or more prolonged rains. Yet on a flow at this stage one
learns, as reported above, that a great deal of water may be being
brought to the surface where the bottoms of everything sitting on
the flow quickly become wet. The water is leaving as hot high-
humidity air that may form wisps of fog in mid air as it cools.
Except where moist algal or moss patches remained, the surface of
the rock became hot in the sun with 150-odd degree Fahrenheit
temperatures being measured. However since some flowering plants
persisted, such as those listed below, it would seem the redistillation

‘process was keeping the root zone moist. New disseminules falling
during this period would undoubtedly die during the dry hot
periods.

Four biological phenomena were apparent at Kamaili in this
stage represented by Figure 3D. First, minute white flecks of what
later proved to be the podetia of the lichen Stereocaulon vulcani
heralded the arrival of this stage two years after the flow had
stopped. The case history of Erechtites represents a second phenome-
non: after its initial flush this annual plant disappeared completely
from the study area. Though the plants produced seed, it is pre-
sumed that the seedlings could not persist long enough on the now-
dry hot surface, after germinating during a rainy period, for their
roots to penetrate to moist depths. A third phenomenon pertained
to the longer-lived plants such as Metrosideros. Actually as Erech-
tites disappeared these first woody-based perennials, seedlings of
the tree Metrosideros, were seen. The original plants often died
back to their crowns and presumably sent up new shoots during
the next more prolonged rainy period.

The fourth phenomenon in the stage represented by Figure 3D
was one of succession in the cryptogamic communities. While the
first appearing Scytonema hofmannii was cleanly and clearly typi-
cally this species, fifteen months later some patches had conspicuous
fungus infections in their sheaths. While the first community to
become established was algal and of Scytonema hofmannii, black-
ened areas of Stigonema eventually became conspicuous. Some-
times low dense coatings of Stigonema are formed on the sunny up-

188 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

per surfaces of the pahoehoe among the podetia of the Stereocaulon
vulcani and are formed so extensively that for areas a decimeter or
so in extent, 30 to 50 per cent of the rock surface is black. This, it
would seem, would be a replacement of the primary blue-green
pioneer colonizer, Scytonema, by the secondary and morphologi-
cally more complex colonizers, Stigonema, and this in turn by
Stereocaulon.

The phenomenon of succession would seem to have been ex-
pressed also in the moss genus Campylopus alone, at least by a suc-
cession of forms. The first to appear was dark green dense tufts
in the crevices between folds of lava nine months after the flow
had stopped. It was identified by Dr. H. A. Miller as C. boswelli.
This was not found again but in the same environment 2 months
later the moss was C. densifolius. At sixteen months C. exasperatus,
ubiquitous on lava in this region, was becoming widespread and
C. densifolius was not refound.

Nephrolepis exaltata went through a period of maximum con-
spicuousness and declined to a much less conspicuous state during
the first 3 years of the stages related to Figures 3A through 3D.
It appeared that during the dry stage “D” few or no new thalli
developed.

It would appear that during the final stage studied at Kamaili
and represented hypothetically by Figure 3E, the water arriving
as rain is soon lost to the plants. The hot zone, if present at all, is
so far down in the rocks that plants with small root systems would
be in dry rock most of the time. The flows in the study areas in this
stage no longer steam after a rain, and presumably the water is
lost largely by percolation. The surface is very variable and extreme
in reference to heat and water.

Seral development (Fig. 3E) is largely maturation of the crypto-
gamic communities, especially in respect to vertical zonation. This
is partially illustrated in Figure 4 which shows, among other things,
the typical pioneer communities of cryptogams established at Ki
(Fig. 1) on a clinker-covered flow. Here a long-persisting fern may
be found to have arisen from a prothallus that grew near a pro-
tuberance from the under surface of a large lava chunk or from
a pendant lava finger extending stalactite-like from the lower sur-
face of a broken-open lava blister roof, on pahoehoe, or underside
of an unusually large clinker. Rain falling on the lava percolates
through slowly and may drip* for a long time from such lower

*Such drippings collected in leaves and shells were a major source of drinking
water for the Polynesians in this district.

Pioneer Populating Processes 189

surfaces making them ideal places for fern prothallus development.

As Figure 4 shows, when zonation develops Stereocaulon vulcani
covers the upward protruding rock surfaces with Stigonema be-
tween the podetia. Campylopus exasperatus tends to fill in between
when the surface is a little lower, perhaps where wind velocities
are lower but there is hardly less light. Scytonema hofmannii per-
sists as the dominant deeper in the flow but where lighted from the
surface. The occasional fern or Metrosideros completes the comple-
ment of organisms persisting generally on the 1955 lava flow areas
and cther plants are rare at this stage.

Change on the flows since 1959 has been slow, hardly any popu-
lation or visible change at all has appeared in the lowest and dryest
areas though a dense vegetational cover of mosses had developed
by 1960 at Kamaili, the wettest (120 inch rainfall) study site. The
pioneer communities can be seen to have developed vertical zona-
tion at this stage and to have become stable.

Discussion

Conditions are extremely variable at the different sites where obser-
vation for this study was done. For example, in the above no dis-
tinction has been drawn between pahoehoe and a’a flows and
(Fig. 1) a two-fold variation in rainfall is to be expected. The tem-
perature varies much more uniformly at these sites. Most of the
study, which the in-places-putative Figure 3 summarizes, was made
on a pahoehoe flow at the 950 foot Kamaili study site. Much of
that upon which Figure 4 was based was from repeated observation
at this site but even more of it was derived from study of a much
drier site at about the 50 foot elevation in the Ku area on a clinker-
covered a’a flow. Our purposes here have been merely to describe
the early changes in reference to the interrelationships between
water, residual heat in the lava and the biotic events as useful in
pointing out the striking difference between the early events of suc-
cession on the land and in the sea.

In the marine environment it would appear that the pioneer algal
communities appear with little difference correlatable with the
chemical nature of the substratum as long as, in this case, the sub-
stratum is stable. This is in general agreement with the relative
success of different antifouling paints composed to flake off as
attached organisms grow. By contrast, in the terrestrial environ-
ment, different types of botanical organisms develop on the differ-

190 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

ent types of lava. The experimental phenomena on terrestrial
materials (Table I) seem related both to the phylogenetic com-
plexity of the organisms and to the degree that the rock is of soil-
like nature.

On land it is commonly reported that a lava flow supports one
or a few relatively lush growths of flowering plants and then, with
succeeding crops declining greatly, may become relatively barren.
As seen in Hawaii an explanation of this phenomenon seems to be
present in the transferring of heat out of the lava by steam. Some
explanation for the first community being blue-green algae is pro-
vided in this hypothesis while not excluding the older idea that the
blue-greens are nitrogen fixers and thus are the pioneers rather
than the non-nitrogen fixing plants. That is, they are more tolerant
of the heat and dryness extremes that characterize an otherwise
barren yet-hot lava flow, than are the plants. No such heat phe-
nomenon is present in the marine environment and the pioneer
communities lead on more directly to the secondary communities.
At least the intertidal lava faces are cooled so quickly the effect,
if there is one, is outside the operational limits of such pioneer-
population studies as this.

It seems that the pioneer communities on land (from the stage
represented by Figure 3E and beyond it) ameliorate and stabilize
conditions by holding water at the surface where it leads to evapora-
tional cooling, and by producing shade. Thus they lead to the next
stage, that of an herbaceous ground cover and an admixture of trees
such as found on the oldest prehistoric flows, in correlation with
the prolongation or stabilization of moisture and lowering the high
temperature extremes.

There is further evidence such conditions are brought about by
the successively more impressive development of the above-men-
tioned communities of cryptogams and Metrosideros in Hawaii. In
Hawaii much of the surface of the 1750 Kaimu lava flow just above
Kaimu Bay is still in this cryptogam-Metrosideros stage. On such
land it must take at least 500 to 1000 years for a practical climax
population to appear on a new lava flow. This time varies greatly
especially in regard to moisture. Tagawa (1964) suggests 700 years
is required. In contrast, if the surface is stable in the intertidal
region, it may take little more than five or ten years; though change
seems to be noticeable for much longer. This latter has not been
determined with any degree of precision and was not an element
in the present study.

Pioneer Populating Processes 191

On land there is evidence that over the many years it takes
a climax population to develop, as Forbes (1912) and Skottsberg
(1941) suggested, there is a succession of blue-green algae, lichens,
mosses, ferns and flowering plants. This is also a succession of
phylogenetically more advanced botanical organisms. There is evi-
dence from the experimental work that the series is related to the
freeing of ions to move in the substratum, v.e., they would hardly
be free to move in the crystalline basalt and much more free to
move in the vitreous material or in a mature soil. Intertidally,
succession is of different algae in several phyla. The successive
kinds to appear are different in growth form (e.g., crusts succeed
other attached forms) or rate of growth and maturity (e.g., rapidly
developing forms appear first). There is no evidence that the inter-
tidal igneous substrata change in time and the populations then
change accordingly.

In both types of habitat the pioneer colonizers appear over a wider
range than that in which they persist if they come to form a com-
munity. As the pioneer communities become established, in both
cases vertical zonation occurs in reference, perhaps, to exposure to
air and water, and in both cases the populations become more stable
as this zonation becomes more pronounced. In the case of the
marine populations perhaps this zonation is caused (Doty, 1946)
by tidal control of the exposure to sea and air. In the terrestrial
environment, other factors such as tolerance of the different mois-
ture and light conditions are causative, the heat factor having been
ameliorated.

These observations and conclusions support the thesis that pio-
neer organisms arrive by chance and colonize unless something
kills or removes them. They tend to be killed or removed outside
of the range in which they become pioneer communities, vertically
zoned, both on land and in the intertidal region. This idea of devel-
opment of vegetations from negatively contagious (random) to
contagious has been commonly accepted in reference to horizontal
distribution. With the above recognition of vertical zonation (storey-
ing) phenomena in these pioneer communities we can extend this
concept to this new dimension.

SUMMARY
Field observation and experimentation over a ten-year period in
reference to the 1955 lava flows in Hawaii has facilitated compara-
tive and descriptive studies of the pioneer population phenomena.

192 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Achievement of stability of surfaces in the sea is a major factor
in community development beyond the subclimax stages whereas
actual chemical nature of the substratum is less important. On land
the chemical and physical nature of a lava flow is important as is
water availability. Rain water seems to play a major role in remoy-
ing heat from the surface of a hot lava flow, and in this process a
warm moist root bed is provided for a time, perhaps accounting for
the early flush of vegetation often reported to appear and disappear
on lava flows. The well known change from random distribution
to non-random distribution during seral development is extended
by the present observations to include vertical zonation in the
pioneer communities.

LITERATURE CITED

CREITZ, G .I., and F. A. RICHARDS

1955. The estimation and characterization of plankton populations by pigment -
analysis. III. A note on the use of millipore membrane filters in the
estimation of plankton pigments. J. Mar. Res. 14: 211-216.

DAWSON, E. YALE
1954. The marine flora of Isla San Benedicto following the volcanic eruption
of 1952-1953. Allan Hancock Foundation Publ. Occas. Paper 16: 1-25.

DOTY, M. S.

1946. Critical tide factors that are correlated with the vertical distribution of
marine algae and other organisms along the Pacific Coast. Ecology 27:
315-328.

(In press.) Pioneer intertidal population and the related general vertical distri-
bution of marine algae in Hawau.

DOTY, M. S., and D. MUELLER-DOMBOIS
1966. Atlas for bioecology studies in Hawaii Volcanoes National Park. Univer-
sity of Hawaii, Hawaii Bot. Sci. Paper No. 2. 510 pp.

EGGLER, W. A.
1941. Primary succession of volcanic deposits in southern Idaho. Ecol. Mono-
graphs 3: 277-298.

1963. Plant life of Paricutin Volcano, Mexico, eight years after activity ceased.
Amer. Midl. Nat. 69: 39-68.

FAHEY, E. M.
1953. The repopulation of intertidal transects. Rhodora 55: 102-108.

FAHEY, E. M., and M. S. DOTY
1949. Pioneer colonization on intertidal transects. Biol. Bull. 97: 238-239.

FORBES, C. N.
1912. Preliminary observations concerning the plant invasion on some of the

lava flows of Mauna Loa, Hawaii. Bernice P. Bishop Mus., Occas. Paper
5: 15-23.

Pioneer Populating Processes 193

GRIGGS, R. F.
1933. The colonization of the Katmai ash, a new and inorganic “soil.” Am. J.
Bot. 20: 92-113.

MacDONALD, G. A.

1949. Petrography of the island of Hawaii. U.S. Geol. Survey, Prof. Paper 214-D.

1959. The activity of Hawaiian volcanoes during the years 1951-1956. Bull.
Volcanologique Ser. II, Vol. 22: 1-70.

MacDONALD, G. H., and T. KATSURA
1961. Variation in the lava of 1959 eruptions in Kilauea Iki. Pacific Sci. 15:
358-369.

MARTIN, G. C.
1913. The recent eruption of Katmai Volcano in Alaska. National Geographic
Magazine 24: 131-181.

MILLER, H. A.
1960. Remarks on the succession of bryophytes on Hawaiian lava flows. Pacific
Sci. 14: 246-247.

NORTHCRAFT, R. D.
1948. Marine algal colonization of the Monterey Peninsula, California. Amer.
J. Bot. 35: 396-404.

PECK, DALLAS L., JAMES G. MOORE and GEORGE KOJIMA

1964. Temperatures in the crust and melt of Alae lava lake, Hawaii, after the
August 1963 eruption of Kilauea Volcano —a preliminary report. U.S.
Geol. Survey Prof. Paper 501-D, pp. D1-D7.

RIGGS, B. G.
1914, The effect of the Katmai eruption on marine vegetation. Science n s. 40:
509-513.

ROBYNS, W., and S. H. LAMB
1939. Preliminary ecological survey of the island of Hawaii. Bull. Jard. Bot.
Brux. 15: 241-293.

SKOTTSBERG, C.

1930. The flora of the high Hawaiian volcanoes. Fifth Int. Bot. Congress, Cam-
bridge: 16-23.

1941. Plant succession on recent lava flows in the island of Hawau. Gotteborgs
Kungl. Vetenskap-och Vitterhetssamhalles Handlinger Sjatte fojden, ser.
B., Bd. 1, no. 8. 32 pp.

TAGAWA, H.

1963. Investigation of pattern in plant communities. I. Pattern in Carex kobo-
mugi Ohwi population. Jap. J. Ecol. 13: 10-15.

1964. A study of the volcanic vegetation in Sakurajima, Southwest Japan.
I. Dynamics of vegetation. Mem. Fac. Sci., Kyushu Univ., Ser. E (Biology)
3: 165-228.

1965. A study of the volcanic vegetation in Sakurajima, Southwest Japan.
II. Distributional pattern and succession. Japanese J. of Bot. 19: 127-148.

1966. A study of the volcanic vegetation in Sakurajima, Southwest Japan.
III. Trap sampling of disseminules on the lava flow and the culture experi-
ment of some pioneer mosses. Sci. Repts., Kagoshima Univ. No. 15: 63-83.

194 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

SSE ZAWIKCAC IE
1961. Development of vegetation in relation to soil formation in the volcanic
island of Oshima, Izu, Japan. Japanese J. Bot. 17: 371-496.

WENTWORTH, C. K.
1938. Ash formations on the island of Hawaii. 3rd Spec. Rpt. Hawaii. Volcano

Observatory vill + 183 pp., Honolulu.

WHITFORD, P. B.
1949. Distribution of woodland plants in relation to succession and clonal
growth. Ecology 30: 199-208.

GROWTH AND DEVELOPMENT OF
Sciadophycus stellatus Dawson"

M. Neusuut, J. Scorr, A. L. DAHL AND D. OLSEN

Department of Biological Sciences
University of California, Santa Barbara, California

INTRODUCTION

E. Y. Dawson in 1944 discovered and named a curious sub-tidal red
alga. This small plant, Sciadophycus stellatus, was found in dredge
hauls from a depth of 40-50 m off Cerros Island, Baja California
and was also dredged from a depth of 43 m off Poimt Loma, Cali-
fornia. Dawson placed Sciadophycus in the Rhodymeniales, largely
on the features of its cystocarp. The senior author collected Scia-
dophycus again from the region south of Cerros Island and also
from La Jolla (Dawson, Neushul and Wildman, 1960). More
recently it has been collected from kelp beds on the south side of
Anacapa Island (Dawson and Neushul, 1966). This latter collec-
tion from 15-22 m represents the northern limit of the genus at this
time.

Sciadophycus (Fig. 1) has a star-shaped, peltate blade that is
supported by a short cylindrical stipe. The stipe is irregularly
swollen and is whitish in color due to the accumulation of floridean
starch. The stellate blade has from 3 to 14 points. Each point pro-
duces a secondary blade and stipe. These secondary blades in turn
become stellate and themselves produce new blades at each point.
A new marginal set of blades and stipes is produced every 2-3 weeks
in culture. The material used in this study remained sterile, but
reproduced vegetatively, producing many sets of marginal blades
and stipes.

The morphology of Sciadophycus is characteristic of many deep
subtidal rhodophyceans. It reproduces vegetatively; it has a some-
what rigid thallus that in nature is oriented relative to the incident
radiation; and it stores reserve material in the stipe (Neushul,
1967). We felt that Sciadophycus would be of interest to grow
under laboratory conditions where its development and growth
could be easily studied. It proved to be particularly amenable to
cultivation in the laboratory.

1This study was supported by N.S.F. grant GB 2850. Collections were made
by diving from RV SWAN, provided by NSF facility grant GB 4698. The

authors are particularly indebted to L. Liddle, R. Cummings, and R. Zingmark
for assistance in the laboratory cultivation of Sciadophycus.

195

190 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

MATERIALS AND METHODS

All experiments were run on a clone established from a single plant
transplanted to the laboratory from Anacapa Island on November
20, 1964. This plant produced marginal bladelets and these in turn
were divided and grown in tanks under continuous illumination
at 2200 lux. The tanks were supplied with running, sand-filtered
seawater that ranged from 13 to 17 degrees C. These culture fa-
cilities are discussed more completely elsewhere (Neushul and
Dahl, in press). A particularly successful technique for growing
Sciadophycus involved the use of small plastic clips (Fig. 2) to
hold the plants and to orient them relative to incident light. Plants
were grown both in the laboratory with artificial illumination and
in a greenhouse supplied with running seawater. Plants were ex-
posed to light intensities from 1100 to 125,000 Lux and from 8
hours of light per day to constant illumination. Growth was re-
corded as increase in wet weight. The plants were taken from the
culture tanks, blotted on a paper towel, and then weighed on an
analytical balance.

Studies of Sciadophycus photropism were conducted on small
blades grown on clips in two plexiglass aquaria. A thin platinum
wire was tied to each terminal blade. This wire served as a pointer
that could be seen against a protractor taped on the back of each
aquarium. Both aquaria were covered with a layer of black plastic.
A removable door in the front of each was used for photographing
the phototropic response at various intervals. One of the aquaria
was illuminated from the top and the other was illuminated from
the bottom. Within each aquarium the Sciadophycus plantlet with
pointer was placed in such a manner that the flat portion of the
blade was either facing toward or away from the light source. When
the plants and attached pointers were photographed a white card
was placed behind the protractors for contrast.

RESULTS

Laboratory grown Sciadophycus plants differ from those collected
from nature in their more regular symmetry and the absence of
grazing damage. In the laboratory the small blades grew into ball-
like colonies of considerable size (Fig. 3). These conglomorations
of blades, stipes and rhizoids contain many interesting features.
Blades and stipes orient in what appears to be a phototropic
response with the upper side of the blades oriented perpendicular

Studies on Sciadophycus stellatus 107

= |My,
= WH hij uly =
} 5M 2g
St %~e AS
= Le, © \ jz
= 4 Zé e \ a
=, c 2 =
a ie
= § a Ss
=~ J
: ie
. nee
- =
~ = aay --

Figure 1. Sciadophycus 1% natural size. S—stipe, B—blade; secondary and ter-
tiary blade and stipe units are shown.

Figure 2. Sciadophycus bladelets shown attached by plastic clips, B—bladelet;
C—clip. Cm. scale is shown.

Figure 3. Sciadophycus, ball-like conglomoration of blades, stipes and rhizoids.
Figure 4. Sciadophycus, reoriented stipe (S), bearing newly-formed blade (B).
Figure 5. Position of Sciadophycus bladelets at start of experiment, both plants
are illuminated from below as indicated by letter b in figures 5-8. The plant on
the left is oriented rhizoid down, the one on the right rhizoid up.

Figure 6. 20 hours after start of experiment.

Figure 7. 40 hours after start of experiment.

Figure 8. 72 hours after start of experiment, the position of the platinum wire
and pointer indicates the amount of tropic movement.

198 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

to the plane of incident light and the stipes growing away from
the light. Blades will sometimes fuse. Stipes frequently attach to a
blade or stipe nearby. These fusions give the colony rigidity and
shape. Some of the stipes inside the ball assume a whitish cast
probably due to the storage of floridean starch. It was noted that in
clumps that were allowed to float freely the blades and rhizoids
were oriented in many directions. When these clumps were held in
one position and not allowed to roll about, the blades and older
rhizoids became oriented relative to the incident light. New blades
formed on some of the reoriented stipes (Fig. 4) and were also
oriented to the incident light. The stipes were found to attach to
substratum in 3-7 days if held in contact with it. If stipes are cut
from the substratum leaving a small portion attached, this portion
will form a new cap in about one month.

The abscised stipe and blade units used in the phototropism —
experiments responded to changes in orientation just like those
growing in the blade clumps. No reorientation occurred in stipe-
blade units held in the dark. No reorientation occurred in stipe-
blade units that were placed upside down in aquaria supplied with
light from below, and no reorientation occurred in stipe-blade units
oriented normally and illuminated from above. In contrast stipe-
blade units illuminated from the lower “stipe” side showed striking
reorientation movements. These movements were exhibited by
plants oriented normally and illuminated from below (Figs. 5-7)
as well as by inverted plants illuminated from above. The turning
rates in both cases were rapid. Inverted plants illuminated from
above turned 0.23 degrees/hr., while those illuminated from below
turned 0.24 degrees/hr. Controls in all cases showed no such move-
ment. These rates are conservative since the plastic clips were
fastened behind the region of the blade where the turning response
occurred and this bending area was not centered on the protractor
(Fig. 8). An attempt was made to maintain the same length of
tissue between the disc and clip in all experiments.

Under a variety of conditions, the maximum doubling rate
achieved by individual plants was a doubling in wet weight in 12-28
days. Out of a total of 80 plants studied only 18 approached the
12-28 day doubling time. While many plants showed rapid growth
(approx. 14 day doubling time) over short periods of time at all
conditions they did not show a consistent weight gain. These in-
consistencies are perhaps attributable to damage or other errors
introduced during handling, to shading by epiphytes, to variation

Studies on Sciadophycus stellatus 199

in growth rates during morphogenesis, or to a combination of these
and perhaps other factors.

DiscussION AND CONCLUSIONS

The laboratory growth rate of Sciadophycus is rapid, being com-
parable to red algal growth rates measured in the sea. Gracilaria,
a red alga from the well-lighted upper subtidal and intertidal in-
creases its weight by 2.6% daily (Jones 1959a), under the most
optimum conditions. Constantinea grown in the sea doubles its
blade area in from 2 to 3 weeks, Neushul and Powell (1964).
Sparling (1961) reports that Rhodymenia in nature can reach 40
cm in length in 3-4 months. Laboratory growth rates for red algae
are mainly for smaller filamentous forms cultured in dishes al-
though Sparling (1961) reports slow growth rates (3-4 cm in 10
or more months) for Rhodymenia and Halosaccion in laboratory
dish culture. Sparling suggests that subtidal plants such as Fauchea
are more amenable to laboratory culture than those from the upper
subtidal and intertidal regions. The rapid growth rate of Sciadophy-
cus in the laboratory further supports this view.

The behavior of Sciadophycus under laboratory conditions illus-
trates its morphological and physiological adaptation to the lower
sublittoral regions. It has a rapid rate of vegetative reproduction
and its rigid thallus rapidly orients positively relative to incident
radiation. A somewhat similar phototropic response has been dem-
onstrated for the Conchocelis stage of the red alga Porphyra by
Ogata (1960). Jones (1959b) also reports a positive geotropic re-
sponse in Gracilaria. The rapid adhesion of newly formed Scia-
dophycus stipes to substrate and the ability of the plant to store
starch in the stipes are other possible adaptations to life in the
lower photic zone.

Sciadophycus collected from the sea does not differ greatly from
that grown in the laboratory although the luxuriant clumps of
blades and stipes produced in the laboratory have yet to be found
in the sea. Plants from the sea have on the stipes what appears to
be “scars” where old blades may have been produced. Laboratory
plants did not produce new blades on the original stipe, nor have
we yet seen any plants from nature with new caps forming on
the mature stipes. While the gross morphology of Sciadophycus
is very like that of Constantinea simplex we have no indication
other than the stipe “scars” that it produces annual new blades
as does Constantinea.

200 ~Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

While the laboratory culture conditions produced what may well
be optimum growth, none of the many plantlets grown in the la-
boratory for a two-year period, produced either gametes or spores.
We are as yet unaware of the environmental factor or factors that
trigger gamete or spore formation. Perhaps new cap formation and
the production of gametes and spores are related phenomena. Powell
(1964) has demonsirated this type of relationship for Constantinea
subulifera.

LITERATURE CITED

DAWSON, E. Y. AND M. NEUSHUL.
1966. New records of marine algae from Anacapa Island, California. Nova
Hedwigia 12: 173-191.

DAWSON, E. Y., M. NEUSHUL AND R. D. WILDMAN
1960. Seaweeds associated with kelp beds along Southern California and North-~
western Mexico. Pacific Nat. 1: 1-81.

JONES, W. EIFION
1959a. The growth and fruiting of Gracilaria verrucosa (Hudson) Papenfuss.
J. Mar. Biol. Assn. U. K. 38: 47-56.

JONES, W. EIFION

1959b. Experiments on some effects of certain environmental factors on Gra-
cilaria verrucosa (Hudson) Papenfuss. J. Mar. Biol. Assn. U.K. 38:
153-167.

NEUSHUL, M.
1967. Studies of subtidal marine vegetation in Western Washington. Ecology,
48: 83-94.

NEUSHUL, M. AND A. L. DAHL

(In press) Composition and growth of subtidal Parvosilvosa from Californian
kelp forests. Proc. First European Symposium on Marine Biology. Helgol.
Wiss. Meeresunters. Vol. 15.

NEUSHUL, M. AND J. H. POWELL
1964. An apparatus for experimental cultivation of benthic marine algae.
Ecology, 45: 893-894.

OGATA, E.
1960. Studies on the growth of Conchocelis—III. Tropism in growth direction.

POWELL, JOSEPH HOWARD
1964. The life-history of a red alga, Constantinea. Ph.D. Thesis, Department of
Botany, University of Washington, Seattle, Washington.

SPARLING, SHIRLEY R.
1961. A report on the culture of some species of Halosaccion, Rhodymenia and
Fauchea. Amer. J. Bot. 48: 493-499.

NEW GENERA IN THE RHODOMELACEAE FROM THE
CENTRAL PACIFIC

GeEorGE J. HoOLLENBERG

University of Redlands
Redlands, California

INTRODUCTION

During a study of the species of Polysiphonia of the Central and
western Tropical Pacific Ocean, a number of interesting algae were
encountered. Some of these are reported in this account. Collectors
are indicated as follows: D., Maxwell S. Doty of the University of
Hawaii, and H., the author.

Abbottella gen. nov.

Minute algae with tetrasiphonous prostrate branches attached by
unicellular rhizoids, and bearing erect, complanate, determinate
branches arising exogenously at intervals of mostly 3 segments in
alternate positions on either side of the prostrate branches; erect
branches tetrasiphonous, with the lateral pericentral cells cut off
first, followed by the formation of the adaxial and abaxial cells;
lateral pericentral cells soon dividing transversely and redividing
in such a manner as to form monostromatic lateral extensions of the
determinate branches 2-3 cells wide; determinate branches bearing
a single, huge, terminal, much-branched trichoblast; reproduction
unknown.

Algae minutae, et ramos prostratos tetrasiphonaceos, per rhizoi-
dea unicellularia affixos, et ramos erectos complanatos determin-
atos, intervallis plerumque 3 segmentorum exogene enascentes,
alterne positos utroque in latere ramorum prostratorum, ferentes;
rami erecti tetrasiphonacei, cellulis pericentralibus lateralibus pri-
mum cellulis adaxialibus abaxialibusque deinde absicissis; illae
mox transverse divisae redivisaeque in tali modo ut extensiones
ramorum determinatorum laterales monostromaticasque 2-3 cellu-
larium latas efficiunt; rami determinati singulam trichoblastam
terminalem permagnam ramosissimam ferentes; reproductio ignota.

Abbottella concinna sp. nov.
(Figure 1, A-H)
Minute saxicolous algae, with prostrate branches a few milli-
meters long and composed of segments 0.3-0.5 diameters long at
maturity; rhizoids cut off as separate cells, commonly with digitate

201

202 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

apices; erect branches to 400, high, with the basal 3 or 4 segments
permanently tetrasiphonous; trichoblasts to 850, long or longer.

Algae minutae saxicolae, ramos prostratos aliquot millimetris
longos, e segmentis maturis 0.3-0.5 diam. longitudine compositos,
habentes; rhizoidea ut cellulae discretae abscissa, apicibus plerum-
que digitatis; rami erecti usque ad 400, alt., segmentis 3 vel 4
basalibus semper tetrasiphonaceis; trichoblastae usque ad 850
long. vel longiores.

TYPE: D. 11160.3 growing on dead coral on the lagoon reef at
Takeke, Raroia, Tuamotu Archipelago, (16°S., 142° 26’W) col-
lected by M. S. Doty and Jan Newhouse, July 9, 1952. One addi-
tional collection, D. 9634Ca, was made by Leonard Horwitz at Arno
Atoll of the Marshall Islands during the summer of 1951. The fluid
preserved material is presently at the University of Hawaii, part of
the latter collection in a sealed ampule. Several glucose slide mounts.
of the type material were made.

The order of pericentral cell formation in determinate branches
of Abbottella is that characteristic of the Delesseriaceae, with the
lateral pericentral cells cut off first, followed by cutting off of
adaxial and abaxial pericentral cells in that order (figs. 1C, 1D, 1E).
The order seems to be the same in the indeterminate branches, al-
though this was not determined with certainty. The adaxial and
abaxial pericentral cells of determinate branches remain undivided,
whereas the lateral pericentral cells quickly enlarge laterally and
divide unequally in a plane perpendicular to the longitudinal axis
of the branch (fig. 1D). The larger of the two resulting cells again
divides in the same plane and the resulting cells divide transversely
(parallel with the longitudinal axis of the branch) forming inner
and outer cells. The inner cells may be designated as daughter
pericentral cells. The process results in the formation of 3-4 daugh-
ter lateral pericentral cells on either flank of each central cell of
mature branches, which are mostly 6-7 cells wide (fig. 1A, 1H).
The branch remains monostromatic except for the central tetra-
siphonous axis. The indeterminate branches remain permanently
tetrasiphonous.

Each mature determinate branch bears a single relatively huge
terminal trichoblast (Fig. 1A) up to 850y long or longer and 35-
40), in diameter at the base. The trichoblasts are repeatedly
branched in a pseudodichotomous manner above the basal 2-3 cells.
Frequently one or two of these basal cells may be as long or longer
than the branch which bears them. The trichoblasts are mostly

New genera from the Central Pacific

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Figure 1. Abbottella concinna

A. Terminal portion of an indeterminate branch showing young and mature
determinate branches.
B

Apex of indeterminate branch showing exogenous origin of determinate
branches.

C.

Lateral view of apex of very young determinate branch showing sequence
of formation of pericentral cells: a. lateral, b. adaxial, and c. abaxial peri-
central cells. Scale as in D.

Face view of apical portion of young determinate branch showing first
division of lateral pericentral cells.

ac|@)'zal|esl (S)

Face view of the apex of a very young determinate branch. Scale as in D.
Transverse section of base of a young determinate branch.

Transverse section of the upper part of a young determinate branch.
. Apical portion of mature determinate branch.

203

204. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

soon shed leaving the branch apex with a terminal notch at the
former point of attachment (Fig. 1H). Short secondary branchlets
usually occur near the base of the determinate branches on the
adaxial side, at about the third segment from the base of the
branch, below which the branch remains cylindrical and tetra-
siphonous. These secondary branchlets, which were observed, were
mostly rudimentary, but may bear one or more less well developed
determinate branches. In one case what appeared to be a single
tetrasporangium was observed in one of these secondary branch-
lets. No other reproductive structures were observed.

This remarkable alga is undoubtedly a member of the Rhodo-
melaceae, as indicated by the polysiphonous structure, the exogen-
ous origin of branches and the much-branched trichoblasts. The
flattened monostromatic branches and the order of pericentral cell
formation are suggestive of the Sarcomenia group, which has been -
intensively studied by Papenfuss (1944) and by Womersley and
Shepley (1959). These investigators do not agree as to the place-
ment of the Sarcomenia group, whether in the Delesseriaceae or
the Rhodomelaceae. Since Abbottella exhibits certain features
clearly Rhodomelaceous but has an order of pericentral cell forma-
tion generally characteristic of the Delesseriaceae, it would seem
to make the order of pericentral cell formation less dependable as
a feature distinguishing the two families.

In certain respects Abbottella resembles Taenioma, namely the
order of formation of the pericentral cells, the flattened and mono-
stromatic determinate branches arising exogenously, and the ter-
minal trichoblasts on the latter. From Taenioma it differs in the
manner of development of the monostromatic margins of the deter-
muinate branches, in the number of divisions of the lateral pericen-
tral cells, and in the nature and number of trichoblasts.

In the flattened, exogenous, determinate branches, and in the
single huge terminal trichoblasts Abbottella resembles Leveillea.
Furthermore, in both genera the determinate branches arise alter-
nately on either side of the indeterminate branches at intervals of
3-4 segments. However, there are basic differences between these
two genera, namely the delesseriaceous order of pericentral cell
formation in Abbottella, the tetrasiphonous base of, and mode of
development of, the determinate branches, and the unicellular
rhizoids of Abbottella. The attachment organs of Leve:llea are com-
pact bundles of cells arising from adjacent ends of the polysiphon-
ous segments.

New genera from the Central Pacific 205

Although Abbottella is clearly a member of the Rhodomelaceae
and might be tentatively assigned to the Polyzonia Group of Kylin
(1956), the affinities are very uncertain and will probably remain
in doubt until further information concerning reproduction is
available.

This alga is named in honor of Dr. Isabella A. Abbott of the
Hopkins Marine Station, of Stanford University, Pacific Grove,
California, a highly esteemed colleague over a period of many years.

Dawsoniella gen. nov.

Minute epiphytes, chiefly prostrate, tetrasiphonous, escorticate,
attached by numerous large rhizoids with broadly knobbed apices;
two indeterminate lateral branches and one erect determinate
branch arising from primordia resembling scar-cells in turn de-
rived endogenously from a common central cell; trichoblasts arising
on the distal end of erect branches only; tetrasporangia one per
segment in the erect branches; cystecarps subterminal on erect
branches; spermatangial stichidia developing from entire tricho-
blast primordia.

Plantae minutae epiphyticae, praecipue prostratae, tetrasiphon-
aceae ecorticataeque, per rhizoidea multa magna, apicibus late
torulosis, affixae; rami duo laterales indeterminati, et unus ramus
erectus determinatus e primordiis cellulis-cicatricibus consimilibus,
e cellula communi centrali derivatis orientibus; trichoblasta solum
in extremitate distali ramorum erectorum enascens; unum tetra-
sporangium utroque in segmento in ramis erectis; cystocarpi im
ramis erectis subterminales; stichidia spermatangialia e primordiis
totis trichoblastae effecta.

Dawsoniella bulborhiza sp. nov.
Figure 2, E-I

Prostrate branches ca. 554 in diameter with attenuate apices,
composed of segments 0.3-0.7 diameters long; rhizoids unicellular,
cut off as separate cells; erect branches to 500 long arising at inter-
vals of 11-13 segments; trichoblasts repeatedly branched, arising
one per segment in spiral sequence on the terminal parts of erect
branches only; tetrasporangia 35-40, in diameter, in very short
series; cystocarps globular, to 250. in diameter; spermatangial
stichidia broadly clavate, arising from the entire trichoblast pri-
mordium, without a sterile apex.

Planta ramos prostratos c. 554 diam., apicibus attenuatis, e seg-

206 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

mentis 0.3-0.7 diametro longis compositos habens; rhizoidea uni-
cellularia, ut cellulae discretae abscissa; rami erecti unusque ad
500 long, intervallis 11-13 segmentorum orientes; trichoblastae
quarum una utroque in segmento, in partibus terminalibus ra-
morum tatummodo erectorum spiraliter ordinatae; tetrasporangia
35-40. diam., in seriebus brevissimis; cystocarpi globosi, usque ad
250u diam.; stichidia spermatangialia late clavata, e primordio toto
trichoblastae enascentia, sine apice sterili.

The type collection of this alga, D 11857.5, cystocarpic, sperma-
tangial and tetrasporic, was epiphytic on Pocockiella. The host
plant was growing on dead coral and encrusting corallines. This
collection was made by M. S. Doty and Jan Newhouse from the reef
near Otetou, Raroia, in the Tuamotu Archipelago, Aug. 21, 1952.
It is represented by several glucose slide mounts. An additional
collection (sterile), by A. D. Conger, at Japtan Is., Eniwetok Atoll,.
Marshall Islands, April 22, 1951, was growing on the same host.

This genus is an unusual member of the Rhodomelaceae in that
three branches commonly arise from the distal end of the same
central cell, namely two indeterminate lateral prostrate branches
and one erect determinate branch. (Fig. 2, F-G; figs. 10, 11). All
branches arise endogenously since they develop from small pri-
mordia which were previously derived from the central cell. Two
opposite branches arise from the same central cell in only a few
members of the family. According to Falkenberg (1901) paired
branches commonly arise from the same central cell in Enantio-
cladia, Kutzingia and Protokutzingia. However, the writer is not
aware of any member of the Rhodomelaceae in which three
branches arise from the same central cell, other than in Dawsoniella.

No trichoblasts occur on the indeterminate branches. Broadly
club-tipped rhizoids very similar to those of Dawsoniella (Figs. 2F,
12) were observed on the prostrate branches of a minute species
of Polysiphonia, probably P. poko, Hollenberg (D. 11858.1) grow-
ing on the same host along with Dawsoniella. However, other fea-
tures were clearly those of Polysiphonia. One is inclined to suspect
that the form of the rhizoids in these two cases may have been
influenced by the host. This alga is named in honor of the late Dr.
E. Yale Dawson, a close associate and friend of the writer over
many years of phycological study.

Ditria gen. nov.
Minute creeping algae with indeterminate branches attached by
occasional rhizoids, which are cut off as separate cells from ventral

New genera from the Central Pacific

Figure 2. A-D Phaeocolax kajimurat

A. Habit sketch.
B. Vertical section of basal attachment to the host. The outermost layer of cells
of the host are displaced by the parasite.
C. Apex of branchlet bearing spermatangial stichidia.
D. Apex of branchlet with whorled tetrasporangia.
E-I Dawsoniella bulborhiza
. Apex of prostrate branch showing initials of two rhizoids, a young determi-
nate erect branch, and primordium of a lateral indeterminate branch.
. Portion of prostrate branch with mature rhizoid, a tetrasporic erect branch,
and early stage of development of lateral indeterminate branches.
. Diagrammatic cross section of a prostrate branch showing origin of a rhizoid,
young determinate erect branch, and primordia of lateral branches.
. Upper portion of erect branch bearing a spermatangial stichidium.
Apex of erect branch with procarp.

Ho O 4

Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967 208

pericentral cells and which have multicellular apices at maturity;
branches mostly determinate, very short and distichous, in a plane
parallel with the substratum; pericentral cells 5, escorticate; tricho-
blasts very large and much branched, arising exogenously, one per
segment in spiral series on indeterminate and determinate branches,
quickly shed, leaving scar-cells; reproduction unknown.

Algae minutae repentes, ramos indeterminatos per rhizoidea
parca affixos habentes; rhizoidea ut cellulae discretae a cellulis
pericentralibus ventralibus abscissa, et dum maturescent apicibus
multicellularibus praedita; rami plerumque determinati, breves et
in plano ad substratum parallelo distichi; cellulae pericentrales 5,
ecorticatae; trichoblastae permagnae ramossissimaeque, exogene
orientes, una utroque in segmento in spira in ramis indeterminatis
determinatisque, cito exutae; cellulas-cicatrices relinquentes; repro-
ductio ignota.

Ditria reptans sp. nov.
Figure 4, A, B

Prostrate branches 80-115, in diameter, composed of segments
one diameter long or shorter, with moderately thick walls; lateral
branches arising exogenously or cicatrigenously, commonly at in-
tervals of 2 and 3 segments in alternating sequence. Chromatophores
numerous 1.5-2.0u in diameter and arranged in forking chains or
transverse bands; trichoblasts to 1.25 mm. long and 40-48, in diam-
eter at the base, with 7-8 dichotomies.

Rami prostrati 80-115, diam., e segmentis aeque longis ac latis
aut brevioribus, membranas satis crassas habentibus, compositi;
rami laterales exogene aut cicatrigene enascentes, vulgo intervallis
2-3 segmentorum, in serie alternante; chromatophora multa, 1.5-
2.0 diam., in catenis furcatis aut fasciculis transversis ordinata;
trichoblastae ad 1.25 mm. long., 40-48, diam. ad basim, septem vel
octo dichotomiis furcatae.

TYPE: D. 19135E3, dredged 15 fa., in front of the river mouth,
Waialua, Oahu, Hawaiian Islands, Aug. 2, 1959. It is represented
by a single glucose slide mount. Additional collections: D. 19127U1,
on Microdictyon sp., dredged 10-14 fa., Pokai Bay, Oahu, July 30,
1959; D. 1912981 on Microdictyon, dredged 15 fa., Pokai Bay, Oahu,
July 31, 1959; D. 1913611, D. 19136K3, dredged 15 fa., along with
the type; D. 18740C, on Codium sp., awash Midway Is., Legit
Charles H. Lamoureux, Dec. 16, 1962.

This alga is similar to Dipterosiphonia rigens (Schousb.) Falken-
berg, occurring in the Mediterranean and the Tropical Atlantic

New genera from the Central Pacific 209

Americas. From that genus Ditria differs in a number of respects:
(1) All branches exhibit dorsiventrality in the continuously pros-
trate habit and in the orientation of the rhizoids, branches and
trichoblasts in relation to the substratum. In Dipterosiphonia only
the free-growing branches exhibit dorsiventrality in these respects;
(2) lateral branches do not arise on every segment as in Diptero-
siphonia; (3) there is no regular pattern of branch origin in deier-
minate and indeterminate pairs as described for Dipterosiphonia;
(4) trichoblasts occasionally occur on indeterminate as well as on
determinate branches in Ditria rather than on determinate branches
only as in Dipterosiphonia.

The name Ditria refers to the determinate branches which arise
at intervals of 2 and 3 segments alternately.

The distichous branches arise in such a manner that two peri-
central cells occur dorsal to the plane of branch origin and three
pericentral cells ventral to that plane. Rhizoids arise from any of
the three ventral pericentral cells.

It should be noted that chromatophores are frequently oriented
in transverse bands as in Womersleyella, but the two algae are
amply distinct in other respects, especially the branching pattern.

Hawaiia gen. nov.

Minute algae with prostrate branches attached by unicellular
rhizoids cut off by a cross-wall from the pericentral cells; erect
branches arising exogenously and branched in an assurgent quasi-
decurrent manner; pericentral cells 8-11, ecorticate; trichoblasts
unbranched arising in somewhat spiral sequence; tetrasporangia
one per segment, in slightly spiral series in the branches; sper-
matangial stichidia cylindrical arising from the entire trichoblast
primordium; cystocarps unknown.

Algae minutae, ramos prostratos per rhizoidea unicellularia, per
dissipimentum a cellulis pericentralibus abscissa, affixos habentes;
rami erecti exogene orientes, in modo assurgente et quasi-decurrente
ramosi; cellulae pericentrales 8-11, ecorticatae; trichoblastae non
ramosae in quasi spira; tetrasporangia quorum unum in quoque
segmento, in paulula spira in ramis; stichidia spermatangialia cylin-
drica, e primordio toto trichoblastae enascentia; cystocarpi ignoti.

Hawauia trichia sp. nov.
Figures 5, 14
Erect branches to 2 mm. high and with branches of 3-4 orders,
60-70, in diameter in the lower parts, composed of segments mostly

210 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

shorter than broad; trichoblasts few, at intervals of 2-4 segments,
at first composed of a series of very short cells, which elongate to a
total length of 500 to 800» and are soon deciduous, leaving rela-
tively large pigmented scar-cells; tetrasporangia 40-55 in diameter
in series of 8-10; spermatangial stichidia oblong-lanceolate, to 240
x 50 on very short one-celled pedicels and sometimes with a short
one-celled sterile tip, arising from the entire trichoblast primordium.

Rami erecti ad 2 mm. alt., ramos 3-4 ordinum habentes, 60-704
diam. in partibus infimis, e segmentis plerumque brevioribus quam
lata compositi; trichoblastae paucae intervallis 2-4 segmentorum,
primum e serie cellularum brevissimarum compositae, hae deinde
longitudinem 500-800, attinentes, mox deciduae, cellulas-cicatrices
colaratas relative magnas relinquentes; tetrasporangia 40-55, diam.,
in serie 8-10; stichidia spermatangialis oblongo-lanceolata, ad 240
x 50u, in pedicellis brevissimis unicellularibus, interdum cacumen -
sterile breve unicellulare habentia.

TYPE: D. 17031.1, tetrasporic, on Amansia, Laupahoehoe Point,
Is. of Hawau, Jan. 29, 1953. Additional collections, all from the
Hawaiian Islands: D. 20059.1, tetrasporic, on Grateloupia sp.,
Waialua Oahu, Apr. 19, 1953; D. 19301, tetrasporic, along with
Polysiphonia scopulorum Harvey in a mat-forming association on
wave-dashed rocks at Kalaekapu, Molokai, Dec. 29, 1953; D.22483.2,
tetrasporic, on reef flat, Kahana, Maui, legit G. Hollenberg, Roy
Tsuda and Richard Buggeln, Apr. 20, 1965; D. 22535, spermaten-
gial, in algal turf, inter-tidal, near Honokohau, northern Maui, by
the same collectors, Apr. 20, 1965; D. 17027, tetrasporic, Laupa-
hoehoe Point, Is. of Hawau, Jan. 29, 1953; D. 17184AC, Kalapana
Beach, Kaimua Bay, Is. of Hawaii, Feb. 27, 1953.

This alga differs from Polysiphonia, to which it is closely related,
in several respects. Unbranched trichoblasts are not characteristic
of any species of Polysiphonia as far as the writer is aware. Also
the manner of insertion of the branches is different from that in
species of Polysiphonia. Although the branches arise exogenously
as in Polysiphonia, the basal segments of branches are mostly not
shorter than corresponding segments of the bearing axis. Further-
more, the pericentral cells of the basal segment are not reduced in
number as in exogenous branches in Polysiphonia. As a result the
branches appear somewhat decurrent as in Pterosiphonia. The
origin of the spermatangial stichidia from the entire trichoblast
primordium is a feature which this alga shares with only a few
species of Polysiphonia.

New genera from the Central Pacific Ol

Phaeocolax gen. nov.

Minute hemiparasites, with a discoid base, replacing the outer
layer of the host but without penetrating rhizoidal processes; erect
primary axis bearing several lateral branches radially arranged;
pericentral cells mostly about 8, surrounded by a cortex of 2-3
layers of cells somewhat smaller than the pericentral cells, which
develop pit-connections with adjacent cortical cells; branches bear-
ing numerous short, radially arranged, mostly simple, conical
branchlets; branchlets bearing numerous long, unbranched, color-
less trichoblasts; tetrasporangia in whorls of 5-8 per segment in the
branchlets; cystocarps globular-ovate, with a small ostiole on the
low conical apex; spermatangial stichidia very numerous, arising
from trichoblast primordia.

Plantae minutae hemiparasiticae, basim discoideam pro strato
hospitis exteriore substitutam habentes, sine, autem, processibus
penetrantibus rhizoideis, axis primarius erectus aliquot ramos later-
ales radialiter ordinatos ferens; cellulae pericentrales plerumque
c. 8 cortice 2-3-stratorum cellularum, paululo minorum quam cellu-
lae pericentrales, foveo-colligationes cum cellulis corticalibus con-
tiguis efficientum, circumdatae; rami ramulos multos breves radia-
liter ordinatos plerumque simplices conicosque ferentes; ramuli
trichoblastas multas longas non-ramosas incolores ferentes; verticilli
5-8 tetrasporangiorum utroque in segmento in ramis; cystocarpl
globulo-ovati, ostiola parva in apice conico humilique praediti; sti-
chidia spermatangialia plurima, e primordiis trichoblastae orientia.

Phaeocolax kajimurai sp. nov.
Figure 2, A-D

Hemiparasites on Pocockiella, with erect axes to 6 mm. high and
400-600 in diameter, simple or with several lateral branches;
trichoblasts to 2 mm. long and 12-17» in diameter, composed of
7-12 cells; tetrasporangia 17-19, in diameter; spermatangial sti-
chidia on 1-2-celled pedicels, very numerous near the apices of the
branchlets, 170-190 x 65-75, with a small one-celled sterile apex;
young cystocarps globular, at maturity with a low conical apex and
a small ostiole, to 285, in diameter.

Plantae in Pocockiella parasiticae; axes erecti usque ad 6 mm.
alt., 400-600, diam. simplices aut aliquot ramos laterales habentes;
trichoblastae ad 2 mm. long., 12-17, diam., e 7-12 cellulis com-
positae; tetrasporangia 17-19, diam.; stichidia spermatangialia in

212 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

pedicellis ex 1-2 cellulis compositis, plurima prope apices ram-
ulorum, 170-190 x 65-75, apicem parvum unicellularemque
habentia; cystocarpi iuvenes globosi, maturi apicem humilem co-
nicumque et ostiolam parvam, ad 285, diam. praebentes.

TYPE: H. 65-86, collected by Mitsuo Kajimura at Diamond Head
Beach, Oahu, Hawaii, May 9, 1965. This collection included tetra-
sporic, cystocarpic and spermatangial material. A single additional
collection, H. 65-123, cystocarpic, was made Oct. 2, 1965 by Mr.
Kajimura at the same locality.

The writer was at first of the opinion that this alga represented
the only known case of a red alga parasitic on a member of the
Phaeophyta. However, at least one such case has been previously
reported. Pleurostichidium falkenbergii was described by Heydrich
(1893: 345). It occurs on Xiphophora chondrophylla (R. Brown)
Harvey in New Zealand. Like Phaeocolax it is a member of the -
Rhodomelaceae. However, it is a very different plant, with dorsi-
ventral construction and strongly flattened branches, with 10-14
pericentral cells and a compact cortex.

Young plants of Phaecolax consist of a relatively deeply pig-
mented, small, discoid base, which is well developed before the
erect axis arises. The latter is less deeply pigmented as it matures.
Sections of the basal disc made perpendicular to the surface of the
host show that the discoid base displaces the outermost layer of
cells of the host. This basal disc consists of a single layer of cells
next to the subepidermal cells of the host (fig. 2B) and erect rows
of 2-3 cells arising from the basal layer. Prominent cytoplasmic
connections exist between the cells of this basal layer but no part
of the parasite appears to penetrate deeper into the host. The discoid
base is at first slightly elongate in the direction of the longitudinal
cell rows of the host.

As a result of the numerous secondary pit connections and the
somewhat stellate cell shape, the cortex of the main axes presents
a somewhat gigartinoid appearance.

The main erect axis is simple or with one to several laterals. The
very numerous, short, conical branchlets are simple or slightly
branched. They appear to arise in a more or less spiral arrange-
ment, but are so densely crowded that the arrangement could not
be definitely determined. The branchlets are in turn beset with
numerous long unbranched trichoblasts (fig. 2A).

Phaecolax resembles Jantinella (Kylin 1941:39) in having tetra-
sporangia in whorls. Kylin places Jantinella close to Bostrychia,

New genera from the Central Pacific 213

since each pericentral cell of a segment usually produces a tetra-
sporangium, and the pericentral cells are transversely divided.
Older axes of Phaeocolax are covered with a cortical layer, but no
evidence of a transverse division of the pericentral cells was ob-
served, although reported for Jantinella. Furthermore, the num-
erous unbranched trichoblasts of Phaeocolax is a feature not char-
acteristic of the Bostrychia group.

The relationship of Phaeocolax seems uncertain. The hemipari-
sitic nature of this alga is indicated by the broad base which dis-
places the surface layer of the host, by the reduced pigmentation
and by the very compact growth form, with correspondingly re-
duced photosynthetic surface.

Womersleyella gen. nov.

Chiefly prostrate algae, attached by multicellular rhizoids; peri-
central cells 5, ecorticate; chromatophores arranged in transverse
bands in the pericentral cells; prostrate branches without tricho-
blasts, but with undeveloped one-celled exogenous primordia, re-
sembling scar-cells, arising one per segment in a one fifth spiral
sequence; erect branches determinate, mostly unbranched, arising
from dorsal primordia, mostly every fifth segment, bearing abax-
ially one to several, relatively huge trichoblasts; tetrasporangia one
per segment in short spiral series; cystocarps and spermatangial
stichidia subterminal on the erect branches.

Algae principue prostratae, per rhizoidea multicellularia affixae;
cellulae pericentrales 5, ecorticatae; chromatophora in fasciculis
transversis in cellulis pericentralibus ordinata; rami prostrati sine
trichoblastis, habentes, autem primordia exogenosa Immatura, uni-
cellularia, cellulis-cicatricibus similia, uno in quoque segmento in
quinta parte spirae oritur; rami erecti determinati, plerumque non-
ramosi, e primordiis dorsalibus, saepissime omni quinto segmento
orientes, unam ad aliquot trichoblastas relative permagnas abax-
ialiter ferentes; tetrasporangia quorum unum in quoque segmento
in brevi spira ordinata; cystocarpi et stichidia spermatangialia in
ramis erectis subterminalia.

Womersleyella pacifica sp. nov.
Figure 3, A-C

Epiphytic, prostrate algae, forming patches to 3 cm. broad on
the host; erect branches to 1.5 mm. high and 40-75, in diameter,

214 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Figure 3.

A-C. Womersleyella pacifica

A. Prostrate branch bearing erect determinate branches.

B. Apex of a determinate branch with huge irichoblast.

C. Apex of prostrate branch showing early development of determinate branches
from exogenous primordia resembling scar-cells.

D. Womersleyella pacifica var. minor.
Prostrate branch bearing a short determinate tetrasporic branch and showing
zonate orientation of chromatophores in the pericentral cells of one segment.

New genera from the Central Pacific 245

commonly narrowed slightly at the base, arising from dorsal pri-
mordia mostly at intervals of 5 segments, but frequently in pairs
on successive segments, with corresponding members of the pairs
at intervals of 5 segments; trichoblasts to 1-2 mm. long and 40-604
in diameter at the base, with about four dichotomies, tapering to
rounded apices, arising on the erect branches at intervals of 2-3
segments, rarely more than one mature trichoblast present on a
given branch at one time, when shed leaving prominent scar-cells
and wall scars; tetrasporangia 50-70, in diameter, greatly distend-
ing the segments; cystocarps ovate, to 270. in diameter; sperma-
tangial stichidia 48-130» long, with 2-3-celled sterile tips, arising
from trichoblast primordia on very short pedicels.

Algae praecipue epiphyoticae prostrataeque, maculas usque ad
3 cm. lat. in hospite formantes; rami erecti usque ad 1.5 mm. alt.,
40-75, diam., ad basim plerumque paululum attenuati, e primor-
dus dorsalibus intervallis plerumque 5 segmentorum, saepe, autem,
bini in segmentis successivis enascentes; trichoblastae ad 1-2 mm.
long, 40-60, diam. ad basim, c. quattuor dichotomiis furcatae, ad
apices rotundatos attenuatae, In ramis erectis, intervallis 2-3 seg-
mentorum, orientes, raro plus quam una trichoblasta simul in ramo,
trichoblastae exutae cellulas-cicatrices et membranas-cicatrices con-
spicuas relinquentes; tetrasporangia 50-70« diam. segmenta ad-
modum distendantia; cystocarpi ovati usque ad 270 diam.; sti-
chidia spermatangialia 48-130 long., cacumina sterilia e 2-3 cellu-
lis constantia habentia, e primordiis trichoblastae in pedicellis bre-
vis-simis orientia.

The prostrate branches are mostly 65-75, in diameter, with seg-
ments 1-1.5 diameters long. Rhizoids 16-25 mm diameter, are mostly
short and are cut off by a cross-wall from the center of the peri-
central cells. They develop multicellular apices. The transversely
banded appearance of the chromatophores is very similar to that
found in a number of species of Herposiphonia and occasionally in
Ditria and in Rhodosiphonia (Hollenberg, 1943, fig. 11). However,
no primordia similar to those on Womersleyella occur on the inde-
terminate branches of Herposiphonia and there is no regular se-
quence of determinate and indeterminate branches as in the latter
genus. Although determinate branches arise only on the dorsal side
of prostrate branches, the apex of the latter does not exhibit any
other evidence of dorsiventrality, since the primordia resembling
scar-cells arise in spiral sequence, one on each segment. From these

216 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Figure 4. Ditria reptans

A. Branching portion of a mature branch.
B. Apex of branch bearing a young and a mature trichoblast.

New genera from the Central Pacific 2al7,

Figure 5. Hawatia trichia

A. Portion of a prostrate branch bearing erect branches and showing un-
branched trichoblasts.
B. Apex of tetrasporic branch.

primordia the determinate branches arise in a delayed exogenous,
or falsely cicatrigenous, manner. That they sometimes arise in pairs
on two successive segments seems to be due to the fact that in such
cases two primordia are equally dorsal in position.

TYPE: H. 65-63, tetrasporic, abundant on Pocochkiella sp. low lit-
toral, Wawamalu Beach, southeastern Oahu, Hawau, May 1, 1965.
It is represented by four glucose slides and some fluid preserved
material.

Additional collections: HAWAIIAN ISLANDS—D. 19127U1,
on Microdictyon sp., dredged 10-14 fa., Pokai Bay, Oahu, July 29,
1959; H. 65-94, tetrasporic, spermatangial, legit Mitsuo Kajimura,
Diamond Head Beach, Oahu, May 9, 1965; PHOENIX ISLANDS—
C. R. Long 2658.4, a fragment on other algae, Enderbury Is., Nov.
9, 1964; MARSHALL ISLANDS—H. 48-0290.5, cystocarpic, on
Pocockiella, inner reef, Eric. Is., Bikini Atoll, July 13, 1948; H. 48-
0914.9, tetrasporic, on Pocockiella, outer reef, Uku Is., Bikini Atoll,
July 9, 1948; H. 48-1091.4, on Halimeda sp., outer reef, Arji Is.,
Bikini Atoll, July 15, 1948; CAROLINE ISLANDS—D. 23253.1,

218 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

Figure 6-8. Womersleyella pacifica, photomicrographs.
6. Prostrate and erect branches.

7. Apex of erect branches showing young and mature trichoblasts.
8. Erect branches bearing spermatangial stichidia.

Figures 9-12. Dawsoniella bulborhiza photomicrographs.

9. Exceptionally short tetrasporic branches and prostrate branches.

10. Prostrate branch bearing two indeterminate lateral branches and a some-
what smaller determinate erect branch from the same node.

11. In the upper part of this photomicrograph may be seen a lateral indetermi-
nate branch and a procarpic determinate branch arising from the same node.

12. Prostrate branch showing the bulbous rhizoids some of which are bilobed.

New genera from the Central Pacific 219

tetrasporic, on dead coral, Dublon Is., Truk Is., legit E. Menez, July
31, 1960.

Womersleyella pacifica var. minor, var. nov.
Figure 3D

Similar to the species but much more delicate, with branches
30-35 in diameter and erect branches 80-125, high and with only
9-4 relatively large tetrasporangia in the greatly swollen segments
of the short fruiting branches.

Varietas proprietates speciei habens. sed minoribus, cum ramis
erectis 80-125, altis et 30-35, latis.

TYPE: H. 48-1213.21, tetrasporic, on Dictyosphaeria versluysi
Weber-van Bosse, Amen Is., Bikini Atoll, Marshall Islands, July 7,
1948. The type is represented by two glucose slide mounts. Addi-
tional collections: D. 9608D, tetrasporic, growing on Galaxaura sp.,
legit Leonard Horwitz, awash near Ine village, Arno Atoll, Mar-
shall Islands, Aug. 18, 1951; D. 23112.2A, on Microdictyon sp.,
eastern side of Ifalik and Falalap Is., (7°14’N., 144°27’E.), legit E.
Menez, Aug. 10, 1960. In the latter collection the segments of
prostrate branches are 1.5-2.0 diameters long and the erect branches
are infrequent and mostly very rudimentary.

Womersleyella is named in honor of Dr. H.B.S. Womersley of
Adelaide, Australia.

SUMMARY

The following new genera and species of Rhodomelaceae (Rho-
dophyta) are reported: Abbottella concinna, Dawsoniella bulbor-
hiza, Ditria reptans, Hawaiia trichia, Phaeocolax kajimurai, and
Womersleyella pacifica.

ACKNOWLEDGMENTS

This study was completed with support from U. S. National Sci-
ence Foundation Grant GB-2735. The author is grateful also for
the use of facilities at the University of Hawaii and for access to
the Library of Maxwell S. Doty of the University. Type material
will be deposited in the Smithsonian Institution, Washington, D. C.

220 ~=—- Bulletin So. Calif. Academy Sciences / Vol. 66, No. 3, 1967

LITERATURE CITED

FALKENBERG, P.
1901. Die Rhodomelaceen des Golfes von Neapel. Fauna und Flora des Golfes
von Neapel. Monograph 26: 1-754. Berlin.

HEYDRICH, F.
1893. Pleurostichidium, ein neues Genus der Rhodomeleen. Berichte der
Deutschen botanischen Gesellschaft. 11: 344-348.

HOLLENBERG, G. J.
1943. New marine algae from Southern California II. Amer. J. Bot. 30: 571-579.

KYLIN, H.
1941. Californische Rhodophyceen. Lunds Universitets Arsskrift. N. F. 37: 1-51.

1956. Die Gattungen der Rhodophyceen. XV + 673 pp. Gleerups, Lund.

PAPENFUSS, G. F.
1944. Structure and taxonomy of Taenioma, including a discussion of the phy-
logeny of the Ceramiales. Madronio 7: 193-214.

WOMERSLEY, H.B.S. and SHEPLEY, E.Ann.
1959. Studies on the Sarcomenia group of the Rhodophyta. Austral. J. Bot. 7:
168-223.

Figure 13. Photomicrograph of apex of branch of Phaeocolax kajimurai showing
immature cystocarps.

New genera from the Central Pacific 221

Figure 14. Apices of branches of Hawatia trichia showing unbranched tricho-
blasts and spermatangial stichidia.

Sih

Figure 15. Prostrate branch with mature terminal cystocarp on an erect branch.

ee

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Vou. 66 OcroBER-DECEMBER, 1967 No. 4.

CONTENTS

Zoospore Release Rates in Giant Kelp Macrocystis. Einar K. Ander-
son and Wheeler J. North

Micro-Algae in Enrichment Cultures from Puerto Pefiasco, Sonora,
_. Mexico. Richard E. Norris

Food Habits, Habitat Preference, Reproduction, and Diurnal Activ-

ity in Four Sympatric Species of Whiptail Lizards (Cnemido-
phorus) in South Central New Mexico. Philip A. Medica .... 251

New Records of Talitridae (Crustacea: Amphipoda) from the Cen-
tral California Coast. Z. L. Bousfield and James Carlton

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VoL. 66 OctToBER-DECEMBER, 1967 No. 4

ZOOSPORE RELEASE RATES IN GIANT KELP
MACROCYSTIS

Ernar K. ANDERSON AND WHEELER J. NortTH

W. M. Keck Engineering Laboratories
California Institute of Technology

INTRODUCTION

The giant kelp, Macrocystis, liberates spores from the fruiting
blades or sporophylls located near the apex of the holdfast. Little
is known about factors influencing release rates of Macrocystis
spores. Neushul (1959) observed sori on Macrocystis plants at all
seasons but presented evidence that a damaged bed displayed fewer
of these reproductive structures. He indicated that the developing
plant begins spore production when it reaches a size ranging from
two to eight stipes. Using the weight of fertile sporophylls as a
criterion of spore production, Neushul found that maximum weights
were obtained from plants weighing between 50 and 150 kg.

Knowledge of factors influencing spore release rates is very useful
for conservation and management work in kelp beds. We are at-
tempting to analyze the many possible variables that might affect
spore production in connection with our experimental efforts to re-
store deteriorated kelp areas in southern California. The present
paper summarizes certain aspects of spore production where tenta-
tive conclusions have been obtained. The general study, however,
is still in progress and further information may extend or modify
our findings. We propose to discuss the influence of sporophyll
appearance, plant size and age, locality, and season on spore release
rates.

MetHops AND APPARATUS
Sporophyll Selection

Certain precautions were observed when selecting samples to elimi-
nate variability that might arise from differences between sporo-
phylls. The principal objective was to obtain fruiting blades that
were healthy and mature (variation due to grazing damage and to

Epiror’s Nore: This paper and the following paper by Richard E. Norris com-
plete the memorial number honoring the late Dr. E. Yale Dawson which began
in volume 66, number 3.

223

224 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

10

No. above average
oO

No. below average
ol

Stipes per plant

Figure 1. Spore release rates as a function of plant size. Number of stipes was
adopted as the criterion of plant size.

99

sporophyll age will be assessed after a background of “normality
has been established). At any location, sampling emphasis was
focused on those plants having the most massive sporophyl1 bundles.
Sporophylls may or may not display optically dense areas and
these can be distinct or can blend gradually with adjacent, less
dense areas. The dense regions have been described as the sporogen-
ous regions (cf. Neushul, 1959), hence we collected preferentially
those blades with dense areas. Likewise blades with extensive dense
areas were chosen in preference to sporophylls with small areas.
If no dense areas were noted on any plants or when storm surge
and poor visibility hampered operations, sporophyll selection was
accomplished haphazardly. Such collections did not yield samples
superficially different in their release rates from the more carefully
selected collections. If multiple blades were present, they were col-
lected instead of single or double blades, since multiples are prob-
ably the oldest. Neushul (1959) noted that spore production was
more uniform when multiple blades were used in his culture studies.

Zoospore release rates in giant kelp Macrocystis 225

Ls)
oO

fo)

re)

ro)

ro)

Spore release rate, thousands per min. per cm2 of blade surface

SON D,J F MAM J J AS ON D,J FM
1965 | 1966 1967

Figure 2. Average spore release rate at four stations from September 1965 to
March 1967. A. La Jolla, depth 12 m; B. La Jolla, depth 19 m; C. Point Loma,
depth 10 m; D. Point Loma, depth 18 m.

Sampling Technique

The basic technique followed while sampling was to enclose a
sporophyll zn situ in a suitable container for a period and then pre-
serve and enumerate spores released during the experiment. Ini-
tially containers were plastic bags fastened around the sporophyll,
leaving attachment to the plant intact. Microscopic examination of
the plastic walls indicated that settling by spores on the interior
surface did not introduce appreciable errors. The bags proved diffi-

226 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

cult to manipulate on all but the calmest days, so small glass jars
were substituted and the sporophyll was severed just before en-
closure. On several days both bags and jars were used but no
statistically significant differences were found at p = 0.05 (Mann-
Whitney U Test). All samples gathered after 8 September 1965
employed the glass jar method exclusively.

Jar sizes initially ranged from 70 to 500 ml but a standard volume
of 130 ml was quickly adopted as a standard (no effect of jar size
on release rate was ever noted). It was necessary to coil the sporo-
phyll during enclosure. The physical twisting and abrasion in-
volved may have ruptured some sporangia but this was possibly
compensated for by lack of movement after the cover was screwed
onto the jar. Detachment from the parent plant undoubtedly would
have long term effects on spore production but this did not seem
to be important for the short duration of our experiments.

After about 30 minutes on the bottom, jars were brought to the ~
surface quickly and the sporophylls were immediately withdrawn.
A small volume of iodine solution was added to the water in the
jars to kill and preserve the suspended spores. Jars were reused
in subsequent experiments after tests showed no significant differ-
ences in rates obtained from new vs. used jars.

Processing

Spores were enumerated in the laboratory by hemacytometer.
When spore concentrations were high, sufficient fields were counted
until a total of about 300 spores was reached. For dilute concentra-
tions, a standard volume (arbitrarily chosen as 6.4 mm? per sample)
was examined. Sporophylls were preserved by freezing, pending
areal measurements and categorization. Areas were determined by
tracing outlines of the sporophylls on quadrille ruled paper and
counting squares in the delineated region. Any dark areas on the
blade were noted in the tracing. The blade was classified into one
of six categories (Table 2), photographed, and then discarded or
preserved if it was of special interest. Since 11 January 1966, blade
thickness was measured at representative points, but this informa-
tion has not yet been compared with other parameters. Blades were
usually thickest over the dark sporangious areas.

Concentration of spores by filtration was conducted on sparse
samples with a molecular filter. The technique was successful
and might be helpful when sample time intervals less than ten
minutes are involved. Our work during 1965-67 employed longer

Zoospore release rates in giant kelp Macrocystis 227
TABLE 1

Summary of spore release rates measured at four locations during
the period 14 April 1965 to 7 March 1967.

No. of Running Ave. No/min/cm?
plants No. of Sampling release Inclusive
sampled samples days rate x 10-3 dates
Location
Bahia 3 6 1 3.8 4/28/65 only
Tortugas
Point
Loma 126 4.65 26 3.9 5/19/65 to
3/7/67
La Jolla 132 475 27 4.0 4/14/65 to
2/27/67
Crystal 13 42 6 2.7 4/17/65 to
Cove 9/21/65
Total 274: 988 60 3.9
TABLE 2

Categories used for characterizing Macrocystis sporophylls en-
countered in our surveys of sporulation rates.

Percent
Frequency

Category Description in Samples
I Deep corrugations, evenly colored 9.5
II Smooth, no corrugations, color even

to slightly mottled 7.2
Ili Corrugated, well defined dark area,

often two dark areas 63.2
I-III Intermediate between I and III, deep

corrugations, ill defined dark area 2.9
II - Ill Intermediate between II and III, smooth,

ill defined dark area 10.1
Misc. None of the above* 7.2

*There were no intermediates between I and II, but occasionally a blade was
Type I in one section and Type II in the remainder.

sampling times. Likewise a high degree of accuracy was not neces-
sary for the dilute samples so filtration was rarely used. Enumera-
tion by Coulter Counter was also attempted and required some
attention to problems of spore clumping and the presence of
detritus. Processing time was comparable to the hemacytometer
method. The Coulter Counter was located at quite some distance
from the Marine Laboratory, so that all enumeration was done by
hemacytometer.

228 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

RESULTS
Ranges and Averages for Release Rates

During the period 14 April 1965 to 7 March 1967, 988 spore
samples were gathered on 60 different days. A total of 274 plants
were assayed at four different locations along about 800 km of
coastline (Table 1). Release rates ranged from nil to almost 76,000
spores per minute per cm? of sporophyll surface. Variation was
considerable, not only from one location or time to another but also
among plants within a restricted region and even for sporophylls
from the same plant on the same day.

Running average release rates for the various beds ranged from
2700 to 4000 spores/min/cm? for the selected sporophylls (‘Table 1).
Any differences were probably not significant. Statistical tests were
not made, however, but daily variations were often so large that
it was considered unlikely that any of these rather small differences _
would be significant. As we learn more about factors influencing
sporulation rates it may be possible to eliminate some of the varia-
tion. In the light of present knowledge it can reasonably be con-
cluded that average annual rates for healthy beds lie in the range
of 1000 to 5000 spores/min/cm? of sporophyll surface.

Effect of Sporophyll Type

As indicated above, sporophylls have a varied appearance and
we have arbitrarily established five categories based on the mor-
phology of the most frequently occurring types. There is also a
miscellaneous category for blades that do not fit any of the charac-
ters we have chosen (Table 2). Data for the period 8 September
1965 to 22 February 1966 were examined to see whether sporo-
phyll appearance bore any relation to average release rate. When
sporulation rates for the different types were tabulated, no large
differences between the means appeared with the exception of the
miscellaneous category which was quite low (Table 3). Types I,
II, I-III, and II-III yielded fairly similar means and ranges.
Type II was twice as great as the others, however, and had a much
wider range with the exception of Type III. Since Type III repre-
sented six to nine times as many samples, it is not surprising that
the range was broad. It seems safe to conclude that the different
morphological types we have designated do not display important
differences in sporulation rates with the possible exception of
Type II, a smooth, even colored, or slightly mottled blade. This type

Zoospore release rates in giant kelp Macrocystis 229
TABLE 3

Spore release rates as a function of sporophyll type. Mean rates

and ranges represent spores released per minute per cm? of sporo-

phyll surface. Sporophylls came from La Jolla and Point Loma,
during the period 8 September 1965 to 22 February 1966.

Sporophyll No. Average Range of rates
type sampled rate x 10-8 x 10-3

I 29 2.08 ORAS0

II 22 5.32 0 - 26.0

III 194 DHS} 0 - 28.9

I-III 9 2.61 0.03 - 11.6

II - Il 31 1.69 0 - 15.9

Misc. 22 0.01 0 - 0.22

TABLE 4

Average spore release rates from sampling stations at La Jolla and
at Pomt Loma. Samples collected approximately monthly from
September 1965 to March 1967.

Total Spore release rate
Depth sampling spores/min/cm2 No. of
m Interval days Total of blade samples
Location
Point Loma 10 9/8/65 to 14 190 3300
3/7/67
Point Loma 18 9/29/65 to 15 912 44.00
3/7/67
La Jolla 12 9/24/65 to ly 251 5100
2/27/67
La Jolla 19 11/30/65 to 14 174 3300
2/27/67

is not common, however, and at present there is no reason to believe
that sporophylls assume this appearance when they become highly
fertile, since Type III sporophylls can have equally high release
rates.

Effect of Plant Size and Age

The criterion of plant size used in our studies has been numbers
of stipes per plant. Stipe counts were made on most of the plants
sampled, at a level of about three feet from the bottom. For young
plants there is a rough correlation between age and stipe numbers
im areas where grazing is not intense. At depths of 30 to 40 feet
a plant may develop 10 to 20 stipes in a year, in two years it may

230 © Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

display 20 to 40 stipes, and by the end of the third year ranges
from 40 to 90 stipes. If stipe grazing becomes significant, total
stipes per plant may decrease instead of increase (North, 1964).

Considerable differences in release rates were found from one
sampling period to the next and we have noted that this may
reflect changes in season or other environmental circumstances.
On some days all plants sampled would yield low rates and on
other days a major proportion would be sporulating copiously.
When attempting to determine relationship of plant size to sporu-
lation capacity, therefore, it was necessary to take account of the
tendency toward “coordinated fluctuation.” This was attempted by
considering sampling days independently. Sporulation by the
plants within each day from 14 April 1965 to 22 February 1966
were classified as above or below the average of that day. The
numbers of higher-than-average plants and lower-than-average
plants were then summed for each size class for all sampling days.
The method has one shortcoming arising from the fact that the
size distribution of plants sampled was not uniform from one day
to another. If, however, a marked correlation exists between plant
size and sporulation rate, this method should yield a predominance
in higher-than-average values at one end of the size range and
lower-than-average plants should prevail at the other end of the
range.

Each size class embraced two plant sizes because of the paucity
of data. A total of 71 plants was considered, ranging in size from
6 to 52 stipes. There were 27 higher-than-average plants (38 per-
cent of the total) and 44 lower-than-average individuals (62 per-
cent). For the smallest three size groups there was a moderate
tendency to be higher-than-average and for the largest nine size
groups there was a tendency to be lower-than-average (Figure 1).
This would support the conclusion that smaller plant sizes are more
prolific than larger individuals. It should be noted, however, that
if we were to consider five size classes at the small end of the range
and eleven size classes at the large end one would conclude that
no relation was demonstrated. It seems wisest at the present time
to refrain from drawing final conclusions, but certainly no un-
equivocal evidence was obtained that indicated smaller plants were
more productive, or vice versa.

As a result of our kelp restoration work the age of certain plants
that we sampled was known accurately and it was possible to
determine when they first began to produce spores in significant

Zoospore release rates in giant kelp Macrocystis 231

quantities (maximum averages amounting to 11,700 spores/min/
cm?). It appears that this stage of maturity is attained at the age
of nine months to a year for plants standing in water about ten m
deep. This conclusion is compatible with the smallest range of
plant sizes found to be fertile by Neushul (1959).

Effects of Location, Depth and Season

To study the effects of location, depth, and season on an intensive
basis, stations at depths of about ten and twenty meters were
selected at Point Loma and at La Jolla. The stations within each
pair were separated by about five km and the La Jolla pair lay
about twenty km from the Point Loma pair. Monthly sampling
commenced in September 1965 and results have been computed
through March 1967. Considering a total of 827 samples, no large
differences appeared between La Jolla and Point Loma (Table 4).
Likewise no substantial differences were apparent that could be
ascribed to the depth parameter. Statistical significance levels for
the observed differences were not calculated but variability was
very large and casual inspection of the data strongly suggested
that little would be gained by such calculations.

When average rates for each station are plotted as a function
of time, indications of fluctuations related to season seem apparent
(Figure 2). In the shallow beds, mid-fall to early winter appears
to be a time of moderate release rate but a drop occurs in mid-
winter. Recovery begins in spring and maximum rates occurred
during late spring and early summer.

At the deep stations a seasonal pattern was somewhat less clear
than the shallow station data, but close to maximal release rates
did occur in late spring and summer, although the values were not
consistently high from month to month. The trend for the deep
station at La Jolla was perhaps confused further by the fact that
this section was adversely affected by warm temperatures and
grazing in late summer 1966. Spore release rates fell drastically
during fall 1966, but began a slight recovery in 1967 that closely
paralleled an improvement in the physical appearance of the plants.

SUMMARY

1. Spore release rates for adult Macrocystis were determined by
maintaining sporophylls in closed containers in situ for short
periods. Concentrations of released spores were determined follow-

“=

232 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

ing killing and fixation and results were computed in units of spores
released per minute per cm? of sporophyll surface.

2. Data reported were gathered from 14 April 1965 to 7 March
1967 and represent 928 samples from 274 plants. Four principal
locations were studied spanning about 800 km and covering depths
from about ten to twenty m. Release rates for individual sporophylls
ranged from 0 to 76,000 spores/min/cm?. Mean annual values for
normal, healthy beds ranged from 1000 to 5000 spores/min/cm?.

3. Reproductive maturity, as judged by spore release rate, was
attained at ages of nine to twelve months. No clear-cut differences
were found between small and large plants, using stipe number as
a size criterion.

+. Intensive studies at four stations did not reveal large differences
in average release rates as a function of depth or location. Seasonal
changes may occur, peaks in production tending to appear in late |
spring and early summer. A secondary peak sometimes occurred
in fall and early winter. Results for the seasonal study only em-
braced an eighteen month period. Work on the seasonal aspect is
still in progress and it is hoped that further data will confirm our
present tentative conclusions.

ACKNOWLEDGMENTS

It is a pleasure to acknowledge assistance in the field from
Laurence G. Jones, David L. Leighton, and Charles Martin. Sup-
port was provided by grants from the Kelco Company of San Diego,
the San Diego County Fish and Game Commission, and the U. S.
Public Health Service. We are grateful for typing assistance from
Marjorie Connely and Peggy Freeland.

LITERATURE CITED
NEUSHUL, MICHAEL
1959. Studies on the growth and reproduction of the giant kelp, Macrocystis.
Uniy. Calif., Ph.D. Thesis, 134 pp.

NORTH, WHEELER J.

1964. Ecology of the rocky seashore environment in southern California and
possible influences of discharged wastes. Proc. 1st Intl. Conf. Wtr. Pol.
Res., 3: 247-262.

Accepted for publication June 1, 1967.

MICRO-ALGAE IN ENRICHMENT CULTURES FROM
PUERTO PENASCO, SONORA, MEXICO!

RicHArpD E. Norris

Department of Botany
University of Washington, Seattle

INTRODUCTION

In June, 1966, the author visited the newly established marine
laboratory at Puerto Penasco, Mexico, near the northern end of
the Gulf of California. This facility is jointly run by the University
of Sonora and the University of Arizona. It is located in a region
of excellent reefs that often are exposed by extremely low tides.
Tide pools formed by the receding tide are exposed to very high
temperatures (average air temperature in August for 15 years—
29.7°C) in the summer months, and many macroscopic algae do
not survive in these pools during the summer. Dawson (1966a and
1966b) reported on a surprisingly rich macroscopic algal flora
from Puerto Penasco. Because microscopic algae from such an envi-
ronment have not been investigated, I established enrichment cul-
tures from tide pools and off-shore water near the marine station at
Puerto Penasco. Maximum sea surface water temperatures at Puerto
Penasco often reach 32°C in the summer months, and during the
period of my visit, June, 1966, the highest sea surface water tem-
peratures were approximately 27°C. Several very rare species of
micro-algae were found in these cultures in addition to two new
species and other algae that seem to be ubiquitous.

MATERIALS AND METHODS

Four ounce jars containing 50 ml. of enriched sea water were car-
ried to the tide pools and inoculated with from 10 to 25 ml. of
water from the various pools. The sea water enrichments used are
of two types: 1) a modified Erd-Schreiber medium containing soil
extract, nitrate, phosphate, and trace metals; and 2) a medium
formulated by Provasoli (personal communication) containing ni-
trate, glycerophosphate, P-II metals, iron, thiamin, biotin, and
vitamin By. The enrichment cultures were placed in an ice chest
soon after they were inoculated, and remained in the ice chest
until they were transported to the laboratories at the University

1Contribution no. 7 to the Puerto Penasco Marine Research Station.

233

234. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

of Washington, approximately three days later. The cultures were
then removed from the ice chest and placed in an incubator with a
16 hour light cycle and a temperature that varies between 20 and
24°C. The micro-flora of these enrichment cultures has been ex-
amined over a period of ten months, and several species of photo-
synthetic phytoplankton and other micro-algal organisms were
isolated from them into unialgal cultures.

OBSERVATIONS

Although blue-green algae dominated many of the enrichment cul-
tures and probably are a major part of the micro-algal flora of
Puerto Pefiasco, this study includes only a survey of Chlorophyta,
Xanthophyta, Chrysophyceae, Haptophyceae, and Pyrrhophyta
that appeared in the enrichment cultures.

CHLOROPHYTA

Nephroselmis longifilis (Butcher) comb. nov.
Figures 1a, b.

Synonyms: Anisomonas longifilis (Butcher) 1959, p. 38.
Heteromastix longifilis (Butcher) Rayns in Parke
and Dixon 1964, p. 528.

There seems to be no clear means of distinguishing the genera
Nephroselmis Stein (1878) and Heteromastix Korshikov (1923),
and I concur with the opinions of Skuja (1948, p. 66), Butcher
(1965, p. 406), and Bourrelly (1966, p. 89) in that these two genera
should be recognized as one, at least until the type species of
Nephroselmis can be isolated and examined with the electron micro-
scope. Korshikov (1938, p. 53) mentioned that there is similarity
in the morphologies of the two genera, but he maintained the
genera separate on the basis of the clear green color of the chromato-
phores in Heteromastix and the protuberance to which the flagella
are attached in that genus. Korshikov considered Nephroselmis to
be a member of the Cryptophyceae and Heteromastix a member of
the Chlorophyta. Recent monographs, however, place Nephroselmis
with the Chlorophyta (Bourrelly, 1966, p. 89). The protuberant
point of flagellar attachment is not a character of enough impor-
tance to be used in separating genera. The microanatomy of the
cells, as demonstrated by Manton, Rayns, Ett], and Parke (1965)
for Heteromastix, and by Parke and Rayns (1964) for Nephrosel-
mis, provides no basis for separating these genera.

Micro-Algae Cultures

to
Oo
Or

Figure 1. a and b. Nephroselmis longifilis. a. Cell with flagella in resting posi-
tion. b. Cell with chloroplast about to divide; two new flagella developing and
two stigmata present.
c, d, and e. Ochromonas mexicana sp. nov. Various forms of motile cells.
f. A scale from the coccosphere of Ochrosphaera verrucosa.
g. A zoospore from a cyst of Chlorarachnion reptans.
h, and i. Zoospores of Platychrysis neustophila sp. nov.
j. A zoospore of Pleurochrysis scherffelii.

236 ©. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

In general morphology of the cells and in stages of cell division,
as seen with the light microscope, the cells in the culture from
Puerto Penasco agree with the descriptions for this taxon by
Butcher (1959) and Manton et al. (1965). There are, however,
two exceptions that should be noted: (1) the size of cells in the
Mexican cultures varies from 4-8 x 5-7 x 2-2.5 p, a range in size
more comparable to Butcher’s report than to the range reported
by Manton et al. (2.5-4.5 x 3-5 x 1.5-2 »). Manton et al, supposedly
used subcultures from the type culture isolated by Dr. Mary Parke,
and the variation in dimensions of the cells may reflect an inter-
esting and significant change in the cultured population over the
approximately 14 years that it has been maintained. (2) the stigma
in the Mexican cultures usually divides at a very early stage, before
the pyrenoid or nucleus divide (fig. 1b). It is quite usual for larger
cells to contain two stigmata, one on each lobe of the chloroplast,
before there is any indication of division of the pyrenoid.

Chlorella salina Butcher 1952, p. 179.

The size, shape, and general internal morphology of the Mexican
cells are very much like the cells described by Butcher for Chlorella
salina. Four or eight autospores are regularly found in the cultures
of the Mexican strain, whereas Butcher reported that the cells in
his isolate produce eight autospores. Cells in the Mexican cultures
range from 3.5 to 8.5 » in diameter.

Stichococcus sp.
Figure 3
Stichococcus often is very abundant in enrichment cultures and
is a contaminant difficult to control when isolating micro-algae.
The species from Puerto Pefiasco seems to be identical to a species
isolated from Pacific Grove, California. It is difficult to assign a
species name to these cultures because there seems to be no marine
species described to which they can be assigned. Experimental in-
vestigations may show that this species is the same as one growing
in freshwater.
XANTHOPHYTA
Chlorarachnion reptans Geitler 1930, p. 634.
Figure 1 g.
This very interesting amoeboid organism has not been found,
so far as I know, since it was originally described by Geitler from

Micro-Algae Cultures 237

marine cultures inoculated at Las Palmas, Canary Islands. Exten-
sive colonies of cells, joined by their colorless arachnopodia, were
observed in one of my enrichment cultures. The morphology is
identical to the species described by Geitler. Carter’s Rhizochloris
arachnoides (1937, p. 24) is very similar to Chlorarachnion with
the exception that the pseudopodia do not join the cells as in the
latter genus. It seems possible that some environmental factor
caused the separation of the cells in Carter’s cultures, and that
these organisms may represent the same taxon. Chlorarachnion
reptans from Mexico has been isolated into unialgal culture, and
it is hoped that experimental studies may show whether or not these
two taxa should be fused into one.

Geitler mentioned an encysted stage in his description of Chlora-
rachnion, and cysts have been commonly found in old cultures of
the Mexican isolate. The cysts are elliptical to spherical in shape,
approximately 10 » in diameter and seem capable of producing
either amoeboid cells or flagellated cells. Numerous uniflagellate
cells (fig. 1 g) are found in some of the older cultures, the single
flagellum is attached in a shallow lateral groove near the anterior
end of the cell. The flagellum is thick and approximately twice the
length of the cell. Studies are being continued to determine the role
in which the flagellated cells may be involved in the life history
of this organism.

CurysopHyta, Chrysophyceae
Ochromonas mexicana sp. nov.
Figures 1 c, d, e.

Cellulae cordatae ad hemisphericas, extremitate anteriore trun-
cata, canaliculum depressionemve vadosam ubi duo flagella affixa
sunt plerumque habente. Extremitas posterior late rotundata ad
obtuse acuminatam. Flagella longitudine inaequa, uno 11% - 2 plo
longiore quam cellula, altero ad 1% plo breviore quam cellula.
Unicum chromatophorum dilute aureum, taeniaforme, cellulas
intus circumdans, plerumque secundum axem anterio-posteriorem.
Pyrenoides non visa. Stigma parvum sed conspicuum chromato-
phoro affixum, ad extremitatem juxta regionem affixionis flagel-
lorum. Granula parva in cytoplasmate dispersa. Cellula plastica
formam interdum mutans praecipue in extremitate anteriore.
Cellulae 4-8 x 5-7 4, ut videtur non compressae. Status immobiles
in culturis saepe visi. Hae cellulae in strato mumbranulae super-
ficialis saepe visae, per stratum tenue materiae gelatinosae ut

238 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

Figure 2. Amphidinium operculatum (Phase contrast, X1875), dorsal view.
Figure 3. Stichococcus sp. (X1625).
Figure 4. Pleurochrysis scherffelii (X1400), Gloeochrysis-stage.

Micro-Algae Cultures 239

videtur circumdatae. Cellulae immobiles in colonias laxas, per divi-
sionem cellularum immobilium interdum formatas, saepe aggre-
gant. Plantae in cultura mixta “enrichmente,” e loco Puerta
Penasco dicto lecta, observatae.

Cells cordate to hemispherical in shape, the flagellar end truncate
and usually with a shallow depression where the two unequal
flagella are attached. The posterior end broadly rounded to bluntly
pointed. Flagella unequal in length, the longer flagellum 11% to 2
tumes the length of the cell. The shorter flagellum is up to one-half
the length of the cell. Cells with a single light-golden chromato-
phore, ribbon shaped, and encircling the cell, usually along the
anterior-posterior axis. A pyrenoid was not seen. A small but con-
spicuous stigma is attached to the chromatophore at the end near
to the flagella attachment region. Small granules are dispersed in
the cytoplasm. The cell is plastic and may change its shape, par-
ticularly at the anterior end. Cells 4-8 x 5-7 »; the cells do not
seem to be compressed. Non-motile stages often are visible in the
cultures. These cells often are in the surface film layer and seem
to be surrounded by a thin layer of gelatinous material. The non-
motile cells often aggregate into loose colonies that may be formed
by division of the non-motile cells. Observed in a mixed enrichment
culture from Puerto Penasco.

Pedinella hexacostata Vysotsky 1888.

This species was originally described from Slavic salt lakes, but
it appears that it may be a relatively common neritic flagellate,
at least in certain parts of the world. It was recently reported from
Great Britain (Lackey and Lackey, 1963, p. 799; Butcher, 1965,
p. 407) and is known to occur at Pacific Grove, California (Norris,
1965, p. 592). It is relatively common in one of the enrichment
cultures from Puerto Pefiasco.

CurysopHyta, Haptophyceae
Pleurochrysis scherffelii E. G. Pringsheim 1955, p. 403.
Figures 1), 4, 5

Masses of cells that appear to be Pleuwrochrysis scherffelii de-
veloped in one of the enrichment cultures. Several different stages
of growth are present including naked, motile, biflagellate cells (the
haptonema, however, was not observed), non-motile Chrysosphaera
and Gloeochrysis stages, and filamentous Chrysotila- and Apisto-

240 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

Figure 5. Pleurochrysis scherffelii (X1875), Chrysotila-stage.

Micro-Algae Cultures 241

nema-like stages. In another culture only Chrysotila- and Apisto-
nema-like stages developed. It is possible, of course, that these plants
are stages in the life histories of other coccolithophorids (Parke,
1961), but they closely resemble the morphology and dimensions
of Pleurochrysis scherffelii as described by Pringsheim from the
eastern coastal region of Great Britain, occurring in brackish water.
Coccolith bearmg cells have not been observed in these cultures.

Platychrysis neustophila sp. nov.
Figure 1 h,1, 6

Cellulae a facie visae circulares ad paululum angulares, a latere
visae fere hemisphericae; 6-12 », diam., 4-6.5 » crass. Latus plana-
tum cellularum membranulae superficiali aquae saepe adhaerens.
Flagella haptonemave non manifesta in cellulis sedentariis per
macroscopium luce utentem visis. Unicum chromatophorum mag-
num in omni cellula. Chromatophorum, autem, in duobus segmen-
tis principalibus profunde lobatum, isthmo segmenta coniungente
saepe angusto atque aegre viso ut cellulae duo chromatophora
discreta habere videantur. Multa granula minuta in peripheria
cellulae. Aliquot granula permagna irregulariter rotundata, proba-
biliter e chrysolaminarino composita, necnon aliquot corpora m1i-
nora globulariaque, probabiliter oleosa, in omni cellula plerumque
videntur. Unicus nucleus parvus propre centrum celluae situs.

Hae cellulae, vulgo neustonicae, duo flagella longitudine aequa
atque unicum haptonema breve, in canaliculo valdoso in parte
cellulae anteriore posita, interdum producunt. Ob has appendiculas
cellulae mobiles fiunt. Tales cellulae ellipticae ad cylindricas, atque
chromatophorum in parte anteriore 4% ad 2/3 cellulae plerumque
situm praebunt. Cellulae mobiles cito natant, demum quiescunt,
appendiculas amittunt, atque in formam fere eandem rotundatam
ut im cellulis aliis immobilibus abeunt.

Cells with a circular to slightly angular outline in face view,
almost hemispherical in lateral view. Cell diameter ranging from
6 to 12 , cell thickness from 4 to 6.5 . Flattened side of cells often
adhering to the surface film of the water. No flagella or haptonema
evident with the light microscope in the sedentary condition.
A single large chromatophore is present in each cell. The chromato-
phore is deeply lobed into two major segments; the isthmus joining
the segments is often narrow and difficult to see so that the cells
appear to possess two separate chromatophores. Many minute

242 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

granules line the cell periphery. Several very large, irregularly
rounded granules, probably chrysolaminarin, are usually present
in each cell. Also, several smaller globular bodies, probably oil,
usually are present in the cells. A single small nucleus lies near
the center of the cell.

These cells, commonly neustonic, may produce two flagella,
equal in length, and a single short haptonema, attached anteriorly
on the cell in a shallow groove, and with these appendages the cells
become motile. Such cells are elliptical to cylindrical in shape,
the chromatophore usually occupying the anterior 144 to 2/3 of the
cell. The motile cells swim rapidly and eventually settle, loose their
appendages and change their shape to approximately the same
rounded form as in other non-motile cells.

Platychrysis pigra Geitler 1930, p. 631-633, 635, the type species
of the genus, retains its flagella and haptonema in its non-motile
attached phase. The haptonema seems to extend to the surface film
and may aid in attaching the cell. The two flagella usually are
coiled around the haptonema within a depression in the cell.
P. neustophila differs from the type species in not retaining flagella
or haptonema in the non-motile phase. Another notable difference
is in the number of chromatophores in each species. Two chromato-
phores are reported for P. pigra by both Geitler and N. Carter (1937.
p. 44), whereas one chromatophore is present in the cells of P
neustophila. Further observations on P. pigra should be made to
determine if it may not have a single deeply lobed chromatophore
like that of P neustophila.

Ochrosphaera verrucosa Schussnig 1940, p. 318.
Figures 1 f, 7.

The numerous cells of Ochrosphaera found in many enrichment
cultures seem to be of the same taxon, probably O. verrucosa, a
species described by Schussnig from the waters of the Istrian Penin-
sula. As far as I know, the coccolith structure for species of Ochro-
sphaera has not been described using electron microscopy. With the
light microscope coccoliths appear to be irregularly spaced on the
coccosphere, and have an elliptical outline in O. verrucosa (fig. 7).
Profiles of coccoliths (fig. 7) show angular wedge-shaped bodies
up to approximately 1 » long. Good electron microscope photo-
graphs of these bodies have not been obtained, but certain details
of structure have been revealed. The basic unit on the coccosphere
seems to be wedge-shaped and of various sizes ranging from 0.2 to

Micro-Algae Cultures 243

1.3 » in length, and from 0.14 to 0.45 » in width (fig. 1 f).
These crystal-like bodies are similar in size and shape to the upright
bodies as they appear around the margins of cells when viewed with
the light microscope. The crystals have thickened ends, usually, and
the narrower end of the wedge usually has an enveloping ring of
electron dense material that may be organic (fig. 1 f). Although
more investigation is necessary before coccolith morphology can
be described, one can postulate that the bodies resembling coccoliths
under the light microscope may actually be a ring of the wedge-
shaped crystals standing upright on their pedestals. Covering the
cell in the center of the rings and also between the rings are other
wedge-shaped crystals lying on their flat sides and slightly over-
lapping one another. The angular appearance of the marginal
bodies on coccospheres viewed with the light microscope seems
to be the face view of one crystal in such a ring of wedge-shaped
crystals. It appears that there are usually six crystals forming the
ring-shaped coccolith-like bodies.

PyRRHOPHYTA
Amphidinium operculatum Claparede et Lachmann 1859, p. 410.
Figure 2

Numerous cells of this species of Amphidinium were found in
several of the enrichment cultures. Designation of species within
the genus Amphidinium often is difficult because range of morpho-
logical characters is not well defined in most species. A. opercula-
tum is the type species of the genus, and it has been acknowledged
as very plastic in its morphology. The epicone of this species is
small and triangular-shaped, and is located on a broadly rounded
hypocone that is more or less compressed dorso-ventrally. Golden
chromatophores radiate from a centrally located pyrenoid that often
is covered with many starch platelets. The large nucleus is located
in the posterior part of the hypocone. Several species of Amphi-
dinium have been described that may belong within the A. oper-
culatum range of morphological variation. These species are:
A. klebsti Kofoid et Swezy (1921, p. 144), A. herdmanii Kofoid et
Swezy (1921, p. 143), A. massartii Biechler (1952, p. 25), and
A. wislouchii Hulbert (1957, p. 199).

This organism is the most abundant of the flagellates in my
Puerto Penasco collections.

244 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

Figure 6. Platychrysis neustophila sp. nov. (X1875), amoeboid, aflagellate stage.
Figure 7. Ochrosphaera verrucosa (Phase contrast, X1875), coccospheres
shadowed with carbon-platinum.

Micro-Algae Cultures 245

Ostreopsis monotis (Meunier) Lindemann 1928, p. 97.

Described from brackwish water at Nieuport, Belgium, this small
armored dinoflagellate appeared in an aquarium in which a coelen-
terate, Aiptasia californica, is being maintained. The Azptasia speci-
mens were collected at Puerto Penasco by Mr. T. Pardy of the
Department of Zoology, University of Arizona. Ostreopsis appeared
in the aquarium approximately two months after it was inoculated
with the animals in June, 1966. It was abundant in the aquarium
for approximately a week, and has not been observed in the aquar-
ium since that time. Fortunately, this species was isolated into uni-
algal culture, and is being maintained in culture in our laboratory.

Symbiodinium microadriaticum Freudenthal 1962

Zooxanthellae are abundant in the coelenterate Azptasia califor-
nica Carlgren that was collected at Puerto Penasco by Mr. T. Pardy.
Living specimens of the animal and its symbiont are being main-
tained in aquaria in my laboratory. These zooxanthellae seem to
be identical in morphological details to the cells described by
Freudenthal. Three animals containing zooxanthellae have been
isolated in separate dishes, and have been maintained in the light
without supplementary food for over three months. Periodically pel-
lets of living zooxanthellae cells are excreted by the animal. There
is a strong indication that Azptasia californica is able to live en-
tirely on the photosynthetic products produced by its zooxanthellae.

DiscussIoN

The species described in this report are, for the most part, relatively
uncommon. Two species have not been described previously, four
species, Chlorarachnion reptans, Ochrosphaera verrucosa, Ostreop-
sts monotis and Nephroselmis longifilis have not been reported since
they were originally described. Pedinella hexacostata is known from
its type locality, and was recently reported near Plymouth, Eng-
land, by Lackey and Lackey (1963) and at Pacific Grove, Cali-
fornia, by Norris (1965). Amphidinium operculatum is widespread
in its distribution as are the commonly found marine species of
Stichococcus and Chlorella. Pleurochrysis scherffelii seems to have
been recorded only in Great Britain, but comment on its distribu-
tion should be reserved until more definite identification is made
of the Mexican taxon.

Patterns of population formation often can be followed in marine

246 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

enrichment cultures. In cultures inoculated in the Straits of Juan
de Fuca and San Juan Islands, Washington, species of Platymonas
(Tetraselmis ) often become dominant after a series of diatom spe-
cles appear in the cultures. Similar cultures inoculated with water
from the Monterey Peninsula, California, often produce abundant
cells of Pyramimonas, a genus not observed in Washington cultures
up to this time. Platymonas also occurs in the California cultures,
but it is much less common than Pyramimonas. It is interesting
to note that similar enrichment cultures grown in New Zealand
(Norris, 1964) also produced large numbers of Pyramimonas cells,
but no Platymonas. In Britain, apparently, both of these genera
seem to be well represented in the enrichment cultures. Conrad
and Kufferath (1954), however, reported abundant species of
Pyramimonas but only one species of Platymonas mostly from field
collections in the region of Liiloo, Belgium. These observations are
noted here because both Platymonas and Pyramimonas were absent
from the Mexican cultures. Instead, in these cultures, appearing in
approximately the same numbers and in the same sequence of
species types during development of the population, were Amphidi-
nium operculatum and Ochrosphaera verrucosa. These two species
occurred in every culture and were dominant species, especially in
older cultures.

The possibility that there may be differences in species of micro-
organisms appearing in enrichment cultures inoculated at different
latitudes or from areas of similar water temperatures and, perhaps,
salinities, is worthy of note at this early stage of investigation.
Ochrosphaera verrucosa was originally described from collections
on the Istrian Peninsula in the Adriatic Sea. Although the Adriatic
Sea is in a more northern latitude than the Gulf of California, it is
similar in that it has quite warm surface water temperatures during
the summer season. Amphidinium operculatum apparently is ubiq-
uitous in estuary and neritic habitats, and it is not surprising
that a strain has adapted to the exceptionally warm water of the
northern Gulf of California. It is especially interesting to note that
Chlorarachnion reptans has been found only in two sub-tropical
regions, the Canary Islands and Puerto Penasco, assuming that
these collections are a taxon different from Carter’s Rhizochloris
arachnoides.

Nephroselmis longifilis has been found only in Great Britain
before this time, but closely related green flagellates have been
observed in various other regions (California, Washington and

Micro-Algae Cultures 247

New Zealand). Ostreopsis monotis was described from brackish
water on the Belgian coast, and it is interesting to note that it also
occurs in a very different environment in the Gulf of California.
These preliminary observations indicate that, after a great deal
more investigation, 1t may be possible to characterize populations
of neretic micro-algae according to factors involving temperature
and salinity tolerances as well as other undefined influences. Studies
on localities with extreme factors, such as the high summer tem-
peratures of Puerto Penasco, may be expected to provide informa-
tion of great value in our estimation and analysis of populations of
micro-algae and factors influencing their distribution.

ACKNOWLEDGMENTS

I am grateful to Dr. D. A. Thomson, Director of the Puerto Penasco
Marine Research Station, and Dr. R. W. Hoshaw, Department of
Botany, University of Arizona, for supporting my trip to Puerto
Penasco through funds from the Office of Naval Research, NONR
Contract 4839, a grant to the Department of Biological Sciences,
University of Arizona, and through funds granted to the Depart-
ment of Botany, University of Arizona, from the National Science
Foundation Institutional Grant to the University of Arizona. In-
vestigations at the University of Washington were supported by
a National Science Foundation Grant (GB-4183). The assistance
of Dr. R. W. Hoshaw, Mr. H. P. Hostetter, and Mr. Donald Edinger,
im making the collections is gratefully acknowledged. Mrs. Jennifer
Von Reis, Miss Shirley Van Valkenburg, and Miss Boyce Thorne
aided in the isolation and maintenance of laboratory cultures. Dr.
Hannah Croasdale translated the descriptions of new species into
Latin.

LITERATURE CITED

BIECHLER, B.
1952. Recherches sur les Péridiniens.
Bull. biol. France Belg., Suppl. 36: 1-149.

BOURRELLY, P.
1966. Les Algues d’Eau Douce, Initiation a la Systematique. Tome I: Les Algues
Vertes. Paris: N. Boubée & Cie, 511 pp.

BUTCHER, R. W.
1952. Contributions to our knowledge of the smaller marine algae. J. mar. biol.
Ass. U.K., 31: 175-191.

248 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

1959. An introductory account of the smaller algae of British coastal waters.
Part I. Introduction and Chlorophyceae. Fish. Invest. Lond., Ser. IV., 74 pp.

1965. Some new methods and suggestions for the taxonomic study of algae.
Br. phycol. Bull., 2: 399-413.

CARTER, N.
1937. New or interesting algae from brackish water. Archiv fur Protistenkunde,
90: 1-68.

CLAPAREDE, E., and J. LACHMANN

1859. Etudes sur les Infusoires et les Rhizopodes. Mém. Inst. nat. genevois,
6: 261-482.

CONRAD, W. and H. KUFFERATH

1954. Recherches sur les eaux saumatres des environs de Lilloo. II. Partie des-
criptive, Aleues et Protistes—Considérations écologiques. Mém. Inst. roy.
sci. nat. Belgique, no 127, 346 pp.

DAWSON, E. Y.

1966a. Marine algae in the vicinity of Puerto Penasco, Sonora, Mexico. Gulf of
Calif. Field Guide Series No. 1. Tucson, Ariz.: The Univ. of Ariz. Press,
57 pp.

1966b. New records of marine algae from the Gulf of California. J. Ariz. Acad.
Sci., 4: 55-66.

FREUDENTHAL, H. D.
1962. Symbiodinium gen. nov. and Symbiodinium microadriaticum sp. nov., a
zooxanthella: taxonomy, life cycle, and morphology. J. Protozool., 9: 45-52.

GEITLER, L.
1930. Ein griines Filarplasmodium und andere neue Protisten. Archiv fiir Pro-
tistenkunde, 69:615-636.

HULBERT, E. M.

1957. The taxonomy of unarmored Dinophyceae of shallow embayments on
Cape Cod, Massachusetts. Biol. Bull., 112: 196-219.

KOFOID, C. A. and 0. SWEZY

1921. The free-living unarmored Dinoflagellata. Mem. Univ. Calif., 5: i-viii +
1-562.

KORSHIKOV, A.
1923. Protochlorinae, eine neue Gruppe der griinen Flagellata. Russkii arkhiv
protistologii, 2: 148-169. [not seen, cited from Parke and Rayns, 1964].

1938. Volvocineae, in Viznacnik, prosnovod vodorostej, U.S.S.R. [in Russian],
Akad. nauk U.S.S.R., Kiev, Inst. bot., 4: 1-184.

Micro-Algae Cultures 249

LACKEY, J. B. and E. W. LACKEY

1963. Microscopic algae and protozoa in the waters near Plymouth in August
1962, J. mar. biol. Ass. U.K., 43: 797-805.

LINDEMANN, E.

1928. Peridineae. in A. Engler, Die natiirlichen Pflanzenfamilien . . . Zweite
Auflage, Bd. 2: 3-104. Leipzig: Wilhelm Engelmann.

MANTON, I., D. G. RAYNS, H. ETTL and M. PARKE

1965. Further observations on green flagellates with scaly flagella: the genus
Heteromastix Korshikov. J. mar. biol. Ass. U.K., 45: 241-255.

NORRIS, R. E.
1964. Studies on phytoplankton in Wellington Harbour. N.Z. J. Bot., 2:258-278.

1965. Neustonic marine Craspedomonadales (Choanoflagellates) from Washing-
ton and California. J. Protozool., 12: 589-602.

PARKE, M.
1961. Some remarks concerning the Class Chrysophyceae. Br. phycol. Bull.,
2: 47-55.

PARKE, M. and P. S. DIXON

1964. A revised check-list of British marine algae. J. mar. biol. Ass. U.K., 44:
499-542.

PARKE, M. and D. G. RAYNS

1964. Studies on marine flagellates VII. Nephroselmis gilva sp. nov. and some
allied forms. J. mar. biol. Ass. U.K., 44: 209-217.

PRINGSHEIM, E. G.

1955. Kleine Mitteilungen tiber Flagellaten und Algen. Archiv fiir Mikrobiol-
ogie, 21: 401-410.

SCHUSSNIG, B.

1940. Uber einige neue Protophyten aus der Adria. Archiv fiir Protistenkunde,
93:317-330.

SKUJA, H.

1948. Taxonomie des Phytoplanktons einiger Seen in Uppland, Sweden. Sym-
bolae botanicae upsalienses, 9: 1-399.

STEIN, F. R. V.

1878. Der Organismus der Infusionsthiere nach eigenen Forschungen in Sys-
tematischer Reihenfolge Bearbeitet. III. Abtheilung. Die Naturgeschichte
der Flagellaten oder Geisselinfusorien. I. Halfte. i-x + 154 pp., 24 pl.
Leipzig: Wilhelm Engelmann.

250 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

VYSOTSKY, A. V.

1888. Mastigophora and Rhizopoda found in Lakes Veisoff and Repny. A report
of the excursion for the botanical study of the Slavic Salt lakes. [In Rus-
sian]. Trudy Obshchestva estestvoispytatelei pri Imperatorskom khar’
kovskom universiteté, 21:119-140.

Accepted for publication June 10, 1967

FOOD HABITS, HABITAT PREFERENCE, REPRODUCTION,
AND DIURNAL ACTIVITY IN FOUR SYMPATRIC SPECIES
OF WHIPTAIL LIZARDS (CNEMIDOPHORUS) IN
SOUTH CENTRAL NEW MEXICO

Puinie A. Mepica!

Department of Biology
New Mexico State University
University Park, New Mexico

INTRODUCTION

The purpose of this study was to compare the ecology and niche rela-
tionships of four sympatric species of whiptail lizards of the genus
Cnemidophorus. Studies of this nature (which provide knowledge of
the ecological requirements of each) may furnish evidence of com-
petition or demonstrate the avoidance of competition among species.

Of the other studies dealing with sympatric distributions of
Cnemidophorus in the southwest the most important are probably
those of Milstead (1953, 1957a, 1957b, 1965). He studied four
broadly sympatric species of Cnemidophorus that seemingly had
mutually exclusive habitat preferences. The greatest overlap in
habitat on the basis of vegetative association was between C. inorna-
tus and C. tigris. In addition, C. neomexicanus and C. tigris overlap
in distribution as does C. exsanguis and C. inornatus. This investiga-
tion was conducted in 1964 and 1965 in a limited area of sympatric
distribution of the four species.

Papers, such as Laughlin (1958), in Texas; Carpenter (1960,
1961, 1962), im Oklahoma; and Echernacht (1964), im Arizona,
deal with the interactions of the species of Cnemidophorus as to food,
space (habitat preferences), reproduction, temperature relation-
ships, and diurnal activity.

A total of 608 lizards were collected to determine their niche rela-
tionships. A sampling program was initiated to determine these
requirements in Cnemidophorus, as interpreted through the factors
mentioned above. Data pertaining to distribution, reproduction and
temperature relationships were taken in addition to obtaining the
food habit data for Cnemidophorus.

Numerous taxonomic problems still exist in the genus Cnemi-
dophorus, and while this paper does not consider these problems in
detail, a few should be noted. Burt (1931) made the first relatively

'P.O, Box 495, Mercury, Nevada

to

252 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

complete study of the genus. Unisexual species have been found and
were first reported on by Maslin (1962). Duellman and Zweifel
(1962) found all specimens of C. exsanguis and C. neomexicanus to
be females. However, I found two males of C. neomexicanus x inor-
natus and one of C. exsanguis on the study area. The interpretations
of the above findings of male lizards of the supposedly all female
forms are discussed in a paper by Taylor and Medica (1966). The
unisexual species, C. exsanguis and C. neomexicanus, and the bisex-
ual C. inornatus and C. tigris are included in this study. The name
C. neomexicanus is used in this paper agreeing with Axtell (1966).

MerEtTHopDs

Much of the field work consisted of collecting whiptail lizards, be-
tween July 6 and October 3, 1964, and March 12 to September 15,
1965. A .22-caliber pistol with No. 12 shot cartridges was used for
taking specimens. This method rarely damaged stomachs and proved
to be the most satisfactory method of collecting large numbers of liz-
ards for stomach analyses. Can traps (pitfall type) were used in the
summer of 1964, but these were unsatisfactory for catching large
numbers. However, the traps were used again in the spring of 1965
to determine emergence from hibernation.

Cloacal, ground, and air temperatures (within 25 mm of the soil
surface) were recorded with a Schultheis quick-recording thermom-
eter 20 to 70° Centigrade. The exact locality of each lizard taken was
recorded to obtain the distribution of each of the four species of
Cnemidophorus 1 1964 and 1965.

Stomach contents were analyzed under a binocular microscope.
The volumes recorded were all estimated for the individual families
of food items found. Arthropods were identified to family when pos-
sible, but in some instances only parts were found and only identifi-
cation to order was possible.

Sex of the whiptails was determined at capture and rechecked
when stomachs were removed. Number and size of ova were re-
corded when present. Snout-vent length of all specimens was meas-
ured with a pair of twelve-centimeter calipers to millimeters.

The study area was divided into three areas of obviously different
vegetation zones, and analyzed in 1964 by the line intercept method.
(Cain and Castro, 1959; Phillips, 1959). Plants were identified from
Kearney and Peebles (1951), U. S. Forest Service (1958), and
Parker (1958).

Biology of whiptail lizards 253
DESCRIPTION OF THE STUDY AREA

The location of the study area is as follows: SW 1 of the SW' of
Section 2, and part of the SE 14 of the SE 14 of Section 3, both in
Township 24 S, Range 1 E. This area is near the Rio Grande River
and Picacho drain, at the edge of the alluvial fan which drains into
the river. The topography of all three areas is broken by an abrupt
rise of approximately 15 feet which bisects them. The bluffs on the
southwestern edge of the study area rise about 30 feet and have the
least amount of cover. The soil throughout the study area is sandy
except for the gravel soil of the levee banks and the westernmost
boundary of the plot. The study area was enlarged by approximately
two acres on the southeastern boundary in 1965 to mclude more
C. tigris and C. neomexicanus habitat since their numbers in 1964
were low.

Area 1 (Figure 1A and 1B) contains mainly saltgrass (Distichilis
stricta), and Russian thistle or tumbleweed (Salsola kali). Approxi-
mately 250 feet to the east lies the Rio Grande River; this region is
subject to infrequent flooding when the river overflows. To the west
lies more saltgrass with interspersed cottonwood trees (Populus fre-
montii) which are 35 to 45 feet tall; this region is grazed in summer
by cattle.

Area 2 (Figure 1C) is a region dominated by a mature stand of
saltcedar (Tamarix pentandra), fourwing saltbush (Atriplex canes-
cens), and mesquite (Prosopis juliflora). Salt cedar attains a height
of approximately 20 to 30 feet; saltbush and mesquite reach about
4: to 6 feet. To the east lie several temporary potholes which hold
water in the spring when irrigation water is released, and are sur-
rounded by cattail (Typha latifolia). On the west lies an expanse of
saltgrass north of Picacho drain; south of the drain the dominant
vegetation is saltgrass and salt cedar which grades into mesquite
about 8 to 10 feet tall.

Area 3 (Figure 1D) is dominated by clumps of mesquite and
widely spaced creosote bushes (Larrea divaricata). Most plants are
less than ten feet tall. This is the most xeric of the three areas. The
topography slopes northeastward, with numerous arroyos lying
along the southwestern edge. Water flows northward flooding por-
tions of area 2 during summer rains. ‘Table 1 indicates species com-
position and crown cover of the vegetation within the three habitats.

The annual rainfall in 1964 was 3.62 inches, the lowest ever re-
corded at State University weather station according to the United

254 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

Figure 1. Cnemidophorus habitat within the study area. (A) Area 1, saltgrass-
tumbleweed association looking southeastward with the Rio Grande River in the
background. (B) Area 1, saltgrass-tumbleweed association looking northwestward
with widely spaced cottonwood trees in the background. (C) Area 2, salt cedar-
saltbush association. (D) Area 3, mesquite-creosotebush association with bluffs in
the background.

States Weather Bureau (1964). In 1965, the annual rainfall was 8.29
inches, 0.28 mches above average (United States Weather Bureau,
1965). The cumulative rainfall for the months of June, July, and
August was 1.10 inches in 1964, and 3.53 inches in 1965 (Table 2).
There was a marked increase in the growth of annual vegetation in
1965.
Bopy S1zE

There is a definite size difference between the species (Fig. 2).
Cnemidophorus tigris is the largest species, the largest male was 96.7
mm in snout-vent length. Females are smaller, indicating sexual

Biology of whiptail lizards 255
TABLE 1

Species composition and crown cover expressed as a percent for the
vegetation present in the south central New Mexico study area in
1964.

Scientific name Common name Areal Area2 Area 3

Saururus spp.
Pluchea spp.
Sphaeralcea spp.
Lycium andersoni

Aplopappus heterophyllus

Suaeda fruticosa
Atriplex canescens
Dalea scoparia
Heterotheca subaxillaris

Salsola kali Russian thistle 1

Solanum elaeagnifolium white horsenettle

Distichlis stricta desert saltgrass 3

Sporobolus spp. dropseed

Prosopis juliflora mesquite 1 3
Tridens pulchellus flufferass

Tamarix pentandra salt cedar 1

Prosopis pubescens
Yucca elata

Cucurbita foetidissima
Koeberlinia spinosa
Sporobolus airoides

lizard tail
marsh fleabane
globemallow

Andersons wolfberry

jimmy weed
seepweed
fourwing saltbush
broom indigobush
telegraph plant

screw-bean
narrowleaf yucca
buffalogourd
crown-of-thorn
alkali sacaton

Opuntia spp. pricklypear
Larrea divaricata creosotebush
Ephedra trifurca Mormon tea
Opuntia spp. cholla

SooocoocoocoooooWwWoOnnnwrndorrwuwodg

—

SooocooocoorNnNFrFwmaonooosoonoooodned

PrPONrFNOOCCOCOOWCOCOCCOCOOCONOCOCOCOrFS

Nr
aS
Orv
—
aN
Or

1 oO
Crown cover in %

dimorphism. C. exsanguis is the second largest species, C. neomezxi-
canus third, and C. inornatus fourth. Size sexual dimorphism was
not found in C. inornatus.

DIsTRIBUTION AND DENSITY

A total of 162 whiptail lizards was collected during 1964. C. inor-
natus was confined to the region of saltgrass and tumblewood, C. neo-
mexicanus and C. tigris were found in the creosotebush-mesquite
association and a few individuals of each in the salt cedar-saltbush
association. C. exsanguis was found in the saltgrass-tumbleweed and
salt cedar-saltbush associations. In 1964, a dry year, C. inornatus and
C. exsanguis preferred the mesic habitat of the saltgrass-tumbleweed

256 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967
TABLE 2

Rainfall recorded at State University, New Mexico, durmg the
months whiptail lizards were active. The deviation from the mean is
in parenthesis.

1964 1965
March 56(-+.26) 20(—.10)
April 42(—.05) 02(—.15)
May 70(—.24) 99 (—.02)
Imac 97(=—96) 85(+.32)
July Sil (778) .83 (—.46)
August 152) Gaels) 18 SGie7)
September 1.18(—.04) 1 Gig orl)
October 103|\Geeei2)) 47 (— .28)

Annual Rainfall

1964 310239)
1965 8.29(+ .28)

association, and C. tigris and C. neomexicanus preferred the xeric
creosotebush-mesquite association.

In 1965, a wet year, C. inornatus extended its range southward
into the creosotebush-mesquite association and C. tigris extended
northward through the salt cedar-saltbush association. C. neomexi-
canus moved northeastward through the saltgrass-tumbleweed com-
munity. Thus in 1965, all species were intimately associated, and
were potentially competing for a portion of the habitat as well as
food.

Milstead (1957b) studied five species of Cnemidophorus (C. ex-
sanguis, C. inornatus, C. septemvittatus, C. tigris, and C. tessellatus )
and found that no more than five species were usually in the same
ecological association, indicating ecological separation by habitat
types. Lowe and Zweifel (1952) found five species at the type local-
ity of C. neomexicanus in Socorro County, New Mexico. The species
C. tigris, C. tessellatus, C. inornatus, C. exsanguis, and C. neomexti-
canus each exhibited some habitat preference although all were
found overlapping in distribution.

Laughlin (1958) thought lizard distribution was related to soil
type, lizards preferring loose sandy soils over compacted fine soils.
All the soil in my study area was of the sandy type, except the coarse
gravelly soils on levee shoulders and the bluffs on the western edge.

The density of some species of whiptails increased considerably on
the study area from 1964 to 1965. C. exsanguis, C. neomexicanus and

Biology of whiptail lizards 257

SS ESS

C. NEOMEXICANUS FEMALE (77)

(|

C. inorNnatus MALE (53)

Seales oe

C.iNorNatus FEMALE (46)

_ eres eso

C.exsancuts FEMALE (141)
C.ricris MALE (66)
C. TIGRIS FEMALE (52)

40 50 60 70 80 90 100

SNOUT-VENT LENGTH (MM)

Figure 2. Average size of adult Cnemidophorus of the four species studied. Each
bar diagram shows the range, mean, one standard deviation, two standard errors,
and the number of specimens. C. neomexicanus and C. exsanguis are the all female
species so no males are shown.

C. inornatus increased, and C. tigris remained relatively constant.
Three possible explanations for the increase in numbers are: (1)
more food was present in the wetter year and/or (2) lizards from the
outlying vicmity immigrated into the area of lower density caused
by removal of 162 lizards in 1964 or (3) less food and wider foraging
activity in dry year. Milstead (1957b), using the same area as Jame-
son and Flury (1949) in Presidio County, Texas, found a change in
lizard densities. He believed the changes were due to the ending of a
drought and the subsequent changes in vegetation.

Milstead (1957a) found that C. tigris had a home range of about
0.53 acres but could see no evidence of territoriality. Territoriality
was not observed in my study. Carpenter’s (1959) observations of
C. sexlineatus indicated that new individuals contmually appearmg
on the area would indicate extensive immigration and emigration.
Carpenter (1962) stated that territoriality was observed in Cnemi-
dophorus but that such behavior was rare. Laughlin (1958) found
that a hierarchy exists within a species based upon size. Bostic
(1966) observed threat behavior in C. hyperythrus and C. labialis. Tt

258 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

Unipenr.

Parts
38

Lepipoprera

Unipenr. Larvae

18.6

CoteopterA

Figure 3. Food habits of Cnemidophorus tigris for 1964 and 1965, indicating the
percent volume of each category.

appears to be the consensus that Cnemidophorus, unlike other liz-
ards, do not exhibit territoriality.

Foop Hasits

The food habit of the four species was based on stomach analysis of
138 C. tigris, 166 C. exsanguis, 118 C. inornatus and 93 C. neomexi-
canus. Principal food categories are compared graphically in Figures
3, 4, 5, and 6. Milstead (1953, 1957b) and Kennedy (1956) con-
cluded that identifying food items below the ordinal level was not
necessary. In this study arthropods were identified to family, but
comparisons are made at the ordinal level. Comparisons were based
upon percent volume rather than on the percent frequency of occur-

Biology of whiptail lizards 259

37.5

LepipoPrerRA

19.7

Coteoptera

Figure 4. Food habits of Cnemidophorus exsanguis for 1964 and 1965, indicating
the percent volume of each category.

rence, because the former is a better measure of the relative impor-
tance of food items.

The major food items belonged to the following orders: Lepidop-
tera, mainly moths and their larvae, comprised 37.9% volume in C,
tigris, 37.5% mC. exsanguis, 28.9% in C. neomexicanus, and 16.1%
in C. inornatus. In all species, Lepidoptera constituted the most im-
portant food item. Coleoptera was the second major item in percent
volume in three species; 18.6% in C. tigris, 19.7% in C. exsanguis
and 21.6% in C. neomexicanus. Coleoptera was the fifth by volume
(12.2%), but most frequent (35.5%) im C. inornatus. The bulk of
the beetles in all four species belonged to the families Carabidae,
Tenebrionidae, Curculionidae, and Scarabidae. Hymenoptera.
mainly ants, constituted 14.5% of the volume, and Homoptera,

260 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

29

LepipopTERA

21.6

Coteoprera

Figure 5. Food habits of Cnemidophorus neomexicanus for 1964 and 1965, indi-
cating the percent volume of each category.

mostly Cicadellidae, constituted 13.4% of the food of C. inornatus.
Orthoptera were used by all four species of lizards and comprised
8.82% in C. neomexicanus, 8.13% m C. exsanguis, 4.95% in C.
tigris, and 4.06% in C. inornatus. Araneida comprised 9.3% in C.
exsanguis, 8.1% in C. inornatus, 5.9% in C. neomexicanus, and
2.4% in C. tigris. Neuroptera (family Myrmeleontidae) were also
found in all species (5.3% in C. inornatus, 2.5% in C. exsanguis,
1.7% in C. neomexicanus and 1.4% in C. tigris). Isoptera, termites
(Kalotermitidae) constituted 1.4% of the volume in C. tigris, less
than 1%in both C. exsanguis and C. neomexicanus, and were not
eaten by C. inornatus. By frequency, termites contributed 6.01% of
the diet of C. tigris, 1.07% of C. neomexicanus, and 1.2% of C. ex-

Biology of whiptail lizards 261

16

LepipoprerA

13.8

Unipenr. Larvae

12.2

Cot EOPTERA

14.5

YMENOPTERA

Figure 6. Food habits of Cnemidophorus inornatus for 1964 and 1965, indicating
the percent volume of each category.

sanguis. In contrast to the low figures for Isoptera in this study, Mil-
stead (1957b), Laughlin (1958), Echernacht (1964), and Bostic
(1966) all found that termites were the main food of C nemidophorus.
Milstead found a percent volume as high as 97.3 in C. septemvittatus
in Presidio County and as low as 15.1 in Terrell County, Texas.
Laughlin gives a percent volume of 32.3 in C. gularis im his study on
the Welder Wildlife Refuge in Texas. Echernacht found a percent
frequency of 96.6 in C. exsanguis, and 95.7 in C. tigris in the Santa
Rita Mountains, Arizona. Bostic found 85.05% frequency in C. hy-
perythrus in southern California and northern Baja California. Uni-
dentified insect larvae contributed 11.4% of the volume in C. tigris
and 9.7% in C. neomexicanus.

262 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

Sand was found in many of the lizards’ stomachs (percent fre-
quencies of 28.0 in C. tigris, 11.4 in C. exsanguis, 15.2 in C. inornatus,
and 26.8 in C. neomexicanus. Sand was found in even larger propor-
tion (82.2%) im C. inornatus of White Sands National Monument.
This indicates that sand is probably ingested while swallowing prey.

Predation on other lizards was relatively msignificant. In one
instance a female C. tigris (61.4 mm snout-vent length) contained
the remains of a small Uta stansburiana. At White Sands National
Monument other lizards made up 2.9% of the volume eaten by C.
inornatus.

Pack (1923) stated, “Bits of wood were no doubt swept in with
the grasshoppers just as sand is often ingested along with imsects.’
On the other hand, Echernacht (1964: 37) contends that plant mate-
rial is ingested occasionally by choice. Plant material was absent in
the lizard stomachs I examined.

Studies of the feeding behavior of several species of Cnemido-
phorus have been done previously (Milstead, 1957b; Carpenter,
1962; Fitch, 1958; Echernacht, 1964; Bostic, 1966) but that of C.
neomexicanus is virtually unknown. During the course of my study
none of this species were observed feeding; however the tempera-
ment of this species is much like that of C. inornatus described by
Milstead (1957a).

There was a change in food habits from 1964 to 1965. A probable
cause was the greater variety of food brought about by more rain and
thus more annual vegetation. The percent volume of Lepidoptera in-
increased as did unidentified larvae. Hymenoptera, mostly ants, de-
creased, indicating that other food is more palatable, since ants were
probably equally available in both years. Isoptera were found only
in 1964, indicating that perhaps Cnemidophorus takes them only
rarely and prefers ants over termites. Larval insects seem to be pre-
ferred over the adults.

There is extensive overlap in the food and competition may exist
among the four species of whiptail lizards for insects of the orders
Lepidoptera, Coleoptera, Orthoptera, and Hymenoptera (Table 3).
A portion of the apparent overlap is probably not real because there
are insect size differences present.

In C. exsanguis and C. inornatus the mean sizes of Lepidoptera
were 0.1211 ml and 0.0766 ml, respectively; Coleoptera 0.0859 ml
and 0.0354 ml; Araneida 0.0885 ml and 0.0175 ml. The differences
at the ordinal level are too slight to permit illustration of the size
preferences of C. tigris and C. neomexicanus but at the family level

Biology of whiptail lizards 263

TABLE 3

Comparisons of major food items between 1964 and 1965,
based on the percent volume (ml.) displaced by the food.

Lepidoptera Hymenoptera Coleoptera Isoptera Unident. larvae

1964 1965 1964 640 1964 1965 1964 1965 1964 1965
C. tigris 35.80 40.63 5.50 1965 22.77 13.23 1.42 OT eo oat 201
C.neomexicanus 2448 3043 21.31 3.58 3748 1613 .03 0 0 11.48
C. exsanguis GAG AM S2eKh Bay sil OMe il 0 0 1.65
C. inornatus 0 16.11 6139 4.00 11.60 1239 — = 0) 13:78

there are differences. C. tigris consumes slightly smaller Lepidop-
tera than C. neomexicanus. There is little difference in the sizes of
larva Lepidoptera. The size of Orthoptera taken were similar in C.
tigris and C. neomexicanus. However, C. tigris ingests a greater va-
riety of Coleoptera (seven families) than does C. neomezxicanus (five
families). Beetles of the families Scarabidae, Tenebrionidae were
smaller in C. tigris, Melyridae eaten were approximately the same
size in both species, and Carabidae and Curculionidae consumed
were larger in C. tigris than in C. neomexicanus. A definite size
preference of the individual food items is indicated with the smaller
species eating smaller sized items. The probability of some compe-
tition for food would be between C. tigris and C. neomexicanus, since
both species prefer about the same food items and both are found in
the same habitat.

REPRODUCTION

The earliest dates on which ova were present in lizards were May
28 for C. inornatus, C. neomexicanus and C. tigris, and May 29 for
C. exsanguis (Figure 7). A female C. tigris 85 mm in snout-vent
length, collected on May 28, 1965, contained three ova (18.7 x 9.3,
16.5 x 8.0, and 12.5 x 8.0 mm). Maturing ova, over 10 mm long,
were found in C. tigris, C. inornatus, and C. neomexicanus from the
last week in May to the third week in July. These findings agree
with those of Milstead (1953), who found that C. imornatus, C. tigris,
and C. septemvittatus had a long breeding season, from early June
to early August. I found C. exsanguis with ova from only late June
to July. Thus there is the possibility that in the other three species
two separate clutches may be laid, but only one clutch in C. exsan-
guis. C. exsanguis would appear to be at a disadvantage with such a
limited breeding season, but this species was the most numerous.

264 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

C. NEOMEXICANUS

10 C.ticris

NUMBER OF FEMALES

WITH OVA

(ial WITHOUT OVA

10 C.inornatus

JULY MAY JUNE JULY AUG.

1964 1965

Figure 7. Gravid lizards which contained maturing ova 10 mm. long or longer.
The open bars signify adult non-gravid lizards indicating the duration of the
breeding season.

Biology of whiptail lizards 265

C. exsanguis lays the largest number of eggs, based on the average
number of ova per female (2.72 for C. exsanguis, 2.15 for C. inor-
natus, 2.0 for C. tigris and 1.59 for C. neomexicanus). This may ac-
count for the greater abundance of C. exsanguis.

Carpenter (1960) and Fitch (1958) found a direct correlation be-
tween the size of the female and the number of eggs per clutch and
my study substantiates their findings.

The incubation period for each species can be inferred from ex-
amination of the ova, dates collected, and appearance of hatchlings
in the population (Table 4). Hardy (1962) used a similar method
for determining the approximate incubation period for C. sexline-
atus. The estimated incubation period of 42 to 62 days agrees with
Milstead’s (1957a) 45 to 60 days.

The sex ratio in C. tigris and C. inornatus does not depart signifi-
cantly from 1:1, according to chi-square analysis. However, during
July, 1964 a ratio of 2 males to 1 female existed. In July, 1965, only
14 C. tigris were collected; five were males, and nine females. This
sample is too small to be considered a valid indication of an unbal-
anced sex ratio. It is possible that the sex ratio may be skewed during
July (Milstead, 1953; Laughlin, 1958).

SEASONAL ACTIVITY

Immature lizards of all four species are the first to appear im the
spring. The numbers of adults progressively increased, with the
greatest number taken from mid-June to mid-July. As the young
began to hatch, the numbers of adults in the population declined. By
the last week in August few adults were seen, and in September only
an occasional lizard was found which had not been hatched the same
year. Comparable results were observed by Carpenter (1959),
Laughlin (1958), Echernacht (1964) and Milstead (1957a). The
reasons for this reduction in number of adults in the population are
still not known.

Young lizards hatched the previous year evidently make up most
of the population from the time the whiptails emerge from hiberna-
tion until late May. Scatter diagrams (Figures 8 to 11) show that
by June the young hatched the previous year merge in size with the
adults and separation of the two groups is difficult.

Maturity is based upon the presence of ova in females, and males
were assumed to be mature if the same size or larger. Lizards that
were considered immature ranged in size from 30.5 to 46.7 mm in

266 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

90 C.EXsANGUIS z e
3 e
O . 3 oe .
Co 2 Saute
° eo ° A
®e e. e?
so] %. ; er ek Sc
e ee Q pO 0 of
a Q ef
e ® e
2
° "Ss Saas
70} ° e :
e
238 5 OG
— eg? : °
= Eis $
= oe ° ° 08
Ir ors ° x
~ 60 e3e
oO °
Zz
tr) °
=
mS e 2 °
z © Ps °
a50 ° :
I °
5 °
°° e
e
$ ? Be aoe oes
a6 é .
ais ore e
zt e
° 3 eo

JULY AUG. SEPT. OCT. |MAR. APR. MAY JUNE JULY AUG. SEPT.
1964 1965

Figure 8. Snout-vent length of C. exsanguis by month, showing the age classes of
lizards.

Biology of whiptail lizards 267
TABLE 4

Approximation of egg incubation time in C nemidophorus. The larg-
est number of females with maturing ova were collected on the date
in column I. The date in column II is given for the largest concentra-
tion of newly hatched collected. Column III is the number of days
that elapsed between the first and second date, and provides an esti-
mate of the average number of days necessary for incubation.

Il Ill
Date of concentrated Date of concentrated Approximate duration
numbers of maturing _ hatchlings found of incubation
ova
C. tigris July 14 August 24 40
C. exsanguis June 16 August 21 62
C inornatus June 25 August 20 46
C.neomexicanus July 9 August 30 54

C. neomexicanus, 27.9 to 48.2 in C. inornatus, 31.0 to 54.0 in C. ex-
sanguis, and 35.2 to 60.7 in C. tigris. The larger figure in every case
overlaps the lower limit of the range of adults (Fig. 2). Large num-
bers of mature lizards became active by the last week in May, 1965.
On March 25, 1965, C. inornatus first appeared. The first mature
C. exsanguis (81.0 mm snout-vent length) was collected April 13,
1965, as it came out of a burrow. This individual was very sluggish
and had probably just come out of hibernation. Its body tempera-
ture was 35.6° C, while the air temperature was 26° C and the soil
36.0° C.

TEMPERATURE RELATIONSHIPS

The mean body temperatures as shown through cloacal tempera-
ture of all four species of Cnemidophorus fell between 39.04 and 39.8°
C. This seems to be the preferred temperature of the genus. Carpen-
ter (1961) obtained an average cloacal temperature (PBT) of 38° C
for C. sexlineatus.

Observations of daily activity in relation to temperature agree
with those of Milstead (1957a), Laughlin (1958) and Echernacht
(1964). Lizards were first observed at about 7:00 A.M. when soil
temperature had reached between 26 and 30° C. On cooler mornings,
especially after a rain the previous afternoon, whiptails did not come
out of their burrows until 8:30 or 9:00 A.M., at soil temperatures of
26 to 30°C. Lizards remained active throughout the morning hours
until the soil temperature reached about 50°C, usually around 1:00
PM. Between 1:00 and 4:00 PM. few lizards were seen. Activity re-

268 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

70 C.INORNATUS

: e
©, e af t.
tite A 5 ee 3 °
: ° t
= s 3 : “3, °° e :
= O) 33 a 2.
fot ee ee e ?
= 50] °° st :
z . ee e ‘e
wd e e
=! as a
—
Zz
wi
>
i}
—
2
e)
r4
an

JULY AUG. SEPT. OCT.|MAR. APR. MAY JUNE JULY AUG. SEPT.

1964 1965

Figure 9. Snout-vent length of C. inornatus by month, showing the age classes of
lizards.

sumed after 4:00 PM. and lasted until about 6:00 PM. Figure 12
shows the cloacal temperature recorded for the four species of
Cnemidophorus.

Cloacal temperatures were more similar to soil temperatures than
to air temperatures. In all cases the mean soil temperatures were
lower than the cloacal temperatures, although the reverse might
have been expected. Possible explanations for differences between
soil and cloacal temperatures are that the lizards moved from the
place in which the body warmed up to a cooler location, or that some
body heat was due to direct solation.

Immature lizards may remain active into October even though
decreasing daily temperatures eventually bring about unfavorable

Biology of whiptail lizards 269

C.ricris

SNOUT-VENT LENGTH (MM)

JULY AUG. SEPT. OCT.|MAR. APR. MAY JUNE JULY AUG. SEPT.

1964 1965

Figure 10. Snout-vent length of C. tigris by month, showing the age classes of
lizards.

270 ~=3=—r Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

G. NEOMEXICANUS

SNOUT-VENT LENGTH (MM)

JULY AUG. SEPT. OCT.|MAR. APR. MAY JUNE JULY AUG. SEPT.

1964 1965

Figure 11. Snout-vent length of C. neomexicanus by month, showing the age
classes of lizards.

Biology of whiptail lizards 271

conditions. Cowles (1941) states, “The young of most species of des-
ert reptiles remain active later in the season than do the adults, one
of the important reasons being the effective heating of these small
bodies in favorable periods which are apparently too brief for utili-
zation by the adults—the long, almost continuous, activity of the
smallest species of lizards being due in part at least to this factor.’
The surface-mass ratio in smaller lizards also enables them to utilize
shorter intervals of favorable exposure (Cowles and Bogert, 1944).

Temperature relationships of the species studied appear to be de-
termined by species size. Numerous observations indicated that the
smaller species come out earlier in the morning. As the soil tempera-
ture increased, the larger species emerged, with C. tigris the last
species to appear, usually between 8:30 and 9:00 A.M. All four pre-
fer a body temperature near 39°C, but this temperature is attained
at different times of the morning. Consequently, the relationship
between small size and lower environmental temperatures that was
observed in the field is not apparent.

DiIscussION

Differences in food, habitat, breeding seasonality, and diurnal ac-
tivity show that the sympatric Cnemidophorus species of this study
have paired habitats. C. exsanguis and C. inornatus prefer the more
mesic habitat and C. neomexicanus and C. tigris the more xeric.
There are similarities in the duration of the breeding season of C.
tigris, C. neomexicanus and C. inornatus, but that of C. exsanguis
was considerably shorter. All four species were active during the
same season and the daily activity was different only during the
early morning with C. inornatus becoming active first.

In 1964, a dry and presumably unfavorable year, habitats were
more sharply restricted. Each of the habitats as interpreted through
vegetation was occupied by no more than two species; C. inornatus
was limited to one area and C. exsanguis to two areas, and C. tigris
and C. neomexicanus were on yet another. In 1965, a much wetter
year with more food available, three species extended their ranges,
but C. exsanguis did not. It appears that during unfavorable periods,
the lizards may retreat to their minimal home range. The reduction
in their distribution probably minimizes competition between C. in-
ornatus and C. exsanguis on the one hand and C. tigris and C. neo-
mexicanus on the other.

When food was abundant in 1965, extensive dispersal of some of
the species took place. Spatial relationships are difficult to determine,

272 Bulletin So. Calif. Academy Sciences / Vol. ee No. 4, 1967

eo NEOMEXICANUS eo TIGRIS

25
20
15
10
5
ce)

C.exsancuis

40
35
30
C. INORNATUS
25
20
15
10
5
ce)
30 35 35 40 45

DEGREES CENTIGRADE

Figure 12. Cloacal temperatures of the four species of Cnemidophorus and the
number of records.

NUMBER OF RECORDS

Biology of whiptail lizards 273

but all four species became sympatric. Since food did not appear to
be limiting distribution and abundance, space may have been at a
premium with possible competition for egg laying sites, places to re-
treat to during the heat of the day, and shelter for the night.

In 1964, the habitat of C. tigris and C. neomexicanus excluded
members of C. exsanguis and C. inornatus and vice versa. The size
and variety of the arthropods ingested by C. inornatus and C. exsan-
guis show considerable differences. C. exsanguis consumed the
largest-sized food items and C. inornatus the smallest. Homoptera
were the major secondary food item in C. inornatus while Orthop-
tera and Araneida were more important in C. exsanguis. Sympatric
distribution without severe competition may have been permitted
in part between C. inornatus and C. exsanguis because their food
habits were considerably different.

The differences in size of the food item and the varieties of food
consumed are not noticeable between C. tigris and C. neomexicanus.
Subtle differences in food items can be discovered by comparing the
families of insects eaten and their respective sizes. For the most part,
there was little difference in size of the Lepidoptera, and the uniden-
tified insect larvae taken by these two species. C. tigris consumed a
larger variety of beetles but two families (Omophoronidae and Sca-
phidiidae) were not eaten by C. neomexicanus. C. tigris ate smaller
members of the families Scarabieidae and Tenebrionidae than C.
neomexicanus. Larger members of the families Melyridae and Cur-
culionidae were selected by C. tigris than C. neomexicanus. It is
probable that subtle differences are present which permit C. tigris
and C. neomexicanus to coexist. Changes in density between the two
species were not significant between 1964 and 1965. The likelihood
of competitive conditions existing between C. tigris and C. neomexi-
canus may be responsible for limiting the range of C. neomexicanus
primarily to the Rio Grande Valley. Axtell (1966) proposes that in-
terspecific competition between C. tigris and C. neomexicanus may
play a more important role as a major isolating factor. This study
has shown this to be a probable cause.

CoNCLUSIONS

1. Changes in lizard distribution from one year to the next have been
reflected in this study. Although the controlling factors are not com-
pletely understood, it is plausible that the increased precipitation and
the reduction in numbers by shooting influenced changes in distri-
bution.

274. Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

2. Rainfall definitely has an influence upon the availability of food
and is reflected in the food preferences. During periods of drought,
higher percentages of Hymenoptera (family Formicidae), Isoptera
(family Kalotermitidae), and Coleoptera made up the bulk of the
diet in three of the species of whiptails. In a wetter year, larvae of in-
sects were the preferred food.

3. Reproduction differences between C. tigris, C. inornatus, and C.
neomexicanus were not great; the number of ova produced were ap-
proximately the same. C. exsanguis apparently lays only one clutch
of eggs; the three other species probably lay two.

4. Young lizards have a longer period of activity than adults. The
young comprise a major portion of the population before and after
the breeding season.

5. All species of Cnemidophorus prefer a mean body temperature
between 39° and 40° Centigrade; no matter at which time of day -
they are active, the smaller species emerge first from their burrows.
Young individuals of the larger species will emerge sooner than adult
animals.

ACKNOWLEDGMENTS

I wish to thank a number of people who aided me in fulfilling thas
study: Thanks to Dr. James R. Dixon for suggesting the problem and
critically reviewing the manuscript; Dr. Ralph J. Raitt and Dr.
James R. Zimmerman for suggestions used in making the figures,
preparing and reviewing the manuscript; Dr. James R. Zimmer-
man, Mr. Anthony Smith, and Mr. Kenneth L. McWilliams in aid-
ing me to identify difficult arthropods; Dr. William Dick-Peddie for
identifying many of the plants; Dr. Robert C. Stebbins for range
maps of Cnemidophorus. I also wish to thank the Society of the Sig-
ma Xi for their Grant-in-Aid of Research that enabled me to con-
tmue this study through 1965, and to my wife Gloria, whose en-
couragement and patience allowed me the opportunity to complete
the study.

LITERATURE CITED
AXTELL, R. W.
1966. Geographic distribution of the unisexual whiptail Cnemidophorus neomezi-
canus (Sauria: Teiidae) present and past. Herpetologica, 22 (4) :241-253.
BORROR, D. J. anp D. M. DELonc
1957. An introduction to the study of insects. New York: Rinehart and Co., 1030 p.
BOSIMC DEE
1966. Food and feeding behavior of the teiid lizard, Cnemidophorus hyperythrus
bledingi. Herpetologica, 22:23-31.

Biology of whiptail lizards 275

BURT, C. E.

1931. A study of the teiid lizards of the genus Cnemidophorus with special refer-
ences to their phylogenetic relationships. Bull. U.S. Natl. Mus., 154:286.

CAIN, S. A., anp G. M. CASTRO

1959. Manual of vegetation analysis. New York: Harper and Bros., 325 p.

CARPENTER, C. C.

1959. A population of the six-lined racerunner (Cnemidophorus sexlineatus).
Herpetologica, 15:81-86.

1960. Reproduction in Oklahoma Sceloporus and Cnemidophorus. Herpetologica,
16:175-182.

1961. Temperature relationships of two Oklahoma lizards. Proc. Oklahoma Acad.
Sci., 41:72-77.

1962. Patterns of behavior in two Oklahoma lizards. Amer. Mid. Nat., 67:132-151.

COWLES, R. B.

1941. Observations on the winter activities of desert reptiles. Ecology, 22:125-140.

COWLES, R. B. ann C. M. BOGERT

1944. A preliminary study of the thermal requirements of desert reptiles. Bull.
Amer. Mus. Nat. Hist., 83(5):267-296.

DUELLMAN, W. E. ano R. G. ZWEIFEL

1962. A synopsis of the lizards of the sezlineaius group (genus Cnemidophorus).
Bull. Amer. Mus. Nat. Hist., 123(3):161-210.

ECHERNACHT, C. A.

1964. Ecological relationships of two species of the lizard genus Cnemidophorus in
the Santa Rita mountains of Arizona. Master’s Thesis, Arizona State Univ.,
68 p.

FITCH, H. S.

1958. Natural history of the six-lined racerunner (Cnemidophorus sexlineatus).
Univ. Kansas Publ. Mus. Nat. Hist., 11:11-62.

HARDY, D. E

1962. Ecology and behavior of the six-lined racerunner, Cnemidophorus sexline-
atus. Univ. Kansas Sci. Bull., 43:1-73.

HODDENBACH, G. A.

1966. Reproduction in western Texas Cnemidophorus sexlineatus (Sauria: ‘Tei-
idae). Copeia, 1966(1):110-113.

JAMESON, D. L., anp A. G. FLURY

1949. The reptiles and amphibians of the Sierra Vieja range of southwestern
Texas. Texas J. Sci., 1:54-77.

JAQUES, H. E.

1947. How to know the insects. Dubuque, lowa: Wm. C. Brown Co., 205 p.

KEARNEY, T. H. anno R. H. PEEBLES

1960. Arizona Flora. Berkeley: Univ. Calif. Press., viii + 1085 p.

KENNEDY, J. P.

1956. Food habits of the rusty lizard Scleoporus olivaceus Smith. Texas J. Sci., 8:
328-349.

LAUGHLIN, H. E.

1958. Interrelationships between two sympatric species of racerunner lizards,
genus Cnemidophorus. Master’s Thesis, University of Texas, Austin, 86 p.

276 = Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

LOWE, C. H., JR., anp R. G. ZWEIFEL

1952. A new species of whiptail lizard (genus Cnemidophorus) from New Mex-
ico. Bull. Chicago Acad. Sct., 9:229-247.

MASLIN, T. P

1962. All-female species of the lizard genus Cnemidophorus, Teiidae. Science,
1135:212-913:

MILSTEAD, W. W.

1953. Competition and other interrelationships in natural populations of race-
runners (genus Cnemidophorus). Doctoral Dissertation, University of
‘Texas, Austin, 100 p.

1957a. Observations on the natural history of four species of whiptail lizards,
Cnemidophorus (Sauria, Teiidae) in Trans-Pecos, Texas. Southwestern Nat.,
2(2-3):105-121.

1957b. Some aspects of competition in natural populations of whiptail lizards
(genus Cnemidophorus). Texas J. Sci., 9:410-447.

1965. Changes in competing populations of whiptail lizards (Cnemidophorus) in
southwestern Texas. Amer. Mid. Nat., 73:75-80.

PACK VEE:

1923. The food habits of Cnemidophorus tessellatus tessellatus (Say). Proc. Biol.
Soc. Wash., 36:85-90.

PARKER, kh. E

1958. Arizona ranch, farm and garden weeds. Univ. Arizona, Circular 265: 1-288.

PENNOCHKH, L. A.

1965. Triploidy in parthenogenetic species of the teiid lizard, genus Cnemido-
phorus. Science, 149:539-540.

STEBBINS, R. C.

1954. Amphibians and reptiles of western North America. New York: McGraw-
Hill, 528 p.

1966. A field guide to the reptiles and amphibians of western North America.
Boston: Houghton Mifflin Co., xiv + 279 p.

SIMPSON, G. G., A. ROE, anno R. C. LEWONTIN

1960. Quantitative zoology. New York: Harcourt, Brace and Co., 440 p.

TAYLOR, H. L. anp PA. MEDICA

1966. Natural hybridization of the bisexual teiid lizard Cnemidophorus inornatus
and the unisexual Cnemidophorus perplerus in southern New Mexico.
Univ. Colorado Studies, Ser. Biol., 22:1-9.

TINKLE, D. W.

1959. Observations on the lizards Cnemidophorus tessellatus and Crotaphytus wis-
lizent. Southwestern Nat., 4(4):195-200.

U.S. DEPT. AGRICULTURE

1958. Range plants of Arizona and New Mexico. Names, symbols and notations.
U. S. Forest Service, 11 + 86 p.

U.S. WEATHER BUREAU

1964. Climatological data New Mexico. 68(13) :233-245.

1965. Climatological data New Mexico. 69 (13) :232-244.

Accepted for publication April 1, 1967

NEW RECORDS OF TALITRIDAE
(CRUSTACEA: AMPHIPODA)
FROM THE CENTRAL CALIFORNIA COAST

E. L. BousFIELD
National Museum of Canada, Ottawa, Canada

AND

JAMES CARLTON
Natural Science Centre, Oakland, California

During recent faunistic surveys of Lake Merritt, Oakland, Califor-
nia, the junior author collected numerous specimens of a shore-
dwelling talitrid amphipod. Although beach hoppers had not previ-
ously been recorded from this artificially controlled lake (e.g. Light
et al, 1954), the material was first thought to be one of the species of
beach hoppers (Orchestoidea) previously recorded from the Califor-
nia coast (Bousfield, 1960). The material later proved to be an
Orchestia of uncertain affinities distinct from species previously
known from the American-Pacific region.

The origin and identification of this species is problematical. The
animal could be endemic to the lake or to similar habitats in this
region although the failure of earlier surveys (e.g. Nold, 1936,
Marchette, 1953) to reveal it among amphipod species (then A7zso-
gammarus confervicolus Stimpson and Corophium insidiosum
Crawford) of Lake Merritt, or along the general California coast
(Bousfield, 1960, Bowers, 1963) lessens this possibility. On the other
hand, the present exotic nature of the general invertebrate fauna of
this small] irregularly tidal lake would indicate that the new talitrid
is also an introduced form. This fairly conspicuous animal would
not likely have been overlooked by Marchette in 1953, yet it was
found in the lake during the initial part of this survey (1962). Thus
the probable period of introduction was between those times. Other
crustacean species such as the decapod shrimp Palaemon macrodac-
tylus Rathbun are believed to have been brought into the San Fran-
cisco Bay region from western Europe, India, Japan and the Orient,
during that period (Newman, 1963). The present material, how-
ever, is apparently not referable to any of the known Japanese or
eastern Asiatic species of Talitridae (see Iwasa, 1939, Gurjanova,
1951, Bulycheva, 1957), nor of other Indo-Pacific regions (e.g.
Stephensen, 1935, Barnard, 1955, 1960). Several invertebrates of
San Francisco Bay, some formerly of Lake Merritt, such as the xan-

277

278 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

thid crab Rhithropanopeus harrisi Gould and the bivalve mollusk
Petricola pholadiformis Lamarck have been brought in from the
American Atlantic coast (Jones, 1940, Bailey, 1932). This beach
hopper, however, is unlike any of the western European or western
Atlantic species known to the senior author (Chevreux & Fage,
1925; Bousfield, in prep.). We are therefore newly describing this
species as Orchestia enigmatica (n.sp.).

Since 1964 a number of terrestrial leaf hoppers have been col-
lected in Golden Gate Park, San Francisco, by Dr. Maria Sandoz and
her colleagues at San Francisco State College and by Dr. F Wayne
Grimm, Baltimore, Md. The material was submitted recently to the
senior author and has now been identified as Talitrus sylvaticus Has-
well. The only other species of land-hopper previously recorded
from California (Pasadena and Balboa Park) is Talitrus topitotum
Burt (= T pacificus Hurley) (Shoemaker, 1936, figs. 1 & 2). In an
extensive revision of the Australian ‘Talitridae (Bousfield, in press) ~
both species have been recorded from the south-eastern United States
and may have been transported with Eucalyptus or other tropical
plants from there into California. The present record of Yalitrus
sylvaticus Haswell is the first authentic one for North America and
the first outside Australia.

Family ‘Talitridae Bulycheva 1957

Genus Orchestia Leach
Orchestia enigmatica n. sp.

Figures 1, 2

Description: Male (11.5-15 mm.). Head slightly deeper than
long, inferior antennal sinus moderately incised. Eye medium,
black, subquadrate, near anterior margin, Antenna 1 short, pedun-
cular segments subequal, flagellum shorter than peduncle, 5-6 seg-
mented, tip not reaching peduncular segment 2 of antenna 2; An-
tenna 2, peduncular segments 4 & 5 moderately powerful, incras-
sated, subequal, with a few marginal spines; flagellum a little shorter
than peduncle, 17-segmented.

Upper lip deeper than broad; apex broad, pilose. Lower lip deep,
shoulders weakly pilose. Mandible, cutting edge with 4-6 teeth; left
lacinia is tri-cuspate, right lacinia is trifid; molar process coarsely
striate (about 18 striations). Maxilla 1, apical pectinate spine-teeth
of outer plate relatively tall; palp minute, 2-segmented; inner plate
with moderately long plumose apical setae. Maxilla 2, plates rela-

Figure 1. Orchestia enigmatica new species, from Lake Merritt, Oakland, Califor-
nia. Male, 11.5 mm.

tively long, proximal plumose seta on inner plate long, stout. Maxil-
liped, inner plate apically truncate, innermost spine tooth smallest;
outer plate broadly rounded distally with strong submarginal row of
stiff setae; palp short, 4-segmented, proximal segments very broad,
4th segment a small subapical knob.

Coxal plates 2-4 subequal, each with sharp posterior lobe. Gnatho-
pod 1, coxal shelf strong, forming nearly complete inner lower mar-
gin, armed with long stiff spines; segment 4 without posterior proc-
ess; segment 5 with deep posterior process set basally with strong
spines; segment 6 distally broadest and posteriorly tumid, spmose;
dactyl slender, a little shorter than vertical palm. Gnathopod 2 ro-
bust; segment 2, anterior margin with short spines; segment 6
broadly ovate, palm oblique, indented in middle, lined with short

280 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

Figure 2. Orchestia enigmatica new species, from Lake Merritt, Oakland, Califor-
nia. Male, 11.5 mm. 2. Female, 11.0 mm.

spines, with large subtriangular tooth near hinge; dactyl stout,
closely fitting convex palm distally, tip curved into posterior palmar
angle.

Peraeopods 1 & 2 relatively long and slender; dactyls short; dacty]
of P2 with small spur. Peraeopods 3-5 progressively longer, lightly
spmose. Peraeopod 3, coxal plate much broader than deep, anterior

New records of Talitridae (Crustacea: Amphipoda) 281

lobe larger, margin smooth, posterior lobe with spinulose margin;
segment 2 broadly ovate, posterior margin strongly convex, spin-
ulose. Peraeopod 4, posterior lobe of coxal plate about twice as deep
as anterior lobe, lower margin spinulose. Peraeopod 5, coxal lobes
not produced below, posterior margin with weak spines; basos (seg-
ment 2) not exceptionally expanded, posterior margin gently con-
vex. Coxal gills short, saclike, not extending below coxal plates.

Pleosome side plates subequal, smooth below; posterior angles sub-
acute, margins weakly serrate and spinulose. Pleopods well devel-
oped, slender, subequal; rami of 10-12 plumose segments, inner
ramus longer than outer; peduncles about equal to rami, with two
coupling spines; peduncle of pleopod 3 with a few spines along outer
margin.

Urosome segments distinct, that of 2 not telescoping dorsally with
segment 1. Uropod 1, rami subequal, shorter than peduncle, outer
ramus with outer marginal spines only, terminal spines strong;
miner ramus with inner marginal spines only. Peduncle with strong-
er inner marginal spines but lacking inter-ramal spine. Uropod 2,
rami relatively stout, shorter than peduncle, bearing 1-2 marginal
spines. Uropod 3 short, peduncle broad (deep), with several dorsal
spines near base of chow spiose sub-conical ramus. Telson spade-
shaped, slightly longer than wide, laterally and apically spinose,
consisting of two medially fused lobes.

In a fully mature male (15 mm., PARATYPE), the palmar mar-
gin of gnathopod 2 is deeply indented in the middle and the large
palmar tooth near the hinge of the dactyl is sharply triangular,
much as in the palm of mature males of Orchestoidea corniculata
Stout and O. pugettensis Dana, (see Bousfield, 1960, fig. 3). In perae-
opods 4 & 5, segments 4, 5 & 6 are somewhat thickened or incras-
sated.

Female (11.0 mm.). Antenna 1 short, flagellum of 3-4 segments.
Antenna 2, peduncular segments 4 & 5 short, relatively slender;
flagellum longer than peduncle.

Gnathopod 1, segment 5 without subapical blister; segment 6 sub-
rectangular, lower margin spinose, palm vertical, gently convex,
spmose angle slightly exceeded by tip of tightly closing dactyl.
Gnathopod 2, segment 2, anterior margin a little expanded, with a
few short spines distally; segment 3 longer than 4; segment 5 with
gently convex posterior blister; segment 6 shorter than 5; dacty] sub-
apical. Brood plates on thoracic segments 2-4 elongate, exceeding
respective leg segment 2, margin lined with 20-30 rather long curl-

282 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

tipped or hooked setae; brood plate of segment 5 shorter and broader
with about 10 long marginal hooked setae.

In other features the female closely resembles the male; body is
relatively more compact and appendages relatively shorter.
Material Examined: Lake Merritt, Oakland, California, under damp
debris at water’s edge, August 30, 1966, James Carlton, coll. Male
(HOLOTYPE), Female (ALLOTYPE), NMC No. 5761; 7 subadult
males, 2 females, 59 juveniles (PARATYPES), NMC No. 5762.
Lake Merritt, Oakland, California, alive among tubes of the poly-
chaete worm Mercierella enigmatica, June 6, 1965, J. Carlton, coll.—
1 large male (15 mm.). (PARATYPE) USNM File No. 260765.
Lake Merritt, Oakland, California, under wet boards, along lake
margin, June 6, 1965, J. Carlton, coll.—2 females (9-10 mm.), 1 juv.
(4.5 mm.), USNM File No. 260765.

Habitat: Common to abundant along exposed beaches of the north
side of Lake Merritt, under damp, rotting wood, leaves, vegetation ©
and other organic debris; often found in company with the amphi-
pod Melita sp.; sometimes found among the tubes of Mercierella
enigmatica Fauvel. Exposed to fluctuating lake levels and varying
salinities of the flood-gate controlled lake.

Remarks: The affinities of this new species are puzzling, hence the
specific name enigmatica. Overall similarity of general body fea-
tures to the primitive complex of Orchestia traskiana—O. georgiana—
O. ochotensis indicates the species is endemic to the North Pacific
region. Among these features of special significance are the short,
broad 4-segmented maxilliped palp; long curl-tipped, brood-plate
setae; slender marginally spinose pleopods; and well-developed spin-
ose coxal shelf of gnathopod 1. Peculiar to this species, however, is
the primitive fully and deeply subchelate condition of gnathopod 1 of
both sexes, the sexually dimorphic antennae, the elongate perae-
opods, the broad shallow coxal plates, and the weakly spmose arma-
ture of the appendages. The small sac-like gills and powerful spinose
third uropods are suggestive of a sand-burrowing facility.

Genus Talitrus Latreille
Talitrus sylvaticus Haswell

Material Examined: Golden Gate Park, San Francisco, California:
(1) under bushes near California Academy of Sciences building, Jan.
26, 1962, F Wayne Grimm coll.—1 female (12 mm.) NMC No. 5766;
(2) Damp ground along South Drive, near Tea Garden, Jan. 27,

New records of Talitridae (Crustacea: Amphipoda) 283

1962, F Wayne Grimm coll.—33 subad. males (8.5 mm.), NMC No.
5767; (3) beneath moist Eucalyptus leaves, June 26, 1966, Mildred
Sandoz coll.—11 subadult, 1 juv., NMC No. 5763. Sigmund Stern
Eucalyptus grove, leaf drifts, San Francisco, California, Feb. 17,
1962, F Wayne Grimm coll.—4 females (2 ovig.), 1 immature, NMC
No. 5768.

Remarks: This material conforms closely with material from New
South Wales and Victoria, Australia, studied recently (Bousfield, in
press). Particularly diagnostic are the pleopods, the first two of
which are reduced but functional, the outer ramus longer than the
inner, and outer margin of the peduncle finely pilose (not setose) ;
the third pleopod is a vestigial stub without rami.

The species is herewith provisionally placed in the genus Talitrus,
after Barnard (1960). However, recent studies on the Australian
fauna indicate that it must be allied with at least three other species
in a new genus of terrestrial leaf hoppers endemic to the Australian
region.

LITERATURE CITED

BAILEY, J. L., JR.
1932. Lake Merritt mollusks. Nautilus 45:138.

BARNARD, J. L.

1955. Gammaridean Amphipoda (Crustacea) in the Collections of Bishop Muse-
um. Bernice P. Bishop Mus. Bull. 215: 1-46.

1960. Crustacea: Amphipoda. (Strand and Terrestrial Talitridae). Insects of
Micronesia, Bernice P. Bishop Mus. 4:11-30.

BOUSFIELD, E. L.

1960. New Records of Beach Hoppers (Crustacea: Amphipoda) from the coast of
California. Bull. Nat. Mus. Canada, No. 172, 1-12.

BOUSFIELD, E. L.
The Terrestrial Talitridae (Crustacea: Amphipoda) of Australia. Austral.
J. Zool. [in press].

BOUSFIELD, E. L.
The Talitridae of the Western Atlantic region. [in preparation].

BOWERS, D. E.
1963. Field Identification of five Species of California Beach Hoppers (Crusta-
cea:Amphipoda). Pacific Sci. 17:315-320.

BULYCHEVA, A.
1957. The Sea Fleas of the U.S.S.R. and adjoining water. Keys to the Fauna of
the U.S.S.R. Zool. Inst. Acad. Sci., USSR. No. 65, 185 pp. [In Russian].

CHEVREUX, E. et L. FAGE
1925. Amphipodes. Faune de France. Paris, 9:1-488.

284 Bulletin So. Calif. Academy Sciences / Vol. 66, No. 4, 1967

GURJANOVA, E. E
1951. Amphipoda Gammaridea of the Seas of the USSR and adjoining Waters.
Trans. Zool. Inst. Sci., 41:1029 pp. [In Russian. ]

IWASA, M.

1939. Japanese Talitridae. J. Fac. Sci. Hokkaido Imperial Univ., Ser. V1:Zool.
6: 225-296.

JONES, L. L.

1940. An Introduction of an Atlantic Crab into San Francisco Bay. Proc. VI
Pacific Sci. Congr. I11:485-486.

LIGHT, S. E et al

1954. Intertidal Invertebrates of the Central California Coast. Univ. California
Press, 446 pp.

MARCHETTE, N. J.

1953. A Limnological Study of a Brackish Water Lake. M. A. thesis. Univ. Cali-
fornia, Berkeley, pp. 11-96.

NEWMAN. W. A.

1963. On the Introduction of an edible oriental shrimp (Caridae, Palaemonidae)
to San Francisco Bay. Crustaceana 5:119-132.

NOLD, J.

1936. The Common Invertebrate Animals of Lake Merritt. Zoology 112 coll.,
Univ. Calif., Berkeley, MS. pp. 1-23.

SHOEMARER, C. R.

1936. The Occurrence of the Terrestrial Amphipods, Talitrus alluaudi and
Talitrus sylvaticus in the United States. Acad. Sct. 26(2):60-64.

STEPHENSEN, Kk. A.

1935. Indo-Pacific terrestrial Talitridae. Bernice P. Bishop Mus., Occ. Papers

X (23) :1-20.
Explanation of symbols on figures 1 and 2.

Ai Antenna 1 Mxpd Maxilliped
A2 Antenna 2 Gn1 Gnathopod 1
Hd Head Gn2 Gnathopod 2
UL Upper Lip P1-5 Peraeopods 1-5
LL Lower Lip Ep1-3 Abdominal side plates 1-3
Rt. Md. Right Mandible Pl 2-3 Pleopods 2-3
Lft. Md. Left Mandible U 1-3 Uropods 1-3
Mx1 Maxilla 1 ali Telson
Mx2 Maxilla 2

Accepted for publication June 15, 1967.

SOUTHERN CALIFORNIA ACADEMY OF SCIENCES
VoLuUME 66, 1967

INDEX OF SUBJECTS

Abbottella concinna

ANTONE IL, TN GSA ool er “506 « MG

Additional notes on snakes taken in
and near Joshua Tree National

Monument, California ......... 1
PM SHIEIO), (Ch, Ea hee ete eae 54, 135
Algae, Chlorophyta .......... 23, 234
CGlinaysoplivitaes 2)05. ss ese 238
Growth t he OSL Ad 23
eae Oplaygbalh thee eo. cM cekty atc ete al 233
aygenmoplyitay.: oj. 6.) he ek. 244,
nidodoplayitalss) +2... +. 161, 195, 201
Xamitlaoplivatay asses oo se ae 236
PMC UUCMTLOMESD a Re aie 57
Amperima velacula ............. 61
/E\I0G1}0) ot SETS 5/5 Aan he aed ee Al 109
Amphidinium operculatum ...... 244
Para lanpodameneaa st es ok ale 277
ANiaGaiesOrN, Jd, Ihe dc ad ole ola c den a 223

An endocranial cast of the Miocene
dog, Tomarctus, from the fossil
beds of Barstow, California ..... 39

A new species of Neofungella (Bry-
ozoa, Stenolaemata) from South-

enna Calitormiate a). vec. nae liso 35
rminialnpebawiOG 2+. .+.c2<.- sss 69
PNMAPACLIC. See ses See a hea 54
ANTEGUNG. 60,0, oreo: Gey aa ene ee ee 135
PAS CIALOINUST OO St os. te es Wey, al//
Basten. AVE (Chest nectar ae Pari e 35
Barnhart, J.T........ i ee eRe Ta 129
ES eanalkegapl ve Gr trains 24. cy Wi mee deh ees 125
IROLSMeeMe rns face 2 sats deste We OES 125
lgods tumicata:s......s.5. 6 B35 WH
Bousitelds Fels ok. oe oe as: 277
PMUVOZOCM set sigs Pie gees Fae dt 35
@allidiwell DWH ts oe a4 we lk 69
Galldiwiell IMIG. 2 55 ose eed eenle ak 69
MO MHUOMMN ou iarrcasd sess tae wate MIRE Q77
Chlorarachnion reptans .......... 236
Clementi ie We. ceed ee ask bene Red 39
WreMmudOphOrUs .... 2.22 een ht 951

Coleoptera: «i... sa cee ot 46
Communities, pioneer, marine ....181
terristrialls jo sede eee ae 183

ComstockwAG 4. oe ee 92, 99
Contrast between the pioneer popu-
lating process on land and shore .175

Coryphista meadii fumosa ........ 94.
DEV all Sy) tre eee A esa ame ye aac 195
Dawson, E. Yale, Obituary ....... 149
Dawsoniella bulborhiza .......... 205
Deformation, geological .......... 129

Description of a new subgenus of
Osmia (Hymenoptera: Megachi-

Iidlae Raine reelt cna Sl 103
Dypterays) 57 ee Saas ieee 49
Ditria reptans .................. 208
IDO tyro Vie Wires eer tenes ey eek 175
colony clizandinne tenner 251

Elasipod holothurians of Antarctica.
1. Genus Amperima Pawson 1965 54

Elpidia glacialis glacialis ......... 135
Enteromorpha prolifera .......... 23
she fossils a sere eter ttc sn ewel nas ae 77
Bitch el Jee tien hee cette: 77

Food habits, habitat preference, re-
production, and diurnal activity
in four sympatric species of whip-
tail lizards (Cnemidophorus) in

south central Mexico .......... 251
Gartheiero mena: Lisle h ol aah ae 149
Gill structure in the caecilian genus

Ey mnopis, See Se. eee ee 109
Growth and development of Sciado-

phycus stellatus Dawson ....... 195

Gymnopis multiplicata proxima ...109

EV AWWAld iciklcio neon eee ee ee 175
Hawaiia trichia .................209
HennenGi ict see ae ea deni 6 99
Flveue, Go) Le shyla cote sors 49

285

Hollenberos Gate eer 201

Holothurians ............. 54, 57, 135

Holothurians of the genus Elpidia
and Kolga from the Canadian Ba-

sin of the Arctic Ocean .......... 135
biyanenopterals ta) are 103
akswayri Ga Eis eeer tee 39
Nenkaints) (Silas eee seo ae eee 46
Joshua Tree National Monument .1, 46
Kier vA. caer ao aes 29
Koleathyalinameer eee er err: 140
Lagodon rhomboides ............ 69

Late-Pleistocene deformation in the
lime-kiln canyon area, Santa Su-

sana Mountains .............. 129
iepidopteray- hie wie er 92
Leptotyphleps humilis cahuilae... 1
Life history, Lepidoptera ....... 92° 99

Spiders 5cis sein - ac: een oe 142
IDapAa Ne Sa contceakne a tramiioie ou wrote cao 6 251
POOmIS wa Bae aera 1
WWowmnres 1) iGreen cen eee ae 142
Macrocy stisiannRGivas esate o 223
Mammal fossil eo. 25 ee eae 39
Medica Aas fae noe aa te epee 251
IMI EKA C Om woemt stir sania cere tar nee 251
Micro-algae in enrichment cultures

from Puerto Penasco, Sonora,

IMexi coca s yee hk ee ed 233
Miocene, fossil ................. 39
Mystacosmia ................... 104
Neofungella californica .......... 35
Nephroselmis longifilis .......... 234
INeuslawllis Mites 5 al seceatiat ae ae ae 195
New genera in the Rhodomelaceae

from the Central Pacific ....... 201

New records of Talitridae (Crusta-
cea: Amphipoda) from central

Cahiformialeeeeeee eon eee 277
INorrism@RinE Cie sce acetal cine 233
North VVar ie pestis rccncn once aanee 223

Notes on Paracumbocera robusta
Vandyke (Coleoptera: Curculioni-
dae)

Notes on the early stages of the bar-
berry geometrid moths, genus
Cory phista, and the description of
a new subspecies of C. meadii

(Eepidoptera) eerie 92
Notes on the life history of Philotes

AU UDO ss0064b0600%¢000c0000 99
Ochromonas mexicana ........... 238
Ochrosphaera verrucosa .......... 242
Olsen) Dis oh eee 195
Orchestia enigmatica ............ 278
Otoliths.’ oc. 420 eee 77

Otoliths and other fish remains from
a Long Beach, California Plio-

cene deposit) ) 33> eee eee ie
Paracimbocera robusta ........... 46
Phaeocolax kajimurae ........... 211
Philolotesirita‘elviracean eee 99
Pierce, W. Dwight, memoriam ... . 147
Pituophis melanoleucus affinis .... 1
Platychrysis neustophila ......... 241
Pleistocene. <5... <3 5aehee ones 129
Pleurochrysis scherffelii ......... 239
Pliocene, fossill.:5 2=heee eae 77
Puerto Penasco, Mexico ......... 233
Pupars. i. ..06 Gi hake eee 49
Recent records of water birds in the
desert a... 1.3. cose See 125
Reimer: RY Doe eee 77
Reproduction, lizards ............ 251
Rhaphiomidas terminatus ........ 49
Schizymenia borealis ............ 169
S. dawsoni\... .. 555550 oeee 168
S. ecuadoreana ............... 171
SJ €pipiiyticay a a eee 166
S:, PACIICA 04.3...) Oe 162
Sciadophycus stellatus ........... 195
Scott; Jg5 es a ee 195
Self-regulatory growth in the green
alga Enteromorpha prolifera for-
MAC) a3 cae eye ee Oe ee 29
Sleeper, E. Li... .. 2 nee 46
Slosson) Jaa sean eae 129
Smakes: oso d once coe 1
Snelling, FR. Re... eee 103

286

Some life history data on several
species of common spiders from
the Jackson Hole area of Wyom-

WA? > occ 6c ot 9 SE OEE Dee 142
Spidensmeenyeiy ce oe thee eee 142
SLEPMCHIGWIN CA ici 6 cee ts es 1
SHICHOCOECUSISD! a5 08a vs toe ns ss 00 0 OAD

Studies in the foliose red algae of the
the Pacific Coast Il. Schizyome-
nia

Studies of the blood of Ascidia nigra
(Savigny). I. Total blood cell

counts, differential blood cell

counts, and hematocrit values... 23

II. Vanadocyte agglutination and

its effect upon the heart ........ 117
CUUIGUSIS)LUGLICUS 032 oe ss ne 282
Tantilla eiseni transmontana...... 1

The pupa of Rhaphiomidas termu-
natus Cazier (Diptera: Apioceri-

dae ie ier pe eI ee a 49
Doves bel Des, aisrenecin dunt ke 6 Be ores Slo 29
TOTMATCLUSESD rte ee ay ae 39
Mri Gaitals,. ene at eects aera ahace 23, 117
Underwater sounds associated with

ageressive behavior in defense of

territory by pinfish, Lagodon

GROMmbOICC SE eee 69
Walle. JicAy. Ire sc dene tease 23, 117
Walken Veo oe 8: hosis arecmeere en ier 109
Womersleyella pacifica .......... 213
We op. Var ominor. joshi as 219
Zoospore release rates in giant kelp

IVIQCTOCY SIS 7 et ee oe ae 223

287

oe

ge @ MS

CO N

10.

STATEMENT OF OWNERSHIP AND MANAGEMENT

Date of filing: September 27, 1967.
Title of publication: Bulletin of the Southern California Academy of Sciences.

. Frequency of issue: Quarterly—March, June, September, December.

Location of known office of publication: 900 W. Exposition Blvd., Los Angeles,
California, 90007.

. Location of Headquarters: Same.

. Publisher: Southern California Academy of Sciences.

Editor: Donald J. Reish, Department of Biology, California State College at
Long Beach, Long Beach, California, 90804.
Managing Editor: None.

. Owner: Southern California Academy of Sciences—A non-profit Corporation.

. Known bondholders, Mortgagees, and other security holders: None.
Extent and nature of circulation:
Average no. copies Single issue nearest
each issue during to filing date
preceding 12 months
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F. Office use, left-over, unaccounted,
spoiled after printing 223 219

G. Total 750 750

Southern California
Academy of Sciences

OFFICERS OF THE ACADEMY

O80 a. SIME DD Jee See One eee ie eye President

iV E PATTI IVIGQITIS, <c.\.crs «66 6 oie cis eens 6 wees cee ess First Vice President

oo. Jthgy 54017 Ge Cee ea Second Vice President

PEMIPEIMEIHOATING 6 So ait. wh aie sea oe edit ds eee dat eee ees Secretary

Cong. ee TE.. JCIGIGI oR SIRS aig a ee ee Treasurer

0. Luna |’. GATS IM GI, Beenie tee eet Oe eS On Editor
DIRECTORS

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"

No

3ULLETIN OF THE
Southern California
Academy of Sciences

pe LOS ANGELES, CALIFORNIA

‘. VOL. 67 JANUARY-MARCH 1968 Part 1

try FS A PT %
LIBRARY

NEW YORK
BOTANICAL GARCE

CONTENTS

A New Red-eyed Tree-frog (Family Hylidae) from Costa Rica, with
a Review of the Hyla uranochroa group. Jay M. Savage

Aggressive Behavior in the Polychaetous Annelid Family Nereidae.
Donald J. Reish and M. Carol Alosi

Billfish Remains from Southern California with Remarks on the Im-
portance of the Predentary Bone. Harry L. Fierstine and Shel-
ton P. Applegate

Pseudocryptochirus crescentus (Edmondson), a Second Crab of the
Corallicolous Family Hapalocarcinidae (Crustacea, Decap-
oda) from the Eastern Pacific with Remarks on Phragmosis,
Host specificity, and Distribution. John S. Garth and Thomas
S. Hopkins 40

Trace Elements in Tissues of the Calico Bass Paralabrax clathratus
(Girard). R. P. Stapleton
| The Addition of the Hydroid Cladocoryne floccosa to the California
Marine Fauna. Dennis C. Lees
Research Note:

Brooding of the Eastern Glass Lizard, Ophisaurus ventralis. —_
Allen Vinegar

Issued April 26, 1968

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Ree UN TOE THE SOUTHERN CALTRFORNIA
ACADEMY OF SCIENCES

Vol. 67 JANUARY-MARCH, 1968 PART I

A NEW RED-EYED TREE-FROG (FAMILY HYLIDAE)
FROM COSTA RICA, WITH A REVIEW OF THE
HYLA URANOCHROA GROUP

JAY M. SAVAGE

Department of Biological Sciences and Allan Hancock Foundation,
University of Southern California, Los Angeles, California 90007

INTRODUCTION

Among the principal objectives of my field studies in Costa Rica, under
a John Simon Guggenheim Memorial Fellowship for 1963-64, was to
rediscover and identify with certainty the species of amphibians and
reptiles collected by William M. Gabb in 1874 from the Talamanca
region of southeastern Costa Rica. Most of these forms were described
by Cope (1875) and many have not been obtained subsequently. With
this project in mind Norman J. Scott, Jr. and I visited the Valle de Tala-
manca and nearby slopes of the Cordillera of the same name during
March 1964 and attempted to follow the route of Gabb’s expedition to
the high peaks of the range. A full account of Gabb’s route and the iden-
tity of his materials will appear elsewhere. While retracing Gabb’s steps
and looking for animals that were conspecific with those collected by
him, we unexpectedly discovered an apparently undescribed population
of red-eyed tree-frogs. With reference to the blood red eyes of members
of this group the new form is called

Hyla lythrodes, new species
Fig. |

Holotype: LACM 26766, an adult male, collected March 20, 1964,
by Jay M. Savage and Norman J. Scott, Jr.

Type Locality: Costa Rica: Provincia de Limon: Canton de Limon:
Alta Talamanca: 21 km SW Amubri at confluence of Rio Lari and Rio
Dipari, 800 m.

Diagnosis: In life, the bright red eyes of lythrodes distinguish it from
all other hylids known from lower Central America, except its three

I

2 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

close red-eyed relatives, Hyla legleri, Hyla rufioculis and Hyla uran-
ochroa, and some members of the genus Phyllomedusa. The latter group
has vertically elliptical pupils (horizontally elliptical in Hyla) and are
usually leaf green in dorsal ground color in life or deep blue-purple in
preservative (the dorsum of the new species is brown both in life and
preservative).

Within the red-eyed group H. lythrodes is distinctive in the following
combination of characteristics: 1) size small, to 30 mm in adult male;
2) snout moderately long, distance from eye to nostril less than diameter
of orbit; 3) tympanum moderate, larger than largest finger disks, ap-
proximately half diameter of orbit; 4) ulnar fold very weak, no series of
enlarged ulnar tubercles; 5) dorsum a uniform light brown; 6) posterior
surface of thigh light, without dark pigment; 7) light line along lip ex-
panded into a distinct suborbital light area; 8) throat light and 9) sole of
foot heavily pigmented. In salient features of morphology the new spe-
cies most closely resembles H. legleri of southwestern Costa Rica, but
differs from it in (/egleri characteristics in parentheses) lacking ulnar
tubercles (a well-developed series present), in having the posterior thigh
surfaces without dark pigment (suffused with dark pigment), the sub-
orbital expansion of the light lip line (no light expanded suborbital
mark) and the light throat (throat usually heavily and darkly pigmented).
H. legleri is the most robust frog in the red-eyed group, while lyth-
rodes agrees with rufioculis and uranochroa in being slender and deli-
cate in form.

In general coloration lythrodes approaches rufioculis of Atlantic and
Pacific Costa Rica but is distinct in morphology and limb coloration.
H. rufioculis has a small tympanum, scarcely larger than the largest
finger disk and less than one-third the diameter of orbit and the poste-
rior surface of the thigh suffused with dark pigment. From H. uran-
ochroa (characteristics in parentheses) the new frog differs in having a
shorter snout (distance from eye to nostril equal to diameter of orbit),
no distinct ulnar ridge (a conspicuous ridge present), dorsal coloration
(bright green in life, blue-grey to purplish in preservative), the expanded
suborbital light area (usually present but usually not expanded) and
dark sole of foot (light).

After preservation the new form might be confused with other hylids
from the Nicaragua-Costa Rica-Panama region that have little or no
finger webbing (at least two phalanges of each finger free from web),
no series of ulnar tubercles forming a distinct ulnar ridge, a uniform
dorsal coloration without dark spots or blotches, no dark bars on the
posterior surface of thighs and the venter immaculate (cherrei, colymba,
elaeochroa, microcephala, staufferi, subocularis and zeteki). H. lyth-

New Red-Eyed Tree-Frog 3

Figure 1. Lateral views of head for tree-frogs of the Hyla uranochroa group. A. H.
uranochroa; B. H. lythrodes; C. H. legleri; D. H. rufioculis; E. H. tica; F. H.
debilis;G. H. rivularis; and H. H. pictipes. Drawn to various scales.

4 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

rodes may be separated from cherrei, colymba, microcephala and sub-
ocularis by foot webbing, since these forms have webs that extend al-
most to the base of the toe disks (at least 1% and usually 2 or more
phalanges free of webbing in the new form). The new species is easily
distinguished from the occasional specimens of H. elaeochroa and H.
staufferi that lack dorsal dark markings by having a short but conspicu-
ous web between fingers 2-3-4 (finger webs reduced to a mere vestige or
absent in elaeochroa and staufferi). Lythrodes most obviously differs
from H. zeteki in having a much larger tympanum (larger than outer
finger disks in the new species versus smaller than finger disks in zeteki).
From all of the mentioned species the new red-eyed form further differs
in having an expanded suborbital light area.

General Characteristics: A small tree-frog with smooth upper sur-
faces; body form slender and delicate. Head viewed from above trun-
cate, broader than long. Skin free from skull. Nostrils somewhat pro-
tuberant, directed laterally. Eyes large, lateral in position; diameter of
orbit equals interorbital width. From side, snout rounded. Distance
from eye to tip of snout greater than interorbital. Distance from eye to
nostril less than orbital diameter. Canthus rostralis rounded, loreal area
slightly concave. Tympanum round, about 1/3 distance from eye to tip
of snout, much larger than outer finger disks, almost 12 diameter of
orbit. A distinct low glandular ridge from eye above tympanum to
shoulder.

Anterior limbs moderate, undersides of hands rugose; fingers smooth
except for single subarticular tubercles. Disks rounded, well-developed.
Thenar tubercle elongate, palmar tubercle small, obscure. Finger web-
bing formula I 3-3 112% - 3% III 3-24 IV. No fringe, prominent fold
or tubercle ridge along outer margins of arm. Male breeding adspers-
ities On upper and inner surface of basal portion of thumb. Hindlimbs
moderate. No fringes or rows of tubercles on outer margins. Underside
of foot with small tubercles. Disks round, slightly smaller than finger
disks. An obscure small elongate inner metatarsal tubercle, but no outer;
no obvious tarsal fold or tubercles. Subarticular tubercles smooth, mod-
erate, single. Toe webbing formula: I 2-212 II 114%2-2% III] 1% - 2+ 1V
2%2-1% V.

Throat smooth, wrinkled and forming single internal vocal sac.
Venter and undersides of thighs granular, covered by numerous small
glandular structures particularly in pectoral region, along flanks and
undersides of thighs, apparently produced by a mite infestation.

Choanae moderate, elliptical; vomerine teeth in two small patches
arranged in transverse series between posterior margins of choanae;
well separated from choanae and other tooth patch. Ostia pharyngea

New Red-Eyed Tree-Frog 5

moderate. Tongue oval; vocal slits large, paired posterior and lateral to
mid-level of tongue.

Coloration: In life, dorsum light uniform brown, eyelids and top of
head with enough green pigment to produce bronze effect. White-ivory
stripe from tip of snout along lip to groin. An obscure light stripe on
posteroventral margin of arm and foot. White line on knee and above
anus. Upper surface of limbs pale brown with pinkish cast. Venter and
throat pale yellow, separated from lateral ivory stripe by a greenish-
black line which is best developed in groin. Undersides of limbs and
anterior and posterior surfaces of thigh yellow, brighter on thighs.

In preservative, light brown above, venter and other under surfaces
white. No hint of green on head; ivory line and greenish border not evi-
dent. Light lip stripe conspicuous, expanded into prominent suborbital
light area. Limb and supra-anal light lines visible. Sole of foot heavily
pigmented. Faint thumb adspersities orange-brown and extensive orange
glandular areas on chest, flanks and under thighs.

Measurements: The single known specimen is 30 mm. in standard
length. Measurements in millimeters followed in parentheses by the
measure as per cent of standard length are: head length 10 (32); head
width 11 (37); vertical diameter of tympanum 1.5 (5); diameter of orbit
4 (13); distance from eye to tip of snout 4.5 (15); least width of inter-
orbital space 4 (13); length of hindlimb (anus to tip of longest toe) 46
(155); tibia 15.5 (52); foot, including tarsal segment, 20 (67); length of
4th toe 8 (26).

Distribution: Known only from the type locality in Subtropical Rain-
forest (Holdridge, 1964). To be expected in the subtropical zone (500-
1500 m) in southeastern Costa Rica and adjacent Atlantic versant of
Panama.

Call and Calling Site: The holotype of the new form was captured in
a tree about 3 m above a 2 m wide tributary of the Rio Lari. The breed-
ing call was strikingly different from the voice in other members of the
red-eyed group.

Hyla uranochroa is usually heard throughout the rainy season (April
to December in Costa Rica) with the largest choruses in the wettest
months (September-November). The call is a steady faint bell-like ping'
ping' ping' with no noticeable interruption. Usually this species is con-
gregated near fast moving streams 1-3 m wide, in vegetation from 0.5 to
3 m above the substratum. The call of H. rufioculis consists of a single
non-melodic scraape' repeated about every 5 seconds. This form has
been heard calling from August to December and tends to aggregate
around small shallow streams or seeps that drain into streams. Males
are found on the stalks and branches of low shrubs or saplings from 30

6 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

to 75 cm above the substratum. Hyla legleri males call from the banks
of small fast moving streams or from branches of low shrubs, no more
than a few centimeters above the ground. The call is a single wauk',
repeated at widely separated intervals. The species has been heard only
early in the rainy season (June-July) before the streams become espe-
cially high.

The call of H. lythrodes most closely resembles that of H. uranochroa,
within the red-eyed group. The note is a weak bell-like ping', produced
in bursts of 5-7 notes and followed by a pause and then another burst.
Both the call and call site of the new species are reminiscent of uran-
ochroa and suggest a closer relationship between these two forms than
either has to /egleri and rufioculis.

STATUS AND RELATIONSHIPS OF THE Hyla uranochroa GROUP

Starrett (1966) suggested that the red-eyed hylas (Hyla uranochroa and
its allies) might be allied to another distinctive cluster of stream-breed-
ing species from Costa Rica, including H. debilis, H. pictipes, H. rivul-
aris and H. tica. Duellman (1963) had proposed previously that the red-
eyed group probably is closely related to the nominal genus Ptychohyla
of upland southern México, Guatemala, El Salvador and Honduras.
Examination of a cleared and stained specimen of seven of the spec-
ies supplemented by radiographs of all eight forms indicates a marked
similarity among the four red-eyed species and H. pictipes and its al-
lies, in skeletal features. All have similarly shaped premaxilla that have
a short posterior process that does not meet the nasal or ethmoid. None
has an ascending process from the maxilla that contacts the nasal or eth-
moid. All have an elongate to ovoid frontoparietal fontenelle. The na-
sals are large and separated from one another on the midline in all eight
forms. The nasals are relatively broad and are separated by the large
ethmoid in debilis, rivularis and pictipes. They are elongate and separ-
ated from one another in the other forms and the ethmoid is rather short.
The ethmoid and nasals are in contact in debilis, rivularis, rufioculis,
and pictipes and separated in legleri, lythrodes, tica and uranochroa.
The quadratojugal is elongate and articulates with the maxilla in legleri,
lythrodes and uranochroa; elongate but not articulating with the maxilla
in tica; reduced to a small nub of borie on the anterior face of the lower
limb of the squamosal in debilis, rivularis, and rufioculis; and is a very
small element or absent entirely in pictipes. The skull is weakly ossified
in legleri, lythrodes, tica and uranochroa as compared to the other four
species. In terms of general skull features the last named species are
remarkably similar in the condition of the nasoethmoid region and the
large quadratojugal-maxilla articulation. The other red-eyed species,

New Red-Eyed Tree-Frog 7

rufioculis, agrees with these forms in having elongate nasals. H. debilis,
rivularis and pictipes resemble one another and differ from the remain-
ing species in having broad nasals that are separated from medial con-
tact with one another by the large anteriorly expanded ethmoid.

The larvae of the several species, where known, also exhibit strong
resemblances as pointed out by Starrett (1966). The tadpoles of rivul-
aris, rufioculis, pictipes and uranochroa are stream-adapted larvae with
large sucking oral disks, denticles in 2 or 3/3 or 4 rows and elongate
low-finned tails.

The male breeding calls and call sites for the individual species are
distinctive. The calls in the red-eyed forms have been summarized
above. Starrett (1960) described the calls of pictipes and tica and Tay-
lor (1952) referred to the calls of debilis and rivularis without descrip-
tion. The calls and calling sites of the four forms allied to pictipes, based
upon data provided by P. H. Starrett and N. J. Scott, Jr. and my field
observations are:

debilis - a steady low insect-like cheep of several seconds duration;
barely audible above rush of stream; all males calling from thick clumps
of foliage overhanging stream, about 0.5 to | m above water or bank;

rivularis - a steady low cricket-like cheep, cheep, cheep of lower in-
tensity and longer duration than call of debilis; males call from situat-
ions similar to those for debilis, but usually from deeper in the stream
bank foliage;

pictipes - a single weak drawn out eeck or two notes chick! eeck!,
with long gaps between calls; males call from along stream bank from
places of concealment near ground level or from rocks in the cascading
streams;

tica - a three or four note series, chirp-chirp-chirp, with a space about
twice as long as call between each series; males call from vegetation
overhanging a stream, from 1-3 m above water, usually not concealed
but sitting out openly on limbs, branches or leaf surfaces.

Choruses of H. debilis and tica have only been heard at the height of
the rainy season in Costa Rica from August to December. Occasional
tica have been heard in the dry season. H. rivularis has been heard cal-
ling at all times of the year. H. pictipes seems to breed at times of low
water and I have heard it calling only in January and February. Col-
lections made by Mrs. Starrett suggest that the males also call and pos-
sibly breeding also takes place during the short dry season that may
occur in late July and early August in Costa Rica. The amount of water
in the torrential streams where this species breeds obviously is a limiting
factor to breeding activity.

In terms of general morphology, external, skeletal and larval charac-

8 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

teristics, it seems apparent that the red-eyed hylas and pictipes and its
relatives form a cluster of related species. It is appropriate to call this
cluster the Uranochrea group in the following discussion.

The eight members of the Uranachroa group do not appear to be
closely related to any other hylid stock in lower Central America. In
many ways the group exhibits characteristics that show relationship
with the genus Ptychohyla of the mountains of upper Central America
and Mexico, as suggested by Duellman (1963). The two stocks have
similar stream adapted larvae and externally resemble one another in
general morphology. Comparison of a cleared and stained Prtychohyla
spinipollex (JMS 1436) with members of the Uranochroa group indi-
cates essential similarity in skeletal features. Contrary to Duellman
(1963, fig. 3), I find no large ascending process of the maxilla that ex-
tends to the level of the ethmoid. Apparently the process figured by him
is the separate palatine bone, seen through cleared tissue. Similarly
bones seen in Duellman’s figure in the premaxillary region appear to be-
the anterior portions of the vomers. This species of Ptychohyla has a
weakly ossified elongate skull, nasals that are separated from one an-
other and the ethmoid is short. There is no nasal-ethmoid contact. The
quadratojugal is short and does not meet the maxilla. In these features
the species agrees with H. tica and several of the red-eyed forms.

Recognition of the genus Ptychohyla is based solely upon the presence
of ventrolateral glands in breeding males. The Uranochroa group
shares basic similarities with Ptychohyla and suggests that both are de-
scendants of a single evolutionary line. It is also possible that the obser-
ved similarities are the result of parallel adaptation to montane life.
Until an adequate evaluation of the relationships of all Central Ameri-
can hylids is undertaken, definite conclusions regarding these two
groups are not possible. If the two stocks are not closely related and
other features besides ventrolateral glands distinguish Ptychohyla from
other hylid lines, then the latter genus might be recognized. If the con-
verse is the case and ventrolateral glands prove to be of multiple origin
in several tree-frog groups, then it will seem best to regard Ptychohyla
and the Uranochroa group as distinct species clusters within Hyla.

SyNopsIs OF Hyla Uranochroa GROUP

Definition: Posterior process of premaxilla not reaching nasal or eth-
moid; no ascending nasal process on maxilla; nasals large, separated
from one another on midline; a flattened prepollex that does not extend
through skin produces a swollen thumb; single vocal sac, with paired
vocal slits in males. Breeding males with moderately developed thumb

New Red-Eyed Tree-Frog 9

adspersities, not spinous. Mountain stream larvae with low tail fin,
large oral disk; denticles in 2 or 3/3 or 4 rows.

General Description: The following characteristics are shared by all
known members of the group. Head about as wide as long; interorbital
space equal to diameter of orbit; skin of head not fused to skull. Nostrils
lateral, near tip of snout, directed laterally and slightly dorsally. Snout
moderate to short, distance from eye to nostril equal to or less than diam-
eter of orbit. Tympanum evident; a distinct supratympanic fold. Ven-
ter strongly granulate. Palms and soles covered by numerous rounded
tubercles. Thenar tubercle moderate, elongate; palmar tubercle small.
Inner metatarsal tubercle moderate, elongate; outer tiny, frequently
obscure. A weak outer tarsal fold or ridge of tarsal tubercles, no inner
fold or tubercles. No elongate or prominent heel tubercle. Fingers and
toes webbed.

Pictipes Subgroup

Diagnostic characters found in all species of this subgroup include.
iris dull orange, brown or gold in life; vomerine teeth in patches that
extend posterior to posterior margins of choanae; male vocal slits at
level of mid-point of tongue and hidden under it for at least half their
length; no conspicuous continuous white lateral line; undersurfaces
marked by scattered small dark flecks.

Hyla debilis Taylor

Hyla debilis Taylor, 1952, p. 880, fig. 62

Holotype: KU 28184, an adult male.

Type Locality: Costa Rica: Provincia de Heredia: Canton de Here-
dia. Isla Bonita (American Cinchona Plantation), E slope Volcan Poas,
1700 m.

Diagnosis: The smallest species in the group, markedly different
from its closest allies in the following combination of characteristics.
1) snout acute in profile; canthus rostralis sharp; 2) tympanum small,
vertical diameter 1/3 diameter of orbit; equal to disks of outer fingers;
3) vocal sac external; 4) modal finger webbing formula I 3-3 II 2~ - 3
If] 2% - 2 1V; subarticular tubercles under thumb single or double; 5)
a weak series of ulnar tubercles; 6) dorsum smooth; 7) modal toe web-
bing formula I 2--2* II 1+-2% III 1%-2% IV 2% - 1+ V; 8) maxi-
mum standard length males 28 mm, females 29 mm; 9) dorsum uniform
dull dark green, olive, tan or beige frequently with small enamel-like
bright green flecks; a discontinuous lateral white glandular ridge from
groin to about mid-body, sometimes reduced to an elongate white spot;

10 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

10) posterior surfaces of thigh bright yellow, usually without any suf-
fusion of dark pigment; upper surface of thigh uniform; 11) sole of foot
suffused with dark pigment; 12) light lip stripe with an expanded sub-
orbital light area; 13) throat with numerous small scattered dark spots
and flecks; 14) iris dull orange in life.

Distribution: Known from two localities on the Atlantic slope of
Costa Rica at Isla Bonita (1700 m) and Rio Quiri (1350 m) near Tapan-
ti, Provincia de Cartago and from Boquete, Provincia de Chiriqui, Pan-
ama (1200 m), UM 69496.

Hyla pictipes Cope

Hyla punctariola pictipes Cope, 1875, p. 106 (Type locality: Costa
Rica: Provincia de Limon: Canton de Limon: E slope Cerro Utyum,
erroneously cited as Pico Blanco, 1500-2100 m.)

Hyla punctariola monticola Cope, 1875, p. 106 (Type locality: Costa
Rica: Provincia de Limon: Canton de Limon: E slope Cerro Utyum,
erroneously cited as Pico Blanco, 1500-2100 m.)
Hyla moesta, Taylor, 1952, p. 855 [quotation of Cope description].

Hyla monticola, Taylor, 1952, p. 855 [quotation of Cope description] .
Hyla pictipes, Taylor, 1952, p. 878 [redescription of syntypes].
Ayla pictipes, Starrett, 1966, p. 17, figs. 1-2 [redescription].

Lectotype: USNM 30652

Type Locality: Costa Rica: Provincia de Limon: Canton de Limon:
E slope Cerro Utyum, misidentified by the collector William M. Gabb
as Pico Blanco, 1500-2100 m.

Diagnosis: The largest member of the group, trenchantly different
from its allies in the following combination of characteristics: 1) snout
acute in profile; canthus rostralis sharp; 2) tympanum small, vertical
diameter 1/3 diameter of orbit; 3) vocal sac internal; 4) modal
finger webbing formula I 312-3 II 2~ - 3% III 3~-2 IV; subarticular
tubercles under thumb single; 5) a series of ulnar tubercles; 6) dorsum
smooth; 7) modal toe webbing formula I 112-2% II 1+-2% III 1+-2%
IV 2142-1* V;8) maximum standard length in males 40 mm, in females
45 mm; 9) dorsum usually uniform deep purple black, leaf green or
olive brown, rarely with obscure transverse blotches, no lateral light
stripe or spot; 10) posterior surface of thigh and groin dark olive with
numerous well-defined yellow spots; upper surface of thigh uniform;
11) sole of foot heavily pigmented; 12) a narrow light lip stripe, without
suborbital expansion; 13) throat mottled with light and dark pigment;
14) iris brown in life.

Distribution: High altitudes of the Cordilleras Central, and Tala-

New Red-Eyed Tree-Frog II

manca of Costa Rica, between 1900-2500 m.

Remarks: Starrett (1966) reported on the rediscovery of this species
and described the color variation. Later Duellman (1966) remarked
that males and females exhibit sexual dichromatism in dorsal color.
Scott and I noted the several dorsal ground colors and patterns describ-
ed by Starrett and Duellman for a series of H. pictipes from the W fork
of Rio Las Vueltas, on the Alto del Roble, Provincia de Heredia, Costa
Rica (2030 m). In this sample all of the previously discussed dorsal
ground colors and patterns occur in males but none of the females are
deep olive-brown to black.

Ayla rivularis Taylor

Hyla rivularis Taylor, 1952, p. 847, fig. 53; 1960; Starrett, 1952, p.23,
Figs. 21-22 (larvae).

Holotype: KU 28197, an adult male.

Type Locality: Costa Rica: Provincia de Heredia: Canton de Here-
dia: Isla Bonita (American Cinchona Plantation), E slope Volcan Poas,
1600 m.

Diagnosis: A distinctive common montane form, separated from
other members of the Uranochroa group in: 1) snout acute; canthus ros-
tralis sharp; 2) tympanum small, vertical diameter 1/3 diameter of orbit;
smaller than disks of outer fingers; 3) vocal sac external; 4) modal finger
webbing formula I 3-3 II 2'’2-3'% III 2 2/3-2* IV; subarticular tuber-
cles under thumb double; 5) a distinct series of ulnar tubercles; 6) dor-
sum smooth, rarely with a few small low granules laterally; 7) modal
toe webbing formula I 2~-3 II 1+-2 2/3 HI 1%4-2 /31V2 1/3-1% V; 8)
maximum standard length of males 34 mm, females 37 mm; dorsum
beige, gray, green-gray or yellowish brown, sometimes uniform, but
usually with dark brown blotches and bands; 10) posterior surface of
thigh dull yellow to gray, usually suffused with some dark pigment;
upper surface uniform; 11) sole of foot heavily pigmented; 12) no light
lip stripe; 13) throat speckled with dark pigment; 14) iris dull gold in
life.

Distribution: The upper slopes of the Cordilleras de Tilaran, Cen-
tral, and Talamanca in northern and central Costa Rica, between 1200-
2000 m.

Hyla tica Starrett

Ayla tica Starrett, 1966, p. 23, fig. 5.

Holotype: UM 122482, an adult male.

Type Locality: Costa Rica: Provincia de Cartago: Canton de Tur-
rialba: S slope Volcan Turrialba, 1300 m.

12 Bulletin So. Calif. Academy Sciences / Vol. 67, No. 1, 1968

Diagnosis: A large species amply distinguished from other members
of the group by: 1) snout rounded to vertical in profile; canthus ros-
tralis rounded to sharp; 2) tympanum moderate, vertical diameter 12
diameter of orbit; equal to or slightly smaller than outer finger disks;
3) vocal sac external; 4) modal finger webbing formula I 242-2% II
134-3 III 2 1/3 - 2 IV; subarticular tubercles under thumb double; 5)
a well-developed series of ulnar warts; 6) dorsum with wide-spaced
warts and tubercles; 7) modal toe webbing formula I 1*-2 II 1-2 III 1-2
IV 2- 1 V; 8) maximum standard length in males 34 mm, in females 38
mm; 9) dorsum brown to beige usually with large dark brown blotches
and spots and some green enamel-like flecks; frequently a series of
enamel white spots along lower margin of dorsal color along flank; 10)
posterior surface of thigh yellow, usually suffused with dark pigment;
upper surface usually barred; 11) sole of foot heavily pigmented; 12) no
light lip stripe; 13) throat with scattered dark spots; 14) iris in life brown-
gold to reddish gold.

Distribution: Slopes of the Cordilleras de Tilaran, Central, and Tala-
manca in northern and central Costa Rica, and the Pacific slope of
Volcan Chiriqui, Panama, from Boquete (UM 70664-67). All localities
are between 1100-1600 m.

Uranochroa Subgroup

Diagnostic characters shared by all members of the subgroup are: iris
bright red in life; vomerine tooth patches entirely between choanae;
vocal slits in males lateral and posterior to middle of tongue, with only a
small section, if at all, hidden under it; a conspicuous continuous white
lateral line on each side of body (sometimes obscure or lost in preserv-
ative) separating ventral from dorsal ground color, a white line along
posteroventral margin of arm, another along posteroventral margin of
hindlimb from heel to foot and a light supra-anal line (sometimes ob-
scure or absent in preservative); venter usually immaculate, never with
a peppering of small dark specks.

Hyla legleri Taylor

Hyla legleri Taylor, 1958, p. 33, figs. 15-16.

Holotype: KU 32982, an adult male.

Type Locality: Costa Rica: Provincia de San José: Canton de Perez-
Zeledon: 15 km WSW San Isidro de El General on road to Dominical,
approximately 800 m.

Diagnosis: Distinguished from other members of the Uranochroa
subgroup in the following combination of features: 1) snout rounded in

New Red-Eyed Tree-Frog 13

profile; canthus rostralis rounded; 2) tympanum moderate, vertical
diameter ¥2 diameter of orbit; equal to or larger than outer finger disks;
3) vocal sac internal; 4) modal finger webbing formula I 3-3* II 1142-2%
III 2+-2 IV; subarticular tubercles under thumb single; 5) a series of
strongly developed ulnar warts; 6) dorsum smooth; 7) modal toe web-
bing formula I 1-2 II 1-2 III 1-2 IV 2-1 V; 8) maximum standard length
of males 35 mm, of females 39 mm; 9) dorsum uniform light to dark
brown with a few spots or mottling of darker brown and bronze flecks; a
well-developed ivory line along flank, usually bordered below by dark
mottling; 10) posterior surface of thigh yellow, suffused with dark pig-
ment; upper surface of thigh uniform; 11) sole of foot heavily suffused
with dark pigment; 12) light lip stripe best indicated anteriorly, usually
suffused with dark pigment at level of orbit, never expanded under eye;
13) throat usually heavily suffused with dark pigment.

Distribution: Known from several localities on the Pacific versant of
southern Costa Rica from 700-1000 m in elevation.

Hyla lythrodes Savage
(see description above)

Diagnosis: Readily separated from the red-eyed members of the
group as indicated in the description and from all other species in the
group in the following characteristics: 1) snout rounded in profile; can-
thus rostralis rounded; 2) tympanum moderate, vertical diameter equal
to % orbital diameter; larger than outer finger disks; 3) vocal sac in-
ternal; 4) modal finger webbing formula I 3-3 II 24% -3% III 3-24 IV;
subarticular tubercles under thumb single; 5) no well-developed ulnar
ridge or tubercles; 6) dorsum smooth; 7) modal toe webbing formula I
2-24 II 14%2-2% Il 1954-2 IV 2% - 1% V; 8) maximum standard
length in male 30 mm; 9) dorsum uniform light brown; ivory flank, arm,
leg and supra-anal light stripes present in life, weakly evident in pre-
servative; 10) posterior surface of thigh yellow, without dark pigment;
upper surface uniform; 11) sole of foot suffused with dark pigment; 12)
light lip stripe well-developed, expanded into large suborbital light area;
13) throat immaculate.

Distribution: see above.

Hyla rufioculis Taylor

Hyla rufioculis Taylor, 1952, p. 827, fig. 47
Holotype: KU 28216, an adult female.
Type Locality: Costa Rica: Provincia de Heredia: Canton de Here-
dia: Isla Bonita (American Cinchona Plantation), E slope Volcan Poas.
Diagnosis: Distinct from all other members of the Uranochroa group

14 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

in: 1) snout rounded in profile; canthus rostralis rounded; 2) tympanum
small, 1/3 orbital diameter; smaller than disks on outer fingers; 3) vocal
sac internal; 4) modal finger webbing formula I 3+-3* II 2~-3 HI 2%4-
2+ IV; subarticular tubercles under thumb single; 5) ulnar ridge present;
6) dorsum smooth; 7) modal toe webbing formula I 1 2/3-2* II 1-2%
III 1-2 IV 2-1 V; 8) maximum standard length in males 31 mm, in fe-
males 40 mm; 9) dorsum light or dark brown to bronze or olive-green,
frequently mottled with darker brown and often with a brassy green suf-
fusion; lateral stripes well-developed, arm, leg and supra-anal stripes
weakly evident in preservative; 10) posterior surface of thigh usually
yellow, always suffused with dark pigment, occasionally so heavily suf-
fused as to appear brown; upper surface uniform; | 1) sole of foot heavily
suffused with dark pigment; 12) light lip stripe well-developed, expan-
ded into large suborbital spot; 13) throat usually immaculate, occasion-
ally with large scattered dark spots.

Distribution: Along both Atlantic and Pacific slopes of the Costa.
Rican cordilleras at elevations between 650-1600 m.

Hyla uranochroa Cope

Hyla uranochroa Cope, 1875, p. 103, pl. 27, fig. 4; Dunn, 1925,
p. 2, pl. 1, fig. 1-1a; Taylor, 1952, p. 834, fig. 49 (synonymy, descrip-
tion).

Hyla alleei Taylor, 1952, p. 831, fig. 48 (Type locality: Costa Rica:
Provincia de Heredia: Canton de Heredia: Isla Bonita (American Cin-
chona Plantation), E slope Volcan Poas.

Holotype: USNM 30651

Type Locality: Costa Rica: Provincia de Limon: Canton de Limon:
near Sipurio, approximately 60 m.

Diagnosis: Distinguished from its close allies by the following com-
bination of characteristics: 1) snout rounded in profile; canthus ros-
tralis rounded; 2) tympanum moderate, vertical diameter 12 or more of
orbital diameter; larger than outer finger disks; 3) vocal sac internal;
4) modal finger webbing formula I 3+-3+ II 2-3 I] 2% -2* IV; sub-
articular tubercles under thumb single; 5) a well-developed ulnar ridge;
6) dorsum smooth; 7) modal toe webbing formula I 2~-2* II 1*-2+ III
1+-2+ TV 2+-1+ V; 8) maximum standard length in males 35 mm, in
females 40 mm; 9) dorsum uniform leaf green in life (purplish or bluish
in preservative), lateral, arm, leg and supra-anal ivory stripes well-
developed, although latter sometimes faded in preservative; 10) pos-
terior surface of thigh yellow, without dark pigment; upper surface uni-
form; 11) sole of foot light, without dark pigment; 12) light lip stripe

New Red-Eyed Tree-Frog 15

AN ARTIFICIAL KEY TO SPECIES OF THE Uranochroa GROUP

la. Vomerine tooth patches extend posterior to choanae; vocal slits in
males hidden under tongue for at least half their length; no continuous
white lateral line from head to groin; iris dull orange, gold or brown in
RCMP eo ea Pictipes subgroup (2)

2a. Upper surfaces smooth or with a few low granular warts; snout acute
in profile; upper surface of thigh not barred with dark; tympanum small,
VenmCAlmGianleten, 1/3 ONDIty a.) hi tuyco be) es arise eae ee elias (3)

3a. Outer finger disks larger than tympanum; no lateral light stripe or
elongate spot between groin and mid-body; no expanded light area un-
der orbit; thigh usually suffused with dark pigment .......... (4)

4a. Thigh and groin with a series of large yellow spots on brownish field;
internal vocal sac in males; dorsum usually uniform in color; subartic-
ilamiuberclesunder thumbsingle;. 95 5 2. 44-4... H. pictipes

4b. Thigh and groin without light spots; external vocal sac in males;
dorsum usually with large dark blotches and spots; subarticular tuber-
clegundercnumby double 2 H. rivularis

3b. Outer finger disks equal to tympanum; a lateral light stripe or elon-
gate spot anterior to groin; a prominent light lip stripe expanded into a
light spot under orbit; thigh usually not suffused with dark pigment . .

0 0 6 6:6 6. 6) ee ene nee Cem lle die Nir eee eee are eek rere H. debilis
prominent, usually slightly expanded in suborbital area; 13) throat
immaculate.

Distribution: Along both Atlantic and Pacific slopes of the Cordil-
leras de Tilaran, Central, and Talamanca of Costa Rica to the Carib-
bean slopes of Provincia de Bocas del Toro, Panama, at elevations from
650-1750 m. The holotype of the species probably came from the west
at a higher elevation than Sipurio.

Remarks: Duellman (1966) placed H. alleei Taylor in the synonymy
of uranochroa, since the presumed diagnostic characteristics of the for-
mer are not consistent in preserved topotypes. Actually the features of
coloration utilized by Taylor, absence of a supra-anal light line, lateral
light line and whitish frosting, to distinguish alleei from uranochroa,
which has all of these features, are differences produced in preservative.
In life all uranochroa, including topotypes of alleei, have light lateral
and supra-anal lines and are green in color. After preservation the lines
fade in some specimens and while most individuals become bluish in
dorsal color with white frosting, others lack the whitish cast. Taylor’s
alleei is based upon two frogs that had undergone these changes upon
preservation.

16 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

2b. Upper surfaces with warts and prominent tubercles; snout rounded
to vertical in profile; upper surface of thigh usually barred with dark;
tympanum moderate, vertical diameter 12 diameter of orbit . . H. tica

eh ay we eel Pe es ek 0) Nie) ei: Je: Ye; ley He) Stee tecl et) ei- Ye). Je}, “el Bertie \cei tive jie; loll ieill NeW EKER cmMte nn oMEcMEIolmtze

1b. Vomerine tooth patches between choanae; vocal slits in males later-

al to tongue, only a small portion hidden by tongue, if at all; a continu-

ous white lateral line from head to groin; irisredinlife........
CEs kN at he ills BI cea ag ES Uranochroa_ subgroup (5)

5a. Sole of foot heavily suffused with dark pigment; dorsal ground color
brown to greenish-brown in life and preservative; snout moderate to
short, distance from eye to nostril less than diameter of orbit . . . . (6)

6a. Posterior surface of thigh suffused with dark pigment .... . (7)

7a. White lip stripe not expanded under orbit; throat usually heavily
suffused with dark pigment to form a fine mottling; tympanum moder-
AtemVerticaladianme tote. 5O hl cementite nnn rn H. legleri —

7b. White lip stripe greatly expanded under orbit; throat immaculate or
with a few large dark blotches; tympanum small, vertical diameter 1/3
ODT vem, Bho ee a yitee Str cata ices tae tare neat eee een ae H. rufioculis

6b. Posterior surface of thigh not suffused with dark pigment .... .
Beech ped tity ator AN iin ska: Gala a. ie: a ein Ss aa H. lythrodes

5b. Sole of foot not suffused with dark pigment; dorsal ground color
uniform leaf green in life, bluish to purplish in preservative; snout mod-
erately long, distance from eye to nostril equals diameter of orbit .

A Saad eek Hn A ae ca NR rae MON a Arama ty On H. uranochroa

RELATIONSHIPS WITHIN THE URANOCHROA GROUP

The characteristics shared by all members of the Uranochroa group and
that distinguish them from other groups within the genus Hyla have
been reviewed in an earlier section of this paper. The eight included
species clearly belong to two distinct evolutionary lines based upon
differences in vomerine tooth placement, iris color, position of vocal
slits in males and basic coloration as detailed above.

Within the Pictipes subgroup, H. tica appears to represent a more
primitive stage of evolution than the three closely related relatively ad-
vanced species, H. debilis, H. pictipes and H. rivularis. H. tica differs
strikingly from the latter forms in having an elongate quadratojugal, a
small ethmoid that is separated from the nasals, rounded to vertical
snout and canthus rostralis usually rounded, moderate tympanum, warty
dorsum and barred upper thigh surface (versus quadratojugal reduced

New Red-Eyed Tree-Frog 1G]

to a small nub or absent, large ethmoid in contact with nasals, acute
snout and sharp canthus rostralis, small tympanum, smooth dorsum and
uniform upper thigh surface).

The principal differences among the members of the advanced stock
are in adult size, vocal sac condition and coloration. Each is distinctive
but rivularis appears to be somewhat intermediate between debilis and
pictipes, and at the same time more closely allied to tica than are either
of the other two forms. Rivularis and tica both have contrasting dorsal
patterns of blotches and spots (sometimes uniform), external vocal sacs,
uniform yellow posterior thigh surfaces, usually suffused with dark pig-
ment and are without discrete light spots.

H. debilis and rivularis differ primarily in coloration, adult size
and size of finger disks. The former species is reminiscent of the red-
eyed subgroup in having a dull dark green to beige dorsum that is fre-
quently uniform or with enamel-like light green flecks and an expanded
suborbital light spot from the distinct lip stripe and at least a hint of a
light lateral line in the groin region. In addition debilis adult males reach
a maximum standard length of 28 mm, females to 29 mm and have small
outer finger disks that equal the tympanum in size. Rivularis is brown to
grayish-green, usually with dark dorsal blotches, lacks a white lip or
lateral light stripe, has adult males with a maximum standard length of
34 mm and females to 37 mm and outer finger disks larger than the
tympanum. Both have external vocal sacs, similar insect-like calls and
unspotted posterior thigh surfaces.

A. rivularis and pictipes differ primarily in coloration, size and con-
dition of the vocal sac. The former is a brownish to gray frog, usually
with dark spots and blotches; the latter is essentially uniform in dorsal
coloration. In addition pictipes has a series of discrete light spots on the
posterior surface of the thigh and in the groin (these areas lack spots in
rivularis), reaches a maximum standard length in males of 37 mm, in
females to 40 mm (in rivularis 34 and 37 mm, respectively), and has an
internal vocal sac (external in rivularis). Neither species resembles
debilis in coloration and both have outer finger disks larger than the
tympanum (equal to tympanum in debilis).

In view of these characteristics it appears that rivularis lies near the
basal stock of the advanced species series and may have been derived
from an ancestor not unlike tica. Debilis and pictipes may be regarded
as independent derivatives of a rivularis-like stock.

The basic similarity in iris color and coloration in members of the
Uranochroa subgroup attests to the close relationship of the four in-
cluded forms. All have a bright red iris, dark upper surfaces and white
lip, lateral, supra-anal, arm and leg stripes in life. H. legleri, lythrodes

18 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

and uranochroa are closely allied and appear to be more primitive than
rufioculis. The three species have an elongate quadratojugal that articu-
lates with the maxilla, the ethmoid separated from the nasals and a
moderate tympanum, equal to 12 orbit (quadratojugal reduced to a nub,
ethmoid meeting nasals and tympanum 1/3 orbit in rufioculis). In these
features rufioculis parallels the characteristics of the debilis-rivularis-
pictipes line.

Within the red-eyed subgroup lythrodes occupies a central and pre-
sumably primitive position. It resembles Jegleri in basic coloration
(brown upper surface and dark pigment on the sole of the foot) and head
shape (eye to nostril distance shorter than diameter of orbit), and uran-
ochroa in body form, the thigh lacking dark pigment on posterior sur-
face, the prominent light spot below the eye and similar breeding call.
It is relatively easy to conceive of uranochroa and legleri as having
been derived from a lythrodes-like ancestor, the former evolving leaf-
green dorsal coloration, unpigmented sole and long snout (eye to nostril -
distance equals orbit); the latter a robust form, dark suffusion of the
thigh, throat area and suborbital light area by dark pigment. H. rufioc-
ulis resembles lythrodes and uranochroa in form and in having a sub-
orbital light area. The species is similar to /egleri in most other charac-
teristics. Possibly it is an off-shoot from the line leading from lythrodes
to legleri.

The relationship of the two subgroups within the Uranochroa group
is suggested by the characteristics of Hyla tica. Although differing from
the legleri-lythrodes-uranochroa stock in basic subgroup characteristics,
tica agrees with these species in the same significant features that sep-
arate it from debilis, pictipes, and rivularis. H. tica resembles the three
red-eyed species in having an elongate quadratojugal (meeting the max-
illa in the red-eyed frogs, separated from it in fica), a small ethmoid that
is separated from the nasals, snout rounded in profile, canthus rostralis
rounded and a moderate tympanum. These similarities indicate the
primitive position of Hyla tica in the Uranochroa group. Origin of the
red-eyed hylas from a form similar to tica but having a maxilla-quad-
ratojugal contact, through changes in pattern, iris color, vomerine tooth
position and vocal slit placement seems entirely probable.

The obvious differences in color pattern among species of the Uran-
ochroa group also suggest the primitive status of tica. H. tica is essential-
ly a blotched and spotted frog without a lip or lateral white stripe. In
many individuals, a series of enamel-like white spots are present along
the flanks near the line of demarcation between the dorsal and ventral
color. The prominent lateral white stripes of the red-eyed group could
have been derived by fusion and extension forward of these light areas

$$$ ________

VOMERINE TEETH BETWEEN CHOANAE
RIS BRIGHT RED

SONTINUOUS WHITE LATERAL LINE
/OCAL SLITS LATERAL TO TONGUE

iranochroa

New Red-Eyed Tree-Frog 19

at the same time that the blotched pattern changed to those patterns
typical of the red-eyed species. The light lateral stripe or elongate spot
in H. debilis also seems to be homologous to the spots in tica. H. rivul-
aris lacks any suggestion of the white areas found in tica. The promi-
nent yellow spots in the groin region of H. pictipes do not correspond to
the white areas in fica but seem to represent places where the light yellow
lateral coloration is not suffused by dark pigment. This pattern could
easily have been derived from that of rivularis, since it also has a yellow
groin region.

A summary (Fig. 2) of significant characteristics and their phyloge-
netic implications for the Uranochroa group emphasizes the basal
evolutionary role of H. tica.

IRIS ORANGE, GOLD, OR BROWN

VOCAL SLITS HIDDEN BY TONGUE

rivularis

rufioculis |

lythrodes _legleri

Ancestral

Stock

Figure 2. Relationships within Uranochroa group. Species above line A-A’ have
snout usually acute, sharp canthus and large ethmoid; below, snout usually round-
ed, canthus rounded and ethmoid small. Species above line B-B’ have quadrato-
jugal reduced or absent, ethmoid meeting nasals and small tympanum; below,
elongate quadratojugal, ethmoid separated from nasals and moderate tympanum.
Characteristics indicated at top of chart indicate features shared by species listed
to left or right of dotted line.

VOMERINE TEETH POSTERIOR TO CHOANAE

NO CONTINUOUS WHITE LATERAL LINE

pictipes

Ne

20 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

ACKNOWLEDGMENTS

The aid of the following individuals who have contributed to preparation of this
paper is gratefully acknowledged: James R. Dixon, Los Angeles County Museum
of Natural History (LACM); W. R. Heyer, Norman J. Scott, and Mrs. Priscilla H.
Starrett, University of Southern California. John T. Kitasako of the latter institu-
tion prepared the illustrations. Other collection numbers mentioned in the text
are indicated by the following abbreviations: KU, University of Kansas; UM,
University of Michigan; and USNM, United States National Museum.

LITERATURE CITED

COPE, EDWARD D.
1875. On the Batrachia and Reptilia of Costa Rica. J. Acad. Nat. Sci. Phila.
(letterpress), ser. 2, (8):93-157.

DUELLMAN, W. E.

1963. A review of the Middle American tree frogs of the genus Ptychohyla.
Univ. Kansas Publ., Mus. Nat. Hist., 15:297-349.

1966. Taxonomic notes of some Mexican and Central American hylid frogs.
Univ. Kansas Publ., Mus. Nat. Hist., 17:263-279.

DUNN, E.R.

1924. Some Panamanian frogs. Occ. Papers Mus. Zool., Univ. Michigan,
151:1-17.

HOLDRIDGE, L. R.
1964. Life zone ecology. San Jose, Costa Rica.

STARRETT, P.
1960. Descriptions of tadpoles of Middle American frogs. Univ. Michigan,
Misc. Publ. Mus. Zool. 110:1-39.

1966. Rediscovery of Hyla pictipes Cope, with description of a new montane
stream Hyla from Costa Rica. Bull. So. Calif. Acad. Sci. 65:17-28.

TAYLOR, E. H.

1952. The frogs and toads of Costa Rica. Univ. Kansas Sci. Bull., 35:577-942.

1958. Additions to the known herpetological fauna of Costa Rica with comments
on other species. No. III. Univ. Kansas Sci. Bull., 39:3-40.

Accepted for publication August 1, 1967.

AGGRESSIVE BEHAVIOR IN THE
POLYCHAETOUS ANNELID FAMILY NEREIDAE

DONALD J. REISH AND M. CAROL ALOSI
Department of Biology, California State College, Long Beach

INTRODUCTION

Previous studies related to aggressive behavior in polychaetous anne-
lids have been limited to three species within the Family Nereidae.
Herpin (1923, 1926) and Reish (1957) reported fighting in Neanthes
caudata (delle Chiaje) [= N. arenaceodentata (Moore), see Pettibone,
1963]. Two members of the same sex would fight when placed together,
but not members of the opposite sex. This behavior was modified during
the period of time the male incubated the developing eggs within a
mucoid tube; he would fight either sex. Abeloos (1950) reported similar
fighting behavior in Platynereis dumerilii (Audouin and Milne Edwards)
[= P. massiliensis (Moguin-Tandon), see Hauenschild, 1951]. This
protandric hermaphroditic species defended its tube from intruders, but
the aggressive behavior disappeared in females with developing eggs;
she accepted a male. The male incubates the eggs and the female dies.
The aggressive behavior in Nereis pelagica Linnaeus was described by
Clark (1959). The actual method of fighting was similar to the other
species (see description below). In N. pelagica fighting took place when
one worm attempted to enter a tube already occupied by another. Occa-
sionally the intruder entered the tube and the two worms co-existed
without fighting. It is not known if the specimens were of the same or
different sex.

It is possible to include two additional activities of nereids as aggres-
sive behavior in the broad sense, but since the underlying causes are
known, these are not herein considered to be this type of aggression.
Cannibalism in laboratory cultures of developing worms, for example
in Nereis grubei (Kinberg) (Reish, 1954), frequently occurs when the
available food supply is low. In swarming and spawning Platynereis
megalops (Verrill), Just (1914) observed that the male wraps itself
around the female and inserts his posterior end into the mouth of the
female. Sperm are released into the coelom of the female through lesions
in the walls of her pharynx. The female then spawns the fertilized eggs
into the water.

Since aggressive behavior in the polychaetes has not been extensively
studied in the past, the purposes of this account are to determine how

21

2D) Bulletin So. Calif. Academy Sciences / Vol. 67, No. 1, 1968

widespread fighting is within the family, to determine if fighting occurs
between species, and to devise a quantitative measure of the intensity of
this behavior.

MATERIALS AND METHODS

Six species of nereids, belonging to three different genera were used
in this study. The majority of the specimens of Neanthes arenaceodentata
were taken from a stock of animals which were reared in the laboratory.
Some specimens were collected from floating docks in Los Angeles
Harbor. Neanthes succinea (Frey and Leuckart) were taken from interti-
dal mud flats in Alamitos Bay, Long Beach. Neanthes limnicola (John-
son) * were collected from the upper reaches of Morro Bay, California.
Nereis grubei, Nereis latescens Chamberlin, and Platynereis bicanali-
culata (Baird) were collected from floating docks in Playa del Rey
Marina, Los Angeles. The specimens were placed in individual petri
dishes and fed Enteromorpha sp. The animals were maintained under
these conditions for at least a week prior to use in experiments.

The procedure for studying aggressive behavior was to place two
nereids in a petri dish with sea water and guide them, if necessary,
around the periphery of the dish with a small brush until they met. The
guiding action did not make any noticeable difference in the results. It
simply speeded up the encounter. Ten specimens of a series were placed
with their own species and other species, insofar as specimens were
available. The behavior was judged on a numerical basis as defined
below. Generally, two minutes were sufficient time to obtain results.
Similar sized specimens were matched with one another.

Description of Aggressive Behavior. The aggressive behavior in-
vestigated involved any offensive or defensive action, using the pro-
boscis and jaws, which the animal exhibited upon meeting another
specimen. The proboscis is protrusible in Family Nereidae and ter-
minates in a pair of chitinous jaws (Fig. 4). The method of fighting was
the same in all species studied. The proboscis was thrust forward very
rapidly and the jaws grasped the opponent. If the grip was firm, a jerking
or twisting body motion followed which sometimes inflicted a wound.
In other cases, the action was slower with the jaws either just penetrating

*The name for this particular species has not been stabilized in polychaete sys-
tematic literature. Hartman (1959) regarded this species as synonymous with
Neanthes diversicolor and Smith (1959) regarded it as Nereis limnicola. We agree
with Hartman that this species belongs to the genus Neanthes because of the
absence of notopodial homogomph falcigerous setae, and we agree with Smith
that the specific name should be limnicola because of its distinctive means of
reproduction in comparison to the European population of N. diversicolor.

Aggressive Behavior in Annelid Family Nereidae 23

the cuticle or missing it entirely. This action continued as long as the
worms were near one another. Nereids are omnivorous feeders and
they use their jaws in grasping food. The action, however, is generally
slower and without jerking body movements (Reish, 1954).

Since a difference in the intensity of fighting was noted, a numeri-
cal score was devised to quantify these differences. The following
system was employed:

0 = No fighting response (Fig. 1).

1 = Avoids contact with the other specimen when the other speci-

men is nearby. Palpi may be flared (Fig. 2).
2 = Fighting position assumed with the palpi flared. Jaws partially
extended (Fig. 3).
3 = Aggressive, violent attacks upon the other specimen with jaws
extended and biting (Fig. 4).
the results of each series were totaled; the higher this value, the more
aggressive the species was considered. When different species were
placed together, the behavior was recorded for both species.

Figure 1. No aggressive behavior; score o.

Figure 2. Defensive or avoids contact with other specimen; palpi may be flared;
score |.

Figure 3. Fighting position assumed; palpi flared and jaws may be extended; score
Dr

Figure 4. Aggressive, with violent attacks upon other specimen; jaws extended
and biting; score 3.

24 Bulletin So. Calif. Academy Sciences / Vol.67, No. 1, 1968

RESULTS

The results of the experiments on intraspecific and interspecific aggres-
sion in these six species of nereids are summarized in Table |. The data
in Table 1 represent a total of 10 encounters of each combination. The
results of each encounter were scored on the basis of a numerical scale
of 0 to 3 as defined above. The figures represent the degree of aggressive-
ness of a species against each of the other five species. The intraspecific
aggression of a species is given above the diagonal line in the right hand
column of Table 1. The average interspecific aggression of the species
against the other five species is recorded below the diagonal line. The
average of all interspecific aggressiveness of five species against a partic-
ular species was determined; the average is recorded along the bottom
line of Table 1.

In four species, namely, Neanthes succinea, N. arenaceodentata,
Nereis latescens, and N. grubei, intraspecific aggression either exceeded
or nearly exceeded the maximum measured interspecific aggression.
The behavior of Platynereis bicanaliculata against itself was interme-
diate. Neanthes limnicola showed very little aggressiveness against
itself. By comparing the figures for intraspecific aggressiveness for a
species to the average interspecific aggressiveness, it will be noted that
in all cases but one, the individuals were more aggressive against mem-
bers of their own species than members of other species. The aggressive-
ness of Nereis grubei against itself was recorded as 27 and against N.
latescens was 28.

The figures below the diagonal line for the average of all interspecific
aggressiveness indicate the comparative degree of aggression of the six
species of nereids; proceeding from the most aggressive species to the
least they are: Nereis grubei (20.0), N. latescens (13.4), Neanthes suc-
cinea (12.2), N. arenaceodentata (11.6), Platynereis bicanaliculata
(7.0), and Neanthes limnicola (0.0).

The mechanism of species discrimination was studied in different
ways, but the results of these experiments left the problem unsolved.
All nereids possess four eyes in trapezoidal arrangement on the dorsal
surface of the prostomium (Figs. 1-4). Specimens of the same sex of
Neanthes arenaceodentata were placed together in petri dishes with
one group left in a lighted room and the other group in continuous
darkness for 24 hours. Over two-thirds of the worms showed injuries
as the results of fighting, but no significant difference was noted between
the light and dark groups. These results indicate that the eyes apparently
do not play a role in this discrimination.

The prostomium, which contains the brain and the eyes, was re-

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I q41dVL

26 Bulletin So. Calif. Academy Sciences / Vol. 67, No. 1, 1968

moved from 16 specimens of Neanthes arenaceodentata and 5 speci-
mens of N. succinea. Specimens of N. arenaceodentata lived three to
four weeks, without feeding, before dying. Removal of the prostom-
ium of epitokal nereids, such as N. succinea, initiated sexual meta-
morphosis by eliminating the inhibiting hormone secreted in the
prostomium (Clark, 1961). It was possible to test the aggressive re-
sponse in this species before completion of epitoky. All specimens of
both species without prostomia continued to fight either with normal
specimens or others lacking a prostomium.

A third series of experiments were undertaken to determine whether
or not recognition in N. arenaceodentata occurs by way of a chemical
medium. Specimens were placed in petri dishes in which worms of the
same sex or opposite sex had lived. No behavioral changes were noted.
Fluid from either ground up males or females was dropped in the
vicinity of either sex. No behavioral change was noted. Many specimens
of male and female N. arenaceodentata were ground up separately, —
and the fluid placed in a two per cent agar solution. The hardened agar
was cut into the shape of worms and placed in the dishes of normal
males or females. No behavioral changes were noted under the various
combinations possible.

The polychaetes Dorvillea articulata (Hartman) and Gycera ameri-
cana (Leidy) were placed separately with all species but Neanthes
limnicola. The nereids did not respond to these two species, both of
which possess jaws and belong to different families.

DISCUSSION

The results presented herein indicate that aggressive behavior in the
polychaete family Nereidae may be widespread. Of six species studied,
aggressive behavior had been known previously in Neanthes arenaceo-
dentata. Aggression had been previously reported in Platynereis dumeri-
lii and Nereis pelagica making a total of seven species known to show
some degree of aggressiveness. Neanthes limnicola is excluded from
this group because worms of this species did not fight with those of the
other species and it was questionable whether or not there were intra-
specific encounters.

Some correlations between some features of the species and their
aggressive behavior were noted. The two members of the genus Nereis
construct mucoid tubes, have equal sex ratio, and are epitokal at sexual
maturity. All three species of Neanthes typically burrow into sediments
in quieter waters. They differ markedly, however, in their reproductive
habits. Worms belonging to Neanthes succinea undergo epitoky and

Aggressive Behavior in Annelid Family Nereidae 27

swarm at sexual maturity. The female of N. arenaceodentata lays her
eggs in the tube of the male, then dies. The male incubates the eggs for
three weeks, after which the young leave. The male is capable of repro-
ducing again. Neanthes limnicola is a self-fertilizing hermaphrodite.
The ecology and reproductive behavior of Platynereis bicanaliculata
is similar to the species of Nereis (Reish, 1957).

The aggressive behavior and its intensity seems to be correlated with
the method of reproduction in the family Nereidae. The condition of
epitoky in nereids was considered to be the most primitive condition
within the family (Clark, 1961). As stated above, four of the six species
studied undergo epitoky; of these, three are the most aggressive species
studied. Modifications in this pattern of behavior with regards to sex
has occurred in the two non-epitokal species Neanthes arenaceodentata
(Herpin, 1923, 1926; Reish, 1957) and Platynereis massiliensis (Abe-
loos, 1950). The opposite sexes do not exhibit aggression in these two
species in which the male incubates the eggs in his tube. The fighting
behavior is either lost or nearly so in the self-fertilizing hermaphroditic
species. Neanthes limnicola.

SUMMARY

1. Intraspecific and interspecific aggressive behavior in six species of
nereid polychaetous annelids was studied under laboratory condi-
tions. A numerical measure was devised to indicate intensity of
fighting.

2. Aggressive behavior was more intense against members of the same
species than against other species. Nereis grubei, N. latescens,
Neanthes succinea, and N. arenaceodentata were very aggressive;
the behavior of Platynereis bicanaliculata was intermediate; Neanthes
limnicola, a self-fertilizing hermaphrodite, showed little or no fight-
ing. Interspecific aggression from the most to the least occurred in
the same species order as listed above.

3. Aggressive behavior did not occur against species belonging to other
polychaete families tested.

4. Various attempts to alter the behavior pattern were unsuccessful.

LITERATURE CITED

ABELLOS, M.
1950. Changement de sexe et comportement sexuel de Platynereis dumerilii
(Aud. et M.-Edw.) (forme atoque). Acad. Sci. Paris C. R. 231:179-180.

28 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

CLARK, R. B.
1959. The tubicolous habit and the fighting reactions of the polychaete Nereis
pelagica. Anim. Behav. 7:85-90.

CLARK, R. B.
1961. The origin and formation of the heteronereis. Biol. Rev. 36:199-236.

HARTMAN, O.
1959. Catalogue of the polychaetous annelids of the world. Allan Hancock Found.
Publ. Occas. Pap. No. 23:1-628.

HAUENSCHILD, C.

1951. Nachweis der sogenannten atoken Geschlechtsform des Polychaeten Pla-
tynereis dumerilii Aud. et M.-Edw. als eigene Art auf Ground von Zucht-
versuchen. Zool. Jahrbucher Jena. 63:107-128.

HERPIN, R.
1923. Ethologie et developpement de Nereis (Neanthes) caudata delle Chiaje.
Acad. Sci. Paris, C. R. 177:542-544.

HERPIN, R.
1926. Recherches biologiques sur la reproduction et le developpement de quel-

ques annelides polychetes. Soc. Sci. Nat. l'ouest France, Nantes, Bull. ser.
4,5:1-250.

JUST. E. E.
1914. Breeding Habits of the heteronereis form of Platynereis megalops at Woods
Hole, Mass. Biol. Bull. Woods Hole. 27:201-212.

PETTIBONE, M. H.
1963. Marine polychaete worms of the New England Region. 1. Aphroditidae
through Trochochaetidae. Bull. U. S. Nat. Mus. No. 227:1-356.

REISH, D. J.
1954. The life history and ecology of the polychaetous annelid Nereis grubei
(Kinberg). Allan Hancock Found. Publ. Occas. Pap. No. 14:1-74.

REISH, D. J.

1957. The life history of the polychaetous annelid Neanthes caudata (delle
Chiaje), including a summary of development in the Family Nereidae.
Pacific Sci. 11:216-228.

SMITH, R. I.
1959. The synonymy of the vivparous polychaete Neanthes lighti Hartman
(1938) with Nereis limnicola Johnson (1903). Pacific Sci. 13:349-350.

Accepted for publication June 15, 1967.

BILLFISH REMAINS FROM
SOUTHERN CALIFORNIA WITH REMARKS
ON THE IMPORTANCE OF
THE PREDENTARY BONE

HARRY L. FIERSTINE

California State Polytechnic College
San Luis Obispo and Research Associate
Los Angeles County Museum of Natural History

and

SHELTON P. APPLEGATE

Division of Vertebrate Paleontology
Los Angeles County Museum of Natural History

INTRODUCTION

Fossil fishes of the family Istiophoridae (Marlins, Sailfishes, and Spear-
fishes, have never been reported from the western United States and
nave rarely been recorded from North America (Berry, 1917; Eastman,
1917; Leidy, 1885; Leriche, 1942; Woodward, 1901). Billfish remains
should be expected in southern California, since the extensive marine
Tertiary deposits commonly yield fishes (carangids (David, 1943) and
scombrids (Fierstine, in manuscript) that probably inhabited the same
environment as the billfishes themselves.

Recently one of us (S.A.) collected or obtained billfish specimens
from various fossil localities in southern California. One of the fossils,
the predentary bone, was found to be such a peculiar osteological fea-
ture that a discussion of its taxonomic and biological implications was
warranted.

MATERIALS AND METHODS

The fossil specimens are housed in the Division of Vertebrate Paleon-
tology, Los Angeles County Museum of Natural History (LACM). All
but one specimen is figured and the data for each specimen is given in
the figure legend or in text. Table | lists the recent material examined in
this study and the pertinent information for each specimen. The follow-
ing scientific names are used in this paper:

Swordfish Xiphias gladius Linnaeus
Shortbill spearfish Tetrapturus angustirostris Tanaka
Longbill spearfish Tetrapturus pfluegeri Robins and deSylva

Mediterranean spearfish Tetrapturus belone Rafinesque

29

30 Bulletin So. Calif. Academy Sciences / Vol. 67, No. 1, 1968

Striped marlin Tetrapturus audax Phillipi
White marlin Tetrapturus albidus Poey
White marlin Makaira indica (Cuvier)
Black marlin Makaira nigricans Lacepede
Blue marlin Istiophorus gladius (Bloch)

Pacific sailfish

The authority for these names are Howard and Ueyanagi (1965),
Merrett and Thorp (1965), and Robins and deSylva (1960, 1963).

LOCALITIES:

Sharktooth Hill, Kern County, California, LACM loc. 1625,SW'% of the SW,
Sect. 25, T 28S, R 28E, Oil Center Quandrangle, U. S. G. S. 1954; near LACM
loc. 1623, Middle Miocene.

El Toro, Orange Co., California, LACM loc. 1945, 1% miles SW of the town of
El Toro, Sect. 34, T 6S, R 8 W, San Juan Capistrano Quadrangle, U. S. G. S., ©
1942; Upper Miocene.

Earl Calhoun Hill no. 2, Orange County, California, LACM loc. 65119. Sect. 34,
T 6S, R 8W, San Juan Capistrano Quadrangle, U.S. G. S., 1942; further east than
loc. 1945, Upper Miocene.

Newport Beach, Orange County, California, LACM loc. 6732, sand quarry near
Palisades Road, Back Bay; Tustin Quadrangle, U. S. G. S. 1950, Late Pleistocene.

SYSTEMATIC DESCRIPTIONS

Order Perciformes
Suborder Xiphioidei
Family Istiophoridae
Istiophorid g. indet.

Figure 1A

Description: A nearly complete 67.5 mm long second abdominal verte-
bra (LACM 17695) was collected by Mr. Richard Bishop at LACM
loc. 1625, Middle Miocene, Sharktooth Hill, Kern County California.
The anterior end of the centrum measures 44.5 mm high and 40 mm
wide; the posterior end of the centrum measures 44.1 mm high and 41
mm wide. The minimum width of the centrum is 21.5 mm.

A nearly complete anterior caudal vertebra (LACM 17049) which
measures 227 mm long between the anterior edge of the zygapophysis
and the posterior edge of the neural spine was collected by Mr. and Mrs.
Lawrence McCain at LACM loc. 6732, Late Pleistocene, Newport

31

Billfish Remains from California

A1O\SIP{ [eANIeN JO winasnyy AyUNOD sajesuy soT = WOVWT

juoujsedsqd Asojorg ‘odsiqQO sin] ueg ‘ada[[OD s1uYde}A[O 93816 VIUIOJI[ED = OTS
UOI}D9[[OD [VdIZo[OAY YI] ‘AydeisouvsdG9 jo 3ynjNsu] sddiisg = OIS

juowjiedsg Asojorg ‘eluIOsI[eD ‘YJeMION ‘ddd][OD sowed = OO

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20UdIDS JO AWIOpedY PIUIOP [VD = SVOx

WOVI uIys poJUNOW UvIDO INULIIV~ di, SUDI1IBIU DAIDYDIN
IssS VION ‘JOAS [exe é 6 DIIPUl DAIDYDIN
L6vl (ON UOIssaD9V WOVT UIys poJUNOUI eBlulos es ‘eleg (DI1pUl DAIDYDI =) adA\O[OH
‘seon] ues odey I6L‘€ I[}H pue ueplog Dulpjivi vsIDyDW
‘yiegc ‘eleg (snipv]s "| =) adAJO[OH UUeUIDAq
L6vI (ON UOIssad9V WOV I uIys poJUNOW ‘seon] ues adey 8087 pue uepiog 1da48 snsoydoijsy
6r7SS VION ‘JOAS [BIxXe OST? snipojs snsoydols]
yyeg (xppnv ‘J, =) adAjOJOH uueWI3aAq
019 ON SVO ulys poyuNoUl “py euryeyed jyo INGE pue ueplof 1aj0y DAIDYDW
Ins [ap
BluIOpyeD eleg
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SJTRO
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SHPO
WOVI ‘JOYS [epnes ‘osaIq ues jjo é xDpnv sninjdv4ja J,
[JOD soyssagd peoy “JIeS UsloyNOS é XDpND snAnjavdAja I
SVO 9}0|dwWo95 ‘yyec eleg jjo €C6l xDpnv sninjdvd.ja J
I87@S VION “JOYS [exe 006! 389 xppnv sninjdvd.Aja J
‘JIe_ ‘Ad19}U0
VEv-L87-6S OIS “JOeySs peoy “dA TW OOT S1AJSOAIJSNBUD SNANJADAJA
WOVI Mel IOMO] é é snippjs sviydiy
WOV TI Toys Tepnes 6 (6 snipojs spy dix
VION ‘JOAS [exe é é snipp]s spy d1x
xUOlNINSUT 10 / pun 214010 AJ1]DIOT (uu) YJsua] IUD IYf1JUI1I¢F

MOQUNN] UO1JIAI]OD

SNAWIOddS LNAOFY AOA NOILVNUOANT IWYANIH

] a1av

pavpuvis

B2 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

Beach, Orange County, California. This was donated to the Los Ange-
les County Museum of Natural History. The centrum is 115 mm long
and its minimum width is 36.5 mm; the dorsal extension of the neural
spine is missing.

Discussion: The general shape of both vertebrae was similar to all the
istiophorids studied except that the centrum of the abdominal vertebra
was more constricted. Width to length ratios of the centrum (Table 2)
only eliminated M. indica as a possible candidate. The large size of the
caudal vertebra probably eliminates T. audax as a contender, however
the lack of comparative material over various size ranges inhibits a
precise identification.

TABLE 2

CENTRUM MEASUREMENTS
OF THE 2ND ABDOMINAL VERTEBRA

Centrum Measurements (mm)

Species Narrowest Maximum Width to

width length length ratio
FOSSIL DES 67.5 31
(LACM 17695)
Pacific Sailfish IDES 54.0 23
(UCLA S549)
Striped marlin 11.5 42.5 Di
(UCLA $8281)
Black marlin 37.0 59.5 .60
(UCLA S551)

Makaira sp.

Figures 1A, 2A

Description: A 281 mm long bill fragment (LACM 17693) was found
at LACM loc. 1945 and a complete 72.5 mm long predentary bone
(LACM 16074) was collected at LACM loc. 65119. Both localities are
Upper Miocene and the measurements for the two elements are given
in Table 3.

The bill has two small nutrient canals exposed at the broken surface
of the proximal (basal) end. The canals are small (4.6 mm by 2.5), close-
ly set together (4 mm apart), and are acentrically located toward the
ventral surface. Although there are only a few denticles preserved, it
appears that only the ventral one-half bears denticles and that the dorsal

Billfish Remains from California 33

Figure 1. A. Istiophorid g. indet., second abdominal vertebra, LACM 723%. left

lateral view. B. Makaira sp., bill fragment, LACM ee. left lateral view.

A line two cm long is indicated for each specimen.

one-half is smooth. The proximal surface of the predentary bone is
rugose and indicates a complicated articulation with the two dentary
bones. The denticles are evenly distributed on the entire dorsal surface
and extend to its widest point.

Discussion: The identification is based on size (Table 3) which compares
poorly with the more slender-billed Pacific sailfish, shortbill spearfish,
and striped marlin. The size of the fossil bill was minimal because of its
lack of denticles and its worn condition. Since we assumed these species
to be representative of the genera, Tetrapturus and Istiophorus, they
were eliminated and only Makaira was left as a possible candidate. The
elimination of /stiophorus on the basis of size is strengthened by the
fact that the Holotype of /. greyi was once a record-size fish (Jordan and
Evermann, 1926).

The bill is nearly identical in size and shape to one (Table 3) described
as Istiophorus calvertensis Berry 1917 from the Calvert formation, Tar

34 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

Figure 2. A. Makaira sp., predentary bone, LACM ou dorsal view. B. Tetrap-

turus audax, dorsal view of lower jaw. The predentary bone became separated
from the rest of the jaw during preparation and has been restored to its normal
anatomical position. The denticular pattern would not normally be interrupted
and its articulation with the dentary bones would not be obvious in this view.

A line two cm long is indicated for each specimen.

Bay, James River, Prince George County, Virginia, ?Miocene. It differs
from /. calvertensis on the peripheral location and size of the nutrient
canals. The denticles are missing on the Virginia specimen, however it
probably also belongs to Makaira. In the recent specimens examined,
the dorsal surface of the bill was smooth except in the Holotype of /.
greyi where the distal one-half of the dorsal surface has small denticles.
Predentary bone discussion: The denticles of the fossil are evenly distrib-
uted on the dorsal surface, a feature that it shares with /. greyi (Holo-
type) and 7. audax. It differs in this feature from M. marlina (Holotype)
and M. nigricans) where the denticles do not extend across the entire
dorsal surface at the basal (proximal) end.

A predentary bone is a rare element in the Teleostei. So far as known,

Billfish Remains from California 35

TABLE 3

Comparison of Bill and Predentary Proportions

Bill (mm) Predentary (mm)
(height / width) (height / width)

Specimen Base Mid pt. One cm from tip Base
Fossil 28 DA) 11.0 --

(LACM 17693) 37 32.5 8.5
Fossil - = - Des)

(LACM 16074) 43.9
Istiophorus 26 Do) I8.5+ --

calvertensis 36 33.0 28.0
Makaira marlina 49 35 11.0 34.0

Type 70 46 10.5 38.5
Makaira nigricans BS 19 7 23

36 27 8 44

Istiophorus greyi 28 17 6.5 16

Type 34 22 9.0 19
Tetrapturus audax 22.0 15.0 J) HS

(LACM) BYES 22.5 VD Dy

+ Measurement taken approximately 7.8 cm from tip.

it occurs only in the clupeiform extinct suborder Saurodontoidei (Berg,
1940) and in the perciform suborder Xiphioidei. It is edentulous in the
saurodontoids and it extends the lower jaw well beyond the upper. The
predentary in the xiphioids is restricted to the family Istiophoridae
where it bears numerous denticles and the upper jaw or bill extends far
anterior to the predentary bone.

The presence of the predentary bone in the saurodontoids is a widely
known fact among paleoichthyologists (Bardack, 1965), however the
presence of the bone in the Istiophoridae is not universally known. It is
briefly mentioned by Regan (1909), Gregory and Conrad (1937 a), Con-
rad (1938), and Nakamura (1938), but no mention is made of this ele-
ment in later anatomical or systematic accounts.

The predentary bone is absent in X. gladius and all members of the
family Scombridae. This element is neither discussed nor figured in the
Gempylidae (Matsubara and Iwai, 1958) nor in the Trichiuridae (Tuck-
er, 1956). The structure (Fig. 2B) is well-developed in 7. audax, M.

36 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

indica, M. nigricans, and I. gladius (observation based on the Holotype
I. greyi). In a single specimen of T. angustirostris the predentary is
represented by a very small denticle-bearing bone at the mandibular
symphysis.

The absence of a predentary bone X. gladius adds another difference
(bill and body shape, fin structure, myology, squamation, vertebral
number, and vertebral shape) to the xiphiid and istiophorid lineages.
The observation that T. audax has a well-developed element and that
T. angustirostris has a tiny one might have important taxonomic impli-
cations. However, until the presence or absence of a predentary bone is
determined for T. pfluegeri, T. belone, and T. albidus, the exact taxono-
mic importance of this element will remain unknown.

The function of the bone has not passed the point of speculation. Bar-
dack (oral presentation before the Society of Vertebrate Paleontology,
November 15, 1966) thought that the edentulous predentary of the
saurodontids may have created a water flow pattern that directly aided ~
the fish to gather food. This function seems unlikely for the predentary
of istiophorids. Their bone helps form the contour of the head, but the
dentary bones themselves should be able to provide this function with-
out invoking a separate bony element.

The long-billed forms have a thin mandibular symphysis in order to
conform to a laminar head shape. Since movement of the lower jaws at
the symphysis is important for expanding the orobranchial cavity
(Schaeffer and Rosen, 1961), then a thin symphysis would make a weak
joint. This joint could be strengthened if it were moved to a thicker part
of the jaw through the development of a predentary bone. The reduction
of the predentary in 7. angustirostris may be a functional response to
the shorter bill and mandibles. The carnivorous characins apparently
strengthen their mandibular joint by developing an interlocking arrange-
ment (Gregory and Conrad, 1937b). There is no symphyseal joint in the
swordfish hence it probably differs from the istiophorids in its method
of expanding its orobranchial cavity. However, the dried lower jaws
seem to be thin and flexible and this flexibility may allow adduction of
the mandibles.

The origin of the predentary bone is unknown. It is unlikely that the
bones of saurodontids and istiophorids are homologous structures.
According to Greenwood, et al. (1966) the Istiophoridae, a member of
the Acanthopterygii, was derived from a Protocanthopterygian. This
latter group seems to have no elements in the lower jaw anterior to the
dentary bone (see Berg, 1940), therefore the istiophorid element is a
neomorph. The saurodontids presumably belong to Greenwood et al’s
Osteoglossomorpha, a separate lineage from the Protocanthopterygii-

Billfish Remains from California 37

Acanthopterygii lineage. These two lines have their common ancestry
in the pholidophoroid holosteans which also seem to lack elements in
the lower jaw anterior to the dentary bone (see Berg, 1940). Thus, the
saurodontoid predentary is also a neomorph and is not homologous with
the istiophorid predentary bone.

SUMMARY

The Istiophoridae was represented in southern California during the
Miocene and Pleistocene periods. Because of a paucity of fossil material
and lack of comparative recent skeletons, exact identifications were
impossible. A second abdominal vertebra and an anterior caudal verte-
bra were identified as istiophorid g. indet., and a bill and predentary
bone were identified as Makaira sp. All fossil elements seemed to be
quite similar to the same elements in living billfish.

The predentary bone of the Istiophoridae is a neomorph since it is
not found in any ancestral or closely related teleost fish. Its large size in
Istiophorus gladius, Makaira nigricans, M. indica, and Tetrapturus
audax and its small size in T. angustirostris may have important system-
atic implications. It is absent in Xiphias gladius. It is suggested that
because of the istiophorid head shape, the symphysis of the lower jaw is
thin. Thus, the symphyseal joint would be weak during expansion and
contraction of the orobranchial cavity except that the predentary bone
functions to move the joint posteriorly to a thicker part of the jaw in
order to strengthen the interdentary joint.

ACKNOWLEDGEMENTS

We wish to thank Dr. Boyd Walker (University of California, Los Angeles), Dr.
Richard Rosenblatt (Scripps Institute of Oceanography), Mr. Jules Crane (Cerri-
tos College and Mr. William Follett (California Academy of Science) for the use
of specimens examined in the course of this study. Particular thanks goes to Dr.
Vladimir Walters (University of California, Los Angeles) for his stimulating
criticism of the function of the predentary bone. Dr. David H. Dunkle (U.S.
National Museum) read the manuscript and offered comments.

Special thanks is due to the administration and faculty of the California State
Polytechnic College, San Luis Obispo for awarding one of us (HLF) a special
research leave for the spring quarter, 1967 to participate in this research.

LITERATURE CITED

BARDACK, D.
1965. Anatomy and evolution of chirocentrid fishes. Univ. Kansas Paleo. Contrib.,
Vertebrata, Art. 10, 86 p.

38 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

BERG, L. S.
1940. Classification of fishes both recent and fossil. Ann Arbor, Michigan: Edward
Bros., 517 p.

BERRY, E. W.
1917. A sailfish from the Virginia Miocene. Amer. J. Sci., 43:461-464.

CONRAD, G. M.
1938. The osteology and relationships of the wahoo (Acanthocybium solandri), a
scombroid fish. Amer. Mus. Novitates (1000):1-32.

DAVID, L. R.
1943. Miocene fishes of southern California. Geol. Soc. Amer., Special Pap. no.
43, 193 p.

EASTMAN, C. R.
1917. Fossil fishes in the collection of the United States National Museum. Proc.
U.S. Nat. Mus., 52:234-304.

GREENWOOD, P. H., D. E. ROSEN, S. H. WEITZMAN and G. S. MYERS
1966. Phyletic Studies of Teleostean fishes, with a provisional classification of
living forms. Bull. Amer. Mus. Nat. Hist., 131:339-456.

GREGORY, W. K. and G. CONRAD

1937a. The comparative osteology of the swordfish (Xiphias) and the Sailfish
(Istiophorus). Amer. Mus. Novitates, (952):1-25.

1937b. The structure and development of the complex symphyseal hinge-joint in
the mandible of Hydrocyon lineatus Bleeker, a characin fish. Pro. Zool.
Soc. London, p. 4, 975-984.

HOWARD, J. K. and S. UVEYANAGI
1965. Distribution and relative abundance of Billfishes (Istiophoridae) of the
Pacific Ocean. Studies in Trop. Oceanogr. Miami vol. 2, 134 p.

JORDAN, D. S. and B. W. EVERMANN
1926. A review of the giant mackerel-like fishes, tunnies, spearfishes and sword-
fishes. Calif. Acad. Sci., Occ. Pap., 12:1-113.

LEIDY, J. 2
1855. Indications of twelve species of fossil fishes. Proc. Acad. Nat. Sci. Phil.
7:395-397.

LERICHE, M.

1942. Contribution a l’etude des faunes ichthyologique marines des terrains
Tertiaires de la plaine cotiere, Atlantique et du centre des Etats-Unis. Le
synchronisme des formations tertiaires des deux cotes del’Atlantique. Mem.
Soc. Geol. France, n.s. 20:5-110.

MATSUBARA, K. and T. IWAI
1958. Anatomy and relationships of the Japanese fishes of the family Gempylidae.

College of Agriculture, Kyoto University, Mem. Fish Series, Special No.,
June: 23-54.

MERRETT, N. R. and C. H. THORP
1965. A revised key to the scombroid fishes of East Africa with new observations
on their biology. Ann. Mag. Nat. Hist., 8:367-384.

Billfish Remains from California 39

NAKAMURA, H.

1938. Report of an investigation of the spearfishes of Formosan waters. Reports of
the Taiwan Government — General Fishery Experiment Station. U.S. Fish
and Wildlife Serv. Spec. Sci. Rept. (153):1-46.

REGAN. C. T.
1909. On the anatomy and classification of the scombroid fishes. Ann. Mag. Nat.
Hist. 8:66-75.

ROBINS, C. R. and D. P. deSYLVA

1960. Description and relationships of the longbill spearfish, Tetrapturus belone,
based on western north Atlantic specimens. Bull. Mar. Sci. Gulf and Carib-
bean, 10:383-413.

1963. A new Western Atlantic spearfish, Tetrapturus pfluegeri, with a redescrip-
tion of the Mediterranean spearfish Tetrapturus belone, Bull. Mar. Sci.
Gulf and Caribbean, 13:84-122.

SCHAEFFER, B. and D. E. ROSEN
1961. Major adaptive levels in the evolution of the actinopterygian feeding mech-
anism. Am. Zoologist, 1:187-204.

TUCKER, D. W.
1956. Studies on the trichiuroid fishes-3. A preliminary revision of the family
Trichiuridae. Bull. British Mus. Nat. Hist., Zool., 4:73-130.

WOODWARD, A. S.
1901. Catalogue of the fossil fishes in the British Museum (Natural History). Vol.
4, London. 636 p.

Accepted for publication December 18, 1967.

PSEUDOCRYPTOCHIRUS CRESCENTUS (EDMONDSON),
A SECOND CRAB OF THE CORALLICOLOUS FAMILY
HAPALOCARCINIDAE (CRUSTACEA, DECAPODA)
FROM THE EASTERN PACIFIC
WITH REMARKS ON PHRAGMOSIS, HOST SPECIFICITY,
AND DISTRIBUTION

JOHN S. GARTH f
ALLAN HANCOCK FOUNDATION
UNIVERSITY OF SOUTHERN CALIFORNIA
Los ANGELES
AND
THOMAS S. HOPKINS*
SCRIPPS INSTITUTION OF OCEANOGRAPHY
UNIVERSITY OF CALIFORNIA
SAN DIEGO

INTRODUCTION

The coral-inhabiting family HAPALOCARCINIDAE is best known
from the coral gall crab, Hapalocarcinus marsupialis Stimpson. Clas-
sical studies on its biology and morphology are those of Semper (1881)
and of Potts (1915), whose work was done at Murray Island on the Great
Barrier Reef of Australia. Knowledge of its occurrence in the eastern
Pacific is comparatively recent, and is the result of the work of Hancock
Expeditions off Central and northern South America. The first report
was that of Schmitt (1936) from Port Utria, Colombia, the second that
of Rathbun (1937) from Secas Islands, Panama, both collections from
Pocillopora coral. The species was significantly absent from the Gala-
pagos Islands, where numerous coral collections were made by Velero
III scientists, but it has been reported more recently from Clipperton
Island, also from Pocillopora coral (Garth, 1965).

The Clipperton Island collections, obtained by the late Conrad Lim-
baugh of the Scripps Institution of Oceanography on the I. G. Y. Expe-
dition of 1958, also included a second and less conspicuous member of
the family HAPALOCARCINIDAE which does not form galls in
branching corals, but rather burrows into corals of a massive type. This
was recognized as related to Troglocarcinus Verrill because of its resem-
blance to T. corallicola Verrill, an inhabitant of the western Atlantic
better known to American workers as Cryptochirus corallicola (Ed-

+ Contribution No. 312, Allan Hancock Foundation
*Present address: University of West Florida, Pensacola, Florida

40

Coral-Inhabiting Crabs 41

mondson, 1933). Since the genus was unknown from the eastern Pacific,
the specimen was sent to Dr. Raoul Serene, joint author of a monograph
on the Hapalocarcinidae of Viet Nam (Fize and Serene, 1957). Serene’s
identification, while allowing for minor discrepancies, left no doubt that
the Clipperton Island specimen was conspecific with Troglocarcinus
crescentus (Edmondson), more recently known as Pseudocryptochirus
crescentus (Serene, 1966), originally described from Johnston Island,
but subsequently reported from several other central and western Pacific
localities.

This Clipperton Island occurrence, while establishing Pseudocryp-
tochirus crescentus in the eastern Pacific at Lat. 10° 18’ N. and Long.
109° 13’ W. as reported by Garth (1965), left it still 600 nautical miles
short of the American mainland. It remained for Mr. George F. Crozier
of Scripps Institution of Oceanography, while diving in the Gulf of Cali-
fornia off El Tule Ranch, 10 miles east of Cape San Lucas, Baja Cali-
fornia, to recover the coral specimen that has yielded the first Pseudo-
cryptochirus from the North American continent. The crabs were rec-
ognized (as Cryptochirus) by the junior author, who sent them to the
senior author for study, together with the coral from which they were
collected. The small series consists of one male and four female crabs,
three of which are ovigerous. The male measures 3.6 X 2.65 mm, the
non-ovigerous female 3.0 X 2.3 mm, and the only entire ovigerous
female 4.6 X 3.7 mm in length and width of carapace. There is still an-
other crab that can be seen at the bottom of its burrow that cannot be
removed without damaging it extensively. Comparison of the five crabs
with the specimen of P. crescentus from Clipperton Island leaves little
doubt that they are the same species, again allowing for minor differ-
ences believed attributable to age and/or sex.

Strengthening the identity of both the Clipperton Island and the Gulf
of California specimens of Pseudocryptochirus crescentus are the iden-
tities of their coral hosts. While the single specimen included among the
decapod collections of Conrad Limbaugh bore no evidence of its coral
host, two additional crabs were discovered by Dr. Edwin C. Allison
clinging to Clipperton Island corals sent to him for study. These he
identified as Pavona clivosa Verrill and P. varians Verrill. The coral
host of P. crescentus on Johnston, Christmas, and Oahu islands is Pavona
duerdeni Vaughan, according to Edmondson (1925, 1933). Indeed, all
records given by Fize and Serene (1957) for this crab are from corals of
the genus Pavona. The coral head from which the Gulf of California
crabs were collected is a magnificent specimen of Pavona gigantea Ver-
rill (Fig. 1), as identified by Dr. Allison, Department of Geology, Cali-
fornia State College, San Diego, and Museum of Paleontology, Uni-

42 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

Figure 1 Entire specimen of the massive coral, Pavona gigantea Verrill, showing
two of the crescent-shaped burrows from which Pseudocryptochirus crabs were
extracted. The larger of these, presumably occupied by a female crab, is the one
sketched in Figure 2 with crab in situ.

versity of California, Berkeley. Standing 15 cm high and measuring
14.5 cm in greatest diameter and 45.5 cm in circumference, it retains
within its base a portion of the granite rock to which it was united before
it was detached from the substrate. Widely spaced around its periphery,
and in such a manner that only two, or at the most three, are visible in
any one camera angle, are crescent-shaped burrows of the following
dimensions in mm:

Height Width Depth (Occupant)
4.5 7.9 30.1 (ov 2 )
3.3 7.0 16.8 (ov? )
3.1 7.0 ---- (in situ)
3.0 6.8 12.5 (ov 9)
1.9 all 8.5 (¢)

1.7 5.0 6.0 (non-ov @ )

Coral-Inhabiting Crabs 43

Figure 2 The burrowing coral crab, Pseudocryptochirus crescentus (Edmondson),
in the characteristic position occupied at the entrance to its burrow, which it
effectively closes. Jens W. Knudsen, del.

Since the crabs, with one exception, had been removed from their
burrows before being seen by the senior author, it cannot be stated with
certainty that a particular crab occupied a particular burrow. However,
it will be noted that the number of burrows corresponds exactly with the
number of crabs recovered or remaining in situ, that the number of large
burrows (over 3.0 mm in height) corresponds to the number of oviger-
ous females, and that the number of small burrows (under 3.0 mm in
height) corresponds to the single male and non-ovigerous female. It is
also probable that the specimen remaining in situ is another ovigerous
female, since the burrow that it occupies is of a height and width (its
depth cannot be measured) comparable to the other large burrows. The
greater proportional width of the burrow thought to have been occupied
by the male would be an accommodation for the larger chelipeds in that
Sex.

A second point of confirmation of the identity of the Gulf of Califor-
nia crabs is found in the shape of the burrow. As the name would imply,

44 Bulletin So Calif. Academy Sciences/ Vol. 67, No. 1, 1968

that of Pseudocryptochirus crescentus is crescentic, with the convexity
of the burrow dorsal to the crab’s position, the concavity ventral to it.
But beyond the crescentic shape, which is shared to a degree by P. viridis
(Hiro) of the western Pacific, there is a secondary excrescence above
the carapace and the corners of the primary crescent turn downward to
accommodate the crab’s legs, giving a very characteristic shape to the
opening. The anterior portion of the crab’s carapace, including the
greatly enlarged basal antennular segment, makes an abrupt angle with
the carapace, and together with the similarly enlarged merus of the first
walking leg, forms an effective operculum or closure (Fig. 2).

The process of modifying a part of the body to stop a hole for pro-
tection from predators, termed phragmosis by William Morton Wheeler,
is found not only in insects, but among amphibians, reptiles, and in one
genus of armadillo (Barbour, 1945). Phragmosis is common among
anomurans, to which the hermit crabs belong, but is rare among brach-
yurans, or true crabs. Indeed, the formation of a nidus or nest of such a
distinctive form or shape as to constitute a specific character, albeit an
extra-corporeal one, while commonplace among birds, wasps, or trap-
door spiders, is uncommon enough among brachyurans to merit special
comment. According to Utinomi(1944:713), and with respect to Pseudo-
cryptochirus viridis, which forms similar crescent-shaped holes on
the coral Turbinaria contorta:

“Tt is clear that the crab settles down in the furrow between the calicles projected
beyond the surface of the coral colony when it is immature, and then the hole it
lives in becomes [sic] to form a crescent shape in accordance with its own charac-
teristic shape. The pit is not deep, usually less than 5 mm... In the species cres-
centus, however, the dwelling is apt to grow deeper as the upward growth of the
host coral Pavona duerdeni proceeds, although it lies obliquely to the surface of the
coral.”

Specimens of Pseudocryptochirus viridis from Eniwetok in the Mar-
shall Islands and of the Turbinaria coral from which they were collected
were available for comparison during this study.

Host specificity as between corals and their decapod commensals is a
matter requiring further investigation. Among the Hapalocarcinidae,
where coral and commensal have a demonstrable physical relationship,
the crab existing either as a lifelong prisoner within the gall that the
coral forms around it, or as the occupant of a burrow that the coral
shapes to its body, while allowing the crab full ingress and egress, the
problem is relatively simple, as crab and coral are usually collected and
preserved together. Among the facultative symbionts of corals, such as
the subfamily Trapeziinae of the family XANTHIDAE and the sub-
family Pontoniinae of the family PALAEMONIDAE, where the crab

Coral-Inhabiting Crabs 45

or shrimp leaves no visible mark on the coral, evaluation of the situation
is more difficult. The decapod crustaceans are most frequently separated
from their coral hosts before the carcinologist receives them, or, equally
deplorable from the ecologist’s standpoint, are mingled with decapods
from other corals. By employing methods especially developed to elimi-
nate such cross-contamination, both Garth (1964) and Patton (1966)
have been able to demonstrate selection preference on the part of both
crabs and shrimps for host corals of a particular family. This is borne
out in the relationship of Hapalocarcinus marsupialis with the family
Seriatoporidae, including both Seriatopora and Pocillopora, on which
the coral gall crab is found. While the relationship of Pseudocrypto-
chirus viridis, found only on Turbinaria, and of P. crescentus, found
only on Pavona to date, would appear to be a generic one, yet because
each coral genus belongs to a different family, Turbinaria to the Den-
drophyllidae, Pavona to the Agariciidae, it is perhaps too early so to
state. However, it is already apparent that the Pseudocryptochirus spe-
cies are not restricted to a single species of coral.

Finally, one comes to the significance of the transgression of the
Pacific Oceanic Barrier by decapod crustaceans in general and by coral-
inhabiting species in particular. This barrier, which consists of over
2,000 miles of open ocean between Hawaii and the Line Islands and the
American west coast, is perhaps the most formidable known, exceeding
for shore-bound marine animals even the Isthmus of Panama, a barrier
of comparatively recent origin, geologically speaking (Ekman, 1953;
Briggs, 1961). Such free-living decapod species as are known to occur
on both sides of it are either those which make their way across the Aleu-
tian arc, which rules out tropical species, or those known to be log-
riders, pelagic as adults as well as larvae, or susceptible to waif trans-
portation in some form. On the other hand, many of the coral commen-
sals are well established on both sides: of the family Alpheidae, the
common Alpheus ventrosus and Synalpheus charon; of the family Palae-
monidae, subfamily Pontoniinae, Harpiliopsis depressus and Fennera
chacei (Bruce, 1965); among the family Xanthidae, subfamily Trape-
zZiinae, Trapezia ferruginea, T. digitalis, and Domecia hispida, all mem-
bers of the Pocillopora colony, family Seriatoporidae. (A similar suite
of species inhabits corals of the genus Acropora in the western Pacific
but is absent from American waters as is the host family, Acroporidae).
The reasons for this selectivity are perhaps best summarized by Patton
(1966: 293):

“It is indeed interesting that in the tamilies Xanthidae and Alpheidae and in

the subfamily Pontoniinae, all of which are abundantly represented on both sides
of the East Pacific Barrier, the only species which extend across this barrier are

46 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

those which are obligate commensals on madrepore corals. It is possible that the
commensals listed above have longer larval lives than their free-living relatives,
although there is as yet no evidence for this. I agree with Garth (1946) that the
specialized habitat of these animals provides a more likely answer. If a given
locality in Pacific America contained the host coral, only a relatively few individ-
uals would have to arrive for a commensal species to become established. Due to
the special conditions of the coral habitat, it is unlikely that any local forms would
be very well adapted to it, and the highly adapted commensals which arrived
would therefore face little competition. This would be in marked contrast to the
free living species, which would have to face strong competition from well estab-
lished American forms and thus would have less chance of becoming established
themselves.”

The above remarks, while not intended to apply to members of the
genus Pseudocryptochirus of the family Hapalocarcinidae, whose pres-
ence in the eastern Pacific was not then suspected, apply equally well to
P. crescentus, now that its presence in the Gulf of California is known.
To what other genera and species of corallicolous crabs they may be
applied in the future depends on the energy and enterprise of a new gen- |
eration of diver-collectors who may take inspiration from this brief
account.

Coral-Inhabiting Crabs 47
LITERATURE CITED

BARBOUR, T.
1945. A naturalist in Cuba. Little, Brown & Co., Boston, 317p.

BRIGGS, J.C.
1961. The east Pacific barrier and the distribution of marine shore fishes. Evolu-
tion, 15:545-554.

BRUCE, A. J.

1965. On the occurrence of Fennera chacei Holthuis (Crustacea, Decapoda,
Natantia, Pontoniinae) in the Indian Ocean. J. Mar. Biol. Assoc. India,
7:80-82.

EDMONDSON, C. H.

1925. Marine zoology of the tropical central Pacific. Bernice P. Bishop Mus.
Bull., 27:1-62.

1933. Cryptochirus of the central Pacific. Bernice P. Bishop Mus. Occas. Pap.,
10 (5):1-23.

EKMAN, S.
1953. Zoogeography of the sea. Sidgwick & Jackson, Ltd., London, 417 p.

FIZE, A., and R. SERENE
1957. Les Hapalocarcinidés du Viet-Nam. Mem. Inst. Oceanogr. Nhatrang,
10:1-202.

GARTH, J.S.

1946. Littoral brachyuran fauna of the Galapagos Archipelago. A. Hancock Pac.
Exped., 5:341-601.

1964. The Crustacea Decapoda (Brachyura and Anomura) of Eniwetok Atoll,
Marshall Islands, with special reference to the obligate commensals of
branching corals. Micronesica, 1:137-144.

1965. The brachyuran decapod crustaceans of Clipperton Island. Proc. Calif.
Acad. Sci., (4) 33:1-26.

HIRO, F.
1937. Studies on the animals inhabiting reef corals. I. Hapalocarcinus and Cryp-
tochirus. Palao Trop. Biol. Sta. Studies, 1:137-154.

PATTON, W. K.
1966. Decapod Crustacea commensal with Queensland branching corals. Crusta-
ceana, 10:271-295.

POTTS, F. A.

1915. Hapalocarcinus, the gall-forming crab, with some notes on the related
genus Cryptochirus. Pap. Dept. Mar. Biol., Carnegie Inst. Washington,
8:35-69.

RATHBUN, M. J.
1937. The oxystomatous and allied crabs of America. U.S. Nat. Mus. Bull., 166:
1-278.

48 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

SCHMITT, W. L.

1936. Hancock Pacific Expedition, 1935. Explorations and field-work of the
Smithsonian Institution in 1935:29-36.

SEMPER, K. G.

1881. Natural conditions of existence as they affect animal life. /nternational
Scientific Series, 31:216-224.

SERENE, R.
1966. Note sur la taxonomie et la distribution géographique des Hapalocarcinidae
(Decapoda-Brachyura). Proceedings of the Symposium on Crustacea held

at Ernakulam from January 12 to 15, 1965. (Mar. Biol. Assoc. India). Part
1:395-398.

UTINOMI, H. [=F. HIRO]
1944. Studies on the animals inhabiting reef corals. III. A revision of the family

Hapalocarcinidae (Brachyura), with some remarks on their morphological
peculiarities. Palao Trop. Biol. Sta. Studies, 2:687-731.

Accepted for publication December 28, 1967.

TRACE ELEMENTS IN TISSUES
OF THE CALICO BASS
PARALABRAX CLATHRATUS (GIRARD)

R. P. STAPLETON

Department of Geology and Allan Hancock Foundation
University of Southern California
Los Angeles, California 90007

INTRODUCTION

Little is known of the distribution and concentration of trace elements in
the tissues of marine fishes. The few trace element analyses carried out
prior to the early 1950’s are summarized by Vinogradov (1953). Most
of these analyses covered only a limited range of elements and many
suffered from defects in technique. More recently, Goldberg (1962)
reported analyses for a wide range of elements in a number of pelagic
fishes. However, to date no one has attempted to carry out replicate
analyses on a number of individuals of the same species in order to deter-
mine the range of variation which might be expected. In view of the
increasing use of offshore waters to dispose of waste materials, such
studies are of potential value for the determination of the effects of
pollutants on marine populations.

Tipton et al. (1963) reported trace element analyses for numerous
samples of human tissues and the University of Southern California
Medical School has been carrying out analyses on abnormal human
tissues for the past several years. As a result of these investigations,
there are probably more data available on trace elements in human
tissue than there are for tissues of any other animal group. These analy-
ses indicate that trace element concentrations may vary over several
orders of magnitude for the same tissue taken from different individuals.
However, human beings and other terrestrial animals live in a very
variable chemical environment. It was expected that fish, living in the
more constant chemical environment of the oceans, might show less
variation from individual to individual. This expectation appears to be
justified by the present investigations.

The calico bass Paralabrax clathratus (Girard), also known as the
bull bass, or the kelp bass, is a popular game fish of the marine waters
off California. The fish is a shallow-water bottom-dweller which feeds
mainly on smaller fishes and crustaceans. Evidence from tagging opera-
tions, reported by Young (1963), indicates that the fish is nonmigratory
and seldom moves far from one area. Consequently, populations tend to

49

50 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

be made up of individuals which have been exposed to nearly the same
environment throughout their lives.

MATERIALS AND METHODS

A number of calico bass were taken by hook and line off the northeast-
ern shore of Catalina Island. This island is separated from the mainland
by a deep water channel twenty miles wide. The only waste effluent on
the island is ten miles down the coast at the town of Avalon, so that fish
from this area should not be affected by man-made pollutants. Six of
these fish were selected for analyses. They averaged about five hundred
grams in weight and about thirty centimeters in length, although there
was a certain amount of variation in size. Four were females and two
were males; two of the females were gravid.

In order to compare the Catalina Island population with a population
from a completely different type of environment, six calico bass were
obtained from the effluent pipe of the Scattergood Steam Plant of the -
Los Angeles Department of Water and Power. This steam plant dis-
charges coolant water at the rate of 230 million gallons per day. The out-
let is situated in fifteen feet of water at a distance of 1200 feet from shore
in Santa Monica Bay. At three-monthly intervals, the outlet pipe is
back-pumped in order to clear it of accumulating debris. During this
operation, large numbers of fishes and other marine organisms are trap-
ped in a settling basin. Water circulating through the cooling system of
the steam plant is allowed to increase in temperature in order to kill these
organisms. At the beginning of the operation water temperature is low
enough that fish may be collected from the settling basin while still alive.

Although not a major source of pollutants, discharge from the Scatter-
good plant appears to be enriched in some trace elements. Analyses for
some of these elements are shown in Table | as reported by Engineering-
Science Inc. (1961) along with values for normal sea water as reported
by Goldberg (1957). However, the figures for normal sea water indicate
conditions far from shore and may not be representative of near shore
values. Consequently, the Scattergood effluent may not be as enriched
in trace metals as would appear from these figures. The coolant water is
also warmed about five degrees Centigrade and is slightly chlorinated to
inhibit growth of organisms in the pipe.

Five of the six specimens collected from the Scattergood plant were
females, none of which were gravid, and one was male. They averaged
about the same size as the individuals from Catalina Island, although
there was somewhat less variation in size among the Scattergood fish.

The fish were kept on ice or refrigerated until they could be dissected.
For the initial analyses, samples of nine tissues were removed, stored

Trace Elements in Calico Bass 5I

in polyethylene bags and frozen. The heart, one eyeball, the liver, both
gonads and the pyloric caeca were removed entire. Samples were taken
of scales, integument and of muscle tissue from two regions, one dorsal
and one ventral. Bone was not analyzed because of the difficulty of
separating it from other tissues, and there were insufficient quantities of
blood or nervous tissue for analysis.

TABLE |

Concentrations of trace metals (in parts per million) for the Scattergood
effluent and for normal sea water.

Metal Scattergood Effluent! Normal Sea Water?
Cadmium 0.05 0.00011
Copper 0.015 0.003

Nickel 0.05 0.0005

Zine 0.05 0.01
Chromium 0.0048 0.00005

1 Engineering-Science Inc. (1961)
2 Goldberg (1957)
3 Hexavalent Chromium only

During dissection, it was noted that the livers of the fish from the
Scattergood effluent were about cne and two-thirds the size of livers of
fish of comparable size from Catalina Island. These enlarged livers
were discolored grayish yellow and were extremely friable, often falling
apart when removed. The cause of this condition is not known, although
there are a number of toxic substances which can produce similar condi-
tions. Other possible causes are the higher temperature of the Scatter-
good effiuent or a local disease-producing organism.

In order to check whether this condition was strictly local, a number
of calico bass were collected from other areas. Four fish were taken at
Dana Point, one from Guadalupe Island and one from San Clemente
Island. All of these areas are relatively free of pollutants and all of these
fish had normal livers. In addition, three fish were taken by hook and
line directly over the boil of the Scattergood effluent. These fish also had
normal livers. It seems likely therefore that this condition is restricted to
fish which actually live within the effluent pipe of the Scattergood plant.
The ratios of liver to body weight for all fish taken are shown in Table 2.

Figure | shows the internal organs of two calico bass, one from Dana
Point with a normal liver, and one from the Scattergood plant with a
liver which is relatively much larger.

52 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

TABLE 2

Ratios of liver to body weight for calico bass from different localities.

Average Ratio of
Number of

Locati : Liver Weight to
pees Fish Measured 2

Body Weight

Scattergood Plant 9 0.026
Boil of the Scattergood

Effluent 3 0.015
Catalina Island 6 0.012
Dana Point 3 0.017
San Clemente Island 1 0.009

ANALYSES

The analyses were carried out by the Spectrographic Laboratory of the.
University of Southern California Medical School. This group has had
considerable experience in analysis of human tissue. The methods
used, except for some minor variations, are fully described elsewhere by
Nusbaum et al. (1961). Analyses were carried out on an Industrial Re-
search Quantometer manufactured by Applied Research Laboratories.

During the preliminary drying operations, difficulties were experi-
enced with the pyloric caeca and these samples were abandoned. Scales
gave erratic values, suggesting that foreign matter from the environ-
ment was adhering to them and these were also abandoned. Because of
their small size, it was necessary to pool samples of hearts and of eye-
balls, so that each sample of these consisted of tissue from three differ-
ent individuals.

Mean values for trace element concentrations in the tissues of the
two populations are shown in Table 3. Values are reported as milligrams
per one hundred grams of dried tissue.

Concentrations did not generally vary greatly between different tis-
sue types, although eyeballs showed greater amounts of most trace ele-
ments. Muscle tissue is low in zinc and liver tissue in calcium. Phos-
phorus, aluminum and cadmium are high in livers, strontium and silver
in integument, and copper and iron in hearts.

There was no essential difference between male and female fish, even
in the gonads. However, the two gravid fish from Catalina Island showed
a threefold enrichment in zinc in the gonads over other fish of the same
population. These gonads also contained only about half as much phos-
phorus, lead, nickel and magnesium as those of other fish. Values for the
gonads of these two fish are reported separately in Table 3.

Trace Elements in Calico Bass 53

Comparison with trace element concentrations in tissues of other fish-
es, as reported by Goldberg (1962), shows that the proportions of trace
metals are generally the same except for higher concentrations of alumi-
num, chromium and barium in calico bass. Fish tissues are generally
higher in trace elements than are analogous human tissues as reported
by Tipton et al. (1963).

Concentrations in fish from the Scattergood plant showed somewhat
higher degrees of variation than did those of fish from Catalina Island.
Yet most elements were present in lower concentrations in the Scatter-
good fish. When concentrations are higher than in the Catalina Island
fish, the enrichment is by a much greater factor than any of the deple-
tions.

Of the five trace metals which are thought to be high in the Scattergood
effluent, cadmium, copper and zinc are high in the Scattergood fish,
while nickel and chromium are low. Apparently then, an increased con-
centration of a particular element in the environment does not neces-
sarily produce an increased concentration in tissues.

The elements which showed the greatest differences in concentra-
tions between the two populations were aluminum (which was present in
almost twice the concentrations in tissues of Scattergood fish as in tissues
of Catalina Island fish), cadmium, and nickel. These three elements are
not known or even suspected to be essential to the metabolism of the
organism. Four other elements — silver, barium, lithium and lead —
showed the least differences, yet these four elements are also not likely
to be necessary to metabolism. Those elements which are known to be
essential fall between these two extremes.

The tissues which showed the greatest differences in concentrations
between the two populations were the livers, not surprising in view of the
abnormal appearance of the livers of the Scattergood fish. Concentra-
tions in the livers of the Scattergood fish showed consistently lower con-
centrations of elements over those of the Catalina Island fish. Most
elements were present in somewhat higher concentrations in the mus-
cles and integuments of the Scattergood fish.

Of the six fish taken from the Scattergood plant, all but one had abnor-
mal livers. The liver of this fish, although normal in size and appearance,
contained about the same concentrations as did the livers of the other
Scattergood fish. This suggests that either changes in trace elements are
not related to changes in livers, or that the agent which produced the
abnormal condition of the livers produced preliminary changes in trace
element concentrations.

Although there were discernible differences between the two popula-
tions, variation within each population was not extreme. In only a few

54 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

TABLE 3

Average values for concentrations of trace elements in tissues of fish from the
Scattergood Steam Plant and from Catalina Island. Values are reported as milli-
grams per 100 grams of dry tissue.

Tissue Ag Al Ba Ca Cd Co Cr

Dorsal Muscle

Scattergood ND? es) 0.20 (2.3053 0.14 0.13

Catalina ND! 0.8 0.17 5 Ona Oss O22 an Only]
Ventral Muscle

Scattergood ND! Pes) 0.14 102.0 0.4 0.12 0.14

Catalina DO0I TOSS 0.13 54 SO: 0.43 0.14
Gonads

Scattergood ND} 2.8 0.28 85.3 1.0 0.36 0.20

Catalina? 0.042 3.8 0.26 SS OS 0.44 0.23

Catalina® OO 222: 0.22 Spd) Os 031/026
Liver

Scattergood ND? 2.8 0.14 ee) 1.1 0.14 0.10

Catalina OL002R e225) 0.18 26.5 2.4 OSS OSS
Integument

Scattergood 0102207 6:9 OF SP GS: Sie OLO 0.18 0.19

Catalina OO 12S OSG SES eam OFZ 0.14 0.14
Heart

Scattergood 0.006 1.6 0.12 38.0 0.4 OME 0:09

Catalina 0.016 0.4 0.20 48.0 0.2 Os 2eeOnly)
Eyeball

Scattergood 0.001 0.58 1900 0.6 0.52 0.48

WW
WwW
S
\o
—
N
nN
N
oS

Catalina 0.002 0.4 0.51 0.55

1Not detected

2Males and non-gravid females

3Gravid females

4Two samples, each consisting of material from three fish

=

Fe Li
aA 0169
2 SC«.62.
‘46 0.67
43 0.56
m3 0186
22 0.84
m0 0.77
6.0 0.58
0.5 0.73
i
2 0:68
A? 077
0.76
0.85
5.80

12.4

Trace Elements in Calico Bass

TABLE 3 (continued)

167
219

182
219

101
242
142

69
104

73
84

128
95

108
147

0.16

Mo

0.01
0.02

0.02
0.02

0.07
0.08
0.06

0.02
0.04

ND!
0.04

0.04
0.02

0.19
0.48

1045

0.22
0.17

0.33
0.18

0.20
0.34
0.32

0.11
0.21

0.54
1.01

0.23
0.37

9.20
16.2

5)

Zn

No. of
Samples

NAD

64
64

56 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

cases did the range of variation for an element within a particular tissue
of the population exceed an order of magnitude. Two samples of muscle
tissue taken from different regions of the same fish showed no significant
differences, indicating that concentrations are probably thesamethrough-
out the same tissue of the same individual.

Figure 1. Calico bass with internal organs exposed. The upper fish is from Dana
Point and the lower fish is from the Scattergood steam plant. Note differences in
relative size and appearance of livers (indicated by arrows). The upper fish is
about forty centimeters long.

Since only one population from a normal environment was examined,
it cannot be said for certain that differences in trace element concentra-
tion between the two populations was a result of the abnormal environ-
ment of the Scattergood effluent pipe. However, the fact that livers of
fish from the effluent were enlarged and discolored, while livers of fish
from a number of different normal environments were not, suggests
that this condition at least is a product of the Scattergood environment.

SUMMARY

1. Trace element concentrations in tissues of two populations of the
calico bass Paralabrax clathratus were examined. One population came
from a normal environment near Catalina Island and the other from the
effluent pipe of the Scattergood steam generating plant. Livers of fish
from this latter population were enlarged and discolored, probably as a
result of the abnormal environment.

Trace Elements in Calico Bass S7/

2. Although trace element concentrations in each tissue type varied
from individual to individual within each population, there was a great-
er degree of variation between the two populations. The tissue with the
greatest differences was liver tissue. In general, concentrations were
lower in liver tissue of fish from the Scattergood plant than in livers of
fish from Catalina Island.

3. The element which showed the greatest differences between the two
populations was aluminum which was present in higher concentrations
in tissues of fish from the Scattergood plant.

4. Differences in trace element concentrations between the two popula-
tions suggest that trace element analyses of tissues could be used for
determining effects of pollutants on marine organisms.

ACKNOWLEDGMENTS

Most of this work was carried out in the Micropaleontology Laboratory of the
Allan Hancock Foundation, University of Southern California, under the direc-
tion of Dr. O. L. Bandy. Analyses were undertaken by the Spectrographic Labora-
tory of the Medical School, University of Southern California, by S. Otter and S.
L. DiDio under the direction of Dr. R. E. Nusbaum. The project was initiated with
the help and cooperation of Dr. L. M. Butt, formerly chief pathologist of the Los
Angeles County General Hospital. Sample collection was assisted by the crew of
R/V Velero, research vessel of the University of Southern California. Advice and
cooperation were generously provided by the Los Angeles Department of Water
and Power, the California Department of Fish and Game and numerous sport
fishermen. The investigation was in part supported by United States Public Health
Service Research Grant WP-00158, from the division of Water Supply and Pollu-
tion Control.

LITERATURE CITED

ENGINEERING-SCIENCE INC.

1961. Report on collation, evaluation, and presentation of scientific and technical
data relative to the marine disposal of liquid wastes. California State Water
Pollution Board, Sacramento.

GOLDBERG, E. D.

1957. Biogeochemistry of trace metals. Geol. Soc. Am. Mem. 67:345-358.

1962. Elemental composition of some pelagic fishes. Limnol. Oceanogr. \xxii-
Ixxv. 7 (suppl.):42-45.

NUSBAUM, R.E., E. M. Butt, T. C. GILMOUR, and S. L. DIDIO
1961. Analysis of human tissue with a direct reading spectrometer. Am. J. Clin.
Path., 35:44-52.

TIPTON, I. H., M. J. COOK, R. L. STEINER, C. A. BOYE,

H. M. PERRY, JR., and H. A. SCHROEDER

1963. Trace elements in human tissue, Part I — Methods, Part II — Adult sub-
jects from the United States. Health Physics, 9:89-145.

58 Bulletin So. Calif. Academy Sciences/ Vol.67, No. 1, 1968

VINOGRADOV, A. P.
1953. The elemental chemical composition of marine organisms. Sears Founda-
tion, Mem. Il, 647 p.

YOUNG, P. H.
1963. The kelp bass (Paralabrax clathratus) and its fishery,
1947-1958. Calif. Dept. Fish and Game, Fish Bull. No. 122, 67 p.

Accepted for publication December 1, 1967.

MEMOIRS OF THE SOUTHERN CALIFORNIA ACADEMY OF SCIENCES

Wake, David B. Comparative Osteology and Evolution of the Lungless Sala-
manders, Family Plethodontidae. Volume 4, October 25, 1966. $6.50*

Guthrie, Daniel A. The Mammalian Fauna of the Lysite Member, Wind River
Formation, (Early Eocene) of Wyoming. Volume 5, October 25, 1967. $3.00*

Fierstine, Harry L. and Vladimir Walters. Studies in Locomotion and Anatomy
of Scombroid Fishes. Volume 6, January 18, 1968. $2.50*

*10% discount to members.

Make checks payable to Southern California Academy of Sciences.

Send order to:

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Los Angeles, California 90007

THE ADDITION OF THE HYDROID
CLADOCORYNE FLOCCOSA
TO THE CALIFORNIA MARINE FAUNA

DENNIS C. LEES

University of Southern California Marine Laboratory
Allan Hancock Foundation
University of Southern California
Los Angeles, California 90007

INTRODUCTION

In September 1965 a survey was begun by the Allan Hancock Founda-
tion of the University of Southern California to study the marine benthos
of Santa Catalina Island, California. The purpose of the study was to
obtain preliminary information on the species of algae, invertebrates
and vertebrates available for study and to determine the location of
various organisms, associations and communities near the planned
University of Southern California Marine Laboratory on that island.
The Santa Catalina Island Biological Survey (SCIBS) was to include all
bottom types around the island from the intertidal to 100 fathoms in
depth.

During the initial phase of this survey (September 1965 to December
1966), a card file of over 500 different taxa was compiled. The Univer-
sity of Southern California biologist-divers conducting the survey have
documented extensions of the geographical range of numerous orga-
nisms, primarily invertebrates.

While participating in this survey, I became interested in the taxono-
my of hydroids (Cnidaria: Hydrozoa). One of the many species observed
was a peculiar athecate form, Cladocoryne floccosa Rotch, 1871. The
genus Cladocoryne may contain four species: Cladocoryne floccosa
Rotch, 1871; Cladocoryne pelagica Allman, 1876; Cladocoryne had-
doni Kirkpatrick, 1890; and Cladocoryne simplex Perrier, 1891. It isa
member of the family Cladocorynidae, which is distinguished from all
other hydroid families by possession of both branched and unbranched
Capitate tentacles.

It was the contention of Philbert (1936) that C. haddoni and C.
pelagica should be synonyms of C. floccosa. He believed the variations
observed in the diagnostic characters were the result of either specific
variation or stage of development. Unfortunately, his conclusion was
not based on examination of C. pelagica and C. haddoni, but on the
descriptions of other workers. C. simplex Perrier is a nomen nudum.
This revision was not mentioned by either Fraser (1938, 1939, 1944,

59

60 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

1946, 1948) or Mammen (1963), the only workers mentioning this
genus since Philbert’s study.

It is my opinion that my measurements (Table 1) from the local
species are not substantially different from those of C. floccosa as given
by Philbert (1936). Rotch described bosses of nematocysts between the
branched capitate tentacles of both the proximal and distal verticils.
These bosses were not described for C. pelagica; these structures are
definitely lacking in the specimens at my disposal. Hargitt (1924) re-
marked on the absence of the bosses but nevertheless ascribed his
specimens to C. floccosa. Philbert (1936) mentioned the variability of
the number of nematocysts in these structures in the specimens of C.
floccosa.

Considering these facts, I have elected to call the local species C.
floccosa. Furthermore, it is my opinion that the revision of Philbert
(1936) is valid; however, in the absence of comparative material, I am
unable to make a definite statement. .

The discovery of Cladocoryne floccosa on Santa Catalina Island,
California, constitutes a generic range extension in the northeastern
Pacific from Braithwaite Bay, Socorro Island, Revillagigedo Islands.
However, in view of other tropical hydroids cellected during this survey,
the discovery of C. floccosa was not surprising.

C. pelagica has been noted only twice from the eastern Pacific (Fraser,
1938). Because it is so conspicuous in the hydroid fauna of Santa Cata-
lina, and its appearance peculiar, I feel it necessary to include a descrip-
tion. For a very detailed analysis and description of the species, see
Philbert (1936) and Weill (1937).

Cladocoryne floccosa Rotch, 1871

Cladocoryne floccosa Rotch, 1871, p. 227-228; Hargitt, 1924, p. 481;
Philbert, 1936, p. 1-16; Weill, 1937, p. 1-11.

Trophosome. — Stolon generally non-reticulate, slightly rugose;
zooids found singly or in slightly branched colonies arising from stolon.
Perisarc well developed; several annulations at base of stem and bran-
ches; stem and branches of uniform diameter throughout. Hydranth
fusiform with four to seven unbranched capitate oral tentacles and about
ten to sixteen branching capitate tentacles arranged in irregular verticils;
tentacles of middle verticil of greatest length (Fig. 1). Branched tentacles
with three to five pairs of pedunculate nematocyst balls arising from
their ventral sides and three to five adnate nematocyst balls dorsally.

Gonosome. — Hydranths with up to fifteen gonophores, borne singly
on short peduncles arising between tentacles. Mature gonophores fig-

The Hydroid Gladocoryne 61

NS
apes

=

Figure 1. Cladocoryne floccosa Rotch, 1871, mature colony (composite drawing).

A. Nutritive zooid; alcoholic specimen.
B. Nutritive zooid; living specimen.
C. Generative zooid, showing gonophores and reduced tentacles;
alcoholic specimen.

62 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

shaped, some nearly as large as hydranth; several mature gonophores
may partly conceal hydranth. Tentacles on fertile hydranths smaller
and fewer in number.

Nematocysts. — Stenoteles and macrobasic telotrichous euryteles
(Philbert, 1936; Weill 1937.

TABLE |

Measurements of Cladocoryne floccosa from Santa Catalina Island.

Colony, maximum height 2-10 mm
Pedicel
Length 1.8-5.5 mm
Breadth .16-.20 mm
Hydranth
Length .9-1.45 mm
Breadth .3-.4 mm
Breadth at oral tentacles .25-.4 mm
Tentacles
Branching
Length .5-1.4 mm
Width at base .08-.14 mm
Length of capitate branches .06-.1 mm
Width of capitate branches .04 mm
Width of nematocyst balls .05-.07 mm
Oral
Length .11-.15 mm
Width at base .05-.06 mm
Width of nematocyst balls .09-.11 mm
Gonophores
Length .35-.5 mm
Width .25-.35 mm

Distribution. — Mediterranean Sea; Isle of Herm, France; Vineyard
Sound, New York, U.S.A.;Sargasso Sea; Natal; Equador; Revillagigedos
Islands; Santa Catalina Island, California, U.S.A.; Japan; The Philip
pines; New Guinea; Australia; Pamban, India.

The Hydroid Gladocoryne 63

Occurrence at Santa Catalina Island:

STATION LOCATION DEPTH DATE
(in m)

SCIBS 8:65 Eagle Reef 7.6 25 October 1965

SCIBS 13:65 Ship Rock 6.1 2 December 1965

SCIBS 16:65 Isthmus Reef —- 7 December 1965

SCIBS 2:66 Fisherman Cove 9.14 4 January 1966

SCIBS 10:66 Bird Rock — 26 April 1966

SCIBS 41:66 Eagle Reef 7.6 9 July 1966

SCIBS 62:66 Isthmus Reef = 31 October 1966
*SCIBS 65:66 Isthmus Reef — 11 November 1966

SCIBS 66:66 West End — 18 November 1966

SCIBS 2:67 Fisherman Cove 3.05 27 January 1967

* Specimens with mature gonophores.

Local Natural History. — At Santa Catalina Island, C. floccosa has
been found primarily on the brown alga Cystoseira osmundacea (Men-
zies) C. A. Agardh, 1809, occasionally on Laurencia sp., and Sargassum
palmeri Grunow, 1915. It has generally been found on the stipe or
heavier portions of the thallus of the alga. Bathymetric range is from
approximately three to ten m. Presence at SCIBS station 2:67, which is
located near the mouth of an intermittent stream, would suggest great
tolerance to salinity and temperature variations. During winter storms,
this area is subject to dilution by large quantities of fresh water. Highest
densities are found during October and November; mature gonophores
were collected in November.

ACKNOWLEDGMENTS

I am indebted to the Allan Hancock Foundation for use of the Oceanography
Library and Laboratory facilities; this information was obtained as part of the
Santa Catalina Island Biological Survey. I also wish to thank the following per-
sons: Robert R. Given, University of Southern California Marine Laboratory,
Santa Catalina Island, California, for his helpful suggestions and criticism in the
preparation and review of this paper; my wife, Anne A. Lees, for drawing the
figure accompanying this description; Linda Dunbar and Marba Randlemon for
typing the manuscript.

64 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

LITERATURE CITED

FRASER, C. M.

1938. Hydroids of the 1934 Allan Hancock Pacific Expedition. Allan Hancock
Pacific Exped., 4:1-105.

1939. Distribution of the hydroids in the collections of the Allan Hancock
Expeditions. Allan Hancock Pacific Exped., 4:155-178.

1944. Hydroids of the Atlantic Coast of North America. Univ. Toronto Press.
640 p.

1946. Distribution and relationship in American Hydroids. Univ. Toronto Press.
464 p.

1948. Hydroids of the Allan Hancock Pacific Expeditions since March 1938.
Allan Hancock Pacific Exped., 4:179-335.

HARGITT, C. W.
1924. Hydroids of the Philippine Islands. Philipp. J. Sci., 24:481.

MAMMEN, T. A.
1963. On a collection of hydroids from South India. J. Mar. Biol. Assoc. India.
SBS Sho

PHILBERT, M.
1936. Etudes sur Cladocoryne floccosa Rotch. Inst. Oceanogr. Monaco Bull.
No. 708 16 p.

ROTCH, W. D.
1871. On a new genus and species of hydroid zoophyte (Cladocoryne floccosa).
Ann. Mag. Nat. Hist., Ser. 4, 7:227-228.

WEILL, R.

1937. Contribution a l’etude des Pteronemida (Hydrozaires) — Le cnidome de
Cladocoryne floccosa Rotch et son interpretations (d’apres les documents
laisses par feu Maurice Philbert). Inst. Oceanogr. Monaco Bull. No. 719

11 p.
Accepted for publication January 18, 1968.

BROODING OF THE EASTERN GLASS LIZARD,
OPHISAURUS VENTRALIS

Noble and Mason (1933) reported on brooding in several species of
lizards, including Ophisaurus ventralis. They concluded that brooding
in this species probably does not have a thermoregulatory function.
Their measurements of body and substrate temperatures indicated a
temperature difference of up to 0.4°C. Smith (1946) in referring to the
above work indicated that brooding did have a possible thermoregulatory
function. Unfortunately, Noble and Mason reported single temperatures
for any one day. A better indication of thermal relations is obtained
from frequent readings under a constant temperature and under con-
trolled changing temperatures.

On 2 June 1967 an Ophisaurus ventralis at the New York Zoological
Park laid seven eggs and was observed coiled loosely around them the
next day (fig. 1). The animal had been kept at about 27°C since its arriv-
al at the zoo on 25 April 67. The lizard was moved into a temperature
controlled room (27°C) on 10 June 67. A thermistor probe was inserted
into the animal’s cloaca and was held in place by tape around the tail.
Thermistors were placed one inch into the tan bark substrate and one
inch above the substrate. When released, the animal burrowed quickly
into the substrate and around her eggs. The following morning the ani-
mal was coiled around her eggs and part of her coil was exposed to the
air. Temperature readings (+0.05°C) were taken every five minutes,
from 1000 to 1100 EST. Figure 2A shows the pattern of temperature
change during this hour. The maximum temperature difference between
animal and substrate was 0.07°C. At 1200 the room temperature was
lowered and readings were taken every 15 minutes until 1600. Figure
3A shows the readings taken for this 4 hour period. Even during the
temperature drop, the cloacal temperature lagged only slightly behind
the substrate temperature, the maximum difference being 0.5°C. The
next morning (12 June 67) the animal was completely buried in the
substrate with its eggs. Temperature readings were started at 0730
and continued every five minutes until 0830. Figure 2B shows the new
temperatures reached. The maximum observed difference between
cloacal and substrate temperatures was 0.08°C. At 0830, the room
temperature was returned to its original 27°C setting. Temperatures
were recorded every 15 minutes until 1200. These results are shown in
figure 3B. The greater lag between substrate and cloacal temperatures
during heating is attributed to the lizard being buried deeper in the

65

66 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968

Figure 1. Ophisaurus ventralis and eggs — 10 June 1967.

substrate than it was during cooling. At 1200 the animal was weighed
(35.37g) and returned to its container. It promptly buried into the sub-
strate, encircling its eggs.

A juvenile albino mouse was placed in the container with the lizard
on 15 June 67. The lizard, being completely buried, protruded its head
from the substrate, grabbed the mouse and quickly swallowed it. Then

Eastern Glass Lizard 67

it drew its head back under the substrate. Subsequent offers of food
were ignored. After the hatching of the first young on 19 July 67, the
adult lizard became more active and no longer coiled around the remain-
ing eggs. Crickets offered the adult animal on 22 July 67 were readily
eaten.

The question arises as to the function of brooding in Ophisaurus.
The observations of Noble and Mason (1933) on Ophisaurus ventralis
and of Pope (1929) on O. harti indicate the shyness and reluctance of
these lizards to protect their eggs. While the observed temperature
measurements apparently negate the likelihood of physiological ther-
moregulation, the possibility of behavioral control still exists. Assuming
that Ophisaurus leaves its eggs to bask, it is unlikely that any significant
heat would be transferred to its eggs because of the small size of these
animals which limits their heat capacity, their high surface area to mass
ratio which would mean a rapid loss of the small amount of heat gained
and finally the loose coil they form around their eggs provides an inef-
ficient coupling for heat transfer. However, rather than the usual pattern
of the animal basking and then returning to its eggs, it is possible that
Ophisaurus controls the temperature of its eggs by changing their level

@ CLOACA
@ SUBSTRATE
@ AIR

1200 1300 1400 1500 1600 0800 0900 1000 1100 1200
11 JUNE 67 12 JUNE 67

Figure 2. Relationship of cloacal to substrate and air temperatures at two differ-
ent temperature settings.

68 Bulletin So. Calif. Academy Sciences/ Vol. 67, No. 1, 1968
% %
276

@ CLOACA 216
B SUBSTRATE

275 @ AIR

274 214
273

272

27.1

269 209

1000 ILJUNE 67 1100 0730 12 JUNE 67 0830

Figure 3. Response of cloacal and substrate temperatures to a drop (A) and to a
rise (B) in air temperature.

in the substrate. This idea is supported by the observed change in level
of the eggs under the two temperature regimes. Further observations of
brooding animals will be necessary to test this hypothesis.

ACKNOWLEDGMENTS

I thank Itzchak Gilboa for his observations of the Ophisaurus feeding and Wil-
liam Meng for photographing the graphs. This study was conducted at the New
York Zoological Park and was supported by NIH Grant GM-10156 to V. H.
Hutchison and by funds to the author from the New York Zoological Society.

LITERATURE CITED

NOBLE, G. K. AND E. R. MASON
1933. Experiments on the brooding habits of the lizards Eumeces and Ophisaurus.
Amer. Mus. Novitates, No. 619, 29p.

POPE, C. H.
1929. Notes on reptiles from Fukien and other Chinese Provinces. Amer. Mus.
Natur. Hist., Bull. 58:335-487.

SMITH, H. M.
1946. Handbook of Lizards. Ithaca, Cornell University Press. 557p.

Allen Vinegar, Department of Zoology, University of Rhode Island, Kingston,
Rhode Island. New Address: Department of Biology, California State College,
Long Beach, California.

Accepted for publication November 30, 1967.

Southern California
Academy of Sciences

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, BULLETIN OF ala E

ite Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

VOL. 67 APRIL-JUNE 1968 ParRT 2

LIBRARY.

auUG 5 1968

NEW YORK
BOTANICAL GARDEN

CONTENTS

Euphausiacea of the Arctic Ocean and Its Peripheral Seas, Stephen
R. Geiger, Kathleen Rodriguez and Manuel M. Murillo ....

The Terrestrial Molting Behavior of the Crab Grapsus grapsus
tenuicrustatus. Jens K. Knudsen

The Pinnotheres concharum Complex (Crustacea, Decapoda,
Family Pinnotheridae). Edward S. Davidson

Studies of the Blood of Ascidia nigra (Savigny). III. Some aspects
of the Biochemistry of Vanadocyte Aggutination, James A.
Vallee, Jr.

Adaptations in Movement Patterns of Two Species of Salt-Marsh
Rodents. George F. Fisler

Seasonal Occurrence of the Commensal Polychaetous Annelid
Ophiodromus pugettensis on the starfish Patiria miniata, Riv-
ian Lande and Donald J. Reish

: Chaetognaths from the Arctic Basin, Including the Description of

: a New Species of Heterokrohnia. John Kayl Dawson ¥

Research Note: a
A Spider Trackway from the Coconino Formation, Seligman, /
Arizona. Raymond M. Alf

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BULLETIN OF THE SOUTHERN CALIFORNIA
ACADEMY OF SCIENCES

VOL. 67 APRIL-JUNE, 1968 No. 2

EUPHAUSIACEA OF THE ARCTIC OCEAN AND ITS
PERIPHERAL SEAS

STEPHEN R. GEIGER, KATHLEEN RODRIGUEZ AND MANUEL M. MURILLO

Department of Biological Sciences,
University of Southern California,
Los Angeles, California

INTRODUCTION

Since 1952 plankton collecting has been carried out in the Arctic Ocean
from drifting ice stations and on several occasions from icebreakers,
under the direction of Professor J. L. Mohr of this department. Although
Euphausiacea are not abundant in the approximately 5000 samples
which were taken in oceanic areas and were not uniformly abundant in
poorly sampled neritic areas, when all of these euphausiaceans are
examined a better understanding of their distribution in the arctic-sub-
arctic is possible.

Scattered records exist of Euphausiacea from the Arctic Ocean and
are particularly scarce over deep areas. From north of Wrangel Island
Brodsky and Nikitin (1955) reported six Thysanoessa inermis. Eu-
phausiids were not taken when Fletcher’s Ice Island, T-3 was northwest
of Ellesmere Island nor when it was north of Prince Patrick Island
according to Mohr (1959) and Grainger (1965) respectively. Johnson
(1963) did not list any from Station Alpha which was in the northern
part of the Canada Basin. None were reported from the Eurasia Basin
by Bogorov (1946), although Sars (1900) reported one Nyctiphanes
(= Meganyctiphanes) norvegica and four Thysanoessa longicaudata
from the FRAM collections and Dunbar (1964) shows T. longicaudata
as occasionally present in the Arctic Ocean, outside of its main area of
abundance in the North Atlantic.

Where euphausiids are present over the continental shelf and slope of
the Arctic Ocean the predominant species are Thysanoessa raschii and
T. inermis. From the reviews of Ponomereva (1959) and Zenkevitch
(1963) it is clear that these species are abundant and very important
contributors to the biomass of the Barents Sea. The populations in the
poorly sampled, less productive brackish waters of the Siberian con-

69

70 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

tinental shelf are much smaller than that in the Barents Sea, but their
characteristics are poorly known. Schmitt (1919), Banner (1954), and
Johnson (1956) have established the presence of these species in the
shelf and slope waters of northern Alaska. Grainger (1965) reported T.
raschii, but not T. inermis from the South Beaufort Sea. Dunbar’s (1964)
review shows that neither species has been found along the narrow ice-
covered continental shelf adjacent to the Canadian Archipelago or
within the western portion of the Archipelago itself.

In areas influenced by North Atlantic waters Meganyctiphanes nor-
vegica and T. longicaudata are found, with the latter penetrating further
into the Artic Ocean; see summaries by Zenkevitch (1963) and Dunbar
(1964). Where the Arctic Ocean is influenced by waters from the Bering
Sea, Schmitt (1919), Banner (1954), Johnson (1956), and Ponomereva
(1957) have reported the presence of the North Pacific-Bering Sea spe-
cies T. longipes.

MATERIALS AND METHODS

The specimens from over deep areas of the Arctic Basin were collected
from the ice floe, ARLIS I (Arctic Research Laboratory Ice Station No.
1) and from the ice islands, Fletcher’s Ice Island T-3 and ARLIS II.
These collections were made during almost continuous operation of the
biological program between September 1959 and May 1967. Additional
samples from peripheral areas include samples from northeast Green-
land waters taken from ARLIS II, February — May 1965; Chukchi,
East Siberian, and Laptev Seas taken from USCGC NORTHWIND,
August — September 1963; and Barents and Kara Seas taken from
USCGC EASTWIND, August — September 1967. Station lists are
available from the Arctic Project of this department and will be de-
posited at the American Documentation Institute, Library of Congress,
Washington, D. C.

The plankton nets which were used were constructed by the Puget
Sound Workshop, Bellevue, Washington and have a one-half meter
opening and mesh sizes of No. 6, No. 20, or No. 24, which have aper-
tures respectively of 215, 73, and 67 microns. Nets were usually towed
vertically between two depths and then closed and raised or towed at a
particular depth before being raised open to the surface. Most of the
samples were preserved in 7% formalin buffered with hexamethylena-
mine, but a small number were preserved in Bouin’s solution or in 70%
ethanol. All stalk-eyed crustaceans were removed from the samples and
euphausiids were identified and measured (tip of the rostrum to the
posterior end of the telson).

Arctic Euphausiacea 71

OBSERVATIONS

In the collections made from the drifting ice stations within the Arctic
Basin euphausiaceans were most abundant over or near the continental
shelf (Fig. 1) in the upper 50 meters of water. Only a few specimens
were collected over deep areas at high latitudes of the Arctic Ocean and
in the eastern part of the Beaufort Sea. Four species of euphausiids
were present; Thysanoessa raschii and T. inermis predominated with T.
longicaudata and T. longipes rarely present.

Of peripheral seas, euphausiids were abundant in the waters of north-
east Greenland and the Barents Sea. Thysanoessa inermis, T. longi-
caudata, and Meganyctiphanes norvegica were present in northeast
Greenland waters and T. inermis, T. raschii, and M. norvegica, in the
Barents Sea. Only two individual euphausiids, and these were both T.
inermis, were taken in the northern part of the Kara Sea. T. raschii, T.
inermis, and T. longipes were collected in the Chukchi Sea, but euphau-
siids were not taken in the East Siberian or Laptev Seas although mysids
and decapods were frequently caught.

Thysanoessa raschii (M. Sars)

Thysanoessa raschii was the euphausiid most frequently caught be-
yond the continental shelf of the Arctic Basin (Fig. 1). It was taken
northward to almost 80°N latitude, eastward into the Beaufort Sea to
about 147°W longitude, and as far west as our collections go, about
174°E longitude. T. raschii was present over the continental shelf of the
Chukchi and Barents Seas, but was not present in the waters off north-
east Greenland although other species of euphausiids were abundant.

Specimens collected from the drifting stations ranged in length from
6-26 mm, with females reaching a maximum of 20 mm and males 26
mm. Among individuals shorter than 17 mm females outnumber males.
No males shorter than 14 mm were recognized; at which size the petas-
ma is undeveloped and the difference in the width of the rostrum in
males and females is not clear. About four-fifths of the specimens from
the Arctic Basin and most from the Barents Sea were smaller than 14
mm. Young individuals, 4-7 mm long, were particularly abundant at
an EASTWIND station located at 72°50'N, 44°23’E.

Thysanoessa inermis (Krgyer)

Within the Arctic Ocean Thysanoessa inermis occurred in many of
the same samples as T. raschii (Fig. 1). In the Atlantic sector, but not in
the Pacific sector, T. inermis usually accounted for the major portion of
the larger samples. Thysanoessa inermis from the Arctic Basin is ap-
parently made up of individuals of a single unimodal size grouping (Fig.

Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

V2

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Arctic Euphausiacea 78

2). Animals range in length from 9-21 mm. In contrast, T. inermis from
the waters of northeast Greenland have a bimodal size frequency (Fig. 2)
among animals ranging from 9-27 mm in length. The smaller group of
animals are similar in size to those from the Arctic Basin, with the larger
group being distinct. Only a small number of larger individuals were
caught in the Barents Sea, with most individuals less than 7 mm long and
a range from 3-25 mm. Although only one male was found in 85 in-
dividuals within the Arctic Basin, they occurred quite frequently in
northeast Greenland waters (Fig. 2).

Thysanoessa inermis was originally described as two distinct species,
Thysanopoda inermis and Thysanopoda neglecta by Krgyer (1846). This
separation was based on eye-shape, variation in the length, shape, and
setation of the second thoracic leg, and the presence or absence of an
additional process on the petasma. Hansen (1911), Einarsson (1945)
and others now consider them as two forms of T. inermis, representing
different growth stages of the single species, in which the smaller neglec-
ta form usually grows into the inermis form. Specimens from the North
Pacific are apparently all of the inermis form (Boden, Johnson, and
Brinton, 1955; Ponomereva, 1963; Nemoto, 1966). In our collection
both forms were found in the Barents and Kara Seas. Specimens of the
neglecta form from the Barents Sea ranged from 5-8 mm long; a single
16 mm long individual from the Kara Sea was also of this type.

Variation in the number of abdominal segments with a spine projec-
ting from their posterodorsal margin has also been recognized, and the
frequency of occurrence of these spines has recently been studied. Ne-
moto (1966) found two-spined forms to be more common than one-
spined or the rare three-spined forms in the North Pacific and its adja-
cent seas, including the Bering Sea. Hansen (1911, 1915) has recorded
several two-spined forms from the eastern coast of North America and
Jones, Forsyth, and Cooper (1967) infrequently found two-spined forms
in the North Sea, but Einarsson’s (1945) studies only mention one-spined
forms from Icelandic waters. In the northeast Greenland, Barents, and
Kara Seas samples only forms with one dorsal spine on the sixth abdomi-
nal segment were found. Specimens with a dorsal spine on the fifth and
sixth abdominal segment, as well as the one-spined forms were collected
throughout the Pacific sector of the Arctic Ocean. From this area the
one-spined forms ranged in length from 9-21 mm with a mean of 14 mm
and two-spined forms ranged from 12-21 mm with a mean of 15 mm.
The percentage of two-spined forms based on all of these specimens was
24 percent and for those over 10.5 mm, at which length Nemoto (1966)
states that a well developed spine is present, was only slightly higher; 25
percent. Three-spined forms were not found.

74 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

NUMBER OF SPECIMENS
S)

1O, 2 V4 716 18° 20: 22 2angee

LENGTH (mm)

Figure 2. Size Frequency of Thysanoessa inermis. The line graph shows the dis-
tribution in three similar pooled samples from the Arctic Basin; stations 44, 45
and 189 collected by W. Rork. The histogram shows the distribution in a sample
from off northeast Greenland; station 207 collected by R. Stendell. On the histo-
grams, blackened areas represent females and open areas males.

Meganyctiphanes norvegica (M. Sars) and
Thysanoessa longicaudata (Krgyer)

Meganyctiphanes norvegica was collected in the waters off northeast
Greenland and the Barents Sea, but not within the Arctic Basin. Thysan-
oessa longicaudata was abundant at some of the stations off northeast
Greenland and was collected several times at high latitudes within the
Arctic Ocean (Fig. 1). It was not collected north of Greenland nor with-
in the area of the Arctic Basin in which 7. raschii and T. inermis pre-
dominated.

Thysanoessa longipes Brandt

One Thysanoessa longipes was collected toward the eastern part of
the Beaufort Sea and two north of the Bering Strait (Fig. 1). The two

Arctic Euphausiacea US

larger specimens, 15 and 26 mm in length, were of the variety with dorsal
spines on the third, fourth, and fifth abdominal segments. The smaller
specimen of 8 mm from 74°48'N, 165°42’W did not have spines; we
interpret this as a young form which has not yet developed spines rather
than as a member of the more southern unspined form of this species,
whose distribution has been studied by Brinton (1962).

DISCUSSION

The predominant species in our collections are the neritic Thysanoessa
raschii and T. inermis. T. raschii was most abundant in the Pacific sector
of the Arctic Ocean over the Chukchi Continental Shelf and the Chuk-
chi Rise. 7. inermis was more abundant than T. raschii in the Barents
Sea. T. inermis was present in northeast Greenland waters while T.
raschii was not.These species were not in our collections which were
made during more than three years of sampling from ARLIS II in the
high arctic over the Canada and Eurasia Basins or from Fletcher’s Ice
Island, T-3 when it was over deep areas of the eastern part of the Beau-
fort Sea. They were not present in the NORTHWIND samples from the
Laptev and East Siberian Seas. These new as well as previous records
give a distributional pattern which suggests that if the populations of T.
inermis and T. raschii of the Atlantic and Pacific sectors of the Arctic
Ocean are now connected, they are connected only along the Russian
continental shelf and slope and less probably along the Alaskan conti-
nental shelf and through the Canadian Archipelago. This is not without
importance for distribution because in warmer periods these connec-
tions could serve as exchange routes for the subarctic populations.

The different frequencies of occurrence of certain of the variable
characteristics described for Thysanoessa inermis also suggest a separa-
tion of the Pacific from the Atlantic populations. We did not find neglec-
ta forms of T. inermis from the Pacific sector of the Arctic Ocean, al-
though this is not unexpected as the specimens were 9 mm or longer and
at this size Einarsson (1945) rarely found neglecta forms in North Atlan-
tic animals and neglecta forms have not been described in the extensive
studies of Pacific euphausiids by Brinton (1962), Ponomereva (1963)
and Nemoto (1966). These forms were not present in specimens which
were all over 10 mm long, from northeast Greenland waters, but did
occur in small 7. inermis from the Barents Sea and in a moderate sized
individual from the Kara Sea.

Further support for this separation of the Pacific and Atlantic popula-
tions is suggested by the greater frequency of occurrence of the two-
spined forms of 7. inermis in the Pacific sector of the Arctic Ocean.

76 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

About one-fourth of the T. inermis from the Pacific sector were of the
two-spined variety, but two-spined forms were not found in our speci-
mens from the Greenland, Barents, or Kara Seas. The absence of two-
spined forms from Icelandic and Greenland waters and the similarity in
bimodal size frequency in T. inermis collected from these two areas in
the same season suggests an affinity between the populations of this
species and a similarity in the environments of these two locations.
However, as the two-spined forms occur at low frequencies on either
side of the Atlantic and may arise from simple genetic changes they may
also occur in the waters around Greenland and Iceland. In addition, the
absence of 7. raschii from northeast Greenland and its presence around
Iceland argues against these environments being identical.

The presence of a high proportion of small individuals of Thysan-
oessa inermis and T. raschii from the Barents Sea indicates that they
are actively reproducing in that area. The absence of small individuals
of T. inermis from northeast Greenland waters, but the presence of clear
first and second year classes, is more difficult to interpret as samples
were only examined from February and March. If they have a life cycle
similar to that described by Einarsson (1945) from north and east Ice-
landic waters, then in February and March samples young should not be
expected and two separate year groups should be present in the plank-
ton. In the Pacific sector of the Arctic Ocean the absence of young, rarity
of males, and lack of a second or third year class of T. inermis suggest
that this population is not functioning optimally. T. raschii young were
not abundant, but males occurred more frequently than in 7. inermis
and individuals reached a size expected for a second year class. These
observations and the predominance of T. raschii over T. inermis sug-
gest that T. raschii is better adapted in this Pacific sector of the Arctic
Ocean than T. inermis.

The occurrences of the less frequently caught species are consistent
with known distribution patterns for these species and the influence of
water masses with which they are usually associated. Meganyctiphanes
norvegica and Thysanoessa longicaudata are primarily boreal, north
Atlantic species and were collected in areas where Coachman and
Barnes (1963) and others have reported the penetration of North At-
lantic water and where animals with distributions similar to those of
these two euphausiids have been found, as for example, the siphono-
phore, Dimophyes arctica and the copepod, Calanus finmarchicus s. str.
by Jaschnov (1966). Similarly the North Pacific and Bering Sea species
T. longipes was found where Coachman and Barnes (1961) and others
have demonstrated that the Bering Sea water penetrates into the Arctic
Ocean and where Bering Sea and neritic species of the Chukchi Conti-

Arctic Euphausiacea Vi

nental Shelf have been transported into the Arctic Basin. Examples of
this sort of distribution are several species of copepods reported by
Johnson (1963), meroplanktonic Anthomedusae and Leptomedusae by
Shirley (1966) and the larvae of the sea anemone Cerianthus by Tibbs
(1967).

Shallow and deep dwelling oceanic Euphausiacea were not present in
our collections and none have been recorded from the Arctic Ocean,
although their introduction from the Atlantic should be possible. Indeed
another oceanic stalk-eyed crustacean, the shrimp Hymenodora glacia-
lis does inhabit both of these oceans. The extensive shallow areas of the
Bering and Chukchi Seas apparently serve as a barrier between the
Pacific and Arctic Oceans. Oceanic species have not evolved from the
neritic forms of the arctic continental shelf. Those euphausiids that are
found over deep areas are the subarctic, neritic species that become less
abundant as the influence of neritic waters, with a stock of neritic indi-
viduals, is reduced.

SUMMARY

1. The neritic, subarctic Thysanoessa raschii and T. inermis predomi-
nated in the Arctic Ocean and its peripheral seas. They occurred
together, but the populations of each are at present apparently sep-
arated into the Atlantic and Pacific sectors of the Arctic Ocean.

2. The occurrences of the less frequently caught Meganyctiphanes
norvegica, Thysanoessa longicaudata, and T. longipes were consis-
tent with the known distribution patterns for these species and the
influences of the water masses with which they are associated in the
areas of capture.

3. Shallow or deep dwelling oceanic Euphausiacea were not present in
the Arctic Ocean.

ACKNOWLEDGEMENTS

This study has been made possible through the efforts of the numerous collectors
involved and the cooperation in securing these collections provided by the staff of
the Arctic Research Laboratory and the United States Coast Guard.

We gratefully acknowledge the use of the laboratory and library facilities of
the Allan Hancock Foundation of the University of Southern California. This
research was supported by contract Nonr 228 (19), NR 307-270, between the
Office of Naval Research, Department of the Navy, and the University of South-
ern California.

LITERATURE CITED

BANNER, A. H.
1954. New records of Mysidacea and Euphausiacea from the northeastern Pa-
cific and adjacent areas. Pacific Sci. 8: 125-139.

78 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

BODEN, B. P., M. W. JOHNSON and E. BRINTON
1955. The Euphausiacea (Crustacea) of the North Pacific. Bull. Scripps Inst.
Oceanogr. 6: 287-400.

BOGOROV, V.

1946. Zooplankton collected by the “Sedov” expedition 1937-1939. [In Russian,
English summary]; /n V. Buinitski, (ed.), Trudy dreifujusjtsjei ekspeditii
glawseiomorputu na ledokoljnom parochode “T. Sedov”, 3: 336-370.

BRODSKY, K. A. and M. M. NIKITIN

1955. Hydrobiological work. In M. M. Somoy, (ed.), Observational data of the
scientific research drifting stations of 1950-1951. Morskoi Transport,
Leningrad, 1: 404-465. Trans. by Amer. Meteorol. Soc. DDC doc., AD
117135.

BRINTON, E.
1962. The distribution of Pacific euphausiids. Bull. Scripps Inst. Oceanogr. 8:
51-270.

COACHMAN, L. K. and C. A. BARNES
1961. The contribution of Bering Sea water to the Arctic Ocean. Arctic, 14:
147-161.

1963. The movement of Atlantic water in the Arctic Ocean. Arctic, 16: 8-16.

DUNBAR, M. J.
1964. Euphausiids and pelagic amphipods, distribution in North Atlantic and

arctic waters. Serial Atlas Marine Environment. Amer. Geographical Soc.
Folio 6, 2 p, 8 pl.

EINARSSON, H.
1945. Euphausiacea I. Northern Atlantic species. Dana-Report, No. 27: 1-185.

GRAINGER, E. H.
1965. Zooplankton from the Arctic Ocean and adjacent Canadian waters. J. Fish.
Res. Bd. Canada, 22: 543-564.

HANSEN, H. J.
i911. The genera and species of the Order Euphausiacea, with account of re-
markable variation. Bull. Inst. Oceanogr. Monaco, No. 210: 1-54.

1915. The Crustacea Euphausiacea of the United States National Museum. Proc.
U.S. Nat. Mus. 48: 59-114.

JASCHNOV, V. A.

1966. Water masses and plankton. 4. Calanus finmarchicus and Dimophyes
arctica as indicators of Atlantic water in the Polar Basin. Okeanologiya
6: 493-503. Trans. by Scripta Technica Inc. for Amer. Geophys. Union,
Washington, D.C. p. 404-412.

JOHNSON, M. W.
1956. The plankton of the Beaufort and Chukchi Sea areas of the arctic and its
relation to the hydrography. Arctic Inst. N. Amer. Tech. Paper No. 1, 32 p.

1963. Zooplankton collected from the high Polar Basin with special reference to
the Copepoda. Limnol. Oceanogr. 8: 89-102.

Arctic Euphausiacea 79

JONES, L. T., D.C. T. FORSYTH and G. A. COOPER
1967. The occurrence of the two-spined form of Thysanoessa inermis (Crustacea:
Euphausiacea) in the North Sea. Bull. Mar. Ecol. 6: 181-184.

KR@YER, H.

1846. Atlas des Crustacés, In Voyages de la Commission scientifique du Nord en
Scandinavie, en Laponie, au Spitzberg et aux Ferée pendant les années
1838, 1839, et 1840 sur la corvette la Recherche, commandée par M.
Fabvre. Publiés par ordre du Roi sous la direction de M. Paul Gaimard,
Paris, A. Bertrand, (not seen).

MOHR, J. L.

1959. Marine biological work. Jn V. Bushnell, (ed.), Scientific studies at Fletcher's
Ice Island, T-3 (1952-1955). U. S. Air Force Cambridge Research Center,
Bedford, Mass. Geophysical Research Paper 63, 1: 83-103. (AFCRC-54-
59-232 (1).)

NEMOTO, T.
1966. Thysanoessa euphausiids, comparative morphology, allomorphosis, and
ecology. Sci. Rep. Whales Res. Inst., Tokyo, No. 20: 109-155.

PONOMEREVA, L. A.

1957. Distribution of Euphausiacea in the far eastern seas (Bering, Okhotsk,
Japan and East China). (In Russian). Acad. Nauk SSSR, Comptes Rendus
(Doklady), 114: 1214-1216.

1959. Euphausiids of the Bering and Okhotsk Seas. Acad. Nauk SSSR, Inst.
Okeanologii Trudy, 30: 115-147.

1963. Euphausiids of the North Pacific their distribution and ecology. Akad.

Nauk SSSR. Institut Okeanologii. Trans. by Israel Program for Scientific
Translations, Jerusalem, 154 p.

SARS, G. O.
1900. Crustacea. /n F. Nansen, (ed.), The Norwegian North Polar Expedition
1893-1896, 1(5): 1-137.

SCHMITT, W. L.

1919. Crustacea. Part B: Schizopod crustaceans. Rep. Canadian Arctic Exped.
1913-18, 7: 1-8.

SHIRLEY, W. D.

1966. The medusae, siphonophores, and ctenophores of the central Arctic Ocean
taken from the track of the drifting stations ARLIS I and ARLIS II. Mas-
ters Thesis, Univ. S. Calif.

TIBBS, J. F.
1967. On some planktonic Protozoa taken from the track of the drift station
ARLIS I, 1960-1961. Artic, 20: 247-254.

ZENKEVITCH, L. A.
1963. Biology of the seas of the U. S. S. R. Trans. by S. Botcharskaya, Inter-
science, New York, 955 p.

Accepted for publication April 4, 1968.

THE TERRESTRIAL MOLTING BEHAVIOR OF THE CRAB
GRAPSUS GRAPSUS TENUICRUSTATUS*

JENS W. KNUDSEN

Pacific Lutheran University
Tacoma, Washington 98447

INTRODUCTION

The molting process of the crab Grapsus grapsus tenuicrustatus differs
from records of other grapsoid crabs and other true crabs as well. Con-
versely, this process does compare with the Alaskan King crab, Paralith-
odes cumchatica, which is an anomuran rather than a brachyuran
species.

METHODS AND MATERIALS

While on research at Eniwetok Atoll of the Marshall Islands the writer
had occasion to examine hundreds of unaltered exuvia of this grapsoid
species. Conveniently, this crab molts (chiefly at night) while perched on
top of a rock above the waters edge. The dactylae of all walking legs are
used to firmly grip the coarse texture of the rock. When the crab has
emerged from its exoskeleton, it leaves the unwanted exuvium “grasp-
ing” the rock surface exactly as it was when molting was completed.
This paper is based on the examination of hundreds of perfect exuvia of
both sexes of this crab.

OBSERVATIONS AND DISCUSSION

The exuvia of Grapsus grapsus tenuicrustatus show an unusual feature
in molting: (1) notably the split of the median portion of the ventral
thoracic wall, (2) which permits a leg shift, and (3) facilitates the exit of
the molting crab from its old exuvium. The typical brachyuran molting
pattern consists of a (1) passive phase (the removal of selected skeletal
salts), (2) an active phase (exoskeleton rupture and ecdysis), and (3) a
physiological phase (secretion of salts to form a new exoskeleton).
Grapsus grapsus tenuicrustatus shows clearly that it undergoes a
passive phase of molting. This is evidenced by the (1) reduction of the
endosternites and endopleurites to a state where they no longer inhibit
the free exit of the old exoskeleton, (2) a reduction and weakening of
the carapace at the epimeral lines, and (3) the removal of skeletal salts

* Supported by NSF Grant GB2412

80

Molting in Grapsus grapsus 8I

at the site of the “reabsorption lines”: on the merus, basi-ischium, and
coxa of both chelipeds. In this respect G.g. tenuicrustatus resembles
Pachygrapsus crassipes (Hiatt, 1948) in its molting pattern as well as
the xanthid crabs Cycloxanthops novemdentatus, Paraxanthius taylori,
Lophopanopeus 1. leucomanus (Knudsen, 1957) and others.

However, a fourth (4) and critical aspect here, which must take place,
is that of a weakening by skeletal salt reduction, of the arthrophragms
which partition the muscle mass between pereiopods two and three (or
walking legs one and two if the chelipeds are not counted), and of the
ventral-median endo-exoskeleton from a point between pereiopods two
and three back to the posterior edge of the carapace.

Due to this last facet of the passive phase of molting of G.g. tenui-
cruStatus, the active phase is also quite different and unlike the act,
given in detail by many works for other brachyurans (Drach, 1939, on
Maia squinado, Pearson, 1908 and Williamson, 1903, for Cancer pagu-
rus, and Hiatt, 1948, and Knudsen, 1957).

From the appearance of the exuvia of this species one may assume
that the active phase is, for the most part, typical of other brachyurans.
That is, the split of the carapace along the epimeral line shows that the

Figure 1. Ventral aspect of the Grapsus grapsus tenuicrustatus exuvium showing
the “T” split and the leg shift which lessens the angle of leg extraction.

82 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

carapace becomes free, posteriorly and laterally, becomes elevated and
permits the rapid expansion and swelling of the body, both dorsally,
laterally, and posteriorly. However, this swelling must also account for
the unique rupture of the ventral thoracic wall in the “T” pattern, as
shown in Figure I, and the shift of the ventral thoracic halves to a more
fronto-lateral position. This shift lessens the angle of extraction of the
walking legs and thus greatly eases the molting of the long limbs. A
more drastic “leg shift” has been recorded by Knudsen (1958) for the
Alaskan king crab, an anomuran. Both the king crab and Grapsus g.
tenuicrustatus are long limbed and both could benefit by the reduction of
friction and drag.

It is curious that the molting pattern in question and that of the
anomuran should be similar when it does not resemble other known
true crabs. The king crab visibly absorbs water into the abdomen (puff-
tail phase of the pre-molt cycle), contracts the abdomen forcing a huge
volume of blood into the thorax and thereby splits all the lines of re-
absorption. This is followed by a parting of the ventral portion of the
thoracic skeleton on the median line and the shift of the leg position to
facilitate extraction.

A series of exuvia of other common Eniwetok grapsids show that
such a split and leg shift is not part of their molting pattern. Eighteen
dry exuvia of Percnon planifrons, two Percnon abbreviatum, seven
Plagussia speciosa and three Grapsus longitarsus revealed that the ven-
tral thorax was perfectly normal and not split. After soaking these in
seawater for 36 hours the Plagussia speciosa exuvia showed a marked
softening of the ventral median thoracic line had taken place but no
evidence of a leg shift was found in that the halves of the ventral exo-
skeleton were in perfect position relative to themselves and to the cara-
pace.

Hundreds of drift exuvia of Hemigrapsus oregonensis and nudus
from Puget Sound, Washington, show no shift. Hiatt (1948) speaks of a
removal of skeletal salts in Pachygrapsus crassipes but mentions no
shifting of the legs. It would seem that this phenomenon is rare in bra-
chyurans if not peculiar to G.g. tenuicrustatus.

The G.g. tenuicrustatus exoskeleton shows that molting is normal
for the brachyuran pattern with respect to the chela. Salts are removed
from the reabsorption line on the chela so that an entire panel of exo-
skeleton can move away enlarging the passage. The massive hands are
then slipped through the otherwise small and restrictive basal segments.
The California Xanthid crabs (Knudsen, 1957) and others, shut off the
flow of blood to the chela at the time of exuvation so that the hands,

Molting in Grapsus grapsus 83

being momentarily bloodless, shrink considerably and easily slide out
of the old exoskeleton.

By observing exoskeletons, however, one can not learn the nature of
rhythmic muscle movements which, together with the swelling, help
move the self-lubricated crab backwards and out of its old exoskeleton.
Normally the wiggling, plus the pressure of swelling (placed as a force
against the old exoskeleton) propel the crab slowly from its former
skeleton. The pressure and propulsion is akin to propelling a wet bar of
soap by squeezing it, except that in this case the pressure is applied by
the crab, from within, against the stationary and unyielding exoskeleton.

Most of the exuvia of G.g. tenuicrustatus are found on rocks near
the waterline (a few of which may have been covered during a high tide
period) while others are found on rocks or other objects (old World War
II landing craft, etc.) which are four or five feet above the high tide level.
Thus, while these observations shed some light on the comparative
molting picture, they fail to explain the source of water for animals
molting out of the water. It is believed that a behavioral pattern has
evolved where G.g. tenuicrustatus takes an excess of fluid into the blood
stream to a point of bodily distention and exoskeleton rupture. Then
the crabs crawl to a perch above water, contracting the body so as to
rupture the exoskeleton. Next, the tips of the walking legs are hooked
into place on the substratum with the body generally arranged with the
posterior side down. In the absence of water, the body weight of the
molting animal reacts to gravity, which together with alternate dnd
rhythmic contractions of the well lubricated body, propels the crab from
its exuvium. Slopes of molting sites may rarely reach 60 degrees, but are
often less than 20 degrees.

In contrast, newly molted Grapsus longitarsus together with their
exuvia, occasionally have been found in shallow tidepools of 10 to 21
inches in diameter at the high tide level. Since no exuvia of this species
are found in situ above the high tide level it is assumed they have not
evolved terrestrial molting, but approach this in their behavior. Strictly
terrestrial grapsids, Geograpsus grayi (numerous records) and G. crini-
pes (only one record) are similarly found in a newly molted condition
hiding under large beach rocks above the intertidal zone, where they
presumably take refuge after molting in water.

The survival value of molting out of water or moving out of water
shortly after molting is apparent. Molters give off chemical substances,
at least as lubricants, which attract fishes and fellow crabs. Large molt-
ing G.g. tenuicrustatus have been observed being pulled across the beach
and under rocks by members of its species which eventually ate the

84 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

live molter. Moray eels hunt this species relentlessly both in and out of
the water while fish frequently dart into shallow water to capture injured
crabs (or molters?) which bleed into the water. Terrestrial molting
avoids much of this.

CONCLUSIONS

Grapsus grapsus tenuicrustatus (1) is apparently a land molter, which
(2) utilizes a ventral-median thoracic split in the exoskeleton and sub-
sequent shift of the leg position which (3) facilitates leg extraction in an
air medium. These phenomenon are apparently peculiar to this brachyu-
ran species.

LITERATURE CITED

DRACH, P.
1939. Mue et cycle d’intermue chez les Crustaces decapodes. Ann. I'Inst.
Oceanog., ns 19:106-377.

HIATT, R. W.
1948. The biology of the lined crab Pachygrapsus crassipes Randall Pacific Sci.,
2:134-213.

KNUDSEN, J. W.
1957. The act of molting in the California Xanthidae, the pebble crabs. Bull. So.
Calif. Acad. Sci., 56:133-141.

PEARSON, J.
1908. Cancer (the edible crab). Liverpool Biol. Soc. Trans., 22:291-499.

WILLIAMSON, H.C.

1903. Contributions to the life histories of the edible crab, Cancer pagurus, and
of other decapod Crustacea; impregnation spawning, casting, distribution,
rate of growth. Rept. Fisheries Bd., Scotland. 22:100-140.

Accepted for publication February 27, 1968.

THE PINNOTHERES CONCHA RUM COMPLEX
(CRUSTACEA, DECAPODA, FAMILY PINNOTHERIDAE)

EDWARD S. DAVIDSON

Smithsonian Institution
Washington, D. C.

INTRODUCTION

A critical examination of the specimens of Pinnotheres concharum
(Rathbun) in the collections of the U. S. National Museum reveals that
the males of at least two different species of Fabia have not been recog-
nized. The species of Fabia here in question are Fabia subquadrata Dana
and Fabia lowei Rathbun. Wells in 1928 synonymized all males of
Pinnotheres concharum with Fabia subquadrata. These males and the
immature females found with them represent both Fabia subquadrata
and Fabia lowei. Fabia lowei, because of the earlier specific designation
of its males and immature females, must now be known as Fabia con-
charum (Rathbun).

The holotype of Pinnotheres concharum, originally Cryptophrys
concharum, is an immature female of 5.0 mm. in carapace width. Syn-
onymies, revised diagnoses of the females of the species, and prelimi-
nary descriptions of the males follow.

Fabia subquadrata Dana
Figure 1, A, D, G, H

Type locality. — Puget Sound; Holotype not extant.

Fabia subquadrata Dana 1851:253; Rathbun 1918:102-103; Wells
1928:286-289, includes all males of Pinnotheres concharum.

Cryptophrys concharum Rathbun 1893:250, part: not specimens from
San Diego (USNM 17498).

Raphonotus subquadratus Rathbun 1904:186, part: not specimen from
Monterey.

Pinnotheres concharum Rathbun 1918:86-87, part: USNM Nos. 49628,
39129, 17502, 18410, 23929 only; USNM 45611 lost; specimen
from Stewarts Point, California not seen.

Diagnosis of female. — Front sharply deflexed with transverse sulcus

across vertical front between orbits; manus of cheliped widening distally,

bearing two rows of hair along lower margin.

Description of male. — Carapace subhexagonal, hard, dorsally flat-

tened; antero-lateral and fronto-orbital margins bearing a continuous

85

86 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

E E G H

Figure 1. Fabia subquadrata Dana and Fabia concharum (Rathbun). A. Third
maxilliped, x 30, Fabia subquadrata; B. Third maxilliped, x 30, Fabia concharum;
C. Right ¢ Gonopod, x 30, Fabia concharum; D. Right ¢ Gonopod, x 30, Fabia
subquadrata; E. 9 Abdomen, x 15, Fabia concharum; F. $ Abdomen, x 15, Fabia
concharum; G. 2? Abdomen, x 15, Fabia subquadrata; H. $ Abdomen, x 15, Fabia
subquadrata.

Pinnotherid Crabs 87

margin of short, dense pubescence; posterior margin convex; frontal

margin projected, medially sulcate beneath pubescence; orbits large,

directed laterally.

Chelae with manus bearing a dense pubescence on upper and lower
margins; immovable finger bearing a large serrate lobe on upper margin;
movable finger bearing one large, proximally directed tooth on lower
margin, upper margin bearing a tuft of dense pubescence.

Ambulatory legs with segments flattened, margins densely pubescent.
Dactyli large, sub-equal, curved.

Abdomen with terminal segment semi-circular, lateral margins of
penultimate segment distally depressed.

Measurements. — 3 USNM 74898: length of carapace 4.5 mm., width
of carapace 5.1 mm.; USNM 23928: length of carapace 9.1 mm.,
width of carapace 11.1 mm.

Range. — Akutan Pass, Alaska to La Jolla, California.

Habitat.. — Reported hosts (from various authors): intertidal to 200

m., in Strongylocentrotus purpuratus, Modiolus modiolus, Mytilus

californianus, Venericardia ventricosa, Styela gibbsii, Mya arenaria,

Mytilus edulis, Cardita borealis, Saxidomus giganteus, Tapes, Pachy-

desma crassitelloides, Echini.

Fabia concharum (Rathbun)
Ieepuee I, 18s, (Ca Bh, 18

Type locality. — San Diego Bay, California; Holotype, immature ?
USNM 17498.

Cryptophrys concharum Rathbun 1893:250, part: not specimens from
Puget Sound (USNM 17502).

Raphonotus lowei Rathbun 1900:590.

Fabia lowei Rathbun 1918:104-105.

Pinnotheres concharum Rathbun 1918:86-87, part: USNM Nos. 17498,
25428, 50443 only; USNM 45611 lost; specimen from Stewarts
Point, California not seen.

Diagnosis of female. — Front sharply deflexed, lacking transverse
sulcus across vertical front between orbits; manus of cheliped not widen-
ing distally, bearing one row of hair along lower margin.
Description of male. — Similar to F. subquadrata. Differing in that the
terminal segment of the abdomen widens distally with distal margin
slightly deflexed; sixth segment of abdomen hairless with margins sub-
parallel; immovable finger bearing two small teeth or lobes on upper
margin; propodus of third maxilliped subtriangular with sharp outer
distal angle produced beyond the gently rounded inner distal angle;
gonopods more curved and more slender near the base than in F. sub-
quadrata.

88 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

Measurements. — 6 USNM 50443: length of carapace 3.0 mm., width
of carapace 2.9 mm.; ¢ USNM 23437 (cotype): length of carapace
10.0 mm., width of carapace 12.5 mm.

Range. — San Pedro, California to Magdalena Bay, Baja California.

Habitat. — Reported hosts (from various authors): Modiolus modiolus,

Modiolus capax, Parapholas californica, Bornea pacifica, Pachydesma

crassatelooides, Tapes, Donax levigatus, Mya californica.

LITERATURE CITED

DANA, J. D.

1851. Conspectus Crustaceorum quae in Orbis Terrarum circumnavigatione,
Carolo Wilkes e Classe Reipublicae Foederatae Duce. Proc. Acad. Nat.
Sci. Phila. 5:253.

RATHBUN, M. J.
1893. Descriptions of New Genera and Species of Crabs from the West Coast
of North America and the Sandwich Islands. Proc. U.S. Nat. Mus., 16:250.

1900. The Catometopous or Grapsoid Crabs of North America. Amer. Nat.,
34:590.

1904. Decapod Crustaceans of the northwest coast of North America. Harriman
Alaska Exped., 10:186.

1918. The Grapsoid Crabs of America. U. S. Nat. Mus. Bull. 97:102-103.

WELLS, W.
1928. Pinnotheridae of Puget Sound. Publ. Puget Sound Biol. Sta., No. 6:286-289.

Accepted for publication February 27, 1968.

STUDIES OF THE BLOOD OF ASCIDIA NIGRA
(SAVIGNY). III]. SOME ASPECTS OF THE BIOCHEMISTRY
OF VANADOCYTE AGGLUTINATION

JAMES A. VALLEE, JR.

Department of Biology
California State College
Long Beach, California

INTRODUCTION

The agglutination of the blood cells of Ascidia nigra was first described
by Hecht (1918). He showed that agitation of A. nigra caused the blood
cells to agglutinate, and that the agglutination process normally reversed
itself after fifteen or twenty minutes. He theorized that agglutination was
caused by the secretion of some substance into the blood, while Fulton
(1920) suggested that this substance was secreted by the blood cells.

Recent work has indicated that sulfhydryl groups take an active part
in the agglutination of the blood cells of several species. Bryan et al.
(1964) showed that a sulfhydryl group inhibitor prevented agglutination
of hemocytes of Limulus polyphemus. Also, Boolootian and Giese
(1959) showed that agglutination of the cells of the coelomic fluid of
several echinoderms was calcium-independent and inhibited by — SH
binding reagents. Gregoire (1953) showed that a low pH occasionally
causes a decrease in the coagulation of insect hemolymph, while a pH
of 9.45 increased coagulation. A considerable amount of work has also
been done on the agglutination of mammalian platelets. The process is
calcium dependent and can be started by the addition of adenosine
diphophate (Born, 1962, Gaarder and Laland, 1964). Through the use
of reagents which block sulfhydryl groups, it has been shown that intact
— SH groups are also essential (Robinson ef al., 1963).

It was therefore decided to study the effects of pH, sodium citrate,
and sulfhydryl group reagents upon the agglutination of the vanadocytes
of A. nigra.

MATERIALS AND METHODS

Animals were collected from sea walls on Key Biscayne, Florida, and
placed in an aquarium with running sea water.

The effects of the — SH group of cysteine on agglutination was deter-
mined as follows. Three solutions were prepared: (1) phosphate buffer
(pH 6.7); (2) a solution of cysteine made up in the phosphate buffer; and
(3) a solution composed of equimolar concentrations of cysteine and

89

90 Bulletin So. Calif. Academy Sciences |Vol.67, No. 2, 1968

iodoacetic acid (which blocks the — SH group of cysteine) made up in
the phosphate buffer. The effects of 0.002 M, 0.004 M, 0.006 M,
0.008 M, 0.010 M, and 0.014 M cysteine, and cysteine-iodoacetic acid
were determined. At each molar concentration, 2 ml of buffer control,
the cysteine solution, and the cysteine-iodoacetic acid solution were
placed separately into three matched test tubes. The visceral vessel of a
tunicate was then punctured and one ml of blood allowed to flow into
each of the three test tubes, which were graduated in milliters. The per
cent transmittance of the three tubes was then measured at 550 mu with
a Coleman Junior spectrophotometer after one minute, ten minutes, and
every five minutes thereafter for one hour. A distilled water blank was
used. As the cells agglutinated they formed a tight ball which sank to the
bottom out of the optical pathway, thus increasing the transmittance of
the supernatant fluid. Elevated transmittance values indicated a high
degree of agglutination. The test tubes were agitated after each reading
to prevent the settling of individual cells, and to resuspend cells liberated
when the processes of agglutination are reversed. The effects of each
molar concentration were determined on five animals. The results were
then averaged and graphed for each molar concentration. In order to
graph the effects of increasing concentrations of cysteine on agglutina-
tion, the difference between the transmittance of the buffer control and
the cysteine solution was calculated for the ten minute reading. This was
done for each molar concentration, and the figures obtained plotted
against the molar concentrations of cysteine used. The effect of sodium
citrate on the agglutination of vanadocytes was also studied. Two solu-
tions were used in this study: (1) the isotonic phosphate buffer control
described above, and (2) 0.02 M sodium citrate, made up in the buffer.
One ml of each solution was placed separately into two matched test
tubes, one ml of blood added to each, and the per cent transmittance of
each determined as described above. The effects were observed on five
animals, and the results averaged and graphed.

The effect of pH on agglutination was determined as follows: 0.54 M
NaCl was adjusted to pH 8.3 with solium bicarbonate, and to pH 5 and 2
with HCl. Two ml of each solution were then placed separately into three
matched test tubes, one ml of blood added to each, and the per cent
transmittance of each recorded periodically as described above. The
effects were observed on five animals, and the results averaged and
graphed.

OBSERVATIONS AND RESULTS

The effects of 0.002, 0.004, 0.006, 0.008, 0.010, and 0.014 cysteine on
the agglutination of the vanadocytes are shown in Figures | through 6.

Tunicate Blood gI

20 40 60
time in min.

PO. 40 60
time in min.

Figure 1. The effect of 0.002 M cysteine ( ), 0.002 M cysteine plus 0.002
M iodoacetic acid (— —), and phosphate buffer (---) on agglutination.

Figure 2. The effect of 0.004 M cysteine ( ), 0.004 M cysteine plus 0.004 M
iodoacetic acid (— —), and phosphate buffer (---) on agglutination.

Figure 3. The effect of 0.006 M cysteine ( ), 0.006 M cysteine plus 0.006 M
iodoacetic acid (— —), and phosphate buffer (---) on agglutination.

92 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

time inmin.

Figure 4. The effect of 0.008 M cysteine ( ), 0.008 M cysteine plus 0.008 M
iodoacetic acid (— —), and phosphate buffer (---) on agglutination.

Figure 5. The effect of 0.010 M cysteine ( ), 0.010 M cysteine plus 0.010 M
iodoacetic acid (— —), and phosphate buffer (---) on agglutination.

Figure 6. The effect of 0.014 M cysteine ( ), 0.014 M cysteine plus 0.014 M
iodoacetic acid (— —), and phosphate buffer (---) on agglutination.

Tunicate Blood

0.002 0.006 OOIO0 O.0I14
M cysteine

20 40 60
time in min.

Figure 7. The inhibitory effect of increasing concentrations of cysteine on ag-
glutination.

Figure 8. The effect of 0.02 M sodium citrate ( ), and phosphate buffer (---)

on agglutination.

Figure 9. The effect of pH 2.0 (
agglutination.

), pH 5.0 (— —), and pH 8.3 (---) on

94 Bulletin So. Calif. Academy Sciences |Vol.67, No. 2, 1968

These Figures also show that, at all concentrations, the equimolar solu-
tion of cysteine and iodoacetic acid had no effect on agglutination. Thus,
the graphs showing the effects of the cysteine-iodoacetic acid solution
are quite similar to the graphs showing the effects of the buffer control.
It is also apparent that 0.002 M cysteine had little inhibitory effect on
agglutination. However, as increasing concentrations of cysteine are
used the per cent transmittance (at ten minutes) decreased from 76 per
cent with 0.002 M cysteine to 32 per cent with 0.014 M cysteine.

Figure 7 shows the increasing inhibitory effects of the higher concen-
tration of cysteine on agglutination. It should be pointed out that, in all
cases, the vanadocytes gradually become unagglutinated, and at the end
of one hour very few aggregates of cells remain. This reversal of the
agglutination process also takes place in the animals, as described above.

The effect of sodium citrate on the agglutination of vanadocytes is
shown in Figure 8. Agglutination occurs normally.

The effects of pH on agglutination are presented in Figure 9. Al-
though agglutination takes place normally at pH 8.3 and 5, the reversal
of the agglutination process is somewhat inhibited at pH 8.3. At pH 2
agglutination is markedly inhibited, occurring only slowly over a period
of one hour, and even then only achieving slight agglutination.

DISCUSSION

It was reported above that cysteine prevents the agglutination of vana-
docytes, and that this effect can be counteracted by blocking the — SH
of the cysteine with iodoacetic acid, before adding the blood sample to
the reagent. It was also found that the agglutination of vanadocytes is
normally reversible, but its reverse is inhibited by a high pH (8.3) and
agglutination is inhibited by a low pH (2.0). The effect of sodium citrate
indicates that calcium plays no role in the agglutination process.

The simplest explanation of the agglutination process, based on the
above observations, is that in normal unagglutinated blood the vana-
docyte cell membranes contain cysteine with — SH groups protruding
from the cell surface. Agglutination would involve the formation of
disulfide links between adjacent cells. The formation of such disulfide
bonds is known to be reversible, as is agglutination of vanadocytes. The
addition of free cysteine to the blood prevents agglutination because the
— Sh group of the free cysteine reacts with all or most of the — SH
groups of the cysteine in the cell membrane, thus preventing the — SH
groups of adjacent cells from reacting with each other. However, if the
— SH group of the free cysteine is first blocked with iodoacetic acid, its
— SH group is no longer available to react with the — SH groups of the

Tunicate Blood 95

cell membranes. The vanadocytes are thus able to form disulfide bonds
with adjacent cells and agglutinate normally.

The observed effects of pH would be expected under the agglutination
theory described above. A low pH prevents agglutination by keeping the
— SH groups reduced. A high pH inhibits the reversal of the agglutina-
tion process by preventing the reduction of the disulfide bonds between
cells.

Agglutination in Ascidia nigra is initiated when the cells and blood
vessels of the test become damaged. This suggests that some substance,
possibly an enzyme catalyzing the oxidation of cysteine to cystine (i.e.,
the formation of disulfide bonds) is released from damaged cells, causing
agglutination of the vanadocytes.

SUMMARY

Cysteine was shown to inhibit the agglutination of vanadocytes, as does
a low pH (2.0). A high pH (8.3) inhibits the reversal of agglutination.
The possible significance of these observations is discussed.

LITERATURE CITED

BOOLOOTIAN, R. A., and A. G. GIESE
1959. Clotting of echinoderm coelomic fluid. Exp. Zool., 140: 229.

BORN, G.V.R.
1962. Aggregation of blood platelets by adenosine diphosphate and its reversal.
Nature, Lond., 194: 927.

BRYAN, F. T., C. W. ROBINSON, JR., C. P. GILBERT and R. D. LANGDELL
1964. N-ethylmaleimide inhibition of horseshoe crab hemocyte agglutination.
Science, 144: 1147-1148.

FULTON, J. F.
1920. The blood of Ascidia atra Lesueur; with special reference to pigmentation
and phagocytosis. Acta Zoologica Stockholm, |: 381-433.

GAARDER, A. and S. LALAND
1964. Hypothesis for the agglutination of platelets by nucleotides. Nature, Lond.,
202 (4935): 909-910.

GREGOIRE, C. H.
1953. Blood coagulation in arthropods. III Reactions of insects hemolymph to
coagulation inhibitors of vertebrate blood. Biol., Bull. 104: 372-393.

HECHT, S.
1918. The physiology of Ascidia atra Leseur. II] The blood system. Amer. J.
Physiol., 45: 157-187.

ROBINSON, C. W., R. G. MASON and R. H. WAGNER
1963. The effect of sulfhydryl inhibitors on platelet agglutinability. Proc. Soc.
Exp. Biol. Med., 113: 857-861.

Accepted for publication March 15, 1968.

ADAPTATIONS IN MOVEMENT PATTERNS OF
TWO SPECIES OF SALT-MARSH RODENTS

GEORGE F. FISLER

Department of Biology,
San Fernando Valley State College, Northridge, Calif.

INTRODUCTION

Knowledge of normal day-to-day movements of small mammals occu-
pying less favorable habitats may be advantageous in studies of popula-
tion dynamics. Utilization of such habitats by individuals possibly differs
from use of more optimum areas within the range of the species. Because
of severe restrictions placed on rodents, the salt marshes of San Francis-
co Bay could be considered marginal habitat. Still, several species of
small mammals live successfully within these marshes and two of these
are endemic (Hooper, 1944; Rudd, 1955). Populations of other species
may or may not have reached sufficient morphological differentiation
from upland populations to be considered distinct subspecies (Hooper,
1944; Thaeler, 1961). The most common mice found in these marshes
are the California vole, Microtus californicus, and the salt-marsh har-
vest mouse, Reithrodontomys raviventris. The vole is widespread in
grasslands as well, but the salt-marsh harvest mouse is endemic to
marshes (Hooper, 1944; Fisler, 1965). The purpose of this paper is to
compare movements of these mice in salt marshes with data from grass-
land studies (Brant, 1962) and to comment on certain adaptations to salt
marshes.

METHODS AND RESULTS

Data on movements of mice were gathered from January, 1959, through
May, 1960, primarily through use of three grids of nest boxes and live
traps. Trap and box spacing was 45 feet (13.7 meters) with each grid
encompassing about 2.1 acres (0.85 hectares). A few data from live trap
line transects have been included. Preliminary analysis disclosed no
difference between grid and transect data (trap spacings identical). Data
have been compiled using the concept of the “average maximum dis-
tance between captures” (av. M) and the “average distance between
successive captures” (av. D) conceived by Brant (1962). The two study
areas, about eight miles apart, were in Tilden Regional Park near Berke-
ley (Brant) and in San Pablo salt marsh near Richmond (this study), both
in Contra Costa County, California.

96

Movement Patterns in Rodents 97

Because there is evidence that major seasonal movements of popu-
lations of R. raviventris from low to high areas and return are made
within the marshes (Dixon, 1908; Fisler, 1965), data only for summer
and winter trapping were utilized. However, there is no evidence for
such movements of Microtus. Indications are that these voles remain on
their home ranges even during high tides that force them to swim for
long periods (Fisler, 1961). Also, Harris (1953) has found no evidence
indicating large-scale movements of Microtus pennsylvanicus to higher
land during high tides. Therefore, data from all times of the year were
used for Microtus.

Microtus and Reithrodontomys do not occupy all areas within a
marsh. Unpublished evidence of the author shows that Microtus is absent
from certain lower parts of the marshes, although R. raviventris is pre-
sent. Neither species occupies the lowest zones (Spartinetum of Hinde,
1954). Also, whereas some marshes contain many voles, others contain
few or none at all. Greenwald (1957) noted that “‘some Microtus lived in
Salicornia or wandered into it” in his study in Marin County. Thaeler
(1961) has commented on the grouping of Microtus about dikes and
embankments in certain marshes. Microtus, therefore, occupies only
certain marshes, and only higher areas or low Salicornia areas in those
marshes inhabited. Reithrodontomys raviventris is widespread in salt
marshes and is absent only from the smallest of these or those that have
been heavily altered by human activity.

Population densities of both species apparently were constant during
my study. Brant’s data were taken during several different population
densities with a peak reaching about 25 animals per acre (10.1 per hec-
tare) for Microtus and 12 per acre (4.8 per hectare) for Reithrodon-
tomys megalotis, the upland relative of the salt-marsh harvest mouse.
My figures for density of Microtus in salt marshes during this study
indicate about 12 to 14 animals per acre (4.8-5.7 per hectare) computed
by the Lincoln index method. Although Getz (1961) has found that
home range size varied inversely with density for M. pennsylvanicus
in a fresh-water marsh, this does not have relevance here as densities did
not vary during my study period and presumably Brant’s data would
average out should range vary with density in M. californicus.

In his analysis, Brant (1962) stated that 50-foot (15.2-meter) trap
spacings resulted in capture of only those individuals with larger home
ranges, so presumably my data from 45-foot (13.7-meter) trap spacings
also show mostly those animals with the larger ranges. In the grassland,
Brant considered that 60 feet (18.3 meters) was the best estimate of the
average maximum distance between capture points for Microtus. Com-
parison of my data with his for the 50-foot (15.2-meter) spacings reveals

Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

98

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Movement Patterns in Rodents 99

a fourfold increase in range of the salt-marsh Microtus over the grass-
land dwellers (Table 1).

Brant (1962) presented extensive data for R. megalotis compared by
sex, but my data are insufficient to analyze by sex. However, a compari-
son of data derived from both sexes of R. megalotis with similar data
from R. raviventris shows that movements of the latter (excluding pos-
sible seasonal migrations) are similar to distances moved by R. mega-
lotis (Table 1). In general, my figures for both sexes combined fall be-
tween the figures given for each sex by Brant. The sets of data compared
were both drawn from the results of 45-(13.7-) and 50-foot (15.2-meter)
trap spacings. However, if one compares my data with that of Brant
collected on smaller grids, including shorter trap spacings, R. raviventris
ranges much more widely than does R. megalotis. I must assume, as did
Brant, that longer trap spacings yield results from more widely ranging
individuals and that if my spacings had been shorter, movements of R.
raviventris would have been less and comparable to the movements of
R. megalotis. These two species of harvest mice have nearly similar day-
to-day movement patterns as far as distance traveled is concerned, even
though occupying quite different habitats.

The average distance between successive points of capture supports
the preceding. For both sexes of Microtus, av. D was 115 feet (35.1
meters) compared with a figure of 26 feet (7.9 meters) obtained by
Brant. Similarly, for R. raviventris, av. D was 122 feet (37.2 meters)
whereas Brant found for R. megalotis a figure of 106 feet (32.3 meters)
for males, 119 feet (36.3 meters) for females, and 108 feet (32.9 meters)
for the sexes combined. This latter figure is only slightly smaller than
my figure. Brant also computed movement ratios utilizing av. D and av.
M values, assigning Microtus a value of 1 and comparing the distances
moved by Reithrodontomys to this. His figures for av. D were 1:4.15
and for av. M 1:3.75. My comparable figures are 1:1.06 and 1:1.08,
respectively. Again, these ratios point out the comparability of the
movement patterns of the two species of harvest mouse but the longer
distances traveled by the marsh-dwelling Microtus.

DISCUSSION

The significance of the greater movement of salt-marsh Microtus, yet
nearly the same patterns for the two species of harvest mice, is at first
obscure. Presumably this significance is related to requirements of in-
dividuals in obtaining essentials for successful living in a marsh.
Reithrodontomys raviventris has solved these basic problems by adapt-

100 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

ing significantly in many ecological, physiological, behavioral, and
morphological characters (Fisler, 1965), whereas maintaining only a
slightly larger range of movement in the marsh than R. megalotis has in
the grassland. The marsh is optimum habitat for R. raviventris and this
species probably could not live outside of it (Fisler, 1965). Microtus has
not solved the marsh problems as well, probably because gene flow still
exists between upland and marsh populations. According to the usual
concept of vertebrate speciation (Mayr, 1963), to become a permanently
adapted species in any habitat (salt marsh in this case), a population
must be spatially isolated from adjacent populations (uplands here) in
order to develop the requisite new adaptations. Such isolation has not
occurred in the marshes for M. californicus as it has for R. raviventris
and salt marshes are suboptimum or “marginal” habitats for Microtus.

A definition for a “marginal” habitat does not seem clear. Kendeigh
(1961) accepted three zones of abundance in distribution patterns re-
lated to habitat; an inner zone of normal abundance (high population),
a zone of occasional abundance (population low but may be high in some
years), and a zone of possible abundance (species not permanently pre-
sent, but occurring in favorable years). Odum (1959) stated that intra-
specific competition brings about wider habitat choice in a species if the
interspecific competition is negligible. Neither of these concepts spe-
cifically describes what a marginal habitat is, yet both state or imply
that there are areas where a species is less likely to exist on the edges of
its range. Indeed, this is ““ccommon knowledge.” The term “marginal
habitat” as used frequently connotes an area of less favorability and
lessened abundance.

How, then, should the relationship between Microtus and a salt-
marsh habitat be described? Microtus californicus apparently has no
graminivorous competitors in the salt marshes of San Francisco Bay (R.
raviventris eats some seeds) and so can occupy certain of them with
regularity (zone of occasional abundance of Kendeigh and forced to that
area by intraspecific competition in the grassland with little interspecific
competition in the marshes). Yet it seems that Microtus californicus is
better adapted to grassland, its more characteristic habitat. Getz (1961)
has stated the M. pennsylvanicus selected areas of graminoids over other
areas. By inference, this is also true of M. californicus for, if one com-
pares grasslands with adjacent marshes, M. californicus is invariably
present in the grassland but may be rare or absent from some of the salt
marshes of the San Francisco Bay area, whereas it is common in others
there. Perhaps, since less favorable areas presumably have less of the
requirements for a rodent population, a marginal habitat could be an
area where a species is regularly present but must utilize more space per

Movement Patterns in Rodents IOI

individual in order to obtain all of the requirements for existence, in-
cluding food sources, nesting sites, and living space.

Other evidence has only incompletely borne out the preceding con-
clusion concerning the relationship of Microtus to a salt marsh. First,
Getz (1961) found that M. pennsylvanicus males had the same size home
range in both abandoned field and grass-sedge (fresh-water) marsh
habitats, although females occupied larger areas in the marsh. He related
this to competition for space. Second, by nature of the San Francisco Bay
area marshes, burrowing (a space requirement), except on raised areas
or upper edges of the marshes, is virtually impossible. Also, food may be
a limiting factor in marshes for Microtus californicus, primarily a grass
eater. Little grass exists in the San Francisco Bay marshes other than in
shoreward areas or on levees and hummocks. However, my trapping
records do show that Microtus utilizes areas which contain only Sali-
cornia, except deep in the marsh (extremely low areas, subject to twice
daily tidal inundation). Spartina zones are also avoided. Small piles of
cut Salicornia are frequently found in runways of M. californicus indi-
cating that these voles do use this as a food source. According to Mac-
Millen (1964), however, the chlorinity of Salicornia fluids in southern
California is about 1.75 times that of sea water. So, unless M. californi-
cus can utilize salty solutions (as can R. raviventris, Fisler, 1963;
Haines, 1964), it would appear that this vole cannot utilize much
Salicornia.

Microtus californicus in central California uplands has no significant
water-conserving mechanisms (Church, 1966) and therefore by infer-
ence would not be adapted to salt conditions in marshes. Furthermore,
they die in 5-6 days without water yet are able to live more than 100 days
on a minimal water regimen (Church, 1966). Water requirements are
probably met through green vegetation, dew, fog condensation, and rain
(in season) as is probably the case for R. raviventris (Fisler, 1965). How-
ever, recent work indicates that Microtus from marshes in southern
California can survive on salt water and laboratory chow for consider-
able periods of time (L. P. Gram, personal communication) and can
process to a degree Salicornia and perhaps other halophytes (Coulombe,
1965). In contrast, salt-marsh populations of M. pennsylvanicus have no
special adaptations to high salinities and can not tolerate salt water
strengths of only one-half that of sea water (Getz, 1966).

The adaptations of Microtus californicus to salt marshes are consider-
ably less complete than those of R. raviventris. Rather, the adaptations
of the former species more closely parallel those minimal adaptations
of R. megalotis to salt marshes (see Fisler, 1965), with the exception
that at least some populations of Microtus have a higher salt toleration

102 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

than do populations of R. megalotis of northern California. M. californi-
cus has not been isolated from upland populations so perfection of marsh
adaptations has not occurred. Instead, Microtus occupies this habitat
only through utilization of areas in the marsh where food (grass) is
present and where burrowing is possible. Utilization of the remainder of
the marsh (Salicornia areas) would appear to be only for food gathering
or living space. Salt marsh is a less favorable (marginal) habitat for
Microtus californicus and the space required to maintain each individual
is cansiderably larger than the space required for an upland individual.

SUMMARY

Movement patterns of Microtus californicus and Reithrodontomys
raviventris in salt marshes show that individuals of the former move over
roughly four times longer distances than do individuals of upland popu-
lations of the same species, whereas the well-adapted marsh species, R.
raviventris, has about the same movement patterns as does its upland
relative, R. megalotis. Microtus, then, is occupying a marginal habitat to
which it is only imperfectly adapted because marsh populations have
never been sufficiently isolated from grassland populations to allow
development of marsh characters as exhibited by R. raviventris.

LITERATURE CITED

BRANT, D. H.

1962. Measures of the movements and population densities of small rodents.
Univ. Calif. Publ. Zool., 62:105-184.

CHURCH, R. L.

1966. Water exchanges in the California vole, Microtus californicus. Physiol.
Zool., 29:326-340.

COULOMBE, H.N.
1965. An ecological study of a southern California salt marsh rodent fauna.
Unpublished Master’s thesis, Univ. Calif., Los Angeles, 141 p.

DIXON, J.

1908. A new harvest mouse from the salt marshes of San Francisco Bay, Cali-
fornia. Proc. Biol. Soc. Wash., 21:197-198.

FISLER, G. F.
1961. Behavior of salt-marsh Microtus during winter high tides. J. Mammal.,
42:37-43.

1963. Effects of salt water on food and water consumption and weight of harvest
mice. Ecology, 44:604-608.

1965. Adaptations and speciation in harvest mice of the marshes of San Francisco
Bay. Univ. Calif. Publ. Zool. 77:1-108.

Movement Patterns in Rodents 103

GETZ, L. L.
1961. Factors influencing the local distribution of Microtus and Synaptomys in
southern Michigan. Ecology, 42:110-119.

1966. Salt tolerances of salt marsh meadow voles. J. Mammal., 47:201-207.

GREENWALD, G. S.
1957. Reproduction in a coastal California population of the field mouse, Micro-
tus californicus. Univ. Calif. Publ. Zool., 54:421-446.

HAINES, H.
1964. Salt tolerance and water requirements in the salt-marsh harvest mouse.
Physiol. Zool., 37:266-272.

HARRIS, V. T.
1953. Ecological relationships of meadow voles and rice rats in tidal marshes.
J. Mammal., 34:479-487.

HINDE, H. P.
1954. Vertical distribution of salt marsh phanerogams in relation to tide levels.
Ecol. Monogr., 24:209-225.

HOOPER, E. T.
1944. San Francisco Bay as a factor influencing speciation in rodents. Misc.
Publ., Mus. Zool., Univ. Mich., 59:1-89.

KENDEIGH, S. C.
1961. Animal ecology. Englewood Cliffs, N. J.: Prentice-Hall, Inc., 468 p.

MACMILLEN, R. E.
1964. Water economy and salt balance in the western harvest mouse, Reithro-
dontomys megalotis. Physiol. Zool., 37:45-56.

MAYR, E.
1963. Animal species and evolution. Cambridge, Mass.: Harvard Univ. Press
(Belknap), 797 p.

ODUM, E. P.
1959. Fundamentals of ecology. 2nd ed. Philadelphia: Saunders, 546 p.

RUDD, R. L.
1955. Population variation and hybridization in some California shrews. Svst.
Zool., 4:21-34.

THAELER, C. S., JR.,
1961. Variation in some salt-marsh populations of Microtus californicus. Univ.
Calif. Publ. Zool., 60:67-94.

Accepted for publication March 29,1968

SEASONAL OCCURRENCE OF THE
COMMENSAL POLYCHAETOUS ANNELID
OPHIODROMUS PUGETTENSIS
ON THE STARFISH PATIRIA MINIATA

RIVIAN LANDE AND DONALD J. REISH
Department of Biology,
California State College at Long Beach,
Long Beach, California 90804

INTRODUCTION

Commensalism has been reported in the polychaete families Aphroditi-
dae, Polynoidae, Amphinomidae, Hesionidae, Pilargidae, Nereidae
and Myzostomidae. Commensal polychaetes are associated with sponges,
polychaetes, sipunculoids, echiuroids, chitons, gastropods, pelecypods,
crustaceans, asteroids, echinoids, ophiuroids, holothuroids, crinoids, -
and enteropneusts (Clark, 1956; Dales, 1957). Ophiodromus pugetten-
sis (Johnson) [ = Podarke pugettensis] is known both as a commensal
on starfish and sea cucumbers and as a free-living species (Bartel and
Davenport, 1956; Reish, 1961). It has been reported from the sea cu-
cumber Protankyra bidentata (Okuda, 1931), from the starfish Luidia
foliata Grube and Pteraster tesselatus Ives in Washington (Hichok and
Davenport, 1957), from the starfish Patiria miniata (Brandt) in southern
California (Bartel and Davenport, 1956), and from the starfish Oreaster
occidentalis Perrier and Pisaster ochraceus (Brandt) in the Gulf of Cali-
fornia (Steinbeck and Ricketts, 1941).

Ecological or experimental studies dealing with commensalism in
polychaetes have been limited to O. pugettensis and several species of
the family Polynoidae by Davenport and his associates (Davenport,
1950, 1953; Davenport Camougis, and Hichok, 1960; Davenport and
Hichok, 1951, 1957; Bartel and Davenport, 1956; Hichok and Daven-
port, 1957). These laboratory studies demonstrated that these commen-
sal species were attracted to their hosts by a chemical which they termed
a host factor.

Field studies involving the commensal polychaete and its host have
not been previously undertaken. The purpose of this study, therefore,
was to determine the frequency of occurrence of the commensal on the
starfish and the seasonal occurrence, both with respect to number and
size of individuals, as a means of learning further of the relationship of
O. pugettensis to P. miniata.

104

Studies on Commensal Polychaetes 105

MATERIALS AND METHODS

Starfish were collected, measured, tagged, and O. pugettensis counted
and measured at Dana Point, Orange County, California. Collections
were made whenever the tides were below a -0.3 feet, surf conditions
permitting, from July 1964 through June 1966. A total of 385 starfish
were tagged during six collecting periods on January 16-17, 1965 (143
starfish), June 30, 1965 (52), July 30, 1965 (33), November 21, 1965
(63), November 22, 1965 (39), and February 5, 1966 (55) (Table 1).

The starfish were marked with small, numbered plastic tags which
were attached to the starfish with 0.01 mm. diameter stainless steel wire.
The wire was pushed through the arm of the starfish at two places and
twisted together. No injuries were noted during the course of the study
as a result of this marking device. Other marking techniques were tried,
but with little or no success. These included various applications of
stains, including indulen, fast green and silver nitrate. Water insoluble
inks and a knot system using nylon thread were unsuccessful. Measure-
ments of the starfish were taken from the center of the disc to the end of
one arm. After the worms were counted and measured, the starfish with
its commensals was returned to the place where it was collected.

The water temperature data summarized in figure 1 were for New-
port Beach as compiled by the United States Weather Bureau, Los An-
geles International Airport.

DATA

The data for the occurrence of Ophiodromus pugettensis on Patiria
miniata are summarized in figure 1 and Tables | and 2. Figure | sum-
marizes the data seasonally as the average number of worms per starfish.
Temperature data are included with the graph in figure 1. Table 1 lists
the number of starfish, the number of starfish with worms, the per cent
occurrence, the total number of worms, and the ratio of the number of
worms to starfish for each collecting period. Table 2 gives the data for
the number of worms counted from 19 individually marked starfish
which were recaptured two or more times.

Occurrence of Ophiodromus puggettensis on Patiria miniata
The total number of worms counted was divided by the number of star-
fish collected each date to determine the average number of worms for
starfish. These data are plotted in figure 1 together with the water tem-
perature data for the City of Newport Beach. A peak in the population
occurred during the winter months each year during the two year period.
A high of 2.0 worms per starfish was counted in December 1964, and

106 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

TABLE 1

The number of starfish with worms observed from Dana Point,
California, July 1964 through June 1966

NUMBER OF NUMBER OF PERCENT TOTAL NUMBER_- RATIO OF

DATE STARFISH STARFISH WITH OCCUR- OF WORMS NUMBER OF
EXAMINED WORMS RENCE OBSERVED WORMS TO
STARFISH

1964
July 12 Dif 5 19 7 0.26
Aug. 10 108 42 39 65 0.36
Sept. 6 14 4 29 5) 0.36
Oct. 23 7 4 57 4 0.57
Dec. 22 121 95 19 247 2.04

1965
Jan. 16 140 90 64 167 1.19
Feb. 12 30 9 30 17 0.57
Mar. 14 80 44 55 82 1.02
June 30 77 31 40 33 0.44
July 10 53 197 32 26 0.49
July 31 31 19 61 35 12
Oct. 24 32 24 TS) 64 2.00
Nov. 21 63 58 92 167 2.60
Dec. 22 39 33 85 81 2.07

1966
Jan. 8 3H 26 70 48 1.29
Feb. 5 5) 41 74 86 1.56
Mar. 5 55 BS) 64 5 0.94
Apr. 2 49 DSS 51 45 0.91
May 8 47 26 5)5) 33 0.78
June 5 68 2 38 33 0.48

2.60 in November 1965. Minimal average values of 0.26 and 0.44
worms per starfish were observed in July 1964 and July 1965, respec-
tively. The highest water temperatures were measured in August of each
year and the lowest during the winter months. The percent occurrence
of worms on starfish followed inversely these same trends. Ninety-two
per cent of the starfish collected had worms present in November 1965;
whereas, only 19 per cent of the starfish had worms present in July 1964
(Table 1).

A total of 1287 worms was observed and measured during the two
year period. The body length of O. pugettensis was found to vary from
2.0 to 30.0 mm. during the period of observation. Seasonal differences

Studies on Commensal Polychaetes 107

ine}
Ol

Ne)
(e)

10

Average Number of Worms / Starfish
an

oO
Ol

Average Monthly Temperature (°C )

1) Uta sUS aj Ls a Calg eee ie lees ae teers ‘lee ale
1964 1965 1966

Figure 1. The relationship between the seasonal occurrence of Ophiodromus
pugettensis (on Patiria miniata (dots) to water temperature (triangles) from July
1964 through June 1966.

were noted: worms collected during the winter months averaged from
12.0 to 17.0 mm in length as compared to 6.5 to 9.0 mm in length during
the summer months.

Population changes of Ophiodromus pugettensis on Patiria miniata

A total of 385 starfish was marked, of which 152, or 39.5 per cent, were
recovered one of more times. Of the 152 recovered starfish, 19 were
recovered two or more times (Table 2). Five starfish were collected three
additional times (Table 2). The majority of the 152 recovered starfish
were observed one to three days later. A total of 53 out of 104 starfish
had the same population of worms present as was observed initially.
There were 18 starfish which had a total increase of 31 worms, and 33
starfish which had a total decrease of 41 worms. In those 48 starfish
which were recovered from 17 to 190 days later, the worm population
was unchanged on 16 starfish, increased on 17 starfish, and decreased on
19.

Only four of the 19 starfish recovered more than once had an un-
changed worm population (Table 2). The number of worms on the 15
starfish either increased or decreased was largely dependent on what
time of the year the starfish was recaptured. If the starfish had been
marked during the winter months and recovered in the spring or summer,
then the number of worms were less. Conversely, if the starfish was

108 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

marked during summer and recovered in the winter, the number of
worms was greater.

DISCUSSION

The number of Ophiodromus pugettensis or Patiria miniata at Dana
Point, California, varied with the time of the year. Peaks in population
were in December 1964, and in November 1965; minimal points oc-
curred during the summer of each year. It is apparent from figure | that
as the water temperature increased there was a corresponding decrease
in the number of worms per starfish. Furthermore, the worm population
on the starfish reached its peak in late fall-early winter prior to the low
water temperatures. Highs and lows in the commensal population oc-
curred one or two months prior to the low and high water temperatures,
respectively.

Two explanations may be advanced to explain the seasonal changes
of O. pugettensis on P. miniata: (1) the worms reproduce in the winter
when they are large in size or (2) the worms reproduce in the spring and
summer. The maturation of the gametes was not followed in this study.
It is not known whether the worm reproduces on the starfish, or at some
time later after leaving the starfish. Davenport and Hichok (1957) re-
ported swimming O. pugettensis at Friday Harbor, Washington in July.
On the basis of other studies dealing with reproduction in polychaetes,
(Reish, 1954; Richards, 1966), it is logical to assume that sexual matu-
rity would be correlated with the maximum size of the worm. It is not
known for certain if the maximum size of this polychaete is reached
during the time it is commensal on the starfish or if it continues to grow
after it leaves the starfish.

If it reproduces during the winter months in southern California,
then it would seem that the larvae must take approximately six months
before they begin to settle on the starfish as small worms during June
and July. Assuming that sexual maturity and spawning occur during
the winter months, the fate of these adults is unknown, the adults may
die following spawning or the adults may simply be smaller because of
the loss of gametes.

If the worms reproduce during the summer months in southern Cali-
fornia, then the worms, which leave the starfish in the late winter months,
must become free-living. Specimens of O. pugettensis have been taken
from surf grass roots at Dana Point in June, 1965, and sub-tidal free
living populations of this species have been reported from southern
California (California State Water Control Board, 1965). If the worms
do shed their gametes in the summer, the sizes of the worms and num-

Studies on Commensal Polychaetes 109

TABLE 2

Summary of the Number of Worms Counted from 19 Individually
Marked Starfish Observed Two or more Times

Number of Worms Present

INITIAL FIRST RECOVERY SECOND RECOVERY THIRD RECOVERY

(DF
(3)
(1)
(1)
(3)
(3)
(3)
(3)
(1)
(1)
(3)
(1)
(3)
(3)
(3)
(3)
(1)
(31)
(29)

(116) —
(32) =
(54) —=
(15) =
(3) 0 (105)
(32) =e
(48) as
(31) 9 (32)
Ge) =
(17) =
(76) —
(161) 4 (188)
(76)
(48)
(115) =
(31) 0
(45) =
(32) 3
(93) =

—NWWeNNNHRHKH KK WDOONAWef

WRWeENNWNNHKH KEK ANKH LN ©

* Numbers in parenthesis denote the number of days since the starfish was marked.

bers on the starfish would gradually increase as the young develop. The
final resolution of this question of the seasonal occurrence of O. puget-
tensis on P. miniata must await data on the time of reproduction in
southern California of this commensal population.

It can be seen from the data on the recovery of marked starfish that
the population of commensal worms is not a stable one. A considerable
amount of movement on and off the starfish occurred in one to three
days after marking. Presumably some of the decreases in the number of
worms may be the result of the handling procedures during tagging.
However, in one instance five additional specimens of O. pugettensis
were found on a starfish recaptured three days later. Where these speci-
mens come from and where they go is unknown. Whether they move
directly from one starfish to another or by way of a free-living existence
is unknown. Undoubtably the host factor described by Davenport and his
colleagues plays a role in assisting the worm to find the starfish.

110 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

SUMMARY

1. The commensal relationship of Ophiodromus pugettensis with the
starfish Patiria miniata at Dana Point, California, was studied over a
period of two years from July 1964 through June 1966.

2. The number of polychaetes on the starfish was found to vary season-
ally and to vary inversely with the temperature of the water. The
per cent occurrence of the starfish possessing commensals also varied
seasonally with highs occurring during the winter and lows during
the summer.

3. The population of worms on an individual starfish is a changing one
as indicated by recovery of marked starfish.

4. Two explanations were discussed to account for the seasonal occur-
rence of O. pugettensis: (1) the worm reproduces in the winter fol-
lowed by a long larval life or (2) the worm leaves the starfish in the
winter and becomes free-living and reproduces in the summer.

LITERATURE CITED

BARTEL, A. H. anp D. DAVENPORT
1956. A technique for the investigation of chemical responses in aquatic animals.
J. Anim. Behav. 4:117-119.

CALIFORNIA STATE WATER CONTROL BOARD.
1965. An oceanographic and biological survey of the Southern California Main-
land Shelf. Appendix — Data. Pub. No. 27, p. 1-445.

CLARK, R. B.
1956. Capitella capitata as a commensal, with a bibliography of parasitism and

commensalism in the polychaetes. Ann. Mag. Nat. Hist., London. Ser.
12, 2:433-448.

DALES, R. P.
1957. Interrelations of organisms. A. Commensalism. Jn Treatise on Marine

Ecology and Paleoecology. J. W. Hedgpeth, Editor. Geol. Soc. Amer.,
Mem. 67:391-412.

DAVENPORT, D.

1950. Studies in the physiology of commensalism. I. The polynoid genus Arc-
tonoe. Biol. Bull. 98:81-93.

1953. Studies in physiology of commensalism. III. The polynoid genera Acholoe,
Gattyana and Lepidasthenia Studies in physiology of commensalism. IV.
The polynoid genera Polynoe, Lepidasthenia and Harmothoe. J. Mar. Biol.
Assoc. U. K. 32:273-288.

DAVENPORT, D., G. CAMOUGIS, ano J. F. HICHOK
1960. Analysis of behavior of commensals in host-factor. I. A hesionid polychaete
and pinnotherid crab. Anim. Behav. 8:209-218.

Studies on Commensal Polychaetes III

DAVENPORT, D. anp J. F. HICHOK

1951. Studies in physiology of commensalism. II. The polynoid genera Arctonoe
and Halosydna. Biol. Bull. 00:71-83.

1957. Notes on the early stages of the facultative commensal Podarke pugettensis

Johnson (Polychaeta: Hesionidae). Ann. Mag. Nat. Hist., London, Ser. 12.,
10:625-631.

HICHOK, J. R. anp D. DAVENPORT
1957. Further studies on the behavior of commensal polychaetes. Biol. Bull.
113:397-406.

OKUDA, S.
1931. Descriptions of two polychaetous annelids found in burrows of an apodous
holothurian. Annot. Zool. Japon. 15:410-415.

REISH, D. J.
1954. Life history and ecology of the polychaetous annelid Nereis grubei (Kin-
berg). Allan Hancock Found. Publ., Occas. pap. 14:1-74.

1961. The use of sediment bottle collector for monitoring polluted marine waters.
Calif. Fish and Game 47:261-272.

RICHARDS, T. L.

1967. Reproduction and development of the polychaete Stauronereis rudolphi
including a summary of development in the super family Eunicea. Marine
Biol. 1:124-133.

STEINBECK, J. AND E. F. RICKETTS
1941. Sea of Cortez. Viking Press, New York.

Accepted for publication January 18, 1968.

CHAETOGNATHS FROM THE ARCTIC BASIN,
INCLUDING THE DESCRIPTION OF A NEW SPECIES OF
HETEROKROANIA

JOHN KAYL DAWSON

Department of Biological Sciences,
University of Southern California,
Los Angeles, California,
and Humboldt State College, Department of Fisheries, Arcata, California

INTRODUCTION

Four species of chaetognaths have been recorded from the Arctic Ocean;
Sagitta elegans, S. maxima, Eukrohnia hamata, and an unspecified
species of Heterokrohnia. S. elegans has been found most abundantly
along the continental shelves and slopes of the Arctic Ocean (Mac-
Ginitie, 1955; Zenkevitch, 1963; Grainger, 1965) although it has been
found over deep water adjacent to the slope (Bogorov, 1946; Brodsky
and Nikitin, 1955; Mohr, 1959). S. elegans from these high latitudes
may be represented by a separate subspecies arctica although the valid-
ity of this designation has been questioned by McLaren (1966). S. maxi-
ma has been recorded as occasionally present over deep water (Brodsky
and Nikitin, 1955; MacGinitie, 1959; Dunbar and Harding (in press).
E. hamata was considered to be an inhabitant of deep water by Mac-
Ginitie (1955) and Zenkevitch (1963). Zenkevitch (1963) considered
this species as one of a group of zooplankters that indicate the presence
of North Atlantic water in the Arctic Basin despite the fact that Mac-
Ginitie (1955) found several reproducing specimens near Pt. Barrow,
Alaska. Other records of E. hamata by Bogorov (1946, Grainger (1965),
and Cairns (1967) show that this species can be found, in smaller num-
bers, over the continental slope and shelf. Heterokrohnia was listed
from over deep water of the Canada Basin by Dunbar and Harding
(in press).

The opportunity to add to the existing information on chaetognaths
of the Arctic Basin was provided by collections made from Fletcher’s
Ice Island T-3 as it drifted over a mainly deep water area between Sep-
tember 1965 and September 1966. This collection is particularly val-
uable as the thirteen consecutive months of collecting allow for a better
understanding not only of the species present, but of changes in vertical
distribution and reproductive condition through the year.

I12

Arctic Chaetognaths 113

METHODS AND MATERIALS

Specimens used in the study were collected from Fletcher’s Ice Island
T-3 by Alan J. Mearns from September 1965 to January 1966, Gary P.
Owen from February 1966 to May 1966, and the author from June 1966
to September 1966. During this 13 month period the ice island drifted
from 75°21'N, 140°53’W in the Canada Basin to 75° 42’N, 160°58’W
in the Chukchi Sea. Collecting was carried out through a meter-square
hole in the sea ice adjacent to the ice island. A list of stations at which
chaetognaths were collected will be deposited with the American Docu-
mentation Institute, Library of Congress, Washington, D. C. Closing
nets with a one-half meter opening and mesh of No. 6, 20 or 24 were
used for vertical tows and No. 6 and 20 non-closing nets for horizontal
tows. A small biological trawl (Menzies, 1962) modified by the removal
of the supporting frame except that portion which held the mouth open
was used for taking a small number of bottom samples. Most samples
were preserved in 7 per cent formalin buffered with hexamethylena-
mine, but some were preserved in Bouin’s fluid or in 70 per cent ethanol.
Hydrographic data was provided by the University of Washington and
areal positions as well as bottom depths by Lamont Geological Ob-
servatory.

Only specimens 8 mm and greater in length were removed from the
samples and identified with the exception of the new species of Heter-
okrohnia in which all specimens were removed. Measurements of tail
and total lengths excluding the tail fin were obtained by placing the
chaetognath on a millimeter scale in water. Samples preserved in
Bouin’s or alcohol sometimes were bent or shrunken and this reduced
the accuracy of measurements of chaetognaths to approximately + 0.5
mm. For Eukrohnia hamata, in addition to measuring total length and
tail length, the number of teeth and hooks were counted. Specimens of
E. hamata were grouped in various maturity stages according to the
classification of Kramp (1939) which is as follows:

STAGE ' MALE GONADS FEMALE GONADS

I Unripe Unripe

II Tail containing All eggs small

more or less sperm

Ill Sperm evacuated All eggs small, seminal
receptacle filled with
sperm

IV Sperm evacuated Ovaries filled with ripe
eggs

Vv Sperm evacuated Eggs evacuated, receptacle

still contained sperm

114 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

RESULTS

Four species, one of which is new, belonging to three genera were col-
lected. These were Eukrohnia hamata, Sagitta maxima, Heterokrohnia
mirabilis, and Heterokrohnia n. sp. . None of the Eukrohnia sufficiently
satisfied the characteristics of E. bathypelagica (Alvarino, 1962) and
thus all were identified as E. hamata. Probably the most trenchant dif-
ferentiating characteristic between E. hamata and E. bathypelagica is
the per cent tail length to total length. Alvarino’s (1962) figure 22 shows
the clearly separate linear relationships of tail to total lengths of both
species. None of the tail to total length data from this collection follows
the E. bathypelagica regression line and most of the data do follow the
line of E. hamata although there is a good deal of variance as the animals
increase in size.

Eukrohnia hamata (Mobius, 1875)

Eukrohnia hamata was the most abundant of the chaetognaths in this
collection with 1159 specimens from 155 hauls, accounting for 97 per-
cent of the chaetognaths collected. Most of the specimens were juveniles,
but all stages of sexual maturity were represented; 1056 juvenile, 64
stage I, 16 stage II, 1 stage III, 7 stage IV, and 15 stage V.

In each of the maturity stages from I to V total length, per cent tail to
total length, number of hooks, and number of teeth are considered (Table
1). The total lengths of the animals show the most marked changes be-
tween stage I and II. Ranges and means for total lengths in stages II and
IV are about the same. The single individual from stage III was not in-
cluded as its tail was badly damaged. The apparent decrease in the
length of stage IV, which corresponds with the ripening of the eggs, may
be an artifact resulting from shrinkage of different degrees and from
measuring a small number of specimens of a wide range of sizes. The
per cent tail to total length shows a gradual increase to stage IV with a
marked increase from stage IV to V. There is a decrease in the mean
number of hooks to stage III, but an increase in the subsequent stages. If
the decrease is real, it seems that this could occur only if the older and
larger hooks dropped off as the animal aged. The number of teeth pre-
sent is most variable and has the lowest value in stage I. Variation is less
in subsequent stages which, with the exception of the single specimen
from stage III, have a fairly constant mean value.

The vertical distribution of mature and immature Eukrohnia hamata
(Fig. 1) shows the mature E. hamata descending to a depth greater than
3000 meters in the month of June with the bottom limit ascending slowly
through the rest of the summer. During the descent of mature individuals
there were no specimens from stages III to V collected at depths of less

Arctic Chaetognaths I15

SEPT OCT NOV
1oof] FF =

300
500

1000;—--

1500

2000

ANN
AY \AA =
_ a

ARN
LONE

2500

\\\

\ \\

WM

X
Nan

\\\\ \\
\\\

LY

3500

NW

\\\\

3800 ' ~ = eel

Figure 1. Distribution of adult and juvenile Evkrohnia hamata. Depth in meters
on left. Bottom indicated by hatched area. Dotted lines represent salinity contours
and on the left from top to bottom they are 30.0, 31.0, 32.0, 33.0, 34.0 0/00. Solid
horizontal lines represent temperature contours and on the left from top to
bottom they are —1.4, —1.4, —0.6, +0.2, +0.2°C. Open boxes represent the
number of immature Guvenile and stage I) caught per 250 meter vertical tow, and
darkened boxes represent ten times the number of mature (stage II-V) caught per
250 meter vertical tow. Vertical lines represent the depth of water which was
sampled in each month.

than 500 meters, and only in the latter part of the summer, i.e. Septem-
ber, were stage V individuals collected at less than 500 meters.
During the general warming of summer the surface — 1.6°C iso-
therms disappear but the deeper temperature layers remain stable.
There appears to be a general decline in the number of E. hamata caught
in the 300 to 500 meter interval, which is the interval with the most
rapid temperature change as well as that with highest temperature (up to
+ 0.6°C) in the Canada Basin. The salinity remains fairly constant with
the exception of the surface salinity which is diluted by the summer fresh
water runoff. The greatest numbers of adult and juvenile E. hamata
were collected during the summer (June-September) in deep water and
in the upper 100 meters respectively, while during winter there was a de-
cline in the number of mature and immature individuals at these levels.
All of the 13 chaetognaths in stage V possess a marsupium formed by
the folding upward and inward of the lateral fins, and two of the 13 con-
tain young in an eggsack (Fig. 2A and B). These two latter specimens
are from station 93 (Dawson), a horizontal tow at a depth of 500 meters
made on August 16, 1966, and station 124 (Dawson), a 600-300 meter
vertical tow made on September 7, 1966. Several of the remaining stage
V specimens still possess remnants of the eggsack which contained the

116 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

Figure 2.
micrograph; B. Diagram of photomicrograph; e — eggsack; f — folded fin; o —
oviduct opening; re — ruptured eggsack; so — spent ovaries; y — young; C. Dor-
sal view of Heterokrohnia involucrum n. sp. Fin rays not shown; D. Dorsal view
of Heterokrohnia involucrum n. sp. Head showing ciliary loop.

young while being held by the parent. Two eggsacks develop adjacent to
each other with each eggsack being in communication with its respec-
tive oviduct opening by a fine tubule. Both specimens of this collection
however possess only one intact eggsack with the other adjacent sack
being ruptured previously in the discharge of young or broken in the
collecting procedure. In the case of the specimen from station 124, one
young remained in the eggsack even though it was ruptured. The speci-
men from station 93 contains young in an undeveloped, curled state,
but the young being held by the animal from station 124 are well de-
veloped with identifiable heads, bodies, and guts. The more developed
young are quite uniform in size; approximately 2.4 mm long. All but the
most posterior young are oriented with their anterior end toward the

Arctic Chaetognaths TANG

anterior end of the eggsack. One E. hamata collected by Rey Stendell off
East Greenland, which was not a part of the year’s collecting, was also
examined. This individual still possessed both eggsacks filled with well
developed young. There were about 50 young to each side or a total of
100 young. This chaetognath was taken April 19, 1965 at 68°55’N, 20°
35’W in a vertical closing net tow from 1100 to 900 meters.

Sagitta maxima (Conant, 1896)

Twenty-three Sagitta maxima were collected from 20 hauls. S. maxi-
ma was caught throughout the year and at various depths. They ranged
in size from 8 to 54 mm and all were immature.

Heterokrohnia mirabilis Ritter-Zahony, 1911

All of the seven Heterokrohnia mirabilis were found in three bottom
trawls and they ranged in size from 7 to 20 mm. Four of the seven speci-
mens were mature. Since bottom trawls are pulled to the surface with the
mouth of the net open, it is possible that H. mirabilis may have been
collected in mid-water. However, their absence in plankton hauls sug-
gests that they were collected at or very close to the bottom.

Heterokrohnia involucrum n. sp.

Ten specimens of a new species of Heterokrohnia, Heterokrohnia
involucrum were collected in five separate tows (Table 2). The trivial
name is from the Latin involucrum meaning sheath or covering. In the
case of Heterokrohnia involucrum the sheath or covering refers to the
collarette covering the length of the body. The five specimens from
station 58 were twisted and shrunken from being preserved in ethanol
and consequently their measurements are least accurate. All specimens
were immature. The holotype and paratypes are deposited at the Allan
Hancock Foundation, University of Southern California under the
chaetognath catalog number 68-1.

The main differentiating characteristic between H. involucrum and
the closely related H. mirabilis and H. bathybia Marumo and Masataka
(1966) is that the new species has a very large long foamy collarette
covering the entire length of the body while H. mirabilis has no collar-
ette and H. bathybia has a collarette extending only from the head to
halfway between the head-trunk septum and the anterior end of the ven-
tral ganglion. Because most of the specimens are immature, it is difficult
to compare the hook and teeth number of H. involucrum with that of H.
mirabilis and H. bathybia. The lateral fins are similar to those of H.
mirabilis and unlike those of H. bathybia. Due to the presence of the

118 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

large collarette, the neck is not as conspicuous as that of H. mirabilis.
The head is also not as large in the new species as it is in H. mirabilis or
H. bathybia and the body appears more transparent when preserved in
buffered formalin than is the case with H. mirabilis.

The holotype (Fig. 2C) is the most mature of the 10 individuals,
having clearly visible developing ovaries. It was collected in a horizontal
tow at 3800 meters (bottom depth 3845M) with a No. 6 mesh non-
closing net at 75°37'N, 153°57’W. The total length of the holotype is
15.7mm excluding tail fin and the tail segment is 35.0% of the total
length. On each side, the numbers of hooks are 11-11; anterior teeth are
12-14; and the posterior are 25-25.

Tangoreceptors are present along the length of the body and fins.
Transverse muscles extend from the neck to the anterior edge of the
lateral fins and from close to the trunk-tail septum to about one-third
the length of the tail section. The lateral fins originate approximately
half way between the head-trunk and trunk-tail septa and extend to the
midposition between the trunk-tail septum and tip of the tail. The lateral
fins narrow about one-third of the distance from their anterior edge and
then become wider in the posterior two-thirds. The tail fin is spade
shaped and all fins are completely rayed, although these rays have not
been included in fig. 2C. The ciliary loop was seen in a paratype speci-
men fixed in Bouin’s.solution, (Fig. 2D). Glandular canals are present
along the dorsolateral margin of the head with a gland reservoir at the
tip of the head. The hooks are very similar to those of H. mirabilis with
the major curvature being at the anterior end of the hooks. The teeth are
the same as those of H. mirabilis in Ritter-Zahony’s (1911) fig. 47, with
the anterior teeth short and flat and the posterior teeth longer and thin.
No gut diverticulum is present and eyes are lacking, both characteristic
of the genus Heterokrohnia. The collarette begins at the head and ex-
tends the length of the animal. Between the head and origin of the lateral
fins the collarette is thick with a distinct outer border. At the lateral fin
area, the dorsal and ventral parts of the collarette retain the smooth
outer border but on the lateral fins the collarette spreads out with no
distinct borders. At the trunk-tail septum area of the fins a very fine col-
larette spreads out further on the fins and the heavier collarette narrows
to be relatively thin, continuing narrow until the tail fin is reached. At
the tail fin the collarette becomes very fine and continues so to the tip of
the tail.

DISCUSSION

The evidence that Eukrohnia hamata descends into deep water during
the summer months to breed is fairly well agreed upon by various

Arctic Chaetognaths 119

chaetognath workers. In Greenland waters Kramp (1939) found that
young E. hamata at the surface start to descend into deeper water as
they mature and continue this downward movement while the female
organs are developing. Breeding then takes place in the deep water
which is evidenced by stages III-V being found only at depths greater
than 500 meters, with some of the young returning to the surface. He
believes that this breeding may occur throughout the year with a maxi-
mum in summer and autumn. In Norwegian waters, however, Wiborg
(1954) found breeding to take place in April and May. David (1958b)
believes that the migration to the deep may be “a behavioral relic of
some deep-living ancestral form” and because there are fewer barriers
to deep forms relative to surface types, then the dispersal of the species
may have been by way of the deep living forms. Generally during the
downward migration of summer the more mature stages of E. hamata
are found at depths greater than 500 meters. David (1958b) collected
only stage III and IV below 750 meters but specimens of stage V (var.
antarctica) were found at the surface as well as in deep water.

In Norwegian waters, Wiborg (1954) found the greatest number of E.
hamata in the spring and summer with peaks in May and July. There are
several factors which could result in the increased yield of young E.
hamata (Fig. 2) collected at the surface during the 13 month sampling
period. The most likely factor seems to be the restocking of copepod
nauplii, following the phytoplankton bloom, which is a probable food
source for the young chaetognath during the summer. However, other
factors could be involved, such as a preference for the lower salinity
caused by the fresh water runoff from the ice or the presence of contin-
uous light in the upper water layers. The absence of immature E. hamata
in the upper 100 meters during the winter could be the result of the re-
verse or lack of any of the above mentioned factors. Both the presence
of young at the surface in the summer and the absence of young at the
surface in the winter show a lag behind the above factors of a month
or so, which would be expected.

The presence of a marsupium containing an eggsack is a characteris-
tic unique to the genus Eukrohnia. It has been reported several times in
the past literature to occur in Eukrohnia hamata. Nordgaard (1805) was
the first person to describe the marsupium with an eggsack. “In samples
from the Vest Fjord (300-400m, 500-600m) there were specimens with
eggbags. The hinderpart of the side fin was bent downward, thus form-
ing a hollow in which the eggs lay tightly pressed together.” A similar E.
hamata from the “Belgica” collection was described by Ritter-Zahony
(1910). This specimen was 30 mm in length and from a depth of 750-
900 meters. He describes the change in the side fins which provide the

120 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

TABLE 1

Eukrohnia hamata. Total and per cent tail length;
hook and teeth number of the maturity stages.

STAGE TOTAL LENGTH PER CENT TAIL LENGTH HOOK NUMBER TEETH NUMBER
(mm) (mm)

RANGE MEAN RANGE MEAN RANGE MEAN RANGE MEAN
I 17-31 24.9 20-33 24.3 9-11 9.7 13-30 19.3
II 24-35 30.4 21-27 24.9 8-10 9.3 20-30 23.0
III 8-9 8.5 20-21 20.5
IV 23-31 267 23-31 26.1 8-9 8.6 DD Ap)
V 27-35 30.2 27-35 30.2 8-11 8.9 20-29 23.0

marsupium for the eggsack as well as the plum shape jelly-like sacks
which contain the eggs. An excellent drawing of the marsupium and
eggsack is shown on his plate V, figure 17. Kuhl (1928) states that in the
genus Eukrohnia, the eggs are not set free but are pasted by a jelly-like
cementing substance to a kind of “eggsack” and that this egg packet is
carried around under the lateral fins by the parental animal in the region
of the trunk-tail septum of the back. MacGinitie (1955) caught two E.
hamata in a surface tow at Point Barrow, Alaska in which he described
young escaping from a marsupium formed by the folding up of the
lateral fins. Ruptured eggsacks have been found in Eukrohnia fowleri
by Tchindonova (1955) as indicated by David (1958b), and David
(1958b) has found an egg-shaped opaque structure at the opening of the
oviduct on a specimen of Eukrohnia bathyantarctica. Both the ruptured
eggsacks and the eggshaped opaque structure were attached to the
chaetognath by a fine tubule which went directly into the oviduct, and
David (1958b) concluded that the ruptured eggsack represented a later
stage of development of the opaque egg-shaped structure. He believed
that the opaque egg-shaped structure may have been seminal vesicles
which had been transferred from the tail segment of one animal to the
oviduct of another. The vas deferens which transferred the sperm from
the tail segment into the seminal vesicles may then be the tubule which
enters the oviduct and provides the pathway for the sperm to enter the
oviduct.

E.. hamata is considered by David (1958b) to be a classic example of
an organism with bipolar distribution, with E. hamata being at the sur-
face or epipelagic layers in the cold polar waters and in the meso- and
bathypelagic layers in the tropical and equatorial regions. Sagitta maxi-
ma appears to be sparsely distributed in the Canada Basin of the Arctic

121

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1D Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

Ocean and it is considered by Alvarino (1965) to be a cosmopolitan
meso- or deep oceanic species extending from the Arctic-Subarctic to
the Antarctic-Subantarctic regions. Heterokrohnia mirabilis seems to be
a relatively rare species in the world oceans. It was considered by David
(1959) to be an endemic antarctic species, but Bieri (1959) has also
found H. mirabilis in the Pacific-Central American region and Tchin-
donova (1955) found a single specimen in the Kurile-Kamchatka
region.

Heterokrohnia involucrum does not appear to be limited to any parti-
cular depth since this new species was collected throughout the water
column. Nine of the ten specimens were collected during the summer, a
fact which may be of some significance. H. involucrum may be an ende-
mic species of the Arctic Ocean since this species has been found no-
where else, but since the main characteristic differentiating H. involu-
crum from H. mirabilis is the presence of a collarette, mishandled speci-
mens could be stripped of their collarette and consequently be identified
as H. mirabilis.

ACKNOWLEDGEMENTS

I wish to thank Mr. Richard Tripp from Dr. L. K. Coachman’s oceanography
group of the University of Washington for providing the hydrographic data for
the year’s sampling. I am also grateful to Dr. Robert Bieri, Dr. Peter David, and
Dr. Elda Fagetti for their correspondence and particularly Dr. Angeles Alvarino
for her consultations. I am especially indebted to Mr. Stephen Geiger for his
patient guidance throughout the preparation of this paper.

This work was supported by a contract between the University of Southern
California and the Arctic Program, Office of Naval Research, Department of the
Navy, Nonr 228 (19), NR307-270.

SUMMARY

During a year’s sampling in the Canada Basin of the Arctic Ocean four
species of chaetognaths were collected; Eukrohnia hamata, Sagitta
maxima, Heterokrohnia mirabilis, and H. involucrum n. sp. . The most
abundant was Eukrohnia hamata which had seasonal changes in the
vertical distribution of the maturity stages; with a downward movement
in the summer to deep water. Two Eukrohnia hamata carrying young in
a marsupium were collected and these along with other E. hamata pos-
sessing a marsupium but no young are described.

LITERATURE CITED

ALVARINO, A.
1962. Two new Pacific chaetognaths, their distribution and relationship to
allied species. Bull. Scripps Inst. Oceanogr. 8: 1-50.

Arctic Chaetognaths 1233)

1965. Chaetognaths. Jn H. Barnes, (ed.), Oceanogr. Mar. Biol. Ann. Rev., Lon-
don, George Allen and Unwin: Ltd. 3: 115-194.

BIERI, R.
1959. The distribution of the planktonic Chaetognatha in the Pacific and their
relationship to the water masses. Limnol. Oceanogr. 4: 1-28.

BOGOROV, V.

1946. Zooplankton collected by the “Sedov” expedition 1937-1939. (In Russian,
English summary). /n V. Buinitski, (ed.), Trudy dreifujusjtsjei ekspeditri
glawseiomorputu na ledokoljnom parochode “T. Sedov”, 3: 336-370.

BRODSKY, K. A. and M. M. NIKITIN

1955. Hydrobiological work. In M. M. Somov, (ed.), Observational data of the
scientific research drifting stations of 1950-1951. Morskoi Transport,
Leningrad, 1: 404-465. Tr. by Amer. Meteorol. Soc. DDC doc., AD 117135.

CAIRNS, A. A.
1967. The zooplankton of Tanquary Fjord, Ellesmere Island, with special refer-
ence to calanoid copepods. J. Fish. Res. Bd. Canada, 24: 555-568.

DAVID, P. M.
1958a. A new species of Eukrohnia from the Southern Ocean with a note on
fertilization. Zool. Soc. London, 131: 597-605.

1958b. The distribution of Chaetognatha of the Southern Ocean. Discovery
Repts. 29: 199-228.

1959. Chaetognatha. B. A. N. Z. Antarctic Res. Exped. 1929-1931, Repts. Ser. B,
8: 73-79.

DUNBAR, M. J. and G. HARDING

(in press) Arctic Ocean water masses and plankton: A reappraisal. Jn A. Jesperson
and J. E. Sater, (ed.), Proc. Arctic Drifting Station Symposium, Arctic Inst.
N. Am., Washington, D.C.

GRAINGER, E. H.
1965. Zooplankton from the Arctic Ocean and adjacent Canadian waters. J.
Fish. Res. Bd. Canada, 22: 543-564.

KRAMP, P. L.
1939. Chaetognatha. Meddeleeser om Grgnland, 80: 1-40.

KUHL, W.
1928. Chaetognatha. Die Tierwelt der Nord- und Ostee, 11 (7b): 1-24.

MACGINITIE, G.
1955. Distribution and ecology of the marine invertebrates of Point Barrow,
Alaska. Smithsonian Misc. Coll. 128: 1-201.

MARUMO, R. and K. MASATAKA

1966. A new species of Heterokrohnia (Chaetognatha) from the western North
Pacific. La Mer; Bulletin de la Societe franco-japonaise d’oceanographie,
4 (3): 165-170.

124 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

MCLAREN, I. A.
1966. Adaptive significance of large size and long life of the chaetognath Sagitta
elegans in the arctic. Ecology, 47: 852-855.

MENZIES, R. J.

1962. The isopods of abyssal depths in the Atlantic Ocean. Jn J. L. Barnard, R. J.
Menzies, and M. C. Bacescu. Abyssal Crustacea, New York: Columbia
Univ. Press, pp. 79-206.

MOHR, J. L.

1959. Marine biological work. Jn V. Bushnell, (ed.), Scientific studies at Flet-
cher’s Ice Island, T-3 (1952-1955). U. S. Air Force Cambridge Research
Center, Bedford, Mass. Geophysical Research Paper 63, 1: 83-103.
(AFCRC-54-59-232 (1).)

NORDGAARD, O.
1905. Hydrographical and biological investigations in Norwegian fiords. Bergens
Mus. Skrifter, 7 (1 A): 23-48.

RITTER-ZAHONY, R.
1910. Die Chatognathen. Fauna Arctica, 5: 249-288.

1911. Revision der Chatognathen. Deutsche Sudpolar-Exped. 13: 1-71.

TCHINDONOVA, Y. G.
1955. Chaetognatha of the Kurile-Kamchatka Trench. Trudy Inst. Okeanol.
12: 298-310. (In Russian).

WIBORG, K. F.
1954. Investigations on zooplankton in coastal and offshore waters of western and
northwestern Norway. Rep. Norweg. Fish. Mar. Invest. 11 (1): 1-246.

ZENKEVITCH, L. A.
1963. Biology of the seas of the U. S. S. R. Tr. S. Botcharskaya, Interscience,
New York, 955 p.

Accepted for publication April 2, 1968.

RESEARCH NOTE

A SPIDER TRACKWAY FROM THE
COCONINO FORMATION, SELIGMAN, ARIZONA

North of Seligman, Arizona, in the Coconino sandstone is an area that
has proved fruitful in the collection of ichnites. The principal locality is
in a canyon west of Chino wash and four miles from U. S. Highway 66.
There we have recovered a substantial number of trackways of reptiles
and a lesser number of trackways of invertebrates.

It is the purpose of this paper to record the probable trackway of a
spider, which is believed to be the first of its kind.

I am grateful to Dr. Dan Guthrie for helpful suggestions in preparing
this paper.

COCONINO SANDSTONE

The Coconino sandstone is a distinctive formation of upper Permian
Age which underlies much of the plateau of northern Arizona and which
is characterized by its prominent cross-bedding, its small sand grains
and its general cliff-forming character. It is underlain by the Hermit
shale characterized paleontologically by its numerous ferns and other
plants as well as insect wings and some tracks of vertebrate animals.
Above it is the Kaibab formation, a fossiliferous limestone of shallow-
water marine origin. The typical Coconino sandstone extends over a
vast area without any appreciable change in type of cross-bedding,
purity of sand, kind of cement or general massive character. Ichnites
have been found throughout the formation.

In 1926 and 1927 Charles W. Gilmore made extensive studies of the
footprints from the Coconino sandstone of the Grand Canyon region
describing seventeen species of vertebrate tracks and the following five
species of invertebrates:

Mesichium benjamini
Octo podichnus didactylus
Paleohelcura tridactyla
Triavestiga sinuousus
Unisulcus sinuosus

These are names only of trackways and no further classification is
given. None of these resembles the trackway of the suspected spider
trackway.

The first fossil spider was described by Romer in 1866 under the

125

126 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

Figure 1. Spider Trackway, Coconino Sandstone
Figure 2. Spider Trackways, Coconino Sandstone

Spider Trackway 127]

Figure 3. Trackway from live Tarantula. (Dugesiella hentzi)

name of Protolycosa anthracophila from the Carboniferous of Upper
Silesea. Eight years later in 1874, the first American fossil spider Ar-
throlycosa antiqua was described by Harger from the Pennsylvanian of
Mazon Creek (Moore 1955). Since these early records many other spe-
cies of spiders have been described, but nothing has been published on
their trackways.

DESCRIPTION OF COCONINO SPIDER TRACKWAY

The spider trackway occurs on two matching rock specimens roughly 14
cm. square, one showing the mould, the other the cast. There are ten
groups of prints, each with a pattern of three points in a forward line
with one point behind the inner of the three forward prints. (Figs. 1-2)
The average length of stride is 3.1 cm. The width of the three forward
prints averages 1:2 cm. The angle between the line of three forward
prints and the rear prints averages 72°. The distance between right and
left footprints averages 3.5 cm.

In order to compare the Coconio trackway with trackways of modern
spiders, three living spiders were chosen, the Tarantula — Dugesiella
hentzi (Fig. 3); the trapdoor spider — Actinoxia versicolor; and Wolf
spider — Lycosa punctulata. After inking their feet, they were allowed
to travel over a white piece of paper. All three spiders gave patterns
very similar to the Coconino pattern, tending to confirm the belief that
the Coconino trackway of Permian age was made by a spider.

128 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 2, 1968

LITERATURE CITED

GILMORE, C. W.
1926. Fossil footprints from the Grand Canyon. Smithson. Misc. Coll.,

77(9):1-41.

1927. Fossil footprints from the Grand Canyon. Smithson. Misc. Coll.,
80(3):1-78.

MC KEE, E. D.

1934. The Coconino sandstone — its history and origin. Carnegie Inst., No.
440-VII:88.

MOORE, R. C.

1955. Treatise on Invertebrate Paleontology. Part P, Arthropoda 2, pp. 46-48.

Raymond M. Alf, Webb School of California, Claremont, Calif. 91711

Accepted for publication January 10, 1968.

ERRATA

Volume 67, Part 1
Figures | and 2 on pages 33 and 34 should be reversed.
Figures 2 and 3 on pages 67 and 68 should be reversed.

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LOS ANGELES, CALIFORNIA

VoL; 67 JULY-SEPTEMBER 1968 PART 3

CONTENTS

Anuran Succession in a Temporary Pond in Colima, Mexico.

James R. Dixon and W. Ronald Heyer

A New Species of the Genus Stenistomera (Siphonaptera: Sys-
trichopsyllidae). Harold J. Egoscue

Ritterella rubra and Distaplia smithi: Two new Colonial Ascid-
ians from the West Coast of North America. Donald P.
Abbott and Winona B. Trason

A New Chigger (Acarina, Trombiculidae) from a Bat, Tadarida
femorascca, Taken in Sonora, Mexico. Richard B. Loomis
and Lynell K. Tanigoshi

Variation, Distribution and Systematic Status of the Black-

- Headed Snake Tantilla yaquia Smith. Roy W. McDiarmid. .

A New Species of Terebripora (Ectoprocta, Ctenostomata) from
Antarctic Cephalodiscus. John D. Soule and Dorothy F.
Soule

A New Species of Acontiate Anemone from Southern California
(Sagartiidae: Sagartia). Ronald H. McPeak

Research Notes:
A New Fossil Weevil from Nevada (Coleoptera: Curculion-
idae). Elbert L. Sleeper
Attachment and Growth of the Stoloniferous Ctenostome
Bryozoan, Zoobotryon verticillatum. John S. Bullivant

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Bia IN OF THE SOUTHERN CALIFORNIA
NCNDEMY SOE, SClLENCGES

Vol. 67 JULY-SEPTEMBER, 1968 PART 3

ANURAN SUCCESSION IN A TEMPORARY POND
IN COLIMA, MEXICO

JAMES R. DIXON
Dept. of Wildlife Science,
Texas A & M University

and
W. RONALD HEYER

Dept. of Biological Sciences,
University of Southern California

INTRODUCTION

While studying the herpetofauna of the Nevado de Colima, Jalisco,
we were able to study anuran succession in a temporary pond in a tropi-
cal deciduous forest (Fig. 1). The pond is in the State of Colima on the
road from Colima to Tecoman, 2.4 km E. and 9.6 km S. of Colima at
520 m elevation. The dominant plants of the area are legumes (Acacia
and Prosopis), with an occasional larger tree (Crescentia) and giant
organ cacti (Lemaireocereus).

Our first visit to the pond was daytime, of July 11, 1967. We were
attracted to the dry bed of the pond by male Leptodactylus labialis call-
ing from hidden burrows in the cracked soil beneath rocks, logs, and
debris. Rain began to fall at approximately 0100 hours on July 12 and
continued until 0500. By 0800 about 20 cm of water had collected in
the pond. Bufo marmoreus and Hypopachus variolosus were calling.
We returned the same night and recorded calls of three additional
species: Agalychnis dacnicolor, Diaglena spatulata, and Smilisca baud-
inii. We revisited the site on several days and nights through July 24, to
collect tadpoles, adults and to record calls and new anuran visitors to
the pond.

MATERIALS AND METHODS

Samples of the adult anuran fauna were taken 8 times in the period
from July 11-24. Larval samples were taken at 3-4 day intervals. At-

129

130 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

tempts were made to sample microhabitats and morphologically dis-
tinct larvae. Larvae were returned to the laboratory for identification,
staged (Gosner, 1960), and gut analyses were made on one or two larvae
of three of the species. Only a few gut analyses were made because we
were primarily interested in gross differences in feeding habits and had
only a small sample of some species..

All specimens of adults and larvae have been deposited in the Los
Angeles County Museum of Natural History.

RESULTS

A summary of the visits made to the pond, time of day, choruses, larval
stages at time of collecting, and anurans present but not chorusing, are
given in Table 1.

Species Accounts

Bufo marmoreus — Most of the breeding activity took place during
the day of July 12. Several amplexing pairs were observed and mating
calls were recorded. A few calling males were observed on the night of
July 12, but none were seen or heard during the remainder of the study.

Agalychnis dacnicolor — Adults were found calling from vegetation
in the pond and some distance from the shore on the night of July 12,
and individuals continued to call throughout the study period. Several
individuals were seen on the retaining wall of the pond on the night of
July 12, but none were calling from these positions. Neither amplexus
or eggs were observed, nor were tadpoles collected of this species. How-
ever, during the study period, egg masses were seen in other areas.

Diaglena spatulata — Adults were calling from rock walls, vegeta-
tion, and shoreline only on the night of July 12. Several amplexing
pairs were found in the water. One individual was found on the night of
July 13, crossing the road near the pond, but heading away from the
water. Neither eggs nor tadpoles were collected.

Smilisca baudinii — This species was the most common, both in
terms of adults present and number of larvae observed in the water.
Adults called on every nightly visit and sometimes during the day. Tad-
poles were observed in large swarms at times. Tadpoles were also ob-
served feeding on vegetation on or near the surface of the pond. The
anterior portion of the gut of the larvae has a manicotto (stomach-like,
thickened walls). The total length of the gut is 12 times body length.
The gut of one tadpole (stage 35), was filled with a mucoid-appearing
matrix consisting of filamentous algae and diatoms. The larvae ap-
peared to be scraping the algae and diatoms off of vegetation in the
water. Adults were breeding thoughout the study period. The last sam-

Anuran Succession 131

Figure 1. Photograph of the study site at the termination of the study.

ples of larvae taken from the pond contained three or more temporal
lots.

Leptodactylus labialis — Adult males were calling from terrestrial
“incubating chambers” both night and day during the entire study.
These chambers were found in clay soil, usually beneath rocks, logs, or
other debris. Some chambers contained either calling males, foam nests,
or were empty. The chambers were usually 30-40 mm in depth, with an
entrance 20-30 mm in diameter. (Fig. 2). The main chamber was
approximately 50 mm wide and 65 mm long. Some of the chambers
contained another opening (probably an escape exit) 90-100 mm ina
direction opposite the main entrance, connecting with the chamber by a
tunnel about 10 mm below the soil surface.

On one occasion two chambers were found under the same rock, one
with foam and eggs, the other empty. The foam was about 20 mm below
the surface of the entrance. Yellowish eggs lacking melanophores were
located in the lower half of the foam.

Apparently males attract females to the chambers, where the eggs
are laid. The eggs hatch in the enclosed foam nest and the larvae remain
within the foam until the first rain, at which time they float or swim from
the nest to the pond. One preserved nest contained 247 larvae at devel-

1932 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

opmental stage 25. It is possible more advanced stages may be reached
before flooding releases the larvae from the nest. A second preserved
nest contained 190 eggs. When one nest was uncovered, it flooded with
water, and the larvae swam into the pond.

The majority of the tadpoles were observed in very shallow water
near the edge of the pond. Three larval guts were examined. The gut is
8-10 times the body length. The largest example (stage 38) has a
manicotto; this is not evident in smaller stages (25). The gut contents
consist of a mud-silt matrix, with a few plant fibers and seeds, and
unidentified debris. The larvae apparently ingest bottom material
indiscriminately.

Leptodactylus melanonotus — Adult males and females were first
observed on July 17, but none were calling. A large number were seen
on July 24, again none were calling. The adults may have moved in for
feeding and perhaps establishment of a breeding site. Actual reproduc-
tion may have been delayed because rain had not fallen at the pond
since July 12, and the water level was receding.

Hypopachus variolosus — Adults were observed calling and in
amplexus on July 12. Males were observed calling on July 13 but
amplexus was not observed. Adults were not ‘present at any other time
during the study. Tadpoles of this species were relatively scarce. Im-
proper sampling techniques or low larval survival rates may have
accounted for their scarcity.

One tadpole gut was examined. The gut is 11 times the body length,
and contains a homogenéous, silty-appearing matrix. These tadpoles
seemingly vacuum the pond bottom, selecting small particles, and pass
them to the gut via a mucus cord, as reported by Savage (1955).

Rana pipiens — This ubiquitous frog appeared at the pond on July
20, and was present during the remainder of the study. Never were
they observed calling or in amplexus. This species was commonly en-
countered on the road following every rain, even though permanent
water was several miles away.

DISCUSSION

There are definite differences in breeding periods and appearance of
larvae. Bufo marmoreus, Diaglena spatulata, and Hypopachus vario-
losus are early breeders. They called for only a short period of time (24-
36 hours), and left the pond by the second day following the first rain.
Apparently these three species were less successful in egg laying and
had a lower larval survival than the other species. Eggs of B. mar-
moreus were observed on July 11, larvae on July 14, but larvae were

Anuran Succession 133

Figure 2. Photograph of a foam nest of Leptodactylus labialis. Arrow indicates
opening of the nest which was beneath a rock.

never collected again. D. spatulata eggs and larvae were never found
and the adults had the shortest activity period at the site of all the
anurans. H. variolosus eggs were observed on July 12. Larvae were
taken first on July 17, and occasionally in later larval samples, but
never in abundance.

Leptodactylus labialis and Smilisca baudinii are early breeders. Eggs
and larvae were present on July 11 for L. labialis; eggs of S. baudinii
were present on July 12 and larvae on July 14 and later. Adult males of
the latter species continued to call throughout the study, and amplexing
pairs were observed on at least three different nights. The larvae of
these two species made up the bulk of larvae present at any one time in
the pond.

Agalychnis dacnicolor appeared on the night of July 12 and called
both night and day during the entire period of the study. However,
amplexing pairs, eggs, and larvae were not observed. Nest sites may
not have been available for this species. A. dacnicolor often lays its
eggs in trees or branches overhanging the water. The large shrubs at the
side of the pond (Fig. 1) could have provided adequate nesting sites,

134 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

but the water level never reached under these large shrubs during the
study period. The species may also require a long calling period before
breeding is actually achieved.

Both Leptodactylus melanonotus and Rana pipiens arrived at the
pond towards the end of the study; no breeding activity was observed.

It is apparent that the number of species of adults breeding at any
single time is not indicative of what species of larvae are present in the
pond. There may be more species breeding than number of species of
larvae using the pond at any one time.

The effect of continual rainfall on anuran succession at this site can
only be imagined. Doubtless there would still be a succession, with
some species breeding and leaving shortly after initial pond formation.
The breeding period of some of these species, such as H. variolosus,
might be extended, however. With continual rain, breeding would
probably take place in the later arriving species, such as L. melanonotus
and R. pipiens. It seems likely that at no time would the species of
larvae in the pond exactly coincide with the breeding species.

There is a definite trend towards terrestrial adaptation in Lep-
todactylus labialis, as indicated by the partly terrestrial period of egg
and larval development prior to the first rain. The presence of calling
males, foam, and eggs and larvae in “incubating chambers” substan-
tiates terrestrial breeding activity prior to the availability of standing
water.

Apparently L. labialis has a competitive advantage in survival of
eggs and young because of the “incubating chambers”. Large numbers
of metamorphosing larvae were observed on July 24, indicating an
aquatic larval life of 13 days. The short aquatic larval life is related to
the advanced hatching of the eggs and early larval development in the
“incubating chambers”.

Biotic Interactions: There appears to be both adult and larval eco-
logical segregation. The calling sites of the adults (Fig. 3) are separated
both horizontally and vertically. D. spatulata and S. baudinii are found
most often associated with one another in similar calling sites. They
occupy the same emergent plant tops in the pond, and call from the
shore beneath low lying vegetation, and from open spaces along the
shore. The mating calls of these two species are very different and effec-
tively serve as a premating isolating mechanism (see sonagrams of D.
spatulata in Porter, 1962; S. baudinii in Duellman and Trueb, 1966).
Hypopachus variolosus are found in similar habitats but spacially
segregated from the former two species. That is, all three species might
be expected to call in certain similar situations, but H. variolosus are
never in close proximity to calling males of D. spatulata or S. baudinii.

Anuran Succession 135

Bufo marmoreus calls while floating on the open surface of the pond
and occasionally calls from the periphery of weeds protruding from the
water. Most of the B. marmoreus breeding activity was also temporally
isolated from that of the other species. A. dacnicolor were found in the
tops of tall plants extending 0.67 to | m above the pond’s surface.
Leptodactylus labialis called only from terrestrial burrows along the
shore of the pond, often as high as 0.5 m above and 3 m back from the
water’s edge.

Figure 3. Schematic diagram of the calling sites of anurans on 12 July 1967; A =
Agalychnis dacnicolor, B = Bufo marmoreus, = Diaglena spatulata, H =
Hypopachus variolosus, L = Leptodactylus labialis, S = Similisca baudinii.

The larvae are active both day and night. S. baudinii tadpoles were
found in open water feeding from vegetation, and sometimes were seen
in large swarms. Leptodactylus labialis larvae were in shallower water
near the edge of the pond, and appeared to be feeding on the bottom.
Upon being approached, they darted to deeper water or potholes in the
pond. H. variolosus tadpoles were usually not observed except in the
actual sample sweeps taken from the pond. We assume the majority of
the H. variolosus tadpoles were feeding in deeper water and on the
bottom.

Food analyses of the three above species indicate that they all feed
upon organic detritus and/or plant matter. Their gut lengths are com-
parable but definite segregation in choice of food is evident. H. vario-

136 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

losus are microphagous feeders, S. baudinii feed on diatoms and algae,
and L. labialis feed on dead organic and bottom debris.

Actual predation on tadpoles was not observed, but large bello-
stomatid Hemiptera and dragonfly larvae were present. Other pre-
dators, such as snakes, were not seen.

We do not know the fate of Bufo marmoreus larvae or of the Diaglena
spatulata eggs. These could have been eaten by a predator or we could
have overcollected the adults. The absence of Agalychnis dacnicolor
eggs and larvae remains unanswered. Perhaps suitable nest sites were
not available, or the males call for a long period before females arrive.
The absense of larvae may be because the eggs remain in the nest for
a long period of time. Another rain may have been necessary to induce
Rana pipiens and Leptodactylus melanonotus breeding.

ACKNOWLEDGMENTS

We wish to thank Roy W. McDiarmid, Jay M. Savage, and Priscilla H. Starrett,
of the University of Southern California for their comments on the manuscript.
We are particularly indebted to Priscilla Starrett for stimulating our interests in
anuran larvae.

Travel funds were provided by a NDEA Dissertation Travel Fellowship ad-
ministered by the University of Southern California awarded to the second au-
thor. Other support funds were awarded to the first author from the Los Angeles
County Museum of Natural History. We thank these institutions for their support.

LITERATURE CITED

Duellman, W. E. and L. Trueb, 1966. Neotropical hylid frogs, genus Smilisca.
Univ. Kansas Publ. Mus. Nat. Hist. 17 : 281-375.

Gosner, K. L., 1960. A simplified table for staging Anuran embryos and larvae
with notes on identification. Herpetologica 16 : 183-190.

Porter, K. R., 1962. Mating calls and noteworthy collections of some Mexican
amphibians. Herpetologica 18 : 165-171.

Savage, R. M., 1955. The ingestive, digestive and respiratory systems of the
microhylid tadpole, Hypopachus aguae. Copeia 1955 : 120-127.

Accepted for publication May 22, 1968.

Anuran Succession 27)

TABLE |

Summary of anuran activity at the site July 11-24, 1967

Species Time and Date*

D DINN D DIND N D D
MN W2 W3s 4b A} 2D A wy

Bufo marmoreus Adult C,A
Larvae 23
Agalychnis dacnicolor Adult Cc GG 2c CEs 3 ec
Larvae
Diagleua spatulata Adult GAP.
Larvae
Smilisca baudinii Adult CAGE Cre C
Larvae 20 25-26 25-26,
29-31,35
Leptodactylus labialis Adult C C Cae? =e Ce eve
Larvae 25 28 31-35 38 39 42M
Leptodactylus Adult P > IP IP |e
melanonotus Larvae
Hypopachus variolosus Adult CARE
Larvae DS 27 29 25,28,
29,3
Rana pipiens Adult IPP le
Larvae

* Abbreviations: D = day; N = night; A = amplexing pairs; C = chorus; M =
metamorphosing tadpoles; P = present but not calling; number indicates tadpole
stage.

A NEW SPECIES OF THE GENUS STENISTOMERA
(SIPHONAPTERA: HYSTRICHOPSY LLIDAE)

HAROLD J. EGOSCUE

Ecology and Epizoology Research
University of Utah, Dugway, Utah 84022

INTRODUCTION

Examination of fleas obtained from deer mice collected in southeast-
ern Oregon revealed an undescribed species of Stenistomera Rothschild
1915. This represents the first time this genus has been recorded for the
state. The new species is of special interest since it combines character-
istics of form and chaetotaxy used by Good (1942) to separate the sub-
genera Stenistomera and Miochaeta, and later by Stark (1958) to elevate
Miochaeta to the status of a full genus. The present paper describes
this new flea and places the genus Miochaeta in synonomy.

Genus Stenistomera Rothschild, 1915

Stenistomera Rothschild, 1915, p. 307. Type species: Typhlopsylla

alpina Baker, 1895.

Stenistomera (Stenistomera) Good, 1942, p. 133 [new usage].
Stenistomera (Miochaeta) Good, 1942, p. 135 [new subgenus].
Miochaeta Stark, 1958, p. 104 [new combination]. Type species:

Stenistomera (Miochaeta) macrodactyla Good, 1942.

Good (1942) believed that the following morphological differences
were sufficient to warrant erection of the subgenera Stenistomera and
Miochaeta: head rounded or slightly angulate in Miochaeta not angu-
late as in Stenistomera; all bristles of the head of Miochaeta normal in
size or only slightly enlarged, not greatly enlarged as in Stenistomera;
frontal row of spine-like bristles absent on Miochaeta that are present
on Stenistomera.

Stark (1958) reevaluated these differences and elevated the subgenus
Miochaeta to the status of a full genus.

The new species is in many ways morphologically intermediate
between Stenistomera alpina (Baker, 1895) and Miochaeta macro-
dactyla (Good, 1942) and makes recognition of the subgenera erected
by Good and the genus Miochaeta as proposed by Stark untenable.

Stenistomera hubbardi, new species.
Figures 1-3

Diagnosis: Shares the following characteristics with previously de-
scribed species: a deep interantennal suture and sheath-like projection

138

New Species of Siphonaptera 139

of the second segment of the antennae; several small spiniforms along
the anterior margin of the mesonotum under the pronotal comb;
abdominal terga II-VI with one row of setae; three antepygidial bristles
in both male and female. Resembles S. alpina in general shape and
size of the movable process of the clasper and presence of a prefrontal
row of short, spine-like bristles; and $. macrodactyla in the rounded
outline of the frons, slender pre- and postantennal bristles on the head,
outline of sternum VII in females, and shape of sternum IX in males.
Differing from all known species in the number of spiniforms on ster-
num IX of males and in details of size and structure of the spermatheca
as described below.

Head (Cand 9). Figure 1. Most of the pre- and postantennal bristles
except those along the frons of the holotype are either missing or broken.
Judging from positions of the alveoli where missing bristles were at-
tached and by the length and shape of remaining bristles, chaetotaxy of
the head is similar for both sexes. Frons rounded, helmet-shaped and
similar in outline to S. macrodactyla (Fig. 4). Prefrontal row of seven to
nine short, tapering, almost spine-like bristles along anterior margin of
frons, extending in an elbow-shaped curve almost to the antennae.
Other preantennal bristles consist of two slightly irregular frontal rows
of about three bristles each and an ocular row of two bristles. Eye ab-
sent. Occiput has three rows of one, three and four bristles, respectively.
Several small bristles between dorsal edge of antennal fossae and
bottom bristle of longest row of postantennal bristles. All principal pre-
and postantennal bristles slightly thicker than those of S$. macrodactyla
but not spine-like as in S. alpina (Fig. 7). Maxillary palps short, four-
segmented, extending about 50 percent of the length of the fore coxa.
Pronotal comb of approximately 18 spines in the male and 16 spines in
the female. Anterior border of pronotal comb straighter than S. alpina
but more curved than S. macrodactyla.

Modified Abdominal Segments, Male (holotype): Fixed process of
the clasper, (Fig. 2) resembling both S. alpina (Fig. 8) and S. macro-
dactyla (Fig. 5) in general outline. Movable process similar in size and
shape to S. alpina, but with more convex anterior and concave posterior
margins; two short, thick, blunt, slightly pigmented, subapical spini-
forms near the posterior margin, more widely separated than S. alpina
but closer together than S. macrodactyla. One acetabular bristle, similar
in length and position to S. alpina but more marginal rather than dis-
tinctly submarginal in origin. Apical portion of sternum IX tapering
less gradually than in S. macrodactyla, but lacking the ventral angle of
S. alpina and bearing two closely spaced, short, sharp, unpigmented,
subapical spiniforms of unequal length on the ventral margin; remaining

140 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

2omm

Figures 1 to 3. Stenistomera hubbardi, n. sp. Fig. 1, head of allotype female; Fig.
2, process of clasper and sternite IX, holotype male; Fig. 3, spermatheca of allo-
type female.

Figures 4 to 6. Stenistomera macrodactyla. Fig. 4, head of female; Fig. 5, process
of clasper and sternite IX of male; Fig. 6, spermatheca.

Figures 7 to 9. Stenistomera alpina. Fig. 7, head of female; Fig. 8, process of
clasper and sternite IX of male; Fig. 9, spermatheca.

New Species of Siphonaptera I4I

bristles of sternum IX all small but tending to be thicker at their bases
than those of the other two species.

Modified Abdominal Segments, Female (allotype): Outline of ster-
num VII gently undulating, similar to that of S. macrodactyla but
bearing fewer bristles and with a slightly deeper sinus and more rounded
lobe. Spermatheca (Fig. 3) as in other species (Figs. 6 and 9) but
smaller, hilla proportionately more slender and tipped with a distinct
papilla.

Size (total length, mounted specimens): Male holotype, 2.0 mm;
female allotype, 2.1 mm.

Types. Holotype male and allotype female from a deer mouse,
Peromyscus maniculatus ssp., Ecology and Epizoology Research host
number 16612, collected five miles south of Crane along Highway No.
78, Harney County, Oregon, 23 October 1966, by H. J. Egoscue,
original numbers 4173 and 4172, respectively. One paratype, a frag-
ment consisting of head, thorax and proleg, sex unknown but believed
to be a male (H. J. E. number 4563) with same data.

The holotype male and allotype female will be deposited in the U.S.
National Museum, Washington, D. C. The paratype will remain in the
Ecology and Epizoology Research reference collections, University of
Utah, Dugway, Utah.

It gives me pleasure to name the species after Dr. C. Andresen
Hubbard, in recognition of his numerous contributions to the know-
ledge of fleas of the western United States.

Discussion: The type locality of S. hubbardi is in arid desert country
characterized by scanty rainfall and wide annual range in temperatures
and is similar ecologically to areas in western Utah where S. macro-
dactyla is found. I believe the general scarcity of S$. macrodactyla and
S. alpina in collections can be attributed to the fact that both are winter
fleas. Year around collecting in Utah’s Bonneville Basin has revealed
these species are most numerous on their preferred hosts during colder
months but are rare or absent in other seasons. Studies in New Mexico
(Morlan, 1955) and southern Nevada (Beck and Allred, 1966) tend to
verify winter maxima for S. alpina in those areas. Stenistomera hub-
bardi also may reach its maximum abundance in winter, which could
explain why it remained undiscovered until now.

The deer mouse may be a chance host of S$. hubbardi. Some likely
possibilities for normal hosts include the desert wood rat, Neotoma
lepida. Judging from the number of occupied houses, wood rats were
common at the type locality of S. hubbardi. Despite special efforts to
collect them, no wood rats were obtained the one night I spent in the
area.

142 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

Except for travel expenses, this work was accomplished under Dugway Proving
Ground U.S. Army Research and Development Contract Nos. DA-42-007-
AMC-35(R) and DA-42-007-AMC-227(R) with the University of Utah, and
reported as Ecology and Epizoology Contribution No. 140. Thanks are extended
to D. Elmer Johnson and Robert E. Elbel for many helpful suggestions and
criticisms.

LITERATURE CITED

Beck, D. E., and D. M. Allred, 1966. Siphonaptera (fleas) of the Nevada Test
Site. Brigham Young Univ. Sci. Bull., 7 (2), 27 p.

Good, N. E., 1942. Stenistomera (Siphonaptera): A reevaluation of the genus,
with the description of a new subgenus and species. Proc. Ent. Soc. Wash.,
44:131-139.

Morlan, H. B., 1955. Mammal fleas of Santa Fe County, New Mexico. Texas
Rept. Biol. Med., 13 : 93-125.

Stark, H. E., 1958. The Siphonaptera of Utah. U. S. Dept. Health, Educ. and
Welfare, Pub. Health Ser., Communicable Disease Center, Atlanta, Ga., 239 p.

Accepted for publication April 15, 1968.

RITTERELLA RUBRA AND DISTAPLIA SMITHI:
TWO NEW COLONIAL ASCIDIANS
FROM THE WEST COAST OF NORTH AMERICA

DONALD P. ABBOTT AND WINONA B. TRASON

Hopkins Marine Station of Stanford University, and
Monterey Peninsula College, Monterey, California

INTRODUCTION

Collections of ascidians from the low intertidal regions of the rocky
shores of central California have repeatedly included two highly dis-
tinctive colonial forms which could not be placed in any known species.
They are described here as new species in the genera Ritterella and
Distaplia.

Ritterella rubra n. sp.

Description: Colony bright scarlet red in life, fading to orange in
preservation. Individual heads capitate, joined at the base by stolons
(Fig. 1 A). Smallest heads about 3 mm in diameter, largest about 14
mm. Exposed surface of the colonies clean and free of debris; stalks
and stolons encrusted with bits of shell and sand (Fig. 1 A). Each head
may contain from 6 to 70 zooids not arranged in systems (Fig. | A).
Branchial and atrial apertures visible on surface of colony but most of
the zooids obscured by pigment cells in test (Fig. | A).

Zooids vary in length from 5 mm to 15 mm although variation
within a single head is small. Length of thorax and abdomen combined
between 2.5 mm and 5 mm. Length of postabdomen from shorter than
the combined length of the thorax and abdomen to more than twice as
long. Variations similar in those with and without gonads.

Mantle musculature not well developed. Anesthetized, preserved
specimens show little severe distortion of the thorax although the num-
ber of gill slits may be difficult to count.

Thorax with both atrial and branchial siphons well developed. Each
aperture six-lobed (Fig. | B). Two orders of tentacles with 6 in each, a
third order of twelve may be present. Number of rows of gill slits from
10 to 13 with from 11 to 15 gill slits per row when viewed laterally (Fig.
| B). Counts made from within the pharynx on dissected specimens
show 16 to 20 per row. One well developed curved languet lies between
adjacent rows dorsally.

Oesophagus short, curving to enter stomach dorsally (Fig. | B).
Stomach round to ovate, covered with areolations and with a dorsal

143

144 Bulletin So. Calif. Academy Sciences|/Vol. 67, No. 3, 1968

— oan c Figure 1. Ritterella rubra, n. sp.
A. Portion of colony showing
several capitate lobes; drawn from
life. B. Mature zooid, removed
from test; composite drawing.

C. Tadpole larva.

raphe (Fig. 1 B). Intestine with pronounced valve anterior to loop (Fig.
1 B). No marked twist to gut which ends in a two-lipped anus at the
level of the 5th row of gill slits from the posterior end of the pharynx
(Fig. 1 B). Pyloric gland on the ascending loop of intestine with duct
entering stomach postero-dorsally (Fig. | B).

Reproductive organs well developed in specimens taken May through
July; lacking in those taken in November. Ovary lies some distance
behind gut loop (Fig. 1 B). Numerous testes lobes lie in a double row
in the postabdomen behind the ovary; a few lobes may lie anterior to
the ovary. Sperm duct runs from testes lobes through postabdomen
and abdomen along the hind gut to terminate near the anus (Fig. | B).
Oviduct follows a similar course.

Larvae in different stages of development present in the atrium.
Internal structure of larva obscured by large quantities of yolk. Body of

New Species of Ascidians 145

larva about 0.8 mm. in length. Three adhesive papillae in a row ante-
riorly and about three rows of 4 ampullae. Otolith and ocellus present
(ice @):

Diagnosis: Colony composed of bright red capitate heads joined by
basal stolons. Zooids not arranged in systems. Individual zooids with
well developed six-lobed branchial and atrial siphons opening on the
surface. Stomach ovate, with areolations, into which the oesophagus
enters dorsally.

Material examined: Carmel Cove, Monterey County, California.
Several collections from under rocky ledges in low intertidal. Pescadero
Point, Monterey County, California. Several collections from under
rocky ledges in low intertidal. Point Pinos, Monterey County, Cali-
fornia. One collection from under rock in low intertidal.

Holotype: U.S. National Museum number 11951. May 29, 1949.
Carmel Cove, Monterey County, California. Under rocky ledge. Zone
4. D. P. Abbott, collector.

Paratypes: U.S. National Museum number 11952. November 28,
1947. Pescadero Point, Monterey County, California. On rocks in cave,
Zone 4. D. P. Abbott, collector. California Academy of Sciences Num-
ber 228. July 3, 1947. West shore of Point Pinos, Pacific Grove,
Monterey County, California. Under rock in Zone 4. Unprotected
rocky shore. V. House and W. Fox, collectors. Los Angeles County
Museum Number 1164. November 28, 1947. Pescadero Point, Mon-
terey County, California. On rocks in cave, Zone 4. D. P. Abbott,
collector.

Discussion: The genus Ritterella was set up by Harant (1931) for R.
aequali-siphonis, a species which had been described originally by
Ritter and Forsyth (1917) as Amaroucium aequali-siphonis. Harant’s
definition of the genus included: a well developed postabdomen, atrial
and branchial siphons 6 lobed, both siphons opening on the surface, no
systems present and a stomach which is not smooth.

Harant (1931) also set up a new subfamily Pseudodistominae with-
in the family Polyclinidae for those Polyclinids with lobed siphons
placed at the same level and without a cloacal languet:

“Polyclinidés a siphons semblables ordinnairement lobés placés
au méme niveau, dépourvus de languette cloacale.” (Harant, 1931,
p. 22)

He placed 4 genera in the subfamily separated as follows:

1. Stomach smooth; numerous rows of stigmata;
— Oesophageal-intestinal length two times longer than the
PlanynxXeasplacent amr en er ee Placentela Redikorzev

146 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

— Oesophageal-intestinal length much shorter than the pharynx;
Nonplacentay ees Ben eae eee Homeodistoma Redikorzev

2. Stomach not smooth;
— 3 rows of stigmata; testes lobes divided in two by their entry

IMO Che SPERM GUC tee y eee Pseudodistoma Michaelsen
— more than 4 rows of stigmata; testes lobes not having this
Character yee 6 ee ee ae ean Ritterella Harant

Considerable confusion and discussion has developed over these
genera largely because later workers were unaware of Harant’s paper.

Oka (1933) set up a new genus, Sigillinaria, in which the type species
was S. clavata. Definition of the genus was brief: body divided into
thorax, abdomen and postabdomen and the two body apertures open to
the outside. This description was equivalent to that of Harant’s whole
subfamily Pseudodistominae.

Using Oka’s generic definition, Van Name (1945) placed what had
been described as Amaroucium aequali-siphonis and Distoma pulchra
in the genus Sigillinaria as S. aequali-siphonis and S. pulchra. Both
species have stomachs with longitudinal plications.

Kott (1957) refers to the type species, S. clavata, in order to include
the presence of a smooth stomach in the generic description. She con-
cludes that if this is done Placentela and Sigillinaria “...cover the
same range of characters and therefore the latter name must be replaced
by Placentela, which has priority.... The definition of Ritterella
may be conveniently expanded to include species with more than 3
rows of stigmata and with a longitudinally folded stomach.” (Kott,
1957, p. 100). This results further in the species designated by Van
Name as S. aequali-siphonis and S. pulchra (formerly Amaroucium
aequali-siphonis or Ritterella aequali-siphonis and Distoma pulchra)
being placed in the genus Ritterella, an arrangement which brings R.
aequali-siphonis back to the genus set up for it by Harant in 1931.

Millar (1960) describing a new species, R. vestita, concludes that
Ritterella and Sigillinaria are synonyms.

Careful study of the original descriptions of Sigillinaria clavata Oka
(1933) and Placentela crystallina Redikorzev (1913) and of specimens
of what appear to be Placentela lacking the diagnostic placenta has led
to the tentative conclusion that these could well be members of the
same genus. A final decision would depend on study of the type speci-
mens. If this proves correct, then Sigillinaria would be synonymous
with Placentela, the latter having priority as noted by Kott (1957).

In view of the existing confusion, the present investigators have

New Species of Ascidians 147

decided that for the present, Harant’s (1931) subfamily and generic
distinctions are most dependable and workable and therefore have
placed this new species in the genus Ritterella as defined by Harant.
Other species in the genus have a stomach with longitudinal plications
but this character need not limit the genus at this time.

The specific name refers to the characteristic color of the living
colony.

Distaplia smithi, n. sp.

Description: Colony composed of up to 100 or more club-shaped or
paddle-shaped lobes, borne on slender stalks up to 5 cm long arising
from a basal mat of stolons (Fig. 2 A). Smaller lobes narrow, gray to
whitish, translucent, and free of encrustation; larger lobes with dis-
tinctly flattened, rectangular or fan-shaped heads, up to 2 cm across.
Older heads, stalks, and stolons opaque, often pigmented orange-brown,
and sometimes encrusted with foreign matter.

Zooids with oral apertures opening on one flattened side of each
head, and with bodies oriented approximately at right angles to the
main axis of the head and stalk (Fig. 2 B, C). Zooids arranged in
systems, each consisting of two rows of individuals and between them
a straight, tubular common cloacal canal running parallel to the main
axis of the head and terminating distally in a pore (Fig. 2 B). One to 8
systems present per head; where more than one occurs the common
cloacal canals lie parallel to one another or diverge slightly distally, and
open separately to the outside. Zooids on the two sides of each system
are alternately placed, and oriented with atrial apertures angling both
inward, toward the common cloacal canal, and distally, toward the tip
of the lobe (Fig. 2 A). In each system zooids show a gradation in age,
the oldest ones lying near the common cloacal pore and new individuals
entering the system at the proximal tip of the canal (Fig. 2 A, B).

Zooids generally characteristic of the genus Distaplia. Mature indi-
viduals 4-5 mm long, with a thorax slightly longer than the abdomen.
Oral siphon with margin smooth or slightly undulating, not lobed.
Atrial aperture in juvenile zooids round, smooth-edged, and borne on a
tubular siphon (Fig. 2 F); aperture in adults enlarged, forming an
asymmetrical gap in the mantle on the side facing the canal into which it
empties, and bearing an extended atrial languet on the opposite side
(Fig. 2 D). Mantle musculature delicate (Fig. 2 E). Fully grown zooids
usually with 12 tentacles, of two sizes alternately arranged (Fig. 2 D).

Pharynx with 4 rows of stigmata, each row with 15-23 stigmata;
variation in number of stigmata per row usually not greater than 1-3
between different rows in the same individual. Parastigmatic transverse
vessels always present in zooids which have developed to the feeding

Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

148

ay
money

=
ide = = RS
S/S5/2 S Z
SS
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New Species of Ascidians 149

stage. Stomach pear-shaped, tapering posteriorly, the wall bearing fine
longitudinal or irregular sculpturing (Fig. 2 I-N); pyloric valve poorly
developed. Intestinal loop compact, rectum rising dorsal to, and slight-
ly to the left of, the esophagus. Commonly two vascular processes,
separate or joined, extend into the test from the posterior border of the
abdomen. In flattened heads the larger zooids may have the abdomen
bent at right angles to the thorax (Fig. 2 B).

Gonad lying on the right side of the abdomen, anteriorly nearly
filling the intestinal loop, posteriorly extending up to 1 mm beyond the
loop when fully enlarged. Gonad hermaphroditic consisting of an
anterior cluster of testes and a posterior ovary, both male and female
elements always visible in stained material. However, gonad develop-
ment is somewhat protandrous (Fig. 2 I-N), thus some young zooids
appear almost wholly male (Fig. 2 I), and some old zooids may appear
very largely female (Fig. 2 N). Common sperm duct tortuously coiled
as it leaves the gonad, then extending straight anteriorly along the right
side of the hind gut to terminate near the anus. Oviduct enters the brood
pouch, which arises postero-dorsally on the right of the thorax (Fig. 2 I,
K-N). Detached brood pouches containing 1-5 developing larvae (Fig.
2 G), some isolated larvae free of brood pouches, and even a few meta-
morphosed larvae are found lying in the tunic below mature zooids
with regressed gonads. Larvae are equipped with both ocellus and
otolith (Fig. 2 H), and are apparently liberated by dissolution of tunic.

Diagnosis: Colony formed of clusters of paddle-shaped lobes, usually
expanded and flattened distally, with all zooids opening on one flat
surface. Zooids borne in double rows along straight, tubular common
cloacal canals; up to 8 systems in a single lobe, each with its own canal
and terminal pore. Zooids of the Distaplia type, with oral aperture
smooth, atrial aperture large and asymmetrical in mature zooids, 4

Figure 2. Distaplia smithi, n. sp. A. Portion of a colony showing lobes and ar-
rangement of zooids ‘in systems. B. Lontitudinal section through a system, show-
ing zooids arranged along common cloacal canal. C. Cross section through a head
bearing two systems, showing common cloacal canals. D. Fully grown zooid,
gonads not developed. E. Thorax of mature zooid, showing mantle musculature.
F. Immature zooid. G. Brood pouches, removed from test. H. Tadpole larva. I-N.
Abdomens, seen from right side, showing gonads in various stages of development.
I. Immature zooid, gonad largely male, no sperm in sperm duct. J. Testes fully
enlarged, some sperm in common sperm duct; ovary still small. K. Ovary
enlarged, testes declining in size, sperm duct enlarged. L. Ovary enlarged, testes
shrunken, common sperm duct gorged with sperm. M. Ovary enlarged, testes
very small, sperm duct still containing considerable sperm. N. Ovary enlarged,
testes fully regressed; some sperm still stored in sperm duct, but gonad appears
almost wholly female.

150 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

rows of stigmata, parastigmatic vessels, and hermaphroditic gonads.
Developing embryos borne in a brood pouch, and equipped with ocellus
and statolith.

Material examined: Knoles Head (mainland West of Cordova),
Prince William Sound, Alaska. Intertidal. June 4, 1965. Stoner B.
Haven, collector. Ucluelet, Vancouver Island, B. C., Canada. Intertidal.
May 31, 1965. Ivan Goodbody, collector. Victoria, Vancouver Island,
B. C., Canada. W. Gordon Fields, collector. Otter Rock, Oregon.
Washed on beach by a storm. February, 1956. Dale Snow, collector.
Shell Beach, Sonoma County, California. In small caves and on sides of
intertidal channels. June 26, 1956. Cadet Hand, collector. Dillon
Beach, Marin County, California. Low intertidal rocks out from Second
Sled Road. Numerous collections. Moss Beach, San Mateo County,
California. Low intertidal. No further data. Asilomar State Park,
Pacific Grove, Monterey County, California. Low intertidal rocks.
Several collections. Pescadero Point, Pebble Beach, Monterey County,
California. Low intertidal channels and caves. Many collections. Car-
mel Mission Point, Carmel Bay, Monterey County, California. Low
intertidal channels and among Phyllospadix. Many collections.

Holotype: U.S. National Museum number 11953. May 24, 1959.
Carmel Point, Monterey County, California. Under ledge, on rocks.
D. P. Abbott, collector.

Paratypes: U.S. National Museum number 11954. April 14, 1956.
Carmel, Monterey County, California. D. P. Abbott, collector. Cali-
fornia Academy of Sciences number 229. March 23, 1952. Pescadero
Point, Monterey County, California. D. P. Abbott, collector Los Ange-
les County Museum number 1165. April 14, 1956. Carmel, Monterey
County, California. D. P. Abbott, collector.

Discussion: D. smithi is highly distinctive among the colonial
ascidians of the rocky shores of North America, and there is little
chance of mistaking it for any other species. It resembles some of the
published illustrations of species of Sycozoa in the form of the colony
and the organization of the systems. It seems highly likely that this is
the “Sycozoa (Colella) sp.” which Huntsman (1912, p. 115) reported
he and others had found “in quantity” at Ucluelet, B. C., in 1909; it is
certainly the “Distaplia sp.” in dichotomy 24 in the Key to the Littoral
Ascidians of the Central California Coast (Abbott, p. 307, in Light,
Smith et al, 1954); and it looks very much like the species shown in
figure 36A (a photo credited to D. P. Wilson) in Forest, (1957).

The species is locally abundant in many areas, growing most pro-
fusely in the low intertidal zone under rocky ledges, in cave-like spaces
below large rocks, and along the sides of deep rocky channels, in

New Species of Ascidians 151
PRINCE WILLIAM SOUND, ALASKA

UCLUELET AND
VICTORIA, B. C.

DILLON BEACH, CALIF.

NUMBER OF ROWS COUNTED

CARMEL BAY, CALIF.

23 GR oC pBON AS) ales a NS) Ug ahh
NUMBER OF GILL SLITS PER ROW

Figure 3. Distaplia smithi, n. sp. Number of gill slits per row in specimens taken
at different localities.

regions where it is always well shaded, and protected from direct wave
action but subjected to pronounced currents of fresh cold water. The
lobes of the colony swing freely in moving water, and it appears that
there is constant erosion at the tips of the lobes, resulting in loss of old
zooids and test distally as new individuals are added to the systems
from the stalk, proximally.

Colonies from the northern and southern ends of the known geo-

152 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

graphic range are quite similar, though the northern colonies tend to
be smaller and have shorter stalks; further, the number of stigmata per
row tends to be higher in the northern latitudes (Fig. 3).

The species is named in honor of Professor Ralph I. Smith, Depart-
ment of Zoology, University of California at Berkeley, under whom
both of the authors obtained doctorates in researches on ascidians.

D. smithi clearly possesses the characteristics of the Holozoinae as
defined by Berrill (1950), including the presence of a brood pouch. The
species had been assigned to the genus Distaplia, after some initial
hesitation, on the basis of its parastigmatic vessels, a finely plicated
stomach wall, hermaphroditic gonad, and presence of both ocellus and
otolith in the tadpole larva. The question of the separateness of the
genera Distaplia, Holozoa, and Sycozoa has been discussed by Van
Name (1945), Brewin (1953), and Millar (1960), among others.
Brewin (1953) has united Holozoa with Distaplia, under the latter
name (as nomen conservandum), and has separated the species D.
fasmeriana into a separate genus Hypsistozoa. Millar (1960) concurs
with the demise of Holozoa, and presents additional evidence that
Distaplia and Sycozoa are doubtfully distinct. At present there are
many species which need careful reinvestigation, including some species
with rather anomolous constellations of characters (e. g., D. australensis
Brewin, and D. mikropnoa Sluiter, which while hermaphroditic, lack
parastigmatic vessels and S$. anomala Millar, which has both unisexual
and hermaphroditic zooids (Millar, 1960). Determination of the condi-
tions of sexuality in a species, especially where a fair degree of pro-
tandry occurs, may require the examination of more and better material
than is sometimes available to investigators, and it is safe to say that if
only certain colonies of D. smithi had been seen, the present investi-
gators might have reported only males, or only females, or only herma-
phrodites. Millar (1960) has pointed out the confusion that might result
from uniting Distaplia and Sycozoa at the present time, and the writers
feel revision of the genera should only follow a careful reinvestigation
of many species.

SUMMARY

Two new species of colonial ascidians from the Central California
coast, Ritterella rubra and Distaplia smithi are described and taxonomic
problems related to the genus Ritterella and to the three genera, Dis-
taplia, Holozoa and Sycozoa are reviewed.

New Species of Ascidians 153

LITERATURE CITED

Berrill, N. J. 1950. The Tunicata with an account of the British species. Ray
Soc. London. 354 p.

Brewin, B. I., 1953. Australian ascidians of the subfamily Holozoinae and a
review of the subfamily. Trans. Roy. Soc. New Zealand, 81 : 53-64.

Forest, J., 1957. Strange wonders of the sea; translanted and adapted from his
‘Beauties du fond des mers’, by H. Gwynne Vevers. Doubleday. 102 p.

Harant, H., 1931. Contribution a histoire naturelle des ascidies et leurs para-
sites. Ann. Inst. Oceanog., Monaco. N.S. 8: 1-165.

Huntsman, A. G. 1912. Ascidians from the coasts of Canada. Trans. Canadian
Inst. Ann. 1911: 111-148.

Kott, P., 1957. The ascidians of Australia. II. Aplousobranchiata Lahille;
Clavelinidae Forbes and Hanly and Polyclinidae Verrill. Australian Jour.
Marine and Freshwater Res. 8 : 64-110.

Light, S. F., Smith, R. et al, 1954. Intertidal Invertebrates of the central Cali-
fornia coast. Univ. Calif. Press. 446 p.

Millar, R. H., 1960. Ascidiacea. Discovery Reports, 30: 1-160.

Oka, A., 1933. Uber Sigillinaria, eine neue Synascidiengattung aus Nordpazifik.
Proc. Imp. Acad. Tokyo 9 : 78-81.

Redikorzev, V., 1913. Neue Ascidien. Zool. Anzeiger. 43 : 205-213.

Ritter W. and Forsyth, R. A., 1917. Ascidians of the httoral zone of southern
California. Univ. Calif. Publ. Zool. 16 : 439-512.

Van Name, W. G., 1945. The North and South American ascidians. Bull. Amer.
Museum Nat. Hist. 84 : 1-476.

Accepted for publication June 7, 1968.

154 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

Abbreviations of labels used on drawings

bp brood pouch

ccl common cloacal canal
dz degenerating zooid

e esophagus

od oviduct

OV ovary

p parastigmatic vessel
pam pyloric ampulla

r rectum

sd sperm duct

t p terminal pore of common cloacal canal

vp vascular process

A NEW CHIGGER (ACARINA, TROMBICULIDAE)
FROM A BAT, TADARIDA FEMOROSACCA,
TAKEN IN SONORA, MEXICO

RICHARD B. LOOMIS AND LYNELL K. TANIGOSHTI!

Department of Biology,
California State College at Long Beach

INTRODUCTION

Examination of more than 1200 individuals representing 25 species of
bats from northwestern Mexico has resulted in the recovery of more
than thirty five species of chiggers. The following new species was taken
from a single pocketed free-tailed bat obtained in southern Sonora. It is
tentatively placed in the genus Trombicula, sensu lato, of the tribe
Trombiculini, as it does not seem to belong to any of the other genera
which regularly parasitize bats of the New World.

The new species described below bears the name of the collector and
illustrator and we wish to extend our appreciation to him for his
contributions.

Trombicula spathi, sp.n.
Figure |

Types: Larvae, holotype and 17 paratopotypes from 13 kilometers
south southeast of Alamos on the Rio Cuchujaqui, Sonora, Mexico,
from a pocketed free-tailed bat, Tadarida femorosacca (Merriam),
original number LCS650718-2, taken 18 July 1965 by L. C. Spath, R.
B. Loomis and J. L. Fowler. The types are in the chigger research
collection, California State College at Long Beach, and paratypes will
be distributed to appropriate institutions and individuals.

Diagnosis: LARVA. Similar to Trombicula usitata Brennan 1965,
but differing from it in having 1 long nude and 6 branched setae on
palpotarsus; posterior margin of scutum slightly rounded; coxa III with
two branched setae; and one nude mastitarsala III.

Description: LARVA. Holotype (measurements in microns, with
differences among paratypes listed in parentheses).

Body: Fully engorged, 354 by 224, color in life orange; eyes 2/2,
anterior larger, ocular plate distinct, color in life red, length across
both eyes 25, width 10.

1 Present address Department of Biological Control, University of California,
Riverside.

155

156 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

Figure 1. Trombicula spathi, sp.n.

A. Scutum and eyes; B. Body setae, d, dorsal v, ventral; C. Gnathosoma, dorsal
aspect; D. Palpotibial segment, ventral aspect; E. Coxa III; F., G., H., Legs I, II,
and III, with nude setae (measurements in microns) and representative branched
setae.

New Species of Chigger 157

Dorsal setal formula 2-6-6-6-4 + 20, total 54; humeral seta 31, seta
of first posthumeral row 28, posterior dorsal seta measuring 24. Ventral
setal formula 2-2 + 24, total 28; first sternal seta 24, posterior ventral
seta measuring 22. Total body setae 82.

Scutum: Subpentagonal, posterior margin weakly rounded; antero-
lateral setae slightly shorter than other subequal scutal setae, scattered
puncta; sensilla flagelliform with 5-7 branches on distal half; sensillary
bases anterior to bases of PL’s.

Scutal measurements of holotypes and (in parentheses) the mean and
range of 10 paratypes: AW, 55 (59, 55-57); PW, 75 (76.1, 73-78); SB,
21 (22.3, 21-24); ASB, 21 (22.8, 21-24), PSB, 17 (18.9, 17-22); AP,
29 (28, 26-29); AM, 21+ (24.1, 22-27); AL, 27 (26.3, 23-30); PL,
34 (31.2, 30-34); S, 56 (55.4, 49-59).

Gnathosoma: Cheliceral blade long and slender, slightly curved,
with tricuspid cap; cheliceral base punctate. Capitular sternum with
pair of branched setae. Galeala nude. Palpal setal formula B/B/NNB;
palpotarsus with one long nude and six branched setae and tarsala, 6,
palpotibial claw trifurcate, with central prong largest and curved
inward.

Legs: Leg I coxa, trochanter, and basifemur each with branched
seta, telofemur with 5 branched setae, genu with 4 branched setae, 3
genualae, and microgenuala, tibia with 8 branched setae, 2 tibialae,
and microtibiala, tarsus with approximately 18 branched setae, striated
tarsala (13), microtarsala, subterminala, parasubterminala, and pre-
tarsala; leg II coxa and trochanter each with branched seta, basifemur
with 2 branched setae, telofemur with 4 branched setae, genu with 3
branched setae and dorsal genuala, tibia with 5 branched setae, and 2
dorsal tibialae, tarsus with approximately 14 branched setae, striated
tarsala (16), microtarsala, and pretarsala; leg III] coxa with 2 branched
setae, trochanter with branched seta, basifemur with 2 branched setae,
telofemur with 3 branched setae, genu with 3 branched setae and dorsa
1 genualae, tibia with 6 branched setae and dorsal tibiala, tarsus with
approximately 12 branched setae and short mastitarsala. Lengths of
legs (holotype) I, 214; II, 225; III, 256; total index, 695. All legs with
segments punctate and ending in two lateral claws and a long slender
median empodium, all without tenent hairs (onychotriches).

Ecological notes: The larvae of T. spathi were found on the wing
membranes. The host was caught in a mist net placed over a shallow
pool along the Rio Cuchujaqui which flows through a mixed tropical
deciduous and thorn forest.

Specimens examined: 18 larvae of type series.

158 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

LITERATURE CITED

Brennan, J. M. 1965. Two new species and other records of chiggers from
Texas (Acarina: Trombiculidae). Acarologia 7:79-83.

Vercammen-Grandjean, P. H., 1960. Introduction a un essai de classification
rationelle de larves de Trombiculinae Ewing 1944 (Acarina-Trombiculidae).
Acarologia 2:469-471.

Accepted for publication June 7, 1968.

VARIATION, DISTRIBUTION AND SYSTEMATIC STATUS
OF THE BLACK-HEADED SNAKE
TANTILLA YAQUIA SMITH

Roy W. McDIARMID

Department of Biological Sciences
University of Southern California,
Los Angeles, California 90007

INTRODUCTION

In August of 1959, David B. Wake and I collected a specimen of
Tantilla in the vicinity of Ruby, Santa Cruz County, Arizona, that
exhibited several morphological characteristics unknown in species of
Tantilla reported from the United States at that time. In 1962 I collected
additional specimens of this species during the course of a herpeto-
faunal survey of the lowlands in southern Sonora and Sinaloa, Mexico.
Subsequent investigation revealed that these snakes are Tantilla yaquia.
The acquisition of new material led me to initiate a project to analyze
variation and distribution in the species in order to clarify its status.

HISTORICAL REVIEW

Smith (1942) described Tantilla yaquia from a single specimen (MCZ
43274) collected at Guasaremos, Chihuahua by H. S. Gentry and noted
the probable relationships between T. yaquia and T. eiseni Stejneger.
Two years later, Hartweg (1944) described T. bogerti from Acaponeta,
Nayarit. He mentioned the similarities between bogerti and yaquia
but distinguished bogerti on the basis of fewer subcaudal scales. Smith
and Van Gelder (1955) discussed a specimen of 7. yaquia from Costa
Rica, Sinaloa and stated that none of the features of their specimen
affected the status of 7. bogerti. In contrast, Zweifel and Norris
(1955) thought that their specimen from Mirasol, Sonora showed
characteristics of both yaquia and bogerti and allocated bogerti to the
synonymy of yaquia, but recognized T. y. yaquia in Sonora and T. y.
bogerti in northern Nayarit.

McCoy (1964) reported two specimens of 7. yaquia from Bisbee,
Arizona and confirmed the conspecificity of yaquia and bogerti. He
noted the clinal variation of certain meristic characters and suggested
that additional material might support subspecific designation of the
Arizonan population. Fowlie (1965) listed additional locality records
of T. yaquia from the Pajarito Mountains of southern Arizona.

Tanner (1966) suggested that T. atriceps (Gunther), T. yaquia, and

159

160 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

T. bogerti (among others) were subspecies of Tantilla planiceps (Blain-
ville) of Baja California. Stebbins (1966) followed Tanner’s arrange-
ment.

In their treatment of the herpetofauna of Sinaloa, Hardy and Mc-
Diarmid (1968) suggested that 7. yaquia, atriceps, and planiceps are
not conspecific. They also pointed out the clinal nature of the character-
istics utilized by Tanner (1966) to distinguish between bogerti and
yaquia in Sinaloa. Accordingly, they placed 7. yaquia bogerti in
synonymy with 7. yaquia.

CHARACTER ANALYSIS

Thirty-three characteristics of all available specimens of Tantilla
yaquia were analyzed. Most of these characters concern scalation or
coloration. Because of the gaps in the range of the species (Fig. 1) and
for purposes of analysis, specimens of T. yaquia are grouped as: A, a
northern population in southern Arizona and northern Sonora, B, a
central population in Chihuahua, southern Sonora and northern Sinaloa,
and C, a southern population in southern Sinaloa and Nayarit.

SCALATION

Ventrals: Because of possible dimorphism in the number of ventrals
and subcaudals, each sex is considered separately for each of the three
populations. The sex was determined by dissection. Ventrals were
counted according to the Dowling system (1951). The number of
ventrals is 134-157 (k = 146.2) in males and 145-165 (x = 152.6)
in females. In males from population A the ventrals are 145-157 (x
= 151.4; N = 5), in population B, 139-154 (144.0; N = 7), and in
population C, 134-150 (145.0; N = 5). The number of ventrals in
females from population A is 155-165 (159.1; N = 8), population B,
145-153 (148.9; N = 9), and in population C, 146-154 (149.2; N
= 5). Thus, females generally have more ventrals than males in the
same population. On the average, the difference is greater between
males and females in population A than it is between males and females
of populations B or C.

Subcaudals: The subcaudal series is incomplete in many specimens
due to broken tails. The subcaudal number is 46—75 (x = 61.9;N =
16); these extremes are found in females. Males have 50-73 subcaudals
(x = 59.8; N = 13). Because of the length of the hemipenis, males
of most snake species have more subcaudals than do females. The
difference between male and female subcaudals in 7. yaquia is not
consistent in the three populations. In fact, in population A, females
average more subcaudals than males. In population A males have 62-75

(x = 66.0; N = 4) subcaudals, and females 62-75 (68.5; N = 6). In

The Black-Headed Snake 161

population B males have 62-64 (62.7; N = 4) subcaudals, and the
females 57-67 (61.1; N = 7). Subcaudals in population C are 50-56
(52.4; N = 5) in males and 46-53 (49.0; N = 3) in females. More
specimens are required to verify the differences in subcaudals for
population A.

Males and females from population B, on the average, have more
ventrals than they do in population A, and slightly less than in popula-
tion C. In contrast, a comparison of the average counts of subcaudals in
both males and females among the three populations indicates that
there are fewer in the south. Between populations B and C, this dif-
ference in the males is more than twice that exhibited between popu-
lations A and B. In females, however, the difference between B and C is
only about one-third greater than the difference between A and B.

Ventrals plus subcaudals (total): Figure 2 illustrates the difference in
ventrals plus subcaudals for the three populations. The data strongly
suggest that the decrease in ventrals plus subcaudals from north to
south is clinal. However, small sample sizes obviate the use of meaning-
ful statistical comparisons which will have to await the collection of
additional material. In both sexes the decrease is always greater between
populations A and B than it is between populations B and C.

Head scales: The preocular, postocular and temporal scales are
generally consistent in number. All specimens examined have one
preocular and two postoculars. In most specimens, the nasal and
preocular scales are in contact; the contact may be broad or narrow.
In a few cases the prefrontal is in contact with the second supralabial
and separates the nasal from the preocular. Nearly all specimens ex-
hibit one elongate primary and one elongate secondary temporal. The
secondary temporal is fused with the primary temporal on the left side
in one specimen from Sinaloa (JFC 62-53). The loreal scale is absent
from all specimens.

The mental scale is separated from the chin shields by the first pair of
infralabials in most specimens. Only two individuals from Arizona
possess a contact between the mental and the chin shields. Seven speci-
mens from population B, including the type of 7. yaquia, have this
contact. In one specimen (ASU 5836) the contact is present on one
side only. In the other 10 specimens from population B, there is no
contact. Few individuals have the mental and chin shields widely sep-
arated. None of the snakes from Sinaloa or Nayarit exhibits a mental-
chin shield contact.

The labial scales generally are consistent throughout the range of
Tantilla yaquia. There are seven supralabial scales and six infralabial
scales in most of the specimens examined. It can be argued that the

162 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

seventh supralabial, the largest, is not a labial scale because it borders
the lip only for a short distance along its margin. However, because of
its free overlapping lower edge, large size, and position in the labial
series, it is considered a supralabial in this study. There is no geo-
graphic consistency to deviation from the normal supralabial count of
seven. One specimen from Arizona (MVZ 43701) has six supralabials
on both sides; another specimen from Arizona (ASDM 2255) has six
supralabials on the left side only. Both low counts apparently are the
result of a fusion of the fifth and sixth supralabials. A specimen from
Teacapan, Sinaloa (LACM 7001) has eight supralabials on the right
side, the result of the splitting of supralabial one.

Normally, the third and fourth supralabial scales border the orbit.
Smith (1942:41) stated that the fourth and fifth supralabials enter the
orbit on the type of 7. yaquia. Reexamination of the holotype indicates
that the third and fourth supralabials enter the eye. If, however, there is
a split of one of the anterior labial scales, then the fourth and fifth
supralabial scales enter the orbit, as in the specimen (LACM 7001)
mentioned above. Occasionally part of the second supralabial enters
the orbit together with the third and fourth (MVZ 43701). No variation
in the number of infralabials was observed.

Body scales: All specimens examined have 15 scale rows one head
length behind the head, at mid- body, and one head length in front of the
anus.

COLORATION

Body color: In preservative, the dorsal surface of the body is light
brown to brownish-tan, fading slightly on the lateral surfaces. In some
specimens, especially those from southern Sonora, the dorsal scales
have a speckled appearance to give the impression of a faint stripe on
each scale row. Microscopic examination shows that this coloration is
due to the posterior superimposition of each dorsal scale resulting in
twice the concentration of pigment at each area of overlap.

The ventral coloration of three live specimens was pinkish-orange.
The color, brightest on the posterior third of the ventrals beneath
the tail, gradually fades on the anterior half of the body. The anterior
quarter of the ventral surface, the throat, and the chin are creamy
white. After storage in preservative, the pinkish coloration is lost
completely, and the ventral surface appears light tan. Some of the
specimens from the vicinity of Alamos, Sonora, and the type specimen
have traces of brownish pigment on the lateral edges of some ventral
scales. These specks of pigment are not present in specimens from other
localities.

The Black-Headed Snake 163

®

Tantilla yaquia

© TYPE LOCALITY
@ LOCALITY RECORDS

Figure 1. Map of southeastern Arizona and northwestern Mexico showing local-

ity records for Tantilla yaquia.

164 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

Head cap and collar: In preservative the dorsal surface of the head
is usually brown, brownish-black, or black (Fig. 3). The frontal, pre-
frontal, supraocular, and parietal scales are usually lighter, often
mottled tan and brown; the latter is more prevalant in the northern
population. Laterally and posteriorly the head color darkens strikingly
in sharp contrast to the creamy white labials and collar. Anteriorly
the head coloration may become much lighter. In some specimens the
internasal scales are grayish and intermediate in coloration between
the head color and the rostral color. A few specimens exhibit a well
defined dark-light border on the internasal scales. The rostral is some-
times lighter than the head cap; in a few specimens the rostral is white.
Specimens with a light snout compose about 75 per cent of population
A, about 40 per cent of population B, and about 30 per cent of popula-
tion C. There is no correlation of rostral color with size or sex of the
snake. With the exception of the higher frequency of light snouted
snakes in southern Arizona, there is no correlation of rostral color
with geographic distribution.

A dark head cap continues onto the neck a distance of from two to
slightly more than four scales (counted at midline) posterior to the
parietals. The head cap extension is usually black and always darker
than the dorsal surface of the head. The posterior border usually forms
a straight edge when viewed from above. The head cap extends pos-
teriorly from the parietals on the midline an average of 2.8 scales in
population A, (N = 13) 2.9 scales in population B (N = 17), and 3.3
scales in population C (N = 10). Although the mode is three scales in
all populations, there appears to be a more extensive head cap in speci-
mens from the south. All of the individuals that have the head cap
extending only two scales posteriorly on the midline are from population
A. All specimens from population C have three to four scales in the
head cap. The only exception to this trend in the posterior extension of
the head cap is found in the northern population. A specimen from
near Sasabe, Sonora (UAZ 23571) has an extensive black head cap that
covers four and one-eighth scales posterior to the parietals. The north-
ern population includes individuals whose head caps extend over the
fewest and greatest number of body scales.

Posteriorly, the head cap always is bordered by a light nuchal collar.
Dorsally this collar is complete in all specimens except one (ASU 5836)
in which a single middorsal scale of the black head cap extends poster-
iorly interrupting the white collar. The nuchal collar varies on the mid-
line from one-half to one and one-half scales in width and extends
laterally as a continuum to join the light coloration of the throat.

In some specimens there are dark spots posterior to the light collar.

The Black-Headed Snake 165

Tantilla atriceps , /
7
| PEER ATE) (N=13)
ana ae (N=I1)
uJ 7
: (
@ oO 4
= ALTE (N=4) 4
7
< of (coca oes (N=6)
sa art
é ve

—_ (N=4)
y ees omen (N=7)

4 Tanti!la yaquia
/ EEE (N=5)
7
pe = oe (N=3) C

180 190 200 210 220 230 240

VENTRALS + SUBCAUDALS

Figure 2. Ranges and means of ventral plus subcaudal scales for populations (A,
B, C) of Tantilla yaquia and selected specimens of Tantilla atriceps. Solid symbols
indicate males; open symbols indicate females. Dots represent single specimens.
Populations are arranged in approximate geographic position by north latitude.

a> NORTH

These spots are the same dark color as the scales anterior to the collar
and usually are restricted to the scale row immediately posterior to it.
The spots are lacking in all specimens from population A, present in all
specimens from population B (except KU 93500), and found in half of
the specimens in population C. When present, the spots may vary in
number from one to nine. Invariably, if spots are present, one will be on
the middorsal scale row. In specimens from population C, coloration
posterior to the white collar is restricted to a single middorsal scale.
Only a single specimen, the same individual that exhibited the mid-
dorsal interruption of the light collar, has dark spots on the anterior tip
of two middorsal scales posterior to the collar.

The black head cap extends laterally below the angle of the mouth
in all known specimens of 7. yaquia. The amount of lateral extension
below the angle of the mouth is measured by counting the rows of
partially or fully dark pigmented scales below the zigzag boundary

166 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

between adjacent scale rows, that intersects the posterior ventral
margin of the seventh supralabial. In most instances this line is simply
an extension of the lip edge formed by the supralabial scales. The
black head cap extends from one-half to three scales below the angle
of the mouth. As with certain other characteristics, there appears to be
a greater lateral extent of the head cap in the southern population.
Individuals from poulation A exhibit a lateral extension ranging from
0.5-2.5 (x = 0.96; N = 13) scales. For population B the range is 0.5-
2.25 (1.40; N = 17) scales, and for population C the range is 1.0-3.0
(1.90; N = 10).

Lateral head coloration: The ventral extent of black posterior to the
eye was measured by recording the portion of the anterior temporal
scale that is white. In all specimens the lower one-fourth to three-fourths
of the anterior temporal is white. More than 80 per cent of those
examined have the lower one-third to one-half of the anterior temporal
white. There is no apparent geographic variation in this character. A
single specimen (JFC 62-53) from Sinaloa has white extending through
parts of the temporal onto the parietal scale. This specimen is abnormal
in having the temporals fused on one side. Even though the white
reaches the parietals, the presence of a dark central spot on the temporal
suggests that this condition corresponds to not having the white reaching
beyond the lower three-fourths of the temporal scale.

The amount of white on each supralabial scale was recorded. There
is no correlation between sex and supralabial color or rostral color and
supralabial color. The first supralabial scale in most specimens is white
or gray-white. When there is black on the first labial, the rostral color
is usually dark. However, specimens with an entirely white first supra-
labial may have either a black or a white snout.

There is some black on the second supralabial in all specimens
examined. Two specimens have all black second supralabials. There
is slightly more white on the second supralabial in specimens from
population A than in those from B or C.

There is definitely less white on the third supralabial in specimens
from the southern parts of the range. In individuals from population A,
the third supralabial is always white over 50 per cent or more of its
surface. No individuals from population B have supralabial three
more than 50 per cent white, and in approximately 40 per cent of the
individuals, less than one-half of each supralabial is white. In popula-
tion C seven specimens have no white on the third supralabial, one has
white on about one-eighth of the scale, and another has white on about
half the scale.

Nearly all specimens have white on most of supralabial four. In

The Black-Headed Snake 167

population A white on most of supralabial four. In population A white
covers more than 80 per cent of the scale; the black of the head cap is
restricted to a small line beneath the eye. In population B white covers
about 75 per cent of the scale, and in a few specimens, the white is
restricted to the lower posterior third of the scale. In population C there
is more encroachment of the black beneath the eye. The white rarely
covers more than half and usually is restricted to the lower posterior
portion of the scale. In one specimen (LACM 7001) almost the entire
fourth supralabial is black.

There is no dark pigment on any part of supralabials five and six in
typical specimens of 7. yaquia. Those specimens from Arizona (MVZ
43701, ASDM 2255) that have only six supralabials, apparently due
to fusion of the fifth and sixth, lack dark pigment on the fifth and most
of the sixth.

In specimens from southern Arizona the seventh supralabiai usually
is white on its lower anterior quarter or more. In general, specimens
from population B have about the same amount of white on the seventh
supralabial as do specimens from population A; a few individuals have
much more. Snakes from southern Sinaloa and Nayarit have more than
half the seventh supralabial scale white. Some from population C have
an entirely white seventh supralabial. The posterior shift of black color
on the seventh supralabial correlates with the posterior extension of the
black head cap along the midline. Both tend to extend more posteriorly
in specimens from the southern limits of the range.

The mental and infralabials are nearly always white in specimens
from population A; there is a slight trace of pigmentation in only two
Specimens examined. Less than half of the specimens from population
B possess a white mental. Most but not all of those with a white mental
also have white infralabials. Other specimens from this region have
some pigment on the mental and infralabials. When present, the dark
pigmentation is more intense on the anterior infralabials. About half of
the known individuals from population C have some degree of pigmen-
tation on the mental, and only two have no pigmentation on the infra-
labials. In some specimens pigmentation is found only on the anterior
infralabials.

SIZE

The two largest specimens of Tantilla yaquia are both males,
measuring 325 mm. total length, from southern Arizona, one taken
in the Pajarito Mountains (UAZ 23573), and another from near Bisbee
(AMNH 4194). The smallest specimen, a male, measured 104 mm.
total length and was taken in January beneath a rock 7.1 mi. NE of the

168 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

Tantilla artricéps

Figure 3. Diagrammatic representation of head patterns of typical Tantilla yaquia
and Tantilla atriceps from southeastern Arizona.

The Black-Headed Snake 169

Alamos airport, Sonora, Mexico. The presence of a conspicuous
umbilical scar on ventrals 125 and 126 indicates that this specimen was
recently hatched. Another small specimen, a female measuring 140
mm. total length has an umbilical scar on ventrals 132 and 133.

A ratio of tail length/total length was calculated for males and
females in each of the three populations. Specimens from the south have
shorter tails than those from the north. In the males the ratios expressed
as percents are 24.4-27.4 (x = 26.1; N = 4) in population A, 24.
3-27.5 (25.4; N = 4) in population B, and 21.2-23.2 (22.1; N = 5)
in population C. For females the percentages are 21.4-28.5 (25.1;N =
6) in population A, 20.9-27.3 (23.7; N = 7) in population B, and
17.2-22.7 (20.1; N = 3) in population C. males and females exhibit
a more drastic change from population B to C than from populations
A to B. The difference in the magnitude of change for tail length/total
length ratios from population to population in males and females
parallels the changes characteristic of each sex in the number of sub-
caudal scales.

DISTRIBUTION AND ECOLOGY

Tantilla yaquia ranges south from southern Cochise and Santa
Cruz Counties, Arizona, through eastern Sonora, western Chihuahua,
and Sinaloa into Nayarit (Fig. 1). In the northern part of its range T.
yaquia is characteristically found above 1000 m in evergreen and
raparian woodland (Lowe, 1964) in Chiricahua, Mule, and Pajarito
Mountains of southern Arizona.

In southern Sonora, Chihuahua, and northern Sinaloa, the snake is
distributed along the dissected foothills and western slopes of the Sierra
Madre Occidental at lower elevations. In this region 7. yaquia com-
monly occurs in the deciduous short tree forest (Gentry, 1942) and
occasionally ranges into the drier thorn woodland.

All localities recorded from southern Sinaloa and Nayarit are at low
elevations (below 200 m) on the coastal plain. The vegetation in this
area is tropical semiarid and dry forests (Hardy and McDiarmid, 1968).
There are no records of 7. yaquia from localities south of the Rio
Santiago valley in Nayarit.

The distributional pattern of T. yaquia is typical of many species
of amphibians and reptiles in northwestern Mexico. Other species that
exhibit this pattern and range from the coastal plains of Nayarit and
Sinaloa northward along the foothills of Sonora into southern Arizona
include: Hylactophryne augusti, Eumeces callicephalus, Elaphe triaspis,
and Oxybelis aeneus.

Very little is known concerning the habits of 7. yaquia. Apparently

170 Bulletin So. Calif. Academy Sciences|/Vol. 67, No. 3, 1968

it is a nocturnal, secretive form, that spends much of its time beneath
rocks and in crevices. Most specimens in the north have been found
beneath rocks and surface litter, especially in March, April, August,
and September, when the soil is damp after winter and summer rains.
In Arizona individuals have been collected in or near streams. One
specimen (MVZ 59778) was found in the stomach of a Rana tarahu-
marae, a frog that is rarely taken away from water. Another snake
(UAZ 23574), collected by R. L. Bezy, was found just before dark as
it was Swimming in a swift portion of the stream in Sycamore Canyon.
Near Alamos, specimens have been collected in December, January
and February, although a few have been taken in July and August. A
specimen was dug from the interstices between the roots and surround-
ing soil of a large mesquite (Prosopis) south of Navojoa in December.
Another specimen was taken at 1945 hours on July 6 on the road north
of Mazatlan, Sinaloa. The ambient temperature was 26.4°C.

SUBSPECIES

The southern specimens of T. yaquia have been considered by some
authors to be subspecifically distinct from the remainder of the pop-
ulation. The characters that were used to diagnose this race, reduced
number of subcaudals, short tail, and more extensive white area poster-
ior to the eye, have been shown to vary clinally throughout the species.
Accordingly, I recognize no subspecies of T. yaquia, and | place T.
yaquia bogerti in the synonymy of T. yaquia.

RELATIONSHIPS

When Smith described Tantilla yaquia in 1942, he suggested that
it was most closely related to T. planiceps of Baja California and T.
eiseni of northern Baja California and California. Since that time, the
acquisition of additional material of the three species has reinforced his
suggestions. The high number of ventral plus subcaudal scales, the
posterior and lateral extent of the head cap, the presence of a light
collar, the occurrence in some specimens of dark specks posterior to the
collar, and other characters confirm the close relationships between
yaquia and the planiceps-eiseni group. However, several other charac-
ters clearly separate the eastern yaquia from the western planiceps and
eiseni. Of primary importance are ventral plus subcaudal counts and
details of head coloration, especially the extensive white postocular
spot of yaquia. In addition, these species are widely separated geo-
graphically by the Gulf of California and the Sonoran Desert.

The Black-Headed Snake I7I

Two other species of black-headed snakes, T. atriceps and T.
utahensis, that have been regarded as allies of yaquia (Smith, 1942),
also occur in the southwestern United States and Mexico. Tantilla
utahensis ranges in a narrow band from eastern California through
southern Nevada, northern Arizona, Utah and into Colorado. Tantilla
atriceps is distributed from northeastern Mexico westward into central
Arizona and Sonora where it approaches the range of T. yaquia. These
two forms are similar to each other in coloration but differ from the
previously mentioned species by possessing a more restricted head cap
and usually lacking a distinct light nuchal collar. In addition they have
a lower number of ventrals plus subcaudals than the closest geographic
populations of the other three species. Apparently they differ from each
other only in the number of ventral plus subcaudal scales. T. atriceps
averages 206.3 in males and 207.9 in females, and T. utahensis averages
223.8 in males and 226.0 in females (Tanner, 1966: Table 3).

Tanner (1966) concluded that Tantilla planiceps, T. eiseni, T.
utahensis, T. atriceps, and T. yaquia represent subspecies of one wide-
ranging species, T. planiceps. In addition he considered the type and
only known specimen of T. hobartsmithi from near La Posa, 10 mi. N
Guaymas, Sonora an aberrant atriceps and placed it in synonymy with
T. planiceps atriceps. My analysis of variation in T. yaquia provides
the opportunity for evaluation of Tanner’s proposals, especially with
reference to the status of this species.

Several character states are compared below for T. yaquia and T.
atriceps. All data for atriceps are in parentheses after those for yaquia;
the source of the data is listed by page number from Tanner’s paper
unless otherwise indicated. Important characters are extensive light
collar present in yaquia (rarely present: key, 148); dark nape spots in
some specimens of yaquia from populations B and C (always absent:
139); head cap extending posterior to parietals two to four scales
(zero to two scales : 139); lateral extension of head cap below angle of
mouth from one-half to three scales (never present: 140); white labial-
temporal spot present and set off posteriorly by the lateral extension
of the head cap (present but not delimited posteriorly: 140); average
number of ventrals plus subcaudals for males in population A, 218.5
(206.3: Table 3) and for females in population A, 226.7 (207.9: Table
3). It appears that there are several differences between populations of
Tantilla referred to yaquia and those referred to atriceps.

Tanner (1966:146) mentioned the differences in color patterns
between specimens of atriceps and yaquia but attempted to show their
“conspecificity” with the following statement: “If, however, a few spec-
imens of eiseni with a well-developed light nape band and perhaps an

gi) Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

eiseni or utahensis with a reduced head and nape pattern and a narrow
light nape band are placed between atriceps and yaquia, the differences
tend to blend into a color pattern gradient.” Apparently Tanner is
suggesting that certain specimens of e/seni or utahensis are intermed-
iate between atriceps and yaquia. This means that even though typical
atriceps and yaquia occur in close geographic proximity in several
places in southeastern Arizona without a suggestion of intergradation,
one must go to an area several hundred miles north or west of the
nearest records for the two species to find Tantilla that may be inter-
mediate in head coloration.

The second characteristic Tanner utilized to show the subspecific
relationship between atriceps and yaquia is the presence of a fine
middorsal dark stripe. As previously mentioned in the character
analysis, there is no indication of either a middorsal or lateral stripe in
T. yaquia. The fine hair line that Tanner mentioned (1966:138, 147) is
a dorsal blood vessel which in some specimens shows through the skin
to resemble a dark median stripe. The variations in presence, width,
and length are easily explained. Following the death of the snake, the
blood in this vessel hardens and contracts. If the shrinkage is great
enought to separate the blood into clots in the vessel, the apparent dorsal
stripe appears to be intermittent or markedly shortened. Also, this
vessel is very obvious in slightly desiccated specimens in which the
dorsal scales are rather transparent. The type of 7. hobartsmithi has
been dried, and the median dorsal vessel is obvious.

The dorsal extent of the creamy white spot behind the eye is
characteristic of all 7. yaquia. This pattern is accentuated by the dark
head cap which bounds it posteriorly and dorsally (Fig. 3). The
relatively invariable arrangement and striking contrast between the
white and black laterally on the head appear to be important character-
istics. Tanner (1966:140, 148) argued that this light area in most atri-
ceps is no longer obvious because of the posterio-lateral contraction
of the head cap. The fact is that it does not contrast posteriorly with an
area of black, nor is it as extensive as in yaquia.

Tanner maintained that in some specimens of T. atriceps from
southern Arizona, the postocular spot is faintly apparent. Information
on 20 specimens of 7. atriceps from five localities in southern Arizona
was provided by C. J. Cole and L. M. Hardy. In all 20 specimens the
fifth supralabial has some brown on its upper margin; 18 of the 20 also
have brown on the sixth, while in two the sixth supralabial is all white.
As previously mentioned, the fifth and sixth supralabials in 7. yaquia
are entirely white. It appears that in nearly all cases the extent of
development of the postocular white spot will distinguish specimens

The Black-Headed Snake 1B

of T. yaquia from T. atriceps (Fig. 3). The lateral extent of the head cap
also will distinguish atriceps from yaquia, as in the case of the speci-
men of “T. atriceps” pictured by Wright and Wright (1957: fig. 212),
which is a 7. yaquia. Although I did not examine this specimen, the
typical yaquia head pattern and the locality leave no doubt as to its
identity.

Tanner concluded that because the scale characters overlap in all
instances, except the subcaudals of females, there is little justification
for recognizing yaquia as a distinct species. Unfortunately most of
Tanner’s data for yaquia were taken from material from southern
Sonora. This biased his ventral plus subcaudal totals towards those of
population B. In addition, most of the atriceps data (63 of 101
Specimens examined) were taken from specimens from Maricopa
County, Arizona. Of the remaining 38, only 18 are from localities in
Cochise, Pima, and Santa Cruz counties in areas of potential sympatry
with yaquia.

Data supplied by C. J. Cole and L. M. Hardy, who also follow the
Dowling method of counting, show that ventral plus subcaudal counts
for 13 male atriceps from the vicinity of Tucson are 194-211 (x = 201.
8); for 11 females from the same area 189-209 (201.1). These averages
are slightly lower than those provided by Tanner (males 206.3, females
207.9). The same counts for yaquia from population A, that population
geographically adjacent to atriceps, are males 207-230 (218.5) and
females 219-233 (226.7). These counts are quite different for the two
species. There is only a five scale overlap between the ranges of scales
in males and an average difference of nearly 17. The differences be-
tween atriceps and yaquia are more striking when the females are com-
pared. There is no overlap in the range of ventral plus subcaudals and
an average difference of about 25 scales.

It has been shown above that the ventral plus subcaudal totals ap-
parently decrease clinally from north to south in T. yaquia. Although
details of the geographic variation of this character in T. atriceps are
not available, a decrease in the same direction is suggested (Fig. 2).
Scattered specimens of atriceps from Cochise county have approxi-
mately the same total ventral plus subcaudal scales as those from near
Tucson in Pima county. Two specimens of atriceps from Santa Cruz
county, nearer the range of yaquia, have 188 scales (a male) and 193
scales (a female). Both of these counts are well below the average for
Tucson specimens. If we include the counts for two males from Sonora,
the reduction in scales becomes more obvious. A male atriceps from
near Hermosillo has 192; the male type of T. hobartsmithi, apparently
a T. atriceps, has 183. These data indicate a clinal decrease in ventral

174 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

plus subcaudal scales in T. atriceps from southeastern Arizona into
Sonora, paralleling but not converging with the decrease in yaquia.
Thus, similarities and overlap in this scale character between atriceps
and yaquia occur only if specimens of yaquia from southern Sonora are
compared with specimens of atriceps from central Arizona. Such a
comparison reveals that the two species are distinctly different in those
areas where their ranges are contiguous.

Undoubtedly, T. yaquia and T. atriceps are distinct species. Clarifi-
cation of relationships between T. atriceps and T. utahensis awaits
completion of a study of these nominal species as is being carried on by
C. J. Cole and L. M. Hardy. Because of the lack of intermediates
between atriceps and utahensis and because of the distinctness of
atriceps and yaquia, the latter of which is more similar to planiceps,
it seems likely that atriceps is distinct from planiceps.

Tantilla yaquia and the western species T. planiceps and T. eiseni
probably are derived from a common ancestral form which was split and
subsequently isolated on each side of the Gulf of California, by the
Colorado and Sonoran deserts formed in the late Tertiary. I suspect
that the three forms evolved in conjunction with the woodland element
derived from the Madro-Tertiary Geoflora (Axelrod, 1958). Tantilla
yaquia became associated with the Sierra Madrean woodland and arid
tropical scrub of eastern Sonora and Sinaloa. In the west T. planiceps
was restricted to the Lagunan woodland in the cape region of Baja
California and 7. eiseni became associated with the Californian wood-
land and chaparral. Savage (1960): postulated interglacial fragmenta-
tion of continuous ranges of Tantilla eiseni and planiceps during the
Pleistocene. Peninsular connections between these two forms during
glacial maxima could account for their similarities. Tantilla atriceps
probably differentiated much earlier than the western species and
evolved in association with the desert grassland of the Chihuahuan
desert area. T. atriceps probably was isolated east of the Rocky Moun-
tains and Sierra Madre Occidental during much of late Cenozoic and
has only recently moved westward into Arizona and Sonora where it is
found in the eastern parts of the Sonran desert. The evolutionary history
of T. utahensis is a matter for speculation. The apparent intermediates
suggest that it was derived from an eiseni stock. However, its similar-
ities to T. atriceps and present day distribution do not preclude its
possible derivation from an atriceps stock and subsequent isolation in
the Great Basin north of the Grand Canyon and Mogollon Rim.

Recent records of T. atriceps and T. yaquia in southeastern Arizona
suggest that it is only a matter of time until the two species will be found
under the same rock. Even though T. yaquia is primarily a woodland

The Black-Headed Snake 175

form and T. atriceps is frequently found in desert grassland, sympatry
is expected where these two habitats interdigitate, particularly since
both species commonly occur in riparian woodland. There are speci-
mens of 7. atriceps from Tubac and south of Tumacacori along the
Santa Cruz River in Santa Cruz County, Arizona. Tantilla yaquia
occurs in this drainage system only about 15 miles away, in the Pajarito
Mountains (UAZ 23573). Similar situations of near sympatry are
encountered in Cochise County between Benson and Tombstone and
between Bisbee and Douglas.

SUMMARY

Examination of more than thirty characteristics of 40 specimens of T.
yaquia indicates that some characters apparently show clinal variation.
Tantilla yaquia differs from other species of Tantilla in several charac-
teristics, including the number of ventrals plus subcaudals, the posterior
and lateral extent of the black head cap, the presence of a light collar,
and the distinct white supralabial-temporal spot. The current systematic
treatment of this population as a subspecies of T. planiceps is untenable.

New evidence indicates that Tantilla yaquia and T. atriceps are
specifically distinct in characteristics of scalation, coloration, and
general habitat. The so-called “intermediates” between these two
species are discussed and their status refuted. In addition it is shown
that characteristics utilized to distinguish the southern population of T.
yaquia bogerti from T. y. yaquia exhibit clinal variation. Since there
and insutficient data to warrant its recognition, 7. y. bogerti is placed
in synonymy with T. yaquia.

The distribution and ecology of T. yaquia are discussed; the probable
evolutionary history is briefly considered.

ACKNOWLEDGMENTS

Several people have aided in the completion of this report. David B. Wake ac-
companied me in the field and offered initial encouragement. Merritt S. Keasey,
William H. Woodin, and Robert L. Bezy made special efforts to collect additional
material in Arizona. Comparative data for Tantilla atriceps were made available
by C. J. Cole and L. M. Hardy. C. J. Cole and C. J. McCoy offered valuable
suggestions throughout the study. Jay M. Savage examined the type of T. yaquia
for me.

Material was examined through the cooperation and courtesy of the following
curators and institutions: R. G. Zweifel, American Museum of Natural History
(AMNH); M. S. Keasey and W. H. Woodin, Arizona Sonora Desert Museum
(ASDM); M. J. Fouquette and H. Heringhi, Arizona State University (ASU); A.
E. Leviton, California Academy of Sciences (CAS); C. J. McCoy, Carnegie

176 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

Museum (CM); J. F. Copp, La Jolla (JFC); W. E. Duellman, Museum of Natural
History, University of Kansas (KU); J. W. Wright, Los Angeles County Museum
of Natural History (LACM); E. E. Williams, Museum of Comparative Zoology
(MCZ); R. C. Stebbins, Museum of Vertebrate Zoology (MVZ); A. J. Sloan, San
Diego Society of Natural History (SDSNH): G. S. Myers, Stanford University
(SU); C. H. Lowe, University of Arizona (UAZ); T. P. Maslin, University of
Colorado Museum (UCM); and H. M. Smith, University of Illinois, Museum of
Natural History (UIMNH).

Field work in 1962 was made possible through a Grant-in-Aid of Research
from the Society of Sigma Xi.

C. J. Cole, W. R. Heyer and J. M. Savage read the manuscript in its final form
and offered valuable suggestions. To all of these people I extend my sincere
thanks.

SPECIMENS EXAMINED

ARIZONA:
Cochise Co.: Cave Creek (AMNH 72991); 0.25 mi. E Portal, 4700’ (AMNH
99357): Bisbee (UCM 875): near Bisbee (AMNH 4194): Tombstone (MVZ 43701).

Santa Cruz Co.: 12 mi. W Nogales (CM 25210); 300 yds. S Pena Blanca Rd.,
about 7 mi. W Junction with Nogales Hwy. (UAZ 23573); Alamo Canyon, 2.5 mi.
SW Pena Blanca Camp (MVZ 59778); Sycamore Canyon, Bear Valley (UAZ
23574); Pajarito Mts., Sycamore Canyon (ASDM 2255); Pajarito Mts., first
canyon E Sycamore Canyon, 50 yds. N road (ASDM 2237); 3 mi. SE Ruby, 4500’
(LACM 7002).

MEXICco:

Sonora: El Zapeta Ranch, about 15 mi. SE Sasabe (UAZ 23571); 1.7 mi. SW
Aribabi (UAZ 23569); Alamos (UAZ 23570, MVZ 78758); 7.1 mi. NE Alamos
airport (ASU 5834, 5835, 5836); 6.1 mi. WSW Alamos (ASU 5837, 5838); 5.5 mi.
W Alamos (ASU 5833); Canyon Aqua Marin, 6.5 mi. W Alamos (ASU 6743);
15 mi. W Alamos (JFC 63-129); 15.7 mi. W Alamos (JFC 63-162); Rio Alamos,
8 mi. SE Alamos (UAZ 23572); Arroyo Cuchujaqui, 8 mi. SE Alamos (LACM

8475); Mirasol, 16 mi. SE Alamos (SDSNH 18190); 25 mi. S Navojoa (LACM
6997).

Chihuahua: Guasaremos, Rio Mayo (MCZ 43274, type of Tantilla yaquia).

Sinaloa: 0.75 mi. ENE El Cajon, 3200’ (KU 93500); Costa Rica, 16 km. S
Culiacan (UIMNH 34921); 43.8 mi. S Ctliacan (UAZ 16310); 22.4 mi. SE Rio
Piaxtla, Hwy. 15 (SU 23778); 16 mi. N Mazatlan, Hwy. 15 (JFC 62-53); 5.8 mi.

N Mazatlan, Hwy. 15 (LACM 6998); Labrados (CAS 64976); Teacapan (LACM
7001).

Nayarit: Acaponeta (AMNH 62259, 62260, type and paratype of Tantilla
bogerti); Jesus Maria (AMNH 74949).

LITERATURE CITED

Axelrod, D. I. 1958. Evolution of the Madro-Tertiary Geoflora. Botan. Rev..,
24 : 433-509.

The Black-Headed Snake 177

Dowling, H. G. 1951. A proposed standard system of counting ventrals in
snakes. British J. Herpetol., 97-99.

Fowlie, J. A., 1965. The snakes of Arizona. Fallbrook, California: Azul Quinta
Press, 164 p.

Gentry, H.S., 1942. Rio Mayo plants. A study of the flora and vegetation of the
Rio Mayo, Sonora. Carnegie Inst. Washington Publ., 527 : 1-328.

Hardy, L. M., and R. W. McDiarmid. (In press). The amphibians and reptiles of
Sinaloa, Mexico. Univ. Kansas Publ. Mus. Nat. Hist.

Hartweg, N. 1944. Remarks on some Mexican snakes of the genus Tantilla.
Occas. Pap. Mus. Zool. Univ. Michigan, 486 : 1-9.

Lowe, C. H., 1964. Arizona landscapes and habitats. in Lowe, C. H. (ed.), The
vertebrates of Arizona. Tucson: Univ. Arizona Press, | : 1-132.

McCoy, C. J., Jr., 1964. The snake Tantilla yaquia in Arizona: an addition to
the fauna of the United States. Copeia, 1964 : 216-217.

Savage, J. M., 1960. Evolution of a penisular herpetofauna. Syst. Zool., 9 : 184-
212.

Smith, H. M., 1942. A résumé of Mexican snakes of the genus Tantilla. Zoo-
logica, 27 : 33-42.

Smith, H. M., and R. G. Van Gelder, 1955. New and noteworthy amphibians
and reptiles from Sinaloa and Puebla, Mexico. Herpetologica, 11 : 145-149.

Stebbins, R. C., 1966. 4 field guide to western reptiles and amphibians. Boston:
Houghton Mifflin Co., 279 p.

Tanner, W. W., 1966. A re-evaluation of the genus Tantilla in the southwestern
United States and northwestern Mexico. Herpetologica, 22 : 134-152.

Wright, A. H., and A. A. Wright, 1957. Handbook of snakes of the United
States and Canada. Ithaca: Comstock Publishing Assoc., Cornell Univ. Press,
2 : 565-1105.

Zweifel, R. G., and K. S. Norris, 1955. Contribution to the herpetology of
Sonora, Mexico: description of new subspecies of snakes (Micruroides eury-

xanthus and Lampropeltis getulus) and miscellaneous collecting notes. Amer.
Midland Nat., 54 : 230-249.

Accepted for publication May 28, 1968.

A NEW SPECIES OF TEREBRIPORA
(ECTOPROCTA, CTENOSTOMATA)
FROM ANTARCTIC CEPHALODISCUS

JOHN D. SOULE AND DOROTHY F. SOULE

Allan Hancock Foundation,
University of Southern California
Los Angeles, California

INTRODUCTION

Although d’ Orbigny erected the bryozoan genus Terebripora and
described two species T. ramosa and T. irregularis, it was not until the
work of Marcus (1938) that clear descriptions and figures of the poly-
pide anatomy appeared in the literature. Since 1847 when d’ Orbigny’s
paper was published most of the species of Terebripora have been
described on the basis of their surface tracings upon mollusk shells,
many of these from fossil deposits. In addition to the work of Marcus,
anatomical descriptions made from preserved material have been pub-
lished by Bobin and Prenant (1954, 1956) and Soule (1950, 1963).

Several specimens of Antarctic hemichordates, Cephalodiscus hodg-
soni and Cephalodiscus densus, with burrowing bryozoans in the
coenecium were brought to our attention through the kindness of Miss
Diana Robbins. Prior to this time the burrowing bryozoans have been
found principally in mollusk shells and rarely in brachiopod shells.
The hemichordates had been fixed in neutral formalin in the field and
later transferred to 70 per cent ethanol. Areas of the coenecium free of
sand grains and other debris were dehydrated, infiltrated in paraffin,
sectioned at 4 », and stained with hematoxylin and eosin. Other
regions were dissected trom the coenecium, stained with azocarmine,
dehydrated, cleared and mounted for anatomical studies. Examination
of the whole mounts and the sections show the burrowing bryozoan to
be a new species of the genus Terebripora.

Genus Terebripora d@’Orbigny, 1847

Colonies stolonate, composed of zoids joined by segmented primary
and secondary stolons. The secondary stolons are affixed to the zoid
about midway between the distal and proximal extremities. The alimen-
tary tract of the polypide is provided with a prominent grinding organ
or gizzard. The genotype is Terebripora ramosa @’Orbigny, 1847.

178

New Species of Ectoprocta 179

Terebripora eltaninae new species
Figure |

Material: Holotype, A.H.F. bryozoan number 148.

Diagnosis: Stolonate burrowing ectoprocts with large elongated
cylindrical autozoids that have a blunt, rounded proximal end. Auto-
zoids connected by secondary stolons to the primary stolons at irregular
intervals, not crowded. Tentacle number is ten.

Description: Zoaria stolonate, with elongated primary stolons that
are divided into internodes of varying length by septae. From the
primary stolons, secondary stolons connect to the autozoids at a point
about midway between their distal and proximal termini. The proximal
ends of the cylindrical autozoids are typically blunt and rounded. The
distal end forms an ovoid opening on the free surface of the coenecium.
Mature autozoids vary in length from 440 » to 620 » in the same
zoarium. At the widest point, the autozoids range from 100 to 140 pz.
The primary stolons are from 15 to 20 u in width. The tentacle num-
ber is consistently ten, as determined by serial sections stained with
hematoxylin and eosin. The sections and the whole mounts show the ali-
mentary tract to be U-shaped in typical ectoproct morphology. The
alimentary tract exhibits a prominent, globular grinding organ or giz-
zard. The muscular system of the autozoid consists of the aperturals
at the distal end, lateral parietals, and proximally anchored retractor
fibers. Many of the autozoids show a proximally placed ovarian mass
consisting of one or more ova surrounded by many small cells. The
reproductive cycle was apparently in its initial stages at the time this
material was collected (January) since no reproductive kenozoids were
found. The zoaria were young as we were unable to find brown bodies
within any of the autozoids, and many juvenile zoids in various stages of
development were present.

Terebripora eltaninae, with 10 tentacles, is distinguished from Tere-
bripora ramosa dOrbigny, with 12 tentacles, and Terebripora comma
Soule, with 8 tentacles. The mature autozoids of Terebripora eltaninae
are consistently larger in size than those of either T. ramosa or T.
comma whose autozoids range between 300 to 350 u in length.

In recognition of the work of the officers and men of her crew, we
have named this species for the oceanographic vessel, the U.S.N.S.
Eltanin.

Occurrence: Eltanin station number 418, off Palmer Peninsula, 62°
39’ S. Latitude, 56° 10’ W. Longitude, five-foot Blake trawl, depth 311
to 426 m, January 2, 1963. Eltanin station 435, off Palmer Peninsula,
63° 14’ S. Latitude, 58° 40’ W. Longitude, 40 foot otter trawl, depth
73 to 92 m, January 8, 1963. Eltanin station 436, off Palmer Peninsula,

180 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

Dn” OQ VU

l0O UW

Figure 1. Mature autozoid of Terebripora eltaninae from a zoarium taken at
Eltanin station 436. Legend: A-apertural muscle fibers; G-gizzard; P-parietal
muscle fiber; R-retractor muscle fibers; S-stolon; T-tentacles.

63° 14’ S. Latitude, 58° 45’ W. Longitude, 40 foot otter trawl, depth
73 m, January 8, 1963.

LITERATURE CITED
Bobin, G. and M. Prenant, 1954. Sur un Bryozoaire perforant, Terebripora
comma (Soule) trouve en Mediterranee. Arch. Zool. Exper. Gen., 91 : 130-144.

. 1956. Faune de France 60 Bryozoaires. Federation Francaise des,
Societes des Sciences Naturelles. Office Central Faunistique Paris. 398 p.

Marcus, E., 1938. Bryozoarios perfuradores de conchas. Arq. Inst. Biol. Sao
Paulo, 9 : 273-296.

New Species of Ectoprocta 181
d’Orbigny, A., 1847. Voyage dans 1l’Amerique meridionale. Zoophytes.
5 3 7-23.

Soule, J. D., 1950. A new species of Terebripora from the Pacific (Bryozoa
Ctenostomata). J. Wash. Acad. Sci., 40 : 378-381.

. 1963. Results of the Puritan-American Museum of Natural History
Expedition to Western Mexico. 18. Cyclostomata, Ctenostomata (Ectoprocta)
and Entroprocta of the gulf of California. Amer. Mus. Novitates, 2144 : 1-34.

Accepted for publication June 7, 1968.

A NEW SPECIES OF ACONTIATE ANEMONE
FROM SOUTHERN CALIFORNIA
(SAGARTIIDAE: SAGARTIA)

RONALD H. MCPEAK

Marine Resources Operations
California Department of Fish and Game
Terminal Island, California

INTRODUCTION

The actinarian fauna of California is poorly known; few species of
acontiarian anemones have been described from the West Coast of
North America. Hand (1955) reported six species of acontiarian
anemones from the intertidal zone of Central California: Metridium
senile fimbriatum, M. exilis (Metridiidae); Diadumene leucolena, D.
lighti, D. franciscana (Diadumenidae); Haliplanella luciae (Haliplanel-
lidae) and Hand and Bushnell (1967) a new acontiate anemone, Flos-
maris grandis (Isophelliidae), from the intertidal mud flats of San
Francisco Bay. Aiptasia californica (Aiptasiidae) was described from
immature material collected at San Diego’s Mission Bay (Carlgren,
1952) and in deep water three species of hormathiid acontiarians were
described from California: Amphianthus californicus, Stephanauge
annularis (Monterey Bay; Carlgren, 1936) and Actinauge verrillii
(Catalina Basin; McMurrich, 1893).

Sagartia, established by Gosse (1855), has undoubtedly been one of
the most mistreated of actinian generic names. Before the establishment
of a sound classification of Actiniaria, most authors assigned anemones
possessing acontia to the genus Sagartia. The resulting genus was
obviously not natural. When Carlgren and T. A. Stephenson established
their classification of actinians based on nematocysts and other aspects
of anatomy, a basis for dividing acontiarians resulted. Carlgren (1949)
recognized only three species of Sagartia: S. elegans (Type), S. troglody-
tes, and S. herpetodes. The first two species are European (Carlgren,
1949), and the latter is reported from Chile (McMurrich, 1904). In a
more recent paper Carlgren (1959) placed herpetodes provisionally
in the genus Cerus!. S. catalinensis here proposed is the first member of
the genus Sagartia reported from North America. The specific name of
this new Californian sagartian is taken from Santa Catalina Island
where this anemone was discovered and is common.

182

New Species of Sagartiidae 183
SYSTEMATICS

Sagartia catalinensis n. sp. belongs to the family Sagartiidae which
according to Carlgren (1949) contains ten genera. Two sagartiid genera
have been described since Carlgren’s 1949 paper; Carcinactis Uchida
(1960) collected in Japanese waters as a commensal with the crab
Dorippe granulata and Habrosanthus Cutress (1961) collected in New
Zealand waters. Carlgren (1949, p. 100) defined the family as follows:
“Thenaria (Acontiaria) with mesogleal sphincter. Mesenteries not dif-
ferentiated into macro- and microcnemes. Acontia with micro-basic
amastigophores and basitrichs.”

Genus Sagartia Gosse, 1855.

DIAGNOSIS

Sagartiidae with well developed base. Column with cinclides and
with modified adhesive verrucae (suckers) capable of attaching foreign
bodies. Sphincter mesogleal, strong or weak. Tentacles fairly numerous.
Longitudinal muscles of tentacles and radial muscles of oral disc
ectodermal. Siphonoglyphs variable in number. About the same
number of mesenteries proximally and distally. More than six pairs of
perfect mesenteries. No differentiation of mesenteries into macro- and
microcnemes. Retractors of mesenteries diffuse to somewhat restricted,
never circumscribed. Gonads present from the mesenteries of the first
cycle onwards. Sometimes asexual reproduction. Acontia well devel-
oped. Cnidom: spirocysts, basitrichs, microbasic p-mastigophores,
microbasic amastigophores. The above generic description is from
Carlgren (1949, p. 101).

Sagartia catalinensis n. sp.

Base: Strongly adherent, broad, generally assuming contour of sub-
Strate to which attached, but often circular in outline. Mesenterial
insertions on base white to flesh-colored in life.

Column: Orange to salmon in life with scattered darker orange spots
(suckers) upon slight elevations occurring from margin to limbus.
Suckers of salmon-colored anemones not as bright as suckers of orange
variety. White flecks or scattered longitudinal white lines generally best
developed on proximal part of column. Mesenterial insertions visible;
transparent to flesh-colored (Fig. 1A). Small elevations mark postition
of cinclides and suckers. Suckers contain numerous granular gland cells
at base; rarely with sand or debris attached. Cinclides restricted to distal
two thirds of column; associated primarily with endocoels of second

184 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

cycle of mesenteries, but occasionally associated with endocoels of
primary mesenteries. Mucus coat often surrounds base. Longitudinal
folds present in upper part of column during contraction.

Column not divisible into regions. Mesenterial insertions visible
through body wall, especially in fully relaxed or young specimens.
Insertions orange along most of column, tending towards transparency
at margin. In extreme extension column a narrow cylinder; generally
column length two times width. Ectoderm equally developed proxi-
mally and distally; mesoglea at least as thick as ectoderm distally,
usually developed less proximally; endoderm poorly developed distally,
less than one half ectoderm.

Measurements: Largest specimen: 2.2 cm high, 1.0 cm limbus, 1.1
cm margin, and 0.8 cm tentacle length. Most specimens are approxi-
mately 1.0 cm in height.

Tentacles: Transparent in extension. Inner tentacles with or without
scattered white or dull yellow flecks occurring mostly on inner surface.
Smaller brown specks (endodermal pigmentation) often occur with or
without white or yellow pigmentation. On inner tentacles of some
specimens, white flecks fused into bars extending varying distance up
tentacle. Base of outer tentacles with white band. The white band is
generally accentuated by a background of orange pigmentation present
on the upper ends of mesenteries and showing through the oral disc.
Orange pigmentation of upper part of mesenteries may be absent in
salmon variety. A second white band generally present one third to one
half distance from base to tip of outer tentacles. One specimen had all
tentacles of one side entirely white.

Tentacles arranged more or less hexamerously; completely retrac-
tile; up to four cycles. Up to 114 tentacles in large specimens; smooth;
evenly tapered; acuminate. Innermost tentacles about three times as
long as outermost. Catch tentacles lacking. Longitudinal muscles of
tentacles ectodermal. Endoderm lacks symbiotic algae as in other
species of this genus.

Disc: Radial muscles ectodermal. Mesenterial insertions evident;
bright orange near tentacle bases becoming dull orange to cream near
mouth. One half of disc, tentacle free; orange, olive brown, or salmon
with white flecks variously developed (Fig. 1B).

Mesenteries and other aspects of internal anatomy: Mesenteries
arranged in three or four cycles. Number of perfect mesenteries highly
variable, 9-15 pairs (Fig. 2A). In one specimen, two pairs of secondary
mesenteries were located in the endocoel of a pair of directives. Labial
and marginal stomata present on perfect mesenteries. Retractors of
perfect mesenteries diffuse to restricted. Young anemones often with

New Species of Sagartiidae 185

Figure 1, A-B. Sagartia catalinensis n. sp. A. Columnar view of nearly expanded
specimen showing mesenterial insertions, white markings of column, suckers
(lower column), cinclides (upper column), and tentacles which are approximately
one half extended. B. Oral view showing tentacle markings, insertions of mesen-
teries including complete and incomplete mesenteries, and white markings of
disc. A and B to same scale. Photos by Jack W. Schott.

only diffuse retractors. Directive retractors slightly more restricted than
others (Fig. 2A, C, D). Up to about fifteen muscle processes per retrac-
tor; some processes quite branched. Mesenteries develop simultaneous-
ly from distal and proximal regions of anemone; fewer mesenteries seen
in middle of column (Fig. 2A, B).

Actinopharynx orange to salmon; corrugations well developed and
at least eighteen in number. Siphonoglyphs 1-3 in number; with
associated directives. A mesogleal, reticular sphincter may be lacking
in small specimens or weak to rather well developed in large specimens

186 Bulletin So. Calif. Academy Sciences|/Vol. 67, No. 3, 1968

(Fig. 2E). When well developed the sphincter is widest distally and
tapers to a point proximally. Acontia normal; with a distinct fin, numer-
ous nematocysts, and many gland cells. Acontia arise from mesenteries
of first two or three orders; coloration white; released with medium
agitation of anemone.

Cnidom: Spirocysts, microbasic b-mastigophores, microbasic p-
mastigophores, and macrobasic p-mastigophores (Classification after
Cutress, 1955). Sagartia catalinensis is the first species of the genus in
which macrobasic p-mastigophores have been found. Nematocyst data
were obtained from smears of living material from ten specimens.

Figure 2, A-E. Sagartia catalinensis n. sp. A. Transverse section taken in mid
region of column showing reduced number of mesenteries (2 cycles). B. Transverse
section taken in lower part of column showing 3 cycles of mesenteries. C. Perfect
mesentery in lower part of column. D. Directive mesetery in upper part of
column. E. Reticular mesogleal sphincter in longitudinal section.

New Species of Sagartiidae 187

—— 0.3mm

oS

188 Bulletin So. Calif. Academy Sciences/Vol. 67, No. 3, 1968

Measurements were taken from eight Santa Catalina Island and two
Los Coronados Island specimens. At least 100 measurements were
made, with a stage micrometer, for nematocysts of each category in the
following regions of the anemone: tentacles, column, actinopharynx,
filaments, and acontia.

Tentacles: Microbasic p-mastigophore — 16-23 by 3.5-4 p
Microbasic b-mastigophore — 7-12 by 4-5 yu
Microbasic b-mastigophore — 9-20 by 2-3 u
Spirocysts — 12-22 by 2.5-4.5

Column: Microbasic p-mastigophore — 16-22 by 3.5-5 p
Macrobasic p-mastigophore — 12-19 by 2.5-5
Microbasic b-mastigophore — 7-12 by 1.5-2.5
Microbasic b-mastigophore — 15-21 by 3-4 u

Actinopharynx: Microbasic p-mastigophore — 20-27 by 3.5-5 p
Microbasic b-mastigophore — 10-30 by 1.5-4 pu

Filaments: Microbasic p-mastigophore — 17-26 by 4-4.5 uw
Microbasic p-mastigophore — 9-15 by 4-5.5 u
(pyriform)

Microbasic b-mastigophore — 10-17 by 2 u

Acontia: Microbasic p-mastigophore — 27-43 by 3.5-6 pu
Microbasic b-mastigophore — 30-38 by 4-5 pu
Microbasic b-mastigophore — 12-17 by 2-2.5 u

Reproduction: Dioecious. Gonads develop on all perfect mesenteries,
including directives. Second cycle of mesenteries (imperfect) may bear
gonads. Asexual reproduction by pedal laceration (tearing); laceration
common.

Habitat and distribution: Firmly attached to substrate; generally to
vertical surface. Vertically distributed from slightly above mean lower
low water to a depth of 30 m at Bird Rock, Isthmus of Catalina,
California. Anemones very numerous in places. This species has been
collected at Santa Catalina and Santa Barbara Islands, California;
Cortez Bank, off the coast of Southern California; and Los Coronados
Islands, Baja California, Mexico.

Type Locality: Bird Rock, Santa Catalina Island, Los Angeles Co.,
California.

Holotype: Deposited at the Allan Hancock Foundation, University
of Southern California, Los Angeles; AHF Coeleterate number 1.

Paratypes: Abundant material deposited in the Allan Hancock
Foundation as AHF Coelenterate numbers 2-10.

New Species of Sagartiidae 189

DISCUSSION

Nematocysts, tentacle number and arrangement, and coloration dis-
tinguishes Sagartia catalinensis from the European species, S. elegans
and S. troglodytes. S. herpetodes, the Chilean species, also differs
markedly from S. catalinensis: McMurrich (1904) reported that in the
19 specimens of S. herpetodes studied all had more than one mouth (a
result of asexual reproduction), generally one or two large central
mouths and numerous smaller outer mouths. This species also differs
from S. catalinensis in coloration, size, and nematocysts. Table I pre-
sents a comparison of the known species of Sagartia.

A closely related genus, Actinothoe, differs from Sagartia only in its
lack of suckers. Actinothoe californica, described from the Gulf of
California by Carlgren (1940), has more tentacles than S. catalinensis,
different nematocyst size ranges, lacks suckers, and has been collected
only on the shell of a Murex.

In Southern Californian waters Sagartia catalinensis might at first
glance be confused with Metridium exilis. Both anemones are small,
have approximately the same number of tentacles, an orange to salmon
column and they occupy similar habitats. The two species, however,
may be distinguished externally by the presence of a distinct thin-walled
capitulum in M. exilis and the absence of such diffrentiation in S.
catalinensis. Internally the two species are distinguished by differences
in sphincter structure, mesenterial arrangement, and nematocysts.

The fact that S. catalinensis prefers vertical surfaces for attachment
becomes very evident when one compares the populations of this
anemone on the vertical mainland side (northeast) of Bird Rock and the
gentle sloping isthmus side (southwest). On the mainland side anemones
are very numerous. On the isthmus side, however, very few specimens
of S. catalinensis can be seen. Vertical preference was also observed
in the population of S. catalinensis at Los Coronados Islands. Some
specimens on the isthmus side of Bird Rock, which live in depressions
in which calcareous sands have collected, are attached to the rock below
and are completely covered by sand except for the tentacles and disc. To
these specimens particles of shell and sand are attached by the suckers
to the column, especially to its upper part.

Sagartia catalinensis also attaches to hard parts of many organisms.
It is commonly attached to the shell of Pseudochama exogyra and less
frequently to Hinnites multirugosus. In fact, on the mainland side of
Bird Rock Pseudochama exogyra is so common that it, or the barnacles
attached to it, are frequently the only substrates available for attachment
of the anemone. Other molluscs, Haliotis corrugata and H. sorenseni

190 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

have also been collected with S. catalinensis attached. Barnacles offer
good substrates for attachment. When attached to the insides of empty
barnacle tests, the anemones have only the upper part of the column or
tentacles extended beyond the orifice of the barnacle. Very infrequently,
S. catalinensis has also been collected from among the holdfasts of the
large brown algae, Egregia laevigata, Eisenia arborea, and Macrocystis
pyrifera.

Asexual reproduction is accomplished in Sagartia catalinensis by
pedal laceration, which involves an elongation of the pedal disc until
the body wall breaks with production of two fragments, normally a very
large parent fragment with mouth and tentacles and a single small
fragment (lacking mouth and tentacles). In a few instances small frag-
ments proliferated in rapid succession were observed. The small
fragments produced by pedal laceration are much larger in proportion
to the size of the adult anemone than those produced by the pinching
method seen in Aiptasia californica from the Gulf of California.
Specimens of S. catalinensis maintained in petri dishes in aquaria
frequently lacerate by extending the pedal disc over the lip of the dish.
By continued stretching towards the base of the petri dish, with one lobe
of the pedal disc on the inside and the other on the outside of the petri
dish, fragmentation is accomplished. Stephenson (1929) observed this
habit in S. elegans and Diadumene cincta.

Stephenson (1929) observed that asexual reproduction generally
produced anemones with irregular symmetry. Sagartia catalinensis
shows such irregularity in the numbers of tentacles, siphonoglyphs, and
perfect mesenteries. Regular symmetry is seen in very few specimens
of S. catalinensis; but when there is symmetry, one finds twelve pairs of
perfect mesenteries, two siphonoglyphs, and hexamerous arrangement
of tentacles.

Spermiogenesis in Sagartia catalinensis takes place in the usual
manner for actinarians: spermatocytes and spermatogonia develop in
the cortex of the folliculus and the more mature stages (spermatdzoa)
accumulate in the medullar region. As maturation occurs most of the
follicular volume becomes occupied with spermatozoa. Nyholm (1943)
reports that in S. troglodytes early spermatogonia are first seen at the
bottom of grooves in the mesenterial epithelium. Grooves of this nature
have not been observed in sections of S. catalinensis.

Spermatozoa are of the primitive type as described by Franzen
(1956), consisting of a distinct head, a short middle piece containing
mitochondrial spheres, and a tail. In S. catalinensis the head and middle
piece combined are 4-5 » long and pyriform. The middle piece contains
at least two mitochondrial spheres. An acrosome could not be detected.

New Species of Sagartiidae IgI

The tail is 50-55 » in length and apparently lacks the terminal thin-
ning reported for Tealia crassicornis (Retzius, 1904)?.

In general an ovum of actinians can be divided into an outer ecto-
plasm and an inner yolk-laden endoplasm as in Sagartia catalinensis.
The ectoplasm in S. catalinensis lies beneath a thin membrane and
consists of numerous fine granules interspersed among much larger
granules. Granules of both sizes readily take up neutral red. The
endoplasmic zone of S. catalinensis contains fine granules of yolk which
are also stained readily with neutral red. Observations on the cytology
of S. catalinensis ova are based upon nearly mature examples, which
are flesh colored and approximately 100-112 , in diameter.

Future collections on other offshore islands and the mainland should
reveal the presence of Sagartia catalinensis in suitable localities.

SUMMARY

A new species of sea anemone, Sagartia catalinensis, is described from
Southern California. A discussion of its habitat and general ecology
are given. Spermatozoa and nearly mature ova are described. The
asexual reproductive process is discussed.

ACKNOWLEDGEMENTS

I am greatly indebted to Dr. Russel L. Zimmer for guidance and
technical assistance; Dr. John L. Mohr for technical assistance; Jack W.
Schott for taking photographs and the Allan Hancock Foundation for
providing facilities and research space.

1 Carlgren (1959) had with some reservations placed herpetodes in the genus
Cerus which differed from Sagartia in the arrangement of mesenteries. His de-
cision to consider herpetodes a species of Cerus was based upon the dissection of
a single juvenile individual which had not lost its pedal disc as had the fourteen
other specimens. The juvenile had 160 tentacles and 130 basal mesenteries. Carl-
gren stated that the material was poorly preserved and difficult to diagnose. There
does not appear to be sufficient evidence to merit placing herpetodes in the genus
Cerus. In this report herpetodes is considered a species of Sagartia.

2 Nyholm (1949) believes that the Tealia studied by Retzius was probably Tealia
coriacea.

192 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

LITERATURE CITED

Carlgren, O. 1936. Some west American sea anemones. J. Wash. Acad. Sci. 26:
16-23.

. 1940. Eastern Pacific Expeditions of the New York Zoological
Society. XIX. Actiniaria from the Gulf of California. Zoologica. 25 : 211-219.

————.. 1949. A survey of the Ptychodactiaria, Corallimorpharia and Act-
iniaria. Kungl. Svenska. Fourth Series. 1 : 1-121.

. 1952. Actiniaria from North America. Arkiv for Zoologi. 3 : 373-
390.

. 1959. Reports of the Lund University Chile Expedition 1948-49.
Corallimorpharia and Actiniaria with description of a new genus and species
from Peru. ACTA Mus. Lund NS (2), 56: 1-38.

Cutress, C. E., 1955. An interpretation of the structure and distribution of
cnidae in Anthozoa. Syst. Zool. 4 : 120-137.

. 1961. Habrosanthus bathamae, n. gen., n. sp. (Actiniaria: Sagartii-
dae) from New Zealand. Trans R. Soc. New Zealand. | : 95-101.

Franzen, A., 1956. On spermiogenesis, morphology of the spermatozoon, and

biology of fertilization among invertebrates. Zoologiska bidrag fran Uppsala.
31: 355-380.

Gosse, Ph. H., 1855. On Peachia hastata with observation on the family of
Actiniadae. Trans. Linn. Soc. 21 : 267-276.

New Species of Sagartiidae 193
Hand, C., 1955. The sea anemones of central California. Part III. The Acon-
tarian anemones. Wasmann J. Biol. 13 : 189-251.

Hand, C. and R. Bushnell, 1967. A new species of burrowing acontiate anemone
from California (Isophellidae: Flosmaris). Proc. U.S. Nat. Mus. 120: 1-8.

McecMurrich, J. P., 1893. Report of the Actiniaria collected by the U.S. Fish
Commission Albatross. Proc. U.S. Nat. Mus. 16: 119-216.

. 1904. The Actinae of the Plate Collection (in Plate Faunna Chilen-
sis 3.2). Zoologische Jahrbuicher. Suppl. VI, Jena. 215-306.

Nyholm, K. G., 1943. Zur Entwicklung und Entwicklungsbiologie der Cerian-
tharien un Actinien. Zoologiska bidrag fran Uppsala. 33 : 69-77.‘

Retzius, G., 1904. Zur Kenntnis der Spermien der Evertebraten. Biol. Unter-
such. 11: 1-31.

Stephenson, T. A., 1929. On methods of reproduction as specific characters. J.
Mar. Bio. Assn. U.K., 16: 131-172.

. 1935. British sea anemones. II, Ray Soc. 121 : 1-426.
Uchida, T. 1960. Carcinactis ichikawai, n. gen,; n. sp., an Actiniarian com-

mensal with the crab Dorippe granulata. Jap. J. Zool. 12 : 595-601.

Accepted for publication June 10, 1968.

Bulletin So. Calif Academy Sciences/Vol. 67, No. 3, 1968

194

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RESEARCH NOTE

A NEW FOSSIL WEEVIL FROM NEVADA
(COLEOPTERA: CURCULIONIDAE)

The fossil specimen upon which the following description is based was
submitted to the author by Mr. Douglas Macdonald via Drs. Theodore
Downes and Charles Hogue of the Los Angeles County Museum of
Natural History. The specimen was so well preserved that it could be
determined to genus on sight. This find is significant in several ways. It
represents the first fossil snoutbeetle from Nevada. It is the first fossil of
the genus Rhyncolus and the first representative of the tribe Rhyncolini
of the subfamily Cossoninae known from North America (Scudder
1893, and 1900.)

The author wishes to thank Drs. Downes and Hogue for their
assistance and Mr. Macdonald for bringing this find to my attention.
The species is named for the daughter of Mr. Macdonald. The photo- -
graphs are courtesey of the Los Angeles County Museum of Natural
History. The figures in parentheses indicate the ratios of width to length,
respectively.

Rhyncolus kathrynae, Sleeper new species
Figures | and 2

Holotype: Nevada, Fernley (on Sam Swarz Ranch). Fossil, dorsum
and sides exposed. Pliocene: Hemphillian, Venturian-Hazen Flora (of
Axelrod). Holotype in the Entomological Collections of the Los Angeles
County Museum of Natural History.

Length 4.0 mm, width 1.3 mm. Rostrum short and broad (1.5:3.25),
dorsal profile slightly convex (Fig. 1), very finely punctate. Scrobes
and antennae not visible. Head very finely punctate, the punctures
scarcely impressed. Eyes very small, circular and finely granulate.
Prothorax (Fig. 2) slightly longer than wide (3.0:3.25), sides evenly
rounded to apical constriction, the latter very feeble, disc flat, very
finely punctate (about one-half the size of those of brunneus), punctures
separated by three-fourths their diameter, intervals between punctures
alutaceous. Scutellum as in other Rhyncolus. Elytra about two-fifths as
wide as long (3.5:8.0), sides feebly convergent in apical three-fourths,
then strongly rounded; disc with feebly impressed striae and strial
punctures; punctures twice the size of those of prothorax, first striae
deeply impressed in basal third; the intervals rather flattened, not

196

New Fossil Weevil 197

convex; interval nine strongly carinate at the humeri. Apex of the elytra
not completely visible. Venter with only the right one-third of the metas-
ternum visible. Metasternum very closely, deeply punctate, the punc-
tures slightly larger than those of the prothorax and separated by
one-half their diameter.

Figure 1. Right side view of holotype of Rhyncolus kathry nace.

Figure 2. Dorsal view of holotype of R. kathrynae. Line = | mm.

198 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

Discussion: This species is closely related to the present R. brunneus
Mannerheim (occurring in Pinus ponderosa and P. jeffreyi), but differs
from that species by the shorter rostrum (in brunneus as long as broad
not including mandibles); the punctures of the prothoracic disc much
smaller, the pronounced alutaceous intervals, and the flatter elytral
intervals (in brunneus feebly convex.)

The holotype is in place in a burrow in a small branch of fossilized
Pinus perhaps florrisanti. Adjacent to the holotype are other burrows of
this species and those of a species of Cerambycidae. The holotype was
partly in the bark of the branch, indicating that it died as it was in the
process of burrowing out of the host plant.

LITERATURE CITED

Scudder S. H., 1893. Tertiary Rhynchophorus Coleoptera of the United States.
U.S. Geological Survey Monographs. 21, 206 p.

1900. Canadian Fossil Insects. Contributions to Canad. Paleontology Il, pt. 2. —
Ottawa. 50 p.

Elbert L. Sleeper, Department of Biology, California State College at Long Beach,
Long Beach, California.

Accepted for publication May 22, 1968.

ATTACHMENT AND GROWTH OF THE
STOLONIFEROUS CTENOSTOME BRYOZOAN,
ZOOBOTRYON VERTICILLATUM

During studies on the feeding (Bullivant, 1967) of the stoloniferous
ctenostome Zoobotryon verticillatum (delle Chiaje) 1828 settlement of
the larvae and formation of the young colony were observed. As these
events are poorly understood in stoloniferous ctenostomes, the obser-
vations are reported herein.

Colonies of this bryozoan were obtained during the summer of 1965
from Newport Harbor, California. In some zooids of the arborescent
colonies single white larvae were observed. The polypides of these
zooids had regressed.

In the laboratory larvae were released from the colony more plenti-
fully during the morning. After liberation the larvae accumulated near
the lighted side of the aquarium. They began to settle within a few hours
on the glass walls of the aquarium, generally just beneath the surface,
rather than on the gravel bottom.

At metamorphosis individual larvae rotated on a selected spot for a
time, settled, and secreted a patch of cement. Within a few hours the
ancestrula (the metamorphosed body of the larva) grew a short stolon,
or rhizoid, the tip of which was applied to the substrate and spread out
as a disc. Sometimes, in small dishes, a larva settled on the surface film
of water and then the stolon grew vertically upwards through the sur-
face. Within 24 hours after settlement there were signs of the tentacles
and pharynx of the developing polypide of the ancestrula. Within 48
hours the first zooid had severed the original attachment made at meta-
morphosis and had lifted free from the substrate, remaining attached by
the stolon (Fig. 1). The polypide of the ancestrula soon emerged and
buds, which would give rise to more zooids, appeared on the stolon
proximal to the first zooid. After several days the young colony con-
sisted of a many zooids attached to the substrate by a single upright
stolon.

When appropriate food was supplied, later growth of the colony took
place in the following manner: One or more septa developed within the
stolon in the terminal bunch of zooids; then a group of zooids divided
into two, three, or four clumps, as one, two, or three new branches of the
stolon extended rapidly from the original group. Repeated branching
formed the mature colony.

Individual autozooids appeared to have a life of about six days in

199

200 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

Figure I First zooid of Zoobotryon verticillatum which has lifted free from the
substrate remaining attached by the expanded tip of the stolon. Developing
tentacles are visible and buds of more zooids occur on the stolon at the base of the
first zooid.

Growth Studies in Ctenostomes 201

young as well as in more mature colonies. During the short life of a
polypide, its caecum, which was initially transparent, became dark
brown in color, presumably because of the accumulation of metabolites.
When the polypide degenerated it left a “brown body” in the zooecium;
later the zooecium became detached from the stolon.

Large colonies of Zoobotryon verticillatum were reared under
laboratory conditions from larvae that settled in the laboratory; these
colonies were grown at room conditions from larvae using the aberrant
diatom Phaeodactylum tricornutum and the flagellate Monochrysis
lutheri. These colonies were grown at room temperature (about 24° C)
in 60 liter aquaria kept near a north-east window. In February, 1966
such colonies, which had been initiated in October 1965, produced lar-
vae which settled and developed on the sides of the aquaria.

An experiment conducted during the period in which larvae were
being released suggested that both growth and sexual reproduction were
limited by temperature. Parallel cultures were fed an excess of algae
and maintained at 20 and 25-26° C for 21 days; only those cultures at
the higher temperature grew and liberated larvae which settled and
metamorphosed.

Hyman (1959) reviewed settlement and colony formation in bryo-
zoans. In carnose ctenostomes and cheilostomes, the ancestrula dif-
ferentiates in situ as the first zooid and the colony is formed by budding
of one zooid from another. The auto-zooids are in direct communication
by interzooecial pores and each (except the ancestrula) may have both
sexual and asexual capabilities. In contrast, the auto-zooids of stoloni-
ferous ctenostomes have sexual, but no asexual potential, and com-
municate with each other only through the stolon to which the blasto-
genetic function is restricted. The ancestrula produces this stolon and
also may form attachment rhizoids, but rarely develops a polypide.
Hyman reported the ancestrulae of Farrella, Mimosella, Vesicularia,
Walkeria and Zoobotryon [pellucidum] lack polypides and cited only
Amathia lendigera as exceptional in this regard.

Zoobotryon verticillatum then provides another example of a
stoloniferous ctenostome in which the ancestrula differentiates as a
functional zooid. This species also is unusual in that the permanent
attachment of the colony is not formed by the ancestrula at metamor-
phosis but is secondarily established by the distal tip of the stolon.

ACKNOWLEDGMENTS

The author wishes to thank Dr. Russel L. Zimmer for his constructive criticism
of the manuscript. The author’s Ph.D. dissertation from which this information
is taken was prepared at the University of Southern California.

202 Bulletin So. Calif. Academy Sciences|Vol. 67, No. 3, 1968

LITERATURE CITED

Bullivant, J. S., 1967. Aspects of feeding of the bryozoan Zoobotryon verticil-
latum (delle Chiaje). Ph.D. dissertation, University of Southern California,
Los Angeles. 165 pp.

Hyman, L., 1959. The Invertebrates: Smaller Coelomate Groups. Vol. V.
McGraw-Hill Book Co. Inc., New York. 783 pp.

John S. Bullivant, Department of Biological Sciences, University of Southern

California. Present address: New Zealand Oceanographic Institute, Department

of Scientific and Industrial Research, Wellington, New Zealand.

Accepted for publication June 10, 1968.

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Southern California
Academy of Sciences

OFFICERS OF THE ACADEMY

Dr. Jay M. Savage ....... Sidon cys 6 laa le SUE < ARC ied eee President

om iAP I IVIOTTIS 25. s soake de se cdo atl. ole gs cs sce First Vice President

Pepi tcigyee CHUNAS) 2 ois .jite enw sh ole ves ee eee wees Second Vice President

Sie ETM EEL IR OFAIEC 5.0 < 5 5 odie Oe wake aie cleo a sds swede epule ee Secretary

Rilem Sse I BeIOUS wilt salar o Slatets woke « (Wkers ahelsle nls cca ciesle aos Treasurer

NMRPAPEAIDIPIPMICCUSIIE 20) apy hyo’ 2s a: vib jajle = saci's, age tale <9 6 ss ee 0 ew bends Editor
DIRECTORS

Philip A. Adams Richard Etheridge Jay M. Savage

Russell E. Belous William J. Morris Elbert L. Sleeper

Henry E. Childs Donald J. Reish Andrew Starrett

Jules Crane Charles E. Rozaire

ADVISORY BOARD

Shelton P. Applegate George D. Fisler John L. Mohr
James R. Dixon Donald Lowrie David L. Walkington
James W. Dole J. R. Macdonald Russell Zimmer

The following past presidents are automatically members of the Advisory
Board: John A. Comstock, Theodore Downs, Hildegarde Howard, Richard B.
Loomis, Kenneth E. Stager, Richard H. Swift, Fred S. Truxal, Louis C.
Wheeler, John A. White, Sherwin F. Wood.

STANDING COMMITTEES

Finances Membership

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SPECIAL COMMITTEES

Fellows Nominating
Fred S. Truxal, Chairman Philip A. Adams, Chairman
AAAS Award Program

John L. Mohr, Chairman Andrew Starrett, Chairman

ad

4

ee

Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

VOL. 67 OCTOBER-DECEMBER 1968

CONTENTS

Bryozoan Fouling Organisms from Oahu, Hawaii with a New
Species of Watersipora. Dorothy F, Soule and John D. Soule

Introduction of an Amphipod Crustacean into the Salton Sea,
California. J. Laurens Barnard and W. Scott Gray

The Genus Hexidionis (Acarina, Trombiculidae) with the De-
scription of a New Species from Western Mexico. James L.
Lucas and Richard B, Loomis

The Structure of the Chela of Heterometrus Sp. and its Mode of
Operation. M.S. Dubale and A. B. Vyas

Mimosella Cookae, New Species (Bryozoa, Ctenostomata), with
a Review of the Family Mimosellidae. William C. Banta

The Ecological Significance of Feeding Behavior in the Mexican
Lizard, Anolis Barkeri. John R. Meyer

The Affinities of the Genus Sobobapteron Pierce. F. M. Carpen-

Breeding of the Black Swift in Veracruz, Mexico. Charles T.
Collins

DECEMBER 31, 1968

Beem LLETIN OF TFHE

No. 4

203

219

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BULLETIN OF THE SOUTHERN CALIFORNIA
ACADEMY OF SCIENCES

Vol. 67 OCTOBER-DECEMBER, 1968 No. 4

BRYOZOAN FOULING ORGANISMS FROM OAHU, HAWAII
WITH A NEW SPECIES OF WATERSIPORA

DoroTuy F. SOULE! AND JOHN D. SOULE?

INTRODUCTION

During the course of an extensive study of the bryozoans of the Ha-
waiian Islands, particular note was made of a relatively few species
which generally constitute the bryozoans in the fouling communities in
many locations there. On the island of Oahu, the authors made collec-
tions at Kaneohe Bay from fixed and floating docks, from rafts, from
suspended metal test panels, and from glass slides which were mounted
in screened racks and hung at various depths. Boat hulls were scraped
there and also at Ala Wai Yacht Harbor, where collecting was done as
the boats were being raised for drydocking at Ala Wai Marine, Ltd.
To the above information has been added data on the fouling species
identified by the authors from the University of Hawaii collections
and from the Bernice P. Bishop Museum collections. Much of the
material from these latter sources lacks accurate collecting data,
however.

Members of the bryozoan phyla (Entoprocta and Ectoprocta) are
among the most common fouling organisms, particularly during the
warmer months of the year. Throughout the world some 150 species are
known which foul ships’ hulls, buoys, floats and test panels (Hutchins,
1952). At times the bryozoans may constitute nearly 100 percent of the
fouling organisms on a given surface.

On Oahu, thirteen species were found repeatedly, though in varying
quantities, on harbor installations and boats. One frequently collected
form, which at first was included in Watersipora cucullata (Busk),
has been designated a separate new species Watersipora edmondsoni

1Research Associate, Allan Hancock Foundation, University of Southern Cali-
fornia, Los Angeles, California, and Moore Laboratory of Zoology, Occidental
College, Los Angeles.

2Research Associate, Allan Hancock Foundation, University of Southern Cali-
fornia, Los Angeles, California, and American Museum of Natural History, New
York, New York.

203

204 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

in honor of Charles Howard Edmondson, who pioneered in efforts to
identify the rich reef and shore fauna in Hawaii.

The harbor areas investigated in this study offer diverse exposures,
water conditions, and shipping traffic on Oahu. Kaneohe Bay is located
on the windward northeast coast, bound on the south by Mokapu
Peninsula and on the north by Kuloa Point. The bay is shallow, much
of it five fathoms or less; boat traffic is largely local fishing boats and
pleasure craft. In recent years the bay has been subject to a greater
than normal freshwater and soil runoff, due to extensive subdivision
along the southwest shore. A freshwater lens often forms on the bay
following heavy rains, which are common during the winter months.
Pollution from shipping or industry is not a problem, as compared
with Honolulu or Pearl Harbors. The runoff has however greatly
increased growth of the bluegreen algae Phormidium crosbyanum,
which forms large green blisters or globes on much of the shallow bay
floor. Relatively low influx of sewage is rising, adding phosphate
(Bathen, 1968).

The University of Hawaii marine laboratory is located in the south-
ern portion of Kaneohe Bay on Moku O Loe Island (Coconut Island);
many collections for the present study were made there. Edmondson
and Ingram (1939) reported on fouling organisms in Hawaii, primarily
from Kaneohe Bay, and identified six species of bryozoans in their
study: Bugula neritina, Zoobotryon pellucidus, Aetea truncata, Cate-
naria lafonti, Rhynchozoon nudum, Schizoporella unicornis, plus
Amathia, sp.

Ala Wai Yacht Harbor is a pleasure boat anchorage on the south
coast of Oahu, east of Honolulu Harbor. Ala Wai Canal, a major fresh
water drainage channel, empties into the ocean at the harbor. House-
boats, which had been anchored only in the local basin for several
years prior to drydocking, were selected for collection of specimens.
Some of the hulls were completely carpeted with fouling organisms,
with bryozoans constituting by far the major portion of the surface
organisms. Specimens were scraped alive from the hulls and placed
immediately in buffered formalin or isopropyl! alcohol.

On the hulls incrusting species provide a surface layer to which
other organisms apparently then attach. The soft-bodied ctenostomes
form trailing masses 20 to 25 cm in length, or when mixed with firmer
branching cheilostomes form a thick feltwork. These growths in turn
provide shelter for numerous small crustaceans, polychaetes, young
mollusks, tunicates, and algae.

Fouling at Pearl Harbor was discussed by Edmondson (1944), but
only two species of bryozoans were mentioned: the common Bugula

Bryozoans from Hawaii 205

neritina and Schizoporella unicornis. Pearl Harbor, an improved deep
water harbor with a single entrance, receives considerable freshwater
runoff from half a dozen streams and drainage outlets and is extensively
polluted by shipping and industry.

Honolulu Harbor is a much smaller harbor with two entrances and
two major stream-drainage outfalls. It has much commercial shipping
traffic. Although little collecting was done at Pearl or Honolulu Harbors
by the authors, they are represented by a wealth of material in the
Bishop Museum collections from those sites. An extensive study of
bryozoans is still underway at the leeward west end of Oahu, at Pokai
Bay.

This project is supported in part by National Science Foundation
Grants GB 5208 and 7723. The cooperation of Drs. Sidney Townsley
and Philip Helfrich of the University of Hawaii has been invaluable
and is greatly appreciated. The rafts and steel plates in Kaneohe Bay
from which our traps were suspended were a part of a project supported
by Lockheed Corporation, and were made available through Mr.
James McVey and Dr. Ernest Littauer. The Bernice P. Bishop Museum
collections were made available through the kindness of Drs. Lucius
Eldredge and Dennis Devaney. Eve Myers and Pete Arapoff were most
helpful in arranging for the authors to collect from hulls known to be
from local waters as they were freshly exposed on being raised for dry-
docking at Ala Wai Marine, Ltd.

FOULING BRYOZOANS OF OAHU

Phylum Entoprocta
Barentsia gracilis (M. Sars), 1835

Phylum Ectoprocta
Order Ctenostomata
Amathia distans Busk, 1886
Bowerbankia gracilis Leidy, 1855
Bowerbankia imbricata (Adams), 1800
Zoobotryon verticillatum (delle Chiaje), 1828
Order Cheilostomata, Suborder Anasca
Aetea truncata (Landsborough), 1852
Bugula californica Robertson, 1905
Bugula neritina (Linnaeus), 1758
Scrupocellaria sinuosa Canu and Bassler, 1927.
Order Cheilostomata, Suborder Ascophora
Hippopodina feegeensis (Busk), 1884

206 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

—

Savignyella lafonti (Audouin), 1826
Schizoporella unicornis (Johnston), 1847
Watersipora edmondsoni new species

KEY TO THE FOULING BRYOZOANS
OF OaHu, Hawall

7a) Colony recumbent stolonatei= 445 4440 eee (2)
b) Colony incrusting or erect; not stolonate .............. (7)
. a) True stolons formed by modified

individuals lacking aperture or

tentacles; non-calcareous’ 235: eee (3)
b) False stolons formed by expansion of the

bases of normal individuals; calcareous

(EctoproctayCheilostomata) eee nee eee Aetea truncata

. a) Normal feeding individuals consisting of

stalk (pedicel) and head (calyx), with

joints; (Entoprocta) yee eee ee Barentsia gracilis
b) Individuals not consisting of stalk
andi calyx:*saccitorm(Ectoprocta)l.- 454 50- eee (4)

. a) Individuals arranged spirally in pairs

biserially around distal part of
cachystolongscomentsneeer a ieee Amathia distans
b) Individuals not in biserial spirals ................... (5)

. a) Individuals arranges bilaterally along

stolon with occasional clusters;

nNocaudalaprojecuonsmer sy eee Zoobotryon verticillatum
b) Individuals single or in pairs or clusters;

somenwaith’ caudal) projeciion’ 44). 44440 4 ae eee (6)
. a) Polypide with ten tentacles ........ Bowerbankia imbricata
b)MWithmershtitentaclesme ia Bowerbankia gracilis
~a) Colony ‘erect, branching 55.) 4545007. (8)
b)i€olony forming faticrustsy) eee (11)

. a) Colony with branches formed of biserial

rows of individuals; no joints;

frontal uncaleified: 2). 5.28) 485.220) eee (9)
b) Colony with branches formed of alternate

individuals; with joints; frontal with

shield or calcified 2... ee ee (10)

. a) Colony bushy, reddish brown. No spines

or avicularia (pincers). Ovicells
large, set diagonally proximally ........... Bugula neritina

Bryozoans from Hawaii 207

b) Colony whitish; individuals with three
spines at distal corners, large and
small avicularia on side walls; ovicells
plobular centered 4.465252 056-25 5608 Bugula californica
10. a) Colony fragile, whitish; seven individuals
to a segment, with light colored joints;
uncalcified frontal with an oval shield
(scute) raised over frontal from
COMOMNI TN arse eae ala oa eS A Scrupocellaria sinuosa
b) Colony branched or spreading, bright red;
individuals uniserial, jointed, trumpet-
shaped; frontal calcified with six
spines around aperture ............... Savignyella lafonti
11. a) Lightly calcified; with ovicell and
frontal perforate; aperture hoof-
shaped, rounded distally .......... Hippopodina feegeensis
b) More heavily calcified; frontal
perforate; aperture with a notch
(sinus) Or curve in proximal edge ................... (12)
12. a) Avicularium on one or both sides of
aperture; aperture with proximal
notch; large perforate ovicell
ADOVEMAPERtUEC) 20 en =. oS Schizoporella unicornis
b) No avicularia, ovicell internal
(endozooecial); aperture with sinus,
cardelles at corners, ovoid; operculum
with dark brown center pillar and
rim; colony orange-brown to
Nigar sien ee 8 ed ales a4 Watersipora edmondsoni

Aetea truncata. Tiny stolon-like colonies wander across irregular
surfaces and over other bryozoans. From the stoliform base, each
individual raises an erect rough tube which has an uncalcified frontal
membrane and an operculum at the distal, head end. A. truncata is
straight across at the distal tip, as though clipped off. Other species of
Aetea have wrinkled erect tubes and spoon-shaped heads.

Aetea truncata (Pl. 1, Fig. 6) was reported by Edmondson and
Ingram (1939) in the fouling community at Kaneohe Bay, but its
importance was discounted because of its negligible vertical growth.
However it is often the initial colonial organism to occupy a substra-
tum, the tubules providing surface irregularities for other organisms
to colonize, and it is thus significant. A. truncata is represented in the

208 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

.

Plate 1.
Figure 1. Calyx of Barentsia gracilis; note tentacles curled on face of calyx.

Figure 2. Barentsia gracilis, showing expanded base, pedicel and calyx.
Figure 3. Amathia distans; note spiral arrangement of zoids around stolon.

Figure 4. Bowerbankia, sp. Zooecia showing subterminal attachment to stolon,
caudal protrusions.

Figure 5. Zoobotryon verticillatum; note wide stolon and small zooecia distri-
buted bilaterally.

Figure 6. Aetea truncata, portion of colony showing erect individuals.

Figure 7. Scrupocellaria sinuosa; note spines and scute over the frontal area.

Bryozoans from Hawaii 209

Bishop Museum collections, from Kaneohe Bay, from Honolulu Har-
bor, and “off Oahu” at 9.1 and 27.4 m depths; collected in December,
January, June and September with no other seasonal or locality data
given.

Collected by the authors in July and August 1966, at Kaneohe Bay;
common on glass slides suspended in screened settling traps at 3.05 m
depth. Water temperature, 26° to 28° C. Aetea truncata is widely
distributed in cool temperate to tropical waters around the world
(Osburn, 1950).

Amathia distans. Extensive, soft, trailing colonies are formed by
biserial rows of small plump tubular zooecia which spiral around the
distal portion of each stolon segment. Apertures are terminal, squared,
open. The soft matted masses of the colonies host many small inverte-
brates. Edmondson and Ingram discounted the species as a fouling
organism of importance because it presumably would break off a boat
hull underway. However interisland barge traffic is rather slow moving,
and the colonies seem to form shorter, more dense growths on such
hulls. Amathia colonies also are sometimes found interwoven with
more rigid bryozoan species such as Bugula californica, giving firmness
to the soft-bodied growths.

Amathia distans (P|. 1, Fig. 3) was collected at the University of
Hawaii marine laboratory fixed and floating docks at a depth of 0.3-
0.6 m at Coconut Island in Kaneohe Bay. It is represented in 18 lots of
the Bishop Museum collections, taken from Kaneohe Bay, Honolulu
Harbor, and Pearl Harbor, and off Ft. DeRussy. Every month of the
year is represented in the collections except March and October. Found
also in the University of Hawaii collections. A. distans has been re-
ported from the south Atlantic, Australian waters, Java, Puerto Rico,
Puget Sound, and from southern California and the Gulf of California
(Osburn, 1953; Soule, 1963).

Barentsia gracilis (Entoprocta) (Pl. 1, Figs. 1, 2). The only entoproct
as yet identified to species level in the Hawaiian collections is small
and delicate, with long stolons which extend over smooth surfaces or
creep in about hydroids and other bryozoans. Individuals consist of a
stalk with basal swelling and joints, and with a cup-shaped calyx which
hangs to the side with tentacles extended. Barentsia gracilis was col-
lected by the authors at Kaneohe Bay, growing on the fixed dock on
stolons of Amathia, and also on glass slides suspended in screened
traps at 3.05 and 6.1 m depths. Because the species is so small and
inconspicuous it has been discounted as a fouling organism. However
it was the first organism to colonize the smooth glass surface of many
of the slides, and would thus furnish larger organisms with a roughened

210 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

substratum. Although B. gracilis was not found in the Bishop Museum
collections, it is probably more common than might be thought and is
overlooked because of its small size. It requires immediate preservation
for identification. This species is worldwide in distribution, according
to Harmer (1915), and Osburn (1953).

Bowerbankia gracilis. A ctenostome, this species forms a colony
which is a tangled mass of trailing stolons bearing individual zooecia
singly, in pairs, or in clusters. It is often covered with algae and en-
tangled with other bryozoans. Bowerbankia gracilis has eight tentacles,
determined by sectioning, as do many species of Bowerbankia.

Bowerbankia gracilis was identified from boat hulls in the Ala Wai
Yacht Basin in July and August, mixed with Bugula californica and
Bugula neritina as well as other ctenostomes. Also found on the under-
sides of the floating docks at the University of Hawaii marine station,
at depths of 0.3-0.6 m in July and August.

Bowerbankia imbricata. The colony is a tangled mass of stolons

with individuals clustered or not. This species has ten tentacles, deter- —
mined by sectioning, which distinguishes it from other species of
Bowerbankia with certainty. The stolons are generally thicker than
those of B. gracilis, with which it is often intertwined.
Bowerbankia, sp. was collected on suspended glass slides at 3.05
and 6.1 m depths, but the colonies were small and were not sectioned. It
was also identified in four lots of the Bishop Museum collections, taken
from Kaneohe Bay, Pearl Harbor, and Honolulu Harbor in January,
February and May. This latter material was not well enough preserved
to section and make tentacle counts for species identifications.

Prenant and Bobin (1956) indicate that there has been great con-
fusion in the past over the identification of the species of Bowerbankia.
The distribution record indicate that B. gracilis is a cosmopolitan
species. B. imbricata has been more frequenily reported from cooler
waters, but is known from the Red Sea, Japan and the Indo-Pacific
(Osburn, 1953; Prenant and Bobin, 1956), in marine and brackish
waters (Bowerbankia, sp. Pl. 1, Fig. 3).

Bugula californica. This species forms a whitish, branching and
bushy, unjointed colony and is often found mixed with hydroids, other
bryozoans and algae on dock pilings. B. californica is easily distin-
guished by having biserial branches, globular ovicells centered distally,
two or three short spines at the distal corners, and raised, “birds-head”’
avicularia along the side walls. Bugula species bud from the dorsal,
distal end of the zooecia, giving a forked shape to the proximal ends
of the new individuals. Bugula californica is not as frequently recog-
nized by collectors as is the reddish-brown Bugula neritina, and magni-

Bryozoans from Hawaii 211

fication is required to recognize the distinctive taxonomic features.
B. californica has not previously been identified from Hawaiian waters
by other investigators, but it occurs repeatedly in the Bishop Museum
collections.

The authors collected B. californica from floats and rafts at Kaneohe
Bay, growing from the shaded undersides in 0.3-1.2 m depths of water,
in July and August. It was also scraped in quantity from houseboats
anchored in Ala Wai Yacht Basin. Museum data shows that specimens
have been collected from December through June, but complete data
is lacking on many of the 35 lots in which B. californica occurs; 25 lots
are from Honolulu Harbor and the rest from Pearl Harbor. Also found
in the University of Hawaii collections.

Bugula californica (Pl. 2, Fig. 1) ranges the eastern Pacific coastline
from British Columbia to Mexico, the Gulf of California and the
Galapagos Islands, in cool temperate to tropical waters. Also reported
from Brazil (Osburn, 1950; Soule, 1959).

It seems possible that Bugula pedata Harmer, 1926, from the Siboga
collections, may be synonymous with Bugula californica Robertson,
1905. Unfortunately Harmer had no locality data, and no ovicells
were present on the single colony he had. The description of the two
species are similar, and the method of branching 1s also; the axillary
zooecium is immersed below the point of bifurcation like Harmer’s
Type 5 branching.

Bugula neritina (P\. 2, Fig. 2). Perhaps the best known bryozoan,
this species forms reddish-brown colonies prominent in many fouling
communities. The zooecia are large, lightly calcified, and there are no
avicularia. The ovicells are quite large, globose, and set at an angle at
the distal end of the zooecium. B. neritina is common in Kaneohe Bay,
on floats, rafts, and hulls from 0.3-1.2 m depths; also collected on glass
slides in screened settling traps suspended at 3.05 m depths, during
July and August. Quantities of B. neritina growing in extensive,
branching colonies, were scraped from houseboats anchored in the
Ala Wai Yacht Basin in Honolulu. It occurs in 66 lots of the Bishop
Museum collections, taken about equally from Pearl Harbor, Honolulu
Harbor and Kaneohe Bay. All months except January are represented.
Also found in the University of Hawaii collections. B. neritina is dis-
tributed around the world in warm temperate to tropical waters.

Hippopodina feegeensis. An incrusting species, the colony formed
is delicate and lightly calcified so that it may easily be overlooked. The
calcified frontal is perforated by numerous pores, as is the ovicell
which lies above the aperture. The aperture is hoof-shaped (hence the
genus name of horse-footed), with straighter sides and an arcuate

212 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

proximal lip. The aperture rim is raised, and individuals are separated
by ridges. Avicularia are long, triangular, and may be single or in pairs,
pointing either distally or proximally, or they may be absent entirely
over much of the colony.

H. feegeensis (Pl. 2, Fig. 3) has been identified by the authors for the
first time in Hawaiian waters, scraped from the underside of a raft, at
0.3-1.2 m depths in Kaneohe Bay. It was also found in seven lots of
Bishop Museum material, six taken from Honolulu Harbor and one
from Kaneohe Bay. Not recorded from Pearl Harbor. A warm water
species, H. feegeensis is actually a misnomer, the type specimen having
come from the Philippine Islands, according to Hastings. It is also
known from the Indo-Pacific and Atlantic, from Florida to Brazil. In
the eastern Pacific it was collected once off Colombia, and found in
southern California as a Pleistocene fossil (Harmer, 1957, Osburn.
1952, Soule and Soule, 1967).

Savignyella lafonti (Pl. 2, Fig. 4). A delicate, red, branching or
spreading colony is formed showing uniserial series of zooecia with a —
joint between each individual. Dried colonies are white. The proximal
end of the zooecium is imperforate and tubular; it widens into a trum-
pet shape bearing large frontal pores. The subterminal aperture is
round, surrounded with six short spines. Ovicells are globular and
perforated. Savignyella lafonti is inconspicuous, and since it loses its
color soon after collecting, can easily be overlooked. Edmondson and
Ingram discounted the species as a fouling organism, although it is
stiff enough to give a certain rigidity to softer species with which it
becomes entwined. Collected by the authors, it was common on floats
and rafts in the shallow waters in Kaneohe Bay, and was frequently
the initial colonizer on glass slides suspended in screened traps at
3.05 m depth. Also found intermixed with Amathia, Zoobotryon,
and Bowerbankia. The species was identified from five lots in the
Bishop Museum collections, from Pearl Harbor, Honolulu Harbor
and Kaneohe Bay. S. lafonti is circumtropical in occurrence and is
also found in warm temperate waters in the Atlantic and has been
found in southern California harbors occasionally. (Harmer, 1957;
Osburn, 1952).

Schizoporella unicornis. This species usually forms a flat crust over
various surfaces, but may occasionally form branching, raised colonies.
The zooecium frontal is perforate, the aperture has a median notch
or sinus, and the avicularia, when present are never median. S. uni-
cornis has a small tubercle (umbo) proximal to the sinus, and the
avicularia are laterial to the aperture, paired or single. The ovicell is
prominent and bears pores and ridges. On living material it is usually

Bryozoans from Hawaii 23

«@
*
i“

oe ot sx et
"2 ys:
* : nd
“ape lamy fee
j “gr
»@. ic
. PS
te, ao’ ‘
aS - . Mp
Oe te Mig
wore 4
—” Bt
~ ie @ <i ‘ ;
oe ee a tals at - 1,"
eee “< tag: +o “+06 ¥vy"
oe 7 =e - ay rn
PR EERE
a) be PAPAS og Ole s2 a o

Plate 2

Figure 1. Bugula californica, showing ovicells, corner spines and “bird’s-head”
avicularia.

Figure 2. Bugula neritina, with pointed distal corners, large ovicells set off-center.

Figure 3. Hippopodina feegeensis. Note hoof-shaped aperture, avicularium on
center Zooecium.

Figure 4. Savignyella lafonti, with trumpet-shaped individuals, ovicells distal to
aperture.

Figure 5. Schizoporella unicornis. Aperture with proximal notch, lateral avicu-
laria.

Figure 6. Watersipora edmondsoni, new species, showing mushroom-shaped
opercular darkening, lateral cardelles (denticles) and tiny knobs at base of sinus
notch.

214 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

necessary to remove the outer coating with bleach or by incineration
in order to see the diagnostic features.

S. unicornis (Pl. 2, Fig. 5) was tentatively identified by Edmondson
and Ingram (1939) as the incrusting species which is especially abun-
dant in Kaneohe Bay, reproducing year round. They record a rapid
rate of settling and colony growth. Edmondson (1944) diagrammed
an ancestrula and the stages following settling, at Pearl Harbor. A
brilliant orange, the live colonies are found on almost every substratum;
glass, wood, shells, coral, and boat hulls. It is represented in the Bishop
Museum collections in 14 lots, from Kaneohe Bay, Pearl Harbor, and
Honolulu Harbor, and in the University of Hawaii collections. Also
found by the authors on floating docks at Kaneohe Bay, 0.3-1.2 m
depths, and at the Ala Wai Yacht Basin on boat hulls. The species is
widely distributed in the western Atlantic from Nova Scotia to Brazil,
the eastern Atlantic from Norway to South Africa; the Red Sea, Indo-
Pacific, Japan, Queensland and the Loyalty Islands. Found also in
southern California and the Gulf of California (Marcus, 1937; Osburn,
1952; Soule, 1961; Soule and Soule, 1964).

Scrupocellaria sinuosa. The colony is fragile, branched and whitish;
it may be confused with Bugula in growth form, but magnification
shows branches composed of segments of about seven zooecia, sep-
arated by light colored joints. There is a distinctive oval scute (shield),
which arises at the side of the frontal membrane and arches out over
it, with a branching pattern on the scute. Most species of Scrupocel-
laria have some type of scute. S. sinuosa has numerous avicularia, 3
or 4 small spines, and a few whips (vibracula) present. The dorsal side
of the colony shows a sinuous line between adjacent zooecia, many
rootlets. Ovicells bear large pores.

Scrupocellaria sinuosa (Pl. 1, Fig. 7) was first described from the
island of Kauai, Hawaii by Canu and Bassler (1927). The colonies,
though delicate and brittle, are sufficiently calcified to give rigidity
in an aggregation of softer species. Found in one lot of Bishop Museum
material, from Kawela Bay, northern Oahu, and in the University of
Hawaii collections. Collected in small quantities by the authors at
Kaneohe Bay. While S. sinuosa cannot be considered as a major
fouling organism, it is worthy of note because it is the only species so
far identified in the fouling community that appears to be endemic to
Hawaii. Canu and Bassler (1927) pointed out several species with
which it had some similarities, but there were important differences
also. S. sinuosa does not fit precisely with any of Harmer’s Siboga
descriptions (1926) or with Osburn’s Pacific coast species (1950).

Bryozoans from Hawaii 215

Watersipora edmondsoni, new species.
Plate 2, Figure 6

Diagnosis: Zoarium incrusting, reddish-brown to tan; growth usually
unilaminar, subradial. Zooecia alternating, elongated when a single
row widens into two rows. Aperture ovoid with a raised rim, a wide
proximal notch and paired cardelles. Operculum with dark brown
central pillar and distal rim areas; light areas on either side of pillar.
Small white knobs on either side at base of pillar area. Frontal with
large pores. No avicularia, no spines; no external ovicells.
Description: The zoaria form fan-shaped to discoidal unilaminar
colonies 20-30 cm in diameter, growing out distolaterally from the
ancestrula and later almost joining behind it. The marginal zooecia
are somewhat raised and furled under. The disks of the colonies of
Watersipora edmondsoni commonly had a colony of Bugula californica
or Savignyella lafonti rooted in the aperture of the dead ancestrula
and standing erect above the incrusting colony. Zooecia are distinct,
separated, elongate, widest below the aperture, with numerous large
pores in the frontal. The aperture is surrounded by a raised rim, some-
times with a slight distal keel, and a wide proximal notch or sinus. No
external ovicells are found; the ovicells of Watersipora are endo-
zooecial (internal at the proximal end of the zooecia). Zooecial dimen-
sions vary: length 1200 « by 400 wide to those measuring 800. long
and 600 wide. Apertures varied from 230 to 260, in width, but
the height of the aperture at the deepest part of the sinus was 220, in
all those measured.

The most distinctive feature of the new species is the operculum.
In superficial examination of the colonies, the opercula stand out as
dark brown, mushroom-shaped structures. The opercular are shaped
like the aperture, ovoid and with a curved lower portion that fits into
the sinus area. A dark, chitin-like central area, resembling a pillar or
a mushroom stem, extends from the sinus distally, widening out at the
upper edge of the operculum until it resembles a mushroom cap. This
leaves lighter areas on either side of the stem. A thin chitinous rim
circles the entire operculum, and a chitinous sclerite extends from
each cardelle to the stem area. Two small white knobs flank the base of
the stem.

Watersipora edmondsoni appeared in field collecting to be a Schizo-
porella sp. because of its orange color. When dry, it resembles Water-
sipora cucullata (Busk) 1854 in the appearance of the rows of zooecia.
W. cucullata has been reported around the world in warmer waters.
However Hastings (1930) noted that there are a number of differences
in the opercula of specimens reported or collected from different areas

216 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

and she suggested that several species probably would be eventually
distinguished. The operculum of W. edmondsoni most closely resem-
bles Hasting’s illustration of a specimen from Amoy, off China.
Mawatari (1952) illustrated oriental specimens which also appear
similar, but do not show sclerites of the same pattern as the new
species or the exact pattern in the central chitinous portion of the
operculum.

Watersipora edmondsoni was collected by the authors in quantity
on houseboats in the Ala Wai Yacht Harbor, in Honolulu. In spite of
the extensive collections of the Bishop Museum, no Watersipora has
been previously reported in Hawaii. Most of the Bishop collecting
was done between 1935 and 1956, and it seems to have been introduced
and become established since that time. A similar situation was re-
ported by Skerman (1960) in Aukland Harbor, New Zealand, where
Watersipora had never been found on test panels until 1960.

Holotype: Allan Hancock Foundation Bryozoan No. 149.

Zoobotryon verticillatum | =Z. pellucidus] (Pl. 1, Fig. 15). A soft,
branching translucent spaghetti-like colony is formed by Zoobotryon,
which may be almost completely covered with silt and algae when
collected. Zooecia are arranged bilaterally along the broad stolons,
although they may occasionally occur in clusters. The zooecia do not
spiral around the stolons as do Amathia sps. Individuals are saccate,
with a blunt square distal tip and terminal aperture. The caudal end
is attached directly and terminally to the stolon, whereas species of
Bowerbankia are attached subterminally and have caudal projections
on some zoids. Z. verticillatum was collected in Kaneohe Bay in July
and August, from both floating and fixed docks, where it was hanging
in great tangled streamers. It occurs in 15 lots of Bishop Museum
material, collected from Pearl and Honolulu Harbors and Kaneohe
Bay, in all months but February and March. Known to be circumtropi-
cal, it is also found in subtropical embayments (Osburn, 1953); re-
ported from Hawaii by Robertson (1921).

LITERATURE CITED

BATHEN, K. H. 1968. A descriptive study of the physical Oceanography of Kane-
ohe Bay, Oahu, Hawaii. Hawaii Inst. Mar. Biol., Tech. rept. No. 14, 353 pp.

CANU, F., AND R. S. BASSLER 1927. Bryozoaires des Iles Hawai. Bull. Soc. Sciences,
Seine & Oise. Facs. 7, suppl.: 1-66.

Epmonpson, C. H. 1944. Incidence of fouling in Pearl Harbor. B. P. Bishop Mus.
Occas. Papers, 18: 1-34.

Bryozoans from Hawaii Dig

EDMONDSON, C. H. AND W. M. INGRAM 1939. Fouling organisms in Hawaii. B. P.
Bishop Mus. Occas. Papers, 14: 251-300.

HarRMER, S. F. 1915. The Polyzoa of the Siboga Expedition. Pt. 1, Entoprocta,

Ctenostomata, and Cyclostomata. Siboga Expeditie, Leyden, 28a: 1-180.
1926. The Polyzoa of the Siboga Expedition. Pt. 2, Cheilostomata,
Anasca. Siboga Expeditie, Leyden, 28b: 181-501.

HARMER, S. F. 1957. The Polyzoa of the Siboga Expedition. Pt. 4, Cheilostomata,
Ascophora... Siboga Expeditie, Leyden, 28d: 641-1147.

Hastincs, A. B. 1930. Cheilostomatous Polyzoa from the vicinity of the Panama
Canal, collected by Dr. C. Crossland on the cruise of the S. Y. St. George.
Proc. Zool. Soc. London for 1929, Pt. 4, no. 53: 697-740.

Hutcuins, L. W. 1952. Bryozoa in Marine fouling and its prevention. Woods
Hole Oceanographic Institution contrib. no. 580. United States Naval Insti-
tute: 140-143, 163, 167, 190-192, 204-207.

Marcus, E. 1937. Bryozoaires marinhos Brasileiros I. Bol. Fac. Philos. Sci.
Letras. Univ. Sao Paulo, Zoologia 1.: 1-224.

Mawatarl, S. 1952. On Watersipora cucullata (Busk) I. Misc. Repts. Res. Inst.
Nat. Resources, Tokyo, no. 25: 14-17.

OsBuRN, R. C. 1950. Bryozoa of the Pacific coast of America, Pt. 1, Cheilostomata,
Anasca, Allan Hancock Pac. Exped., Univ. Southern California, 14: 1-270.
1952. Bryozoa of the Pacific coast of America, Pt. 2, Cheilostomata,
Ascophora. Allan Hancock Pac. Exped., Univ. Southern California, 14: 271-
612.
1953. Bryozoa of the Pacific coast of America, Pt. 3, Cyclostomata,
Ctenostomata, Entoprocta and addenda. Allan Hancock Pac. Exped. Univ.
Southern California, 14: 613-841.

PRENANT, M. AND G. BoBIN 1956. Bryozoaires (premiére partie), Entoproctes,
Phylactolemes, Ctenostomes. Fauwne de France 60: 1-398.

ROBERTSON, A. 1921. Report on a collection of Bryozoa from the Bay of Bengal
and other eastern seas. Records. Indian Mus., Pt. 1, no. 8. 22: 33-65.

SKERMAN, T. M. 1960. Recent establishment of the Polyzoan Watersipora cucul-
lata (Busk) in Auckland Harbor, New Zealand. New Zealand Jour. Sci.,
3: 615-619.

SOULE, J. D. 1959. Results of the Puritan-American Museum of Natural History
Expedition to western Mexico, 6. Anascan Cheilostomata (Bryozoa) of the
Gulf of California. American Mus. Novitates, No. 1969: 1-54.

1961. Results of the Puritan-American Museum of Natural History

Expedition to western Mexico, 13, Ascophoran Cheilostomata (Bryozoa)

of the Gulf of California. American Mus. Novitates, No. 2053: 1-66.

1963. Results of the Puritan-American Museum of Natural History
Expedition to western Mexico, 16. Cyclostomata, Ctenostomata (Ectoprocta)
and Entoprocta of the Gulf of California. American Mus. Novitates, No.
2144: 1-34.

218 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

SouLE, D. F. anp J. D. SOULE 1964. The Ectoprocta (Bryozoa) of Scammon’s
Lagoon, Baja California. American Mus. Novitates No. 2199: 1-56.

1967. Faunal affinities of some Hawaiian Bryozoa (Ectoprocta). Proc.

California Acad. Sci., 35: 265-272.

Accepted for publication September 6, 1968

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INTRODUCTION OF AN AMPHIPOD CRUSTACEAN
INTO THE SALTON SEA, CALIFORNIA

J. LAURENS BARNARD

Smithsonian Institution
Washington, D.C.
and

W. ScoTT GRAY

Pacific Marine Station
Dillon Beach, California

Between 1946 and 1955 the senior author searched for amphipods
three times in the Salton Sea suspecting that several species might have
been introduced through human agencies. This belief developed from
an interest in fouling organisms of marine harbors (Barnard, 1958).
Eurytopic, often cosmopolitan, species of amphipods in the genera
Corophium, Jassa, Stenothoe, Podocerus, and Elasmopus live in tubes,
among hydroids, and as nestlers on piles, docks, and buoys in harbors
throughout the world. It was believed possible that seaplanes originating
from marine harbors and landing in the Salton Sea might bring in amphi-
pods with fouling organisms. No amphipod was detected in the Salton
Sea as late as 1955. In 1962, Carl L. Hubbs, Boyd W. Walker, James
St. Amant, and R Boolootian brought to our attention the presence
of amphipods now living in the Salton Sea; Walker forwarded extensive
collections of these animals to us. The amphipod proved to be Carino-
gammarus mucronatus (Say), a species occurring along the American
Atlantic and Gulf of Mexico coasts. Since C. mucronatus (Say) is one
of the most common amphipods in lagoons and estuaries of the Texas
coast (Breuer, 1957, Simmons, 1957) it was probably introduced along
with marine grass, Diplanthera wighti, that was brought from Texas to
the Salton Sea in 1957 under the aegis of the California Department of
Fish and Game. This project, directed by Lars Carpelan (Walker, 1961),
was to determine which game fish might be used to establish a sport-
fishery in the Salton Sea. The amphipod, now very abundant in the
Salton Sea, appears to be the principal food of the sargo [ Anisotremus
davidsoni (Steindachner)] Hubbs, written communication).

As this paper was being submitted for publication Mr. Alan J. Mearns
discovered another species of amphipod living with C. mucronatus in
the Salton Sea. We have tentatively identified this species as Corophium
louisianum Shoemaker, another member of the Texas lagoon fauna.

The Salton Sea is located in the Cahuilla Basin of southeastern Cali-
fornia, north of the delta of the Colorado River. This saline lake was

219

220 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

formed during the period of 1904-1907 when flood waters from the
Colorado and Gila rivers became impounded in a below-sea level basin
which contained a salt flat of ancient origin. In 1956 the salinity was
approximately 33 ml/l but the ionic proportions of the salts were not
in the same ratio as in the ocean. Despite the ionic imbalance, a large
number of marine and brackish-water invertebrates, as well as several
species of fish, have been successfully introduced, by plan or accident,
into the Salton Sea. The full account of the Salton Sea may be found in
Walker (1961) and Arnal (1961).

A list of invertebrates accidentally introduced in 1957 into the
Salton Sea is given by Linsley and Carpelan in Walker (1961) but no
amphipod is mentioned and C. mucronatus may not have been well
established until after the survey of that time. Heretofore, the species
has been known from estuaries and lagoons along Atlantic America
from Massachusetts to Texas. As described below, populations of that
species from Massachusetts, Maryland, and Mississippi have been
examined and found to be slightly different morphologically from those
of the Salton Sea, the latter being smaller as adults than marine indi-
viduals, and females having a high percentage of pleonal tooth aber-
rations. Oceanic specimens from the Gulf Coast examined by us seem
to have more of these aberrations than do individuals from more
northern Atlantic estuaries, especially Chesapeake Bay. This variation
in pleonal tooth development may reflect variation in physical factors
of the environment, such as temperature or chemicals; alternately,
some genetic mechanism which considers the isolation of the Salton
Sea population might be invoked to explain this variation.

Gammarus Fabricius, 1775

Composed of the subgenera Gammarus; Rivulogammarus; Marino-
gammarus; Pectenogammarus; an unnamed subgenus represented by
Karaman’s erroneous “fluviogammarus”; and the following new sub-
genus.

Mucrogammarus, new subgenus

Diagnosis. — Gammarus with cephalic lobes obliquely truncate
but corners softly blunt and not sharply angular; calceoli absent in both
sexes; gnathopod 2 of male similar to gnathopod 1 but larger, palm of
propodus very oblique and lacking slight bulge or cushion at proximal
defining corner, hands of both pairs of gnathopods with several groups
of basally bent, blunt spines, palms armed with stout spine-setae, pres-
ence of dominant midpalmar spine typical of other gammaruses but
spine elephantine, short, very broad, blunt; posterodistal corner of

Salton Sea Amphipods 221

article 2 on pereopod 3 with sharp lobe, lobes obsolescent on pereopods
4-5; anterior margin of article 6 of pereopod 5 with numerous long
setae; inner ramus of uropod 3 only slightly shortened.

Type-species. — Gammarus mucronatus Say, 1818.

Our decision to propose a new subgenus for Gammarus mucronatus
and remove the species from the Baikalian genus Carinogammarus,
reflects our belief, from its morphology, distribution, and habitat, that
this species is a product of the early diversification of the Pale-Nearctic
Rivulogammarus stock at approximately the time that species of the
other subgenera were invading the sea. G. mucronatus has stronger
connection to its carinate European congeners than to species of fresh-
water America. It replicates to some extent the trends seen in Marino-
gammarus; however, G. mucronatus may have found an open niche in
North America which it could occupy with such success that further
radiation was stalled by the eurytopicity, in the physical sense, of the
species. The paucity of environmental isolating mechanisms and the
lack of significant competition may have been factors also. It thus pre-
served several characters untested by strong competition as it occupied
a niche or habitat marked by extreme physical variables. Gammarus
(Mucrogammarus) mucronatus would appear to be one of those species,
like the polychaete Capitella capitata Fabricius, which has wide toler-
ance to physical variables in the environment but which is constricted
in its habitat development mainly by competition from other organisms
(Reish and Barnard, 1960).

We suggest that the presence of a marine carinate gammarus in the
northwestern Atlantic Ocean, with the absence of such an organism in
both American freshwaters and European marine waters is a reflection
of several factors. These may include greater complexity of Eurasian
freshwater habitats, the greater age of gammaruses in European marine
and freshwaters, and a more successful competitive position of Euro-
pean marine members of Gammarus and Marinogammarus than was
the position of European marine mucrogammaruses.

Mucrogammarus mucronatus is not a relict in the sense of Holm-
quist (1959), but might be considered to be an allopatric refugee.

Gammarus (Mucrogammarus) mucronatus (Say), new combination
Figures 1-4

Gammarus mucronatus Say, 1818; Milne-Edwards, 1840, Smith,
1873; Herrick, 1887; Schellenberg, 1937a; Bousfield, 1954; Breuer,
1957; Simmons, 1957; Bousfield, 1958.

Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

222

Figure 1. Gammarus (Mucrogammarus) mucronatus Say, male, 9.0 mm, Salton
Sea: A, lateral view of body; B, article 5 of pereopod 4 (upside down); C, pereo-
pod 1; D, E, F, article 2 of pereopods 3, 4, 5; G, lower lip; H, inner plate of
maxilliped; I, coupling hooks of pleopod 1; J, pleopod 1; K, outer plate of maxil-
liped; L, maxilliped; M, articles 6-7 of pereopod 4.

Salton Sea Amphipods 223

Gammarus macrophthalmus Stimpson, 1853.

Gammaracanthus macrophthalmus. Bate, 1862.

Gammaracanthus mucronatus. Bate, 1862.

Carinogammarus mucronatus. Stebbing, 1899; Holmes, 1904; Paul-
mier, 1905; Stebbing, 1906; Kunkel, 1918; Johansen, 1930; Shoe-
maker, 1930; Bousfield, 1953.

Carinogammarus macrophthalmus. Stebbing, 1906.

Type-locality. — “in the bay of Egg Harbor (New Jersey) and near

the mouth of St. Johns river, Florida;”

Description of male from Salton Sea. — Head with short, obtusely

angled rostrum, lateral lobe with flat anterior margin oriented obliquely

to horizontal cephalic axis, anterodorsal corner of lobe blunt with scarce
indication of point, flat margin very slightly concave, excavation below
lateral lobe almost even and of medium size for ““gammaruses,” antero-
ventral corner of head obtusely extended; eye reniform, large; antennae
1 and 2 equal in length, slightly more than % body length, articles 1-3
of antenna 1 successively shorter, accessory flagellum 4-5 articulate,
primary flagellum nearly twice as long as peduncle; gland cone of an-
tenna 2 large, reaching halfway along article 3, articles 4-5 subequal
in length, flageilum slightly shorter than articles 4-5 combined, pedun-
cular article 4 of antenna 2 with about 6 dorsal sets of spines and few
setae; calceoli absent; epistome, from side view, rounded, not produced;
upper lip broadly rounded below from anterior view; mandibular in-
cisors strongly 5-toothed, right lacinia mobilis complexly digitate, left
lacinia mobilis a replica of incisor tooth row with 5 teeth, molar strongly
triturative, bearing one long plumose seta and palmate, striated molar
flake, article 1 of palp short, article 2 longest, article 3 slightly shorter
than 2, article 3 linearly ovate, with strong comb of short medial setae,
several long terminal setae and sparse medial row of medium-length
setae, article 2 moderately setose medially; lower lip with inner lobes
obsolescent, mandibular lobes blunt from direct anterior view; inner
plate of maxilla.1 fully setose medially, with 12 plumose setae and
numerous setules, outer plate with 11 castello-serrate spines, palp
article 2 similar on both right and left members, with 4 short marginal
spines and submarginal longer setae, small hump between 2 lateralmost
spines; inner lobe of maxilla 2 slightly narrower than outer lobe, fully
setose medially, with slightly submarginal row of 9 plumose setae, row
of serrate spines and setae beginning terminally and extending along
medial edge, surface and lateral edge with many setules; inner plate of
maxilliped subrectangular, reaching end of palp article 1, apex armed
with 3 heavy spines, 9 plumose setae, and 2 non-plumose setae; sub-
terminally, 5 spines on posterior surface in distomedial corner, along

224 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

medial edge 10 long plumose setae with many setules, distal half of
antertor surface with many setules; outer plate broad and squat,
medially with 9 short spines, apically with 5 long plumose setae, outer
plate reaching near middle of palp article 2; article 3 of maxillipedal
palp shorter than second but longer than first, slightly extended as weak,
rough-surfaced lobe anterodistally, dactyl stout but claw-like, apically
with finely striate nail-like structure, 1 seta on dactyl dorsoproximally,
and accessory setules inserted near base of nail, small rough area dor-
sally near base of nail similar to but smaller than surface of distal lobe
article 3; coxae 1-3 rectangular, spinose on anterior and posteroventral
margins, coxa 4 with shallow broad, posterodorsal excavation, spinose
on anterior and posterior margins, coxae 5-6 with small almost hook-
like anterior lobe; gnathopod 2 distinctly larger than gnathopod 1,
generally similar to each other, article 5 cup-shaped, posterior lobe
armed with 5-7 bundles of comb-raker setae, sixth articles elongate,
palm of propodus on gnathopod | more oblique and relatively longer
than in gnathopod 2, palms irregularly sinuous, with one deep excavation
near which irregular peg-tooth spine attached, setae and spines distal
to peg-spine sharp but proximally becoming more and more blunt,
distally rounded or peg-like, palmar defining corners with several scat-
tered, submarginal peg-like spines smaller than that at excavation
(various views and patterns shown in figures); dactylus with several
subapical setules; pereopod 1 larger than 2, both strongly setose pos-
teriorly except on article 6; article 2 of pereopod 3 with anterior and
posterior margins nearly parallel, posteroventral corner thus broadly
expanded relative to article 3, corner slightly extended ventrally; article
2 of pereopods 4-5 tapering distally, posteroventral lobe obsolete,
corner bearing several stout spines and setae; article 6 and dactyl of
pereopods 3-5 rotated, with dactyl pointing outward, most accentuated
in pereopod 3 so as to be almost rotated to posterior direction (and so
drawn in accompanying aspect view), pereopods 3-5 strongly setose
and spinose but only article 6 of pereopod 5 with anterior setae, other-
wise spines present only on anterior margins of that article; dactyls of
pereopods 1-5 with 2 accessory setules and nail-like distal constriction;
pereon dorsally smooth, pleonites 1-3 with carina ending in sharp
posterodorsal tooth on each segment, teeth irregular in size and presence,
generally associated with increasing size but less frequently fully devel-
oped in females than in males; urosomites 1-2 each with 4 dorsal sets
of spines, urosomite 3 with 2 sets, urosomites 1-2 slightly raised dor-
sally; posterodorsal epimeral margins of pleonites 1-3 minutely scal-
loped and weakly setose, then minutely spinose again near ventral side,
epimera 2-3 with medium-sized posteroventral tooth, epimeron 1

Salton Sea Amphipods 225

of ri

EMI re

Figure 2. Gammarus (Mucrogammarus) mucronatus Say, male, 9.0 mm, Salton
Sea: A, upper lip; B, base of antenna 2; C, base of antenna 1; D, E, medial and
lateral gnathopod 1; F, G, lateral and medial gnathopod 2; H, I, gnathopods 1,
2; J, maxilla 1; K, dorsal pleonites 4-6, right to left; L, major palmar spine of
gnathopod 2; M, maxilla 2.

226 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

rounded posteroventrally but with small tooth defining posteroventral
corner, pleonal epimeron 1 with ventroposterior margin planiform,
sparsely setose, posteroventral corner with distinct but minute tooth
terminating oblique lateral ridge, anteroventral rounded margin sparsely
setose; epimera 2 and 3 with sinuous posterior margins and large
posteroventral tooth on each, only that of epimeron 2 terminating from
lateral ridge, ventral spines occurring as oblique row on face of epi-
meron 2 but mostly marginal on epimeron 3, both epimera with mid-
anterior brush of setae on medial face; peduncles and rami of uropods
1-2 evenly spinose throughout dorsal margins, each ramus with | long
and 2 short terminal spines; uropod | slightly over-extending uropod
2, rami subequal on uropod 1, outer conspicuously shorter than inner
on uropod 2; inner ramus of uropod 3 extending 80 percent along outer
but not reaching end of article 1, thus article 2 very short; apices of
telson with at least 2 stout spines, one long seta and other long or short
setae, lateral margins of telsonic lobes with 2-3 sets of 2-3 heavy spines,
medial margins with 2 sets of 1-2 heavy and several slender spines.

Material Examined. Salton Sea, California, vicinity of New River, 544
specimens, coll. B. W. Walker and W. J. Baldwin, March 7, 1962;
Mississippi Sound at Gulfport Beach, Belle Fontaine, Henderson Point,
Deer Island, mouth of Pascagoula River, and Bay St. Louis at Cedar
Point, Feb. 6-19, 1964, numerous specimens, coll. C. E. Dawson;
Chesapeake Bay, 1500+ specimens, coll. Fish Hawk, 1915-1921;
Chesapeake Bay near Chesapeake Beach, Maryland, 100 + specimens,
coll. A. Pizzini, July 4, 1938; Falmouth, Massachusetts, 50 specimens
and Martha’s Vineyard, Massachusetts, 7 specimens, coll. E. L. Mills,
May 9, 1964 and June 29, 1962.

Literature Records. Laguna Madre, Texas, Simmons, 1957; Baffin
and Alazan Bays, Texas, Breuer, 1957; Alabama, Herrick, 1887;
mouth St. Johns Pleasant, New Jersey, Philadelphia Academy of Science
Museum specimen registry, 1890; Great Egg Harbor, New Jersey,
Holmes, 1904; New York City, New York, Paulmier, 1905; Vineyard
Sound, Massachusetts, Smith, 1873; Noank and New Haven, Connecti-
cut, Kunkel, 1918. Grand Manan, Bay of Fundy, Stimpson, 1853;
Yarmouth, Shelburne, and Halifax counties, Nova Scotia, Bousfield,
1958; Cape Breton Island and mainland of Nova Scotia, Bousfield,
1954; Port Daniel, Quebec and Avonport, Nova Scotia, Johansen,
1930; Aspy River and Eastern Harbor, Cape Breton Island, and Plateau
River, Nova Scotia, Shoemaker, 1930; North Shore of Chaleur Bay
and Gaspé Bay, Quebec, Bousfield, 1953.

Distribution. Quebec to Texas and Salton Sea, California.

Salton Sea Amphipods DG]

Figure 3. Gammarus (Mucrogammarus) mucronatus Say, male, 9.0 mm, Salton
Sea: A, B, uropods !, 2; C, D, palps of maxilla 1; E, F, G, H, female, 8.0 mm:
brood plates of coxae 2, 3, 4, 5; I, J, medial and lateral gnathopod 1; K, L, medial
and lateral gnathopod 2; M, N, O, P, Q, R, gills of coxae 2, 3, 4, 5, 6, 7; male,
8.0 mm: S, T, U, V, W, X, gills of coxae 2, 3, 4, 5, 6, 7; heads: Y, male, 14.0 mm,
Mass; Z, male, 8.0 mm, Salton Sea; dorsal outlines of metasome: 1, male, 9.0 mm,
Md; 2, male, 9.0 mm, Salton Sea; 3, male, 5.0 mm, Salton Sea; 4, female, 7.0 mm,
Salton Sea; 5, male, 5.0 mm, Salton Sea; 6, female, 7.0 mm, Salton Sea; 7, male,
9.0 mm, Salton Sea; 8, female, 10.0 mm, Mass.; 9, female, 11.0 mm, Mass; 10,
male, 14.0 mm, Mass.; 11, female, 7.0 mm, Salton Sea.

228 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968
VARIABILITY OF THE AMPHIPOD

Specimens of Mucrogammarus mucronatus from Chesapeake Bay
(Maryland-Virginia), Woods Hole, Massachusetts and Mississippi
were examined for variation in dorsal pleonal teeth. A greater tendency
to developmental failure of teeth is seen in females than in males. This
tendency is most common in the third tooth, then shifts to the first tooth
and finally results in the loss of the second tooth. Hatched juveniles in
the brood pouch of their parent essentially lack dorsal pleonal teeth.
Apparently teeth develop within a few instars for we have found teeth
occurring in juveniles as small as 2.3 mm. Hatched juveniles taken
from brood pouches in material from Chesapeake Bay ranged from
1.0 mm to 2.5 mm and averaged 1.8 mm in length.

Although a slight reduction of the third pleonal tooth occurs in adult
males from Chesapeake Bay and Massachusetts and 11 percent of the
females do not develop the third tooth, those northern populations seem
to be more stable than southern and Salton Sea populations. Both males
and females from Mississippi show a 14 percent failure of the first tooth
but females show more than a 50 percent failure of the third tooth,
more than twice as frequently as in males. No loss of the second tooth
occurs in Mississippi specimens. In the Salton Sea only a small per-
centage of males has all of the teeth in normal condition and all females

TABLE |

Dorsal pleonal teeth of male and female Mucrogammarus mucroatus in Salton
Sea, California. Symbols: T= large tooth; t=small tooth; O= no tooth. Formulas
denote pleonites 1-3.

Male
Tooth No. of Length, mm.
Formula Individuals Range Median
T-T-T 14 4.5-11.0 8.0
T-T-t 42 3.5-12.0 7.0
T-T-O 28 3.5-10.0 5.5
t-T-t 10 5.0-9.0 6.0
O-T-O 5 4.0-6.0 5.5
O-O-O 5 3.0-5.0 4.0
Female
T-T-T 0 g 2
T-T-t 0 2 ss
T-T-O 129 4.0-8.5 6.0
t-T-t 0 é My
O-T-O 85 4.0-8.5 6.0

O-O-O 14 4.0-7.0 4.5

229

Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

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230 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

Figure 4. Gammarus (Mucrogammarus) mucronatus Say, male, 9.0 mm, Salton
Sea: A, maxillipedal palp articles 3-4; B, dactyl of pereopod 4; C, uropod 3;
D, E, F, pleonal epimera 1, 2, 3; G, telson; H, I, J, coxae 5, 6, 7; K, right mandi-
ble; L, apex of left mandible; M, N, gnathopods 1, 2 of female, 8.0 mm; O,
uropod 3.

lack the third tooth entirely. More than 40 percent of Salton Sea females
also lack the first tooth. Approximately equal but very small proportions
of both males and females fail to develop all three dorsal teeth, or the
development is delayed until full adulthood.

Recapitulating the results (tables 1-2) by counting the number of
possible and actual teeth present in each of the three populations results
in a trend from 8 per cent of the teeth being present in Chesapeake
individuals, through 82 per cent in Mississippi individuals to 60 per
cent in Salton Sea individuals.

Although the imbalance of dissolved salts in the Salton Sea may be a
partial explanation for the phenotypic abnormalities of dorsal teeth in

Salton Sea Amphipods 231

Mucrogammarus mucronatus, one must not overlook the increase of
seasonal and perhaps daily thermal extremes in the southern popula-
tions as well as the general increase in environmental temperature. A
comparison related to this condition may be made with marine amphi-
pods in general: far more carinate, cuspidate and spiny Amphipoda
occur in cold polar waters than occur in warm waters of low latitudes.
Entire families of considerable diversity are involved in this cold-water
ornamental expression (e.g., Acanthonotozomatidae). With the ex-
ception of one family, Lepechinellidae, this principle does not apply
to the deep sea and is one more example of the known discontinuity
between amphipod faunas of cold shallow and deep seas (Barnard,
1962).

ACKNOWLEDGMENTS

We are indebted to all those persons mentioned at various places in this paper
who have assisted with information and the loan of materials. For the loan of
materials, in addition to those collectors already noted, we wish to thank E. L.
Mills of Queens University, Canada and T. E. Bowman of the Smithsonian Insti-
tution. Dr. Bowman kindly read and aided in the preparation of the text. We owe
our special thanks to Miss Marilyn C. Imbach who made the initial laboratory
studies on this problem. Miss Naomi B. Manowitz inked our drawings.

LITERATURE CITED

ARNAL, R. E. 1961. Limnology, sedimentation, and microorganisms of the Salton
Sea, California. Geol. Soc. Amer., Bull. 72: 427-478.

BARNARD, J. L. 1958. Amphipod crustaceans as fouling organisms in Los Angeles
Long Beach Harbors, with reference to the influence of seawater turbidity.
Calif. Fish and Game, 44: 161-170.

. 1962. South Atlantic abyssal amphipods collected by R. V. Vema: Jn

Abyssal Crustacea. Vema Research Series no. 1, pp. 1-78.

BaTES, C. S. 1862. Catalogue of the specimens of amphipodous Crustacea in the
collection of the British Museum, London, 399 p.

BOUSFIELD, E. L. 1953. Studies on the shore Fauna of the St. Lawrence Estuary
and Gaspe Coast. Ann. Rept. Natl. Mus. (Canada) Bull. no. 136: 95-101.
1954. Studies on the shore Crustacea collected in Eastern Nova Scotia
and Newfoundland, 1954. Ann. Rept. Natl. Mus. (Canada), Bull. no. 142:

127-152.
. 1958. Littoral marine arthropods and mollusks collected in western
Nova Scotia, 1956. Proc. Nova Scotian Inst. Sci., vol. 24: 303-325.

BREUER, J. P. 1957. An ecological survey of Baffin and Alagan Bays, Texas Publ.
Inst. Mar. Sci. 4: 134-155.

HERRICK, C. L. 1887. Contributions to the fauna of the Gulf of Mexico. Mem.
Denison Sci. Assn., 1: 1-56.

DB) Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

HoiMEs, S. J. 1904. The Amphipoda of southern New England. Bull. U.S. Bur.
Fish., 24: 459-529.

HotmaulisT, C. 1959. Problems on marine glacial relicts. An account of investi-
gations on the genus Mysis. Akad. Avhandling, KL. 10: 1-270.

JOHANSEN, F. 1930. Marine Crustacea, Malacostraca and Pantopodia (Pycno-
gonida), collected in the Gulf of St. Lawrence, Newfoundland and the Bay
of Fundy in 1919, 1922, 1923, 1925 and 1926. Canad. Field-Nat., 44: 91-94.

Kunkel, B. W. 1918. The Arthrostraca of Connecticut. Conn. Geol. Nat. Hist.
Surv., 6: 15-181.

MILNE-EDwarps, M. 1840. Histoire naturelle des crustacés, comprenant l’anato-
mie, la physiologie et la classification de ces animaux, 3: 1-638.

PAULMIER, F. C. 1905. Higher Crustacea of New York City. N. Y. State Mus.
Bull. 91: 117-189.

REIsH, D. J. AND J. L. BARNARD 1960. Field toxicity tests in marine waters utilizing
the polychaetous annelid Capitella capitata (Fabricius). Pacific Nat., 1(21):
1-8.

Say, T. 1818. An account of the Crustacea of the United States. Jour. Acad. Nat.
Sci., 1: 376-401.

SHOEMAKER, C. R. 1930. The Amphipoda of the Cheticamp Expedition of 1917.
Contr. Canad. Biol. Fish., 5: 221-359.

Stmnmons, E. G. 1957. An ecological Survey of the Upper Laguna Madre of Texas.
Publ. Inst. Mar. Sci. 4: 156-200.

SMITH, S. I. (in A. E. VERRILL) 1893. Report upon the invertebrate animals of
Vineyard Sound and the adjacent waters with an account of the physical
characters of the region. Rep. U.S. Fish. Comm., 1871-1872, pp. 295-778.

STEBBING, T. R., 1899. Amphipoda from the Copenhagen Museum and other
sources. Trans. Linn. Soc. London, ser. 2, Zool., 7: 395-432.
. 1906. Das Tierreich. Amphipoda I. Gammaridea, 806 p.

STImpson, W. 1853. Synopsis of the marine Invertebrata of Grand Manan: of
the region about the mouth of the Bay of Fundy, New Brunswick. Smith-
sonian Contrib. to Knowledge, 6: I-IV, 5-66.

WALKER, B. W. (ed.) 1961. The ecology of the Salton Sea, California, in relation
to the sportfishery. Calif. Fish and Game, Fish Bull. no. 113, 204 p.

Accepted for publication July 29, 1968

THE GENUS HEXIDIONIS (ACARINA, TROMBICULIDAE)
WITH THE DESCRIPTION OF A NEW SPECIES
FROM WESTERN MEXICO

JAMES L. LUCAS AND RICHARD B. Loomis
Department of Biology, California State College at Long Beach

INTRODUCTION

Studies of chiggers taken in western Mexico have revealed a new
species of chigger of the genus Hexidionis Vercammen-Grandjean
and Loomis. Six other species belong to this genus: the type-species
Hexidionis jessiemae (Gould), and five species previously assigned
to the genus Trombicula Berlese. To facilitate the recognition of these
seven species of Hexidionis we have provided a key to the larval stage.

In addition, we propose that Pentidionis Vercammen-Grandjean
and Loomis, 1967, originally named as a subgenus of Hexidionis, be
elevated to generic status. Pentidionis occurs in northern Africa and
adjacent Asia; whereas, Hexidionis is known only from North America.

Grateful acknowledgment for helping to assemble these and other
chiggers is extended to many individuals including: William J. Wrenn,
Kenneth D. Peyton, W. Leon Hunter, Lynell K. Tanigoshi, James P.
Webb, Jerry L. Fowler, Dean E. Harvey, and Dan B. Odenweller. We
also wish to thank Elaine Katzer for her fine drawings.

The studies upon which this paper is based were supported by a
research grant AI 03407 from the National Institute of Allergy and
Infectious Diseases to California State College at Long Beach.

Pentidionis Vercammen-Grandjean and Loomis, new status

Hexidionis (Pentidionis) Vercammen-Grandjean and Loomis, 1967:
139-140.

Type-species.-Thrombicula agamae André, 1929.

Included species. — Eutrombicula maura Taufflieb, 1960, and E.
meridialis Taufflieb, 1960.

Remarks. — Initially the genus Hexidionis was divided into two
subgenera: Hexidionis from North America and Pentidionis from
northern Africa and Asia Minor. Larvae of the species in the two
subgenera share these characteristics: seven branched setae on the
palpal tarsus; the presence of several internal bars in the distal leg
segments; general shape of the scutum; the distal position of all tibialae

233

234 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

I and II, and tenent hairs on the claws. However, we believe that Penti-
dionis should be elevated to generic status, because of numerous
differences, including those listed below:

1. The subterminala of the palpal tarsus is present in Hexidionis
and absent in Pentidionis.

2. The parasubterminala I is absent in Hexidionis and present in
Pentidionis. In Hexidionis a branched seta is near the subter-
minala, but it is not a parasubterminala.

3. The microtarsala II is proximal to tarsala II in Hexidionis but it
is distal in Pentidionis.

4. Two of three genualae I are distal in Hexidionis, but are proximal
in Pentidionis.

5. Genualae IJ and III are on the distal part of the segment in Hexi-
dionis, but they are proximal in Pentidionis.

The similarity of Hexidionis and Pentidionis seems to be the result
of convergence of larval characteristics apparently correlated with
similar habitats and hosts. Hexidionis lacerticola (Loomis) of the
southwestern deserts parasitizes American iguanids; whereas, the
similar Pentidionis agamae (André) occurs in arid northern Africa
and adjacent Asia on agamid lizards. The saurian families of Iguanidae
and Agamidae are themselves classic examples of convergent evolution
which appears to be repeated in these two genera of chiggers. Penti-
dionis, Hexidionis, Toritrombicula Sasa, and Iguanacarus Vercammen-
Grandjean seem to belong to the same group. Species of Toritrombi-
cula occur on circumtropical and subtropical birds, and Iguanacarus
consists of three intranasal species of the Galapagos Marine Iguana.
All of these genera have been found on hosts from arid habitats, and
the present distribution of the latter two and possibly of all four genera
may be the result of dispersal by marine birds.

Hexidionis Vercammen-Grandjean and Loomis

Hexidionis Vercammen-Grandjean and Loomis, 1967:139-140.

Type-species. — Trombicula jessiemae Gould, 1956.

Included species. — Trombicula allredi Brennan and Beck, 1956;
T. breviseta Loomis and Crossley, 1963; T. doremi Brennan and Beck,
1956; T. lacerticola Loomis, 1964; T. polytechnica Hoffmann, 1963
and Hexidionis navojoae new species.

Diagnosis. — Larva. Palpal tarsus with 7 B.S.; tarsus I without
parasubterminala. See other characteristics under the genus Pentidionis
and in the key to the species of Hexidionis.

New Species of Chiggers 235

Hexidionis navojoae, new species
(Figure 1)

Types. — Holotype and 14 paratopotypes from 6 kilometers north
of Navojoa, Sonora, México; host Neotoma albigula, original numbers
RBL641203-18 (holotype and 7 paratopotypes), RBL641203-14 (2)
RBL641203-15 (3), and RBL641203-16 (2); collected 3 December
1964 by R. B. Loomis and K. D. Peyton. The holotype and two para-
topotypes will be deposited in the Rocky Mountain Laboratory,
Hamilton, Montana. Paratopotypes now at California State College
at Long Beach will be distributed to appropriate institutions and
individuals.

Diagnosis. — Larva: Resembling Hexidionis allredi and H. jessie-
mae in having 3 genualae I with dorsal genualae separated by greater
distance than distance between distal genualae but differing in having
two proximal tibialae longer than 12 and in length of PL, 41-46
(see key to species).

Description. — Based on holotype, with differences noted among
the paratopotypes, with all measurements in microns:

Body: Nearly round; color in life yellow; eyes 2/2, ocular plate
indistinct.

Gnathosoma: Cheliceral base with posterior puncta; blade slender
with tricuspid cap. Palpal setae B/B/BBB, tarsal setae 7 B.S., pal-
potibial claw trifurcate. Galeala with numerous branches.

Scutum: About one and one-half times as wide as long with puncta
scattered on posterior two-thirds. Lateral margins sinuous; anterior
margin perpendicular to lateral margin; posterior margin concave.
Sensilla filiform with barbs on proximal half and distal half bearing 9
or 10 branches.

Scutal measurements of holotype, and (in parentheses) means,
standard error (+1), and extremes of 15 types. AW, 56 (58, +0.6,
55-63); PW, 61 (66, +0.5, 61-71); SB, 22 (24, 0.4, 21-26); ASB,
24 (24, +0.4, 21-26); PSB, 19 (21, +0.4, 17-23); AP, 16 (17, +0.4,
15-18); AM, 31 (33, +0.4, 30-36); AL, 28 (30, +0.4, 27-34); PL,
41 (42, +0.4, 41-46); S, 59 (60, + 1.19, 54-69).

Body setae (Figure 1): All body setae with many branches. Dorsal
setal formula for holotype, 2 (humerals)-2-6-6-6-6-4-4-4 plus approxi-
mately 14 postanal setae; measurements of humeral seta 33, post-
humeral seta 41, posterior dorsal seta 29. Ventral setae 2-2 plus
approximately 31, measurements of sternal setae 42 and 41, small
posterior seta 29. Total body setae approximately 90.

Legs: All coxae lightly punctate. Leg I with 3 genualae (11-13),
microgenuala; 2 tibialae subequal (11-13), microtibialae; tarsala (13),

236 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

Figure 1. Selected features of the larvae of Hexidionis navojoae, n. sp. and H.
allredi. Hexidionis navojoae, n. sp. (except Figure 1 E). A. Scutum and eyes. B.
Dorsal aspect of body, showing arrangement of setae. C. Gnathosoma, dorsal
aspect. D. Palpotibia and tarsus, ventral aspect. E. Tibia I of Hexidionis all-
redi (paratype). F. Body setae: posterior dorsal (PD), first sternal (1st), humeral
(H). G. Leg. I, showing specialized setae with measurements in microns. H. Leg
II, as above. I. Leg III, as above.

New Species of Chiggers 237

microtarsala, subterminala (15), pretarsala (9). Leg II with genuala
(9); 2 tibialae (11-7); tarsala (17), microtarsala, pretarsala (10). Leg
III with genuala (8); tibiala (8). All legs with internal bars in genu
(2-3), tibia (3-4), tarsus (4-5). Each leg bearing two claws with 3 to
5 tenent hairs (onychotriches) and a clawlike empodium with one
onychotrich. Leg index of holotype and (in parentheses) mean, standard
error (+1) and extremes of 15 types: I, 320 (314, + 2.4, 282-338); II,
289, (278, 4.1, 242-306); III, 315 (317, +3.2, 291-338); total, 921
(909, + 10.9, 815-982).

Remarks. — This species closely resembles H. allredi but the latter
has shorter tibialae (8-10), shorter PL’s (less than 38), and the lateral
palpotibial seta is nude or with few branches whereas it is heavily
branched in H. navojoae. The anterior dorsal body setae are arranged
as 2 (humerals), 2 (mid-dorsals), and 4 (first row) in H. allredi; whereas
in H. navojoae the arrangement is 2 (humerals), 2 (mid-dorsals), and
6 (first row).

Ecological notes. — The type locality near Navojoa is in the arid
thorn forest. Larvae of this species also were taken from rodents
trapped in mixed thorn forest and short tree deciduous forest near El
Novillo and in the Alamos area and from the Sonoran Desert near
Hermosillo.

Hexidionis allredi and H. navojoae are sympatric, and both have
been found together at almost all known localities of the latter species.
They have been taken together on the same individual! rodent 17 times
in March, April and December. However, these two sympatric species
show different seasons of larval activity since larvae of H. navojoae
were taken from December to April, whereas H. allredi were found on
hosts from March to December.

Specimens examined. — A total of 288 larvae in the Chigger Re-
search Collection at California State College, Long Beach, including
both H. navojoae and H. allredi, listed below (in parentheses) with the
locality, host, and date of capture.

Hexidionis navojoae (108). MEXICO, SONORA: 6 km N Navojoa,
3 Dec. 1964, Neotoma albigula (24, including types), Perognathus
pernix (4); 13 km SSE Alamos, Peromyscus eremicus, 9-10 April 1963
(12); 10-11 March 1963 (16), 27-28-29 March 1961 (38); 8 km W La
Estrella (near El Novillo Dam), 7 April 1966, Perognathus baileyi (3);
10 km S Hermosillo, 2 Dec. 1964, Perognathus penicillatus (3),
Peromyscus eremicus (5); 3 km § El Novillo Dam, 6 April 1966,
Peromyscus eremicus (3).

Hexidionis allredi (180). UTAH, Washington Co., Rockville, 13
July 1953, Neotoma lepida (1 paratype). MEXICO, SONORA: 6 km

238 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

N Navojoa, 3 Dec. 1964, Neotoma albigula (16); 13 km SSE Alamos,
5 Aug. 1964, Peromyscus eremicus (8), Perognathus artus (9), Lepus
alleni (4), Neotoma albigula (8); 9-10-11 April 1963, Peromyscus
eremicus (9), Perognathus artus (6); 17 April 1962, Peromyscus
eremicus (8), Perognathus artus (6), Onychomys torridus (9), Neotoma
albigula (21), Perognathus goldmani (1), Cnemidophorus costatus
(5), Urosaurus ornatus (2), Sceloporus nelsoni (5); 6 Juiy 1960,
Peromyscus eremicus (6), Perognathus artus (10), Neotoma albigula
(5); 10 km S Hermosillo, 2 Dec. 1964, Neotoma albigula (20), Pero-
myscus eremicus (16); 3 km S El Novillo Dam, 13 July 1965, Perogna- ~
thus goldmani (5).

KEY TO THE SPECIES OF HEXIDIONIS
The following key to the larvae includes the known distribution of
each species.

The genus Hexidionis is characterized as a member of the tribe
Trombiculini with flagelliform sensilla branched; scutum subpenta-
gonal with large puncta; palpal tarsus with seven branched setae and
subterminala; galeala branched; genualae I two or three; genualae II
and III present; several distinct internal bars (4-5) in long tarsal
segments; tarsal claws and empodia with tenent hairs (onychotriches);
two mastitarsalae III nude or with basal barbs.

1. Two genualae I; tarsala II with knob, (Calif., Ariz., Nevada, Baja

Calif., Sonora to Hidalgo, México) on lizards ...... H. lacerticola
I threesgenualae Is tarsala i without knob 4... 445s eee D)
2. Distance between dorsal genualae I[<between distal dorsal and
lateral genualae. I... o.. 352 gk ees Tae: Tee 3
2. Distance between dorsal genualae I>between distal dorsal and
laterall:genualac 2: eat. hee ae ee ee 5
3. Dorsal palpotibial seta nude; total leg measurements less than
L200 oh en ek We Sy gS I 10 Ok rr 4
3. Dorsal palpotibial seta branched; total leg measurements greater
thant ZO0rc2(Mexico) eee eee ee H. polytechnica

4. Dorsal body setae long (21-24, ) slightly expanded and flattened;
PL greater than 25 » (Utah, Mojave and Sonoran Deserts of U.S.
and pnorthwesterne Mexico) meee ae er nee H. doremi

4. Dorsal body setae short (14-18 «) greatly expanded and flattened;
PL less than 20, (Texas, Coahuila and northeastern Sonora,
IMEC RICO): 2 shy is ee ar See H. breviseta

5. Tarsus I longer than 100, ; AM longer than 45, ; AL longer than
40; PL longer than 50 (Mojave and Sonoran Deserts........

BSS SS os MM ct Se dey Seat ca RAD RE RT EE ty se Nea a ea H. jessiemae

New Species of Chiggers 239

5. Tarsus I shorter than 100, ; AM shorter than 35, ; AL shorter than
AOreemalesshorterthan SOs ee he ye bce sw ke oe 6
6. Tibialae I shorter than 10, , dorsal setal formula beginning 2
(humerals)-2-4, PL shorter than 40,, (Utah, Calif., to Sonora,
WESC) MPEP Pe fn en a Rete toe is 6 ate kis H. allredi
6. Tibialae I longer than 11, , dorsal setal formula beginning 2 (humer-
als)-2-6, PL longer than 401 , (central and southern Sonora, México)
PIs. ho eS! Ps sig pray hce ee eyeklessiewanc H. navojoae un. sp.

LITERATURE CITED

BRENNAN, J. M. AND D E. BEck. 1956. The chiggers of Utah (Acarina, Trombi-
culidae). Great Basin Nat., 15: 1-29.

GouLD, D. J. 1956. The larval trombiculid mites of California (Acarina, Trombi-
culidae) Univ. Calif. Publ. Ent., 41: 1-115.

HOFFMANN, A. 1963. Contribuciones al conocimiento de los trombiculidos mexi-
canos (Acarina: Trombiculidae) An. Esc. Nac. Cienc. Biol., Mex., 12: 101-
109.

1965. Contribuciones al conocimiento de los trombiculidos mexicanos

(Acarina: Trombiculidae). Cienc. Biol., Mex., 9: 1-28.

Loomis, R. B. 1964. A new species of chigger (Acarina: Trombiculidae) from
lizards of western North America. Great Basin Nat., 24: 13-17.

Loomis, R. B. AND D. A. CrossLeY Jr. 1963. New species and new records of
chiggers (Acarina: Trombiculidae) from Texas. Acarologia, 5: 371-383.

TAUFFLIEB, R. 1960. Contribution a l’etude Trombiculidae Marocains. Descrip-
tion de nouvelles especes et etude d’une population de Neotrombicula. Ar-
chives de I’ Institut Pasteur d. Maroc, 6: 27-48.

VERCAMMEN-GRANDJEAN, P. H. AND R. B. Loomis. 1967. Note on Hexidionis
n. g. and Pentidionis n. sg. Acarologia, 9: 139-140.

Accepted for publication September 6, 1968.

THE STRUCTURE OF THE CHELA OF HETEROMETRUS SP.
AND ITS MODE OF OPERATION

M. S. DUBALE AND A. B. VYAS

Department of Zoology
University School of Sciences
Gujarat University
Ahmedabad, India

The use of scorpion pedipalps in the ingestion of food is well known
both to scientist and layman. Accounts of this appendage as a compo-
nent of the feeding apparatus have been given by a number of observers
including Brunson (1951) and Stahnke (1966). Observations made by
the latter author and his students are of particular interest. The mor-
phological descriptions of scorpion pedipalps, distributed over a num-
ber of families and genera, are also available as a result of the investi-
gations of various workers, including Lankester et. al. (1885), Pocock
(1900), Snodrass (1935), Tembe & Awati (1943), Mathew (1965).
Some authors, including Pocock and Mathew, have also thrown light
on the mechanism relating to the operation of the movable finger (the
tarsus) of the chela. One of the salient features reported by them is that
this movable finger is served by retractor muscles but lack protractors
(extensors). A review of the literature indicates, however, that the
functional anatomy of the chela has not been studied in detail. The
following report is an attempt to supply such information. Efforts have
also been made to verify the suggestions made by different workers as
to the mechanism of the opening of the movable finger and to suggest
the probable forces responsible for this action.

MATERIALS AND METHODS

Live scorpions were collected from the outskirts of Ahmedabad, India
and were kept alive in the laboratory under suitable environmental
conditions for observations. The dissections were made in 0.6 per cent
normal saline solution under a stereoscopic binocular dissecting micro-
scope. The closing action of the movable finger has been observed care-
fully with the naked eye and also under the binocular microscope.
Various parts of the chela were stimulated by the electric current of a
12 volt dry cell. The muscles situated inside the tibia and the patella
were subjected to similar electrical stimulations.

OBSERVATIONS
Pedipalps: Scorpion pedipalps arise from the lateral sides of the cepha-
lothorax just posterior to the chelicera. Each pedipalp consists of the

240

Chela of Scorpions 241

following six segments: the most proximal one is the coxa and the suc-
ceeding segments are the trochanter, femur (humerus), patella (brach-
ium), tibia (hand and fixed finger) and tarsus (movable finger).

The coxa of the pedipalp articulates with the lateral membrane of
the preoral cavity. Towards the distal end, the pedipalp forms a pincer
like chela by the modification of a part of the penultimate segment, viz.
the tibia, and the tarsus. The extension of the former is frequently
referred to as the immovable finger. The tarsus forms a movable digit
and articulates with the outer margin of the tibia near the base of the
immovable digit. Thus both the tibia and the tarsus together present
the structure of the chela and the movable and immovable fingers form
a powerful pincer. Along the inner surfaces of the fingers are denticu-
late structures which make possible a tighter grip.

Con

s YS

Figure 1. Diagrams of the ventral view (Fig. 1A) and lateral view (Fig. 1B)
respectively of the chela showing the attachment of the fingers.

Abbreviations: Con-condyle; Cor-Corium; Dep. Tar. (pat.)-Depressor tarsus
(Patella portion; Dept. Tar. (tib.)-Depressor tarsus (Tibial portion); Jt-Hinge
joint; Tib-Tibial claw; Tar-Tarsal claw; WF-White fibrous tissue.

Arthrology of the tibio-tarsus joint (Fig. 1A, B): The tibia and the
tarsus are joined by what is known as the tibio-tarsal joint. To a certain
extent this joint is in the nature of a hinge joint, formed towards the
outer end of the base of the tarsus and the attached portion of the tibia.
The rest of it consists mainly of the corium of the tarsus which moves
within the cavity of the tibia, internal to and below the immovable
finger.

242 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

The hinge itself consists of a dicondylic articulating structure. These
condyles are formed by the ends of the abutting surfaces of the tibia.
They fit into the corresponding facets formed at the outer ends of the
articulating surfaces of the tarsus. The middle portion of the joint is
connected by means of the corium. As the retractor muscles contract,
the movable digit is brought closer to its immovable counterpart. During
this operation, the tubular corium which joins the two claws becomes
folded in such a way that the tarsal portion of the corium is encased
within the tibial one.

As the retractor muscles relax, the reverse process takes place and
the movable finger is seen gradually moving away from its counterpart.

Muscles associated with the movement of the chela (Fig. 2A, B):
Typical muscular operation involving the movement of a part or whole
of the body is carried out by two sets of muscles working in opposite
directions. It is fairly reasonable to expect the presence of retractor
muscles being accompanied by a corresponding set of protracting
muscles. Even the claws of crustaceans, which closely resemble those
of a scorpion, are served by protractors as well as retractors (Mathew,
1965). This study of Heterometrus scorpions has verified further that
scorpion chela have only the retractor set of muscles, generally termed
M. Depressor tarsus. These retractor muscles consist of two parts, one
of which arises from the tibia and the other from the patella.

M. Depressor tarsus (tibial portion): This is a broad and massive
muscle which more or less completely fills the cavity of the tibia. It is
composed of eight fasciculi which show unipinnate arrangement. Each
fasciculus arises partly fleshily and partly tendinously in a broad origin
from the inner wall and the hind margin of the tibia. All the fasciculi
converge towards the base of the movable claw and insert on it by a
common tendon towards the inner end of the base.

M. Depressor tarsus (patellar portion): The main mass of this muscle
is situated within the patella and moves distally as a tendinous ribbon
passing through the tibia. Its muscle fibers show a parallel type of
arrangement. The muscle arises fleshily in a broad origin from the
proximal end of the patella where it is represented by a broad and fleshy
belly. As it travels into the tibia, the form changes to a long and narrow
tendon which passes upwards towards the tarsus through the mass of
the M. Depressor tarsus (i.e. tibial portion) and gains insertion on the
tarsus, interal to that of the latter muscle.

DISCUSSION

The operating mechanism of the chela of the scorpion is served only by
the retractor muscles. Various explanations have been given regarding

Chela of Scorpions 243

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LY Go SO o, TUR
LEE

Dep Tar (7b) Dep Tar (Tib)
Dep Tar (Pat) Dep Tar (Pat)

IB}

A

Figure 2. Diagrams showing the muscles operating the tarsal claw.

the nature of the protractory mechanism. Mathew (1965), studied the

following possibilities:

1. Hydraulic pressure.

2. Elasticity of the cuticle at the hinge.

3. Spring action of thickened cuticular patches at the inner angles of
the hinge joint.

The first possibility was earlier suggested by Parry (1960) in relation
to the operation of the spider legs. Mathew (1965) pointed out that in
scorpions the protractory function of the movable finger does not cease
even after the removal of the relevent chitinous exoskeletal covering.
The second possibility is also ruled out on the same grounds. Our
observations confirm the findings of previous authors. The third possi-
bility was also proven incorrect when the chela continued its protractory
action after the thickened cuticular patches at the inner angles of the
joint were removed.

Histological structures show that the corium is a strong structure
possessing well developed fibrous material. It is suggested that an up-
ward tension exists due to the infolding of the tubular corium present
between the fixed and movable fingers. Moreover, the arthrological
characteristics are such that an upward tension is maintained in the
normal position. As the retractory muscles relax, the tension on the
corium is gradually released and it assumes the original shape resulting
in the opening of the chela.

244 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

SUMMARY

1. A study of the pedipalp of Heterometrus sp. scorpion is undertaken
to investigate the mechanism of the movement of the tarsus.

2. As in other scorpions, the tarsus of the chela of Heterometrus is

served by retractory muscles only.

3. It is indicated that the easing of the tension created on the corium

during the retractory movements, results in the opening of the tarsus.

LITERATURE CITED

TEMBE, V. B. AND AwatTl, P. R. 1943. Buthus tamulua (Far.). Univ. Bombay.
12(5): 1-13.

Brunson, R. B. 1951. An unusual meal. Turtox News. 29: 151.

LANKESTER, BENHAM, BECK. 1885. On the muscular and endoskeletal systems of
Limulus and Scorpio with some notes on the anatomy and generic characters
of scorpion. Trans. Zool. Soc. Lond. 11: 311.

Parry, D. A. 1960. Spider hydraulics. Endeavour. 19: 156.

Pocock, R. L. 1900. Fauna of British India-Arachnida. The Indian Press, Alla-
habad.

MaTHEw, A. P. 1965. On the movable claw of the pedipalp in the scorpion
Heterometrus scaber. Jour. Animal Morpho. Physiol. 12: 271.

Snopcrass, R. E. 1935. Principles of insect morphology. McGraw-Hill Company,
New York.

STAHNKE, H. L. 1966. Some aspects of scorpion behavior. Bull. So. Calif. Acad.
Sci. 65: 65.

Accepted for publication June 10, 1968

MIMOSELLA COOKAE, NEW SPECIES
(BRYOZOA, CTENOSTOMATA), WITH
A REVIEW OF THE FAMILY MIMOSELLIDAE.

WILLIAM C. BANTA

Department of Biological Sciences
University of Southern California
Los Angeles, California, 90007.

INTRODUCTION

The genus Mimosella, widespread throughout Europe, eastern Africa,
the Atlantic, West Pacific and Indian Oceans (Harmer, 1915); Prenant
and Bobin, 1956), has not been previously recorded from the East
Pacific, probably because the animals are small and easily overlooked.
The species described here, Mimosella cookae, was collected at Guada-
lupe Island, on the western side of Baja California. Specimens are well
preserved and in reproduction, so it is possible to observe some impor-
tant aspects of the morphology of this unusual genus.

Family Mimosellidae, Hincks, 1851
Genus Mimosella, Hincks, 1851
Mimosella cookae, new species

Type locality. Guadalupe Island, Baja California, 29°, 11’ N; 118°,
17’ W; between Outer Island and South Bluff. Several tangled colonies
adhering to floating algae.

Holotype. Several colonies fixed in 10% formalin. Deposited at the
Allan Hancock Foundation, the University of Southern California, Los
Angeles, California. AHF type 651; bryozoan type 153.

Paratype. Several colonies at the British Museum (Natural History),
London.

Name. Dedicated to Miss Patricia L. Cook of the British Museum
(Natural History).

Diagnosis. Colony composed of one or a few main stolons with
adnate lateral stolons and predominantly uniserial clusters of keno-
zoids, each bearing a single autozoid. Muscles present in stolons and
Kenozoids. Peduncles of autozoids short, each bearing an annular
abscission zone. Autozoids posses a thin, corregated “articulation”
region on the abneural side of the zoecium just distal to the peduncle.

245

246 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

—temb

New Species of Mimosella 247

Basal muscles bilateral, separate, inserting distal to the corregated
zone. Embryos brooded in the tentacle sheath.

Description. Each colony consists of a single main stolon with
periodic short lateral branches which give rise to kenozoids bearing
elongated autozoids (Fig. 1).

The main stolon consists of a series of elongate tubular autozoids
separated by septa occurring at intervals of about 1 mm (0.7—1.3
mm); distal internodes are shorter than proximal ones. Septa are cir-
cular transverse plates perforated by a central pore, as is usual in
stolonate Bryozoa (Fig. 1, sep). Methacrylate sections demonstrate
that the communication pores are plugged by 2-4 special cells sur-
rounded by a tiny pore cincture. A pair of lateral stolons emanate from
the main stolon at a swelling just proximal to each septum; they likewise
are separated by septa (Fig. 1). Lateral stolons may produce other
lateral stolons or may branch into a series of small kenozoids (35-40
in either dimention). Each kenozoid bears a short process which ex-
pands into an autozoid.

Within the cavity of the main stolon, just proximal to each septum,
there are massive muscles which extend from the basal to the frontal
surface (Fig. 1, mus). Similar muscles can be seen in toluidine blue-
stained methacrylate sections of lateral kenozoids, but they are not
visible in whole mounts. Neither frontal nor basal surfaces of stolons
or kenozoids are modified at the insertions of the muscle fibers. Similar
muscles are present in a number of stoloniferous ctenostomes (see
Silén, 1950); their functions are unknown.

Figures 1-6 Mimosella cookae, new species; glycerine jelly whole mounts of
paratype material. 1, base of colony, showing mode of branching, zoecial scars
and stolonal muscles; scale A. 2. Mature autozoid; scale B. 3, brooding autozoid
with young embryo, showing relation of embryo to zoid membranes; scale B 4,
brooding autozoid with an advanced embryo; scale B. 5, base of an autozoid,
showing basal and parietal muscles; scale A. 6, peduncle of an autozoid, showing
morphology of the abscission zone; scale A.

Figures 7-10. Diagramatic representations of mimosellid autozoids, showing
varying morphologies and actions of basal muscles. Arrows indicate presumed
directions of movement of zoecia when basal muscles contract; in no case has
the actual motion of living animals been adequately described. 7, Mimosella
bigeminata (after Silén, 1950); dashed outline indicates position of zoecium when
basal muscles are relaxed. 8, M. verticillata (after Marcus, 1937 fig. 9). 9, M.
cookae. 10, M. firmata (after Marcus, 1938 pl. 14, fig. 34B).

Abbreviations: abz, abscission zone; bm, basal muscles; car, middle chamber of
cardium; cec, cecum; cor, corregated thin region of cuticle; deg, degenerated
polypide; dia, diaphragm; emb, embryo; fun, funiculus; kz, kenozoid; /s, lateral
stolon; ms, main stolon; mus, stolonal muscles; ph, pharynx; pm, parietal mus-
cles; r, cuticular ring near abscission zone; rec, rectum; sca, scar of shed autozoid;
sep, septum; set, setigerous collar; ves, vestibule; vm, vestibular muscles; zoe,
zZoecium of an autozoid.

248 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

Old autozoids are shed like leaves; most zoids still attached to the
colony are healthy, so zoecia are presumably dropped off as soon as
they are dead. This habit, which Harmer (1915) has aptly termed
“deciduous”, is associated with a modification of the cuticle (see below).
Each kenozoid bears only one autozoid; this feature distinguishes M.
cookae from all other members of the genus.

Functional autozoids are elongate, nearly cylindrical, and measure
about 400 » (350-500 ») long, by 70% (50-100 ) wide. The orifice is
drawn into a quadrangular shape by the tension of the vestibular
musculature. There is a distinct setigerous collar (Fig. 2, set). The
pharynx leads into a complex cardium consisting of three parts (Fig.
2, car); the middle chamber is surrounded by fine circular fibers, pre-
sumably muscles. The cecum or “stomach sac” leads directly into the
rectum [=intestine]. Testes, when developed, fill most of the body
cavity from the level of the proximal end of the cecum to the diaphragm.
Ovaries are absent in the specimens examined, but many zoids are
brooding.

Embryos are brooded in the tentacle sheath. Polypides probably
begin to degenerate as soon as larvae are set in place, because even
very young larvae (less than 20 long) are located in zoecia in which
the polypides have almost completely degenerated. The relationship of
the larva to the zoid’s membranes are best seen when the embryo is
small (Fig. 3), because older larvae become quite large (largest meas-
ured: 230 x 115. ; fig. 4, emb), filling almost all the available space
within the zoecium. Parietal, vestibular and basal muscles remain
intact; the first two probably aid in expulsion of the embryo.

The base of the zoid is not perfectly round. The anal side of the zoid
near its attachment to basal kenozoid, is folded inward ventrally and
bears hemicircular corrugations (Fig. 6, cor). The zoecial flexor (erec-
tor?) muscles, here called basal muscles, are difficult to see because
they are poorly developed and easily confused with the retractors of
the lophophore, which originate near them. For this reason, basal
muscles are best observed in brooding zoids, in which retractors are
absent.

Basal muscles consist of two, three, or at the most, four pairs of fibers
originating bilaterally on the proximal zoid wall. Both Joliet (1877)
and Silén (1950) have suggested that basal muscles are serially homo-
logous to parietal muscles. The basal muscles of M. cookae appear to
corroborate this theory; their origins are in the same vertical plane
as those of parietals, and they are spaced at intervals about equal to
the distance between parietals. They insert independently into the
dorsal [anal, or neural] side of the zoecium. The only reliable character

New Species of Mimosella 249

distinguishing parietal muscles from basal muscles in M. cookae is
that basal muscles do not run circumferentially, but insert relatively
more proximally than parietals (Fig. 5, bm).

The insertion of the parietals distal to the corregated region suggests
that their contraction flexes, rather than extends the zoecium. This
suggestion must remain speculative, however, since live animals have
not been observed, and.it is not certain that the zoecia move at all.

Just proximal to the corregated area in the zoecial cuticle, the
zoecium narrows and the cuticle thickens into a short, tough tube. The
proximal end of the tube is limited by the septum, while the distal limit
appears to be the zone at which abscission of the zoecium takes place.
The abscission zone is marked by a tiny groove (Fig. 6, abz) and, just
distal to it, a cuticular ring of reinforced ectocyst (r). “Scars” of shed
zoecia are marked on kenozoids by short tubes with septa near, but not
at, the end (Fig. 1, sca, sep).

DISCUSSION

Basal muscles. The morphology of basal muscles in M. cookae differs
from that of the other known species of Mimosella. In M. bigeminata
Waters, basal muscles are paired, fan-shaped bundles of fibers which
originate on the dorsal side, unite into a single tendon, and insert just
proximal to the thinnned, flexible region (Harmer, 1915). According
to Silén (1950), the action of the muscles is probably erection of the
zoecia from the flexed position, with the dorsal side pressed next to the
stolon (Fig. 7). The erection is presumably opposed by the resilience
of the cuticle. This cannot be the case in M. cookae, however, because
muscles insert distal to the corregated region.

Marcus (1937) has described an animal from Santos Bay, near
Sao Paulo, Brazil, in which the basal muscles insert distal to the thinned
area. The arrangement differs from that of M. cookae, however,
because the thinned area of the former is on the dorsal side of the
zoecium (Marcus, 1937). If the zoecia move at all, it seems probable
that basal muscles flex, rather than erect them, and that flexing must
be toward the anal side (Fig. 10). This is opposite the direction of
flexion proposed for M. cookae (Fig. 9).

Joliet (1877), who apparently observed live Mimosella verticillata,
observed that bilateral muscles originate on the proximal zoecial wall
and insert on the “peduncle”, the narrow proximal part of the zoid.
He described “‘natation” as a bending of the peduncle. Harmer (1915)
illustrates the insertion of basal muscles at a constriction of the pedun-
cle, which he calls the “diaphragm”. It appears that this “diaphragm”

250 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

may represent the abscission zone. Harmer stated that his observations
“agree exactly” with those of Joliet, but their descriptions of the
structure of the peduncle and insertions of basal muscles differ. Neither
author indicated whether basal muscles originate on the dorsal or the
ventral sides of zoecia.

Silén (1950:361, 363) apparently observed that the basal muscle
insertions of M. verticillata are similar to those of M. bigeminata. His
discussion indicated that the muscles originated on the anal side and
insert on the abanal side (Fig. 7). He seemed to have reversed the poly-
pide in his diagram, however (p. 363, fig. 12, on the left). Marcus
(1938:224, fig. 32), on the other hand, illustrated exactly the opposite
situation. He showed the muscles originating on the dorsal side; parie-
tals originate ventrally. Furthermore, the polypide is oriented so that the
dorsal side faces the older (inner) portion of the colony. This is contrary
to the situation in the rest of the Eurystomata (Silén, 1944). According
to Marcus, basal muscles insert on the septum, so contraction must
result in flexion toward the center of the colony (fig. 8).

In view of the contradictions in the literature, it is probably unwise
to draw any firm conclusions about movements caused by contraction
of basal muscles. This is especially true since movements of live mimo-
sellids have not been recorded since the descriptions by Hincks (1851;
1880) and Joliet (1877).

The abscission zone. Silén (1950:359) described a “very small keno-
zoid between the stolon and the autozoid” in M. bigeminata Waters (Fig.
7, kz). Silén’s observations were made on Harmer’s (1915) material, but
neither Harmer (1915) nor Waters (1914), figured basal kenozoids.
In M. cookae the proximal portion of the stolon between the septum
and the abscission zone does indeed resemble a kenozoid (Fig. 6), but
toluidine blue-stained methacrylate sections clearly show that there is
no septum at the abscission zone.

Basal kenozoids, however, do occur in M. bocki Silén; each autozoid
bears three or four kenozoids at its base (Silén 1942). Prenant and
Bobin (1956): illustrated occasional basal kenozoids in M. gracilis
Hincks, 1851, but I have not been able to observe them in my material
of the same species (from the Norman collection, collected at Santos
Bay, Guernsey), presented to me by Patricia L. Cook of the British
Museum (Natural History). The abscission zone in this species is very
close to the septum.

Affinities. The species of Mimosella fall into two groups. The first
group consists of predominantly erect forms in which autozoids origi-
nate directly from the main stolon or are borne on a short series (1-4)
of basal kenozoids. If more than one basal kenozoid is present, those

New Species of Mimosella 251

between the distal kenozoid and the main stolon are barren. This
condition produces colonies in which autozoids are regularly spaced
along the main stolon like leaflets on the sensitive plant, Mimosa, from
which the generic name is derived. This group includes: (1) the geno-
type, Mimosella gracilis Hincks, 1851; (2) M. bigeminata Waters,
1914; and (3) M. bocki Silén, 1942.

The second group consists of adnate species in which the main
stolon creeps along the substrate and is anchored by lateral stolons.
Lateral stolons are usually short and barren, but give rise to small
kenozoids which bear either one or two autozoids, depending on the
species. This arrangement produces colonies in which autozoids are
grouped in bunches along the main stolon. Included in this group are
(1) Mimosella verticillata (Heller, 1867); M. firmata Marcus, 1937;
(3) M. tenuis Harmer, 1915; (4) M. cookae n. sp.; and (5) a doubtful
species, M. tremulans (Hincks, 1862). “M. elegans Richiardi” ap-
parently remains a manuscript name (see Prenant Bobin, 1956).

Marcus considered his Bahia de Santos specimens a subspecies (var.
firmata) of M. verticillata Waters, but it is herein regarded as a separate
species for the following reasons: (1) zoids of M. firmata are somewhat
shorter (500-600 ) than those of M. verticillata (SOO-800 ; Marcus,
1937) (2) the diaphragm of M. firmata is farther proximal than that
of M. verticillata; (3) M. firmata possesses specialized kenozoids
called “adhesive discs”, absent in M. verticillata; (4) the arrangement
of basal muscles is entirely different in the two species (compare Figs.
8 and 10).

M. cookae appears most closely related to M. firmata Marcus, but
it differs from the latter in a number of respects, including the fol-
lowing: (1) M. cookae lacks adhesive discs, present in M. firmata; (2)
M. cookae possesses one autozoid per kenozoid; kenozoids of M.
firmata normally bear two, although occasionally there may be only
one; (3) the diaphragm is located in the distal quarter of the zoecium
in M. cookae, but is much farther proximal (near the middle) in M.
firmata.

Mimosellids are apparently closely related to the family Valkeriidae;
in fact, the only reliable character separating the families is the pre-
sence of basal muscles in Mimosella. Both families possess erect or
adnate colonies with deciduous autozoids, without gizzards, usually
borne on kenozoids. Hincks (1862) described a species which he called
Valkeria tremulans, which he records undergoes flexing movements
as the polypide is retracted (Hincks, 1880). There is nothing to suggest
that this species is not a Mimosella, perhaps identical to M. verticillata
(but see Hincks, 1880:548). The close relationship between the two

252 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

families is further substantiated by the morphological resemblance of
the basal muscles to parietals in M. cookae.

Soule (1954), without explanation, included Hypophorella Ehlers,
1876 in the Mimosellidae. Hypophorella had long been placed in the
Valkeriidae [ = Walkeriidae] Hincks 1880 (see Marcus, 1940 and Borg,
1930), In my opinion, Hypophorella does not belong in either family;
Hypophorella possesses “protective vessicles”’, highly aberrant vesti-
bular musculature, and a strongly developed boring apparatus, none
of which are present in any of the Valkeriidae or Mimosellidae. Fur-
thermore, there are differences in reproductive habits. Prouho (1892)
described the larva of H. expansa Ehlers, 1876 as a cyphonautes; eggs
are extruded through a supraneural pore. Larvae of Mimosella cookae
are brooded in the tentacle sheath; larvae of Valkeria uva (Linné, 1758)
are brooded, but it is uncertain where (Barrois, 1877). Hypophorella,
therefore, appears to be sufficiently distinct to be placed in a separate
family, the Hypophorellidae (Joyeux-Laffuie, 1888a, b; Prenant and ©
Bobin, 1956). Prenant and Bobin (1956) appear to be the authors of
the Hypophorellidae, even though they did not recognize that the
taxon was new (International Congress of Zoology, sec. 4, arts. lle
and 13a). Brien (1960) ascribed the family to “Soule, 1854” [sic],
but this is incorrect.

ACKNOWLEDGEMENTS

I thank Dr. John D. Soule, Dorothy F. Soule and K. June Lindstedt for their
critical reviews of the manuscript. The research, conducted at the Allan Hancock
Foundation, University of Southern California, was supported in part by an
NIH Biomedical Support Grant Award, number 1-So5-FR-07012. Contribution
number 322 of the Allan Hancock Foundation.

LITERATURE CITED

ALLMAN, G. T., 1856. A monograph of the fresh-water Polyzoa, including all the
known species, both British and foreign. Ray Society, London, viii + 121
pp.

Barros, J. 1877. Recherches sur l’embryologie des Bryozoaires. Trav. Inst. Zool.
Lillie, 1: 1-305.

Bora, F., 1930. Moostierchen oder Bryozoen (Ectoprocten). Die Tierwelt Deutsch-
lands, 17: 25-142.

BRIEN, P., 1960. Classe des Bryozoaires. Traité de Zoologie, 5: 1053-1335.

Busk, G., 1852. An account of the Polyzoa, etc. In Mac’gillivray, J., Narrative of
the voyage of H. M. S. Rattlesnake, etc., T and W. Boone, London. 1:343-402.

New Species of Mimosella 253

EHLERS, E., 1876. Hypophorella expansa. Ein Beitrag zur Kenntniss der minieren-
den Bryozoen. Abhandl. Konigl. Ges. Wiss. Gottigen, 21: 1-142. (Cited from
Prenant and Bobin, 1956: 272; not seen).

HARMER, S. F., 1915. The Polyzoa of the Siboga Expedition. Part I. Entoprocta,
Ctenostomata and Cyclostomata. Siboga-Exped. Monogr. 37A, vi + 180 pp.

HELLER, C., 1867. Die Bryozoen des adriatischen Meeres. Verhandl. Zool.-Bot.
Gesell. Wien, 17: 77-136.

Hincxs, T., 1851, Notes on British Zoophytes, with descriptions of some new
species. Ann. Mag. Nat. Hist. ser. 2, 8: 353-362.

1862. A catalogue of Zoophytes of South Devon and South Cornwall
(Pt. 2). Ann. Mag. Nat. Hist., ser. 3, 9: 22-30, 200-207, 303-310, 467-475.

1880. A history of the British marine Polyzoa. Van Voorst, London.
cexli + 161 pp.

INTERNATIONAL CONGRESS OF ZOOLOGY, 1961. International code of zoological
nomenclature. ed. 15, 176 pp.

JOLIET, L., 1877. Contributions a histoire naturelie des Bryozoaires des cétes de
France. Arch. Zool. exp. gén., ser. 1, 5: 193-304.

JOYEUX-LAFUIE, J., 1888a. Sur le Delagia chaetopteri, type d’un nouveau genre
de Bryozoaires. C. R. Acad. Sci. Paris, 106: 620-623.

1888b. Description du Delagia chaetopteri (J. J.-L.), type d'un nouveau

genre de Bryozoaires. Arch. Zool. exp. Gén., sér. 2, 6: 135-154.

Linng, C., 1758. Systema Naturae, Stockholm. ed. 10, vol. 1, Lithophyta and
Zoophyta. [Not seen]

Marcus, E., 1937. Papers from Dr. Th. Mortensen’s Pacific Expedition 1914-
1916. LXIX. Bryozoen von St. Helena. Forhandl. Videnskab. Medd. Dansk
Naturhist., 101: 183-252.

1938. Bryozoarios marinhos Brasileiros —II. Bol. Fac. Phil. Sci., e

Letr., Univ. Sao Paulo, 4, Zool., 2: 1-137.

1940. Mosdyr (Bryoz6a eller Polyz6a). Danmarks Fauna, Copenhagen,

46: 1-401.

PRENANT, M. AND G. BoBin, 1956. Bryozoaires, premiere partie, entoproctes,
phylactolemes, cténostomes. Fauna de France, Paris, 60: 1-398.

Prouno, H., 1892. Contribution a Vhistoire des Bryozoaires. Arch. Zool. exp.
Gén., ser. 2, 10: 557-656.

SILEN, L., 1942. Carnosa and Stolonifera (Bryozoa) collected by Prof. Sixten
Bock’s expedition to Japan and the Bonin Islands, 1914. Arch. for Zool.,
34A: 1-33.

1944. The anatomy of Labiostomella gisleni Silén (Bryozoa Protocheilo-

stomata), etc. Kungl. Svenska Vetensk. Handl., ser. 3,21: 1-111.

— 1950. On the motility of entire zoids in Bryozoa. Acta Zool., 31: 349-386.

SouLE, J. D., 1954. Post-larval development in relation to the classification of
the Bryozoa Ctenostomata. Bull. So. California Acad. Sci., 53: 13-34.

254 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

WartTERS, A. W., 1914. The marine fauna of East Africa and Zanzibar, from the
collections made by Cyril Crossland, etc. Bryozoa — Cyclostomata-Cteno-
stomata and Endoprocta. Proc. Zool. Soc. London, 2: 831-858.

Accepted for publication September 6, 1968

THE ECOLOGICAL SIGNIFICANCE OF
FEEDING BEHAVIOR IN THE MEXICAN LIZARD,
ANOLIS BARKERI

JOHN R. MEYER

Department of Biological Sciences,
University of Southern California,
Los Angeles, California 90007

INTRODUCTION

It was shown in a recent paper (Meyer, 1968) that the Mexican lizard,
Anolis barkeri Schmidt, is restricted to the immediate vicinity of streams
of moderate to steep gradient in areas of humid to wet forest (classi-
fication of Holdridge, 1964). At that time the reasons for the habitat
restriction were unknown, but additional data indicate a correlation
between feeding behavior and distribution.

Previous reports of food items in the diet of Anolis barkeri included
ants (Robinson, 1962; Brandon, et al., 1966), orthopterans (Kennedy,
1965), larval lepidopterans, larval and adult coleopterans, and asilid
flies (Brandon, et al., 1966). Robinson (1962) hypothesized that the
lizards fed on ants utilizing sticks as “bridges”, and Brandon, et al.
(1966) thought that A. barkeri might be a nocturnal feeder to some
degree. My field observations and analysis of stomach contents make
it possible to examine these hypotheses.

Observations on feeding behavior were made during the summers
of 1962 and 1964 in the Los Tuxtlas region of southern Veracruz,
Mexico. Stomachs for food analysis were taken from specimens collected
by me in the same region, and in northwestern Chiapas, Mexico, during
the summers of 1964 and 1966.

FEEDING BEHAVIOR

Anolis barkeri occurs in the immediate vicinity of streams, generally
profusely littered with boulders, logs, and other debris. The streams
vary in size from rivulets no more than half a meter across, to small
rivers 10 to 12 meters in width.

During June of 1962, 16 lizards were observed over 24 hour periods
to determine daily routine. The study area was along a 100 meter
section of the Rio Quezalapam (Meyer, 1968, Fig. 4) in the Los
Tuxtlas region. The following synopsis is based upon these observa-
tions, and was supported by observations on more than 50 lizards
during subsequent field work.

255

256 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

0600 (sunrise) - 1000 hrs. move about on boulders and
debris in or along stream,
feeding

1000 - 1700 hrs. lie out of sight under ledges

or boulders near water, or in
shade on boulders, etc.; little
or no activity

1700 - 1930 (darkness) hrs. _‘ feeding as in early morning

1930-0600 hrs. situated on boulders, logs, or
debris in stream; no activity,
apparently sleeping

Feeding behavior consisted of slow scanning of a boulder or other
object located in the stream, or comparable activity along the bank
immediately above the water line. When a prey item was sighted, the
lizard moved quickly and grabbed it. After varying periods of time
spent on a boulder, etc., a lizard would unhesitatingly enter the water
and swim to another object in the stream, where scanning for prey was
resumed. Rand (1967) indicated that in Anolis lineatopus and many
other visually oriented insectivorous lizards, feeding involves passive
waiting on a perch for prey. From time to time the lizards may change
perch sites, but there is no active searching for prey as in olfactorily
oriented and some visually oriented lizards. Other anoles for which
comparable behavior is known include A. sagrei (Collette, 1961), A.
concoalor (Roy McDiarmid, pers. comm.), and A. carolinensis (pers.
obs.). The feeding behavior of A. barkeri is basically a passive, perching
type, adapted to fit the aquatic situation, and is unique for the genus
insofar as is known.

Swimming by A. barkeri is accomplished by lateral undulations of
the body and tail, with the limbs tucked posteriorly along the body. The
tail is laterally compressed, due to the elongated neural and haemal
spines of the caudal vertebrae. In Fig. 1 caudal vertebrae of A. barkeri
are compared with those of A. sminthus, a terrestrial member of the
fuscoauratus species series, which also includes A. barkeri (Meyer,
1968). The haemal, and especially the neural spines in A. sminthus
show much less elongation than in A. barkeri, and are typical of those
anoles with rounded tails. During normal swimming the entire body,
but not the head, is submerged; during escape behavior even the head
is submerged. The lizards are strong swimmers and have been observed
to make almost direct crossings of very swift water. It is of interest to
note that Anolis carolinensis, which is primarily arboreal but on

Feeding Behavior in Mexican Lizard 257

occasion enters water (Carr, 1940), swims with most of the body on
the surface of the water and uses the limbs and body movement for
propulsion (pers. obs.).

Foop

Stomachs for food analysis were taken from six females and six males
from the Los Tuxtlas region, and from six females and ten males from
northwestern Chiapas. Although there is a size difference of about
20 mm (snout-vent length) between adult females and males in A. bar-
keri, neither sample size nor present objectives warrant separate treat-
ment of the sexes. Data for the Los Tuxtlas and Chiapas samples were
analyzed separately, but the slight difference found between them
permits their combination in the following discussion. A breakdown
of the contents of 28 stomachs is presented in Table 1. Both prey
frequency (per cent of total food items) and prey distribution (per cent
of stomachs containing an item) are given for each food item.

Ants (Formicidae) were found in eight of the stomachs and may have
been captured as they crossed stick-bridges (Robinson, 1962), but
could easily have fallen or been knocked or washed into the streams
by rain and been eaten as they climbed out on objects in the streams.
Also of relatively high distribution in the stomachs (6) were damselflies
(Zygoptera), most of which appeared to be teneral and were probably
eaten following emergence from the nymphal stage on objects in the
streams or along the banks. Other insects associated with the aquatic
environment in at least some stage included coleopterans (Limnichidae,
Elmidae, Psephenidae), dipterans (Chironomidae, Heleidae, Stratio-
mylidae), and hemipterans (Saldidae). These aquatics included both
larval and adult stages, and are accessible to the lizards from their
vantage point as they scan the boulders, etc., or the banks for prey.
The limnichid adults and psephenid adults apparently stay below the
surface of the water, but the lizards were never observed to feed below
water level.

Of the non-aquatic insects, many were larval lepidopterans and
coleopterans that probably found their way into the streams by falling
or being knocked or washed in by rains. The latter seems especially
to have been the case with the larval scolytids and elaterids, which are
associated with rotting logs and could have been washed out by rising
waters. Most of the remaining non-aquatic insects were adults, and
undoubtably found their way into the streams by falling or being
knocked by rains from overhanging vegetation. On the basis of behav-
ioral observations it does not appear likely that many of these insects
were captured during their normal activities on vegetation.

258 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

Figure 1. Caudal vertebra number 6 (A) and number 15 (B) of Anolis barkeri
(both X 10), and number 6 (C) and 15 (D) of Anolis sminthus (both X18).

The remaining food items included arachnids, diplopods, isopods,
and gastropods, none of which are considered to have been associated
with the aquatic environment. They could all have fallen or been
brought into the streams by rains or rising waters. A rapid rise in
stream level was observed on several occasions on the Rio Quezalapam
following heavy rains, increasing the depth of the stream one half to
two meters and innundating much of the adjacent banks.

If all food items listed as “undetermined” in Table 1 are ignored,
the resulting total of 102 is found to be composed of 30 aquatics and
72 non-aquatics. The food of Anolis barkeri, therefore, is found to be
composed of over 70% non-aquatic invertebrates, captured in an
aquatic situation. It may be concluded that the lizards depend heavily
upon the streams to bring a large portion of their prey to their feeding

Feeding Behavior in Mexican Lizard 259

perches. This portion of their diet is supplemented by insects associated
with the aquatic environment.

DISCUSSION

In evaluating the correlation between feeding behavior and habitat
restriction in Anolis barkeri it is impossible to separate other aspects
of the lizards’ biology. Limited data on the temperature preference of
the species indicate that it is relatively low, although comparable data
are not available for other Anolis in the surrounding forest. Kennedy
(1965) gave cloacal temperatures for seven individuals as averaging
24.4 C, while the air temperatures averaged 23.2 C. The latter were
recorded one centimeter above the lizards’ resting sites, which were
undoubtedly near the water and with cooler air temperatures than
would have been encountered away from the water. Kennedy gave the
impression that the lizards are given to frequent basking on boulders,
etc. in and along the stream, but my observations indicate that the
lizards only rarely lie in the sun. It is my impression that A. barkeri is
definitely shade-loving, in contrast to Basiliscus vittatus which is fre-
quently encountered along the same streams.

Other aspects of the natural history of A. barkeri are virtually un-
known, and their effects in influencing the distribution of the species
cannot be evaluated. Nothing is known regarding reproduction in A.
barkeri, outside of the fact that eggs have been reported as deposited
in captivity by Robinson (1962) and Kennedy (1965). The role of the
aquatic environment in aiding the lizards in escape from predators is
supported only by their behavior to humans (Robinson, 1962; Kennedy,
1965), and a single escape from a snake, Leptophis ahaetulla (pers.
obs.). In all cases the lizards took to the water and swam underneath
to some concealed point in debris and boulders where they surfaced.

Because of their dependence upon streams to bring prey to them,
A. barkeri do not stray far from the immediate vicinity of the streams.
Further, since the stream-borne prey is brought in from the terrestrial
environment by frequent rains and rising waters, the lizards are re-
stricted to streams in areas of high, well-distributed rainfall. In southern
México such areas are covered with humid to wet forest (classification
of Holdridge, 1964), which also provides abundant vegetation, with
associated invertebrate fauna, overhanging the streams. It also appears
that the lizards are further restricted to streams of moderate to steep
gradient because of the usual profusion of boulders and other debris
in these streams. Lowland streams of slight gradient in southern Mexico
are generally relatively deep and with few protruding objects. As indi-
cated above, the presence of objects in the streams is of great importance
to A. barkeri, since they serve as feeding perches.

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Feeding Behavior in Mexican Lizard

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262 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

ACKNOWLEDGMENTS

I wish particularly to thank Drs. Joseph Schaffner and Horace Burke of Texas
A&M University for their determinations of the arthropod remains in the
stomachs, and for comments regarding the insects found. In addition, I am grate-
ful to Dr. Fred Thompson of the University of Florida for determination and
information on molluscs found in the stomachs. Dr. Douglas Robinson of the
University of Costa Rica graciously made available his facilities in San Andres
Tuxtla, Veracruz, and assisted me in the field. Other persons who assisted me in
various aspects of field work are: Drs. Schaffner and Burke, J. Van Conner, Harry
Gentner, Joseph Loyd, Richard Roncskevitz, Thomas Stubbs, and my wife, Terry.
I wish also to thank Drs. William B. Davis and Richard J. Baldauf of Texas A & M
University for their assistance in obtaining equipment and support for field work.
Thanks are extended to Dr. Schaffner and Dr. Jay M. Savage of the University
of Southern California for reading this manuscript and making helpful suggestions.

A Grant-in-Aid of Research from the Society of the Sigma Xi made possible
field work during the summer of 1966.

LITERATURE CITED

BRANDON, R. A., R. G. ALTIG, AND E. H. ALBERT 1966. Anolis barkeri in Chiapas,
Mexico. Herpetologica, 22:156-157.

Carr, A. F., JR. 1940. A contribution to the herpetology of Florida. Univ. Florida
Publ., Biol. Sci. Ser., 3:1-118.

CoLLETTE, B. B. 1961. Correlations between ecology and morphology in anoline
lizards from Havana, Cuba and southern Florida. Bull. Mus. Comp. Zool.,
Harvard, 125:137-162.

HOLDRIDGE, L. R. 1964. Life Zone Ecology. Trop. Sci. Center, San Jose, Costa
Rica.

KENNEDY, J. P. 1965. Observations on the distribution and ecology of Barker’s
anole, Anolis barkeri Schmidt (Iguanidae). Zoologica, N. Y., 50:41-44.

MEye_ER, J. R. 1968. Distribution and variation of the Mexican lizard, Anolis
barkeri Schmidt (Iguanidae), with redescription of the species. Copeia, 1968:
89-95.

Ranb, A. S. 1967. Ecology and social organization in the iguanid lizard, Anolis
lineatopus. Proc. U. S. Nat. Mus., 122(3595):1-79.

RoBINSON, D. C. 1962. Notes on the lizard, Anolis barkeri Schmidt. Copeia, 1962:
640-642.

Accepted for publication July 16, 1968

RESEARCH NOTE

THE AFFINITIES OF THE GENUS SOBOBAPTERON PIERCE*

In 1965 the late Dr. W. Dwight Pierce described (under the name of
Sobobapteron kirkbyae) an insect wing which he assigned to the extinct
order Protorthoptera. The fossil was collected near the Soboba Indian
Reservation, north-east of San Jacinto, California, and in shale which
had previously been determined as Pleistocene by Dr. D. I. Axelrod.
Realizing that the order Protorthoptera was known only from Upper
Carboniferous and Permian strata, Dr. Pierce was led to believe that
the age of the shale in which the fossil was found must be older than
the Pleistocene and, indeed, “nearer Permian’.

Since I was preparing a review of the Protorthoptera at about the
time of the publication of Dr. Pierce’s article, I requested and obtained
the loan of the type specimen of S. kirkbyae for study. The present
paper includes additional descriptive details of the fossil and a presen-
tation of my own conclusions about its affinities.

Dr. Pierce based his determination of the ordinal position of the
fossil on the presence of a “fringe of clubbed hairs” bordering the wing
and also on the nature of the branching of the radial sector, which he
felt was of a type not found in any living order of insects. Although Dr.
Pierce did not make a family assignment of the species within the
Protorthoptera, he included it within the superfamily Hapalopteroidea.
This taxon, which was originally given ordinal status by Handlirsch
(1906), was based upon a single species, Hapaloptera gracilis, which is
now placed within the Protorthoptera, close to the family Cacurgidae
(Carpenter, 1965).

Although the wing of kirkbyae does appear to have a border of
clubbed hairs, careful examination of the fossil shows that this fringe
occasionally projects for a considerable distance away from the wing
itself and that the fringe is actually formed by inorganic (mineral)
deposition, apparently as a result of a reaction between organic com-
pounds of the wing and certain chemicals in the matrix.! The darkened,
irregular areas within most cells of the wing (shown in Dr. Pierce’s
figure but not discussed in his description) are also mineral in nature.

*Research aided by NSF grant GB 7308-2.

1] am indebted to Dr. Cornelius Hurlbut, of the Department of Mineralogy,
Harvard University, for confirmation of this interpretation.

263

264 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

The venation of the wing turns out to be that of a damsel-fly (sub-
order Zygoptera) in the order Odonata (see figure 1). Dr. L. K. Gloyd,
at the Museum of Zoology, University of Michigan, to whom I sent
my drawing of the wing, informs me that the specimen was undoubtedly
that of a species of the living genus Enallagma (Coenagrionidae). Dr.
Gloyd was further of the opinion that the fossil wing could very well
have belonged to Enallagma clausum Morse, which now occurs in
California as well as in other parts of the United States. Unfortunately,
the variability of venational details in the species of Enallagma prevents
specific determination on the basis of the wing alone. For the present,
it seems advisable to consider the specific name (kirkbyae) valid, since
precise synonymy with any living species cannot be established. The
generic name Sobobapteron, however, is herein placed as a junior
synonym of Enallagma and the species moved from the Protorthoptera
to the Odonata.

[ie
i ee
DSSS RRS
Da ea

Figure 1. Enallagma kirkbyae (Pierce); original drawing, based on holotype
(No. $9113), in Los Angeles County Museum, Invertebrate Paleontology.

Dr. Axelrod has informed me (pers. comm.) that there is no question
that the age of the deposit which produced the insect wing is Pleistocene.
In his account of the plants (Axelrod, 1966), he points out that the
flora of the formation (Bautista) which also produced the insect wing
can largely be duplicated today by vegetation in the nearby mountains
at altitudes of about 3000 ft. above the fossil site. Mammals which have
been collected in the same formation are likewise considered of Pleisto-
cene age (Frick, 1921).

Fossil Insect 265

LITERATURE CITED

AXELROD, D. I. 1966. The Pleistocene Soboba Flora of Southern California.
Univ. Calif. Publ. Geol. Sci., 60:1-79.

CARPENTER, F. M. 1965. Studies on North American Carboniferous Insects. 4.

The Genera Metropator, Eubleptus, Hapaloptera and Hadentomum. Psyche,
72(2):175-190.

Frick, C. 1921. Extinct Vertebrate Faunas of the Badlands of Bautista Creek
and San Timoteo Canon, Southern California. Univ. Calif. Publ. Geol.,
12:277-424.

HAND LIRSCH, A. 1906. Die fossilen Insekten. Leipzig.

PIERCE, W. D. 1965. Fossil Arthropods of California. 26. Three New Fossil Sites
in California. Bull. So. Calif. Acad. Sci., 64:157-162.

F. M. Carpenter, Biological Laboratories, Harvard University, Cambridge,
Massachusetts, 02138.

Accepted for publication September 16, 1968.

266 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968
BREEDING OF THE BLACK SWIFT IN VERACRUZ, MEXICO

The Black Swift, Cypseloides niger, ranges throughout much of western
North America, Central America and the West Indies, but migrates
from the northerly areas during the winter months. Despite this wide
range of occurrence its actual breeding distribution is still poorly
defined; its breeding in many areas has only been assumed on the basis
of scattered sight and specimen records of adults during the mid-
summer months. Although its range in Mexico includes the states of
Baja California, Durango, Mexico, San Luis Potosi, and Tlaxcala, it
is thought to breed only in Oaxaca, Nayarit, Puebla, and Veracruz
(Friedmann, Griscom and Moore, 1950). The only information avail-
able on its breeding in Mexico based on direct observations of nests or
young is that of Rowley (1966) for Oaxaca. Thus, the following obser-
vations seem pertinent.

In July 1964, the junior author, accompanied by J. Lynch, encoun-
tered a small nesting colony of C. niger on the mountain, Cofre de
Perote, in Veracruz. Four nests and at least six adults were observed
near a 40 ft. (12.2 m) high waterfall located at the end of a valley in the
subhumid oak-pine zone at an elevation of approximately 9100 ft.
(2766.7 m). Additional swifts or nests were not observed near other
falls in the vicinity. Four adults and two nestlings were collected be-
tween 27-29 July and have been deposited in the American Museum of
Natural History. Unfortunately the condition of the specimens, which
were preserved in alcohol, prevents subspecific identification. Although
Black Swifts have often been observed flying in the mountains of west-
central Veracruz in the summer months and a specimen was taken near
Xico in late June (Loetscher, personal communication) breeding sites
have not been previously located.

The swifts were nesting on mossy ledges behind and to the sides of
the waterfall; the single nest collected was constructed of mosses and
ferns and lined with a few pine needles. Similarly constructed nests of
C. niger have been reported from Oaxaca (Rowley, 1966) and numerous
inland sites in western United States (Hunter and Baldwin, 1962;
Knorr, 1961; Michael, 1927). Almost all other members of the genus
Cypseloides, for which the nests are nown, also build a mossy nest on
rocky outcrops in dark places near water and often behind waterfalls
(Lack, 1956; Collins, 1968).

The two nestlings, found in separate nests (a clutch of one is usual
in this species), were only slightly different in age. The smaller bird
still had traces of the egg tooth, and the incoming pennaceous feathers
were mostly confined to the secondaries and secondary coverts. The

Breeding of Black Swifts 267

primaries and secondaries of the larger nestling were about 10-15 mm
long and starting to erupt from their sheaths. Some completely en-
sheathed feathers had just erupted through the skin on the back. Both
nestlings had a heavy covering of blackish plumulaceous feathers on
the back of the head, back, flanks, belly, throat, and patagial region of
the wing. As noted by others, these feathers were located in the apteria
and along the margins of the pterylae (Hunter and Baldwin, 1962). The
young are hatched naked, and the downy plumage, a portion of the
first teleoptile plumage, is entirely post-hatching in its development.
It presumably aids in the development of thermoregulation of the nest-
lings. The downy feathers are longer on the back than the belly or wings,
but none was sufficiently developed to determine whether they could
be classified as down or semiplumes. In Cypseloides rutilus this downy
plumage is composed of loose-webbed semiplumes having a definite
rachis and aftershaft (Collins, 1963).

Undigested insects were recovered from the throats of two adults
taken at night on the nest. A total of 276 individuals of four kinds of
Hymenoptera, 200 of which appeared to be of a single species of winged
ant (Formicidae), were present. These food items ranged from 2 to
12 mm in length; insects 9 and 10 mm long were most common (Table
1). These food items are slightly larger than those taken by the smaller
swifts, Cypseloides rutilus and Chaetura brachyura (Collins, 1968),
but closely approximate the size range of food items taken by the larger
species Apus apus (Lack and Owen, 1955).

TABLE 1
Sizes of insect food items taken by adult Black Swifts in Veracruz.

Size of
food items

Number of
individ-

1Total length from tip of head to tip of abdomen.
All fractional measurements read to next whole millimeter.

268 Bulletin So. Calif. Academy Sciences |Vol. 67, No. 4, 1968

ACKNOWLEDGEMENTS

We are grateful to Frederick W. Loetscher, Jr. for providing information on the
occurrence of the black swift in Veracruz, and to Eugene Eisenmann and Richard
K. Brooke for their helpful comments on the manuscript. Field work was aided
by grants to the junior author from The Society of the Sigma Xi, the General
Research Fund of The University of Illinois, and the Explorer’s Club.

LITERATURE CITED

CoLLins, C. T., 1963. The “downy” nestling plumage of swifts of the genus
Cypseloides. Condor. 65:324-328.

CoLuins, C. T., 1968. The comparative biology of two species of swifts in Trini-
dad, West Indies. Bull. Florida State Mus., 11:257-320.

FRIEDMANN, H., L. GRISCOM, AND R. T. Moore, 1950. Distributional check list of
the birds of Mexico. Part I. Pacif. Coast Avif., 29:1-202.

HuntTER, W. F. AND P. H. BALDwin, 1962. Nesting of the Black Swift in Montana.
Wilson Bull., 74:409-416.

Knorr, O. A., 1961. The geographical and ecological distribution of the Black
Swift in Colorado. Wilson Bull., 73:155-170.

Lack, D., 1956. A review of the genera and nesting habits of swifts. Auk, 73:1-32.

Lack, D. AND D. F.-OwEN, 1955. The food of the swift. Jour. Anim. Ecol., 24:
120-136.

MICHAEL, C. M. 1927. Black Swift nesting in Yosemite National Park. Condor
29:89-97.

RowLEY, J. S. 1966. Breeding birds of the Sierra Madre del Sur, Oaxaca, Mexico.
Proc. Western Found. Vert. Zool., 1:107-204.

Charles T. Collins, Department of Biology, California State College at Long
Beach, Long Beach, California, 90801 and Macreay J. Landy, Department of
Biological Sciences, George Washington University, Washington, D.C., 20006.

Accepted for publication September 19, 1968

SOUTHERN CALIFORNIA ACADEMY OF SCIENCES
VOLUME 67, 1968

SUBJECT AND AUTHOR INDEX

IND DOMAID MRA eee lak be eee ees 143
/NCEICIING' 5 5 6 Sono CE ese ate os 555235
Adaptations in movement patterns

of two species of salt-marsh ro-

GINS: so dg tee eee 96
VAC CUMUMUILGGICMr i a ae eae 207
Agalvchnis dacnicolor .......... 130

Aggressive behavior in the poly-
chaetous annelid family Nerei-

GAS 4 oo 6 Se RoR er ee en eee 21
ANIVE, [Roc Nila: 5 se ete ee eee Serer a ae 128
PN OSTA Ores sus Giger en Vghae 21
Amathia distans ............... 209
Amphibia, Costa Rica .......... 1

NIG Xa COMPRA h ee cc oid istame arate 129

PMWOSeEMVyA ee eee ae 19

SUCCESSION Nes: eyes tok Rit ee 129
Ammphipodases- 5 sae o0 sss oe 219

A new chigger (Acarina, Trombi-
culidae) from a bat, Tadarida
femorosacca, taken in Sonora,

IMIS) 5 ae A aie ee ar a 155
A new fossil weevil from Nevada
(Coleoptera: Curculionidae) ...196

A new red-eyed tree-frog (Family
Hylidae) from Costa Rica, with a
review of the Hyla wranochroa
group

A new species of acontiate anemone
from southern California (Sagar-

LN CASES CHE CUIZEIC) ee eee 182

A new species of Terebripora (Ecto-
procta, Ctenostomata) from Ant-

arctic Cephalodiscus ......... 178
A new species of the genus Stenis-
tomera (Siphonaptera: Hystri-
CHOPS Willa) sere eee eee 138
AUMOINS (XUUFEORT oo5n000050050006 BSS
JN TMIRN COE 6 9) 68 et ee 178
PAIL OZO Ames res sich sha 3 sees 192
Anuran succession in a temporary
pond in Colima, Mexico ...... 129
END OICERIOS So 12S Sas oboe ee soe ee 29
PNA CIN Aiesiey cass sassy alee ae 240
TOSI 35 3k See ners a ee EN 125

ATCuCEOCeanun eee 69, 112
VAS GICICENUC Ce eee ene 89
AASCIGIANNG fon tee ke eee 89, 143

A spider trackway from the Coco-
nino Formation, Seligman, Ari-
LOMA ee ec: carp GAG Die Sone toe 125

Attachment and growth of the sto-
loniferous ctenostome bryozoan,

Zoobotryon verticillatum ..... 199
FAVESSOnCE GIN Cent tae 266
Bamtas wii piv a8 aces te eee ates 245
Bannardy Jeeta tai ane aseth ce 219

Billfish remains from southern Cali-
fornia with remarks on the im-
portance of the predentary bone. 29

Bloodytumnicatalss anes ane aee 89
Bone, predentary .............. 29
Breeding of the black swift in Vera-
ChUZS IMIEXICOM a ae ee 266
Brooding of the eastern glass lizard,
Ophisaurus ventralis ......... 65
BRyOZOas ee. OS alae 4s

Bryozoan fouling organisms from
Oahu, Hawaii with a new species
of Watersipora .......... Pee 08
Bufo marmoreus ...........4%. 130
Bugula californica .............
Be CRIT tense ne eee

Bulllivanta Je S-aeee ete OD
Ealtitonniay fossil eee 29
Carpentery hae Vinge eee OS)
Cladocoryne floccosa ........... 59
Coleopteraiae eee eae 196

LOSSII 4, AAs VAG cers Moore eee 196
Eollins Gy Wis cece ee ee 266
Coral, crab inhabiting .......... 40
CostasvRicaans ke ee l
Gypsclordcsimiccinree eee 266
Davidson tEsSt- sheen eee 85
Dawsons Keres con 6 ee ae oe 112
Decapoda: we ceasces ie meee 40, 85

269

THO Tul aes ny ec eee er 80
Diaglenatspatulatae panne ee 130
Distaplia smithi ............... 147
Dixons Resa rca a oes eben 129
Dub ale NIN S yey orcs ee sae 240
ECO PiOCtam nena 178, 199
Beoscues He Jig aecisces some eee 138
Eukrohnia hamata ............. 114
Euphausiaceaanoes sone aoe ae: 69
Euphausiacea of the Arctic Ocean

and its peripheral seas ........ 69
Fabia concharum .............. 87
ASUOQUAAT ATA eee 85
JENERSUIMNG, Jal Ie os bonovngooccccs 29
Sl ety Grokster co aera 96
Fouling organisms ............. 203

Gammarus (Mucrogammarus) mu-

GRON GUS re eine eles aie iraser eae 221
GanthiyieSs asta et a cen 40
GeISeItSa Repack senso cee 69
Grapsus grapsus tenuicrustatus ... 80
Graves WES ea Wires nea en ee Oe 219
LAW aliilieeacaenn tent tae sanct aamenaere pe share 203
Heterokrohnia involucrum ...... 117
Heterometrus sp ............... 240
IHOSHGUOWES voccccooebeoeoeoe ee 233
Hi navojoa@ 224. bas. Noe: D3)
Ley Cle WHO RG cer ee er eer ae 129
Hippopodina feegeensis ......... 211
Hopkins iSite oe ens cee 40
FIVdtOZOa. cau cae node 59
Hyla lythrodes ................ 1
Ep piGhipesscroupiIn eee 9
H. uranochroa group ........... 6
Hypopachus variolosus ......... 132
Imsectassfossill ieee ieee ne 263

Introduction of an amphipod crus-
tacean into the Salton Sea, Cali-

PORIMIA sis hae ee eee ee 219
Lemunalsein, Uo Wo 8 bic co oop oesegs 80
MESO StI) RC aids ai dee met ee 59
Leptodactylus labialis .......... 131
LER nClanOnOtliss ee 132
Moomiss -R&Be vis. geese cs eee 155, 233

270

Eucas) Js Tos csc a ee ee 233

IMMGUSGURG Sx o5000000000c000006 By
Mammalia ..c2:c haan aoe eee 96
McDiarmid, R.W.............. 159
McPeak, (Ro Ss. 3.0505 Heer 182
Mexico ...... 129, 155, 233, 255, 266
MieyercJe Re ace oe DSS
Microtus californicus ........... 96
Mimosella cookae ............. 245

Mimosella cookae, a new species
(Bryozoa, Ctenostomata), with a
review of the family Mimosel-

Wd aes ies St 8 ede 245
Miocene Ossillen esa 29
Mucrogammarus .............. 220
IMUM, IMIG IMIG Sob ectes ccc oe occ 69
New ‘Semlisy s 432 Geese eee 220

New species ...1, 117, 138, 143, 147,
or Es ade 155, 179, 183, 196, 235, 245

Ophiodromus pugettensis ....... 104
Ophisaurus ventralis ........... 65
Paralabrax clathatus ........... 49
Ratinicaarniniaraier eee 104
Renndionissn nee 233
Remmiransstossilleas eee 125
Pinnotheres concharum ......... 85
Pisces; fossil)... c3783 eee 29

tracey elements yaar 49
Pleistocene, fossil ........... 29, 263
Pliocene fossil: 44s 196
Polychaeta) =<. 30a ee 21, 104

behavioman eet ee 21, 104

Pseudocryptochrirus crescentus
(Edmondson), a second crab of
the corallicolous Family Hapalo-
carcinidae (Crustacea, Deca-
poda) from the Eastern Pacific
with remarks on phragmosis, host

specificity, and distribution .... 40
Pseudocryptochirus crescentus ... 40
IRAnGyDIPICRS eo eee 132
Reish, D3) .36 aos eee 21, 104
Reithrodontomys raviventris .... 96
Reptilia eae eee 65, 159, 255

brooding .-..05 2... eee 65

ecology on ashlee eee 255
Rhyncolus kathrynae ........... 196

Ritterella rubra ............... 143

Ritterella’ rubra and _ Distaplia
smithi: two new colonial ascidi-
ans from the west coast of North

ANTUTIGIPICE, o.9 Cae Ree e ana ENC ren eee 143
RO GRISWEZAIKG mon, 23S en hs hele 69
Sagartia catalinensis ........... 183
SalitomeSea) 2.224262 5.55: jue ae 219
Savignyella lafonti ............. 212
SAVAGES, Uo: IMIS Sestareenegenn isnt e eee |
Schizoporella unicornis ......... 212
Scrupocellaria sinuosa .......... 214
Seasonal occurrence of the com-

mensal polychaetous annelid

Ophiodromus pugettensis on the

starfish Patiria miniata ....... 104
Siphonaptera, new species ...... 138
Slee penmlaallaa nsec cee Seca oes 196
Smilisca baudinii .............. 130
SOVODUDIGIONME risa rei 2 263
SOULCMD ME Gee cbse ke! 178, 203
SOULMMDS == ta ae ee ee. 178, 203
SlapletoneeRer Rs ycc hie se sek 49
Stenistomera hubbardi ......... 138

Studies on the blood of Ascidia
nigra (Savigny). III. Some aspects
of the biochemistry of vanadocyte

acclutinavionee an aes ose 89
Tadarida femorosacca .......... 155
Manigoshia IK. o5 oe we Gea es 155
Tantilla atriceps ............... 159
Io SRG rove natcsoleken ce eee ane ee 159
Terebripora eltaninae .......... 179

The addition of the hydroid Clado-

271

coryne floccosa to the California

Mahinemiauin ayn 59
The affinities of the genus Sobo-
bapteron Pierce ............. 263

The ecological significance of feed-
ing behavior in the Mexican liz-
ard, Anolis barkeri .......... 255

The Pinnotheres concharum com-
plex (Crustacea, Decapoda, Fam-
ily Pinnotheridae) ........... 85

The genus Hexidionis (Acarina,
Trombiculidae) with the descrip-
tion of a new species from Wes-
(FM IMI@RIEO oocccoe ce es oucce 233

The structure of the chela of Heter-
ometrus sp. and its mode of oper-
ALIOMMEs es As easier a eeaieney cacken. 240

The terrestrial molting behavior of
the crab Grapsus grapsus tenui-

CUESTA cee ray Ros a 80
Trace elements in tissues of the cali-

co bass Paralabrax clathratus

(Grand) ih eee eh tg cee 49
Trasom WEB H ae ese el eee 143
Trombicula spathi ............. 15)
Vallee se Ay aida an i a tet 89
Vanadocyte agglutination ....... 89

Variation, distribution and syste-
matic status of the black-headed
snake Tantilla yaquia Smith ...159

Mine Sata Avery earths scene nan 65
Vy ase A Be ack Sue een eke 240
Watersipora edmondsoni ....... 215

Zoobotryon verticillatum ...199, 216

hwn —

10.

STATEMENT OF OWNERSHIP AND MANAGEMENT

. Date of filing: September 24, 1968.

. Title of publication: Bulletin of the Southern California Academy of Sciences.
. Frequency of issue: Quarterly — March, June, September, December.

. Location of known office of publication: 900 W. Exposition Blvd., Los An-

geles, California, 90007.

. Location of Headquarters: Same.
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Editor: Donald J. Reish, Department of Biology, California State College at
Long Beach, Long Beach, California, 90804.
Managing Editor: None.

. Owner: Southern California Academy of Sciences — A non-profit Corpora-

tion.

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the purpose, which function, and non-profit status of this organization and
the exempt status for federal income tax purposes have not changed during
the proceding 12 months.

Average no.
copies each
issue during Single issue
preceding 12 nearest to
months filing date
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B. Paid circulation
1. Sales through dealers and carriers, 10 6
street vendors and counter sales
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F. Office use, left over, unaccounted,
spoiled after printing 205 159
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272

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Southern California
Academy of Sciences

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re LIBRARY

APR 3 1969

NEW YORK
BOTANICAL GARDEN

Mer tLrETIN OF THE

Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

VOL. 68 JANUARY-MARCH 1969 Part 1

HYMENODORA GLACIALIS
(DECAPODA: NATANTIA) FROM THE ARCTIC BASIN

ALAN D. HAVENS AND WESLEY L. RORK

Department of Biological Sciences
University of Southern California
Los Angeles, California 90007

Bull. So. Calif. Acad. Sci. 68(1): 19-29, 1969

HYMENODORA GLACIALIS
(DECAPODA: NATANTIA) FROM THE ARCTIC BASIN

ALAN D. HAVENS AND WESLEY L. RORK
Department of Biological Sciences
University of Southern California

Los Angeles, California 90007

ABSTRACT: A study was made of the shrimp Hymenodora
glacialis (Buchholz) collected from Fletcher’s Ice Island
from June 1965 to January 1967, when the island drifted
over the deep water of the Canada Basin. A vertical distri-
bution was determined by means of horizontal and vertical
plankton net hauls, which accounted for most of the catch;
the animal is most abundant from 350-1000 m, less abundant
from 1000-3800 m, and least abundant from 0-350 m. In
addition, some specimens were taken from near the bottom
using a small biological dredge at depths of about 2000 and
3800 m. No seasonal or geographical variations in abun-
dance, or size variations with depth, etc. were indicated. An
analysis of sampling gear used indicated that more shrimp
were caught when a higher tow speed was employed or a
larger sized mesh used: there was no correlation between
the size of the animals caught and tow speed.

Most of the animals captured were from 10 to 30 mm
long; a study of secondary sexual characteristics indicated
that few specimens were mature, and that sex determination
is difficult with individuals under 40 mm, small males re-
sembling females. Only a few females were ovigerous. A
study of gut contents suggests that the species has a diverse
diet, but that the most important food is copepods, with
chaetognaths and radiolarians also being fairly important.
Gut contents were often nearly intact in large specimens.
Two larger animals had ellobiopsid parasites.

INTRODUCTION

In the biological collections made from Fletcher’s Ice Island T-3 from
June 1965 to January 1967, the natant decapod crustacean Hymeno-
dora glacialis occurred in sufficient numbers to attract our attention.
This fact was particularly interesting, since specimens were caught
using a wide variety of sampling techniques, none of which would be
considered especially good for catching shrimp; and also because this
organism is among the largest of the Arctic pelagic invertebrates, and
may therefore be an important factor in the ecology of the region.
Previous records indicate that Hymenodora glacialis is abundant

19

20 Bulletin So. Calif. Academy of Sciences

in the Greenland and Norwegian Seas and Baffin Bay, although it has
been recorded from as far south as 30°N latitude in the Atlantic Ocean
(Stephensen, 1935; Sivertsen and Holthuis, 1956). It appears to be
primarily a meso- and bathypelagic species in the northern North
Atlantic, but has been taken at many depths. A few records exist of
the occurrence of this form in the Arctic Ocean: Sars (1900) recorded
it from north of the New Siberian Islands, Bogorou (1946) from north-
west of Severnaya Zemlya, Dunbar and Harding (in press) from the
Beaufort Sea, and Barnard (see Mohr and Geiger, in press) from
northwest of Ellesmere Island; and J. C. Yaldwyn, of the Australian
Museum, has some specimens from the Beaufort Sea under study.

METHODS AND MATERIALS

Studies by biologists from the University of Southern California were
renewed on June 13, 1965, on Fletcher’s Ice Island T-3. Between then ~
and January 14, 1967, the island drifted within an area bounded by
74° and 79°N lat. and 139° and 177° W long. primarily over deeper
water of the Canada Basin but with several transects over the Chukchi
Rise (Fig. 1).

Hymenodora glacialis was collected primarily with ¥2 meter plank-
ton nets with no. 6, no. 20, and no. 24 mesh sizes, and a few specimens
were taken with a 1 meter net, mesh size no. O and no. 6; a wire mesh
sieve was employed in the capture of specimens at the surface of the
hydrohole, and dredging was done near the bottom with a Menzies
Trawl. Several variations of the latter were used, the modified Menzies
I, with an opening | by 0.1 m; the modified Menzies I, with dimensions
of 0.9 by 0.15 m, having the edges bent out into flanges, and the modi-
fied Menzies T-3, which used the MMII frame, but parachute material
for the bag, instead of the no. 0 mesh used in the other types.

A list of stations at which this species was taken, as well as a detailed
description of the collecting gear, will be deposited with the American
Documentation Institute, Auxiliary Publication Service, which is
administered by the Library of Congress, Washington, D.C. and can
also be made available upon request to the Arctic project of this depart-
ment. The collections were made by J. A. Pierce III, A. J. Mearns,
G. P. Owen, J. K. Dawson, and W. L. Rork. More than 700 samples
were examined, without the aid of magnification, and decapods were
removed for further study. Specimens were preserved in 7 per cent
formalin buffered with hexamethylenamine, or in Bouin’s and 70 per
cent ethyl alcohol, and total length (from the most anterior part of the
rostrum to the tip of the telson) was measured.

Decapods from the Arctic Basin 72)

DATA

All of the decapods collected from ice island T-3 were identified as
Hymenodora glacialis (Buchholz) a shrimp of the family Oplophoridae
on the basis of descriptions by Sars (1885), Kemp (1910), and Sivertsen
and Holthuis (1956); the last include a discussion of the differences
between H. glacialis and H. gracilis (Smith), which are very similar
and which at least in the North Atlantic have overlapping distributions
(Sivertsen and Holthuis, 1956). The criteria used to distinguish the
two species are as follows: in H. glacialis the lobe over the second
segment of the antennal peduncle is broadly rounded, while in H.
gracilis it is produced to a blunt point; H. glacialis has a groove on the
carapace which is lacking in H. gracilis (see Sivertsen and Holthuis,
1956, Fig. 12), and H. gracilis has a podobranch on the second max-
illiped which is lacking in H. glacialis. Finally, H. glacialis has a shorter
rostrum with a more convex lower margin and swollen upper lateral
surfaces, while in H. gracilis the rostrum is longer and the upper
lateral surfaces concave.

Adult specimens examined all lacked the long and pointed distal
end of the rostrum illustrated for H. gracilis in Sivertsen and Holthuis
(Fig. 13); the end of the rostrum was blunt and up-turned, and there
were 4 to 7 rostral teeth above. Larval shrimp in the collection are
generally similar to the description of H. glacialis larvae given by
Stephensen (1935).

22 Bulletin So. Calif. Academy of Sciences

Efficiency of Sampling Gear. The effects of variations in sampling
technique and sampling conditions were examined prior to any attempt
at analysis of possible spatial or temporal fluctuations in the shrimp
population. Vertical net tows were made by rapidly hauling the net
through the water column; for the most hauls a closing device was used,
for greater accuracy in determining depth distribution. Horizontal
net tows were accomplished by stationing the net at various depths,
and relying upon the difference in speed between the ice island drifting
on the surface and the current below to produce an effective tow speed.
A convention was adopted to give a rough indication of relative tow
speed: 0, if the cable was hanging vertically into the water, 1, if there
was a Slight cable angle, 2, if there was a marked angle, and 3, if the
cable was touching the edge of the hydrohole cut in the ice, indicating
a high tow speed. Vertical net hauls, of short duration, captured one
shrimp per six hauls, and horizontal net tows, which often lasted 10
or 20 hours, caught one per four hauls.

TABLE I
Efficiency of capture, Ratio of
as related to Mesh size shrimp captured
variation in: per haul
a. mesh size, horizontal No. 24 1/20
and vertical hauls No. 20 1/6
combined. No. 6 1/3
Speed, m/min.
b. tow speed, vertical 10-14 1/36
net hauls. 15-19 1/17
20-39 1/5
40-80 1/5
Wire angle
c. Wire angle, hori- 0-1 1/8
zontal net hauls. 2 1/5
3 1/1
Variant No. shrimp No. hauls
d. Design of Menzies MMI | oo. Bie Tax
trawl MMII 1S 16
MM T-3 0 6

It can be seen from Table la-c, that more shrimp were captured when
a larger mesh size was used, and when tow speed for vertical hauls or
wire angle for horizontal tows was greater. The Menzies Trawl also

Decapods from the Arctic Basin 23

captured a number of shrimp (Table 1d); here again the catch was
improved when the MM II variant, with its larger mouth, was employed.

Vertical Distribution. The only precise determination of the depth
at which Hymenodora glacialis occurs was made with the vertical
closing net (Table 2a). One shrimp was caught on a tow between 1900
and 2500 m, the record depth for H. glacialis captured with this device,
during the study. Shrimp were not caught in horizontal tows just under
the ice surface, nor were they found in traps lowered to depths of 0-4
m, though one specimen was captured at the surface of the hydrohole
with a wire mesh scoop. Vertical, non-closing net hauls between depths
over 100 m and the surface appear to confirm the above indicated dis-
tribution pattern (Table 2b).

TABLE II
VERTICAL DISTRIBUTION

Depth Range % Water Shrimp Per
(Meters) Filtered Meters Filtered
a. Vertical closing 0-500 Dali 1/7500
net 500-1000 19 1/2300
1000-2000 By 1/8900
2000-3780 DD 0
Depth Range of Haul, Shrimp Per
(Meters) Haul
b. Vertical 0-250, 300 0
non-closing net 0-500 1/7
0-1000, 2000, 3000, 3785 1/1
Depth Range % of Shrimp Per
(Meters) Tows Tow
c. Horizontal net 0-350 34 1/11
400-800 oD 4/7
900-1300 23 2/7
1400-1900 9 1/3
2000-2900 9 1/7
3000-3780 3 1/4*

*Unreliable because of small number of tows.

Horizontal net tows must be regarded as less reliable than vertical
closing net tows, because of the possibility of sample contamination
during retrieval, which will increase with depth, but the distribution
of the catch is somewhat similar (Table 2c). Though less reliable than
closing net hauls, the number of specimens (76) is enough for a statisti-
cal analysis; a chi-square test was employed, the expected numbers

24 Bulletin So. Calif. Academy of Sciences

of shrimp being estimated on the basis of the proportions of the total
hours fished within each depth range. The expected and observed
numbers of shrimp were found to be significantly different at a P .01
level with 4 degrees of freedom, indicating a non-uniform distribution
with respect to depth; fewer shrimp were observed in the 0-350 m
range, and more in the 400-800 m range, than expected, while for the
remaining categories of 900-1300, 1400-1900, and 2000-3800 m,
the differences were not great.

Some 33 hauls were made with the modified Menzies Trawl, an
average of one shrimp per two hauls being taken; most of the shrimp
were caught in hauls which sampled the bottom at about 2000 and
3800 m. While a closing device was not used, contamination during
retrieval was unlikely, considering the shape of the frame; the MM IIT
version proved to be much more efficient than the vertical nets at cap-
turing shrimp.

Seasonal Variations and Geographical Distribution. As the ice
island was generally drifting in a westerly direction, from 141° to
176° W, when shrimp were captured (Fig. 1), geographical variations
in the catch were looked for. It was found that fluctuations in horizon-
tal and vertical net catches were related to variations in sampling
conditions and technique, and geographical or seasonal variations are
not apparent; it can only be said that the animal is present throughout
the year.

Size Variation. Data on the number of specimens of various size
ranges is presented in Table 3. An examination of the sizes of the
shrimp caught by nets run at different tow speeds revealed no correla-
tions; there is no evidence that larger shrimp will evade the nets more
than smaller ones. The data likewise do not support any strong correla-
tion between size and vertical or geographical distribution, or month
of capture.

TABLE III
SIZE VARIATION

Length Number
(mm)
< 10 2
10-19.5 73
20-29.5 31
30-39.5 17
40-49.5 13

50 < |

Decapods from the Arctic Basin 25

Sexual Identification. Determination of the sex of the animals was
made on the basis of Sars’ (1885) description of the morphology of
the first and second pleopods of the male. In this species, small males
closely resemble females; many individuals under 40mm long could
not definitely be assigned to one sex of the other. There is a great deal
of variation in the morphology of the endopod of the first pleopod in
immature specimens; the smallest male in the collection displaying
the adult condition of the first pleopods was 33 mm long. The appendix
masculina, which is found only in males, appears considerably later
than the appendix interna, which both sexes possess on the second
pleopods; the smallest specimen having this organ was 35 mm long.

On the basis of the characters of pleopods | and 2, 11 specimens
were identified as males, and 15 as females; ambiguous specimens, all
under 40 mm long, were not sexually identified. Two adult females
were Ovigerous, and the one measurable specimen was 45 mm long.
Two additional ovigerous females collected on 15 August 1967 were
52 and 56 mm long. A tentative separation of immature specimens
into males and females indicated that the proportions of the sexes in
the population are approximately equal.

TABLE IV
STOMACH CONTENTS

Number of shrimp
Item contained in

Copepods 5
Chaetognaths l
Radiolarians l
Polychaetes

Amphipods

Ostracods

Hymenodora (jaw)

Foraminifera

Bryozoan*

Filamentous Algae

Muscle Fibres or

Tubule Bundles I

SS SS LS) SS

Stomach Contents. Ninety-seven shrimp were dissected for stomach
contents: 12 from vertical and 70 from horizontal tows, 15 from
Menzies Trawl catches, and | from the surface. Eight specimens were
still in a larval stage and lacked well defined stomachs. The stomachs
were removed from the rest of the individuals, which were 12 mm and

26 Bulletin So. Calif. Academy of Sciences

above, and of these, 17 were empty. Material in the stomachs of the
remainder was identified, and the number of specimens containing
various food items in their stomachs is listed on Table 4. Copepods
apparently constitute the most significant food item, many shrimp had
their stomachs full of them; in a few cases chaetognaths or polychaetes
filled the stomach. Radiolarians were commonly present in small num-
bers. None of the other food items appears to be a very important
element in the diet. A great number of various sizes and shapes of
unidentifiable spines and tubules was found, which may have belong
to crustaceans, polychaetes, or radiolarians, but no identification of
such fragments was attempted.

In a great many cases, especially in larger specimens, the stomach
contents were in fairly good condition, which simplified the job of
identification of food items; many of the copepods were practically
unaltered. Radiolarians were usually fragmented, but were on occasion
intact; chaetognath remains took the form of intact heads or disas-
sociated hooks. The smallest specimens with any food material in the
stomach were 12 and 13 mm long; these had copepod remains, which
were generally fragmented. No correlations were found between
stomach contents, quantitative and qualitative, and seasonal, geo-
graphical, and vertical distribution, or the size of the animals.

Parasites. Two specimens had ellobiopsid parasites under the abdo-
men, a male 47 mm long, and an individual of undetermined sex, 37
mm long. The male was somewhat retarded in the development of its
secondary sexual characteristics, having a very narrow endopod on the
first pleopod, and the appendix interna only on the second pleopod,
but this may be simply coincidence.

DISCUSSION

Hymenodora glacialis is regarded as meso- and bathypelagic. Kemp
(1910) noted its occurrence from 250 to 539 m off the west coast of
Ireland. According to Heegard (1941) it is often found on the surface
in northern waters as well as in the stomachs of birds that have ap-
parently been feeding at the surface, and Squires (1957) states that it
occurs from 250 to 2000 m off west Greenland. Our findings tend to
support this pattern of vertical distribution: the species seems to be
commonest in the mesopelagic range, and somewhat less common in
the bathypelagic; and we have only a few records from the epipelagic
range — 3 specimens, including one from the surface.

It is interesting to note that the vertical distribution of this shrimp
in the Arctic supports Coachman’s (1963) conclusions concerning
Arctic water masses; that there are three layers: a surface layer of cold,

Decapods from the Arctic Basin ZeT]

Arctic water of low salinity, from the surface to 200 m; an intermediate
layer of warmer Atlantic water, of higher salinity, from 200 to 900 m,
and a layer of bottom water below 900 m, of intermediate temperature
but salinity equal to that of the Atlantic water. Hymenodora glacialis
is commonest in what would be considered the lower Atlantic water,
below 500 m, and less common in the bottom water; it is least common
in the upper layers, especially above 350 m. This would not be sur-
prising for an Atlantic form; its distribution might simply result from
the temperature and salinity characteristics of the Arctic water masses:
decrease in abundance in the bottom water could be the result of lower
temperature, and the even greater scarcity in the Arctic water, the
result of still lower temperatures and/or low salinity.

Gut content analysis of our arctic specimens confirm the findings
of Tchindonova (1959) that this species feeds on a wide variety of
things, including copepods, ostracods, chaetognaths, radiolarians,
and polychaetes, and that large specimens frequently contain whole
organisms in the stomach. Interesting though this may be, we must
avoid over-interpreting data on stomach contents of shrimp brought
in with plankton nets, as feeding on other organisms in the net is pos-
sible, while regurgitation of stomach contents could also take place.

SUMMARY

Some 137 specimens of the shrimp Hymenodora glacialis (Buchholz)
were collected by five USC marine biologists from the Arctic ice island
T-3, from June 1965 to January 1967, by means of horizontal nets,
vertical closing nets, and bottom trawls, and from the surface. An
analysis of the sampling gear showed that more shrimp were caught
when a larger mesh size was used, when towing speed was greater in
the case of vertical tows, and when the current was faster in the case
of horizontal tows.

Vertical distribution of the species was found to be similar to that
indicated by previous records, the greatest number of shrimp being
found from 350 to 1000 m, fewer from 1000 to 2000 m, records of
shrimp from greater depths being somewhat uncertain, although there
is good evidence that they were taken from the bottom; and occur-
rences of shrimp from depths under 350 m being sparse. Application
of a Chi-square test indicated that the probability of accidentally
arriving at this distribution pattern is extremely low. No seasonal or
geographical variations were found within the limits of the study, or
size variation with depth. The fact that so many shrimp were caught
over a wide geographic range seems to indicate that Hymenodora
glacialis is an important factor in Arctic ecology.

28 Bulletin So. Calif. Academy of Sciences

A study was made of changes in the secondary sexual characteristics
with the increase in size of the animal, determining that specimens
under 40 mm in length may not be classifiable as males or females. A
study of gut contents, the results of which may be taken with some
reservation, indicated that the most important food consists of cope-
pods, with chaetognaths and radiolarians also being fairly important,
although the species will take a wide variety of things. In many cases,
the gut contents were nearly intact, especially those of larger animals,
confirming a previous finding that the food is not chewed very much
before ingestion. Two of the larger specimens had ellobiopsid parasites.

ACKNOWLEDGEMENTS

Much thanks is due to Mr. Stephen R. Geiger for his many helpful
suggestions; and to the previously mentioned biologists who were
responsible for collection of the specimens. Thanks is also due to Dr.
Lowell Wayne, for his advice on the application of statistics and to
Dr. John Yaldwyn, for his helpful criticism of the manuscript, and the
use of the laboratory facilities of the Allan Hancock Foundation of the
University of Southern California is gratefully acknowledged. This
research was supported by contract Nonr 228 (19), NR 307-270
between the Office of Naval Research, Department of the Navy and
the University of Southern California; Professor John L. Mohr, Princi-
pal Investigator.

LITERATURE CITED

Bocorov, V., 1946. Zooplankton collected by the “Sedov” expedition 1937-39.
(In Russian, English summary.) Jn V. Buinitski (ed.), Trudy dreifujusjtsjei
ekspeditri glawseiomorputu na ledokoljnom parochode “TY. Sedov”, 3: 336-
370.

CoacHMaN, L. K., 1963. Water masses of the Arctic, Proceedings of the Arctic
Basin Symposium October 1962, Arctic Institute of North America, Wash-
ington, D.C. pp. 143-167.

DUNBAR, M. J. AND G. HARDING. Arctic Ocean water masses and plankton: A re-
appraisal, Jn A. Jespersen and J. E. Sater, (ed.), Proc. Arctic Drifting Sta-
tion Symposium, Arctic Institute of North America, Washington, D.C.
(in press).

HEEGARD, P. E., 1941. Decapod crustaceans. Zoology of East Greenland. Med-
delelser om Gr@nland, 121: 1-12.

Kemp, S., 1910. The Decapoda Natantia of the coasts of Ireland. Fisheries, Ire-
land, Sci. Invest., 1908, I.

Monr, J. L. AND S. R. GEIGER. Arctic Basin faunal précis — Animals taken mainly
from Arctic drifting stations and their significance for biogeography and

Decapods from the Arctic Basin 29

water-mass recognition. Jn A. Jespersen and J. E. Sater, (ed.), Proc. Arc-
tic Drifting Station Symposium, Arctic Inst. N. Amer., Washington, D.C.
(in press).

Sars, G. O., 1885. Crustacea, 1. The Norwegian North Atlantic Expedition,
1876-1878, No. 6: 1-280.

Sars, G. O., 1900. Crustacea. The Norwegian North Polar Expedition. 1893-
1896, 1 (5): 1-141.

SIVERTSEN, E. AND L. B. HOLTHUIS, 1956.

SIVERTSEN, E. AND L. B. HOLTuHuIS, 1956. Crustacea Decapoda (the Penaeidea
and Stenopidea excepted). Michael Sars North Atlantic Expedition. 1910,
5 (12): 1-54.

SquirEs, H. J., 1957. Decapod. Crustacea of the Calanus Expedition in Ungava
Bay, 1947 to 1950. J. Fish. Res. Bd. Canada 35: 463-494.

STEPHENSEN, K., 1935. Crustacea Decapoda. The Godthaab Expedition. 1928.
Meddelelser om Grgnland, 80: 31-33, 66-74.

TcHINDONOVA, J. G., 1959. Feeding of some groups of macroplankton in the
northwestern Pacific. Akademia nauk SSSR, Trudy Institut Okeanologii,
30: 166-189 [pp. 176-177 trans. from Russian].

Accepted for publication December 11, 1968.

fmeeCbETIN OF THE

Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

VOL. 68 _ APRIL-JUNE 1969 ParT 2

(ullaudimnrZzins

CIBRARY)

AUG 12 1969

NEW YORK
BOTANICAL GARDE:

CONTENTS

Another New Species of Speleocola Lipovsky (Acarina: Trombicu-
lidae) off Chiropterans from Sonora, Mexico. James P. Webb,

. Jr. and Richard B. Loomis 59

Amelogenesis in the trigger-fish Balistidae. John D. Soule 64

New Records of Marine Algae from Southern California, Anne
Mower and Thomas B. Widdowson Ne,

Stictodora ubelakeria a New Species of Heterophyid Trematode
from the California Sea Lion (Zalophus californianus). Mur-

_ ray D. Dailey 82
The Bathhouse Beach Assemblage. J. S. Bullivant 86
Watersipora arcuata, a New Species in the subovoidea-cucullata-

nigra complex (Bryozoa, Cheilostomata). William C. Banta . 96
Distribution and Development of Mysids (Crustacea, Mysidacea)

from the Arctic Ocean and Confluent Seas. Stephen R. Geiger 103
Research Notes:

Pacific Ridley Sea Turtle, Lepidochelys olivacea, in Puerto

Rico. David K. Caldwell and Donald S. Erdman 112

Hatchling Green Sea Turtles, Chelonia mydas, at Sea in the
Northeastern Pacific Ocean. David K. Caldwell 113
A Second Record of the Slender Mola, Ranzania laevis (Pen-
nant), from California. John E. Fitch 115
Some Observations on a Captive Desert Shrew, Notiosorex
crawfordi. Vincent Brach

-\

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BULLETIN OF THE SOUTHERN CALIFORNIA
ACADEMY OF SCIENCES

Vol. 68 APRIL-JUNE, 1969 No. 2

Bull. So. Calif. Acad. Sci. 68(2): 59-63, 1969

ANOTHER NEW SPECIES OF SPELEOCOLA LIPOVSKY
(ACARINA: TROMBICULIDAE) OFF CHIROPTERANS
FROM SONORA, MEXICO

JAMES P. WEBB, JR. AND RICHARD B. LOOMIS
Department of Biology,
California State College,
Long Beach

ABSTRACT: Speleocola davisi, n. sp. is described from larvae
off three bats: Glossophaga soricina leachii (type host), Lep-
tonycteris sanborni, and Desmodus rotundus murinus, from
mines near La Aduana, Sonora, México. A key is provided
for the four species of Speleocola.

INTRODUCTION

Loomis and Davis (1965) reported a single larval chigger,
identified as Speleocola secunda Brennan and Jones, from a vampire
bat, Desmodus rotundus murinus Wagner, taken in Sonora, México.
However, recent studies of the genus Speleocola revealed that this
larva and seven others from two additional kinds of bats from the same
locality represent a new species which is described below. Although
it is similar to S. secunda, it differs in several conspicuous charac-
teristics. In addition, a key to the larvae is provided for the four species
of Speleocola Lipovsky.

_ Speleocola davisi, new species
Figure 1|

Speleocola secunda: Loomis and Davis, 1965:497.

Types. — Larvae: Holotype and 7 paratopotypes from La Aduana
(8 km W Alamos), 480 m,.Sonora, México off 3 Glossophaga soricina
leachii (Gray), Pallas’ long-tongued bat, WJW630806-48 (holotype),
WJW630807-32 (3), and WJW640807-34 (2); Leptonycteris san-
borni Hoffmeister, Sanborn’s long-nosed bat, WJW630806-4 (1);
and Desmodus rotundus murinus Wagner, vampire bat, WJW630806-
26 (1), taken 6 August 1963 by R. M. Davis, R. B. Loomis and W. J.
Wrenn, or 7 August 1964 by R. E. Dingman, R. B. Loomis, L. K.

59

60 Bulletin So. Calif. Academy of Sciences

Tanigoshi and W. J. Wrenn. The holotype and one paratopotype will
be deposited in the collection of the Rocky Mountain Laboratory,
Hamilton, Montana, and some of the paratopotypes now in the chigger
research collection at California State College, Long Beach, will be
deposited in appropriate institutions.

Diagnosis. — Larva of Speleocola having sensilla with shaft ex-
panded and bearing expanded setules, pretarsala II absent, second
pair of sternal setae branched, coxa II seta nude, without lateral
humeral setae between coxa II and III, and dorsopalpotibial seta
branched. Refer to key for comparisons with other species.

Description. — Larva. Holotype (all measurements in microns,
with variations of paratopotypes listed in parentheses): Body engorged,
375 by 180, eyes 2/2, anterior larger, posterior plate and lens faintly
visible.

Dorsal setal formula 2-8-6-6-8-6-6-2-2, total 46; measurements
of dorsal humeral seta 30, seta of first posthumeral row 22, posterior
dorsal seta 19.

Ventral setal formula 2-2-6-2-8-4-8 + 30, total 62; measurements
of first sternal seta 27, second sternal seta 23, posterior ventral seta 21.

Scutum: bell-shaped, moderately punctate; sensilla with proximal
portion of shaft nude, and with distal two-thirds of shaft expanded,
bearing basally expanded setules.

Scutal measurements of holotype (with mean and extremes of the

8 types, unless otherwise noted): AW 24 (26, 24-27), PW 38 (38,
36-41), SB 12 (11, 8-12), ASB 20 (21, 19-23), PSB 17 (18, 16-20),
AP 26 (27, 26-30), AM 21 (21, 20-23), AL 17 (15, 14-17), PL 26
(255,23-26), Si3il 29& 31, 2):
Gnathosoma: cheliceral blade with small tricuspid cap; cheliceral
base and capitular sternum lightly punctate. Galeala nude. Palpal
setal formula B/B/BNB; palpotarsus with 3 branched and 3 nude
setae, and tarsala, 5; palpotibial claw with 3 prongs.

Legs with specialized setae as follows. Leg I, coxa with 1 branched
seta, 3 genualae and microgenuala, 2 tibialae and microtibiala, tarsala,
13 (14, 13-15), microtarsala, subterminala, parasubterminala and
pretarsala; leg II, coxa with 1 nude seta, genuala, 2 tibialae, tarsala
14 (14, 13-15), and microtarsala; leg III, coxa with 1 branched seta,
genuala, tibiala, and 5 mastitarsalae. All legs with seven segments
lightly punctate and terminating in 2 stout claws and clawlike em-
podium without onychotriches. Leg measurements, holotype and (in
parentheses) mean and extremes of the 8 types: I, 180 (182, 162-203);
Il, 146 (154, 144-167); III, 167 (173, 140-190); total, 493 (509,
462-558).

Figure 1. Speleocola davisi, n. sp. A. Scutum and eyes. B. Dorsal aspect of gnatho-
soma. C. Ventral view of palpal tibia and tarsus. D. Representative body setae:
PD, posterior dorsal; H, humeral; 2 St, second sternal; and 1 St, first sternal. E.
Leg I; genu, tibia and tarsus with nude and nearly nude setae, bases of branched
setae, and measurements in microns. F. Leg II. G. Leg III.

62 Bulletin So. Calif. Academy of Sciences

Remarks. — No evidence of dimorphism was found in this sample
of eight larvae of S. davisi as reported by Loomis and Webb (1969)
for the larger samples of larvae of Speleocola secunda and S. tadaridae.

The five hosts were captured in two abandoned mine tunnels in the
vicinity of La Aduana, approximately eight km west of Alamos,
Sonora. Both mines were humid and one of the tunnels contained
standing water along the entire length. The hosts of S. davisi (taken
on 6 August 1963) were captured in the tunnel having a dry floor,
according to Loomis and Davis (1965) who also reported three other
species of bats from the mines. Cockrum and Bradshaw (1963:3)
described this area as Arid Tropical Thornforest with woody plants
5-6 meters in height.

Speleocola tadaridae has been taken near Topolobampo, Sinaloa,
México, approximately 165 km to the south and from 1 km west of
Tajitos, Sonora, México, (one larva off Tadarida brasiliensis, taken
30 June 1965) which is 575 km to the northwest of the type locality
of S. davisi. The nearest record of S. secunda is from the vicinity of ~
Escarcega, Campeche, Mexico, more than 2100 km to the southeast.

All four species of Speleocola have been found predominantly
upon bats although S. secunda has been reported from rodents of the
genera Peromyscus and Nyctomys, as well as seven species of bats.
Speleocola davisi is known from three kinds of bats, S. tadaridae has
been taken only from two species of free-tailed bats of the genus
Tadarida, and S. cortezi Loomis and Webb (1969) is recorded only
from the fish-eating bat, Pizonyx vivesi.

We are happy to dedicate this new species to Mr. Richard M. Davis
in recognition of his many contributions to the studies of chiggers and
their vertebrate hosts.

KEY TO THE LARVAE OF SPELEOCOLA
Subfamily Trombiculinae, Tribe Trombiculini

i-Pretarsala Tlipresent’;. 24 224028 gas oS. eee Z
Pretarsala Il absent atc se ele oh 2 et ees 3

2. Second pair of sternal setae with several branches; AM 28-31, ;
sensilla with shaft and setules slightly expanded
(Baja: Calitomnia) ts i) i lerclicc) Se nas alae aes ae ea S. cortezi
Second pair of sternal setae nude; AM 14-19, ; sensilla with shaft
and setules greatly expanded (southern México southward to
A Mtau take \e) iW. enn een nn a SPR MDS Wen ann VTE tRE Rial eet ELAN hrs Gus os S. secunda

3. Coxa II seta branched; dorsopalpotibial seta nude; two lateral
humeral seta between coxae II and III (Oklahoma and Texas to
Sinaloa MEXICO) ees gel ul age oe em ee S. tadaridae

New Species of Chiggers 63

Coxa II seta nude; dorsopalpotibial seta branched; no lateral
humeral setae (southern Sonora, México) .............. S. davisi

ACKNOWLEDGMENTS

We are grateful to William J. Wrenn for the recovery and preparation of these
chiggers and to Lee C. Spath for the preparation of the illustrations. We also
thank Dr. James M. Brennan of the Rocky Mountain Laboratory, Hamilton,
Montana for the loan of Speleocola slides. Appreciation is extended to Sr. Dr.
Rodolfo Hernandez Corzo, el Director General, Direccion General de Caza,
Departamento de Conservacion de la Fauna Silvestre, Secretaria de Agricultura y
Ganaderia for permits to collect mammals and other vertebrates in México.
Studies upon which this paper was based were supported by the U.S. Public
Health Service Research Grant AI-03407 from the National Institute of Allergy
and Infectious Diseases.

LITERATURE CITED

BRENNAN, J. M. AND E. K. Jones. 1960. Chiggers of Trinidad, B. W. I. (Acarina:
Trombiculidae). Acarologia, 2: 493-540.

CockRuM, E. L. AND G. VAN R. BRADSHAW. 1963. Notes on mammals from Sonora,
Mexico. Amer. Mus. Novitates, (2138): 1-9.

Lipovsky, L. J. 1952. A new genus and species of chigger mite (Acarina; Trombi-
culidae). J. Kansas Entomol. Soc., 25: 132-137.

Loomis, R. B. AND R. M. Davis. 1965. The vampire bat in Sonora, with notes on
other bats from southern Sonora. J. Mammal., 46: 497.

Loomis, R. B. AND J. P. WEBB, JR. 1969. A new species of Speleocola (Acarina:
Trombiculidae), off a bat, Pizonyx vivesi, from Baja California, Mexico.
Bull. So. Calif. Acad. Sci., 68: 36-42.

Accepted for publication March 11, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 64-71, 1969

AMELOGENESIS IN THE
TRIGGER-FISH BALISTIDAE

JOHN D. SOULE
Department of Histology
School of Dentistry,
University of Southern California
Los Angeles, California 90007

ABSTRACT: The trigger-fish dentition is polyphyodont, with
attachment by a periodontal ligament similar to the perio-
dontium found in mammals, the teeth thus having a longer
functional life and a slower rate of development and eruption
than is seen in many fish. Histological studies reveal that
balistid dentin begins development prior to the appearance
of the initial enamel matrix. The reactions to a battery of
stains exhibited by the dentin and the enamel matrix are
indistinguishable from those seen in the developing teeth
of amphibians, reptiles and mammals. In the balistids, the
enamel matrix is a product of columnar ameloblasts and is
an “ectodermal enamel” rather than a “mesodermal enamel”
as has been described in other osseous fish.

INTRODUCTION

Divergent opinions exist wherein some authors, reporting on the
formation of the teeth in osseous fish, have described the enamel
matrix as a “mesodermal” derivative, while others have regarded it
as “ectodermal”. However, no histological evidence has previously
been presented that lends support to either of these concepts.

Among the early papers that dealt histologically with the origin of
enamel in the bony fish was that of C. S. Tomes (1900), who studied
tooth development in the hake (Merlucius). He found that the span
of activity of the ameloblasts was very short; these cells are rapidly
transformed into stroma that subsequently becomes mineralized to
form enamel. While the implication is clear, Tomes did not demon-
strate an enamel matrix.

Mummery, (1917) working with sparids and labrids, considered
the enamel a secretory product of columnar ameloblasts, stating, “It
is curious that, in the early stages of development in these fish, the
ameloblasts seem to exercise their functions in the same manner as
in Mammalia. From the evolutionary stand this seems a very puzzling
problem.”

J. T. Carter (1918) made a further investigation into tooth develop-
ment in the hake (Merluccius vulgaris). He reported that, after the
appearance of a thin layer of dentin, the ameloblasts produce a secre-

64

Amelogenesis in Fish 65

tory product on the dentin surface which is mineralized to form a
pointed enamel cap.

Kvam (1946), as part of a comprehensive investigation of tooth
development in fish, amphibians, reptiles and mammals, studied the
formation of enamel in eight species of bony fish. Kvam observed that
the dental crown possessed a “hard covering stratum” enamel. The
organic content of this covering, he asserts, is like dentin, formed by
the mesodermal pulp. Kvam’s findings indicated that in the bony
fish, the outer stratum of dentin calcifies to a high degree, while the
remainder of the dentin mineralizes to a lesser extent. This outer
stratum he defines as enamel “irrespective of its genesis, appearance
and structure.” Kvam draws a distinction between “mesodermal
enamel” which is formed by a secondary calcification of the dentin’s
outer stratum and “ectodermal enamel” which is deposited on the
outside of the dentin. Kvam reported that in the fish and the amphib-
ians, the hard outer stratum was “mesodermal enamel” and in the
reptiles and mammals it was an “ectodermal enamel.”

Kvam (1950) reviewed the work of other investigators and con-
tinued the study of enamel formation in the bony fish, including the
genera Labrus, Ctenolabrus, Merlucius, Anguilla and Gobius. He
reiterated his earlier stand that the osseous fish have “mesodermal
enamel”, rejected the findings of Tomes (1900), Mummery (1917),
Carter (1918) and others, and concluded by stating, “From the in-
vestigations discussed here it does not appear that there is produced
any certain evidence that the strongly calcified tip we often find on the
teeth of osseous fish is formed by the ectodermal part of the tooth-
germ.” He followed the same train of thought in later papers, (Kvam,
1953;,1960).

Kerr (1960) studied enamel formation in a number of bony fish,
including the eel (Anguilla), the trout (Salmo), cod (Gadus), pike
(Esox), and wrasse (Labrus). He found the enamel to be of the ““meso-
dermal” type, saying, “In development, the tooth substances appear
first between the i.d.e. and the pulp in the deepest part of the cup; it
forms exclusively on the deeper side of the basement membrane and
hence appears primarily at least to be a mesodermal production.” In
summary, Kerr concludes, “The formation of the enamel has been
investigated in a number of teleosts and primitive actinopterygians
and found to be of a mesodermal type with considerable similarity
to that of elasmobranchs.”

Moss, Jones, and Piez (1964) reported the results of both amino
acid analysis of the protein and histological examination of shark
(Squalus) tooth enamel and the scale of a teleost (carp). This analysis

66 Bulletin So. Calif. Academy of Sciences

Coke

eect LED ries ae

Figure 1. Above the dentin is a thin band of enamel matrix and adjacent amelo-
blasts. Note pale staining predentin and the row of odontoblasts lining the periph-
ery of the dental pulp. Hematoxylin and eosin. All photomicrographs of Balistes
bursa. Figure 2. Crown tip, showing the vascularized enamel organ with the
radial capillaries. The material between the enamel organ and the dentin is the
organic portion of the enamel matrix, hematoxylin and eosin. Figure 3. Section
stained with Mallory’s azan, showing a band of enamel matrix. Figure 4.
Schmorl’s thionin, showing the branching of the dentinal tubules. A band of
enamel matrix is present above the dentin. Figure 5. Enamel matrix as dif-
ferentiated by Soule’s gold chloride method. Figure 6. Aldehyde-fuchsin tech-
nique. Note the enamel matrix above the dentin.

Legend. A — ameloblast; D— dentin; E—-enamel matrix; O — odontoblast;
P — predentin; T — dentinal tubule; V — vascularized enamel organ.

Amelogenesis in Fish 67

showed the presence of collagens which are chemically classified as
ectodermal. This suggests that the enamel protein of Squalus, like
that of mammals, is derived from tissue of ectodermal origin. They
further stated, “The position taken by the proponents of a mesodermal
origin of shark enamel can probably be explained also by a considera-
tion of odontogenesis in the shark in particular, and in fish in general.
Unlike odontogenesis in tetrapods, the formation of the organic matrix
of dentin does not precede the formation of the matrix of enamel. In
all fish, the inner enamel epithelium of the enamel organ undergoes
cytodifferentiation very reminiscent of tetrapod amelogenesis, while
the enamel matrix is deposited centrifugally, prior to dentinogenesis.”

Provenza (1964) points out that in mammals the pre-enamel matrix
stains strongly with DNFB-H acid and stains for combined SS and
SH, it is stained a light green with Azure A at pH 4, and reacts strongly
with stains for elastic fibers.

Soule (1966), using several histological staining techniques and
autofluorescence to differentiate the developing enamel matrix in
amphibians, showed the similarity of the reactions in the amphibians
to those which occur during mammalian amelogenesis and concluded
that in amphibians, the enamel matrix is ectodermal in origin.

METHODS AND MATERIALS

Off Kaunakakai, Molokai and Pokai Bay, Oahu, six specimens of
the trigger-fish, Balistes bursa, were killed with a spear gun and their
heads immediately fixed in neutral formalin. After decalcification in
5 percent trichloracetic acid, thorough washing, dehydration, and
paraffin embedding, sections were cut at 6. and mounted in serial
groups for direct comparison. Successive slides in each grouping
were stained with hematoxylin and eosin, Mallory’s azan, aldehyde
fuchsin, peracetic acid-aldehyde fuchsin-Halmi, Soule’s gold chloride,
Verhoeff’s elastin stain, Azure A at pH 4, DNFB technique of Zerlotti
and Engel, and Schmorl’s thionin. Mammalian control material from
the foetal pig and sections of lower jaw from the trout (Salmo) were
included in each procedure. Additional balistid material from Balistes
verres and Verrunculus polylepis, from the Gulf of California, Mexico
was subjected to the same battery of stains.

RESULTS

In Balistes, as in other fish, amphibians, and reptiles there is a con-
tinuous succession of developing teeth. Thus, there is available a

68 Bulletin So. Calif. Academy of Sciences

series of tooth germs in many stages of development which facilitates
observations on the early formation of dentin and enamel.

The early tooth development in the balistids, unlike that in many
fish, takes place deep in the jaw. The developing teeth are found within
bony crypts, separated from the functional teeth by a layer of cancellous
bone. Kvam (1946) described a similar situation in Ctenolabrus
rupestris (Jago’s goldsinny).

In Balistes bursa, Balistes verres and Verrunculus polylepis a
vascularized enamel organ (Fig. 2) is present during the span of time
in which enamel is being deposited and the tooth is slowly erupting.
In its initial stages the enamel organ consists of a single layer of
columnar ameloblasts, covered by a layer of cuboidal cells which are
later restricted to the lateral aspects of the cervical crown. The cuboidal
cells have indistinct cell boundaries. The ameloblasts are tall, columnar
with dark granular cytoplasm and ovoid nuclei, located toward the
basement membrane in the cytoplasm of the cell end, away from the
developing dentin.

Covering the curvature of the developing crown, the vascularized
enamel organ shows two or three strata of epithelial cells. The outer-
most layer is reduced to a squamous epithelium which is continuous
with the cuboidal epithelium that covers the ameloblasts in the area
of the radicular dentin. Immediately beneath the squamous outer
stratum is a zone of variable thickness, composed of multiple layers
of closely contiguous cells ranging from squamous to an irregular
cuboidal morphology. This stratum is penetrated by numerous thin
walled blood vessels, many of them oriented radially. The inner
epithelial layer, adjacent to the enamel, is composed of elongated
columnar cells. These cells are exceedingly tall, with a granular
cytoplasm and ovoid nuclei whose chromatin material is finely divided
and pale in staining reaction. Carter (1918) dealing with Labrus
bergyltei and Pagellus centrodontus, Kvam (1946) in Ctenolabrus
rupestris, and Mummery (1917) in Sargus ovis and Tautoga onitis,
described a similar vascularized enamel organ.

Stained with hematoxylin and eosin, the newly formed enamel
matrix (Figs. 1, 2) appears as a narrow homogenous purple-red band
apposed to the surface of the eosinophilic young dentin. Where amelo-
genesis is in progress, columnar ameloblasts can be found; in sections
where amelogenesis is just completed the ameloblasts are reduced to
squamoid cells. Mallory’s azan stains the enamel matrix (Fig. 3)
bright red as maturation progresses, in contrast to the blue of the
young dentin.

Soule’s gold chloride technique renders the balistid enamel matrix

Amelogenesis in Fish 69

maroon-red in contrast to the pale lavender of the dentin and has
the same reaction in the mammalian control, (Fig. 5).

In the trigger-fish (Fig. 4), Schmorl’s thionin colors the enamel
matrix pale blue in contrast to the dentin matrix, which is stained pale
lavender and possesses dark purple branching dentinal tubules. These
Staining reactions were found in the mammalian controls and in
previous work carried out on amphibian material (Soule, 1966).

Aldehyde fuchsin and peracetic acid-aldehyde fuchsin techniques
stain elastic fibers and oxytalan fibers purple in color. These techniques
stained the enamel matrix (Fig. 6) purple in the balistid material as
well as in the mammalian controls.

Azure A at pH 4 rendered the enamel matrix a pale blue-green,
contrasting with the blue-purple of the dentin.

Zerlotti and Engel (1962) D.N.F.B. stain for protein, when used
on the balistid material, colored the enamel matrix a bright yellow in
contrast to a pale tan seen in the dentin, and produced a similar reac-
tion in mammalian material.

Verhoeff’s technique for elastin stains the enamel matrix dark grey
in the balistid species, and black in the mammalian controls.

DISCUSSION

While the dentition of the trigger-fish is polyphyodont, the rate of
succession, judging from histological evidence, is slow when com-
pared to that in other lower vertebrates. In the trigger-fish, sections
show fewer succedaneous teeth in various stages of development. In
the balistids there is a deep bony crypt in which tooth development
takes place, with a shelf of cancellous bone separating the developing
teeth from functional teeth. This is a common occurrence in mamma-
lian teeth but is rarely seen in the lower vertebrates. As was shown
by Soule (1969), the functional teeth in the trigger-fish are attached
by a periodontium which includes a shallow alveolar socket, a perio-
dontal ligament, and an acellular cementum apposed to the radicular
dentin. This form of tooth attachment implies a longer functional life
to the erupted teeth, a slower turn-over in the number of teeth, and
a slower rate of development and eruption.

As in the mammals, the balistid dentin begins development prior
to the appearance of the first enamel matrix. The staining reactions
exhibited by the dentin and the enamel matrix are essentially similar
to those seen in amphibian, reptilian and mammalian developing
dentin and enamel. This strongly indicates that in the balistids the
enamel matrix is a product of the ameloblasts and is an “ectodermal

70 Bulletin So. Calif. Academy of Sciences

enamel” rather than a “mesodermal enamel” as has been described
in other osseous fish. This is compatible with the findings of Moss,
Jones and Piez (1964), which showed that the enamel protein in a
shark (Squalus) is of ectodermal origin. However, their explanation
of the position of the proponents of mesodermal enamel, ie. that
amelogenesis preceeds dentinogenesis in all fish, is in variance with
the findings in the trigger-fish, where the initial dentinogenesis preceeds
amelogenesis, just as it does in mammals, amphibians and reptiles.

The enamel on the teeth of fish is a comparatively thin layer which
mineralizes rapidly during development with an early loss of stainable
enamel matrix. Coupled with the rapid sequence of tooth development
and eruption, as occurs in most fish, it is easy to understand why the
early enamel matrix is not readily found and the formation of enamel
has been ascribed to a “mesodermal” origin. When the tooth develop-
ment sequence is slower, as it is in the balistids, the formation of the
enamel matrix is also slower. While probably not as slow as it is in the
mammals, reptiles or amphibians, the rate permits demonstrating a
stainable enamel matrix with histological staining reactions com-
parable in all respects to those found in the higher vertebrates.

The possibility also exists that there are two mechanisms of dentin
and enamel formation at work; one mechanism where “‘mesodermal”’
enamel and atubular or relatively atubular dentin is formed, and a
second where “ectodermal” enamel and tubular dentin are formed.
Histological examination of sections of a jaw of the trout (Salmo)
showed a homogenous, atubular dentin and no evidence was seen of
an enamel matrix. The balistid teeth possess tubular dentin with
branching dentinal tubules like those found in mammalian teeth.
The balistid amelogenesis, with the formation of “ectodermal” enamel
is like that seen in amphibians, reptiles and mammals.

ACKNOWLEDGEMENTS

The author wishes to express his appreciation to Mr. James Smola for the pre-
paration of the slides used in this study, to Mr. James McVey and Mr. Stanley
Swerdloff of the University of Hawaii and William van Heukelem of the Oceanics
Institute for collecting the specimens of Balistes bursa, to Dr. John Stephens for
the specimens of Verrunculus polylepis and Balistes verres, and to Dr. Dudley
Thomas for the specimens of Salmo sp.

LITERATURE CITED

CarTER, J. T. 1918. On the cytomorphosis of the enamel organ in the hake. Quart.
J. Micro. Sci., n.s. 63: 387-400.

KERR, T. 1960. Development and structure of some actinopterygian and urodele
teeth. Proc. Zool. Soc. London, 133: 401-424.

Amelogenesis in Fish 71

KvaM, T. 1946. Comparative study of the odontogenetic and phylogenetic de-
velopment of dental enamel. Den Norske Tannlaegeforenings Tidende,
56: 1-198.

1950. The development of mesodermal enamel on piscine teeth. Det.
Kingelige Norske Videnskabers Selskab Trondheim: 7-115.

1953. The phylogenetic transition from mesodermal to ectodermal enamel.
Det. Kongelige Norske Videnskabers Selskabs Forhandlinger, 26 (19): 83,84.

1960. The development of the tooth tip in Triton cristatus Laur. Acta
Odont. Scandinavica, 18: 503-519.

Moss, M. L., S. J. JONES AND K. A. PIEZ. 1964. Calcified ectodermal collagens of
shark tooth enamel and teieost scale. Science, 145: 940-942.

Mummery, H. 1917. On the structure and development of the tubular enamel of
the Sparidae and Labridae. Phil. Trans. R. Soc. London, 208 (B): 251-269.

PROVENZA, D. V. 1964. Oral histology, inheritance and development. J. B. Lippin-
cott, Philadelphia: 1-548.

SouLE, J. D. 1966. Origin of the enamel matrix in developing amphibian teeth.
Bull. So. Calif. Acad. Sci., 65: 193-201.

1969. Tooth attachment by means of a periodontium in the trigger-fish
(Balistidae). J. Morph., 127 (1): 1-5.

Tomes, C. S. 1900. Upon the development of the enamel in certain osseous fish.
Phil. Trans. R. Soc. London, 193 (B): 35-46.

ZERLOTTI, E. AND M. B. ENGEL. 1962. The reactivity of proteins of some connec-
tive tissues and epithelial structures with 2, 4, dinitrofluorobenzene. J.
Histochem. Cytochem. 10: 537-546.

Accepted for publication March 11, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 72-81, 1969

NEW RECORDS OF MARINE ALGAE FROM
SOUTHERN CALIFORNIA

ANNE MOWER AND THOMAS B. WIDDOWSON*
Department of Botany,
University of California,
Los Angeles 90024

ABSTRACT: Tinocladia crassa, Sporochnus apodus, and
Dudresnaya colombiana have been found at Little Harbor,
Catalina Island. Each of these is a new record of a genus
from California.

INTRODUCTION

The southern California Channel Islands, although they have a rich
flora, have been generally neglected by phycologists, except for Dawson
(1949) and Silva (1957). A single collection made at Little Harbor,
Catalina Island, by Mr. Dennis Lees and Mr. Robert Given, on 20
November 1967, contained three single, fertile specimens of genera
not previously recorded from California: Tinocladia, Sporochnus, and
Dudresnaya. Since these three genera all have a number of species,
scattered widely in distribution throughout the world, the final identi-
fication of the Californian plants will require an examination of all
the species in each genus. The taxonomy of Tinocladia and Sporochnus,
at least, is in need of revision. However, since a single specimen is
an inadequate basis for such a revision, the Californian plants have
been identified as well as is presently possible.

Tinocladia crassa
Figure |

Tinocladia crassa (Suringar) Kylin was found on a rock outcrop
in the upper subtidal zone. This species had previously been collected
at two other localities in southern California, at La Jolla and Point
Dume. These previous collections had been identified as Eudesme
(Aegira) virescens by Dawson (1945, p. 96; specimens EYD 2059
[UC M108098], EYD 8640 [HAHF 71910], and EYD 9577
[HAHF 71924]). The record from La Jolla came from ‘“‘mid-littoral
tide pools.” The specimens collected at Point Dume were “‘on cobble
shore” and “low tide from reef.”

*Present address: Department of Biology, California State College at Long Beach,
California 90801.

72

13

New Algal Records

Ys

——)

5

S

ni SES
Pe ae ae DD

Ce
S11
=
—

Se
TI pen, = BMY

a
S&S

Qs

Figure 1. Specimen of Tinocladia crassa from southern California. a. Habit. b
Cross-section, showing differences between medulla, inner and outer cortex. c.
Cortical filament, showing unilocular sporangia in various stages of development.

Bulletin So. Calif. Academy of Sciences

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New Algal Records WS

According to Kylin (1940, p. 34), the main difference between
Eudesme J. Agardh (1882) and Tinocladia Kylin (1940) is the presence
in Tinocladia of a transition layer of sparsely branched filaments
(lower cortex) between the central axis (medulla) and the outer as-
similatory filaments (upper cortex). This transition is very abrupt in
Eudesme. In addition, Tinocladia is usually much the more robust
plant, measuring about 3 mm. in diameter against about | mm. for
Eudesme. The general habit (Fig. la) and structure (Fig. 1b) of the
Californian plants are clearly that of Tinocladia.

There are five currently recognized species of Tinocladia: T. austra-
lis (Harvey in Hooker) Kylin, 7. crassa (Suringar) Kylin, T. falklandica
(Skottsberg) Kylin, 7. irregularis (Tilden et Fessenden) Kylin, and
T. novae-zelandiae Kylin. The characteristics used in describing them
have been: the degree of branching, the overall length and width of
the plant; and the dimensions of the upper and lower cortical cells,
the medullary cells, and the unilocular sporangia. The species of this
genus appear to be poorly defined on these grounds (Womersley,
1967, p. 235), all being included in the natural range of variation
found in single populations (Bailey, 1968, pp. 139-144, Fig. 53).
As may be seen in Table I, the features of the Californian plants agree
best with the description of Tinocladia crassa.

Sporochnus apodus
Figure 2

Sporochnus apodus Harvey was collected in 30 feet of water on
shingle bottom.

The genus Sporochnus C. Agardh (1817) has a filiform main axis
which is pinnately or alternately branched, with sporangia occurring
on numerous small branchlets of determinate growth, called recep-
tacles. The similar genus Nereia Zanardini (1846) has sporangia on
small papillae; Perisporochnus Chapman (1954) has whorled branch-
ing; Bellotia Harvey (1855) has umbellate branching; Perithalia J.
Agardh (1890) lacks a clear distinction between branches of deter-
minate and indeterminate growth; and Tomaculopsis Cribb (1960)
has an unbranched main axis.

The species of Sporochnus are distinguished mainly on the mor-
phology of the mature receptacle. The species appear to be poorly
defined on these grounds (J. Agardh, 1896, p. 30), as variation across
the limits described for several species can be found on different
branches of the same plant (Earle, 1969). Three species (8. elsieae
Lindauer, S. rostratus Taylor, and S. stylosus Harvey) were described
as having receptacles with the terminal tufts of hairs on a style or stalk.

76 Bulletin So. Calif. Academy of Sciences

S. apodus Harvey has completely sessile receptacles, subcylindrical
in shape and widest at their base. S. comosus C. Agardh was described
as having subsessile receptacles, linear-lanceolate in shape. Womersley
(1967, p. 240) amplified this description by defining the length of the
pedicels as 1/2 to 1 times the length of their receptacles. The remainder
of the species of Sporochnus [S. bolleanus Montagne, S. gaertneri
(Gmelin) C. Agardh, S. moorei Harvey, S. pedunculatus (Hudson)
C. Agardh, S. radiciformis (Brown ex Turner) J. Agardh, and S.
scoparius Harvey] have receptacles with pedicels of diverse lengths.

The receptacles of the Californian Sporochnus range from sessile
near the apex of the plant (Fig. 2b) to subsessile or short pedicellate
near the base (Fig. 2c). Sporochnus with short pedicels previously
collected from Pacific Mexico has been identified as S$. pedunculatus
(Dawson, Neushul, and Wildman, 1960, p. 14; Bahia de Los Angeles,
April 21, 1962, EYD 22767 [HAHF 73968] ). Even the longest
pedicels on the Californian plant are shorter than is usual for S.
pedunculatus, and seems to refer this plant to one of the Australian
species, S. apodus or S. comosus. The features of the Californian
plant agree best with the original illustration (Harvey, 1859, Pl. 92)
and current description (Womersley, 1967, p. 239) of S. apodus, and
it is so identified.

Dudresnaya colombiana
Figure 3

One cystocarpic plant of Dudresnaya colombiana Taylor was col-
lected on a rock outcrop in 20 feet of water.

The genus Dudresnaya, in the Family Dumontiaceae (Order Cryp-
tonemiales) is very similar in its vegetative structure to a number of
other genera, such as Acrosymphyton and Thuretellopsis (same family);
Calosiphonia and Schmitzia (Calosiphoniaceae, Gigartinales); and
Gulsonia (Ceramiaceae, Ceramiales). All have a conspicuous central
filament of large cells. Each of these cells bears near its equator
(somewhat toward the distal end in Gulsonia) a whorl of four branches
which rebranch to form a corymbose arrangement of cortical filaments.
A number of rhizoidal filaments pervade the jelly-like material between
the cortex and the central filament, running more or less parallel to
the central filament (Fig. 3b). It is only when female material is avail-
able that it becomes relatively simple to distinguish between all these
genera. The auxiliary cell of the Californian plant is intercalary in a
specialized filament (Fig. 3c). The nature of this filament indicates
that this specimen belongs to a genus in the Order Cryptonemiales.
Within the Cryptonemiales, Acrosymphyton has terminal auxilliary
cells and Thuretellopsis has the internal cortical branches appearing

New Algal Records WA

in more distinct whorls than is the case with Dudresnaya and the
Californian plant. Gloiosiphonia (Family Gloiosiphoniaceae, Order
Cryptonemiales) is the only genus previously recorded from southern
California which is at all similar to the plant collected at Little Harbor.
However, in Gloiosiphonia the cortex is more coherent, forming a
continuous surface layer.

pani Me ; 1 THY eis
DRY ¢, pra p i
PPT. CI oy B
rere ee TT de
UTE Trane AR 2 en 7s, a RCE
ate WE, AONE vIees ee Tote yy tsa
rine
7 ri 75 L
‘ “He

Figure 2. Specimen of Sporochnus apodus from southern California. a. Habit. b.
Portion of secondary branch near apex of plant, showing sessile receptacles. c.
Portion of secondary branch near base of plant, showing subsessile and short
pedicellate receptacles. d. Reproductive filament from a receptacle.

78 Bulletin So. Calif. Academy of Sciences

TABLE II

Features of the Californian plant of Dudresnaya, compared with those described
for D. colombiana (Taylor, 1945, p. 162).

Feature D. colombiana Californian plant
Overall length 5 cm. 5 cm.
Maximum width 6mm. 5 mm.
Width at tip 1 mm. .5-1 mm.
Diameter axial cells (tip) 12-16u 9-1 1u
Diameter axial cells (base) 20u 15u
Diameter cortical cells 4-Ty, 4-6u
Distance between whorls 200u 140u
Taper of cortical filaments slight slight
Orders of branching 1-3 3
Shape of branch tips acute acute

Dudresnaya is currently credited with nine species: D. australis J.
Agardh ex Setchell, D. bermudensis Setchell, D. canescens J. Agardh,
D. colombiana Taylor, D. crassa Howe, D. hawaiiensis R. K. S. Lee,
D. japonica Okamura, D. minima Okamura, and D. verticillata (Velley
in Withering) Le Jolis. D. nodulosa Ercegovic has recently been trans-
ferred to Gulsonia (Feldmann and Feldmann, 1967). These species
are distinguished principally on their external morphology. Only D.
crassa, D. colombiana, and D. hawaiiensis approach the width of the
Californian plant at its widest part (Fig. 3a). Of these, D. crassa is a
relatively large plant (up to 18 cm. long) and has the auxiliary cell
near the middle of its filament (Taylor, 1950). D. hawaiiensis has
characteristic external branchlets which are short and flattened. The
Californian plant does not have flattened external branchlets (Fig. 3a)
and the auxiliary cell is usually second from the base in a branch nine
or more cells long (Fig. 3 c), so the plant does not appear to belong to
either D. hawaiiensis or D. crassa.

The type specimen of D. colombiana (Wm. R. Taylor No. 495c
[HAHF 7023]) was crushed when dried, so the gross morphological
features are now obscure. When the features of the Californian plant
are compared with Taylor’s description (Table II) of Dudresnaya
colombiana, the two specimens can be seen to be very similar. The
Californian plant appears to be a little more delicate in form, but the
differences are not great enough to suggest that it is a separate taxon.

CONCLUSION

Changing the identification of the southern Californian population
from Eudesme virescens to Tinocladia crassa has removed an extensive

New Algal Records 79

axial celli_
~

Figure 3. Specimen of Dudresnaya colombiana from southern California. a.
Habit. b. Arrangement of cortical branches around the main axis. c. Auxiliary
cell branch (stippled) with gonimoblast in early stage of development.

disjunction in the distribution of Eudesme virescens, which has been
reported from Alaska (Dawson, 1961, p. 391), southern British
Columbia, northern Washington (Scagel, 1957, p. 78), southern
California, and nowhere between. On the other hand, Tinocladia
crassa now has an amphipacific distribution in Japan and California.
The genus Tinocladia is now reported from Japan, Australasia, Pata-
gonia, and California.

Sporochnus has occasionally been reported from Pacific Mexico
(Dawson, Neushul, and Wildman, 1961, p. 78), but the genus has not

80 Bulletin So. Calif. Academy of Sciences

been recorded from elsewhere in Pacific North America. S. apodus
is a new record for the Northern Hemisphere.

Dudresnaya has not previously been recorded from Pacific North
America, the closest records being the type localities of D. hawaiiensis
and D. colombiana.

The specimens of the three species described in this paper have
been deposited in the herbarium of the Allan Hancock Foundation
(HAHF).

The authors wish to thank Dr. G. F. Papenfuss, University of
California, Berkeley for helpful criticism during the preparation of
this paper. Appreciation is also due to Dr. I. A. Abbott, Hopkins
Marine Station, Pacific Grove; Dr. A. Bailey, University of British
Columbia; Dr. S. Earle, Farlow Herbarium, Harvard University;
and Dr. H. B. S. Womersley, University of Adelaide, who read the
manuscript and commented on parts of it. Dr. P. C. Silva, University
of California Herbarium, Berkeley (UC); and the staff of the Allan
Hancock Foundation Herbarium, University of Southern California,
Los Angeles (HAHF) gave freely of their hospitality.

LITERATURE CITED
AGARDH, C. A., 1817. Synopsis algarum scandinaviae. ... Lund. 135 p.

AGARDH, J. G., 1882. Till algernes systematik... Nya bidrag. Lunds Univ.
Arsskr. 17 (4), 136 p.

1890. Till algernes systematik. Nya bidrag. Lunds Univ. Arsskr. 26 (4),

125 p.
1896. Analecta algologica. Cont. III]. Lunds Univ. Arsskr., N.F., Avd.
2,7 (2), 140 p.

BaILEy, A., 1968. Studies on the Chordariaceae (Phaeophyta) of Southern Austra-
lia. Ph.D. Thesis, University of Adelaide.

CuHapMaNn, V. J., 1954. Algae of the Three Kings Islands, New Zealand. Rec.
Auckland Inst. Mus. 4: 199-204.

Criss, A. B., 1960. Records of marine algae from south-eastern Queensland V.
Univ. Queensland Pap., Dept. Bot. 4 (1), 31 pp.

Dawson, E. Y., 1945. Notes on Pacific coast marine algae I. Bull. So. Calif. Acad.
Sci. 43: 95-101.

1949. Contributions towards a marine flora of the southern California
Channel Islands I-III. Allan Hancock Found., Occ. Pap. 8, 57 p.

1961. A guide to the literature and distributions of Pacific benthic algae
from Alaska to the Galapagos Islands. Pacific Sci. 15: 370-461.

Dawson, E. Y., M. NEUSHUL, AND R. D. WILDMAN, 1961. New records of sub-

littoral marine plants from Pacific Baja California. Pacific Naturalist
INS) 33=3.0!

New Algal Records 81

EARLE, S., 1969. Phaeophyta in the eastern Gulf of Mexico. Phycologia 9. (In
press).

FELDMANN, J., AND G. FELDMANN, 1967. Sur la synonymie de Crouaniopsis
annulata (Berthold) J. and G. Feldmann =Gulsonia nodulosa (Ercegovic)
comb. nov. Soc. Phyc. France, Bull. 11: 19-21.

Harvey, W. H., 1855. Short characters of some new genera and species of algae
discovered on the coast of the colony of Victoria, Australia. Ann. Mag.
ENIStea Sell 3552-550:

1859. Phycologia Australica. Vol. 2.

1860. Algae. In J. D. Hooker. The botany of the Antarctic voyage of
H. M. Discovery Ships Erebus and Terror, in the years 1839-1843, under
the command of Captain Sir James Clark Ross... Vol. II. Monocotyledones
and Acotyledones. p. 282-343.

INAGAKI, K., 1958. A systematic study of the Order Chordariales from Japan and
its vicinity. Sci. Pap. Inst. Algological Research, Fac. Sci. Hokkaido Univ.
4: 87-198.

KyYLIN, H., 1940. Die Phaeophyceenordnung Chordariales. Lunds Univ. Arsskr.
N.F. Avd. 2, 36 (9). 67 p.

OKAMURA, K., 1907. Icones of Japanese algae. Vol. I (4). Tokyo. Published by
the author. ,

SCAGEL, R. F., 1957. An annotated list of the marine algae of British Columbia
and Northern Washington. Nat. Mus. Canada Bull. No. 150., 289 p.

StLva, P. C., 1957. Notes on Pacific marine algae. Madrono 14: 41-51.

SKOTTSBERG, C., 1921. Marine algae |. Phaeophyceae. /n Botanische Ergebnisse
der schwedischen Expedition nach Patagonien und dem Feuerlande 1907-
1909. K.Sv. Vet.-Akad. Handl. 61 (11), 56 p.

TaYLor, W. R., 1945. Pacific marine algae of the Allan Hancock Expeditions to
the Galapagos Islands. Allan Hancock Pacific Exped. 12, 528 p.

1950. Reproduction of Dudresnaya crassa Howe. Biol. Bull. 99: 272-284.

TILDEN, J. E. AND A. P. FESSENDEN, 1931. Batrophora irregularis, a new brown
alga from Australia. Bull. Torrey Bot. Club. 57: 381-388.

WoMERSLEY, H. B. S., 1967. A critical survey of the marine algae of southern
Australia II. Phaeophyta. Australian J. Bot. 15: 189-270.

ZANARDINI, G., 1846. Sulla Desmarestia filiformis di Giacobbe Agardh e sulle
Chordariee in generale. Atti Settima Adun. Sc. Ital. [Napoli, 1845] p.
899-900.

Accepted for publication February 17, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 82-85, 1969

STICTODORA UBELAKERI A NEW SPECIES
OF HETEROPHYID TREMATODE
FROM THE CALIFORNIA SEA LION
(ZALOPHUS CALIFORNIANUS)*

Murray D. DAILEY

Department of Biology

California State College
Long Beach, California 90801

ABSTRACT: Stictodora ubelakeri sp. n. (Digenea: Heterophyi
dae) is described from the small intestine of the California
sea lion (Zalophus californianus). It differs from other
members of the genus in body size, shape and size of seminal
vesicles and absence of esophagus. This is the first report of
this genus from a marine mammal.

INTRODUCTION

While conducting a survey for helminth parasites found in the Cali-
fornia sea lion, a large number of heterophyid trematodes were
recovered from the small intestine of a female Zalophus californianus
(Lesson, 1828) found dying in Alamitos Bay, California. The sea
lion was approximately 1.5 years old and was suffering from a massive
lungworm infection.

The worms were identified as belonging to the genus Stictodora
(Looss, 1899). This genus currently contains 13 species (Yamaguti,
1958) and has been reviewed by Cheng (1951). It has also been
considered in a key constructed by Witenberg (1953). Members of
this genus have been found in the small intestine of certain piscivorous
birds, dogs, cats and experimentally in rats and mice. This is the first
report of a natural infection in a marine mammal.

MATERIALS AND METHODS

The worms were removed from the intestine, washed, fixed in AFA
(10 parts formalin, 50 parts 95 per cent ethanol, 2 parts glacial
acetic acid and 40 parts distilled water) and Bouins solution. Sectioned
worms were cut at 8, and stained with hematoxylin-eosin. Whole
mounts were stained in Semichon’s carmine or celestine blue B,
dehydrated in ethanol, cleared in xylene, and mounted in Piccolyte.
Drawings were made with the aid of a drawing tube. All measurements
are given in microns unless otherwise stated. Average measurements
are presented with ranges in parentheses.

*This study was supported by the Naval Undersea Warfare Center, Point Mugu,
Marine Bioscience Facility under Contract No. N68530-68-C-0833.

82

New Species of Trematod 83

Figure 1. Stictodora ubelakeri n. sp. A. ventral view of entire worm. B. Semi-
diagramatic enlargement of gonotyl complex. C. egg. Abbreviations used: a —
acetabulum; g — gonotyl; gp — genital pore; i — intestinal ceca; o — oral sucker;
Ov — Ovary; p— pharynx; r—seminal receptacle; s—seminal vesicle; t —
testis; vg — ventro-genital sac; vt — vitellaria.

OBSERVATIONS
Stictodora ubelakeri, n.sp.**
GicaleA Bae)
Description based on measurements from twenty-five specimens.
Diagnosis: Body pyriform, 765 (510-968), body width 370 (278-
515). Cuticle covered with scale-like spines over entire body. Oral
sucker circular and subterminal, 52 (40-67) long by 56 (47-65)
wide. Prepharynx 22 (10-47) in length. Pharynx 59 (34-78) long by
50 (39-68) wide. Esophagus lacking. Intestinal cecae extending to
posterior end of body. Gonotyl and acetabulum enclosed in ventro-
genital sac. Gonotyl oval, 101 (78-114) by 79 (65-94) wide, armed
with a semicircle of numerous, very fine spines at posterior end.
Acetabulum attached to wall of ventro-genital sac and measures 67
(52-85) long by 33 (28-37) wide in seven sectioned specimens. Genital

**This species is named in honor of Dr. John E. Ubelaker.

84 Bulletin So. Calif. Academy of Sciences

pore median, approximately at posterior of anterior one-third of
body. Testes two, at or slightly posterior to mid-body, 90 (78-104)
long by 48 (40-67) wide. Seminal vesicle large, consisting of two
chambers, one large and one small. Ovary oval, dextral, between
right testis and seminal vesicle, 99 (78-114) long by 36 (29-41) wide.
Seminal receptacle well-developed, dextral, between ovary and right
testis, frequently as large or larger than ovary. Vitellaria entirely
post-testicular extending outside cecal field. Eggs, in fixed and stained
specimens, oval, operculate, yellowish brown, 30 (29-31) long by
15 (14-16) wide.
Host: Zalophus californianus.
Location: Small intestine
Holotype and Paratypes: USNM Helm. Coll. No. 70423, 71418.
Locality: Southern California, U.S. A.

DISCUSSION

Stictodora ubelakeri does not closely resemble any one species of the
genus but has features similar to several previously described forms.
In body shape and size it is similar to S. mergi (Yamaguti, 1939) but
differs in almost all other respects. The placement of ovary, testes,
and seminal receptacle approximates that described for S. lari (Yama-
guti, 1939) and S. diplacantha (Johnston, 1942) in that all three have
the seminal receptacle located between the ovary and right posterior
testis. S. ubelakeri differs from these species in length of esophagus,
shape of seminal vesicle, type of acetabulum and gonotyl. The seminal
vesicle of S. ubelakeri resembles that described for S. sawakinensis,
(Looss, 1899) all other members of this genus have more than one
constriction. However, these two species differ in body size, esophagus
length, placement of vitellaria, placement of testes and seminal recep-
tacle. The attachment of the acetabulum to the ventro-genital sac
most closely resembles that described for S. tridactyla (Martin and
Kuntz, 1955). However, there are no other similarities between these
two species. The spination of the gonoty] consists of numerous, uniform,
fine spines covering a large, bulbous, stationary pad which extends
around the acetabulum to an unattached free surface. This feature
and lacking esophagus are unique to S. ubelakeri.

SUMMARY

A new species, Stictodora ubelakeri, is described from the small
intestine of a California sea lion, Zalophus californianus (Lesson)
1828, collected in southern California. It differs from other members
of the genus in body size, shape and size of seminal vesicle and absence

New Species of Trematod 85

of esophagus. This is the first report of this genus from a marine
mammal.

ACKNOWLEDGEMENTS

I would like to express my appreciation to Dr. Walter Martin, Department of
Biological Science, University of Southern California for his help and advice.
My sincere thanks also to Dwight Mudry and Lorraine Peterson for their
technical services.

LITERATURE CITED

CHENG, H. T. 1951. Stictodora maniliensis and Stellantchasmus falcatus from
Hong Kong, with a note on the validity of other species of the two genera
(Trematoda: Heterophyidae). Lingnan Sci. J. 23: 165-175.

JOHNSTON, T. 1942. Trematodes from Australian Birds. I. Comorants and Darters.
Tr. Roy. Soc. Australia 66: 226-242.

Looss, A. 1899. Weitere Beitrage aur Kenntnis der Trematodenfauna Aegyptens,
zugleich Versuch einer naturlichen Gliederung des Genus Distomum Retzius.
Zool. Jahrb. Syst. 12: 521-784.

MarTIN, W. E. AND R. E. Kuntz. 1955. Some Egyptian Heterophyid Trematodes.
J. Parasitol. 41: 374-382.

WITENBERG, G. 1953. Notes on Galactosomum and related genera (Trematoda:
Heterophyidae). Thapar Commemoration Vol. Hebrew University, Israel.
pp. 293-300.

YAMAGUTI, S. 1939. Studies on the helminth fauna of Japan. Pt. 25. Trematodes
of Birds, IV. Jap. J. Zool. 8: 129-210.

1958. Systema Helminthum. Vol. 1. The Digenetic Trematodes of Verte-
brates. Interscience Publishers Inc. New York.

Accepted for publication February 25, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 86-95, 1969

THE BATHHOUSE BEACH ASSEMBLAGE

J. S. BULLIVANT
New Zealand Oceanographic Institute,
Department of Scientific and Industrial Research,
Wellington, New Zealand.

ABSTRACT: The Lower Pleistocene, Bathhouse Beach locality,
Santa Barbara, California, was examined. The described
fauna of molluscs, bryozoans, foraminiferans, ostracods and
brachiopods was reviewed and latitude range and depth
distributions noted. The bulk of the fauna with perhaps the
exception of the foraminiferans occurs off the coast of Cali-
fornia today and the affinity of the fauna is decidedly with
the Recent Californian rather than with the Aleutian or
Panamic provinces.

The cyclostome bryozoan Diaperoecia californica was
so abundant in the deposit as to give it the character of a
biostrome. The bulk of the sediment in the deposit was
carbonate, the remainder silt. The biostrome was in a region
of slow sedimentation, away from the shoreline. Its top in
36.6-54.9 m was capped by coralline algae which provided a
substrate for the bryozoan.

INTRODUCTION

The Bathhouse Beach site at Santa Barbara has been mentioned in
several studies of the Tertiary geological history of Southern California
and the main fossil groups have been examined and the species listed
by different authors.

The site is a bluff over 30 feet high which is cut back by a road at
the western end of the beach boulevard at Santa Barbara. The silty
sediment is richly fossiliferous, consisting mainly of variable amounts
of molluscs and bryozoans in places cemented into lenses. While
examining the bryozoa the author observed that the species which
was by far the most abundant was Diaperoecia californica, a twiggy
clump-forming cyclostome. This species occurs at present off the
coast of California attached to rocks or calcareous algae. The apparent
absence of a suitable substrate for D. californica at Bathhouse Beach
prompted the author to examine the deposit and the known fauna in
an effort to reconstruct the palaeoecological situation.

Some authors (Arnold, 1903; Bailey, 1935; Woodring, Stewart
and Richards, 1940; Woodring, Bramlette and Keen, 1946) assign
the site to the lower Pleistocene, while others (Arnold, 1907; Smith,
1912; 1919; Waterfall, 1929; Grant and Gale, 1931) assign it to the
Upper Pliocene.

Keen and Bentson (1944) give a good description of the Santa

86

Pleistocene Invertebrates 87

Barbara formation to which the site belongs and consider the Pliocene
— Pleistocene boundary cuts through the lower member of this
formation which includes bryozoan beds such as that exposed at
Bathhouse Beach. This lower member, recognized by Bailey (1935),
was thought by Woodring, Bramlette and Keen (1946) to represent a
shallow water facies.

Records of the fauna of Bathhouse Beach are scattered, Arnold
(1903, 1907) and Berry (1908), list molluscs, a brachiopod and also
an echinoderm. Arnold (1907) also figures a collection of bryozoa
and Soule and Duff (1957) give a more complete description of the
bryozoa. Lownes (1959) lists Foraminifera and Le Roy (1943) and
Crouch (1949) have described ostracods while Hertlein and Grant
(1944) mention some brachiopods.

FAUNA
Mollusca

Arnold (1907) and Berry (1908) list 68 mollusc species of which
Grant and Gale (1931) question the identity of one, the Mexican
Tritonalia perita. Of the 67 species, 3 are not reported as Recent and
one, Lora turricula schneideri is questionably reported Recent from
Granite Cove, Port Althorp, Alaska. Two additional species are newly
listed in this paper.

Sixty-one of the .65 Recent species which occur at Bathhouse Beach
have been reported from the Californian Province (between Puget
Sound and Cape San Lucas, Schenk and Keen, 1936). Thirty-eight of
these extend into the Aleutian Province north of Puget Sound and 4
into the Panamic Province. Four species are confined at the present
time to the Aleutian Province. These are: Odostomia avellana Car-
penter, Pecten caurinus Gould, Pecten beringianus Middendorf,
Margarites optabilis Carpenter var. knechti (Arnold).

Unfortunately there is little published information on the depth
distribtion of the West Coast molluscs. Burch (1941, et seq.) gives
depths at which species have been dredged by collectors particularly
off Redondo Beach and Monterey. It appears that most of the Bath-
house Beach species have been collected along the shore, but three
have only been taken by dredging.

Neptunea tabulata (Baird); 46-218 fathoms, Grant and Gale (1931);

30 fathoms, Burch (1941 et seq.).

Nemocardium centifilosum (Carpenter); 10-75 fathoms, Burch

(1941 et seq.).

Puncturella delosi Arnold, 12 fathoms and 67-81 fathoms, Burch

(1941, et seq.).

88 Bulletin So. Calif. Academy of Sciences

Of the remainder, 43 species were dredged down to 20 fathoms, 27
down to 30 fathoms. No doubt a thorough analysis of benthic surveys
in the future will reveal a truer picture of depth distribution.

Of considerable interest is the description by Jones (1964) of a
benthic community, the Amphiodia-Cardita community on the shelf
between Pt. Conception and Pt. Hueneme. The dominants are the
ophiuroid Amphiodia urtica and the pelecypod Cardita ventricosa,
also abundant is the gastropod Bittium subplanatum and among other
molluscs Psephidia lordi. Unfortunately the spatial distribution of
this community is not given, but its depth range is indicated by Jones
and Barnard (1963), to be 38-54 fathoms.

Cardita ventricosa, a species of Bittium, and species of Psephidia
are abundant in certain samples from the Bathhouse Beach deposit.
These samples were taken from the top 11 feet of a portion of the
deposit on the seaward side of the road which has since been replaced
by a car park.

Arnold (1907) lists Bittium asperum and Bittium catalinensis from
Bathhouse Beach. A comparison of the Bittium species obtained by
the author from the site with specimens of Bittium subplanatum
from the Amphiodia-Cardita community revealed that the two were
similar but the fossil form was more heavily sculptured with generally
an additional cord on the summit of each whorl.

Grant and Gale (1931) regard Psephidia barbarensis Arnold from
Bathhouse Beach as a subspecies of P. lordi. An examination of
specimens of Psephidia from Bathhouse Beach revealed three forms,
a small oval form and a larger more trigonal form are taken to be
P. ovalis and P. lordi respectively, while the third form bears obvious
rather irregular concentric sculpture and differs slightly in the hinge
and is taken to be P. cymata Dall. P. ovalis and P. cymata are new
records for the locality.

Bryozoa

Arnold (1907) lists and figures 16 species of which 7 were again
recorded by Soule and Duff (1957). Soule and Duff (1957) list 25
species and one subspecies from Bathhouse Beach. Of these species
and subspecies one is only known from the Pleistocene of California
and one is only found living off the Isle of Guernsey. Twenty-three
occur at present off the coast of California, 5 extend into the Aleutian
province, 20 extend into the Panamic province and 1 occurs only in
the Panamic province and the tropical Atlantic and | species and its
subspecies is confined to the Californian province.

Of the 22 species and subspecies for which depth data are given,

Pleistocene Invertebrates 89

20 species have been taken in depths down to 80 fathoms, 7 have not
been taken in less than 6 fathoms.

Ostracoda

Le Roy (1943) described 14 species and subspecies of ostracods
from Bathhouse Beach. Crouch (1949) found 13 of these species and
subspecies and in addition 4 other species. The author examined a
small sample for ostracods and found 10 of the species and subsnecies
described by Le Roy including Bairdia verdesensis not noted by
Crouch, as well as Cythereis diegoensis noted by Crouch and not
Le Roy and Catwella semitranslucens Crouch a new record.

Benson (1959) has described the distribution of recent ostracods
in Todos Santos Bay and the Estero de Punta Banda, Baja California.
He divides the fauna into estuarine, saltwater lagoon and marsh,
rocky tide pool and 4 open bay biofacies. Thirteen species and sub-
species of the 19 species and subspecies of ostracods from Bathhouse
Beach occur in this fauna. Most of the species described by Benson
belong to his Biofacies I. “Its distribution is believed to reflect the
medium and fine sandy substratum, a mild temperature variation, and
the known and supposed plant distribution.” This biofacies extends
from shallow water at least to 30 fathoms. Benson lists 10 species
characteristic of this.eenvironment, 5 of these are found in the Bathhouse
Beach fauna.

In addition the most abundant ostracod in the sample examined
from Bathhouse Beach was Loxoconcha lenticulata which occurs
abundantly in the Estero de Punta Banda saltwater lagoon and salt
marsh biofacies, in the tide pools and in Biofacies I. Its depth range is
given as 0-30 fathoms and it occurs on all bottoms but seems to be
especially associated with coralline and “spongy” algae.

Foraminifera

Lownes (1960) includes a list of foraminiferans from Bathhouse
Beach examined by Preston Jones, and describes them as a “definite
Pleistocene Assemblage.” The list includes 64 species and gives some
idea of their abundance.

Natland (1933) and Bandy (1953) have delimited zones off the
coast of California on the basis of characteristic groups of foraminifera.
The greatest affinity of the Bathhouse Beach fauna appears to be with
the Cassidulina fauna extending from 125-600 feet off San Pedro
and San Diego. But the shallower water Elphidium translucens and
Cibicides fletcheri were also abundant.

Natland named 212 species from a transect between San Pedro and

90 Bulletin So. Calif. Academy of Sciences

Species Depth Range fathoms Locality
O 50 100 150

Trifaring baggi
Cibicides fletcheri
Cibicides gallowayi
Cassidulina californica
Cassidulina limbata

Elphidium translucens

N4ANRHM HW AAN WH
ZWEZWE F MWS EF

Planulina ariminensis

Figure 1. Seven of the most common foraminifera, the present day depth distribu-
tion of which has been reported. Localities, Santa Monica Bay (SM) and Todos
Santos Bay (TS). Cross marks occurences of living animals.

Catalina Island and from Pliocene-Pleistocene deposits in Hall Can-
yon, Ventura, California. Thirty-one species in the Bathhouse Beach
fauna occur in Natland’s fauna.

The shallow water foraminiferan assemblages off Catalina Island
described by McGlasson (1959) are not well represented at Bathhouse
Beach.

Walton (1955) has studied in some detail the foraminiferan com-
munities in Todos Santos Bay and Estero de Punta Banda, while
Zalesny (1959) has examined the distribution of Foraminifera in
Santa Monica Bay. Both authors separated living and dead specimens,
but Zalesny does not distinguish them in his faunal list. It is apparent
from Walton’s work that living specimens have a narrower range
and occur at the top of the range of dead specimens of a given species.
_ Walton names 64 species which include 5 tentative assignations
occurring between 3-620 fathoms. Zalesny names 89 species extending
from 6.5-460 fathoms. Thirty-three species are common to both
localities. Of the Bathhouse Beach fauna only 10 species were listed
from Todos Santos Bay by Walton and 15 from Santa Monica Bay by
Zalesny 8 occurred at both localities. The figure gives ranges of the
7 species common at Bathhouse Beach which occurred either living
and dead in Santa Monica Bay or living in Todos Santos Bay.

Owing to the few species in common, it is not possible to assign
the Bathhouse Beach fauna to any of Walton’s facies.

Brachiopoda

Hertlein and Grant (1944) note three species of brachiopods from
Bathhouse Beach. Glottidia albida ranges through Californian and

Pleistocene Invertebrates 91

Panamic provinces. Jones and Barnard (1963) have studied its dis-
tribution with respect to depth, bottom type and associated animals
on the Southern Californian shelf. It occurs in depths between 0-90
fathoms. Morrisia hornii has only been reported from the Californian
province on the West Coast, in depths down to 200 fathoms. The
author found it to be common in the deposit. Terebratalia transversa
caurina which occurs from Alaska to Lower California was also
reported.

Echinodermata
Both Arnold (1903, 1907) and Berry (1908) report Strongylocen-
trotus purpuratus (“Several nearly perfect tests —’, Arnold, 1903).

This is a recent species common along the Californian Coast.

Polychaeta

A spirorbid worm tube was noted attached to some of the Dia-
peroecia branches. It is probably an undescribed Laerorbis (Hartman,
pers. comm.).

Coralline Algae

Pieces of nodulous coralline algae about 2 cm in diameter were
found limited to a layer 1-2 feet thick at the top of the deposit on the
north side of the road. The algae are either Lithothamnion or
Lithophyllum.

Sediment

No complete sediment analysis was run, but three samples from
the bottom, middle and top of the deposit were wet sieved.

Particle Size Top % wt. Middle % wt. Bottom % wt.

over 1.0mm | 13.2 523) Sel

1.0-0.061 mm 62.0 25.8 2550
under 0.061 mm 24.8 58.9 59.9

The sample from the top contained mainly molluscs. The other
two samples resemble each other and are probably typical of the bulk
of the deposit. The coarse fraction (15%) was made up of Bryozoa and
the medium fraction (25%), Bryozoa and Foraminifera.

Addition of acid to the coarse and medium fractions from the
bottom sample left a very small residue of fine quartz grains. Weighing
a sample of the fine silt fraction from the bottom sample before and
after addition of dilute acid indicated 24.2% carbonate.

oO Bulletin So. Calif. Academy of Sciences

DISCUSSION

The following interpretation emerges from the above remarks on the
fauna and sediment. The sediment is largely calcareous and the
non-calcareous fraction is silt. This suggests the site was some distance
from the shore line and probably elevated as a bank.

The absence of littoral molluscs (Littorina, Tegula, Haliotis, Mytilus,
Olivella, Donax) confirms the absence of a nearby shoreline. What
little is known of the depth distribution of the Mollusca indicates a
depth of between 35-55 fathoms at which the sediment was laid down.

The depth distribution of the bryozoans, ostracods and brachiopods
throws little additional light on this estimate; although the ostracods
may indicate a slightly shallower depth.

More is known of the depth distribution of foraminiferans than of
ostracods off this coast. However the depth zones as indicated by
dead foraminiferans are fairly wide. A depth range of 20-100 fathoms
is suggested for the Bathhouse Beach forams. At least two or three of
the species probably lived in about 20 fathoms (e.g. Cibicides gal-
lowayi, Elphidium translucens).

Smith (1919) has discussed the climate of the Tertiary and Quater-
nary of California in terms of the faunas. “The Lower Pleistocene
(lower San Pedro) shows the entire coast, from Alaska to San Diego,
in the grip of the cold northern climate, a southward shifting of the
isotherms of at least a thousand miles, and a general lowering of
temperature by about 12°F. as far south as Los Angeles.”

Such a large difference in climate is surprising in view of the fact
that the Bathhouse Beach fauna is so well represented off the coast of
California today. Four of the molluscs are now restricted to the
Aleutian province but the bryozoans have a stronger relationship
with the Panamic fauna than the Aleutian fauna. It must be remem-
bered also that changes in a species range may result from the action of
factors other than climate, for example, competition and sedimentation.

Should climate have affected depth distribution, then a shallower
depth estimate for the assemblage may be indicated.

As already mentioned the abundance of bryozoans, particularly
Diaperoecia californica, in the fauna suggests the presence nearby
of a hard substrate. No doubt many of the encrusting bryozoans e.g.
Malusia, Microporella, Smittina, were attached to shells and this was
indeed observed, however, the mass of Diaperoecia must have been
attached to some other substrate. There seem to be two possibilities.
Either the Miocene shale which underlies the formation outcropped
nearby, or else the bank was capped by coralline algae. No fragments

Pleistocene Invertebrates 93

of shale debris were found, but coralline algae did occur near the top
of the beds. This bryozoan has been observed living attached to
coralline algae.

The interpretation that emerges then, is that there was a bank
rising to 20-30 fathoms in a region of slow sedimentation. The physical
factors of the marine environment were much as they are today al-
though the temperature was perhaps a little lower. Coralline algae on
top of the bank provided a substrate for bryozoans, particularly
Diaperoecia which was so abundant as to form a biostrome. Other
algae occurred on the bank as evidenced by the presence of Acmaea
insessa, Strongylocentrotus purpuratus and the ostracod Loxoconcha
lenticulata.

On the slopes of the bank, represented by the exposed portion at
Bathhouse Beach, the fallout of bryozoan fragments, mollusc shells,
foraminiferan and ostracod shells formed the bulk of the sediment.

Pectens and the large venerid Humilaria perlaminosa perlaminosa
were common and a Cardita-Bittium association probably existed
close by, finally moving in over the bank.

ACKNOWLEDGMENTS

This study was carried out while completing the degree of Doctor of Philosophy
in biology at the Univesity of Southern California, Los Angeles, California. The
author is grateful for the advice given by Dr. William E. Easton during the study
and thanks Mr. J. W. Brodie, Director, New Zealand Oceanographic Institute,
for editing the manuscript.

LITERATURE CITED

ARNOLD, R., 1903. The paleontology and stratigraphy of the marine Pliocene and
Pleistocene of San Pedro, California. Mem. Calif. Acad. Sci., 3: 420 p.

ARNOLD, R., 1907. Geology and oil resources of the Summerland District, Santa
Barbara County, California. U.S. Geol. Survey. Bull. 321: 93p.

BaILEyY, T. L., 1935. Lateral change of fauna in the Lower Pleistocene. Geol. Soc.
Amer. Bull. 46: 489-502.

Banpy, O. L., 1953. Ecology and paleoecology of some California Foraminifera.
Part I. The frequency distribution of recent Foraminifera off California.
Jour. Paleonotology. 27: 161-203.

BENSON, R. H., 1959. Ecology of Recent ostracodes of the Todos Santos Bay
region, Baja California, Mexico. Univ. Kansas Paleontological Contrib.,
Arthropoda, Art. 1, 80p.

Berry, S. S., 1908. Miscellaneous notes on Californian mollusks. Nautilus.
22) 37-9.

94 Bulletin So. Calif. Academy of Sciences

Burcu, J. Q., 1941-1946, Distribution list of the West American marine mollusks
from San Diego, California, to the polar sea (and other notes): Minutes
Conch. Club So. Calif. No’s 1-63.

Croucu, R. W., 1949. Pliocene Ostracoda from Southern California. Jour.
Paleontology. 23: 594-99.

Grant, U. S. IV, aND H. R. GALE, 1931. Pliocene and Pleistocene Mollusca of
California. Memoirs San Diego Society of Natural History. 1: i036 p.

HERTLEIN, L. G. anD U. S. Grant, 1944. The Cenozoic Brachiopoda of western
North America. Publ. Univ. Calif. Los Angeles, Math. and Phys. Sci.
3: 236 p.

JONES, G. F., 1964. The distribution and abundance of subtidal benthic Mollusca
on the mainland shelf of Southern California. Malacologia, 2: 43-68.

Jones, G. F. AND J. L. BARNARD, 1963. The distribution and abundance of the
inarticulate brachiopod Glottidia albida (Rinds) on the mainland shelf of
Southern California. Pacific Naturalist. 4: 27-52.

KEEN, A. M. AND H. BENTSON, 1944. Check list of California Tertiary marine
Mollusca. Geol. Soc. Amer. Spec. Pap. 56, 280 p.

LE Roy, L. W., 1943. Pleistocene and Pliocene Ostracoda of the coastal region
of Southern California. Jour. Paleontology. 17: 354-73.

Lownes, R. E., 1959. Geology of portions of the Santa Barbara and Goleta
quadrangles, California. M..S. Thesis, Geology Dept., Univ. of So. Calif.
75 p.

McGriasson, R. H., 1959. Foraminiferal biofacies around Santa Catalina Island
California. Micropaleontology, 5: 217-240.

NATLAND, M. L., 1933. The temperature and depth distribution of some Recent
and fossil Foraminifera in the Southern California region. Scripps Inst.
Oceanogr. Bull. tech. ser. 3: 225-30.,

SCHENK, H. G. anD A. M. KEEN, 1936. Marine molluscan provinces of western
North America. Proc. Amer. Phil. Soc. 76: 921-38.

SmiTu, J. P., 1912. Geologic range of Miocene invertebrate Fossils of California.
Proc. Calif. Acad. Sci. ser. 4, 3: 161-82.

SMITH, J. P., 1919. Climatic relations of the Tertiary and Quaternary faunas of
the California region. Proc. Calif. Acad. Sci. ser. 4, 9: 123-173.

SouLE, J. D. anD M. M. Durr, 1957. Fossil Bryozoa from the Pleistocene of
Southern California. Proc. Calif. Acad. Sci. 29: 87-146.

WATERFALL, L. N., 1929. A contribution to the paleontology of the Fernando
Group, Ventura County, California. Univ. Calif. Publ. Geol. Sci. 18: 71-92.

WALTON, W. R., 1955. Ecology of the living benthonic Foraminifera, Todos
Santos Bay, Baja California. Jour. Paleontology. 29: 952-1018.

WoonrIinG, W. P., M. N. BRAMLETTE AND W. S. W. KEw., 1946. Geology and
Paleontology of Palos Verdes Hills, California. U. S. Geol. Survey, prof. pap.
207, 201 p.

Pleistocene Invertebrates 95

WoopRING, W. P., R. STEWART AND R. W. RICHARDS, 1940. Geology of the
Kettleman Hills Oil Field, California. U. S. Geol. Survey, prof. pap. 195.
170 p.

ZALESNY, E. R., 1959. Foraminiferal ecology of Santa Monica Bay, California.
Micropaleontology, 5: 101-26.

Accepted for publication March 20, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 96-102, 1969

WATERSIPORA ARCUATA, A NEW SPECIES
IN THE SUBOVOIDEA-CUCULLATA-NIGRA COMPLEX
(BRYOZOA, CHEILOSTOMATA)

WILLIAM C. BANTA
Department of Biological Sciences
University of Southern California

Los Angeles, California, 90007

ABSTRACT: A new species, Watersipora arcuata, is proposed
for the species usually identified as W. nigra Soule (1961),
which differs from the holotype of Pachycleithonia nigra
Canu and Bassler (1930) in its smaller size, an arcuate proxi-
mal border to the aperture, the distribution of interzoidal
communication pores, possession of a basal window, and in
other respects. A synonomy and detailed description of the
species and its variations is given. The type locality is in San
Diego, California.

INTRODUCTION

Hastings (1930) described several morphological variants of a species
complex she designated Watersipora cucullata (Busk), commenting
that the complex probably consisted of several species. Among the
forms involved was one with an arcuate, concave proximal border
to the aperture and operculum (Hastings, 1930, pl. 15, fig. 101).
Osburn (1952) considered this form a subspecies of W. cucullata.
Since the type was not available at the time (D. F. Soule, pers. comm.,
1968), Osburn presumed that the form was identical to Pachycleithonia
nigra Canu and Bassler (1930) and named it W. cucullata, var. nigra
(Canu and Bassler). Soule (1961) agreed with Osburn’s generic place-
ment of the form, but raised it to species rank, designating it Water-
sipora nigra (Canu and Bassler). Hastings (in litt. to D. F. Soule, 1964)
compared the type specimen of Busk’s Lepralia cucullata to Soule’s
specimens and agreed the species are distinct.

At the suggestion of Dr. J. D. Soule, Dr. D. F. Soule and Miss P. L.
Cook (see also Cook, 1968: 184), I have examined the type specimen
of P. nigra Canu and Bassler and concur that W. nigra Soule (1961)
is a distinct species; a new name, Watersipora arcuata, is therefore
proposed, referring to the characteristic concave proximal border of
the aperture.

Watersipora arcuata, new species
Figures 1-4

Watersipora cucullata (Busk): Hastings 1930: 729, pl. 15, fig. 101 (in
part). Galapagos Islands. [Not Lepralia cucullata Busk 1854: 81].

96

New Species of Bryozoa 97

Watersipora cucullata (Busk), var. nigra (Canu and Bassler): Osburn
1952: 473, pl. 56, figs. 3, 5. Gulf of California. [Not Pachycleithonia
nigra Canu and Bassler, 1930: 24].

Watersipora cucullata (Busk): Wisley 1958: 363, fig. 1. Australia.

Watersipora cucullata (Busk): Skerman 1960a: 615, fig. 1; 1960b: 620,
figs. New Zealand.

Watersipora nigra (Canu and Bassler): Soule 1961: 47. Gulf of
California.

Watersipora nigra (Canu and Bassler): Soule and Soule 1964: 35,
figs. 11 and 12. Western Baja California.

Watersipora nigra (Canu and Bassler): Banta 1968: 497, pl. 1, figs.
1-9; 1969a; 1969b. California.

Type locality. Southwestern Yacht Club Marina, near Point Loma,
San Diego Bay, San Diego, California. Specimens collected alive
January 19, 1967, by the author from floating dock facilities.

Holotype. Colony fragments fixed in 10 per cent formalin in sea
water and preserved in 70 per cent ethanol; deposited at the Allan
Hancock Foundation, University of Southern California, Los Angeles.
AHF bryozoan type 155.

Paratype. Colony fragments at the British Museum (Natural History).
Some material is retained in the author’s collection.

Diagnosis. A watersiporid ascophoran cheilostome without spines,
avicularia or ovicells, forming encrusting unilaminar or multilaminar
colonies. Frontal wall single-layered, tremocystal, perforated by 2-3
pairs of intrazoidal septulae, which are sometimes calcified, located
in zoecial corners. Hypostega overlain by a darkened ectocystal
epitheca; cellular parts orange-red. Embryos are brooded internally
in an evagination of the vestibule. Autozoids monomorphic, possessing
a proximally concave (involute) border to the aperture and operculum.
Peristome imperforate, thin; periopercular ring and opercular lucidae
present. Roughly half the basal surface is occupied by an uncalcified
ectocystal basal window.

Description. Colonies are usually loosely encrusting and may be
unilaminar or multilaminar. Opercula and epithecae of older zoids
are dark reddish brown or black; cellular parts are orange-red. Young
zoids have a transparent cuticle, so distal edges of the colony are
bright brick red. The red pigment fades to brown in preservatives
(Banta, 1968). Colonies may be very large; at the type locality, some
masses attain the size of a man’s head.

Sizes of zoecia and their apertures are variable, and the variations
may be statistically significant, even between different colonies taken
from the same locality. Unless otherwise stated, the measurements

98 Bulletin So. Calif. Academy of Sciences

given below are those of type specimens and are based on 30 measure-
ments; the range of measured values and the standard deviation (c)
are given in parentheses.

Zoecia average 910y (740-1115u ; = 8.5) long by 380, (320-460, ;
o =4.4) wide. Apertures average 225, (190-250, ;o=1.1) wide
and 200u (170-220, ; «= 0.88) long.

The frontal wall, which is overlain by a dark epitheca, is a one-
layered calcareous septum, usually called a tremocyst by bryozoologists
(Mawatari, 1952; Osburn, 1952; Soule, 1961; Canu and Bassler,
1920: 47). It is perforated by approximately 150 pseudopores 18-28,
in diameter and by 2-3 pairs of intrazoidal communication organs
(Banta, 1969a; a report on the histology and development of these
organs is in preparation). One or occasionally two pairs of intrazoidal
septulae are located lateral to the aperture at about the level of the
cardelles; another pair is located in the extreme proximo-lateral
corners of the zoecium (Figs. 1, 3, dis, pis). Intrazoidal septulae are -
usually uncalcified and therefore almost indistinguishable from pseu-
dopores in KOC1-treated material. They may be calcified, in which
case each is represented by a pore plate perforated by 1-5 communi-
cation pores (Fig. 3, dis).

The anter of the aperture is approximately semicircular. The
cardelles are triangular, blunt, and are sunk slightly below the level
of the peristome, which is thin and imperforate (Figs. 1, 3, per). The
proximal margin of the poster is concave rather than convex, as is
usual in the Cheilostomata.

The operculum has the same shape as the aperture (Fig. 2; Banta,
1968, Fig. 1). Preserved opercula are dark reddish-brown as seen by
transmitted light. There are two main sclerites: (1) a thin marginal
sclerite at the distal border of the porta (Fig. 2, msc); and (2) a pair of
longitudinal connecting sclerites (/sc). The longitudinal sclerites are
extended laterally at the junction of the porta and vanna; inosculation
of fibrils between the skeletal matrix and the cuticle of the opercu-
lum occurs at the distal border of these lateral projections (Banta,
1968: 501). A pair of tiny lucidae, characteristic of watersiporids, is
borne on the proximal part of the vanna (Figs. 3, 4, Ju). The operculum
is surrounded by a narrow periopercular ring (Banta, 1969b).

Each zoecium is provided with approximately 8 (6-9) lateral
multiporous pore plates. There are about 8 (5-10) transverse pore
plates distributed near the lateral edges and base of the transverse
wall. The basal wall is incompletely calcified; a large oval cuticular
area, the basal window, occupies about half its surface (Banta, 1968,
Figs. 2, 4, 9).

New Species of Bryozoa 99

ee car) ((
/ i cup) O
es ic

(Ges per

Fistres 1-4. Watersipora arcuata, new species. |. Frontal ew of KOC1-treated
Zoecia; paratype; scale A. 2. Operculum of the same, viewed by transmitted
light; scale B. 3. Frontal view of KOC1-treated zoecia of a variant form collected
at Oceanside, Califonia; Scale A. 4. Operculum of the same, viewed by trans-
mitted light; scale B. Figures 5-7. Pachycleithonia nigra Canu and Bassler. 5.

perture and peristome of holotype; scale C. 6. Dry, somewhat shriveled opercu-
um of the same; scale C. 7. Aperture and peristome, after Canu and Bassler,
text-fig. 6.

Abbreviations: car, cardelles (“condyles” of Canu and Bassler); cup, “cup”,
illustrated without explanation by Canu and Bassler; dis, distal intrazoidal septula;
Isc, lateral sclerite; /u, lucida; msc, marginal sclerite; per, peristome; pis, proximal
intrazoidal septula; psp, pseudopore.

100 Bulletin So. Calif. Academy of Sciences

Variations. Watersipora arcuata is moderately variable. Three
specimens collected at Oceanside, California, for example, are espe-
cially distinct from the holotype. Zoecia are proportionately broader
(Fig. 3), measuring about 990, (750-1375u ;0=4.9) long by 620u
(450-750, ;o= 8.7) wide. Apertures and opercula are almost exactly
the same sizes as those of the holotype, measuring 225, (210-240, ;
«= (0.99) wide by 180, (175-190, ;7= 0.48) long, but its opercula are
darker and thicker (Fig. 4).

I have examined specimens of Watersipora from Waitemata Harbor,
Auckland, New Zealand, presented to me by Mr. D. P. Gordon, and
consider them identical to specimens of W. arcuata from San Diego.

Affinities. Watersipora arcuata resembles the holotype specimen
of Pachycleithonia nigra Canu and Bassler 1930 (US N M no. 8496)
in possessing dark reddish brown opercula with lucidae, in having an
evenly-perforated single-layered frontal wall, and in lacking spines,
avicularia, and ovicells. Epithecae of the holotype are mostly torn
away, remaining only near the edges; they are colorless. Canu and
Bassler (1930: 25) indicated that epithecae of P. nigra are “black”
[italics theirs]. The dark color has apparently been lost.

Differences between the two species are obvious. Zoecia of P.
nigra are very large, measuring about 1700, (1500-2100, ) long by
1000, (800-1500, ) wide. The peristome is much heavier and thicker
than in W. arcuata (Fig. 5).

Apertures of P. nigra are roughly skull-shaped and are slightly
wider than long (about 400, wide by 300, long). The poster is not
proximally concave (Fig. 5). Opercula of the holotype are shriveled
and dry; I have not been able to see sclerites, but lucidae are present at
a position corresponding to that in W. arcuata (Fig. 6).

Each zoecium of P. nigra possesses about 6 (5-6) pairs of multipo-
rous lateral pore plates, each perforated by about 5 pores. Transverse
pore plates are basal only; none are located near lateral edges of the
transverse wall. Frontal pseudopores are smaller (10-15) and less
numerous than in W. arcuata; intrazoidal septulae appear to be absent.

This description of P. nigra differs in several respects from that of
Canu and Bassler (1930). The aperture is described as proximally
concave; their text-figure (fig. 6), reproduced here (Fig. 7), shows
an aperture similar to that of W. arcuata. Their photographs (PI.
4, figs. 9-14), however, agree well with the description given here for
P. nigra. W. arcuata occurs in the Galapagos Islands, the type locality
of P. nigra (Hastings, 1930); it is possible that Canu and Bassler may
have had both species in their collection.

Watersipora arcuata is most closely related to the highly variable

New Species of Bryozoa 101

complex of species usually referred to W. subovoidea (d’Orbigny)
[I agree with Harmer, 1957, that Lepralia cucullata Busk is identical
to W. subovoidea]. W. arcuata, however, can be distinguished from
all other watersiporids by its possession of a proximally concave
aperture and an uncalcified basal window.

ACKNOWLEDGEMENTS

I thank Dr. Russel L. Zimmer, Dr. John D. Soule, Dr. Dorothy F. Soule, and
Dr. Olga Hartmen for their advice and critical reviews of the manuscript. Dr.
Alan Cheetham and Mr. Dennis P. Gordon kindly provided specimens for
comparison. Drs. Daniel S. Fertig and Bernard L. Strehler loaned equipment
and provided technical assistance. The research was conducted at the Allan
Hancock Foundation, University of Southern California, Los Angeles, and was
supported in part by an NIH Biomedical Support Grant Award. Contribution
328 of the Allan Hancock Foundation.

LITERATURE CITED

Banta, W. C., 1968. The body wall of cheilostome Bryozoa, I. The ectocyst of
Watersipora nigra (Canu and Bassler). J. Morph., 125: 497-506.

1969a. The body wall of the encrusting cheilostome, Watersipora nigra
(Canu and Bassler) (Bryozoa): Preliminary report. Atti Soc. Ital. Sci. Nat. e
Museo Civ. St. Nat. Milano, 108. [in press].

1969b. Uscia mexicana, new species, a watersiporid bryozoan with
dimorphic autozoids. Bull. So. Calif. Acad. Sci. 68: 30-35.

Busk, G., 1854. Catalogue of marine Polyzoa in the collection of the British
Museum, part II, Cheilostomata (Part). Brit. Mus., London, 55-120 p.

CANU, F. AND R. S. BassLeR, 1930. The bryozoan fauna of the Galapagos
Islands. Proc. U. §. Nat. Mus., 76: 1-78.

Cook, P. L., 1968. Bryozoa (Polyzoa) from the coasts of tropical West Africa.
Atlantidae Rep. 10: 115-262.

HaRMER, S. F., 1957. Polyzoa of the Siboga Expedition. Part IV. Cheilostomata
Ascophora. II. (Ascophora, except Reteporidae, with additions to part II,
Anasca). Siboga-Exped. Monogr. 28d: 641-1147.

HastTinocs, A. B., 1930. Cheilostomatous Polyzoa from the vicinity of the Panama
Canal collected by Dr. C. Crossland on the cruise of the S. Y. “St. George”.
Proc. Zool. Soc. London, 1924 (4): 697-740.

Mawatari, S., 1952. On Watersipora cucullata (Busk) II. Anatomical study.
Misc. Rep. Res. Inst. Nat. Resour. Tokyo, 28: 17-27.

OsBurN, R. C., 1952. Bryozoa of the Pacific coast of America, Part II, Cheilosto-
mata Ascophora. Allan Hancock Pacific Exped., 14: 271-611.

SKERMAN, T., 1960a. The recent establishment of the polyzoan, Watersipora
cucullata (Busk) in Auckland Harbour, New Zealand. New Zealand J. Sci.,
3: 615-619.

102 Bulletin So. Calif. Academy of Sciences

1960b. Ship-fouling in New Zealand waters: a survey of marine fouling

organisms from vessels of the coastal and overseas trade. New Zealand J.
Sci., 3: 620-648.

SouLE, J. D., 1961. Results of the Puritan-American Museum of Natural History
Expedition to Western Mexico, 13, Ascophoran Cheilostomata (Bryozoa)
of the Gulf of California. Ameri. Mus. Novit., 2053: 1-66.

SouLE, D. F. anp J. D. Soule, 1964. The Ectoprocta (Bryozoa) of Scammon’s
Lagoon, Baja California, Mexico. Ameri. Mus. Novit., 2199: 1-56.

WISLEY, B., 1958. The settling and some experimental reactions of a bryozoan

larva, Watersipora cucullata (Busk). Australian J. Mar. Freshwat. Res.,
9: 362-371.

Accepted for publication March 11, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 103-111, 1969

DISTRIBUTION AND DEVELOPMENT OF MYSIDS
(CRUSTACEA, MYSIDACEA) FROM THE ARCTIC
OCEAN AND CONFLUENT SEAS.

STEPHEN R. GEIGER
Department of Biological Sciences
University of Southern California

Los Angeles, California 90007

ABSTRACT: Three species of mysids (Crustacea, Mysidacea),
Mysis litoralis, M. oculata, and M. polaris were present in
plankton collections from the East Siberian and Laptev seas.
Two or three of these species frequently occurred together in
these neritic areas strongly influenced by the runoff from
rivers, while only M. polaris and Boreomysis nobilis were
found in the Arctic Ocean and adjacent areas of deep water
which are covered by ice. The occurrence of M. litoralis and
M. oculata each in two distinct groups, characterized by
different body lengths and development of secondary sexual
characteristics, indicates that more than one year is needed
for maturation and that the breeding season is limited for
these species in Siberian seas. Size differences in M. litoralis
juveniles from the East Siberian and Laptev seas are probably
attributable to different lengths of time between spawning and
collection rather than solely to environmental differences
between the two seas.

INTRODUCTION

Geiger, Rodriguez, and Murillo (1968) found euphausiids in plankton
samples from over the northern continental shelf of the U.S.S.R.,
except where there was a large discharge of fresh water from rivers.
However, mysids (other stalk-eyed crustaceans) were abundant in
the area of low salinity which lacked euphausiids. These mysids were
of particular interest as they were from an area where previous in-
formation on distribution and life history was difficult to interpret.
This difficulty resulted from changes which were made recently in
the species composition of the arctic-subarctic members of the genus
Mysis. Holmquist (1958) recognized M. oculata as a pair of species,
M. oculata and M. litoralis. The specimens she designated as M.
litoralis have the same morphology as the species originally described
by Banner (1948) as Pugetomysis litoralis, which he later synonymized
with M. oculata (Banner, 1954). Holmquist (1959b) also described
a new species, M. polaris, on the basis of two specimens from widely
separated northern locations.

103

104 Bulletin So. Calif. Academy of Sciences

50° W 90°W 130° W

UOT “on 0/7 7,

ae iy Ma CS?
ive RUUD Rea
LS, vce

EAST

SIBERIAN =,

LAPTEV <&

S02E 90°E ISZO°E

Figure 1. Location of plankton samples in Arctic Ocean and its confluent seas.
Solid lines: drift of ice stations and path of SEADRAGON;; dashed lines: depth
contours in meters; partly darkened circle: presence of Mysis polaris; “A”: five
M. polaris at five stations; dot: absence of mysids. Details of East Siberian and
Laptev seas on Fig. 2.

MATERIALS AND METHODS

Most of the specimens used in this study were collected from the
USCGC NORTHWIND on a cruise over the Siberian continental
shelf between the coast and the edge of the pack ice in 1963 (Figs. 1
and 2). Thirteen plankton hauls were made in the Chukchi Sea from
August 9-12, 20 hauls in the East Siberian Sea from August 16-26,
and 43 hauls in the Laptev Sea from August 26 to September 10.
Other samples examined included 19 from the Barents Sea and 8
from the northern part of the Kara Sea, made during an August-
September 1967 cruise of the USCGC EASTWIND; 90 samples
from the nuclear powered submarine SEADRAGON on a cruise
from McClure Strait in the Canadian Archipelago to Barrow, Alaska
by way of the north pole in August and September 1960; and about
5000 samples from arctic drifting ice stations, over the Amerasia
and Eurasia Basins and off the northeast coast of Greenland from
September 1959 to May 1967.

Almost all of this plankton was caught in 1/2 m nets with mesh
openings of 62, 73, or 215,. The mesh used on the NORTHWIND
had openings of 215, and on the EASTWIND 73,. All three sizes

Arctic Mysids 105

were used from the drifting ice stations. The sampling device on the
SEADRAGON used nets with mesh openings of 223, . Nets in which
mysids were caught were usually either towed vertically from near
the bottom to the surface or horizontally at a given depth and then
pulled open to the surface. Horizontal tows made from the NORTH-
WIND were about 10 minutes or less in duration, while those from
the drifting station were from about 8 to 27 hours.

Mysids were measured from the anterior tip of the rostrum to the
posterior end of the telson, excluding setae.

DISTRIBUTION

Four species of mysids were in the plankton collections: Mysis litoralis
(Banner), M. oculata (O. Fabricius), M. polaris Holmquist, and
Boreomysis nobilis G. O. Sars. The occurrences of these species are
listed below, first in neritic areas where they were most abundant,
and then in other neritic and oceanic areas.

Sixty-one mysids were collected from 20 plankton tows made in
the East Siberian Sea during the iatter half of August 1963 in 3 hori-
zontal, 3 vertical, and 1 oblique tows (Fig. 2A). Mysis litoralis was
present in 5 of these tows. Most specimens: 18 females, 5 males, and
18 juveniles were taken in the oblique tow made at 71°31'N, 154°58’E
in which the net was hauled from near the bottom (at 13m) to the
surface. In the 5 tows (Fig. 3A) 37% were females, 10% males, and
53% juveniles. A 20 mm M. oculata female was caught in a horizontal
surface tow. Horizontal, vertical, and oblique tows caught 7 M. polaris:
a 16 mm female, a 16 mm male, and juveniles 7-9 mm long.

Three species of Mysis were present in 22 (15 horizontal and 7
vertical) of 43 plankton hauls made in the Laptev Sea between the
end of August and mid-September 1963 (Fig. 2B). One hundred
ninety-seven M. litoralis were taken in 17 tows: 11 horizontal and 6
vertical. In horizontal hauls 10% were females, 7% males, and 83%
juveniles, while in vertical hauls 11% were females, 16% males, and
73% juveniles. A higher ratio of sexually differentiated individuals to
juveniles occurred on the three occasions when the net touched bottom,
but only 12 specimens were caught: 3 females, 3 males, and 6 juveniles.
The size and frequency of the various developmental stages of M.
litoralis from all samples is shown in Fig. 3B. Forty-six M. oculata
were present at 5 stations: 3 horizontal and 2 vertical tows. Most were
caught at 74°32’N, 127°00'E where a horizontal tow was made at 24
m, in 34 m of water. There were 13 females, 15 males, and 7 juveniles.
Figure 3C gives the sizes and frequencies of the M. oculata from the

106 Bulletin So. Calif. Academy of Sciences

Laptev Sea. Eighteen M. polaris were taken at 13 stations: 8 horizontal
and 5 vertical hauls. Three were females, 2 males, and 13 juveniles.
Females were 16, 17, and 19 mm long, males 17 and 25 mm, and
juveniles 7-12 mm.

Along the continental shelf and slope off northeast Greenland two
species were collected from pelagic areas and four from bottom
samples. A 20 mm long male Mysis polaris was taken in a dipnet at
the surface of the sampling hole on April 22, 1965 when ice island
ARLIS II was over 1170 m of water (Fig. 1). Boreomysis nobilis, a
23 mm individual without developed secondary sexual characteristics,
was caught at 77°N, 11°W on February 26, 1965, in a vertical haul
from 500 m to surface in 530 m of water. Off northeast Greenland
B. nobilis and other mysids were taken in the same series of dredge
hauls used by Stendell (1967) in his study of echinoderms, although
perhaps significantly usually not in the same hauls in which echino-
derms were present. The following species were recorded: B. nobilis, —
2 specimens from 2 stations; Michthyops théeli (Ohlin), 7 from 4
stations; Pseudomma frigidum, H. J. Hansen, 5 from 3 stations, and
Parerythrops spectabilis G. O. Sars, 2 from 2 stations. The species
collected by dredge have been reported previously from dredged
samples from East Greenland by Stephensen (1943) and others.

Mysids were not recovered from the Chukchi, Kara, or Barents
seas or from over the continental shelf north of Alaska. This absence
should not be interpreted as indicating an absence of this group from
these areas, as their presence there has been established by the work
of Linko (1908), Schmitt (1919), Banner (1954), Holmquist (1959a,
1963), and others.

Eight mysids were taken over deep areas of the Arctic Ocean.
Interestingly, 6 of these were Mysis polaris (Fig. 1), of which 5 were
taken in horizontal tows at 14 or 20 m over the Amerasia Basin
between November 1962 and January 1963. All were juveniles between
9 and 12 mm long. The other M. polaris was a badly damaged speci-
men, about 15 mm long, collected as the SEADRAGON traveled at an
average depth of 46 m, along the edge of the Siberian continental shelf
in August 1960 (Fig. 1). Boreomysis nobilis was the only other species
collected in plankton hauls in the Arctic Ocean. A 36 mm male was
collected in December 1962 in the same series of samples which
contained the 5 M. polaris mentioned above. It was collected in a
horizontal haul at 505 m where the water depth was about 3000 m.
The other specimen was a 33 mm long female collected in September
1965 over the Canada Basin at 75°21'N, 140°53’W in a horizontal
tow at 100 m where the water depth was 3675 m.

Arctic Mysids 107
145 150 155 160

Mysis /itoralis
Mysis oculata

= Mysis polaris
= absent
oc
O
ZZ
Lu
(a)
=)
ie
<x
=)
145 150 155 160 165 170 175
FONGInU DES EASiIi
5 120 125 130 135 140
a5
kK
(7
O
Zz
LJ
e
=)
ba
Kk
<x
Bi B

5 120 I25 130 135 140

Figure 2. Presence of Mysis in plankton samples. A. East Siberian Sea; B. Laptev
Sea.

DEVELOPMENT

Size and development of the oostegites and fourth pair of pleopods
of Mysis litoralis varied considerably. In most females under 20 mm
long the posterior pair of oostegites did not extend anterior to the
sixth pair of thoracic appendages, while in those 20 mm or over these
oostegites extended anterior to the sixth pair of thoracic appendages.
Males in which the fourth pair of pleopods did not reach the posterior

108 Bulletin So. Calif. Academy of Sciences

end of the sixth abdominal segment were, with one exception, shorter
than 21 mm; those in which this pair of pleopods extended beyond the
posterior end of the sixth abdominal segment were, with one exception,
19 mm or longer. M. oculata was much less variable in length and
likewise the oostegites and fourth pair of pleopods were in a more
uniform stage of development. The last pair of oostegites extended
anterior to the sixth pair of thoracic appendages except in two females,
and the fourth pair of pleopods reached or extended posterior to the
end of the sixth abdominal segment in all of the males. In the four
female M. polaris the posterior pair of oostegites did not reach the
sixth pair of thoracic appendages; in the males the fourth pair of
pleopods reached almost to the middle of the sixth abdominal segment
in two specimens and to the posterior end of that segment in the other
two.

Only in Mysis litoralis were juvenile mysids sufficiently abundant
to permit a comparison of length of individuals obtained from two |
areas. The East Siberian Sea juveniles had a mean length of 6.7 mm;
more than one-fourth of the juveniles from the Laptev Sea were longer
than those from the East Siberian Sea, and their mean length was
8.5 mm.

No mysids were found with embryos or larvae in the marsupium.

COMMENSALS

A dajid isopod was removed from between the eighth thoracic append-
ages of a juvenile Mysis polaris collected in the Arctic Ocean at
84°24'N, 169°02’E in December 1962. Dr. Charles G. Danforth, of
California State College at Los Angeles, has tentatively identified it
as an immature female of Holophryxus alaskensis Richardson. Several
mysids examined in this study were infested with commensal ciliate
protozoans, which are now under study by Dr. John L. Mohr of the
University of Southern California.

DISCUSSION

Most mysids were caught in the East Siberian and Laptev seas, where
oceanographic data collected at the same time as the mysids showed
that the water depth was from 10-49 m and the fresh water intrusion
from large rivers was great (U. S. Coast Guard, 1965). Two or three of
the predominant species, Mysis litoralis, M. oculata, and M. polaris,
were often caught together in either horizontal or vertical tows and
therefore information on the ecological separation of the species was
limited. M. litoralis was more abundant than M. oculata, as has been

Arctic Mysids 109

44

27
yw 25
=
Wu B
=
© 20
lJ
c mma females
fs WZZA males
Le tc Juveniles
Oo
© jo
LJ
aa)
=>
=)
Ze 1)
5 10 15 20 25 30
5

5 Ke) 15 20 25 30

LENGTH, mm

Figure 3. Mysis of various lengths and developmental stages. A. M. litoralis from
East Siberian Sea; B. M. litoralis from Laptev Sea; C. M. oculata from Laptev Sea.

110 Bulletin So. Calif. Academy of Sciences

reported by Holmquist (1963) around Barrow, Alaska, but off western
Greenland M. oculata is more abundant (Holmquist, 1959a). The
occurrence of M. polaris in the East Siberian Sea, Laptev Sea, off
northeast Greenland, and in the Arctic Ocean demonstrates this to be
a more widely distributed and abundant species than was previously
believed (Holmquist, 1959b). Its occurrence at several locations
within the Arctic Ocean beyond the edge of the continental shelf, and
the absence of M. litoralis or M. oculata, suggests a greater tolerance
to under-ice conditions and suggests that M. polaris lives toward the
edge of the continental shelf and is carried from there by currents into
oceanic areas. Boreomysis nobilis is from a genus whose members are
usually found in or over deep areas (Stephensen, 1943; Tattersall,
1955), but the extent of its establishment in the Arctic Basin needs
further study.

The distinct separation, in August and September samples, of
Mysis litoralis and M. oculata each into two size groups suggests that _
they do not mature in one year along the Siberian continental shelf.
Such a bimodal distribution of specimens of various sizes also suggests
a limited breeding season. Holmquist’s (1959a) findings for these
species, based on dredged samples from Greenland fjords, suggest
more rapid maturation but also indicate a limited breeding season.
Other species of mysids from temperate regions spawn at various
times of the year (Tattersall and Tattersall, 1951; Mauchline, 1968).
Such spawning produces a continuum of lengths and stage of develop-
ment of sexual characteristics, and leads to the occurrence of females
with young throughout the year. The largest adults of M. litoralis and
M. oculata that have been reported occur in Siberian seas (Holmquist,
1959a) and our samples from that area also include large specimens.
The greater length of juveniles from the Laptev Sea, compared to the
East Siberian Sea, probably results from differences in the time between
Spawning and collection, rather than from an entirely environmental
difference between the two seas.

ACKNOWLEDGMENTS

Dr. Charles G. Danforth kindly identified the isopod found on Mysis polaris.
Use of the laboratory and library facilities of the Allan Hancock Foundation of
the University of Southern California is gratefully acknowledged. This research
was supported by contract NONR 228 (19), NR 307-270, between the Arctic
Program, Office of Naval Research, Department of the Navy, and the University
of Southern California.

Arctic Mysids tI

LITERATURE CITED

BANNER, A. H., 1948. A taxonomic study of the Mysidacea and Euphausiacea
(Crustacea) of the northeastern Pacific. Part II. Trans., Royal Canadian
Inst., 27: 65-125.

1954. New records of Mysidacea and Euphausiacea from the northeastern
Pacific and adjacent areas. Pacific Sci. 8: 125-139.

GEIGER, S. R., K. RODRIGUEZ AND M. M. MuRILLo, 1968. Euphausiacea of the
Arctic Ocean and its peripheral seas. Bull. So. Calif. Acad. Sci., 67: 69-79.

Hotmaulist, C., 1958. On a new species of the genus Mysis, with some notes on
Mysis oculata (O. Fabricius). Meddelelser om Grgnland, 159 (4): 1-17.

1959a. Problems of marine glacial relicts on account of investigations on
the genus Mysis. Berlingska Boktryckeriet, Lund, 270 p.

1959b. Mysis polaris —a new species of the genus Mysis. Kungl. Fysio-
grafiska Sallskapets I Lund Forhand lingar, 29: 21-25.

1963. Some notes on Mysis relicta and its relatives in northern Alaska.
Arctic, 16: 109-128.
Linko, A., 1908. Schizopoda of the Russian northern seas. Scientific results of the

Russian polar expedition of 1900-1903, under the direction of Baron E. Toll.
Akad. Nauk, SSSR, Leningrad, Ser. 8, 18 (8): 1-76. [In Russian].

MAUCHLINE, J., 1968. The biology of Erythrops serrata and E. elegans (Crustacea,
Mysidacea). J. mar. biol. Ass. U. K., 48: 455-464.

ScumiTT, W. L., 1919. The schizopod crustaceans of the Canadian Arctic Expedi-
tion, 1913-18. Report Canadian Arctic Exped. 1913-18, 7 (Crustacea)
(B): 1b-8b.

STENDELL, R., 1967. Echinoderms collected from a drifting ice island off the East

Greenland coast, with comments on their distribution in adjacent waters.
J. Fish. Res. Bd. Canada, 24: 833-842.

STEPHENSEN, K., 1943. Leptostraca, Mysidacea, Cumacea, Tanaidacea, Isopoda
and Euphausiacea. Zoology of East Greenland. Meddelelser om Grgnland,
121 (10): 1-82.

TATTERSALL, O. S., 1955. Mysidacea. Discovery Reports, 28: 1-190.

TATTERSALL, W. M. AnD O. S. TATTERSALL, 1951. The British Mysidacea. The
Ray Society, London, 460 p.

UNITED STATES CoasT GUARD, 1965. Oceanographic cruise USCGC NORTH-
WIND, Chukchi, East Siberian and Laptev seas, August-September 1963.
Oceanographic Report No. 6 (CG 373-6), U.S. Government Printing Office,
Washington, 69 p.

Accepted for publication March 20, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 112, 1969

RESEARCH NOTES

PACIFIC RIDLEY SEA TURTLE, LEPIDOCHELYS
OLIVACEA, IN PUERTO RICO

A live specimen of the Pacific ridley sea turtle, Lepidochelys olivacea,
was captured from a charter-fishing boat 4 to 5 miles offshore west of
Punta Salinas, or about 3 miles west of San Juan Harbor, Puerto Rico,
presumably in October, 1967.

The dried carapace, generously made available by Captain Mike
Benitez of Santurce, Puerto Rico, is now in the collections of the
Los Angeles County Museum of Natural History. The carapace
measures 48 cm in length in a straight line between perpendiculars
from the center of its anterior end to its greatest posterior projection
(not over the curve), and 51.5 cm in greatest width. There are 7
laminae on each side; the overall color of the surface of the dry carapace
is greenish-grey. Sex was not recorded when the animal was killed.

The species is now well known from the region of northeastern
South America (Pritchard, 1966, 1967; Carr, 1967), and has once
before been reported from the Greater Antilles from Cuba (Aguayo,
1953; Carr, 1957). The Puerto Rican record now confirms the occa-
sional presence of the Pacific ridley in the Greater Antilles, but our
data suggest that it is very rare in Puerto Rico. Erdman lived in La
Parguera, on the southwestern coast, for 12 years and never saw a
specimen. Galo Casiano, a life-long resident of La Parguera, told
Erdman that this kind of turtle was very rare and that he had only
seen a few in his SO years plus of fishing in the area.

LITERATURE CITED
Acuayo, C. G. 1953. La tortuga bastarda (Lepidochelys olivacea) en Cuba. Mem.
Soc. Cubana de Hist. Nat., 21: 211-219.
Carr, ARCHIE. 1957. Notes on the zoogeography of the Atlantic sea turtles of the
genus Lepidochelys. Rev. Biol. Trop., 5: 45-61.
1967. So excellent a fishe. Garden City, New York: The Natural History
Press, x + 248 p.

PRITCHARD, PETER C. H. 1966. Sea turtles of Shell Beach, British Guiana. Copeia,

1966: 123-125.
1967. To find the ridley. Internatl. Turtle and Tortoise Soc. J., 1(4):
30-35, 48.

David K. Caldwell, Marineland Research Laboratory, St. Augustine,
Florida 32084 and Donald S. Erdman, Federal Aid Projects F-1-R,
Department of Agriculture, Commonwealth of Puerto Rico, San Juan.
Accepted for publication February 4, 1969.

WD

Bull. So. Calif. Acad. Sci. 68(2): 113-114, 1969

HATCHLING GREEN SEA TURTLES, CHELONIA MYDAS,
AT SEA IN THE NORTHEASTERN PACIFIC OCEAN

Carr (1967: 101) stated that he knew of no place that small sea turtles
of any kind could be caught with any degree of regularity. His reference
was to very small turtles at sea, and not to emerging hatchlings on the
nesting beach.

Small sea turtles are highly prized by salt water aquarists and
command a premium price. In early June, 1963, several tuna and
sardine fishermen brought with them hatchling- and just post-hatchling-
sized green turtles, Chelonia mydas, when they returned home to
San Diego and San Pedro, California, from the Revillagigedo Islands.
The fishermen reported that the turtles were frequently encountered
at the surface around Clarion and Socorro Islands during the summer,
and at night often came up to the lights of their anchored vessels
where they were easily dipnetted. The response by the aquarium
hobbyists to this discovery was instantaneous and $25.00 or more
apiece was offered for the turtles. With this incentive, the fishermen
brought back large numbers of these baby green turtles on succeeding
trips that year, and repeated this the following year. Enough turtles
were brought in to flood even this large and lucrative market to the
point where some dealers were having trouble selling the turtles for
even $5.00 or less.

Similar data on the capture of baby green turtles at sea was provided
by Mr. Gilbert Furuya, a commercial fisherman, although his findings
were not confirmed by subsequent captures. He wrote me (pers. comm.,
21 December 1963) that in November of that year he had scooped up
a number of hatchling-sized green turtles about 50 miles SE of
Manzanillo, Mexico, and about 10 miles offshore. He noted that his
boat was drifting at night with floodlights hanging over the side and
that from their behavior the turtles apparently had been attracted to
his lights. He felt that the turtles were there that time of year, and
earlier, regularly enough and in large enough numbers to make him
confident of collecting them again.

Green turtles nest in the Revillagigedo islands (Caldwell, 1963),
and Mr. Furuya’s locality data would be approximately off the Mexican
state of Michoacan where green turtles also nest (Peters, 1957;
Caldwell, 1963). Consequently, these hatchlings almost certainly
came from those rookeries. How long they remain in the waters in
either vicinity is not known, but enough were there in season to make
it worthwhile for the fishermen to capture them. Certainly they were
there more dependably than the occasional baby sea turtle of any

113

114 Bulletin So. Calif. Academy of Sciences

species that is infrequently captured as a straggler at sea throughout
most of the tropical and temperate waters of the world.

I examined some of the turtles from each locality and confirmed
the identifications and the fact that they were hatchling or just post-
hatchling in size. Not enough data are available to determine if these
hatchlings were Chelonia mydas agassizi or C. m. carrinegra. All
were very dark dorsally and almost white ventrally. Specimens were
deposited in the herpetology collections of the Los Angeles County
Museum of Natural History.

LITERATURE CITED

CALDWELL, David K. 1963. The sea turtle fishery of Baja California, Mexico.
Calif. Fish and Game, 49: 140-151.

CarRR, ARCHIE. 1967. So excellent a fishe. Garden City, New York: The Natural
History Press, x + 248 p.

PETERS, JAMES A. 1957. The eggs (turtle) and I. The Biologist, 39: 21-24.

David K. Caldwell, Marineland Research Laboratory, St. Augustine,
Florida 32084.

Accepted for publication February 4, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 115-118, 1969

A SECOND RECORD OF THE SLENDER MOLA,
RANZANIA LAEVIS (PENNANT), FROM CALIFORNIA.

Four slender molas, captured in a purse seine at the “43-fathom spot”
(lat. 32°40'N, long. 117°59'W) some 20 miles SE of San Clemente
Island during the night of September 12, 1968, appear to be the second
record of the species from California. According to crew member
Shoichi Abe of the seiner Determined, the net was set for bluefin tuna,
Thunnus thynnus, but when pursed it contained only the four Ranzania
and an unidentified shark. Abe brought two of the molas to California
State Fisheries Laboratory to have them identified, and another crew
member took the other two to John Olguin, Cabrillo Beach Marine
Museum, who retained one for displaying in the museum and turned
the other over to me. The three specimens in my possession (258, 277,
and 298 mm TL) have been placed in the fish collection of the Los
Angeles County Museum of Natural History (accession numbers
LACM 30177-1 through-3).

Figure 1. Slender mola, Ranzania laevis, 258 mm total length, captured in a purse
seine 20 miles SE of San Clemente Island, California, September 12, 1968. Photo
by Jack W. Schott.

115

116 Bulletin So. Calif. Academy of Sciences

Figure 2. Front view of three slender molas captured SE of San Clemente Island,
showing peculiar mouths, apparently incapable of closing. Photo by Jack W.
Schott.

The only previous record for California is that of Snyder (1913)
who reported upon a 460 mm individual that was found dead on the
beach at Oceano (San Luis Obispo County) in August 1909.

Fraser-Brunner (1951) presented a rather exhaustive review of the
family Molidae, including detailed information on taxonomy, distri-
bution, and developmental stages for the various species, but he had
little to report on their natural history. The only statement he made
concerning food habits of Ranzania was based upon Barnard’s (1927)
observation that the stomach of a South African specimen that had
been caught in a trawl net contained “several pieces (in various stages
of digestion) of littoral seaweeds, some of which had evidently been
torn off the rocks.” Fraser-Brunner (1951) speculated that while its
peculiar mouth did not seem adapted for such food gathering, “it is
possible that the lips can suck in and close upon a frond [of seaweed]
while the teeth nip it off.” The lips of Ranzania extend well beyond
the teeth and form a rather rigid, oval-shaped, funnel-like mouth
(Fig. 2). The orofice supposedly closes so that the rictus is vertical,
but in five specimens that I have examined (the present four from off

Slender Mola i 1 7/

California, and a 330 mm TL specimen seined off northern Chile at
lat. 18°05’S, long. 72°32’W in 1963) the mouth was inflexible and
could not be closed by applying external pressure with the fingers
from any direction. I prefer to believe that the algae in the stomach
of the South African specimen had been torn loose by the trawl net,
and were sucked in during the fish’s dying gasps after the net was
hauled from the water. Normal deterioration of the living seaweed
could have been responsible for the “various stages of digestion”
noted by Barnard (1927).

I examined the stomachs of the three Ranzania in my possession
(from the 43-fathom spot) and found an assortment of crustacean,
fish, and mollusk remains (Table 1). The fish appeared to have been
well chewed before being swallowed, and only disarticulated vertebrae,
bony fragmentia from the head region, and otoliths were found. The
crustaceans and pteropods appeared to have been ingested entire,
but because of digestive action and spoilage, sufficient disintegration
had occurred to preclude making more-exacting determinations.
Numerically, crustaceans were the most important food items, but
fish, in the two stomachs containing their remains, had contributed

TABLE |

Food Items Found in Stomachs of Three Ranzania laevis
Netted off California September 12, 1968

Type of food Number of items

30177-1* 30177-2* 30177-3*
(258mmTL) (277mmTL) (298 mm TL)

Fish
Trachipterus altivelis} | 1
myctophid larva |
unidentified larva ° I

Crustaceans

natantian shrimp >10 >10 S15

hyperiid amphipods >10 >10 >10

crab megalops | 3 p)

crab zoea l

unidentified crustaceans >10 > 20 > 20
Mollusks

pteropod | |

* Los Angeles County Museum of Natural History accession number.
1 Identified from otoliths; specimens about 3 inches (75 mm) long.

118 Bulletin So. Calif. Academy of Sciences

the greatest bulk. Most feeding appears to have taken place within
500 feet (150 m) of the surface, but probably not at the surface.

Based upon 2,615 young Ranzania captured in plankton nets
around Hawaii during the months of January through May, and an
adult female 335 mm T.L. found in the stomach of a marlin during
October, Sherman (1961) speculated that spawning of R. laevis occurs
only during “the late winter and early spring in the Hawaiian region.”
Neither sex nor state of maturity could be determined for my three
specimens, but this could have reflected the advanced state of dete-
rioration (spoilage) when I examined them, rather than a lack of
maturing ova or sperm.

ACKNOWLEDGMENTS

I am indebted to Johnny Kwock for identifying the disintegrated crustacean
remains I found in these Ranzania stomachs, and to Jack W. Schott for the
excellent photographs; both are fellow employees at California State Fisheries
Laboratory.

LITERATURE CITED

BARNARD, K. H. 1927. A monograph of the marine fishes of South Africa. Part II.
(Teleostei — Discocephali to end. Appendix.) Ann. S. Afr. Mus., 21: 419-
1065.

FRASER-BRUNNER, A. 1951. The ocean sunfishes (Family Molidae). Bull. Brit.
Mus. (Nat. Hist.), 1: 87-121.

SHERMAN, KENNETH. 1961. Occurrence of early developmental stages of the
oblong ocean sunfish Ranzania laevis (Pennant) in the central North Pacific.
Copeia, 1961: 467-470.

SNYDER, JOHN O. 1913. Notes on Ranzania makua Jenkins and other species of
fishes of rare occurrence on the California coast. Proc. U.S. Nat. Mus.,

44: 455-460.

John E. Fitch, California Department of Fish and Game, Terminal
Island, California. 90731.

Accepted for publication February 4, 1969.

Bull. So. Calif. Acad. Sci. 68(2): 119-120, 1969

SOME OBSERVATIONS ON A CAPTIVE DESERT
SHREW, NOTIOSOREX CRAWFORDI

On April 8, 1968, while collecting parasitic reduviid bugs in the
desert near Vail, Pima Co., Arizona, I collected a juvenile female
desert shrew, Notiosorex crawfordi Coues, in the lodge of a white-
throated wood rat, Neotoma albigula albigula Hartley. This association
of Notiosorex with Neotoma has been reported by others (Gander,
1928: Ryckman et al., 1965). The shrew was found about a foot below
the surface in the storage portion of the lodge, among mesquite twigs.
It made no attempt to bite or avoid capture, and was carried some
thirty miles back to Tucson in a small loosely-topped bottle without
incident. The shrew ate well from the day of capture, eating as often
as it was fed. A mouse, Peromyscus sp., was offered, but did not appear
to interest the shrew greatly. No effects from possibly toxic saliva
were noted even after the mouse had sustained several bites on the tail
over a period of an hour.

Upon my arrival in Los Angeles, the shrew was housed in a five-
gallon aquarium filled three inches deep with cedar shavings. A small
cardboard box with one open end was provided for shelter, and two
watch glasses were used for food and water. The shrew was fed ten to
fifteen mealworms each day. At no time was the shrew observed to eat
meat, although this was offered on several occasions. The shrew
showed evidence of taming within several days, and was frequently
taken out and allowed to run on a large couch. Whenever running,
the shrew proceeded in zig-zag spurts of about ten inches, making a
high-pitched squeaking sound while in motion. The tail was carried
curved stiffly in a C-shape, as observed with a captive Notiosorex by
Dixon (1924). While in its cage, the shrew was rarely seen unless the
cage was jarred, as usually occurred during feeding time. The shrew
would then tunnel under the shavings, surfacing near the food dish.
The flexible nose was thrust into the air for a moment before the shrew
climbed into the dish to search for mealworms. The conclusion of a
meal was usually signaled by a squeak and a dive into the shavings,
but often the shrew would first drink copiously from the adjacent
water dish. In addition, I occasionally observed the shrew cleaning
the tip of its nose after feeding by bending it over, tapir-fashion,
whereupon it was licked once or twice.

The shrew spent most of its time in the shelter box, but could often
be found in a small depression under it. The regular defecation stations
observed for captive Notiosorex by Hoffmeister and Goodpaster
(1962) were also seen with my specimen. The top of the box was used

119

120 Bulletin So. Calif. Academy of Sciences

on occasion, but the favored site was along the edges of the aquarium
bottom under the shavings. The appearance when the cage was cleaned
was that the feces had been smoothly troweled into the corners. Definite
scent trails were noted, for if the shrew’s box were displaced a few
inches during feeding, and the shrew were startled, it would invariably
dash back to the original position of the box. Not finding the box in its
usual place, sniffing and probing would quickly re-establish the location.

Within a week after being brought to Los Angeles, the shrew began
to develop abnormally long front claws, which were trimmed carefully
with scissors. This had to be repeated several times during the period
of captivity, and twice the hind claws required similar trimming.
Although Hoffmeister and Goodpaster (1962) felt that Notiosorex
was most likely not a burrower, the constant burrowing activities of
my specimen and the excessive claw growth observed would indicate
that Notiosorex may have fossorial tendencies.

On June 20, 1968, the shrew was preserved as an alcoholic ©
specimen. It was deposited in the collection of the Los Angeles Co.
Museum, LACM No. 28258.

ACKNOWLEDGEMENTS

I would like to thank Dr. Ron Lester of the Los Angeles Co. Museum for positive
identification of the shrew; Dr. Jay Savage, for assistance in preparing the manu-
script, and Mr. Regan Walk, who rendered valuable aid in the field collection
of the specimen.

LITERATURE CITED

Drxon, J., 1924. Notes on the Life History of the Gray Shrew. Jour. Mamm.
5: 1-6.

GANDER, FRANK F., 1928. A Gray Shrew in a Wood Rat’s Nest. Jour. Mamm.
9: 247-8.

HOFFMEISTER, D. F., AND W. W. GooppasTER, 1962. Life History of the Desert
Shrew Notiosorex crawfordi. Southwestern Naturalist 7: 236-52.

RycKMAN, R. E., e¢ al., 1965. Epizootiology of Trypanosoma cruzi in South-
western North America. Jour. Med. Ent. 2: 88.

Vincent Brach, Department of Biology, University of Southern Cali-
fornia, Los Angeles, Calif., 90007.

Accepted for publication March 20, 1969.

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Southern California
Academy of Sciences

OFFICERS OF THE ACADEMY
BOARD OF DIRECTORS

OO aoa IM CIARISET. CE Bi aleer eR Rate ea oe President
PRMME RIMM SEATIECIO [0.12 royal chs aed < ocichers + is'e) se sisiale sce ole sre First Vice President
(2 TEs Le (SITE ofS a ceca nae Second Vice President
SMES OAAITS felete shel s cilop I's) ohei'sinie\dnic)s) «leis sw 'sisve.e' e's ob eee els Secretary
Re PEM MERON SEs Nesey orice! sew SSyahe SeNRS el a hove. sie 'slo.e% olla y vere Treasurer
ROU MPM TiS SEM Pe cea icc atc, os Sus 0/8 « igs s ohav's\oi'el we taba ors, w ocd See ee Editor
Jobn J. Baird Richard Etheridge J. R. MacDonald

Bayard H. Brattstrom John E. Fitch John L. Mohr

Jules Crane, Jr. Takashi Hoshizaki John D. Soule

ADVISORY BOARD

The advisory board automatically consists of the past presidents of the society:
John A. Comstock, Theodore Downs, Hildegard Howard, Richard B. Loomis,
Jay M. Savage, Kenneth E. Stager, Richard H. Swift, Fred S. Truxal, Louis C.
Wheeler, John A. White, Sherwin F. Wood.

COMMITTEES

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meer LhLETIN OF THE

= Southern California

: Academy of Sciences

LOS ANGELES, CALIFORNIA

VOL. 68 JULY-SEPTEMBER 1969 Part 3

ElLBR AR Y

NOV 12 1969

NEW YORK
BC TANK CAL GARDEN

CONTENTS

Further evidence of close relationship of the trematopsid and dis-
sorophid labyrinthodont amphibians with a description of a
new genus and new species. Peter Paul Vaughn 121

Response in Bahamian sharks and groupers to low-frequency,
pulsed sounds. Donald R. Nelson, Richard H. Johnson and
Larry G, Waldrop 131

Pimeliaphilus zeledoni n, sp. (Acari, Pterygosomidae), a parasite
of Triatoma dimidiata (Latr.) (Hemiptera, Reduviidae). Jr-
win M. Newell and Raymond E. Ryckman 138

A review of the colubrid snake genus Amastridium. Larry David
Wilson and John R. Meyer 145

A new species of Hannemania (Acarina, Trombiculidae) from
Bufo punctatus of western North America, with comments on
Hannemania hylae (Ewing). Richard B. Loomis and W. C.
Welbourn, Jr.

An ecological study of the polychaetous annelids associated with
fouling material in Los Angeles Harbor with special reference
to pollution. Robert W. Crippen and Donald J. Reish

A new species of Odontacarus Ewing (Acarina: Trombiculidae)
from lizards of Baja California Sur, México. Richard B.
Loomis and Lee C. Spath

Research Notes:

The Response of Male Grunion to a Wiggling Stick. Jules M.
Crane, Jr.

A western yellow bat in Los Angeles County, California.
Glenn R. Stewart

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BULLETIN OF THE SOUTHERN CALIFORNIA
ACADEMY OF SCIENCES

Vol. 68 JULY-SEPTEMBER No. 3

Bull. So. Calif. Acad. Sci. 68(3): 121-130, 1969

FURTHER EVIDENCE OF CLOSE RELATIONSHIP
OF THE TREMATOPSID AND DISSOROPHID
LABYRINTHODONT AMPHIBIANS WITH A DESCRIPTION
OF A NEW GENUS AND NEW SPECIES

PETER PAUL VAUGHN

Department of Zoology
University of California
Los Angeles, California 90024

ABSTRACT: A new species of a new genus of trematopsid
labyrinthodont amphibian, Ecolsonia cutlerensis, is described
on the basis of a partial skull found in the Lower Permian of
northern New Mexico. The basic similarities to other trema-
topsids, including the presence of the characteristically
elongated external narial opening, are clear; but in the nature
of the palate — with wide interpterygoid vacuities — Ecol-
sonia shows marked resemblances to the dissorophid laby-
rinthodonts. This reinforces earlier assessments of close
relationship between the trematopsids and dissorophids.

INTRODUCTION

Of the families of labyrinthodont amphibians, the trematopsids and
dissorophids seem to have included the forms most highly adapted
for existence out of water. The dissorophids are now well known
through the recent work of Carroll (1964b), who has discussed both
the Pennsylvanian and Early Permian members, and DeMar (1966b,
1968), who has clarified certain details in the construction of the skull,
and who has also been concerned with the patterns of “armor” in the
Early Permian forms and with methods of assessing the degree of
terrestrial adaptation in the various genera. Including the one known
Pennsylvanian genus and two genera known from low in the Upper
Permian, the Dissorophidae now includes thirteen genera (DeMar,

121

122 Bulletin So. Calif. Academy of Sciences

1968). The last general survey of the Trematopsidae was made by
Olson (1941), who recognized two Early Permian genera, Acheloma
and Trematops; later, Olson (1956) described a third Early Permian
genus, Trematopsis. Romer (1947) tentatively added the poorly
understood Parioxys to the Trematopsidae, but Carroll (1964a) has
shown that this assignation is incorrect.

Olson (1941) emphasized the apparent affinities of trematopsids
and dissorophids, but he also pointed out significant differences. In
Trematops, although not in Acheloma, the intercentra of the vertebrae
form complete rings around the notochordal canal; in all dissorophids,
as far as known, the vertebrae are built on the more normally rhachito-
mous pattern. Trematopsids are not known to have carried dorsal
armor plates — so conspicuously and variously developed among the
Permian dissorophids. In some members of both families, the otic
notch is closed posteriorly to form a more or less complete annulus,
but Olson noted that this closure was accomplished somewhat dif-
ferently in the two families. Most striking, the trematopsids are -
characterized by an extremely long external narial opening that
reaches far back to separate partially the prefrontal and lacrimal
bones; the posterior portion of this opening is sometimes called an
“antorbital fossa.” In addition, the interpterygoid vacuities of the
dissorophid palate are enormously expanded — even in small forms
— whereas the vacuities in trematopsids are only moderately devel-
oped. Nevertheless, Olson concluded that the trematopsids were more
closely related to the dissorophids than to any other known group of
Permian labyrinthodonts.

Romer (1947), in a general review of the Labyrinthodontia, grouped
the trematopsids and dissorophids closely together, and he also
expressed his opinion that the zatracheids are properly to be con-
sidered as members of the same phyletic unit. Largely on the basis
of the general similarity between the early, unarmored dissorophid
Amphibamus and the contemporaneous zatracheid Stegops — both
known from the Allegheny Series of the Pennsylvanian System —
Carroll (1964b) concluded that the only clearly discernable relation-
ship of the Dissorophidae is with the Zatracheidae. But, DeMar
(1966a) has recently described a new Early Permian dissorophid with
a slender head and completely enclosed otic notch, Longiscitula,
that shows a remarkable combination of dissorophid and trematopsid
features. As in advanced dissorophids, the dorsal margin of the otic
notch has a distinctive flange that projects ventrally from the region
where the supratemporal and squamosal bones meet; this flange is
much more highly developed than the approximately corresponding

Fossil Amphibians IDs

ridge seen in Trematops. Also as in dissorophids, the frontal bone
makes a broad entry into the margin of the orbit, and there is dorsal
armor covering at least the anteriormost part of the vertebral column
in Longiscitula. Further, the pattern of exostoses on the dermal skull
roof is reminiscent of dissorophids. Despite these features that are so
dissorophid-like, Longiscitula also displays the trematopsid hallmark:
a very elongate external naris, which even, as in trematopsids, is
partially subdivided into anterior and posterior moieties by a flange
projecting laterad from the nasal bone. The elongate skull in Lon-
giscitula is also, according to DeMar, to be reckoned as a sign of
affinity with trematopsids. Unfortunately, almost nothing is known of
the palate in Longiscitula.

NEw GENUS AND SPECIES OF TREMATOPSID AMPHIBIANS

A partial skull at hand from the Lower Permian of northern New
Mexico represents another form with a mixture of dissorophid and
trematopsid characters. The species represented by this skull is so
different from any previously described that a new genus must be
named for its reception. There are clear indications of affinities with
the Dissorophidae, but, on the bases of the long narial opening, the
lack of prominent exostoses on the dermal skull roof, and the absence
of any evidence for dorsal armor, the new genus is better referred to
the Trematopsidae, at least tentatively.

Class AMPHIBIA
Subclass LABYRINTHODONTIA
Order TEMNOSPONDY LI
Suborder RHACHITOMI
Superfamily ERYOPOIDEA
Family TREMATOPSIDAE
Ecolsonia, new genus
Type species. — Ecolsonia cutlerensis, new species.
Diagnosis. — Dorsal part of dermal skull roof of same general
proportions as in the trematopsid Acheloma except that the orbits
are somewhat larger, and with basically the same sutural pattern
except that the frontal bone makes a broader entry into the orbital
margin. No prominent exostoses on dermal skull roof, but a slight
swelling on the postparietal bone and a ridge along the lateral part of
the prefrontal bone. External narial opening extends far back to
separate partially the prefrontal and lacrimal bones. Interpterygoid
vacuities very large, almost as wide as in dissorophids. Vomers have

124 Bulletin So. Calif. Academy of Sciences

Figure 1. Ecolsonia cutlerensis, new genus and species. Holotypic skull, UCLA
VP 1734, in A, dorsal, and B, ventral views. Semidiagrammatic, pitting of dorsal
surface not shown. Size indicated by 2-cm scale. Stippled areas represent matrix.
O.R., limits of orbital rims as preserved. Other abbreviations: F, frontal; L,
lacrimal; N, nasal; P, parietal; PF, postfrontal; PL, palatine; PO, postorbital; PP,
postparietal; PRF, prefrontal; PS, parasphenoid; SQ, squamosal; ST, supra-
temporal; T, tabular; V, vomer; tk, vomerine tusk.

Fossil Amphibians 12

Nn

long palatine processes. Parasphenoidal rostrum reaches forward to
meet the vomers.

Etymology. — Named for Prof. E. C. Olson who first clearly
recognized the unity of the family Trematopsidae.

Ecolsonia cutlerensis, new species
Figure |

Holotype. — UCLA VP 1734 (Fig. 1), a partial skull that includes:
most of the dorsal portion of the dermal skull roof except for the right
posterolateral corner and the premaxillary region; the bones forming
the posterior border of the left external naris; a fragment of the anterior
part of the sphenethmoid; the anterior portion of the palate including
the vomers, parts of the palatines, and the anteriormost part of the
parasphenoid. Associated parts include fragments of pitted dermal
bone and a maxillary fragment with four teeth of typical labyrinthodont
pattern. The holotype is part of the vertebrate paleontological col-
lection of the University of California, Los Angeles.

Horizon and locality. — The holotype was collected by Mr. Ralph
Molnar and myself in December 1963, from the well known Vander-
Hoof quarry of the University of California, Berkeley, in sec. 8, T. 22
N., R. 3 E., near Arroyo de Agua, Rio Arriba County, northern New
Mexico. The quarry is in the lower part of the undifferentiated Cutler
Formation. The age is Early Permian, more specifically, Wolfcampian.
This quarry and its vertebrate fossils have been discussed by Langston
(1953), who gives evidence for the estimate of age.

Diagnosis. — The same as for the genus.

Description and discussion. — The illustration of the holotype of
Ecolsonia cutlerensis (Fig. 1) speaks largely for itself, but some
additional description is necessary. The length of the specimen is
106 mm from the hindmost point of the suture between the postparietal
bones to the anteriormost point of the suture, as preserved, between
the nasal bones; the front parts of the nasals, and the premaxillaries,
are missing. Measured along the occipital rim on the left side, the
distance from the lateralmost point of the tabular to the suture between
the postparietals is 39 mm. The least interorbital width is about 33 mm.
Imperfect preservation at the lateral edge of the skull table prevents
any statement as to whether or not the otic notch was closed, and of
course the absence of the premaxillaries makes it impossible to know
if an internarial opening was present.

The pitting of the dermal skull roof (not shown in Fig. 1) is of a
pattern common among labyrinthodont amphibians, with essentially

126 Bulletin So. Calif. Academy of Sciences

circular pits surrounded by narrow, anastomosing ridges. There are
no prominent exostoses such as are found in many dissorophids, but
there is a slight swelling midway along the occipital rim of the post-
parietal, and a ridge passes along the lateral part of the prefrontal
bone forward and ventrad toward the posterior end of the external
naris. Even though these elevations are not strongly developed, they
do seem to indicate tendencies parallel to those of dissorophids.

The frontals are about one and one-half times as long as the parietals.
Conspicuously greater length of the frontals, as compared with the
parietals, is a feature of trematopsids, more so in Acheloma than in
the later Trematops (Olson, 1941). Among dissorophids, the frontals
and parietals tend to subequality in length, although the frontal is
considerably the longer bone in the primitive dissorophid Tersomius
(Carroll, 1964b) and also in the trematopsid-like Longiscitula (DeMar,
1966a). Another way in which Ecolsonia resembles Acheloma more
than it does Trematops is in the small size of the tabular. In this
connection, it may be noted that E. cutlerensis is roughly equivalent
in age to the species of Acheloma, which are known from the Wichita
Group of north-central Texas — Wolfcampian to lowest Leonardian.
Trematops is known only from higher levels in the Leonardian —
from the Clear Fork Group — and the poorly koown Trematopsis
(Olson, 1956) is based on a single species known only from still higher
in the Clear Fork.

A somewhat dissorophid-like feature of Ecolsonia is the broad
entry of the frontal bone into the border of the orbit. This is most
pronounced in dorsal aspect where the shortest distance between the
prefrontal and postfrontal bones is 12 mm, but in a lateral view of the
orbital rim it may be seen that these bones send tongues toward one
another that narrow the entry of the frontal to about 7 mm. In con-
sideration of these details, the degree of entry of the frontal into the
orbital margin in Ecolsonia actually lies somewhere between the
conditions seen in trematopsids and dissorophids (see figures by
Olson, 1941 and Carroll, 1964b).

The frontal forms a large part of the orbital margin in Longiscitula
too, and as previously noted, this form has a trematopsid-like narial
opening, but the differences between this genus and Ecolsonia are
immediately apparent. The skull in Longiscitula is remarkable for its
overall slenderness, whereas in Ecolsonia the skull seems to be of
more “normal” proportions. Furthermore, the internarial width is
much less in Longiscitula. The holotype of L. houghae (DeMar,
1966a, Fig. 2) has a skull about 125 mm long, a length that cannot be
much different from the original length of the holotypic skull of E.

Fossil Amphibians 127

cutlerensis, but the distance between contralateral external nares in
the holotype of L. houghae is only about 14 mm — measured midway
along the nares — whereas the corresponding distance in the holotype
of E. cutlerensis is about 34 mm. Ecolsonia obviously has a much
broader snout, with proportions similar to those of Acheloma.

The external narial opening deserves special attention. The one on
the left side of the holotype of E. cutlerensis is better preserved, but
part of the smooth dorsal rim can also be seen on the right side. On
the left side, only the posterior part of the rim — the border of the
“antorbital fossa” — is preserved, but this is enough to show that the
anterior portions of the prefrontal and lacrimal bones are widely
separated from one another, and that these bones have smooth margins
that form the posteromedial and posterolateral boundaries of the
opening. Parts of these bones directly in front of the anteriormost
extension of the orbit are missing, but projection of the preserved
portion of the orbital rim shows that the suture between them could
have been no longer than in Acheloma. Anterior to the prefrontal, the
nasal bone forms part of the medial border of the narial opening. The
picture is comparable in detail to the condition in Acheloma, and by
comparison with that genus, it is probably safe to assume that the
premaxillary and maxillary bones completed the border. About 7 mm
in front of the anterior termination of the suture between the prefrontal
and nasal bones, a short spur of the nasal projects laterad into the narial
opening. Such a spur is present in Acheloma and Trematops too; it
partially subdivides the external narial opening into an anterior part —
primarily for olfaction according to Olson (1941) — and a posterior
part or “antorbital fossa” — which served principally for the intake of
air according to Olson. Indeed, the external narial opening in Ecolsonia
is so like those in Acheloma and Trematops — and this is such an
unusual kind of narial aperture — that the only conceivable assigna-
tion of this new genus would be to the Trematopsidae were it not for
the demonstration by DeMar (1 966a) of the basically dissorophid nature
of Longiscitula.

The occipital surfaces of the postparietal and tabular bones in
Ecolsonia are like those figured for Trematops by Olson (1941, Fig. 8).

It is in the greatly expanded interpterygoid vacuities of the palate
that Ecolsonia shows its closest resemblance to the dissorophids.
Olson (1941) felt that the palates in Acheloma and Trematops were
so alike that a description of one would suffice for both, and he there-
fore illustrated only the condition in Trematops. He remarked that,
despite general similarities between trematopsids and dissorophids,
the latter are quite different in that their interpterygoid vacuities are

128 Bulletin So. Calif. Academy of Sciences

very large and in that the parasphenoid makes contact with the vomers.

As may be seen in Olson’s illustration of Trematops (1941, Fig. 8),
the interpterygoid vacuities are moderately developed, forming in
combination an opening that Olson characterized as “heart-shaped”
and that narrows rapidly towards its apex at the anterior end. As they
pass forwards, the lateral margins of the vacuities converge on each
other at an angle of about 45 degrees. Olson notes that details of the
relative contributions of the pterygoids, palatines and vomers to the
margins of the vacuities are unclear.

Only the anterior portion of the palate is preserved in the holotype
of E. cutlerensis (Fig. 1), but the fact that the palatine processes of the
vomers diverge from one another at about a right angle shows that the
interpterygoid vacuities must have been almost as wide as in dis-
sorophids. Indeed, details of the preserved part of the palate are very
similar to those in dissorophids (see figures by Carroll, 1964b). The
palatine processes of the vomers are remarkably long, as in the Pennsy]l-
vanian dissorophid Amphibamus and the primitive Early Permian —
form Tersomius. Only small fragments of the palatines remain, but
it is clear that they formed the posterior boundaries of the internal
nares; the medial boundaries are formed by the vomers. As in Acheloma
and Trematops, the internal naris lies below the posterior part of
the external narial opening. The ventral surface of the conjoined vomers
is broadly rounded, but the lateral surfaces are nearly vertical, with
the internal narial borders lying about 5 mm dorsal to the major
vomerine surface; the palatine processes are semicylindrical. Both
parts of each vomer are covered with a shagreen of tiny teeth, and a
labyrinthine tusk can be seen on the anterolateral part of the left
vomer — the corresponding region on the right is damaged. This
resembles the condition in the dissorophid Broiliellus; among tre-
matopsids, tusks are known in this position in at least Trematops
and Trematopsis (Olson, 1941, 1956). The anteromedial parts of
the conjoined vomers are inclined dorsad as in other trematopsids
and also dissorophids. As in dissorophids, the anteromedial boundaries
of the interpterygoid vacuities are formed by the vomers; conditions
in this region in previously known trematopsids are unclear.

In Acheloma and Trematops, according to Olson (1941), the
parasphenoidal rostrum does not make contact with the vomers, but
although there are a number of fractures in this region in the holotype
of E. cutlerensis, it is clear that there is such a contact in this form, as
in dissorophids. The suture is difficult to follow, but the anterior end
of the parasphenoid seems to be broadened and apparently underlaps

Fossil Amphibians 129

the posteromedial parts of the vomers. Only a small fragment of the
anteriormost part of the sphenethmoid is preserved.

The nature of the palate in Ecolsonia clearly distinguishes this
genus from both Acheloma and Trematops. Distinction from Trema-
topsis (Olson, 1956), in which the palate is very poorly known, must be
based on other grounds. Trematopsis is remarkable for its very large
orbit. Only the upper parts of the orbital rim are preserved in the
holotype of E. cutlerensis, but restoration shows that the orbital
diameter must have been somewhat less than 30 mm, which gives a
figure of, very roughly, 0.23 for the ratio of orbital diameter to esti-
mated overall length of skull roof. This figure is very close to the
ratios 0.25 and 0.24 for Acheloma whitei and Trematops willistoni
(Olson, 1956, Table 2), but known skulls in both of these species are
only about one-half as long as the estimated original length of the
holotypic skull of E. cutlerensis. In a skull referred to Acheloma
cumminsi that is almost one and one-half times as long as that of E.
cutlerensis, the ratio is only 0.15 (Olson, 1956). It would seem, then,
that the orbit in Ecolsonia is relatively large as compared to Acheloma
and Trematops, and it is significant that in this way too, Ecolsonia
is like dissorophids; the broader entry of the frontal into the orbital
margin in Ecolsonia as compared to Acheloma and Trematops is
probably correlated with this relatively greater orbital diameter. The
ratio in Trematopsis seltini is 0.24, but the only known skull is 230
mm long, about 100 mm longer than the estimated original length of
the holotypic skull of E. cutlerensis. As Olson (1956) notes, small
species usually have orbits that are proportionately much larger than
the orbits in larger species of the same genera. Thus, the large orbit
in Trematopsis does adequately distinguish this genus from Ecolsonia.

CONCLUDING REMARKS

Ecolsonia shows an interesting combination of trematopsid-like and
dissorophid-like features. Except for incipient swellings and the
enlarged orbit, the dermal skull roof — especially in the presence
of the elongated external nares — looks like those of trematopsids;
but the palate looks like those of dissorophids. Although their armor
apparently was not developed until Permian time, the basic pattern
of the dissorophids had already been established in Pennsylvanian
time, as shown by Amphibamus (Carroll, 1964b), and it is thus highly
unlikely that dissorophids were derived from trematopsids; the fairly
primitive pattern of the palate in Acheloma and Trematops makes

130 Bulletin So. Calif. Academy of Sciences

the reverse derivation seem also unlikely. What Ecolsonia, and
Longiscitula, show is that there were parallel morphological tendencies
in the evolution of trematopsids and dissorophids, and this reinforces
the assessment by Olson (1941) of close relationship between
these families. Indeed, these two genera may represent intermediate
shoots from the same basal stock that gave rise to trematopsids and
dissorophids.

ACKNOWLEDGMENT

I am grateful to the National Science Foundation for support of this study through
grants GB-1014 and GB-7784.

LITERATURE CITED

CARROLL, R. L., 1964a. The relationships of the rhachitomous amphibian
Parioxys. Amer. Mus. Novitates, No. 2167: 1-11.

1964b. Early evolution of the dissorophid amphibians. Bull. Mus. .
Comp. Zool., Harvard, 131: 161-250.

DEMar, R. E., 1966a. Longiscitula houghae, a new genus of dissorophid amphib-
ian from the Permian of Texas. Fieldiana, Geol., 16: 45-53.

1966b. The phylogenetic and functional implications of the armor of
the Dissorophidae. Fieldiana, Geol., 16: 55-88.

1968. The Permian labyrinthodont amphibian Dissorophus multicinctus,
and adaptations and phylogeny of the family Dissorophidae. J. Paleont.,
42: 1210-1242.

LANGSTON, W., JR., 1953. Permian amphibians from New Mexico. Univ. Calif.
Publ. geol: Sci., 29: 349-416.

OLson, E. C., 1941. The family Trematopsidae. Jour. Geol., 49: 149-176.

1956. Fauna of the Vale and Choza: 12, A new trematopsid amphibian
from the Vale Formation. Fieldiana, Geol., 10: 323-328.

Romer, A. S., 1947. Review of the Labyrinthodontia. Bull. Mus. Comp. Zool.,
Harvard, 99: 1-368.

Accepted for publication May 13, 1969.

Bull. So. Calif. Acad. Sci. 68(3): 131-137, 1969

RESPONSES IN BAHAMIAM SHARKS AND GROUPERS
TO LOW-FREQUENCY, PULSED SOUNDS

DONALD R. NELSON, RICHARD H. JOHNSON,
AND LARRY G. WALDROP

Department of Biology
California State College
Long Beach, California 90801

ABSTRACT: Responses to low-frequency (50-200 Hz), pulsed
sounds were observed in reef sharks (Ginglymostoma cirra-
tum, Sphyrna tiburo), pelagic sharks (Carcharhinus falci-
formis), and in several species of groupers (Mycteroperca
bonaci, M. venenosa, and Epinephelus striatus). By three
criteria for positive responses, (i) number present, (ii) close-
ness of approach to transducer, and (iii) attentiveness of
behavior, sharks and groupers of reef areas scored higher
during periods of sound playback than during control (quiet)
periods. Pelagic silky sharks were attracted to low-frequency,
pulsed sounds and apparently habituated to them on both an
intra-daily and inter-daily basis. Acoustic responses were
suspected when certain sharks and groupers were observed to
be attracted to speared, struggling fish and to schools of fish
feeding in an excited manner.

INTRODUCTION

The attraction of reef and pelagic fishes to acoustic signals was studied
during an expedition to the Bahama Islands in the summer of 1968.
Earlier sound-playback experiments conducted on reefs south of
Miami, Florida, had shown that certain sharks were attracted to low-
frequency (20-60 Hz), pulsed sounds resembling those of speared,
struggling fish (Nelson and Gruber, 1963; Nelson, 1966). More recent
playbacks by Banner (1968) demonstrated that young lemon sharks,
Negaprion brevirostris, of a size approximating that of the species
at birth, could be attracted by pulsed noise (broad band), sometimes
becoming excited to the extent of biting the speaker. Steinberg et al.
(1965), using the fixed-installation, underwater, video-acoustic system
at Bimini, Bahamas, noted that yellowtail snappers, Ocyurus chrysurus,
were attracted by pulsed 20-Hz sounds and that certain other reef
fishes responded in various ways to playback of recordings of natural
fish sounds. Experiments by Richard (1968), also utilizing the video-
acoustic system at Bimini, confirmed the effectiveness of low-frequency
(25-50, 100-200 Hz), pulsed sounds in attracting several species of

131

162 Bulletin So. Calif. Academy of Sciences

reef sharks and also demonstrated similar responses in some predatory
teleosts such as groupers and snappers. Further studies (Myrberg
et al., 1969), using the Bimini video-acoustic system demonstrated
responses by sharks, primarily Rhizoprionodon sp., to somewhat
higher-frequency signals consisting of “overdriven” sine waves with
fundamentals to 800 Hz, and bands of filtered noise with frequencies
to 500-1000 Hz. The sharks were noted to habituate to these signals
and, in addition, to show an increased swimming activity as their
numbers in the area increased.

In the present study, sound playback was conducted from an
anchored 7-m powerboat. Data were gathered directly, by an observer
in the water at the stern of the boat from which the transducer was
suspended at a depth of about 10 m. Underwater visibility permitted
effective observation within a radius of approximately 20 to 30 m.

The transmitting system included a Uher 4000 Report-L tape
recorder, Heathkit AA-23 amplifier (30 watts), and a U.S. Navy
J9 sound-projecting transducer. Sound levels were measured with a ~
U.S. Navy H44 hydrophone (with preamplifier) matched to a General
Radio 1564A sound and vibration analyzer.

The test sound consisted of intermittent trains of pulses of filtered
random noise which were hand pulsed (when recorded) to simulate a
struggling-fish sound. This signal contained frequencies from 50 to
200 Hz (30 dB/ octave attenuation outside this range), pulse rates of
4 to 7 sec, pulse lengths of 0.14 to 0.25 sec, train lengths of 0.3 to 7
sec, and inter-train intervals of 0.7 to 10 sec. The signal was projected
into the water at a sound-pressure level of about 50 dB above 1
dyne/cm? at one m, a level calculated to be detectable above ambient
noise at distances of at least several hundred m.

OBSERVATIONS ON THE REEFS

Reef playback was conducted in water 10 to 20 m deep, over bottom
types (coral rocks and ledges) favorable to groupers, at various locations
south of Bimini and in the vicinity of Fresh Creek, Andros Island. At
each site, one 15-min control period (transducer in water, sound off)
and one 15-min sound period were conducted. The period type
presented first was alternated between control and sound. We recorded
(i) number and ‘species of fish observed, (ii) fish-transducer distance
at the fish’s closest approach, and (iii) behavior of the fish, especially
the orientation of its longitudinal axis relative to the direction of the
transducer. Behaviors such as approaching, circling, sitting facing,
and tail-standing facing were classified as attentive; swimming away,

Fish Behavior 133

passing by, and entering hole were considered non-attentive. In some
cases a behavior, eé.g., sitting broadside, was classified as ambiguous.

All three response measures indicated positive responses (attraction)
to the test sound for certain sharks and groupers (Table 1). During
the sound periods more individuals were seen, they approached closer,
and their behavior appeared more attentive than during the control
periods. Although the greater fish-transducer distance for black
groupers, Mycteroperca bonaci, during sound periods than during
control periods may seem to be contrary evidence, it is not. Instead it
was because many newly attracted individuals of this basically shy
species remained near the limit of visibility, a relatively long distance
from the transducer.

A typical response of nurse sharks, Ginglymostoma cirratum,
observed during the sound periods was to approach at medium speed,
swimming directly at the transducer, then to turn away or circle briefly,
often within 1 m of the transducer. Groupers, Mycteroperca bonaci,
M. venenosa, and Epinephelus striatus, usually approached more
slowly, often by a more circuitous route, and with frequent stops. They
typically remained at or near their point of closest approach until the
end of playback, usually hovering just off the bottom facing the
transducer. If relatively close to but below the transducer, groupers
sometimes assumed an upward inclination of the body axis, a behavior
we designated tail-standing.

We also observed responses by sharks and groupers to the naturally
occurring signals of wounded fish during times when we were spear-
fishing. On two separate occasions, nurse sharks located caves in which
wounded fish had taken refuge. In both cases the rapidity of arrival
(1-2 min) and the direction of approach suggested that the sharks were
not using olfactory orientation until they reached the immediate vicin-
ity of the wounded fish. Another incident suggesting acoustic attraction
occurred when a large (30-Kg) black grouper rapidly approached to
within 3 m of a hole containing a freshly speared, violently struggling
fish. This happened within 10 sec of the time the fish was speared.
Later that afternoon, this grouper was seen to engulf and swim away
with a wounded 4-kg parrotfish, Scarus coelestinus, that had broken
free from a spear.

Several times we observed reef sharks, Carcharhinus springeri, and
sharpnose sharks, Rhizoprionodon sp., during spearfishing when none
had been seen previously. In two incidents for each of these species,
the sharks appeared within about 30 sec after a speared fish had
struggled vigorously. These observations strongly suggest acoustic
attraction. It is unknown, therefore, why we did not see these sharks

134 Bulletin So. Calif. Academy of Sciences

during our sound-playback periods in this area, especially since
Myrberg et al. (1969) report attraction to their test sounds in both
species. Perhaps our particular test signal was inappropriate for
attracting these species.

OBSERVATIONS AT SEA

Open-ocean playback was conducted at a U.S. Navy (AUTEC)
deep-moored buoy in the center of the Tongue of the Ocean, off
Fresh Creek, Andros Island, in water 1830 m deep with visibility
exceeding 30 m. A semi-resident group of 1-2 m silky sharks, Car-
charhinus falciformis, was found regularly at the buoy. Of 22 indi-
viduais tagged or otherwise recognizable, 9 were seen on 2 or more
days (maximum, 8; mean 3.3 days) during our 9 days of observation
at the buoy. Other pelagic fishes present were blue runners, Caranx
fusus; rainbow runners, Elagatis bipinnulatus; almaco jacks, Seriola
rivoliana; dolphin, Coryphaena hippurus; and wahoo, Acanthocybium ~
solanderi.

At the beginning of each of six consecutive days of playback at the
buoy, we started with a control period and followed it with a sound
period. Since sharks and other fishes were usually present in considerable
numbers, even during the control periods, we observed primarily the
reactions of individuals before and during sound playback, rather
than numbers of individuals present. When the transducer was first
lowered into the water, a few sharks sometimes gathered, circled one
or two m away, and soon dispersed. Blue runners also occasionally
investigated the newly submerged transducer. Except for this infre-
quent initial interest, the sharks and other fishes apparently gave
little or no attention to the transducer during the control periods.

During sound playback, however, numerous sharks reacted, some
within seconds of the onset of sound, by approaching the transducer at
higher-than-normal speeds, circling it closely, and sometimes possibly
touching it. A typical acoustic response is exemplified by one shark
which, before the sound, was swimming slowly about 15 m beyond the
transducer. At the sound onset it turned, swam with accelerated speed
directly at the transducer, and then abruptly turned away (with a
noticeable flinching of the body) when about 0.3 m from the transducer.
Most of the vigorous responses occurred during the first few minutes
of the 15-min playback period. No definite responses to the test sound
were observed in any pelagic fishes other than sharks.

At least 12 responses were observed during the sound period on the
first day of playback. On the second day, about 6 to 8 responses

Fish Behavior ISIS

occurred, all during the first two minutes. On the third day, although
several sharks were present as usual, only one vigorous response and
several mild responses were seen. On the fourth day one well-defined
and one mild response was seen. On the fifth day no responses were
observed, and on the sixth only a questionable response.

This reduction in number of responses (apparent habituation) on
successive days of playback is evidence for day-to-day retention of
learned information, /.e., the sharks learned that our test sound was
not associated with food. The observed habituation to the test sound
during a single 15-min period agrees with the observations of Myrberg
et al. (1969) indicating habituation in sharpnose sharks, Rhizopriono-
don sp., during successive 3-min sound periods separated by 3-min
control periods.

On our last visit to the buoy we speared several 1-kg blue runners
in the presence of silky sharks. The responses of the sharks to these
fish struggling on the spear were much more vigorous than any
responses to the test sounds previously presented. The sharks became
excited within 2-3 sec, dashed about at high speed, and soon tore the
fish from the spear. At times, two or more sharks competed for bites
of the same small jack, each attempting to eat it off the spear at the
same time. The rapidity of these responses precluded odor as the
initiating stimulus. It seemed that auditory detection of the fishes
struggling sounds or visual detection of the “flashing” shiny sides of
the fish, or both, played important roles as attracting stimuli. If sound
was primarily responsible, then it is evident that the natural struggling
sounds possessed a higher stimulus value than our artificial test sound.

On several occasions at the buoy, while we were feeding fish, it
appeared that the sudden movements and excited actions of a group of
feeding blue runners had a powerful stimulatory effect on nearby
sharks. At such times, sharks, which had been circling slowly in the
distance, became excited, approached the feeding jacks, and competed
with them for pieces of food. It was evident that the stimulus was the
excited activity of the jacks and not the presence of food, because
pieces of food alone elicited no particular excitement from the sharks
until the odor was detected.

These observations support the hypothesis of Banner (1968) that
hydroacoustic stimuli associated with normal feeding behavior in
certain fishes may be very relevant stimuli to sharks in their everyday
lives — possibly as significant or more so than the sounds of wounded,
struggling fish. Struggling sounds of the type generated by hooked or
speared fish, while of unquestionable attractiveness to sharks, would
not occur very often in areas rarely frequented by man. During natural

136 Bulletin So. Calif. Academy of Sciences

predation, however, some vigorous struggling probably precedes
ingestion when small prey fish are slashed or siezed by larger predatory
fish. It is suggested that efforts be made to record accurately a wide
variety of hydrodynamic sounds produced by feeding and struggling
fishes. Analysis of these sounds should be a prerequisite to further
playback experiments aimed at determining the significance of sounds
in the natural feeding behavior of fishes.

ACKNOWLEDGEMENTS

Financial assistance for this study was provided through project NO001 4-68-C-
0318, Oceanic Biology Programs, Office of Naval Research. We also express our
sincere thanks to Robert F. Mathewson, Director of the Lerner Marine Labora-
tory, Bimini, Bahamas, and to Edward W. Crawford of Palm Beach, Florida,
for help with the logistical aspects of the study.

LITERATURE CITED

BANNER, A., 1968. Attraction of young lemon sharks, Negaprion brevirostris, by
sound. Copeia. 1968: 871-872.

MyrBeErG, A. A. JR., A. BANNER, AND J. D. RICHARD, 1969. Shark attraction using
a video-acoustic system. Marine Biol. 2: 264-276.

NE tson, D. R., 1966. Hearing and acoustic orientation in the lemon shark,
Negaprion brevirostris (Poey), and other large sharks. Diss. Abstracts.
27: 333B.

NEtson, D. R. AND S. H. GRUBER, 1963. Sharks: Attraction by low-frequency
sounds. Science. 142: 975-977.

RICHARD, J. D. 1968. Fish attraction with pulsed, low-frequency sound. J. Fish.
Res. Bd. Canada. 25: 1441-1452.

STEINBERG, J. C., W. C. Cummincs, B. D. BRAHY, AND J. Y. MACBAIN (SPIRES),
1965. Further bio-acoustic studies off the west coast of North Bimini, Baha-
mas. Bull. Mar. Sci. 15: 942-963.

Accepted for publication April 28, 1969.

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Bull. So. Calif. Acad. Sci. 68(3): 138-144, 1969

PIMELIAPHILUS ZELEDONIN. SP. (ACARI,
PTERYGOSOMIDAE), A PARASITE OF TRIATOMA
DIMIDIATA (LATR.) (HEMIPTERA, REDUVIIDAE)!

IRWIN M. NEWELL
Department of Life Sciences
University of California, Riverside 92502
and

RAYMOND E. RYCKMAN
Department of Microbiology, School of Medicine,
and Department of Microbiology, Graduate School,
Loma Linda University, Loma Linda, California 92354

ABSTRACT: Pimeliaphilus zeledoni n. sp. iS compared in
detail with P. andersoni Newell & Ryckman 1966. Although
seemingly very closely related, these species parasitize dif-
ferent species of hosts whose presently known distributions
are allopatric.

INTRODUCTION

Subsequent to the publication of our monograph (Newell and Ryck-
man, 1966) on the species of Pimeliaphilus attacking Triatominae,
we received a good series of a Pimeliaphilus collected from Triatoma
dimidiata (Latreille), by Dr. Rodrigo Zeledon, of the University of
Costa Rica. Because of the importance of this mite in Dr. Zeledon’s
current research on T. dimidiata we are naming it at this time. Accord-
ing to Dr. Zeledon (personal communication), these mites interfere
with the molting process of the nymphal bugs.

At first, the mite appeared to be P. andersoni Newell and Ryckman
1966, but because of the considerable differences in host and geo-
graphical distribution it was compared carefully with that species on
the basis of all characters given in the tabular key in Newell and Ryck-
man 1966, pp. 414-417. This substantiated the similarity of the Costa
Rica form to P. andersoni, but left a residue of apparently significant
differences which did not agree well with any assumption that the two
forms are identical. Accordingly we are describing it as a new species,
Pimeliaphilus zeledoni.

"This study was supported by a grant from the National Science Foundation
(GB-5027) to the University of California at Riverside, and by a Fellowship
in Tropical Medicine from Louisiana State University.

138

New Species of Mites 139

Figures 1-7. Pimeliaphilus zeledoni, n. sp., female. Fig. 1, dorsum. Fig. 2,
scutum. Fig. 3, anal region, dorsal. Fig. 4, left palp, posterior. Fig. 5, venter.
Fig. 6, tarsus I. Fig. 7, tibia and tarsus of palp, posterior, solenidion broken off
at base.

140 Bulletin So. Calif. Academy of Sciences

The diagnosis below is in the format followed in Newell and Ryck-
man 1966. Those unfamiliar with Pimeliaphilus and with the terms
and conventions used will find it necessary to refer to that paper for
the necessary explanations, and for references to illustrations. Because
of the similarity of P. zeledoni to P. andersoni, which was well illus-
trated in that paper, illustrations here will be confined to photographs.
These, in conjunction with the data given in the diagnosis, are adequate
to characterize the species.

The photographs in this paper were taken with a Leitz Aristophot
camera, using 71 mm Adox film. All specimens were mounted in Hyrax.
Donna Claycomb of the University of California, Riverside, prepared
the specimens for study and assisted in the photography.

Pimeliaphilus zeledoni Newell and Ryckman, new species
Figures 1-13

Female. — \diosoma (Figs. 1, 5) 557-687 (616 » )° long in mature
but non-replete individuals, L/W 1.25-1.34 (1.30)°. The largest replete -
individuals in the series measured 788-938 (860 » )*, L/W 1.09-1.21
(1.15)*. Scutum with 3 pairs of setae. Medial length of scutum 147-157
(153 1 )°, L/W .89-1.03 (.96)°. Scutal setae | at -.05 to -.13 (-.09)°; that
is, the centers of their bases are anterior to the median point of the con-
cave anterior margin of the plate (Fig. 2). Scutal setae 2 at .02-.06
(.04)°, setae 3 at .18-.24 (.21)°. Ratio of interval between right and
left setae 1/ interval between levels of setae 1 and 3 = 2.08-2.94
(2.55)°. Ratio of interval between levels of setae 2 and 3/ interval
between levels of setae 1 and 2 = 1.00-2.18 (1.37)°. Setae 3 more
widely spaced than setae | in all females seen, 174-218 (192 » )’ long.
Cornea on a small setigerous sclerite. Dorsal and marginal setae,
excluding those flanking the anal cleft, numbering 134-14® each side.
Dorsalmost setae of anal papilla arboriform (Fig. 3).

Coxal setae numbering 2-2-3-0! or 2-2-3-18. In two specimens,
coxa IV had 0 setae on one side, | seta on the other; the same variation
has been noted in P. andersoni. Supracoxal seta present on I, seemingly
recessed in part only. Medial seta of coxa I slender, smooth, flexible.
Lateral seta of coxa II also slender, tapering, 1 or 2 minute barbs.
Medial seta of coxa II 49-53 (50 » )® long.

Medial seta of coxa II completely smooth’, lateral seta also smooth
or with | or 2 faint barbs; both setae of II slender, tapering uniformly.
Medial seta of coxa II 49-53 (50 »)®. Ventral setae of gnathosoma
slender, smooth*. Dorsal surface of gnathosoma uniformly arched,
without pronounced sculpturing, peritremes not recessed in surface
but lying above it. Width of peritremes / width of gnathosomal base

New Species of Mites 141

.84-.92 (.88). Peritremes forming a low, flat W. Rostral flange collar-
like, as in P. gloriosus Newell and Ryckman. Trochanter of palp a very
short cylinder. Femur and patella of palp not fused, each with a single
dorsal seta (Fig. 4). Dorsal seta of femur penicillate, barbed, 82-99
(89 »)° long. Palpal tarsus (Fig. 7) a short cylindrical cap, its length
about equal to its diameter; with a solenidion, | eupathid, 5 normal
setae, and a very minute (ca. .1 » ) spike between the solenidion and
eupathid, as in other species of the genus. In Fig. 7, only the base of
the solenidion is shown; the shaft is broken off.

Figures 8-13. Pimeliaphilus zeledoni, n. sp., male. Fig. 8, dorsum. Fig. 9, scutum.
Fig. 10, dorsal setae 9 and 10, showing setigerous sclerites separated by striae.
Fig. 11, anal papilla, dorsal. Fig. 12, dorsal setae 9 and 10, showing setigerous
sclerites fused. Fig. 13, dorsal setae 9 and 10, showing setigerous sclerites partially
separated by striated cuticle.

142 Bulletin So. Calif. Academy of Sciences

Anterior seta of trochanter I 39-49 (46 1 )® long. None of femora of
legs divided. Bothridion of tibia III at .25-.30 (.28)°, peripectinate
throughout, especially in distal portion. Bothridion of tibia IV at
.30-.33 (.32)°. Tibia IV 71-74 (73 » )° long. Basal solenidion of ta I
at .21-.24 (.22)°, distal solenidion at .39-.44 (.41)° (Fig. 6). Distal
solenidion of ta I 6.67? as long as companion seta. Basal solenidion
17-20 (19 » )? long, distal solenidion 74-80 (77 » )° long. Dorsal setae
between paired eupathidia of ta I narrow, frond-shaped, pectinate.
Solenidion of tarsus II at .19-.24 (.20)°, 11-14 (12, )° long. Solenidion
of tarsus III at .18-.20 (.19)°, 4-5 (4.5 » )* long. Each claw of ta II with
2 or 3 tenent hairs on each side of the shaft.

Male. — I\diosoma (Fig. 8) 339-405 (380 , )° long. Scutum (Fig. 9)
with 4 pairs of setae. Eleven pairs of dorsal and marginal setae, exclud-
ing those of the anal papilla. Pairs 9 and 10 are sometimes borne on a
single sclerite (Fig. 12), but in other cases this sclerite is partly (Fig. 13)
or completely (Fig. 10) divided by striated cuticle. Anal papilla (Fig.
11) in dorsal view with chaetotaxy similar to that illustrated for P. -
joshuae Newell and Ryckman 1966 (p. 434, Fig. 76).

Type Locality. — Universidad de Costa Rica, Ciudad Universitaria,
Costa Rica. In laboratory cultures of Triatoma dimidiata. The original
source of these cultures is not known, but they originated from near
San Jose, Costa Rica.

Remarks. — We are still not certain that the form described here
should be considered a species distinct from P. andersoni or only a
subspecies. Further studies of the geographical distribution of Ptery-
gosomidae parasitic on Triatominae may help to resolve the question.
More extensive collections of P. andersoni would also be of value. The
data available on the females of P. andersoni are based on only two
specimens. These are from well separated areas (Arizona and Texas),
on different hosts [ 7. recurva (Stal) 1868 and T. gerstaeckeri (Stal)
1859]; yet they show remarkable similarity to each other (Newell and
Ryckman 1966, p. 417, table 2). It does not seem illogical to believe
that the apparent differences between P. andersoni and P. zeledoni
will become increasingly significant as more data accumulate. Accord-
ingly we will presently regard P. zeledoni as specifically distinct from
P. andersoni.

There is no other species yet described in the genus with which it
needs critical comparison. The form of the rostral flange, (character 3),
the wide separation of scutal setae 3 (character 5), the extreme length
of scutal setae 3 (character 16), the extreme shortness of the proximal
solenidion of tarsus I (character 24), and the shortness of the scutum

New Species of Mites 143

(character 29) all contribute to the similarity in facies between P.
andersoni and P. zeledoni.

The continuously varying characteristics which separate the two
forms most convincingly are the following:

Character P. andersoni P. zeledoni
16 Length of scutal setae 3 244-245 (245)? 174-218 (192)?
21 Length of dorsal seta of fe II 98 59-78 (69)°
(See ERRATUM below)
23 Position of proximal solenidion .321 PDE Wai22)>
of ta I
25 Length of distal solenidion 51-67 (S59)? 74-80 (77)?
of ta I
28 Median length of scutum 100-131 (116)? 147-157 (153)5
29 L/W of scutum .64-.70 (.67)? .89-1.03 (.96)®
31 Position of scutal setae 2 -.01 to -.03 (-.02)? .02-.06 (.04)>

33 Interval between scutal setae 3 3.11-3.13 (3.12) 2.08-2.94 (2.55)5
of right and left sides/level
of setae 3 minus level of setae 1

34 Level of scutal setae 2-3/level 2.59-3.16 (2.88)? 1.00-2.18 (1.37)°
of setae 1-2

Most of the above differences would appear to lie outside the range of
normal intraspecific variability, especially considering that P. zeledoni
and P. andersoni are essentially identical in most of the continuously
varying characteristics measured for these species (characters 14, 15,
Paterno 0522-24265 27, 30-and 32):

The variation in degree of separation between the setigerous sclerites
of dorsal setae 9 and 10 shows that this character is of little or no value
in separating males of different species of Pimeliaphilus. This is a
general type of variation in this and probably related genera — closely
placed sclerites vary in the degree of fusion or separation by inter-
vening striated cuticle.

Erratum. —In the statement of Morphological Characters and
Variants in Pimeliaphilus (see Newell and Ryckman 1966, p. 416),
character 21 was stated as “Length of dorsal seta of tibia II (30-125, ).”
This should read “Length of dorsal seta of femur IT (30-125 1 ).”

Host Distribution. — The host-parasite relationships of Pimeli-
aphilus andersoni and P. zeledoni raise a number of questions con-
cerning the biogeographical associations of these parasites and their
hosts. The known hosts for P. andersoni are Triatoma recurva (Stal)
1868, and T. gerstaeckeri (Stal) 1859. T. recurva is known from
northwestern Mexico in the states of Nayarit, Sinaloa and Sonora, and
the central plateau of Arizona in the United States; while 7. gerstaeck-

144 Bulletin So. Calif. Academy of Sciences

eri occurs in northeastern Mexico and central and western Texas in
the United States. Pimeliaphilus zeledoni at this time is reported from
Triatoma dimidiata (Latr.) 1811, collected near San Jose, Costa Rica
in Central America. We have no specimens of Pimeliaphilus from the
T. dimidiata populations between Costa Rica and east central Mexico.
Populations of T. dimidiata are geographically widespread from
northern South America through Central America to north of Vera
Cruz in Mexico. There is no reason to believe, at the present time, that
the distributions of 7. gerstaeckeri and T. dimidiata are sympatric
anywhere. The southernmost distribution of 7. gerstaeckeri in north-
eastern Mexico and the northernmost distribution of 7. dimidiata in
east central Mexico are separated by some 100 kilometers (Tay, 1969,
pp. 39, 40). In the past these species may have been sympatric. In
addition to their allopatric distributions, these bugs also differ eco-
logically. T. gerstaeckeri inhabits nests of wood rats of the genus
Neotoma, while T. dimidiata is most often collected from man-made
dwellings. T. dimidiata, however, has also been collected in association -
with sylvatic mammals other than Neotoma. The question which
remains is: Why are such closely related parasitic mites found on three
allopatric populations of rather diverse Triatominae with distinctly
different vertebrate hosts? The answer to this question will probably
emerge as we learn more of the ecological and geographical distribution
of the mammalian hosts, triatomine and pterygosomid parasites, and
apply this against the background of post-Pleistocene history of south-
western North America, Central and South America.

LITERATURE CITED

NEWELL, I. M. AND R. E. RYCKMAN, 1966. Species of Pimeliaphilus (Acari:
Pterygosomidae) attacking insects, with particular reference to the species
parasitizing Triatominae (Hemiptera: Reduviidae. Hilgardia, 37: 403-436.

Tay, J., 1969. Localidades nuevas de triatominos mexicanos y su infeccién
natural por Trypanosoma Cruzi. Revista “Medicina” Mexicana, 49: 35-43.

Accepted for publication May 13, 1969.

Bull. So. Calif. Acad. Sci. 68(3): 146-160, 1969

A REVIEW OF THE
COLUBRID SNAKE GENUS AMASTRIDIUM

LARRY DAVID WILSON
Department of Biology
University of Southwestern Louisiana
Lafayette, Louisiana 70501

: and
JOHN R. MEYER
Department of Biological Sciences
University of Southern California
Los Angeles, California 90007

ABSTRACT: Analysis of 18 characteristics of scutellation,
osteology, coloration, and body measurement indicates that
the characteristics used to distinguish Amastridium veliferum
and A. sapperi are disconcordant. Numbers of ventrals and
maxillary teeth vary clinally from high numbers in the
northern portion of the range to low numbers in the southern
portion. Specimens north of and including Honduras have
a loreal scale, while those south of Honduras lack this scale.
Specimens from Panama have a lighter dorsal and ventral
coloration and more prominent light lateral spots than those
from the remainder of the range. Grooving of the rear teeth is
not characteristic of all specimens of “sapperi’ as purported
by previous authors. In view of the disconcordant nature of
these characteristics and the absence of additional distin-
guishing features to complement any of the other variable
characteristics, we prefer to recognize only a single species,
veliferum, in the genus Amastridium. Intergeneric relation-
ships of Amastridium are obscure, but the genus does not
appear to be closely related to any other Middle American
group.

INTRODUCTION

Amastridium is a poorly known, yet widely distributed genus of the
Middle American snake fauna. Its range extends from Nuevo Leon,
Mexico to Panama, yet in the 108 years since the description of
Aimastridium veliferum by Cope (1861), only 25 additional specimens

are known to have been collected.

The nomenclatural history of this genus has not been particularly
entangled, but as Dunn (1931) noted, the first four specimens collected
were each described as a new genus and species, Amastridium veli-
ferum Cope, Fleischmannia obscura Boettger (1898), Phydrops [sic]
melas Boulenger (1905), and Mimometophon [sic] sapperi Werner

145

146 Bulletin So. Calif. Academy of Sciences

The first review of the genus was that of Dunn (1925), who pointed
out that the snakes described as Amastridium veliferum by Cope and
Mimometopon sapperi by Werner are congeneric. He also demon-
strated certain differences between the nominal species, described
the hemipenis and attempted to indicate the possible relationships of
the genus. Since 1925 discussions of members of the genus Amastri-
dium have consisted of reports of additional specimens from wide-
spread localities. Dunn (1925) demonstrated a combined range for
both species extending from Chiapas, Mexico to Panama; Smith
(1943) reported a specimen from Chiapas, Mexico, and he later (1944)
extended the range of A. sapperi 850 km northward into the state of
Nuevo Leon, Mexico. Martin (1955) corroborated Smith’s long range
extension, reporting two specimens from southern Tamaulipas,
Mexico. Taylor (1954) recorded two additional specimens from Costa
Rica.

During the summer of 1968, we were fortunate in being able to
collect two specimens of this genus at Mr. Louis Ware’s Finca Whiskey _
River, located at El Copito, 1.5 km SE El Jaral, Departamento de
Cortés, Honduras. This locality is a cafetal through which passes a
road leading from the Tegucigalpa — San Pedro Sula highway to a
cleared area. The cafetal is very near the northeastern shore of Lago
de Yojoa, and the road was built by Mr. Ware and his men, using
as ballast volcanic earth dug from the side of the road. As a result,
when the road was completed a series of pits remained along one side
of the road. The pits were 2-5 m long, 1-2 m wide, and 2-4 m deep. Due
to the perpendicular nature of the walls, the pits formed natural traps
into which fell individuals of many of the smaller species of amphibians
and reptiles found in the area. On the floor of most pits was a mass
of decayed leaves and twigs, which provided a microhabitat for poten-
tial food items for the entrapped amphibians and reptiles, which were
probably able to sustain themselves for some length of time. Certainly
in two visits we saw no evidence that the entrapped animals were dying.

We first collected in the pits on 3 and 4 July, at the suggestion of
Mr. Ware, and found representatives of a total of 19 species of amphib-
ians and reptiles, including one adult male Amastridium. The other
species collected were Bufo valliceps, Eleutherodactylus gollmeri, E.
rugulosus, Engystomops pustulosa, Leptodactylus melanonotus, Phry-
nohyas venulosa, Rana pipiens, Smilisca baudinii, Ameiva undulata,
Anolis tropidonotus, Lepidophyma flavimaculatum, Sceloporus vari-
abilis, Scincella cherriei, Adelphicos quadrivirgatus, Coniophanes
fissidens, C. imperialis, Drymobius margaritiferus, Ninia sebae, and
Xenodon rhabdocephalus.

Review of Colubrid Snakes 147

The pits were visited again on 8 August, and 10 species of amphib-
ians and reptiles, including a juvenile female Amastridium, were
collected. All species taken on this trip were among those collected
on the first visit to the pits. ;

After returning to the United States, we discovered that two of the
snakes collected were of the genus Amastridium, and we attempted
to determine their specific status. Upon comparison of our specimens
with others from the length of the range by the junior author during a
museum tour, it became evident that taxonomic aspects of the genus
were worthy of review. All available specimens in this country were
subsequently examined by the senior author, and among this material
iS a specimen from southern Veracruz, Mexico that helps to fill in the
distributional gap between the records from Tamaulipas and Chiapas.
We were able to examine this specimen through the kindness of the
collector, Mr. Joseph Copp, to whom we are indebted.

Presently there are two recognized species of Amastridium, veliferum
and sapperi. These two taxa were placed in separate genera by their
respective authors, veliferum in Amastridium by Cope (1861) and
sapperi in Mimometopon by Werner (1905). Boettger (1898), appar-
ently unaware of Cope’s description of A. veliferum from Panama,
described another specimen from Costa Rica as Fleischmannia
obscura. Werner (1903), unaware of Cope’s work, but having access to
Boettger’s work, described Mimometopon sapperi from Guatemala.
Boulenger (1905), apparently having access to none of the above-
mentioned papers, described Phrydops melas from Costa Rica.
Fleischmannia obscura was synonymized with A. veliferum by Dunn
(1925) and Phrydops melas with A. veliferum by Dunn in 1931.
There are certain inconsistencies in the original description of P.
melas. The maxillary tooth count was given as 22, a number higher
than that found in any of the specimens we have examined. Perhaps
this was a lapsus for the number 12, a much more likely number for
the region from which the holotype came (see discussion on osteology).
Also, this specimen was stated to have apical pits, but we have found
apical pits only on the neck and most descriptions state that there are
none. Dunn (1931) implied, however, that he examined the holotype
of P. melas and determined it to be conspecific with Amastridium
veliferum.

Until the present time A. veliferum Cope and A. sapperi (Werner)
have been regarded as distinct species. The following discussion
demonstrates that this is not the case, and that only a single species is
involved. The name for the species in question should stand as Ama-
stridium veliferum Cope, 1861.

148 Bulletin So. Calif. Academy of Sciences

ANALYSIS OF VARIATION

Eighteen characteristics of scutellation, osteology, coloration, and
body measurements were analyzed. It is convenient for purposes of
discussion to designate the specimens from Nuevo Leon and Tamauli-
pas as population A, those from Veracruz, Chiapas, Guatemala, and
Honduras as population B, and those from Nicaragua, Costa Rica,
Panama, and the Canal Zone as population C.

Scutellation. — Specimens of Amastridium from throughout the
range have the following scutellational characteristics in common:
supralabials 7-7, 3rd and 4th entering the orbit; infralabials usually
9-9 (CRE 290 has 8-8 and USNM 29216 has 9-8), with four in contact
with the anterior chin shields, the 5th infralabial is the largest; pre-
oculars 1-1; postoculars 2-2 (USNM 110334 has the two postoculars
on both sides of the head fused into single scales); temporals 1 + 2 on
both sides of the head (1 +1 on the right side of LACM 45150, and
the anterior temporal is fused with the upper temporal in the second ~
row in UMMZ 65319); anal plate divided; dorsal scale rows 17
throughout.

Three scutellational features show variation: number of ventrals,
number of subcaudals, and condition of the loreal. It should be noted
that the following analysis is hampered by a preponderance of female
specimens from the northern portion of the range and of male
specimens from the southern portion of the range. Of the 11 specimens
examined from Mexico, Guatemala, and Honduras, 9 are females.
Eight of the 12 specimens examined from Nicaragua, Costa Rica,
Panama, and the Canal Zone are males; one cannot be sexed, as it
consists of only a head and a portion of the neck.

Subcaudals vary from 68 to 86 throughout the range. Seven males
have a range of 72 to 86 (mean 78.8). Six females have a range of 68
to 85 (mean 79.7). There is no consistent geographic difference in
numbers of subcaudals when arranged according to latitude (Table 1).

It is obvious, in both males and females, that ventrals are higher
in the northern portion of the range than they are in the southern
portion (Table 1). The picture is clearer, however, for females than
for males due to the better “spread” of females throughout the range.
Females from population A (no males are known from this area)
have a ventral range of 163 to 170 (mean 167.0). Females from
population B have a ventral range of 144 to 166 (mean 157.0), males
a range of 146 to 150 (mean 148.0). Females from population C have

a ventral range of 126 to 134 (mean 130.0), males a range of 119 to
129 (mean 124.3).

Review of Colubrid Snakes 149

TABLE |
VARIATION IN VENTRALS AND SUBCAUDALS IN AMASTRIDIUM

LATITUDE VENTRALS SUBCAUDALS
MALES FEMALES MALES FEMALES

24°-27°N ,

(Nuevo Leon) | = 163 — 79
21°-24°N

(Tamaulipas) — 168-170 (169.0) = 79-82 (80.5)
18°21°N

(Veracruz) — 156 — —
15°-18°N

(Chiapas &

Guatemala) 150 152-166 (160.5) 86 85
12°-15°N

(Honduras) 146 144 — 85
9°-12°N

(Nicaragua,

Costa Rica, 119-129(124.3) 126-134 (130.0) 72-86 (77.8) 68-70 (69.0)
Panama &

Canal Zone)

Total 119-150 (129.0) 126-170 (154.7) — 72-86 (78.9) 68-85 (79.7)

Specimens of Amastridium from the northern portion of the range
(Nuevo Leon to Honduras) have a loreal scale, while those from the
southern portion of the range (Nicaragua to Panama) lack this scale.
The preocular and loreal are fused on both sides of the head of USNM
110334, but as Smith (1943) pointed out, the outlines of the two
scales are clearly visible.

Osteology. — Due to the rarity of this snake, we felt justified in
making counts of the maxillary teeth on only one side of the head of
each specimen in which this was possible. The data suggest a clinal
decrease in number from north to south. Two specimens from population
A have counts of 16+ 2 and 17+2 (mean number of prediastemal
teeth 16.5). Maxillary tooth counts for members of population B are
as follows: 17+2, 16+2 (2 specimens), 14+ 2 (2 specimens), and
13+ 2 (mean 15.0). Maxillary tooth counts for members of population
C are as follows: 14+ 2, 13+ 2 (4 specimens, one specimen counted on
both sides by Malnate), 12+ 2 (5 specimens, one specimen counted
on both sides by Malnate), and 11 + 2 (mean 12.5). The count of 22
reported by Boulenger (1905) for the type of Phrydops melas is
obviously in error.

150 Bulletin So. Calif. Academy of Sciences

Dunn (1925) and others have stated that A. veliferum and A.
sapperi differ in respect to grooving of the posterior maxillary teeth,
veliferum lacking grooves and sapperi having them. No such simple
interpretation of tooth grooving can be made. A large specimen
(UMMZ 109702) from the northern portion of the range has a well-
developed groove extending the length of the anterior face of the tooth,
but a specimen from Veracruz (JFC 63-12) has only a shallow groove
on the dorsal portion of the anterior face of the posterior teeth.
Furthermore, two specimens from Chiapas (USNM 46509 and
110334) and one from Honduras (LACM 45150) have no trace of
grooving on the posterior maxillary teeth. Solution to this problem must
await the acquisition of additional material, but our observations
demonstrate that not all specimens from the range of the nominal
species sapperi have grooved rear teeth.

Measurement. — The tail length ratio varies from 0.277 to 0.319
in males (mean 0.308) and from 0.244 to 0.288 (mean 0.267) in
females. Six females and seven males have complete tails. When the
individual ratios are arranged according to the localities from which
specimens came, a gradual increase in the tail length ratio from north
to south in both males and females is indicated. Again this trend is
more obvious for females than for males. One female from population
A (no males are available) has a ratio of 0.248.The range for females of
population B is 0.281 to 0.288 (mean 0.284); one male from this
area has a ratio of 0.277. One female from population C has a ratio
of 0.288 and the range for males is 0.309 to 0.320 (mean 0.315).

Color Pattern. — The color pattern of all specimens examined is
basically the same. All have a dark dorsum, essentially unicolor in
most, with a series of small white dots located on scale row five or six
on each side, the spots being separated from one another by one to
four scales. The venter is also dark (but not as dark as the dorsum)
and essentially unicolor in most specimens, but some obscure vermic-
ulations are present on a few (e.g. LACM 45150). Two specimens
from Panama (MCZ 38223, UMMZ 65319) are very light dorsally and
ventrally in comparison with all other specimens from farther north,
and the lateral spotting is more prominent, with the individual spots
covering a larger portion of the scale. The color pattern of another
specimen from Panama (ANSP 22273), examined by Malnate, is
apparently similar to that of the two Panamanian specimens personally
examined.

The color pattern of the head is similar among all the specimens
(Fig. 2). In each case the head pattern consists of a prominent light
blotch on the nape, the medial and lateral (but not central) portions

Review of Colubrid Snakes 151

300
kilometers

Figure 1. Distribution of Amastridium veliferum in Mexico and Central America.
Star represents the type locality.

of the parietals and the upper portion of the temporal scales. The
posterior edge of this blotch is always deeply indented by a spear
point of dark groundcolor, which extends to, or slightly onto, the
posteromedial edge of the parietals. The remainder of the head pattern
is rather complex, but is similar in all specimens, although more
distinct in some than in others. The anterior head pattern always
consists of a dark line that runs the length of the middle portion of each
internasal and continues onto the prefrontal. In addition, on each
prefrontal there is another more lateral dark line that extends the
length of the scale. There is a dark median line on each supraocular. On
the frontal the pattern is variable, but often comprises a more or less
longitudinal, medial irregular marking. On each parietal there is a
central blotch that is delimited medially and laterally from the light
nape blotch by fairly regular black lines.

It is evident that the characters utilized by previous authors to
distinguish the two species, A. veliferum and sapperi, are disconcor-
dant. Those specimens north of and including Honduras have a loreal,
while those south of Honduras lack this scale. The numbers of ventral

2 Bulletin So. Calif. Academy of Sciences

Figure 2. Dorsal view of the head of an adult Amastridium veliferum
Honduras (LACM 45150). Six times normal size. :

from

Review of Colubrid Snakes 153

scales vary clinally througout the range from north to south, as do the
numbers of maxillary teeth. In addition, minor differences in color
are evident. The two Panamanian specimens seen by us are much
lighter in coloration than those from Costa Rica northward, yet the basic
pattern is identical throughout the range. In view of the disconcordant
nature of the characters utilized to distinguish the two nominal species,
and in the absence of any additional distinguishing features to
complement any of the other variable characters, we prefer to receg-
nize Amastridium as containing but single species, veliferum, and
present the following synonymy, diagnosis and description.

Amastridium Cope

Amastridium Cope, 1861 (1860): 370. Type species: Amastridium
veliferum Cope.

Fleischmannia Boettger, 1898: 69. Type species Fleischmannia
obscura Boettger.

Mimometopon Werner, 1903: 349. Type species: Mimometopon sapperi
Werner.

Phrydops Boulenger, 1905: 453. Type species: Phrydops melas
Boulenger.

Range: Atlantic and Pacific versants from Nuevo Leon, Mexico
south to Panama (Fig. 2).

Content: One species

Diagnosis and Description: A medium small species of a monotypic
genus (maximum total length recorded, 724 mm), with a relative tail
length of 0.277 to 0.319; posterior vertebrae with hypapophyses;
maxillary teeth 11 to 17, subequal, followed by two enlarged rear
teeth, grooved or not; dorsal scales in 17 rows, no reduction, smooth
with paired apical pits only on neck region; ventrals 119 to 170; anal
plate divided; subcaudals in 68 to 86 pairs; males with supra-anal
tubercles.

Head with a distinct canthal ridge, a rostral, 2 internasals, 2 pre-
frontals not entering the orbit, a frontal, 2 supraoculars, and 2
parietals; nostril between two nasals; loreal present or absent (when
absent apparently fused with nasal); 1 preocular; 2 postoculars;
temporals 1 + 2, anterior temporal separating parietal and fifth supra-
labial or parietal and fifth supralabial in very narrow contact in front
of anterior temporal; supralabials 7, third and fourth entering orbit;
infralabials 9, four touching anterior chin shields and fifth the largest;
pupil round.

154

Figure

45150).

Bulletin So. Calif. Academy of Sciences

: Paste
} RE Aas oe

3. Sulcate view of the hemipenis of Amastridium

veliferum

(LACM

Review of Colubrid Snakes 155

Hemipenis (Fig. 3) simple, slightly clavate; sulcus spermaticus
bifurcates at the point of junction of spinose area and calyculate
area, each arm extending for only a‘short distance into the calyculate
area; basal two-thirds of organ spinose, distal one-third calyculate;
two enlarged spines at the base, one lateral to the sulcus spermaticus
and the other on the absulcate side; other spines smaller, those on
absulcate side subequal; calyces on absulcate side small and spinulate,
those on sulcate side larger and papillate; organ not capitate.

Dorsal coloration as follows (based on notes on a fresh specimen,
LACM 45150; Fig. 1): dorsum dark gray with a row of very small
white spots every four to five scales on the fifth row; venter grayish
brown, lighter anteriorly; dorsum of head dark gray on rostral, inter-
nasals, prefrontals, frontal, supraoculars and lateral portions of
parietals; a wavy black line extends posteriorly from the rostral on
either side of the middorsal suture to the posterior edge of the
prefrontals; another more lateral black line extends the length of the
prefrontals; frontal irregularly outlined with black and with a wavy
black line down the center of the scale; supraoculars outlined with
black and with a black line extending through the center of the scale
from anterior to posterior; parietals mostly dark gray, but the median
suture and a narrow area on either side is rust-colored and outlined
with black; lateral edge of each parietal rust-colored and bounded
medially by a black line extending almost the entire length of the
parietal; rust-colored areas on parietals confluent with nape blotch;
posteromedial area of nape blotch indented by a spear point of dark
groundcolor; nape blotch bounded below by a black line extending
from posterior edge of eye almost to angle of jaw; supralabials black
with heavy rust flecking, a light line extending from ventral edge of
eye to sixth supralabial, white spot present near ventral edge of supra-
labials 1 to 5; chin grayish brown with a white spot on each scale;
iris dark rust brown.

Amastridium veliferum Cope

Amastridium veliferum Cope, 1861 (1860): 370 (holotype, ANSP
3738; type locality: “Cocuyas de Veraguas, New Grenada’-
Cocuyas, Panama), 1886: 495; 1893: 481; 1894: 840; 1900
(1898), pl. 24, fig. 13; Boulenger, 1894: 352; Dunn, 1925: 1; Taylor,
1951: 81; 1954: 714; Underwood, 1967: 23.

Fleischmannia obscura Boettger, 1898: 69 (holotype in the Sencken-
bergischen Naturforschenden Gesellschaft Frankfurt; type locality:
San Jose, Costa Rica).

156 Bulletin So. Calif. Academy of Sciences

Mimometopon sapperi Werner, 1903: 349 (holotype originally in the
Zoologische Sammlung des Bayerischen Staates; now either lost or
destroyed — Stuart, 1963: 89; type locality: “Guatemala”; type
may have come from Alta Verapaz, according to Stuart, pers. comm.)

Phrydops melas Boulenger, 1905: 454 (holotype, BMNH 1905S.
1.30.53; type locality: Cariblanco, Costa Rica).

Amastridium sapperi: Dunn, 1925: 1; Smith, 1943: 397; 1944: 136;
Smith and Taylor, 1945: 31; Martin, 1955: 178; Stuart, 1963: 89.

Phydrops [sic] melas: Dunn, 1931: 163.

Mimometophon [sic] sapperi: Dunn, 1931: 163.

GENERIC RELATIONSHIPS

A variety of genera have been suggested as possible relatives of
Amastridium by various authors. Cope (1861), in his generic diagnosis,
compared Amastridium to the composite (at that time) genus Coronella
and to Xenodon, neither of which is now considered to have close
affinity with Amastridium.

Boettger (1898) stated, in the description of Fleischmannia obscura,
that this taxon is related to Trimetopon and Hydromorphus and
furthermore, that except for the round pupil of Fleischmannia, its
physiognomy somewhat resembles that of Psammodynastes. Charles
Myers (pers. comm.) is of the opinion that there is no close relationship
of Amastridium with Trimetopon or with any of the genera closely
related to Trimetopon (e.g. Rhadinaea, Coniophanes). A close relation-
ship with Hydromorphus is also unlikely, as this genus has a much
different habitus than that of Amastridium, numerous scutellational
differences, and a highly variable head scutellation (Nelson, 1966).
As Boettger suggested, Psammodynastes is superficially similar to
Amastridium, but Psammodynastes has, among other things, a peculiar
type of maxillary dentition in which “2 or 3 small anterior teeth are
followed by 2 much enlarged fang-like teeth, these in turn are followed,
after a short interval, by 5 small teeth and 2 very large grooved fangs”
(Smith, 1943). By way of contrast, the prediastemal teeth of Ama-
stridium are isodont, and in addition, Psammodynastes is an Oriental
genus.

Werner (1903) distinguished his genus Mimometopon from Fleisch-
mannia of Boettger by the presence of grooved rear teeth in the former
and the lack of grooving on the rear teeth of the latter and postulated
a relationship between Mimometopon and Thamnodynastes. As Dunn

Review of Colubrid Snakes 157

(1925) pointed out, Thamnodynastes differs from Amastridium in having
a vertical pupil and scale pits, and in lacking hypapophyses. The
hemipenes of some Thamnodynastes are very similar to those of
Amastridium. However, hemipenial structure is quite variable in
Thamnodynastes, as presently recognized, and the genus is in need of
revision (Joseph R. Bailey, pers. comm.).

Boulenger (1905) stated that his genus Phrydops appeared to be
related to Synchalinus. Since the name Synchalinus corallioides is
based on a specimen of Phrynonax (= Pseustes) poecilonotus, accord-
ing to Dunn (1931), this is an unlikely association.

Dunn (1925) compared Amastridium to five genera, Paraoxyrhopus,
Tretanorhinus, Hydrocalamus (= Coniophanes bipunctatus), Thamno-
dynastes and Diadophis. He came to the conclusion that Amastridium
resembled Paraoxyrhopus, a South American genus, most closely in
all known features. No specimens of Paraoxyrhopus have been avail-
able to us and the genus is presently being revised by Joseph R. Bailey.
According to James A. Peters (pers. comm.), Bailey feels that
Paraoxyrhopus may be a relative of Xenopholis, another South
American genus most recently discussed by Bogert (1964) and
suggested to have relationships with two other South American genera,
Diaphorolepis and Synophis. We are unable at this time to clarify the
relationships of Amastridium, except to state that the neural spines
of the vertebrae are not expanded as they are in Paraoxyrhopus
(Schenkel, 1900), Xenopholis and Synophis (Bogert, 1964).

Savage (1966) included Amastridium in his Middle American his-
torical element, and Scott (1969) indicated that it is not closely
related to any other Middle American group, a point with which we
agree.

ACKNOWLEDGMENTS

We thank the following people for the loan of specimens in their care: Joseph
F. Copp, 1441 Muirlands Drive, La Jolla, California, personal collection (JFC);
William E. Duellman, University of Kansas Museum of Natural History (KU);
Hymen Marx, Field Museum of Natural History (FMNH); James A. Peters,
United States National Museum (USNM); Douglas A. Rossman, Museum of
Zoology, Louisiana State University (LSUMZ); Jay M. Savage, University of
Southern California (CRE); Dorothy M. Smith, University of Illinois Museum of
Natural History (UIMNH); Donald W. Tinkle, University of Michigan Museum
of Zoology (UMMZ); Ernest E. Williams, Museum of Comparative Zoology
(MCZ); John W. Wright, Los Angeles County Museum of Natural History
(LACM). We also thank Edmond V. Malnate for sending us data on two spcimens,
including the holotype of Amastridium veliferum, in the collection of the Academy
of Natural Sciences of Philadelphia (ANSP).

158 Bulletin So. Calif. Academy of Sciences
SPECIMENS EXAMINED

Mexico
Chiapas: Chicharros (USNM 46509); Escuintla (UMMZ 88304); Las Nubes
on Mt. Ovando, 8 km from La Esperanza (USNM 110334); Region Soconusco
(UIMNH 33644).
Nuevo Leon: Hacienda Vista Hermosa, Santiago (FMNH 37140).
Tamaulipas: Rancho del Cielo, 7 km NW Gomez Farias (UMMZ 109701-2).
Veracruz: Mexico Hwy. 180, 15 km E Coatzacoalcos (JFC 63-12).
Guatemala
Alta Verapaz: Chama (MCZ 28095).
Honduras
Cortés: El Copito, 1.5 km SE El Jaral (LACM 45150, LSUMZ 20872).
Nicaragua
Rio San Juan: 17 km from Greytown (USNM 29216-7).
Costa Rica
Alajuela: Cariblanco (MCZ 15319); Isla Bonita (KU 31913).
Cartago: Turrialba (KU 31914, MCZ 56069).
Heredia: Puerto Viejo (CRE 69).
Limon: E] Tigre, 9-14 km SW Siquirres, 680 m (CRE 290).
Panama
Panama: Rio Chagres (MCZ 38223); Agua Clara, Rio Chagres (ANSP 22273,
examined by Edmond V. Malnate).
Veraguas: Cocuyas (ANSP 3738, holotype, examined by Edmond V. Malnate).
Canal Zone
Barro Colorado Island, Shannon Trail (UMMZ 65319).

LITERATURE CITED

BOETTGER, O., 1898. Katalog der Reptilien-Sammlung im Museum der Sencken-
bergischen Naturforschenden Gesellschaft in Frankfurt Am Main. II. Teil
(Schlangen). Frankfurt: Gebrtider Knauer. 160 p.

BOULENGER, G. A., 1894. Catalogue of the snakes in the British Museum (Natural
History). Vol. 2. Taylor and Francis, London. 382 p.

1905. Descriptions of new snakes in the collection of the British Museum.
Ann. Mag. Nat. Hist., ser. 7, 15: 453-456.

Cope, E. D., 1861. Descriptions of reptiles from tropical America and Asia. Proc.
Acad. Nat. Sci. Phila. (1860), 11: 368-374.

1886. An analytical table of the genera of snakes. Proc. Amer. Philos.
Soc., 23: 479-499.

1893. Prodromus of a new system of the non-venomous snakes. Amer.
Nat., 27: 477-483.

1894. The classification of snakes. Amer. Nat., 28: 831-844.

1900. The crocodilians, lizards, and snakes of North America. Rept.U-S.
Natl. Mus. 1898: 153-1270.

Dunn, E. R., 1925. Amastridium, a neglected genus of snakes. Proc. U. S. Natl.
Mus., 65(11): 1-3.

Review of Colubrid Snakes 159

1931. Some Central American snake genera. Copeia, 1931: 163.

MarTIN, P. S., 1955. Herpetological records from the Gomez Farias region of
southwestern Tamaulipas, Mexico. Copeia, 1955: 173-180.

NELSON, C. E., 1966. Systematics and distribution of snakes of the Central Ameri-
can genus Hydromorphus (Colubridae). Texas J. Sci., 18: 365-371.

SAVAGE, J. M., 1966. The origins and history of the Central American Herpeto-
fauna. Copeia, 1966: 719-766.

SCHENKEL, E., 1900. Achter Nachtrag zum Katalog der herpetologischen Samm-
lung des Basler Museums. Verhandl. Naturfor. Ges. Basel, 8: 142-199.

ScoTT, N. J., JR., 1969. A zoogeographic analysis of the snakes of Costa Rica.
Ph. D. Thesis, Univ. Southern California. 390 p.

SmiTH, H. M., 1943. Summary of the collections of snakes and crocodilians made
in Mexico under the Walter Rathbone Bacon Traveling Scholarship. Proc.
U. S. Natl. Mus., 93: 393-504.

1944. Snakes of the Hoogstraal expeditions to northern Mexico. Zool.
Ser., Field Mus. Nat. Hist., 29: 135-152.

SmiTH, H. M. AND E. H. Taytor. 1945. An annotated checklist and key to the
snakes of Mexico. Bull. U. S. Natl. Mus., 187: 1-239.

SmiTH, M. A., 1943. The fauna of British India, Ceylon and Burma, including the
whole of the Indo-Chinese sub-region. Reptilia and Amphibia. Vol. 3.
Serpentes. Taylor and Francis, London. 583 p.

STuART, L. C., 1963. A checklist of the herpetofauna of Guatemala. Misc. Publ.,
Mus. Zool., Univ. Michigan, no. 122: 1-150.

TAYLor, E. H., 1951. A brief review of the snakes of Costa Rica. Univ. Kansas
Sci. Bull., 34: 3-188.

1954. Further studies on the serpents of Costa Rica. Univ. Kansas Sci.
Bull., 36: 673-800.

UNDERWOOD, G., 1967. A contribution to the classification of snakes. British
Museum (Natural History). London. 179 p.

WERNER, F., 1903. Ueber Reptilien und Batrachier aus Guatemala und China in
der zoologischen Staats-Sammlung in Miinchen nebst einem Anhang tiber
seltene Formen aus anderen Gegenden. Abh. Bayer. Akad. Wiss., 22: 342-
384.

Accepted for publication May 13, 1969.

Bull. So. Calif. Acad. Sci. 68(3): 161-169, 1969

A NEW SPECIES OF HANNEMANIA (ACARINA,
TROMBICULIDAE) FROM BUFO PUNCTATUS OF
WESTERN NORTH AMERICA, WITH COMMENTS ON
HANNEMANIA HYLAE (EWING).!

RICHARD B. LOOMIS AND W. C. WELBOURN, JR.
Department of Biology, California State College,
Long Beach California 90801

ABSTRACT: Hannemania bufonis, n. sp. is described from
larvae taken off the red spotted toad, Bufo punctatus Baird
and Girard. The type locality is Whitewater Canyon, River-
side Co., California, and it also is known from Arizona,
western Texas, southern Utah and Sonora, Mexico. Closely
similar is Hannemania hylae (Ewing) redescribed from topo-
types taken off the type host, Hyla cadaverina Cope (origi-
nally listed as Hyla arenicolor) from Cottonwood Creek,
San Diego Co., California. Additional locality and host
records include larvae from Hyla arenicolor, taken in Arizona,
western Texas, southern Utah, and northern Sonora, Mexico,
and off Hyla cadaverina from Baja California Norte, Mexico.

INTRODUCTION

Studies of the chiggers from amphibians of southern California revealed
two species. One species is Hannemania hylae (Ewing) from the Cali-
fornia tree frog, formerly Hyla arenicolor, later Hyla californiae
Gorman (1960) and now Hyla cadaverina Cope (Duellman, 1968).
The second species, which is new, was found on the red spotted toad,
Bufo punctatus Baird and Girard. Both species are described below
and information is given about their known geographic distribution,
larval variation and life histories.

The genus Hannemania was proposed by Oudemans (1911) and
currently is placed in the subfamily Leeuwenhoekinae. The larvae
can be distinguished from the larvae of other genera in this subfamily
by the presence of a distally expanded flange possessing recurved teeth
on the cheliceral blade, and anteromedian projection of the scutum
and the lack of stigmata and tracheae. The larvae penetrate the skin
of amphibians and become imbedded and encapsulated in the dermis
(Hyland, 1961).

* Studies upon which this report is based were supported by a Research Grant
AI-3407 from the National Institute of Allergy and Infectious Diseases.

160

New Species of Chigger 161

Hannemania bufonis, new species
Figure |

Types. — Larvae: Holotype and 13 paratopotypes; holotype and 6
paratopotypes from Whitewater Canyon, 4 miles north of Whitewater,
Riverside Co., California, host red spotted toad, Bufo punctatus,
original number WCW670508-5, collected 8 May 1967 by W. C. Wel-
bourn, Jr.; 7 paratopotypes also from Whitewater Canyon from four
Bufo punctatus, original numbers VPZ660729-5, -7, -15 and -16,
taken 29 July 1966 by Virginia P. Zinsmeister.

Diagnosis. — Larva, similar to Hannemania hylae in having one
genuala II and III, and lacking femoralae and differing from H. hylae
in having parasubterminala I branched (occasionally nude), tarsala I
longer and thinner than tarsala II, PL’s laterally peninsulate and long
(52-72 in H. bufonis and 39-54 in H. hylae), AP narrow (17 or less),
PW wide (65 or more), PSB 26 or more and with a small ocular plate.

Description of holotype (all measurements in microns, with vari-
ations of paratypes in parentheses). Body: fully engorged, 1166 (1034-
1200) by 840 (711-840), color in life red to orange; eyes 2/2, equal,
red in life, small ocular plate present.

Dorsal setal formula 2-4-8-2-8-8-+ 9, total 41; measurements of
humeral seta 49, setae of first row 38-42, posterior dorsal setae 45-49.

Approximately 60 ventral setae; measurements of sternal seta 36,
posterior ventral setae 30-35.

Scutum: punctate, anteromedian projection without puncta; widest
between the PL’s, being slightly longer than wide, sensilla flagelliform
(see figure 1).

Scutal measurements of holotype (with mean and extreme of 13
paratopotypes in parentheses unless otherwise noted). AW 51 (50.4,
47-55, 12), PW 70 (73.5, 65-75), SB 26 (26.5, 25-33), ASB 51 (52.3,
43-56), PSB 31 (28.9, 27-31), AP 15 (14.6, 12-17), AM 36 (34.4,
31-39, 7), AL 40 (35.2, 30-40, 12), PL 64 (62.1, 57-67, 12), S (77.3,
72-87, 6). 7

Gnathosoma: Cheliceral blade distally expanded with recurved
teeth; cheliceral base and capitular sternum punctate. Galeala
branched. Palpal setal formula B/B/BNB; palpotarsus with 5 branched
setae, and tarsala (10); palpotibial claw trifurcate.

Legs with specialized setae as follows: Leg I, with 4 (3-5) genualae
and microgenuala; two tibialae and microtibiala; tarsala 22 (17-22),
microtarsala, subterminala, parasubterminala and pretarsala. Leg II,
with genuala, two tibialae, tarsala 19 (15-19), microtarsala, and pre-
tarsala. Leg II, coxa with one branched seta; genuala; tibiala and
lacking mastisetae. Each leg with 6 punctate segments terminating in

162 Bulletin So. Calif. Academy of Sciences

two claws and clawlike empodium, with onychotriches. Leg index: I,
305 (267-327); I, 277 (240-288); III, 270 (252-306); total 852 (768-
921).

Taxonomic remarks. — The number of genualae on leg I varies
among the larvae of both Hannemania bufonis and H. hylae. The
number and arrangement varies between individuals and on the legs
of a single specimen. Examined H. bufonis had two to six genualae I
with a mean of four, whereas H. hylae possessed three to seven genualae
I for a mean of 4.9.

The length and width of the ocular plate (when visible) has been
used to identify H. bufonis. Measurements of ocular plates of H. bufonis
(type series) revealed a mean length of 22.1 (20-23) and a width of 9
(7-10), whereas the ocular plates of the topotypes of H. hylae were
31.5 (30-33) long and 13.3 (12-14) wide.

Tarsala I of H. bufonis is longer than tarsala II. The means and
extremes for 76 specimens are 20 (17-26) for tarsala I and 17.5 (15-22)
for tarsala Il. Measurements of the type series (14 specimens) are:
tarsala 19.5 (17-22) and tarsala II 17.5 (15-19) and 20 from Arizona
are: tarsala I 19.8 (17-22) and tarsala II 17.2 (14-19). The means of
the tarsalae of 28 specimens from Texas are slightly larger as tarsala I
is 22.8 (20-26) and tarsala II is 19 (18-20). The means are smaller in
13 larvae from Utah as tarsala I is 18.1 (17-22) and tarsala II is 16.3
(15-19).

The parasubterminala I of H. bufonis usually has one to four
branches although it may be nude. All specimens examined from
Sonora, Mexico had a nude parasubterminala. In eight type specimens
of H. bufonis the branched parasubterminala I 20.6 (19-22) was nearly
as long as the subterminala I 21 (20-22) and in four types the nude
parasubterminala I was 19 (18-20) and the subterminala I was 20.2
(19-21). However the parasubterminala was aiways nude in H. hylae.
In ten specimens of H. hylae the parasubterminala I was 15.6 (14-16)
and the subterminala I was 19.5 (19-20).

Ecological notes. — Hannemania bufonis has been taken only from
Bufo punctatus. The chigger was embedded in the ventral dermis
especially of the belly and hind legs. Larvae are also found on the
dorsum, even in the dermis of the parotoid gland of one toad.

In California, toads with H. bufonis usually were associated with
rocks and boulders. However, in Texas the hosts were taken in low
rolling hills apparently devoid of large rocks.

Numerous engorged larvae of H. bufonis from California and Texas
have been reared to nymphs and adults, and it was observed that they
passed from the engorged larval stage to the adult stage without the

New Species of Chigger 163

Figure 1. Hannemania bufonis, n. sp. A. Scutum and eyes; B. Dorsal view of

gnathosoma; C. Ventral aspect of palpotibia and tarsus; D. Representative
body setae, |St, first sternal, H, hymeral and PD, posterior dorsal; E. Leg I;
genu, tibia and tarsus with nude setae and bases of branched setae, with measure-

ments in microns; F.LegII; G. Leg III.

164 Bulletin So. Calif. Academy of Sciences

active nymphs feeding. Each of ten engorged larvae from the Granite
Mountains, San Bernardino Co., California was placed into an indi-
vidual culture. After 31 days without food, seven were adults, two
were in the imagochrysalis stage and only one was still an active nymph.

This rapid development probably shortens the life cycle from
engorged larva to freeliving unfed larva, which may be correlated with
the availability of the host toads.

Specimens examined. — Total 272 larvae all from Bufo punctatus:
ARIZONA, Mohave Co.: Grand Canyon National Mon., Toroweap
Valley, 25 April 1943 (17). Pima Co: 9 mi. N Vail, 9 April 1963 (26);
Organ Pipe Cactus National Mon, | mi. S Headquarters in camp-
ground, 12 Aug. 1963 (10); and Quitobaquito, 7 July 1956 (25).
CALIFORNIA, Riverside Co., Joshua Tree National Mon.: Barker
Dam, 5 Aug. 1965 (4), Squaw Tank, 12 Oct. 1962 (4), Whitetank
Campground, 4 Nov. 1963 (8). Riverside Co.: Whitewater Canyon,
1.5 to 4 mi. N Whitewater, 17 April 1965 (3), 3 July 1966 (25), 29
July 1966 (66). San Bernardino Co.: Dripping Springs, Granite Mts.,
17 mi. NNE Amboy, 13 Oct. 1968 (11); Joshua Tree National Mon.,
Fortynine Palms Oasis, 28 Aug. 1963 (4) and Indian Cove, 11 April
1960 (11). TEXAS, Culberson Co.: 18-21 mi. SE Whites City,
New Mexico, 13 July 1968 (26); 28 mi. SE Whites City, New Mexico,
14 July 1968 (8). Brewster Co.: 1.8 mi. E Lajitos, 20 July 1968 (1).
UTAH, Washington Co.: Hurricane, 21 May 1941 (1); Snow Canyon,
15 June 1967 (16). MEXICO, SONORA: 8 mi. S Alamos, 6 April
1966 (4); road between La Aduana and Minas Nuevas Aug. 1968 (2).

Hannemania hylae (Ewing)
(Figure 2)

Trombicula hylae Ewing, 1925, Proc. Ent. Soc. Wash. 21(7): 146.
Holotype from Hyla arenicolor (= Hyla cadaverina Cope), Barrett
Dam, Cottonwood Creek, San Diego Co., California, 15 March
1925 by L. M. Klauber.

Hannemania hylae, Ewing, 1931, Proc. U.S. Natl. Mus. 80(8): 4;
Gould, 1956, Univ. Calif. Publ. Ent. 11: 25-26.

Diagnosis. — Larva similar to H. bufonis in having one genuala on
legs II and III and lacking femoralae and differing from H. bufonis in
having parasubterminala I nude, tarsala I subequal to tarsala II, PL
short (less than 55), AP wide (17 or more), PW less than 65, PSB less
than 26, and, with a large ocular plate.

Description of species (based on 21 topotypes from Cottonwood
Creek, near Barrett Dam, San Diego Co., from 3 Hyla cadaverina col-

New Species of Chigger 165

lected 10 March 1968 by W. C. Welbourn, Jr.). Body: Fully engorged,
900 (900-1100) by 480 (480-660), color in life red to orange; eyes
2/2, subequal, red in life, large ocular plate present.

Dorsal setal formula 2-4-8-2-8-+ 24, total 48; measurements of
humeral seta 42, setae of first row 33-37, posterior dorsal setae 34-41.

Approximately 46 ventral setae, measurements of sternal seta 30,
posterior ventral seta 24-30.

Scutum: punctate except for anteromedian projection, sensilla
flagelliform (see figure 2).

Scutal measurements of 21 specimens (unless otherwise noted) with
mean and extreme, AW 47 (44-49, 20), PW, 62.2 (59-65, 14), SB 25.2
(23-29), ASB 52.6 (50-55, 8), PSB 24 (23-25, 15), AP 19.5 (17-21,
10), AM 26.6 (24-30, 17), AL 31 (28-34, 18), PL 44.1 (39-49, 15),
S 70 (68-78, 8).

Gnathosoma: Cheliceral blade distally expanded with recurved
teeth; cheliceral base and capitular sternum punctate. Galeala branched.
Palpal setal formula B/B/BNB; palpotarsus with 5 branched setae and
tarsala (12); palpotibial claw trifurcate.

Legs with specialized setae as follows: Legs I, with three to seven
genualae and microgenuala; two tibialae and microtibiala; tarsala 20.6
(19-23), microtarsala, subterminala, parasubterminala and pretarsala.
Leg II, with genuala and microgenuala; two tibialae; tarsala 21.8 (20-
23), microtarsala, and pretarsala. Leg III, coxa with one branched
seta; genuala; tibiala and lacking mastisetae. Each leg with six punctate
segments, terminating in two claws and clawlike empodium, with ony-
chotriches. Leg index: I, 313 (270-336); II, 272 (280-300); III, 292
(272-324), total 877 (782-960).

Of 117 specimens measured, the means and extremes of tarsala I
are 19.8 (17-23) and tarsala II are 21.9 (18-28). “Measurements of
tarsala I from each area are: 20.6 (19-23), 21 topotypes; 19.5 (18-21),
16 from Arizona; 18.4 (17-20), 20 from Utah; 20.1 (17-24), 40 from
Texas; and 19.6 (18-22), 20 from Sonora, Mexico. Measurements of
tarsala II are: 21.8 (20-23), 21 topotypes; 21.4 (18-24), 16 from
Arizona; 21.1 (20-22), 20 from Utah,; 20.1 (17-24), 40 from Texas;
22.3 (21-24), 20 from Sonora, Mexico.

Ecological notes. — Hannemania hylae parasitizes Hyla cadaverina
in southern California and northern Baja California, Mexico whereas
it infests Hyla arenicolor from Arizona, west Texas, southern Utah
and northern Sonora, Mexico. This chigger usually is found on tree
frogs taken from rocky canyons with permanent springs or streams
flowing through semi-arid lands. Hannemania hylae usually was found
in the ventral dermis of the legs and belly as noted by Ewing (1926).

166 Bulletin So. Calif. Academy of Sciences

Figure 2. Hannemania hylae (Ewing). A.Scutum and eyes; B. Dorsal view of
gnathosoma; C. Ventral aspect of palpotibial and tarsus; D.Genu with seven
genualae; EE. Representative body setae, 1St, first sternal, H, humeral and PD,
posterior dorsal; F. Leg I; genu, tibia and tarsus with nude setae and bases of
branched setae, with measurements in microns; G. Leg II; H. Leg III.

New Species of Chigger 167

Many engorged larvae have been reared to the nymphal and adult
stages, and in every case the nymph fed prior to transforming into the
adult. Cultured engorged larvae transformed into nymphs within two
weeks (as did H. bufonis) but they remained active nymphs until they
died or were fed enough collembola eggs to transform into the adult
stage.

Specimens examined: Total 319 larvae: ARIZONA, all from Hyla
arenicolor; Coconino Co.: Clear Creek Canyon, 10 Sept. 1965 (6);
Cochise Co.: Chiricahua Mountains, South fork of Cave Creek, 25
July 1968 (1); Pima Co.: Bear Canyon, 1.5 mi. E Sabino Canyon
Visitor Center, 20 March 1967 (24); Madera Canyon, | mi. N Madera
Canyon lodge, 26 July 1968 (32). CALIFORNIA, all from Ayla
cadaverina: Orange Co.: Harding Canyon, 20 Feb. 1966 (8), 25 April
1964 (8); Silverado Canyon, 28 June 1967 (2); Riverside Co.: Tahquitz
Canyon, 24 Feb. 1968 (34); Whitewater Canyon, 5 mi. N Whitewater,
30 March 1962 (6). San Bernardino Co., Joshua Tree National Mon.:
Fortynine Palms Oasis, 23 Sept. 1961 (2), 28 Aug. 1963 (20), 20 Sept.
1967 (19), 26 April 1968 (4); Indian Cove, 11 April 1960 (11). San
Diego Co.: Anza-Borrego State Park, Palm Canyon, 25 June 1967 (41);
Indian Flats Campground, 4 mi. N, 2 mi. W Warner Springs, 16 June
1967 (6). TEXAS, Jeff Davis Co.: 4 mi. W, 5 mi. N Fort Davis, 16-17
July 1968, Ayla arenicelor (40). UTAH, Washington Co.: Zion
National Park, Narrows trail, Virgin River, 10 Sept. 1967, Hyla areni-
color (20). MEXICO, BAJA CALIFORNIA NORTE: 5 mi. E Cerro
del Castillo, 30 March 1961, Hyla cadaverina (10). SONORA, all from
Hyla arenicolor, 5 mi. NW Cananea, 3 April 1966 (10); 11 mi. E
Imuris, 3 April 1966 (15).

ACKNOWLEDGMENTS

For specimens of amphibians we thank numerous students in Biology
at California State College, Long Beach, including Richard M. Davis,
Jerry L. Fowler, James P. Webb, Jr., William J. Wrenn and Virginia P.
Zinsmeister who also assisted in the recovery of chiggers. We are grate-
ful to Elaine Katzer for the fine illustrations. Appreciation is extended
to Mr. William R. Supernaugh, Superintendent of Joshua Tree National
Monument, California for permission to collect specimens.

LITERATURE CITED

DUELLMAN, W. E., 1968. The taxonomic status of some American hylid frogs.
Herpetologica 24: 200.

168 Bulletin So. Calif. Academy of Sciences
Ewinc, H. E., 1925. Two chiggers (Trombicula larvae). Proc. Ent. Soc. Wash.
21: 146.

EwInc, H. E., 1926. The life history and biology of the tree-toad chigger, Trom-
bicula hylae Ewing. Ann. Ent. Soc. Amer. 29: 261-267.

EwiInG, H. E., 1931. A catalogue of the Trombiculinae of chigger mites, of the
New World with new genera and species and a key to the genera. Proc.
U.S. Natl. Mus. 80: 1-19.

GorRMAN, J., 1960. Treetoad studies, I. Hyla californiae, new species. Herpeto-
logica 16: 214-222.

GouLD, D. J., 1956. The larval trombiculid mites of California (Acarina: Trom-
biculidae). Univ. Calif. Publ. Ent. 11: 1-116.

HYLAND, K. E., 1961. Parasitic phase of chigger mite, Hannemania hegeneri
on experimentally infested amphibians. Exp. Parasit. 11: 212-225.

OUDEMANS, A. C., 1911. Acarologische Aanteekeningen XXXVI. Entomologie
Bericht. Amsterdam 3: 137-139.

Accepted for publication June 11, 1969.

Bull. So. Calif. Acad. Sci. 68(3): 170-187, 1969

_ AN ECOLOGICAL STUDY OF THE
POLYCHAETOUS ANNELIDS ASSOCIATED WITH
~ FOULING MATERIAL IN LOS ANGELES HARBOR WITH
SPECIAL REFERENCE TO POLLUTION.

ROBERT W. CRIPPEN* AND DONALD J. REISH
Department of Biology,
California State College, Long Beach,
Long Beach, California 90801.

ABSTRACT: A quantitative survey of the polychaetes was
made at 28-day intervals from floating docks in Los Angeles
Harbor for a 17-month period. Additional data consisted of
water temperature, turbidity, chlorinity, dissolved oxygen,
phosphates and nitrates — nitrites. Stations were selected
according to variations in the degree of pollution. Each
station was characterized by at least one unique polychaete.
The number of species present at a station decreased as the
‘degree of pollution increased. Capitella capitata comprised
an increasing percentage of the total polychaete population
from the outer harbor to the inner harbor. Polychaetes were
absent from the highly polluted station in the inner harbor.
The relationship of the chemical and physical data to the
polychaete populations was discussed.

INTRODUCTION

Plants and animals have been utilized as indicators of varying degrees
of pollution since the classical studies by Kolkwitz and Marsson
(1908) on German fresh water streams. Such studies were extended
into the United States by Forbes and Richardson (1913) and more
recently by Patrick (1949), Gaufin and Tarzwell (1952), and Keup,
et al. (1966). Gaufin and Tarzwell (1952) considered the following
criteria for possible benthic faunal indicators of stream pollution:
(1) a large number of individuals of a species, (2) a small number of
different species, (3) animals with principally scavenger feeding
habits, and (4) either a tolerance to low dissolved oxygen or some
adaptation for a low oxygen environment. In contrast, a healthy, non-
polluted area is characterized by a large number of species each repre-
sented by a few individuals, thus exhibiting a biological equilibrium.
The use of the indicator species concept in marine waters dates to
the study by Wilhelmi (1916) of German estuaries. He stated that the
polychaete Capitella capitata played a similar role in marine waters

*Present address: The Ira C. Darling Center Marine Laboratory, University of
Maine, Walpole, Maine 04573.

169

170 Bulletin So. Calif. Academy of Sciences

as the sludge worm Tubifex does in fresh waters. Blegvad (1932)
found that certain species of polychaetes flourished in the vicinity of
domestic outfall sewers in Copenhagen Harbor. Interest in the biologi-
cal problems of marine pollution began to attract attention in the
early 1950’s and has continued and expanded to the present time.
Subtidal benthic animals were used as indicators of varying degrees
of pollution by Filice (1954a, 1954b, 1958, 1959) in the San Francisco
Bay area, Reish (1955, 1959) in Los Angeles-Long Beach Harbors,
Kitamori (1961) in Japan, Gilet (1960) and Bellan (1965) in France,
to mention a few. For example, Reish (1959) was able to divide the Los
Angeles-Long Beach Harbors into five zones based on the indicator
organism concept: a healthy zone, two semi-healthy zones, a polluted
zone, and a very polluted zone which lacked macroscopic animals.

The use of both intertidal algae and invertebrates as indicators of
varying degrees of pollution was found to be of value by Bellan-
Santini (1968) in Marseille. While fouling organisms have been the
subject of extensive studies throughout the world (Anon. 1952b),
they have not been studied with reference to pollution in the past.
However, Barnard (1958) discussed the relationship of amphipods
and spionid polychaetes to turbidity in Los Angeles-Long Beach
Harbors, and Reish (196la) correlated water temperature and dis-
solved oxygen to the settlement and growth of the serpulid polychaete
Hydroides norvegica in the same area.

The purpose of this study, therefore, was to conduct a survey of the
polychaetes associated with the fouling material on five floating docks
in Los Angeles Harbor to determine whether or not they may be of
use as indicators of pollution, and to ascertain whether or not any
relationship exists between polychaetes and the chemical and physical
characteristics of the water. If such a relationship were found to exist,
it would greatly facilitate sampling with respect to time, equipment,
and manpower. Fouling organisms are herein defined as those plants
and animals which attach to man-made structures. Pollution is herein
defined as the act of making the water unclean by man’s activity.

Pollution in Los Angeles — Long Beach Harbors

Los Angeles-Long Beach Beach Harbors are one body of water
hydrographically; the separation is political (Fig. 1). The history of
the development and pollution in these harbors has been previously
described (Anon, 1952a; Reish, 1959). Industrial wastes are emptied
primarily in the inner harbor within slips and basins. Oil refinery
wastes make up the single largest industrial source in terms of volume.

Harbor Pollution 171

Domestic outfalls are located throughout the harbor but only the
Terminal Island sewage treatment plant discharges any large quantity
(29.5 million liters per day). Storm drains are located primarily in
the inner harbors at the ends of slips, basins, and channels. From
the previous studies, it can be stated in general terms that the water
quality, as measured by dissolved oxygen concentration or by benthic
animal populations, is poorer in the inner reaches of the inner harbor;
conversely, the water quality improves as one proceeds towards the
open ocean.

MATERIALS AND METHODS

Seventeen collections of fouling organisms and water samples were
made at five stations at 28-day intervals from October 14, 1966
through January 8, 1968. The station locations ranged from the outer
harbor area to the inner harbor area of Los Angeles Harbor (Fig. 1).
This series of stations exhibited a range of environmental conditions
from a relatively unpolluted region in the outer harbor (Fig. 1, LA7)
to a very polluted region in the inner harbor (Fig. 1, LASO). The
station numbers employed followed the system previously used (Anon,
1952a; Reish, 1959).

Station Descriptions
Figure |

Station LA7. This station was located at boat moorage numbers
384, 386 and 388 at Fleitz Brothers Yacht Anchorage in Watchhorn
Basin. Wastes discharged in the vicinity include about 158,970 liters
daily of ballast water and line flushings from the U.S. Navy fueling
wharf (Roy C. Hampson, personal communication).

Station LA26. This station was located at boat moorage number
one at Norm’s Landing in the main channel of Los Angeles Harbor. No
significant amounts of wastes are discharged in the vicinity of this
station.

Station LA39. This station was located within the inner reaches of
Slip 1 at the Los Angeles Harbor Department’s dock near Pier 160. While
no major wastes are emptied in the vicinity of this station, this area is
affected by limited water circulation (Reish 1961b).

Station LA54. This station was located at boat moorage number
53 at Pacific Yacht Landing in the East Basin region of the harbor.
No wastes are discharged in the vicinity of this station, but it is affected
by the oil refinery wastes discharged into the Consolidated Slip.

Station LA5O. This station was located at finger J at Island Yacht

172 Bulletin So. Calif. Academy of Sciences

LOS ANGELES HARBOR

— 1189115’

Figure 1. Los Angeles Harbor showing station locations.

Anchorage Number 2 in Consolidated Slip. This slip receives 43.1
million liters of waste waters per day from the Dominguez Channel
(Roy C. Hampson, personal communication). Dominguez Channel
is a natural channel about 24 km long. The channel receives industrial
effluents, primarily cooling waters and oil refinery wastes. Recently
13 km of this channel was deepened and widened and this section is
under tidal influence (Rambow, 1964; Hoag, 1966).

Harbor Pollution [73

Water Analysis

Water samples from each station at each collection period were
analyzed for water temperature, turbidity, chlorinity, dissolved oxygen,
phosphates, nitrates and nitrites.

Water Temperature. The temperature of the surface water was read
to the nearest 0.1C with a thermometer.

Turbidity. A water sample of approximately 3.5 liters was taken
at a depth of 10 cm with a one gallon glass jar. The sample was brought
to the laboratory where it was mixed and a 3.0 liter sample removed.
This sample was filtered through a previously weighed millipore
prefilter (Type AP20). Following filtration, the prefilter was rinsed
three times with distilled water, dried and re-weighed. The weight of
the residue was determined and recorded as mg/liter.

-Chlorinity. The chlorinity was determined in the laboratory by the
Mohr method (Barnes, 1959).

Dissolved Oxygen. Water samples were taken 10 cm below the
surface, fixed in the field, and titrated in the laboratory according to
the standard Winkler method (Barnes, 1959).

Dissolved Nutrients. A 500 ml portion of the filtered water used in
the turbidity determination was refiltered through a millipore mem-
brane filter (size 0.45, ). Phosphates were determined colorimetrically
according to the procedure outlined by Barnes (1959) for the eight
collection periods between June 1967 and January 1968. Total nitrate-
nitrite values were determined colorimetrically following the procedure
outlined by Strickland and Parsons (1965) for the entire study. Nitrate
and nitrite values were determined separately by the same method for
the seven collection periods between July 1967 and January 1968.

Biological Techniques

Samples of biological material were scraped from floating logs of
docks. Each sample covered a surface area of 800 cm?, and each
successive sample was taken adjacent to the previous one, in so far
as was possible. The material was preserved in the field with formalin.
In the laboratory the material was washed through a 250, Tyler
screen to remove formalin and sediment. The larger fouling organisms,
such as mussels, were removed and their presence noted. When the
volume of the biological material was less than 25 cm3, the entire
sample was sorted and the polychaetes identified. If, the volume of
material exceeded 25 cm’, five aliquots were selected at random, and
the material was identified, counted, and multiplied by the appropriate
factor.

174 Bulletin So. Calif. Academy of Sciences

RESULTS

Physical and Chemical Data

The following physical and chemical data are summarized in Table 1 as
ranges and means.

Water temperature. The surface water temperatures ranged from a
low of 13.3C in January 1968 at LA7 to a high of 24.1C in August
1967 at LASO (Table 1). Typically, the lowest temperatures for any
period were recorded at LA7 and the highest at LA50 with LA26,
LA39 and LAS54 intermediate.

Turbidity. The turbidity just beneath the surface, as measured by
the amount of material retained on a millipore prefilter, ranged from a
low of 0.0 mg/liter at LA7 in November 1967 to a high of 23.7
mg/liter at LAS5O in November 1966. The mean turbidity values
increased progressively from the outer harbor at LA7 (2.7 mg/liter)
to the inner harbor at LASO (6.7 mg/liter) (Table 1). Turbidity values
fluctuated seasonally as well as from station to station. In general,
the values measured were higher than the mean for a given station
during the summer of 1967 and lower during the late fall and early
winter of 1967-68.

Chlorinity. The surface chlorinity of the five stations ranged from
20.8 S/oo at LA7 in September 1968 to 10.6 °/oo at LAS4 in April
1967. The higher chlorinity measurements at each station followed,
in general, the higher water temperatures during the warmer months
of the year. The lower chlorinity measurements were correlated with
the fresh water run-off into the harbor from rain and industrial
effluents.

Dissolved Oxygen. Generally, the highest subsurface dissolved
oxygen (D.O.) measurements were obtained in the outer harbor and
the lowest in the inner harbor. The D.O. ranged from 2.4 to 5.7
mg/liter at LA7 and from 0.0 to 0.4 mg/liter at LA5O. Zero D.O.
readings were measured in one instance at LA54. The mean D.O. values
during the 16-month period of study were 4.0 at LA7, 2.3 at LA26,
2.6 at LA39, 1.5 at LAS4, and 0.1 at LA50 (Table 1).

Dissolved Nutrients. Phosphates were determined at each station
beginning in June 1967. The highest and lowest measurements of
phosphates occurred at LASO where values of 0.12 and 5.89 » g-at/liter
were determined. The mean value for the 8-month period of measure-
ment of phosphates was significantly higher at LASO than the other
four stations (Table 1).

The total nitrate-nitrite values ranged from 0.0 to 46.4 » g-at/liter
during the 16-month period of analysis. The mean nitrate-nitrite

175

Harbor Pollution

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176 Bulletin So. Calif. Academy of Sciences

values were highest at LA7 and lowest at LA5O (Table 1). Nitrate
and nitrite values determined separately followed the same trend as
the total values with the mean nitrite values being slightly higher than
the mean nitrate values at all stations but LA7 (Table 1).

Biological Data

A total of 295,963 specimens of polychaetes comprising 32 species
in 14 families was taken during the 17 collecting periods from October
14, 1966 through January 8, 1968. The number of species at each
station for each collection period are included in Table 2. Polychaetes
were present at all stations during the course of the study except at
LASO (Table 2). There were 30, 19, 17 and 5 species collected from
stations LA7, 26, 39 and 54 respectively (Table 1).

Station LA7. This station represented the least polluted of the five
stations sampled. The polychaetes most characteristic of this station
were Cirriformia luxuriosa, Cirratulus cirratus, Halosydna johnsoni
and Hydroides norvegica. The dominant organisms other than poly-
chaetes included the pelecypod Mytilus edulis, the barnacles Balanus
amphitrite and B. crenatus, and crab Pachygrapsus crassipes. A total of
8945 specimens of polychaetes were collected representing 30 species,
9 of which were unique to this station. A range of 4 to 16, with a median
of 8, species of polychaetes were collected at this station. In general,
the larger number of both specimens and species were taken in the late
spring and early summer of 1967 with the fewer numbers during the
winter months.

Station LA26. The polychaetes characteristic of this station included
Cirriformia luxuriosa, Polydora limicola, Ophiodromus pugettensis,
Hydroides norvegica, Capitella capitata, Ctenodrilus serratus and
Typosyllis fasciata. Other dominant organisms included the pelecypods
Mytilus edulis and Hiatella arctica, and the green alga Ulva sp. A total
of 217,961 specimens comprising 19 species were collected. Two
species, Polydora ligni and Ctenodrilus serratus, accounted for ap-
proximately 75 per cent of the number of specimens collected. A
range of 6 to 12, with a median of 10, species of polychaetes were
collected at LA26. No apparent seasonal differences with regard to
the number of species present were noted, but there was a sharp
increase in the number of specimens encountered between late May
and mid-October 1967.

Station LA39. The most characteristic species of this station were
Capitella capitata, Boccardia proboscidea, Syllides sp., Polydora
limicola, Ophiodromus pugettensis, Stauronereis rudolphi, Cirriformia
luxuriosa, and Hydroides norvegica. Other important organisms

177

Harbor Pollution

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Harbor Pollution 181

included the phoronid Phoronis sp., and the pelecypods Hiatella
arctica and Mytilus edulis. A total of 67,055 specimens comprising
17 species of polychaetes were collected. A range of 6 to 12, with a
median of 8, species of polychaetes were collected at this station. The
largest number of species were taken in the later summer and fall
months of the study, and the fewest number were taken during the
winter months. The largest number of specimens were encountered
from late summer to early winter.

Station LA54. Polychaetes were taken in only 6 of the 13 collections
made at this station. Five species totaling 2002 specimens were taken
from May through October 1967 with Capitella capitata constituting
the dominant species. An unidentified oligochaete was frequently
present along with the green alga Enteromorpha sp., and a chironomid
larvae.

Station LA5O. No polychaetes were collected during the period of
study. Other organisms present included an unidentified oligochaete,
blue green algae, diatoms, and rat-tail maggot larva.

DISCUSSION

Each of the five stations was unique with regard to their biological,
chemical, and physical characteristics; however, LA26 and LA39
were more similar than any other two stations (Table 1). A relationship
between the number of polychaete species and the number of speci-
mens was found to exist for some of the chemical and physical
characteristics of the water but not for others.

Temperature. Although variations were noted, the warmer the water
temperature, the greater the polychaete diversity and the larger the
number of specimens present, except at stations where the dissolved
oxygen was lower than about 0.5 mg/liter. Conversely, the minimal
number of species and specimens was observed during the colder
months. These data correspond to what was observed in nearby
Alamitos Bay and Playa del Rey (Reish 1964a,b).

Turbidity. The turbidity increased progressively from the outer to
inner harbor area. This corresponded inversely to the number of
polychaete species present. The highest population of Family Spionidae,
whose species utilize sediment for tube construction, occurred at the
station (LA26)with the next to lowest mean turbidity value. These
findings compare favorably with the observations Barnard (1958)
made during the 1950-51 period in Los Angeles-Long Beach Harbors.
He found that tubiculous amphipods and polychaetes were more

182 Bulletin So. Calif. Academy of Sciences

abundant in the area of the harbor having a high turbidity coincident
with favorable dissolved oxygen and temperature conditions. Station
LA26 was located near one of Barnard’s stations which exhibited
high populations of these tubiculous forms.

Dissolved Oxygen. The D.O. content of the water is one of the most,
if not the most, widely used indicator of water quality. Decomposition
of a pollutant may lead to reduction or depletion of D.O. (Ketcham,
1967). The highest mean D.O. value for a station for this study was
4.0 mg/liter at LA7. For comparison, mean value of 7.0 mg/liter D.O.
was recorded during this same time period at a station similar to LA7
in unpolluted Newport Harbor 48 km south of Los Angeles Harbor.
No polychaetes were collected at any of the stations when the dissolved
oxygen concentration was below 0.3 mg/liter. A suppression of the
number of polychaete species was noted when the dissolved oxygen
conditions were below 1.0 mg/liter; the median number of species
present for these conditions was 4. The median number of species
present for dissolved oxygen conditions between 1.0 and 1.9 mg/liter ©
was 10.

Dissolved Nutrients. Some general relationships between nitrate-
nitrites, phosphates and D.O. can be seen by noting the mean values in
Table |. As the nitrate-nitrites decreases and phosphates increase, the
D.O. decreases. Oil refinery wastes received in the inner harbor is one
possible explanation for the direct relationship between the nitrate-
nitrites and D.O. Oil oxidation requires a high level of D.O. (ZoBell,
1964), and when this level falls below five per cent saturation, nitrates
are reduced stepwise to molecular nitrogen (Standard Methods, 1960;
Preddy and Webber, 1964). The inverse relationship between D.O.
and phosphate is probably coincidental. Two primary sources of
phosphate are prevalent in the inner harbor: storm drains from surface
run off and industrial effluents.

The concentration of nitrite in sea water is small compared to
nitrate (Vaccaro, 1965). Higher nitrite values are often found in
polluted waters (Barnes, 1959). The mean nitrite values were higher
than the mean nitrate values at all stations but LA7 where they were
nearly equal (Table 1).

Bottom-dwelling polychaete species have been found to be useful as
indicators of varying degrees of marine pollution (Reish, 1959). One of
the primary purposes of this study was to ascertain whether or not the
polychaetes found in the fouling community of a floating dock would
be of importance asan indicator of marine pollution. Ifthis was foundtobe
true, the advantages would be that samples could be taken quickly and

Harbor Pollution 183

without the use of a boat, bottom samplers and extra man power. The
number of species, the number of specimens, and the dominant species
for each station are listed for each station in Table 1. While no truly
unpolluted station was represented in this study, variations in the
composition of the dominant species are noted. Each station was
characterized by at least one unique dominant polychaete species, and
there was a definite decrease in the number of polychaete species
present proceeding from the outer harbor at LA7 to the inner harbor
at LA50. Furthermore, quantitative differences were noted with
regard to specimens present at four stations. For example, the largest
specimens of Cirriformia luxuriosa were collected at LA7; they became
progressively smaller in size towards the inner harbor. However,
five times as many specimens of C. luxuriosa were taken from LA26
than LA7 (Table 2). Capitella capitata, a polychaete indicative of
polluted conditions (Wilhelmi, 1916; Reish, 1959), occurred at all
four stations with polychaetes; however, the percentage of the number
of specimens present compared to the others increased from lows of
5.1 and 2.3 per cent at LA7 and LA26 to 35.8 and 75.3 per cent at
LA39 and LAS4, respectively. The dominance of one species over
the others is similar to what Gaufin and Tarzwell (1952) noted for
fresh water pollution indicators.

Reish (1959) recorded 71 species of polychaetes from the benthos
of Los Angeles-Long Beach Harbors in 1954. It is of interest to note
that only nine species were present on the bottom and in the fouling
community: Hypoeulalia bilineata, Ophiodromus pugettensis, Ne-
anthes arenaceodentata, Platynereis bicanaliculata, Stauronereis
rudolphi, Cirratulus cirratus, Cirriformia luxuriosa, Armandia, bio-
culata and Capitella capitata. However, the harbor conditions, as
defined by the indicator polychaetes, were found to be generally similar
in the two studies. Reish (1959) described station LA7 as healthy,
and stations LA54 and LASO as polluted to very polluted. These
results agree with the current study. LA26 and LA39 were described
as healthy and polluted respectively by Reish. In the current study
these stations were biologically, chemically and physically more
similar than any other two stations. The degree of pollution was found
to be intermediate between LA7 and LAS4. This difference between
the two studies at LA26 and LA39 may be due to one or a combination
of several factors: totally different environments, change in pollution
conditions during the period between the two studies, or a difference
in water circulation between the shore where the fouling organisms
were collected and the mid-channel where the benthos was collected.

184 Bulletin So. Calif. Academy of Sciences
ACKNOWLEDGMENTS

The authors wish to thank Dr. James A. Blake for his identification of the spionid
polychaetes and Mr. Stanley G. Crippen for his assistance with some routine
aspects of this study. Thanks is also extended to Dr. Paul A. Haefner, Jr. and
Mr. David G. Trainer for reading and critisizing the manuscript. We thank Mr.
Roy C. Hampson, Los Angeles Regional Water Quality Control Board, for
supplying the data on waste discharges in the harbor.

SUMMARY

1. A quantitative survey of the polychaetous annelids was made at
28-day intervals from five selected floating docks in Los Angeles
Harbor from October 1966 through January 1968. Chemical and
physical data taken at the same time consisted of water temperature,
turbidity, chlorinity, dissolved oxygen, phosphates and _ nitrates-
nitrites. Stations were selected according to variations in the degree
of pollution.

2. A total of 295,963 specimens comprising 32 species of polychaetes
were taken from four stations during the period of study. No poly-
chaetes were present at any time at the highly polluted station. These
data were summarized in tabular form.

3. Each station was characterized by at least one unique commonly
encountered polychaete species. The number of species present at a
station decreased as the degree of pollution increased.

4. Capitella capitata coprised an increasing percentage of the total
polychaete population from the outer harbor to the inner harbor.

5. Water temperatures, turbidity and phosphates were highest at the
most polluted station in the inner harbor. Chlorinity, dissolved oxygen
and nitrates-nitrites were highest at the cleanest station studied in
the outer harbor. These data were summarized as in tabular form as
ranges and means for each station.

6. The use of the polychaete fouling community as indicators of varying
degrees of pollution was discussed.

LITERATURE CITED

ANON, 1952a. Los Angeles-Long Beach Harbors pollution survey. Calif., Los
Angeles Regional Water Pollution Control Board No. 4, 43 p.

1952b. Marine fouling and its prevention. U.S. Naval Institute, Annapolis,
388 p.

Harbor Pollution 185

ANON, 1960. Standard methods for the examination of water and waste water,
eleventh ed., American Pub. Health Assoc., N.Y.. 626 p.

BARNARD, J. L., 1958. Amphipod crustaceans as fouling organisms in Los Angeles-
Long Beach Harbors, with reference to the influence of seawater turbidity.
Calif. Fish and Game. 44: 161-170.

BaRNES, A., 1959. Apparatus and methods of oceanography. Interscience Publ.,
New York, 341 p.

BELLAN, G., 1965. Influence de la pollution sur le faune annelidienne des substrats
meubles. /n Pollutions marines par les microorganismes et les produits
petroliers. Commission internationale pour l’exploration scientifique de la
mer Mediterranee, Monaco. p. 123-126.

BELLAN-SANTINI, D., 1968. Influence de la pollution sur les peuplements benthi-
ques. Rev. Intern. Oceanogr. Med. 10: 27-53.

BLEGvaD, H., 1932. Investigations of the bottom fauna at outfalls of drains in the
Sound. Rept. Danish Biol. Station. 32: 1-20.

FILIcE, F. P., 1954a. An ecological survey of the Castro Creek area in San Pablo
Bay. Wasmann J. Biol. 12: 1-24.

1954b. A study of some factors affecting the bottom fauna of a portion of
the San Francisco Bay estuary. Wasmann J. Biol. 12: 257-292.

1958. Invertebrates from the estuarine portion of San Francisco Bay
and some factors influencing their distribution. Wasmann J. Biol. 16: 159-
211.

1959. The effect of wastes on the distribution of bottom invertebrates in
the San Francisco Bay estuary. Wasmann J. Biol. 17: 1-17.

ForBES, S. A. AND R. E. RICHARDSON, 1913. Studies on the biology of the Upper
Illinois River. Bull. Illinois State Lab. Nat. Hist. 9: 481-574.

GAUFIN, A. R. AND C. M. TARZWELL, 1952. Aquatic invertebrates as indicators of
stream pollution. Public Health Repts. 67: 57-64.

GiLET, R., 1960. Water pollution in Marseilles and its relation with flora and
fauna. In Waste Disposal in the Marine Environment, E. A. Pearson, Editor.
Pergamon Press, New York, p. 39-56.

Hoac, J., 1966. Treatment of petroleum refinery waste water for disposal to
Dominguez Channel. Bull. Calif. Water Pollution Control Assoc. 3: 26-27.

KETCHUM, B. H., 1967. Man’s resources in the marine environment. Jn Pollution
and marine ecology, T. A. Olson and F. J. Burgess, Editors. Interscience
Publishers, New York, p. 1-11.

KeEup, L. E., W. M. INGRAM, AND K. M. MACKENTHUN, 1966. The role of bottom-
dwelling macrofauna in water pollution investigations. Public Health
Service Publication, No. 999-WP-38, 23 p.

KOLKWITz, R. AND M. Mansson, 1908. Oekologie der pflanzlichen Saprobien.
Ber. Deutsch. Bot. Ges. 26: 505-519.

KiTamort, R., 1961. The relations between the distribution of the genus Capitella,
polychaetous annelids, and pollution. Inland Sea Res. Biol. Station Bull.
13: 1-18. [In Japanese, English summary].

186 Bulletin So. Calif. Academy of Sciences

PATRICK, R., 1949. A proposed biological measure of stream conditions based on
a survey of the Conestoga Basin, Lancaster County, Pennsylvania. Proc.
Acad. Nat. Sci., Phila. 101: 277-295.

PREDDY, W. S. AND B. WEBBER, 1964. The calculation of pollution of the Thames
Estuary by a theory of quantized mixing. In Advances in water pollution
research, Vol. 3, E. A. Pearson, Editor. Pergamon Press, Oxford, p. 309-
323.

RaMBow, C. A., 1964. Pollution study of a future tidal estuary. J. Water Pollution
Control Fed. 36: 520-528.

REISH, D. J., 1955. The relation of polychaetous annelids to harbor pollution.
Public Health Repts. 70: 1168-1174.

1959. An ecological study of pollution in Los Angeles-Long Beach
Harbors, California Allan Hancock Foundation. Occasional Paper No. 22,
119 p.

196la. The relationship of temperature and dissolved oxygen to the
seasonal settlement of the polychaetous annelid Hydroides norvegica
(Gunnerus). Bull. So. Calif. Acad. Sci. 60: 1-11.

1961b. The use of the sediment bottle collector for monitoring polluted .
marine waters. Calif. Fish and Game. 47: 261-272.

1964a. Studies on the Mytilus edulis community in Alamitos Bay, Cali-
fornia: II. Population variations and discussion of the associated species.
Veliger. 6: 202-207.

1964b. Discussion of the Mytilus californianus community on newly
constructed rock jetties in southern California. Veliger. 7: 95-101.

STRICKLAND, J. D. H. AND T. R. Parsons. 1965. A manual of sea water analysis.
Second Edition, revised. Res. Board of Canada, Fisheries Bull. No. 125,
203 p.

VACCARO, R. F., 1965. Inorganic nitrogen in sea water. In Chemical oceanography,
Vol. 1, J. P. Riley and G. Skirrow, Editors. Academic Press, London, p.
365-408.

WILHELMI, J., 1916. Ubersicht tiber die biologische Beurteilung des Wassers.
Geo. Anturf. Freude Berlin, Sitzer. vol. for 1916, p. 297-306.

ZOBELL, CLAUDE E., 1964. The occurence, effects, and fate of oil polluting the sea.
In Advances in Water Pollution Research, Vol. 3, E. A. Pearson, Editor.
Pergamon Press, Oxford, p. 85-108.

Accepted for publication June 9, 1969.

Bull. So. Calif. Acad. Sci. 68(3): 187-190, 1969

A NEW SPECIES OF ODONTACA RUS EWING
(ACARINA: TROMBICULIDAE) FROM LIZARDS
OF BAJA CALIFORNIA SUR, MEXICO!

RICHARD B. LOOMIS AND LEE C. SPATH
California State College, Long Beach
California 90801

ABSTRACT: Odontacarus robbinsi n. sp. is described from
larvae taken off Sceloporus orcutti licki from 3.2 km S San
Antonio, Baja California Sur, Mexico, and additional larvae
were from Sceloporus magister zosteromus, and Urosaurus
nigricaudus of the cape region. This species closely resembles
Odontacarus cayolargoensis Brennan, 1959.

INTRODUCTION

Examination of trombiculid mites found on three species of iguanid
lizards from the cape region of Baja California Sur, México, has
revealed a new species of Odontacarus Ewing. Two other species of
Odontacarus are known from Baja California. Odontacarus cognatus
Brennan was taken in the north, and O. arizonensis (Ewing), has been
found throughout the peninsula on lizards, including the hosts of the
new species.

The new species described below bears the name of Mr. Lynn W.
Robbins who collected the type hosts as well as numerous other verte-
brates and their chiggers.

Odontacarus robbinsi, new species
Figure |

Types. — Total 25 larvae: Holotype and 18 paratopotypes from
3.2 km S San Antonio, 375 m, Baja California Sur, Mexico, taken 28
June 1967 off 2 Sceloporus orcutti licki, LWR670628-3 (holotype
+ 10); LWR670628-2 (5); Urosaurus nigricaudus, LWR670628-8
(2); and Sceloporus magister zosteromus, LWR670628-9 (1); and 6
paratypes from 19 km SW San Jose del Cabo, 2-20 m, Baja California
Sur, Mexico, taken 3 July 1967 off Urosaurus nigricaudus, LWR-
670703-1.

The types are in the chigger research collection, California State
College, Long Beach. The holotype and one paratype will be sent to

1Studies upon which this paper is based were supported by the U. S. Public Health
Service Research Grant AI-03407 from the National Institute of Allergy and
Infectious Diseases.

187

188 Bulletin So. Calif. Academy of Sciences

the Rocky Mountain Laboratory, Hamilton, Montana, and other para-
types will be sent to appropriate institutions and individuals.

Diagnosis. — Larvae, similar to Odontacarus cayolargoensis
Brennan (1959), in having palpal setal formula B/B/BNN, palpal tarsus
7B, branched galeala, branched sensilla, without parasubterminala I,
| mastitarsala III with basal barbs; but differing from O. cayolargoensis
in having 4 dorsal and 3 ventral teeth on the cheliceral blade (5 and 6
in O. cayolargoensis), longer tarsala I (32) and tarsala II (20) (12 and
13 respectively in O. cayolargoensis), anteromedian setae (AM) in
line with anterolateral setae (AL), and posterolateral setae (PL)
posterior to, or in line with sensillary bases (AM setae posterior to AL
setae, and PL setae anterior to sensillary bases in O. cayolargoensis).
Odontacarus robbinsi differs from O. arizonensis and O. cognatus in
having palpotibial setae BNN (NNN in O. arizonensis and BBB in
O. cognatus), genuala II (absent in others), tarsala II not expanded
(distally expanded in O. arizonensis, slightly expanded in O. cognatus),
genuala III (absent in others), and mastitarsala III (present in O. ari-
zonensis, absent in O. cognatus).

Description. — Larvae (all measurements in microns, with means
and extremes of 25 types listed in parentheses). Holotype: body par-
tially engorged, 288 by 230, eyes 2/2 on ocular plates, anterior
slightly larger.

Dorsal setal formula 10-8-6-10-8 +27, total 69; measurements;
anterior dorsal seta 50, posterior dorsal seta 40.

Ventral setal formula 2-10-8 +14, total 34; measurements; sternal
seta 27, posterior ventral seta 31. Body setae total 103.

Scutum: PW longer than PSB + ASB, posterior margin rounded
(somewhat angular), lightly punctate, flagelliform sensilla with branches
on distal third of shaft.

Scutal measurements of holotype (with means and ranges of 25
types in parentheses) AW 61 (63, 59-66), PW 80 (79, 76-87), SB 25
(24, 21-27), ASB 33 (33, 29-38), PSB 25 (24, 22-26), AP 33 (33,
31-38), AM 40 (40, 36-43), AL 38 (38, 36-42), PL 55 (53, 48-59),
S 705695 57-76):

Gnathosoma: Cheliceral blade with 4 dorsal and 3 ventral teeth,
cheliceral base and capitular sternum punctate, palpal setal formula
B/B/BNN, palpal tarsus with 7 branched setae and tarsala 7; palpal
claw trifurcate, with dorsal prong largest and curved outward. Tracheae
and spiracles present.

Legs: Leg I with 2 genualae, microgenuala, 2 tibialae, microtibiala,
tarsala 32 (31, 28-33), microtarsala, subterminala (parasubterminala
absent), and pretarsala; Leg II with genuala, microgenuala, 2 tibialae,

New Species of Chigger 189

tarsala 20 (19, 18-21), microtarsala and pretarsala; Leg III with
genuala, tibiala, and mastitarsala, 54, having several basal barbs. Each
leg with 6 elongate, lightly punctate segments, terminating in 2 claws
and a clawlike empodium, each with 6 onychotriches.

Ecological notes. — Larvae of Odontacarus robbinsi were taken
from three Sceloporus orcutti licki, one S. magister zosteromus, and
five Urosaurus nigricaudus, from three localities in the cape region
of Baja California. Nelson (1922) indicated these localities are in the
Arid Tropical Zone characterized by a dry climate and a tropical flora.
Chiggers associated with Odontacarus robbinsi were O. arizonensis,
Eutrombicula alfreddugesi, and Neoschoengastia sp.

Specimens examined. — Total of 33 larvae: MEXICO: BAJA
CALIFORNIA SUR, Boca de la Sierra, 12 Aug. 1966, Urosaurus
nigricaudus (1); Miraflores, 12 July 1963, Urosaurus nigricaudus (2);
3.2 km S San Antonio, 6 July 1963, Urosaurus nigricaudus (3); 7 July
1963, Sceloporus orcutti licki (2); 28 June 1967, 2 Sceloporus orcutti
licki (16), Sceloporus magister zosteromus (1), Urosaurus nigricaudus
(2); 19 km SW San Jose del Cabo, 3 July 1967, Urosaurus nigricaudus
(6).

ACKNOWLEDGMENTS

For the loan of paratypes of Odontacarus cayolargoensis we thank Dr. James M.
Brennan of the Rocky Mountain Laboratory, Hamilton, Montana. Appreciation
is also extended to Sr. Dr. Rodolfo Hernandez Corzo, el Director General,
Direccion General de Caza, Departamento de Conservacion de la Fauna
Silvestre, Secretaria de Agricultura y Ganaderia for permits to collect reptiles
and other vertebrates in México. We are indebted to K. K. Asplund, R. M. Davis,
E. M. Fisher, L. M. Hardy, J. Knox Jones, Jr., L. W. Robbins, E. L. Sleeper,
and J. P. Webb, Jr., for collecting vertebrates and their ectoparasites.

LITERATURE CITED

BRENNAN, J. M. 1959. Synonymy of Odontacarus Ewing, 1929, and Acomata-
carus Ewing, 1942, with redescriptions of O. dentatus (Ewing) and O. aus-
tralis (Ewing), also descriptions of three new species from southern United
States (Acarina: Trombiculidae). Ann. Entomol. Soc. Amer. 52: 1-6.

BRENNAN, J. M. 1966. New records of chiggers (Acarina: Trombiculidae) from
Baja California and islands of the Gulf of California. J. Parasitol. 52: 772-
VIS:

BRENNAN, J. M. AND E. K. JONES. 1959. Keys to the chiggers of North America
with synonymic notes and descriptions of two new genera (Acarina: Trom-
biculidae). Ann. Entomol. Soc. Amer. 52: 7-15.

NELSON, E. W. 1922. Lower California. and its natural resources. Nat. Acad.
Sci. 16(First Memoir): 1-194.

Accepted for publication June 16, 1969.

190 Bulletin So. Calif. Academy of Sciences

Figure 1. Larva of Odontacarus robbinsi, n. sp. A. Scutum and eyes. B. Dorsal
aspect of gnathosoma. C. Ventral aspect of palpotibia and tarsus. D. Body setae:
H, humeral; PD, posterior dorsal; St, Sternal. E. leg I, showing nude setae and
measurements. F. leg II, as above. G. leg III, as above.

Bull. So. Calif. Acad. Sci. 68(3): 191-193, 1969
RESEARCH NOTES

THE RESPONSE OF MALE GRUNION
TO A WIGGLING STICK

The California grunion, Leuresthes tenuis, spawns on sandy beaches
during high tide cycles from March through July. At that time the
female grunion, accompanied by 1-8 males (Walker, 1952), swims
with an incoming wave high up onto the beach. She then generally
burrows tail first more or less straight down into the sand until about
80 per cent of her body is buried. During the active burrowing and
while she is in the sand, the female wiggles or twitches from side to
side. Many males may surround her at this time, wriggling into the
sand around her, ventral side down, in a characteristic snake-like
fashion. The males then release their milt which is worked down the
side of the female to the eggs by her sideward movements. The males
depart and the female wrenches free of the sand with violent twitching
movements. All return to the ocean with the next wave or by simply
flopping back down to the water.

Since the egg-laying female grunion is the only moving upright
object normally found in the spawning area, the following experiment
was performed to test the hypothesis that the appropriate movement of
any upright object simulating the female might serve as the copulatory
cue.

In areas where spawning grunion were abundant, pointed wooden
dowels, one inch in diameter and two feet long, were inserted in the
sand near individual fish and wiggled by hand in 30° arcs at a rate of
about 1-2 arcs/sec, which roughly approximates the movement of a
female grunion. When a fish was observed to wriggle down in an S-
shaped configuration into the puddled sand around the stick, a sample
of the water between the stick and the fish was taken with an ordinary
kitchen baster. This sample was squirted into a vial and saved for
laboratory examination. The fish then was captured by hand and
sexed by squeezing its sides to express the gametes.

Random samples of water were taken in the same manner in areas
where the grunion density was less than 25 fish per quarter square meter
and an area where the density was approximately 170 fish/0.25 m2.

A total of 42 water samples were taken around the sticks and all of
these contained sperm. Forty-one of the fish associated with the samples
proved to be males. The forty-second was washed away before it could
be caught.

Wik

192 Bulletin So. Calif. Academy of Sciences

Only 4 of the 43 random water samples taken in areas where the
fish density was low showed any cloudiness indicative of the presence
of sperm. All of the samples from the area of high fish density showed
heavy sperm concentrations. However, 19 of the water samples taken
around the sticks showed greater sperm concentrations than the most
concentrated samples taken in the area of low fish density and eleven
of these 19 samples were more concentrated than any of the random
high fish density water samples. Three of the water samples from
around the sticks closely approximated the concentration of sperm
obtained by squeezing the fish. On at least one occasion the fish adjacent
to the stick was actually seen to release its milt prior to the time the
water sample was taken.

The males will not respond to the sticks unless and until the grunion
run is well under way, i.e., the normal spawning process is occurring
along most of the beach.

The male fish do not come to the stick but when a stick is wiggled
very near them, they respond to it by moving downward into the sand
as described above. Whether it is the vibration of the stick itself or the
vibrations set up in the surrounding sand that the fish responds to is
not clear. Part of the response seems to require the soft, puddled sand
which is created by the pressure of the stick (or female) when it is
moved. Without this puddling condition, the male cannot work his way
into the sand. The actual release of milt may be under the control of
the male or may be in response to pressure, since the males, when they
are ripe, will discharge milt when their sides are gently squeezed.

Still another possibility relates to the fact that high pitched squeak-
ing sounds may be heard which appear to come from the female as she
lays her eggs. It may be that the abrasion of sand by the stick generates
frequencies comparable enough to deceive the male.

All of this does not preclude the possibility that, although there are
insufficient data to confirm this, a male grunion may respond positively
to an upright, non-wiggling object, e.g. a stick or boots. The one obser-
vation of fish around a stationary stick was not confirmed by sexing
fish. The impression created, however, is that a puddling of the sand
is a definite requirement.

Many experiments to explore the various parameters of this problem
suggest themselves. Whatever the explanation, a wiggling stick does
serve as a cue to male grunion to release their milt around that stick in
a manner apparently identical with their normal beliavior during
spawning.

I wish to thank Mr. John Olguin, Director, Cabrillo Beach’ NRSEOEN
San Pedro, California and my students at Cerritos College, Norwalk,

Grunion Behavior 193

California, especially Roger Zachary and Chris Beattie, without whose
enthusiastic participation this experiment would not have been

completed.

LITERATURE CITED

WALKER, B. W., 1952. A guide to the grunion. Calif. Fish and Game. 38: 409-420.

Jules M. Crane, Jr., Biology Department, Cerritos College, Norwalk,
California 90650.

Accepted for publication May 13, 1969.

Bull. So. Calif. Acad. Sci. 68(3): 194-195, 1969

A WESTERN YELLOW BAT IN LOS ANGELES
COUNTY, CALIFORNIA

Constantine (1966) has summarized all known records of the western
yellow bat (Lasiurus ega xanthinus Thomas) in the southwestern
United States. Only two of these records are from Southern California:
Palm Springs, Riverside County (Constantine, 1946) and Cottonwood
Spring, Joshua Tree National Monument, Riverside County (Loomis,
1964). On 22 January 1969, an adult male was taken at 1330 Pros-
pect Drive, Pomona, about 1.5 miles inside of the southeastern bound-
ary of Los Angeles County. The bat was discovered in the home-
owner’s front yard about 3 PM on a windy, rainy afternoon, four days
after the beginning of an unusual eight-day tropical storm. I arrived at
5 PM and found the animal still in its original position. A whorl of
dead fronds had become detached from near the top of a Mexican fan
palm and slid down the trunk to the ground, a distance of about 14 m..
The bat was hanging head down on the frayed leaflets of a frond about
20 cm from the petiole. In this position on the outside of the frond, it
would normally have been sheltered by fronds of the whorls above.
Having been exposed, however, the bat was soaking wet. It was torpid
and moved only slightly when touched. The air temperature at this
time was about 12°C. Measurements of this specimen were: length
116 mm, forearm 47 mm, tibia 20 mm, hind foot 7 mm, ear 7 mm. The
study skin and skull are deposited as specimen No. 00695 in the mam-
mal collection of California State Polytechnic College, Kellogg-
Voorhis Campus.

This new record extends the known range 70 miles west of Palm
Springs, and from the desert into the coastal region (shortest distance
from Pomona to the coast is 30 miles). Ryan (1968) has suggested that
the distribution of this species in Southern California may be closely
associated with the occurrence of fan palms which seem to be its usual
roosting sites. Since the California fan palm (Washingtonia filifera)
and the taller, more slender Mexican fan palm (W. gracilis) are com-
monly used as decorative trees throughout this area, it is possible that
the yellow bat is much more widespread here than the records presently
indicate. Significantly, perhaps, the address given above is adjacent
to the Palm Lakes Golf Course where a number of fan palms are
planted.

LITERATURE CITED

CONSTANTINE, D. G., 1946. A record of Dasypterus ega xanthinus from Palm
Springs, California. Bull. So. Calif. Acad. Sci. 45: 107.

194

Western Yellow Bat 95
1966. New batlocality records from Oaxaca, Arizonaand Colorado. J. Mam-
malogy, 47: 125-126.

Loomis, R. B. 1964. The southern yellow bat in Joshua Tree National Monu-
ment, California. Bull. So. Calif. Acad. Sci. 63: 26.

RYAN, R. M., 1968. Mammals of Deep Canyon, Colorado Desert, California.
The Desert Museum, Palm Springs, California, 137 pp.

Glenn R. Stewart, Biological Sciences Department, California State
Polytechnic College, Kellogg-Voorhis Campus, Pomona, California
91766.

Accepted for publication May 13, 1969.

Bull. So. Calif. Acad. Sci. 68(3): 196-197, 1969
SCIENTIFIC NEWS AND COMMENTS

MARINE LIFE REFUGES

Three marine life refuges were established on southern California
beaches by the 1968 Legislature. The legislation to establish these was
introduced at the request of city and county officials (Laguna Beach
and Newport Beach, Orange County) who were becoming alarmed at
the rapid depletion of marine life in the tide pools.

The law governing use of these three beaches became effective
November 13, 1968. It stipulates that in these three refuges, “the
following fish, mollusks, and crustaceans may be taken under the
authority of a sport fishing license: abalone, lobster, bonito, rockfish,
mackerel, perch, kelp bass, sand bass, spotted bass, corbina, croaker
and halibut. All other fish and forms of aquatic life are protected and
may not be taken without a written permit from the Department”
(Section 10664, Fish and Game Code).

The legal description of each refuge is as follows:

Newport Beach — The refuge extends from the eastern boundary
of the city of Newport Beach to Poppy Avenue, and extends 200 feet
seaward from the mean high tide mark.

Laguna Beach — The refuge boundary begins at the western boun-
dary of Laguna Beach at mean high tide, extends seaward 600 feet
along the city boundary, eastward about 5,725 feet, northward 700
feet, then westward along mean high tide line to the point of beginning.

South Laguna Beach — The refuge boundary begins at mean high
tide and a line which bears South 48° 50’ 00” West, runs south 48°
50’ 00”, West about 600 feet to the minus 20 foot contour at mean
lower low water, runs southeasterly and generally parallel to shore
about 2700 feet along the minus 20 foot contour, to a line which bears
South 35° 57’ 06” West, then runs North 35° 57’ 06” East to a line
of mean high tide, then runs northwesterly along the mean high tide
line to the point of beginning.

ACADEMY AWARDS

At the annual meeting of the Academy held on the campus of Univer-
sity of California, Irvine on May 10, 1969, the following awards were
presented:
Best Paper Awards:
First Prize: Diane S. Baker, Occidental College, “Isolation and
Characterization of Some Canavanine-Resistant Mutants of
Escherichia coli.” $200.00.

196

News and Comments 197

Second Prize: Roy M. Yarnell, California State College at Fuller-
ton, “Will Classification Ever Become the Backbone of the
Invertebrates?” $75.00.

Third Prize: Jack Turner, California State College at Fullerton,
“Physiological-Ecology of the Great Horned Owl, Bubo vir-
ginianus pacificus.” $25.00.

AAAS Awards .

Wayne R. Davis, California State College at Long Beach, “A
two-way analysis of variance between dissolved oxygen sup-
pression and DDT (or thermal pollution) to determine strength
of reproductive inhibition in Neanthes arenaceodentata.”
$130.00.

David C. Harris, California State Polytechnic College, Pomona,
“Studies on yellow-headed and red-winged black birds.”
$117.00.

MEETING NOTICE

The Western Society of Naturalists will hold their annual meeting on
the Campus of University of California, Los Angeles on December 27-
30, 1969. Local chairman is Leonard Muscatine. Submit papers to
David Montgomery, California State Polytechnic College, San Luis
Obispo, California 93401 (membership required).

Scientific news or comments which are of interest to the readers of the
Bulletin may be included in this section by contacting the Editor. Please
allow a lead time of three to four months.

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Academy of Sciences

OFFICERS OF THE ACADEMY
BOARD OF DIRECTORS

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PUTATENVEI STATECUL iy aire. gic ete ane eleieve Neh ie anslete ale Sava ehe First Vice President
PIMC SICEPCE 20. ole cso vse cee eee sem eane Second Vice President
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2eBULLETIN OF THE

Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

VOL. 68 OCTOBER-DECEMBER 1969 PART 4

KoMaucbinurZ ins

LIBRARY

aeR 4) 1810

NEW YORK
BOTANICAL GARDE

CONTENTS

Bryozoan -algal associations in southern California waters. Penny
Pinter
The identity of the frog, Pseudohyla nigrogrisea of Ecuador.
John D. Lynch
A new species of Hexidionis (Acarina, Trombiculidae) from kan-
garoo rats (Genus Dipodomys) of western North America.
Richard B. Loomis and James L. Lucus
Serpulidae (Annelida: Polychaeta) from Oahu, Hawaii. Dale Strau-
ghan
New neotropical Curculionidae (Coleoptera). Elbert L. Sleeper...
The recent introduction of Watersipora arcuata Banta (Bryozoa,
Cheilostomata) as a fouling pest in southern California.
William C. Banta
Three brief narrow-band sound emissions by a captive male Risso’s
dolphin, Grampus griseus. David K. Caldwell, Melba C. Cald-
well, and J. Frank Miller
. Research Notes:
\ A record of the entoniscid parasite, Portunion conformis.
: Muscatine (Crustacea: Isopoda), infecting two species of
Hemigrapsus. Fred M. Piltz
Survival of weevils through the digestive tract of an amphib-
ian. Jay W. Fair
Scientific News and Comments
Index to volume 68

—=\

DECEMBER 31, 1969

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BULLETIN OF THE SOUTHERN CALIFORNIA
ACADEMY OF SCIENCES

Vol. 68 OCTOBER-DECEMBER, 1969 No. 4

Bull. So. Calif. Acad. Sci. 68(4): 199-218, 1969

BRYOZOAN-ALGAL ASSOCIATIONS IN
SOUTHERN CALIFORNIA WATERS!

PENNY PINTER
Department of Biology,
Simmons College
Boston, Massachusetts

ABSTRACT: Intertidal bryozoan algal associations were studied
along the southern California coastline between La Jolla and
Santa Barbara and on Santa Catalina Island. Seventeen species
of bryozoans were identified incrusting 6 species of Chloro-
phyta, 13 species of Phaeophyta and 43 species of Rhodophyta.
Collections were made at 15 southern California stations;
herbarium specimens of algae from 32 southern California
stations were examined. Factors affecting bryozoan preference
for an algal substrate were: (1) the location of algae in the
littoral region; (2) availability of various substrata; (3) produc-
tion of anti-fouling substances by brown and possibly red
algae.

INTRODUCTION

On a number of occasions bryozoan (ectoproct)-algal associations
have been recorded in the literature. Darwin (1845) made note of
the Flustraceae found incrusting Macrocystis pyrifera (Linnaeus)
C. A. Agardh, at Tierra del Fuego and “Chiloe”’. Such associations on
the English coast were also mentioned by Hincks (1880) and Busk
(1852), by Joliet (1877), Prenant and Tessier (1924), and Prenant
(1927, 1932) on the French coast, Bock (1950, 1954) on the Baltic
Coast. Osburn (1950, 1952, 1953) and Robertson (1908) noted the
bryozoan-algal associations on the California coast, and Rogick and
Croasdale (1949) published a detailed study of such occurrences in
the Woods Hole area. More recently, the selection of algal substrates

! Systematics-Ecology Program Contribution Number 204

199

200 Bulletin So. Calif. Academy of Sciences

by bryozoan larvae has been investigated by Ryland (1958, 1959,
1962), Crisp and Williams (1960) and Crisp and Ryland (1960).

The purpose of the present study is to observe the algal-bryozoan
associations occurring predominantly in the intertidal area of the
southern California coastline between La Jolla and Santa Barbara
and including Santa Catalina Island.

METHODS

Algae were collected from fifteen sites along the southern Cali-
fornia coastline. The most accessible algae were located in the intertidal
area. The large kelp, collected from beach debris, were probably
from offshore kelp beds. Data were supplemented from herbarium
specimens donated by E. Yale Dawson to the Rutgers University
Herbarium.

The localities of my field trips and the sites reported on the her-
barium specimen sheets are given in Tables 1 and 2, respectively.
Localities in the species descriptions noted with an asterisk refer to
bryozoans found only on the herbarium specimens. Localities marked
with a plus refer to bryozoans collected both in this study and found
on the herbarium sheets as well. Localities not marked with symbols
indicate bryozoans collected by me.

Figure 1. Membranipora membranacea showing spinules on membrane surface
and tower cell.

Figure 2. Membranipora villosa. Zooids of young colony, chitinous spinules on
membrane surface and long spines near margin of zooecia. Abbreviations: s,
spine; sp, spinule; tc, tower cell.

Bryozoan-Algal Associations 201

ACKNOWLEDGEMENTS

My sincerest thanks to E. T. Moul of Rutgers University at New Brunswick,
New Jersey for access to the Yale Dawson algae collection; to John D. Soule
and Dorothy F. Soule for their helpful advice, useful suggestions and constant
encouragement; and to Frank E. Round, Donna M. Walters and Lawrence Pinter
for reading the manuscript. I also want to thank Roger Taylor, Frank Ennik
and Lawrence Pinter for their help in field collecting. This study was initiated in
the Department of Zoology, California State College at Los Angeles and com-
pleted in the Systematics-Ecology Program, Marine Biological Laboratory,
Woods Hole, Massachusetts.

Order Cheilostomata Busk
Suborder Anasca Levinsen
Family Membraniporidae Busk
Genus Membranipora Blainville
Membranipora membranacea Blainville
Figure 1

This species of Bryozoa was found frequently on Macrocystis
pyrifera and Egregia laevigata Setchell. On the older kelps Membrani-
pora membranacea colonies were found covering large areas with
colonies coalescing and giving the kelp a white, lace-like appearance.
M. membranacea appears to be a very rapidly growing bryozoan. On
the two species of kelp mentioned above, where both M. villosa and
M. membranacea were found together, the latter grows over the
former and is the dominant species. Bobin and Prenant (1966) found
M. membranacea colonies which covered several decimeters and they
also concluded that their growth was quite rapid. M. membranacea
was found incrusting the blades, stipes and bladders of the two species
of algae.

Description: A new variation of this species hitherto undescribed
has been found. Small delicate spines have been found on the surface
of the frontal membrance. These spinules are more delicate in appear-
ance than those found on M. villosa. They were also found on colonies
which contained tower cells. No spines were radiating from the
cryptocyst.

The twinned ancestrula of M. membranacea lacks the long or forked
spines sometimes possessed by M. villosa. Except in zoocia near the
ancestrula, the zooecia are rectangular, arranged in rows and alternate.
The membrane occupies the entire frontal. Each corner has a blunt,
knobby spine projecting at a right angle. A tall membranous tube
called a tower cell, blunt at the tip, is found at the junction of a single
zooecium from which two, rather than one, zooecia are budding.

202 Bulletin So. Calif. Academy of Sciences

Occurrences: Ventura, Alamitos Channel, 3 mi. NE of Avalon
(floating), Avalon Harbor, Corona del Mar, La Jolla, San Clemente,
Victoria Cove.

Membranipora villosa Hincks
Figure 2

M. villosa was found on only two species of algae, Macrocystis
pyrifera and Egregia laevigata, both large kelps. The colonies were
small, 3-4 cm. at most, and scattered over the surface of the blades.
O’Donoghue (1926) found this species to be the most common of the
incrusting forms on eelgrass and large brown kelp from Departure
Bay, British Columbia.

Although Robertson (1908) and Osburn (1950) observed large
numbers of Membranipora villosa colonies coalescing and frequently
covering the entire surface of a frond, I did not find this condition on
any of the large kelp examined from southern California. It is possible
that when M. villosa is not competing with M. membranacea, M.
villosa does produce large colonies. Robertson and Osburn considered
the chitinuous spines on the frontal membrane to be the most distinctive
feature of M. villosa. M. villosa and M. membranacea are quite similar
in appearance, i.e., both have spines on the frontal membrane. I am in

TABLE |
CALIFORNIA COLLECTING LOCALITIES

Station Collecting Date
Number Sites Collected
1 Ventura State Beach, Ventura Co. February 1965
2 Alamitos Channel, Los Angeles Co. March 1965
3 Alamitos Bay, Los Angeles Co. April 1965
4 Cabrillo Beach, Los Angeles Co. April 1965
5 Victoria Cove, Laguna Beach, Orange Co. May 1965
6 Dana Point, Orange Co. May 1965
7 Santa Catalina Channel, 3 mi. NE of south tip of Santa May 1965
Catalina Island, Los Angeles Co.
8 Fourth of July Cove, Santa Catalina Island, Los Angeles June 1965
Co.
9 Avalon Harbor, Santa Catalina Island, Los Angeles Co. June 1965
10 Little Harbor, Santa Catalina Island, Los Angeles Co. June 1965
(beach debris)
11 Corona del Mar, Orange Co., (part beach debris) April 1965
12 San Clemente, Orange Co. June 1967
13 Oceanside, Orange Co. (beach debris) June 1967

Victoria Cove, Laguna Beach, Orange Co.
La Jolla, San Diego Co.

September 1968

June i965

Bryozoan-Algal Associations 203

nplete agreement with O'Donoghue (1926) who noted that these
) species could easily be confused with one another.

Description: M. villosa produces a twinned ancestrula with long
icate, frequently forked, spines. Spines on all corners of the quad-
ular zoocecia found in older parts of the colony are unlike the
nt, knobby spines of M. membranacea. A fifth and pointed spine
ocated on the midanterior margin.

Occurrences: Ventura, Alamitos Channel, Cabrillo Beach, Corona
Mar, Avalon Harbor, 3 mi. NE of Avalon, floating in the Catalina
annel, La Jolla, Little Harbor, Santa Catalina Island.

TABLE 2
CALIFORNIA COLLECTING LOCALITIES
OF HERBARIUM SPECIMENS EXAMINED

ition Herbarium Date
nbers (H) Collecting Localities Collected

{ San Pedro, Los Angeles Co. 1908

{ La Jolla, San Diego Co. June 1946

{ San Pedro, Los Angeles Co. November 1908
{1 San Diego, San Diego Co. July 1924

{1 San Pedro, Los Angeles Co. February 1908
{ San Pedro, Los Angeles Co. October 1908
{ San Diego, San Diego Co. July 1926

{ San Pedro, Los Angeles Co. June 1908

{ San Pedro, Los Angeles Co. February 1907
{ La Jolla, San Diego Co. October 1949
{ La Jolla, San Diego Co. 1949

{ Santa Barbara, Santa Barbara Co. 1935

{ Avalon, Santa Catalina Island, Los Angeles Co. March 1948

{ Santa Barbara, Santa Barbara Co. 1935

{1 Balboa, Orange Co. April 1911

1 San Pedro, Los Angeles Co. 1935

1 Ventura, Ventura Co. June 1946

1 Pacific Beach, San Diego Co. March 1899

{ Cherry Cove, Santa Catalina Island, Los Angeles Co. October 1948
1 San Diego, San Diego Co. June 1946

1 San Diego, San Diego Co. 1924

1 San Pedro, Los Angeles Co. December 1908
1 Santa Monica, Los Angeles Co. November 1912
1 Los Angeles, Los Angeles Co. 1884

1 San Pedro, Los Angeles Co. November 1907
1 La Jolla, San Diego Co. July 1912

1 San Pedro, Los Angeles Co.

1 Avalon, Santa Catalina Island, Los Angeles Co. June 1924

1 San Diego, San Diego Co.

1 Pacific Beach, San Diego Co. ==

1 Long Point, Santa Catalina Island, Los Angeles Co.

1 Pacific Beach, San Diego Co. April 1898

204 Bulletin So. Calif. Academy of Sciences

Membranipora tuberculata (Bosc)

Membranipora tuberculata was found on eleven species of algae.
Gelidium spp. and Cystoseira osmundacea (Menzies) C. A. Agardh
were obviously the most common algal substrates. M. tuberculata
was found on the stipe and blades (near the base) of C. osmundacea
but never on the vesicles.

Although Sargassum sp. was not collected at any of the stations,
several authors (Rogick and Croasdale, 1949; Osburn, 1950; Prenant
and Bobin, 1966) noted that Sargassum sp. is commonly incrusted
with tuberculata.

Description: M. tuberculata forms a heavy white, lace-like incrust-
ment lacking ovicells or avicularia and possessing a pair of distal
tubercles that sometimes fuses to form one broad rim. Cryptocyst has
lateral spinules.

Occurrences: Corona del Mar, Cabrillo Beach, Victoria Cove, La
Jolla*, Santa Monica*, Long Point*, San Clemente, Oceanside.

TABLE 3
BRYOZOANS ASSOCIATED WITH CHLOROPHYTA

Chlorophyta Species Bryozoan Species

ae) ~ = — soy n

= Ss = ~ S = = a 5 for)

Si 3 & Sis = -/S82!/s5 216 8

SIS Se Ss) SSS 1S SING

v S) oS Sere - £2 A ~ Sia) QO =

DY SBS SiS es es ie si as r=}

cs elSS/Z2/SSisSSlegicsies5
Ee iS) = No » mS SS - © tes: foal 1S)
a LY Qa 8 On Qa 2S = =/~-& <
‘=~ 0 A Alte at Sia) yeu] Ss om
= c = S >
CeCe erste ts [es |Z

Chaetomorpha sp.

F
>
a

Cladophora
delicatula

Derbesia
marina

Enteromorpha sp.

ie Sil alee eee

Ulva lobata

*

Ulva sp.

+ single occurrence H = herbarium specimen
* less than 10 occurrences

(numbers refer to collecting localities in Tables 1 and 2)

Bryozoan-Algal Associations 205

Family Hincksinidae Canu and Bassler
Genus Cauloramphus Norman
Cauloramphus spiniferum (Johnston)

This species occurred only on the holdfast of Prionitis lanceolata
Harvey. It has been recorded from rocks (Robertson, 1900; Soule,
1959) and calcareous algae (Soule, 1959) as well.

Description: The zooecia are closely set; frontal area membranous.
Distal spines are erect; the proximal spine is not as stout as the distal
one and is recurved over the opesium. The avicularia are stalked and
resemble other spines.

Occurrence: Victoria Cove.

Family Thalamoporellidae Levinsen
Genus Thalamoporella Hincks
Thalamoporella californica (Levinsen)

T. californica was found on seven species of algae. Several authors
(Robertson, 1908; Osburn, 1950; Soule, 1959) have noted algal
associations for this species.

Description: T. californica usually forms cylindrical, erect colonies,
although some younger colonies form flat incrustations on algae.
Tubes may be formed around small parts of algae. Zoocia elongate
with porous cryptocysts. Opesiules lateral and unequal in size. Tuber-
cles on either side of the operculum. Avicularia nearly as long as the
zooecia. Rounded mandibles directed distally. Ovicells large and
bilobate.

Occurrences: La Jolla+, Victoria Cove, Avalon, Santa Catalina
Island, Corona del Mar.

Family Cellariidae Hincks
Genus Cellaria Ellis and Solander
Cellaria mandibulata Hincks

No previous California records are known for C. mandibulata and
associated substrates. The only record I found of an algal substrate
was from a herbarium specimen (Dawson collection) of Sphacelaria
plumella var. californica, a filamentous brown algae, collected in
1907 from San Pedro.

Description: The avicularium broader than zooecium. Mandible
semi-circular. Zooecia moderately large, narrowing almost to a point
on either end, broadest near midline.

Occurrence: San Pedro*.

206 Bulletin So. Calif. Academy of Sciences

Family Scrupocellariidae Levinsen
Genus Tricellaria Fleming
Tricellaria occidentalis (Trask)

T. occidentalis was found on several species of algae. It occurred
on Egregia laevigata south of Oceanside. On E. laevigata, the
bryozoan incrusted the edges of the holes (bored by urchins) on the
stipe. T. occidentalis was not found on E. laevigata in comparable
areas north of the Oceanside location. The occurrence of T. occidentalis
on other species of algae is sporadic. Robertson (1905) found this
species more abundant north of Point Conception.

Description: The zooarium bushy, with internodes composed of
three zooecia. Scutum well below the middle of the opesium, may be
narrow like a spine or divided into several points. Usually three outer
and three inner spines, long and jointed. Avicularia lateral. Ooecia
large and globular, with numerous small pores.

Occurrences: La Jolla, Avalon Harbor*+, San Diego*, San Pedro’,
Santa Barbara”*.

Genus Scrupocellaria Van Beneden
Scrupocellaria californica Trask

In this study, Scrupocellaria californica was recorded only once, on
Gastroclonium coulteri (Harvey) Kylin.

Description: The zooarium is branched and bushy. The scutum is
small, reduced to a curved spine. The zooecium possesses two outer
spines, sometimes a small third one, plus | to 2 inner spines. A small,
slightly raised frontal avicularium is present on most zooecia imme-
diately proximal to the opesium. Lateral avicularia are mostly giant,
with hooked rostrum. There are 4 to 6, occasionally 9, zooecia in an
internode. The vibracular chamber is small and not visible from the
frontal area; seta are poorly developed.

Occurrence: Victoria Cove, Laguna Beach.

Family Bicellariellidae Levinsen
Genus Bugula Oken
Bugula neritina (Linnaeus)

The only specimens of Bugula neritina in this study were those on a
herbarium specimen sheet at Rutgers University, on the alga Macro-
cystis pyrifera, from San Diego, California. Robertson (1905) records
this species of Bryozoa from rocks, floats, kelp, etc., along the shore.

Bryozoan-Algal Associations 207

Osburn (1950) records that it is constantly present on piles and
wharves and the underside of floats. Ryland (1965) notes it as a serious
fouling organism of shipping in Europe. From my collections it is
obvious that, although B. neritina may occasionally incrust on kelp,
it is more commonly found in southern California on floats and pilings
of wharves.

Description: The colony is reddish brown, dichotomously branched.
The zooecium is large with a single spine on the outer distal corner
of the zooecium. The ovicell is large and globular and attached on the
inner corner of the zooecium near the distal end.

Occurrence: San Diego*.

Suborder Ascophora Levinsen
Family Hippothoidae Levinsen
Genus Hippothoa Lamouroux
Hippothoa hyalina (Linnaeus)

Hippothoa hyalina is a cosmopolitan species and has been recorded
on the Pacific Coast from Alaska to the Galapagos Islands. Of the
species of algae inspected, 53 per cent of the kinds (not numbers) of
species were incrusted with H. hyalina. Previous writers have found
H. hyalina incrusting a wide variety of substrates.

Description: Younger zooecia are hyaline, transversely ribbed,
with narrow, elongate fenestrae which partially separate the zooecia.
Older colonies may lose their hyalinity and become chalky white.
The aperture is rounded, with a narrow sinus proximally; an umbo
may be present proximal to the aperture. Ovicells are raised and
perforated, and dwarf the zooecia.

Occurrences: Victoria Cove, Cabrillo Beach, Corona del Mar,
Avalont, Santa Catalina Channel (3 mi. NE of Avalon), San Diego*,
Balboa*, Los Angeles* (collected 1884), La Jolla*, Long Point,
Santa Catalina*, Santa Barbara”.

Family Schizoporellidae Jullien
Genus Schizoporella Hincks
Schizoporella unicornis (Johnston)

Schizoporella unicornis is not commonly found incrusting on algae;
it was found at only one station. Ryland (1962) found 70 per cent of
the occurrences of this species on rocks and 30 per cent on algae.
Soule and Soule (1964) found this bryozoan commonly incrusting
mollusk shells. Rogick (1949) also found this species most frequently
on rocks and shells but less frequently on algae.

208 Bulletin So. Calif. Academy of Sciences

TABLE 4
BRYOZOANS ASSOCIATED WITH PHAEOPHYTA

Phaeophyta Species Bryozoan Species
2
= =
~ ~ & ~ ~
SS S S — : FP
= = Sis sis s <= |Z
=
SS Ss $| 2 Ss aS) =|] 5 op
~ Qq =f Qs i NY S Se
= oe = Ss — 5S oS SS = LoS sy © =&
u/s = Sis sSs|S 5/8 S18 sli S/23
Onl sl oswleSis S/S 21s S18 8/32/08
SHelhie Siw SISsSeis SIS SIs 42/82/25] 5 2
Si ~ — = 2 x Set || SS ng oc
1S) oS |i i= Ss SRS aS Ses |S SS S| SS iL
Ol ols sliS Ji Ss S18 VISSIS SIS Siz Lie S
@ > VIS s|S 58/8 sles | s SS Sic S
Silo SiS Sy Sells S's Ss] 5 2/5 cs s =
HES IS isos ds = is |S iz

*

Cystoseira
osmundacea

Dictyota
flabellata

Ectocarpus
granulosoides

Egregia
laevigata

Hesperophycus
harveyanus

Macrocystis
pyrifera

Pachydictyon
coriaceum

Pelvetia
fastigiata

Sargassum
agardhianum

Sphacelaria 9H
plumula var.

californica

Taonia
lennebackerae

Zonaria
farlowii

Zonaria
tournefortii

¢ single occurrences H = herbarium specimen
* less than 10 occurrences
(numbers refer to collecting localities in Tables 1 and 2)

Bryozoan-Algal Associations 209

Description: The frontal of S. unicornis is a tremocyst with large
pores. An umbo may or may not be present proximal to the aperture,
which is rounded and bears a rounded sinus on the proximal border.
Avicularia are present, usually one at the side of the aperture with
the mandible directed forward; these may be lacking over large areas
of the colony.

Occurrence: Alamitos Bay.

Family Microporellidae Hincks
Genus Microporella Hincks
Microporella cribosa Osburn

Microporella cribosa did not show an affinity to any specific algae
in this study. Osburn (1950) reported that it was sometimes found on
shells and pebbles. Soule (1961) reported finding it on mollusk shells
in the Gulf of California.

Description: Most distinctive feature of M. cribosa is sieve plate
covering the ascopore. The perforated tremocyst is rough in appear-
ance; umbo situated posterior to the sieve plate; spines long and jointed
at the base. Aperture wider than long and straight on the proximal
border.

Occurrences: La Jollat, Long Point, Catalina Island*.

Family Cheiloporinidae Bassler
Genus Cryptosula Canu and Bassler
Cryptosula pallasiana (Moll)

Cryptosula pallasiana is not a common algal inhabitant along the
southern California coastline. Bruce, Colman and Jones (1963) found
it on shells and stones around the Isle of Man. Rogick and Croasdale
(1949) noted in the Buzzards Bay, Vineyard Sound region that this
species normally formed large colonies and was found on rocks
rather than algae. This could account for its scarcity on algae from
the stations collected. This species was found only on Ulva lobata
Setchell and Gardner, from the Alamitos Bay station.

Description: The colonies small, approximately 0.5 cm in diameter.
Tremocyst frontal possesses large pores; the orifice widened at the
lower half. The peristome thin, elevated and fused with the porous
frontal.

Occurrence: Alamitos Bay.

210 Bulletin So. Calif. Academy of Sciences

Family Celleporidae Busk
Genus Holoporella Waters
Holoporella brunnea (Hincks)

Holoporelia brunnea is not common as an algal inhabiting species.
Among all the herbarium specimens examined and the freshly collected
material there was only a single occurrence of this species. Soule and
Soule (1964) found this species normally incrusting rocks and shells.
Osburn (1952) found it to be nondiscriminating in substrate selection.
I found that H. brunnea does not commonly incrust algae in the
region from Santa Barbara to north of San Diego.

Description: Colony grayish white, zooecia more or less erect.
Frontal granular and has areolar pores; aperture rounded with a
straight proximal border notched in the center. Umbo proximal to
the aperture. Small avicularium between the aperture and base of
the umbo. Peristome with two black, jointed spines. Large interzooecial
subspatulate avicularia are the most distinctive character of the species.

Occurrence: Alamitos Bay.

Order Cyclostomata Busk

Family Crisiidae Johnston

Genus Filicrisia d’Orbigny
Filicrisia franciscana (Robertson)

Filicrisia franciscana was noted on several occasions. On Gastro-
clonium coulteri (Harvey) Kylin, it was found growing on the holdfast.
Robertson (1910), noted that specimens were found on rocks at
Coronado, California. Osburn (1953) does not make any special
reference as to the substrate on which his specimens were found.

F. franciscana was also found on Gelidium robustum (Gardner)
Hollenberg and Abbott. In Victoria Cove this species was found in
tide pools in the littoral zone growing attached to the green filamentous
algae of Entermorpha sp. and Chaetomorpha sp.

Description: Zooarium bushy; zooecia tubular. Spinous processes
and internode joints black. Ovicell adnate to internode for its entire
length; ooeciostome forward on frontal border with tube curved
backward.

Occurrence: Victoria Cove.

Genus Crisia Lamouroux
Crisia occidentalis Trask

Crisia occidentalis was recorded from a single fall collection in a
littoral tide pool in Victoria Cove. The algal substrate was Chaeto-
morpha sp., a green filamentous algae.

Bryozoan-Algal Associations

TABLE 5
BRYOZOANS ASSOCIATED WITH RHODOPHYTA

Rhodophyta Species

Bossiella
orbigniana

Bryozoan Species

franciscana

Spiniferum
californica

S

23}:

s2/ss]3
3 as asics ||
e838 == £ &
SElSglse} s
SS lS ES 2] 6
RSfer;es sy] s
Se '~ =| 8
Ax fo S|] o cs] &
es 7 eS 7 les =

Cauloramphus .
Disporella

Herbarium
Filicrisia

cribosa

—

Thalamoporella
Incrusted

californica
occidentalis

Scrupocellaria
californica

Tricellaria
No Bryozoans

tL

Botryoglossum
farlowianum

Callophyllis
megalocarpus

Ceramium
eatonium

Corallina
chilensis
Corallina
gracilis
Corallina
vancouverensis
Cryptopleura
crispa
Farlowia
compressa
Gastroclonium
coulteri

Gelidium
cartilagum
robustum

Gelidium
coulteri

Gelidium
crinale var.
luxurians

Gelidium

pulchrum

Gelidium
__ purpurascens

* less than 10 occurrences

=

=

_|

No)
ae

eers

H = herbarium specimen
(numbers refer to collecting localities in Tables 1 and 2)

ZW

BRYOZOANS ASSOCIATED WITH RHODOPHYTA

Bulletin So. Calif. Academy of Sciences

TABLE 5 (continued)

Rhodophyta Species

+

Bryozoan Species

sis S
ke) 8 = o|o
= 8 SR Sil so = v eS ||
SlISeleel Sle ISSIS8is_ ES ss] a3) Se
= ~ St td = 5 88
SISIESIZSElSSISS/SEISSISSISEISEI ES 83
@ het SSS] S| BB lSs LS es AS|LA& FEO] Ss 2
Sl al[SE/SSIEE/SSISE/SS Ss/§s/=e]e
o|/olji<—=]/ SS] es iS} o o/OS}/sSStiSSlscolmo
=/elrss| Ss] ee] ca Es ES|SE]SSlSSl eo S
Solollagc]/2c/Sn/S82/8 HSS & BOS Os © o=
OPES WS) eS es es es ab 3 BR |Z
Gigartina 2H
armata x |
Gigartina 13H 19H
armata Var.
echinata
Gigartina x 5
canaliculata
JL
Gigartina x 11
leptorhynchos
Gigartina 13H 13H
multidichotoma
Gigartina 15H
serrata 20H 21H
21 ll
Gigartina xX 22H
Spinosa ilies [Re 5
Gracilaria 23H 23H
textorii var.
cunninghamii ie
Gracilariopsis 2H
andersonii 25H
Grateloupia 2H
filacina
Heterosiphonia 2H
erecta
Hypnea

valentiae

H = herbarium

speciman

(numbers refer to collecting localities in Tables | and 2)

BRYOZOANS ASSOCIATED WITH RHODOPHYTA

Bryozoan-Algal Associations

TABLE 5 (continued)

213

Chlorophyta Species

Bryozoan Species

perforata

Prionitis
lanceolata

= (as 7
S 3
a ny) 8 in} = a n
=e] S| =], |S2/8slS [SS] 88).31 ee
a: . i<j = = S. Ss S$
aS g > |Ss/ 88 Ss S/o SS
ol BES/SEls8|Ss/ee/Es| Pel SE SEE SE
SIES SIRS iS e/SS) 52/5 5] 89) Sei esiSzlee
S| SISS| SSIS §] L383 S/S5] SS] SSI SS Sis o
(PIS ealSslS &1 SAS S|] Ss] SS] VSS] Ssel Ss © <
Slolle g]/2 9/8/85 /8 S/S =] 2s Ss ©] SSF 9]! oS
Of (SQ [es PS ts PS |S lea WS We ez
= +
Laurencia x 26H 26H 26H 26H
gardneri
Laurencia xX 5,11
pacifica 27H
Laurencia 32H
spectabilis
ee Sue
Laurencia 2H
snyderac
Liagora 28H
california 7 || t
Lithithrix x g*
aspergillum
Pikea 30H
californica
Plocamium xX S)
pacificum
; al
Plocamium x 5
violaceum
Polyspes 31H 31H 31H
bushiae
eels
Porphyra Xx 5
naiadum
Porphyra x | 5t
—

Prionitis
linearis

Prerocladia

caloglossoides

Rhodoglossum

affine

X

* less than 10 occurrences
+ single occurrence
(numbers refer to collecting localities in Tables 1 and 2)

ett

herbarium specimen

214 Bulletin So. Calif. Academy of Sciences

Description: Colonies dense and bushy with 7 to 10 zooecia per
internode near tips and 5 zooecia per internode close to base. Zooecia
connate along the entire length. Tips flexed forward with a sharp point
on dorsal tip of many of the tubes. Ovicells in axis of internode;
ooeciostome aperture circular, located on a short tube opening below
apex of ovicells. Joints white to yellow.

Occurrence: Victoria Cove.

Family Lichenoporidae Smitt
Genus Disporella Gray
Disporella californica (@Orbigny)

From herbarium specimens of red algae I found that Disporella
californica was recorded from two localities. Soule (1963) found this
species incrusting on marine algae, shells and other bryozoans.

Description: Radii uniserial, tubules connate to tips with rays-
extending beyond tips of tubules. Pores of central cancelli larger than
tubule apertures; pinhead spicules abundant. A few colonies as large
as 5 mm in width.

Occurrence: San Diego* and La Jolla*.

DISCUSSION

Several aspects of bryozoan substrate selection were observed. The
brown alga Pelvetia fastigiata was commonly found in the upper
littoral fringe. Although this alga was collected in large quantities,
no bryozoans were found. Certain other algae were found devoid of
bryozoans, but these were either collected in limited quantity or their
size was such that it was unlikely that the plant could support an
incrusting colony. Both Enteromorpha sp. and Chaetomorpha sp.,
are small filamentous green algae, the algae formed dense green mats
and the bryozoans were only attached by a few basal zooids or by
rhizoids, the colonies being otherwise suspended in the water (Table 3).

Other authors have noted in the literature the general lack of fauna
incrusting Pelvetia sp. (Colman, 1940; Ryland, 1958, 1962). Colman’s
observations were based on transects along the British coast and
Ryland’s, on laboratory experiments.

Hesperophycus harveyanus, another brown alga found in the upper
littoral fringe, is also generally devoid of bryozoans. However, in
Avalon Harbor, this alga was incrusted with bryozoans (Table 4).

Since the collections were concentrated in areas with tidepools,

Bryozoan-Algal Associations 215

an important factor in the incrustation of bryozoans is the secretion
of tannins by Phaeophyta (Sieberth and Conover, 1965; Conover and
Sieberth, 1965). These antibacterial tannins, which are produced by
the tips of the algae, precipitate protein and keep the tips free of
sessile organisms. Hydroids have been shown to be sensitive to
solutions of 1:1,000 (Sieberth and Conover, 1965).

Both Balanus balanoides and Mytilus edulis were found to be
suppressed in tidepools dominated by the brown alga Ralfia verrucosa
but not suppressed in tide pools dominated by the red alga Hilde-
brandia prototypus. The waters from the pools of Ralfia verrucosa
were found to be toxic to trochophores, veligers and nereid worms.

Although experimental evidence is lacking, a reasonable explana-
tion for the lack of organisms incrusting Pelvetia fastigiata, and some
Hesperophycus harveyanus, is the presence of tannins. Both species
of algae were collected in tide pools. The tannin concentration is
diluted during high tide. The length of exposure time during low tide
would also reduce the number of successfully incrusting organisms.

F. E. Round (pers. comm.) has suggested that bryozoan incrustment
may be inhibited by phenols produced by some red algae. Prionitis
sp. is found in the lower littoral tidepools and although was occasionally
incrusted by bryozoa, the incrusting colonies were sparse and small
(Table 5).

Both in the examination of young entire plants of Macrocystis
pyrifera and Egregia laevigata and the tips of older plants, no bryozoans
or other incrusting animals were found. Incrusting occurred only on
older plants (Table 4). Another factor preventing incrustation is the
physical extension of the growing tips. This action would tear or
dislodge incipient colonies.

Another aspect of bryozoan settlement observed is that a given
species of bryozoan incrusts on a specific alga in one locality but does
not in another locality with both the bryozoan and alga present in both
localities. Tricellaria occidentalis incrusted in holes in the stipes of
Egregia laevigata, collected from the region of La Jolla, the southern-
most station; however, it was not found incrusting in holes on stipes
or any other place on Egregia laevigata at any other locality studied.
It appears that the area for incrustation is highly specific and limited
geographically.

No ctenostomes were found incrusting intertidally on algae south
of Point Conception. In collections examined from Pacific Grove
and Carmel, ctenostomes were found incrusting some intertidal algae,
i.e., Corallina sp., Grateloupia californica and Prionitis lanceolata.
Possibly the combination of warm shallow water and exposure during

216 Bulletin So. Calif. Academy of Sciences

low tide is not conducive to the settlhement and development of
ctenostomes in the intertidal areas in the southern part of the state.

Several aspects of algal zonation and bryozoan distribution were
observed. The intertidal zonation nomenclature employed follows
that used by Womersley and Edmonds (1952): supra littoral, upper
littora, mid littoral, lower littoral and sub littoral zones. Doty (1946),
Dawson (1966) and Round (1965) were followed for vertical algal
distribution.

Pelvetia fastigiata and Hesperophycus harveyanus are two repre-
sentatives of the upper littoral zone that were collected. As has been
previously discussed, the variety and number of bryozoans collected
on these algae were scanty. Progressing down a vertical transect,
the number of colonies and species increase and reach the maximum
in species numbers in the lower littoral and upper sublittoral fringes.
This is an area of transition from the Chlorophyta and the brownish
red Rhodophyta to the bright red Rhodophyta. This area is rich in
the number of species of algae.

The upper sublittoral below the fringe is characterized by the algae
Cystoseira osmundacea and Macrocystis pyrifera. Although only four
species of Bryozoa (three from collecting stations and one from
herbarium sheets) were found on these algae, the algae which were
incrusted were generally heavily incrusted.

CONCLUSION

There appears to be a definite preference for an algal substrate by
some Bryozoa. This preference is delimited by: (1) the location of algae
in the littoral region; (2) availability of various substrata; (3) produc-
tion of anti-fouling substances by brown and possibly red algae.

Seventeen species of bryozoans were identified incrusting on 6
species of Chlorophyta, 13 species of Phaeophyta and 43 species of
Rhodophyta. Collections were made at 15 southern California stations;
herbarium specimens of algae from 32 southern California stations
were examined.

LITERATURE CITED

Bock, K. J., 1950. Uber die Bryozoen und Kamptozoen der Kieler Bucht. Kieler
Meeresforschungen, 7: 161-166.

1954. Einige zahler zur bewuchsdichte von epizoen auf Laminarien aus
6stlichen Kieler Bucht. Veroff des Instituts Meeresforschung in Bremer-
haven, 3: 42-45.

Bruce, J. R., J.S. COLMAN AND N. S. JONES, 1963. Bryozoa in Marine fauna of the
Isle of Man, pp. 225-238. Liverpool University Press.

Bryozoan-Algal Associations 217

Busk, G., 1852. Catalogue of the Marine Polyzoa in the British Museum. Part 1,
Cheilostomata. pp. 1-54, pls. 1-68.

1854. Catalogue of the Marine Polyzoa in the British Museum. Part 2.
Cheilostomata. pp. 55-120, pls. 69-124.

Cotman, J. S., 1940. On the faunas inhabiting intertidal seaweeds. J. Mar. Biol.
Assoc. U.K., 24: 129-183.

CONOVER, J. T. AND J. MCN. SIEBERTH, 1965. Effect of tannins excreted from
Phaeophyta on planktonic animal survival in tide pools. Proc. Fifth Int.
Seaweed Symposium, Halifax, Canada, pp. 99-100.

Crisp, D. J. AND J. S. RYLAND, 1960. Influence of filming and of surface texture
on the settlement of marine organisms. Nature, 185: 119.

Crisp, D. J. AND G. B. WILLIAMS, 1960. Effect of extracts from fucoids in pro-
moting settlement of epiphytic Polyzoa. Nature, 188: 1206-1207.

Darwin, C. D., 1845. The Voyage of the Beagle. Leonard Engle, ed. Natural
History Library edit., Doubleday, New York, 1962. 524 p.

Dawson, E. Y., 1966. Marine Botany: an Introduction. Holt, Rinehart and
Winston, New York. 371 p.

Doty, M. S., 1946. Critical tide factors that are correlated with the vertical
distribution of marine algae and other organisms along the Pacific Coast.
Ecology, 27: 315-328.

Hincks, T., 1880. A history of the British marine Polyzoa. 1: 1-601; 2: pls. 1-83.
John van Voorst, London.

JouiET, L., 1887. Contributions a histoire naturelle des Bryozoaires des cotes
de France. Archives Zoologie Experimentale et Génerale, 6: 193-304.

O’DonoGuuE, C. H., 1926. Observations on the early development of Membrani-
pora villosa. Contrib. Canad. Biol. Fish., N.S., 3: 249-263.

OsBurRN, R. C., 1950. Bryozoa of the Pacific coast of America. Part 1, Cheilosto-
mata-Anasca. Allan Hancock Found. Publ. 14: 1-269.

1952. Bryozoa of the Pacific coast of America. Part 2, Cheilostomata-
Ascophora. Allan Hancock Found. Publ., 14: 270-611.

1953. Bryozoa of the Pacific coast of America. Part 3, Cyclostomata,
Ctenostomata, Entoprocta and Addenda. Allan Hancock Found. Publ.,
14: 612-841.

PRENANT, M.. 1927. Notes ethologiques sur la faune marine sessile des environs
de Roscoff, I]. Travaux de la Station Biologique de Roscoff, 6: \-58.

1932. Etude de binomie intercotidiale la Baie et la Point de Quiberon.
Travaux de la Station de Roscoff, 10: 37-103.

PRENANT, M. AND G. BoBIN, 1966. Bryozoaires, Part 2: Chilostomes Anasca.
Faune de France, 68: 1-647.

PRENANT, M. AND G. TEISSIER, 1924. Notes ethologiques sur la faune marine
sessile des environs de Roscoff. Travaux de la Station Biologique de Roscoff,
2: 1-49.

218 Bulletin So. Calif. Academy of Sciences
ROBERTSON, A., 1900. Papers from the Harriman Alaska Expedition. VI. The
Bryozoa. Proc. Washington Acad. Sci., 2: 315-340.

1905. Non-incrusting chil6stomatous Bryozoa of the west coast of North
America. Univ. California Publ. Zool., 2: 235-322.

1908. The incrusting chilostomatous Bryozoa of the west coast of North
America. Univ. California Publ. Zool., 4: 253-344.

1910. The cyclostomatous Bryozoa of the west coast of North America.
Univ. California Publ. Zool., 6: 225-284.

Rocick, M. D. AND H. CROASDALE, 1949. Studies on marine Bryozoa, III. Woods
Hole Region Bryozoa associated with algae. Biol. Bull., 96: 32-69.

Rounb, F. E., 1965. The Biology of the Algae. Edward Arnold, Ltd., 269 p.
London.

RYLAND, J. S., 1958. The settlement of Polyzoa larvae on algae. Proc. XVth Int.
Congr. Zool., pp. 236-239.

1959. Experiments on the selection of algal substrates by Polyzoa larvae.
J. Exp. Biol., 36: 613-631.

1962. The association between Polyzoa and algal substrata. J. Anim.
Ecol., 31: 331-338.

1965. Polyzoa, in Catalogue of main marine fouling organisms. Organ.
Econ. Coop. Develop., 2: 1-83.

SIEBERTH, J. MCN. AND J. T. CONOVER, 1965. Sargassum tannin, an antibiotic
which retards fouling. Nature, 208: 52-53.

SouLE, J. D., 1959. Results of the Puritan-American Museum of Natural History
Expedition to western Mexico. 6. Anascan Cheilostomata (Bryozoa) of the
Gulf of California. Amer. Mus. Novit., no. 1969, 54 p.

1961. Results of the Puritan-American Museum of Natural History
Expedition to western Mexico. 13. Ascophoran Cheilostomata (Bryozoa)
of the Gulf of California. Amer. Mus. Novit., no. 2053, 66 p.

1963. Results of the Puritan-American Museum of Natural History
Expedition to western Mexico. 18. Cyclostomata, Ctenostomata (Ectoprocta)
and Entoprocta of the Gulf of California. Amer. Mus. Novit., no. 2144, 34 p.

SouLE, D. F. anp J. D. SouLE, 1964. The Ectoprocta (Bryozoa) of Scammon’s
Lagoon, Baja California, Mexico. Amer. Mus. Novit., no. 2199, 56 p.

WoMERSLEY, H. B. S. AND S. J. EDwarps, 1952. Marine coastal zonation in

southern Australia in relation to a general scheme of classification. J. Ecol.,
40: 84-90.

Accepted for publication July 24, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 219-224, 1969

THE IDENTITY OF THE FROG,
PSEUDOHYLA NIGROGRISEA OF ECUADOR

JOHN D. LYNcu!
Museum of Natural History
University of Kansas
- Lawrence, 66044

ABSTRACT: A small frog, Pseuwdohyla nigrogrisea, previously
considered a treefrog (Hylidae) is herein shown to be a species
of the genus Eleutherodactylus (Leptodactylidae). The species
is redescribed on the basis of fresh specimens and distribu-
tional and ecological notes on the species presented. The
species is herein figured for the first time.

INTRODUCTION

Andersson (1945) named a new genus and species of hylid frogs
(Pseudohyla nigrogrisea) on the basis of one adult and five juvenile
specimens from Banos, East Ecuador (Province Tungurahua). Little
comment has been made concerning the systematic status of the genus,
although Goin (1961) assigned the genus to the synonymy of Hyla.
The late Doris Cochran showed me photographs of the holotype and
queried me about the possibility that Pseudohyla was a leptodactylid.
I borrowed the type-series of this species for comparison with several
species of Eleutherodactylus which I collected in the Pastaza valley
in July 1968.

Andersson distinguished Pseudohyla from Hyla on the basis of the
lack of webbing and prevomerine teeth. He recorded the presence of
claw-shaped terminal phalanges and intercalated cartilages. The
holotype of P. nigrogrisea is bleached but otherwise in relatively good
condition. The pectoral girdle and sacrum have been exposed by dis-
section by persons previously examining the specimen. Contrary to
Andersson’s report, the digits lack intercalated cartilages and have
T-shaped terminal phalanges. Each digital pad bears a circumferential
groove. The sacral diapophyses are round, not dilated. The color
pattern is bleached in the holotype, but the juveniles retain more
pigment. The faded pattern of the adult is in complete agreement with
the more intense pattern of the juveniles.

Pseudohyla nigrogrisea Andersson is not a hylid but a leptodactylid of
the genus Eleutherodactylus. | am aware of no earlier names for the
species and do not know of any synonyms proposed since 1945. I
collected specimens of this species in July 1968 at Abitagua, the area

'Present address: Department of Zoology, University of Nebraska, Lincoln, 68508.

AN)

220 Bulletin So. Calif. Academy of Sciences

Figure 1. Dorsal view of Eleutherodactylus nigrogriseus (KU 120158, snout-vent
length 28.5 mm).

Frog from Ecuador DDS)

near the border of Tungurahua and Pastaza Provinces, approximately
6 kilometers (airline) NE of Mera, Ecuador. A redescription of Eleu-
therodactylus nigrogriseus (Andersson), new combination, is given
below. Following the system of diagnosis used in my earlier papers
on Ecuadorian Eleutherodactylus (Lynch, 1968, 1969), E. nigrogri-
seus 1s diagnosed as follows:

DESCRIPTION

Diagnosis. — skin of dorsum shagreened with scattered tubercles,
that of venter areolate; tympanum small, one-third diameter of eye;
snout subacuminate in dorsal view, somewhat truncate in lateral pro-
file; interorbital distance about equal to width of eyelid; no fronto-
parietal ridges; prevomerine teeth present, 4-6 teeth situated on each
dentigerous process, dentigerous processes lie median and posterior
to choanae, relatively small, triangular in outline; males lacking vocal
slits; first finger slightly shorter than second, all digits except inner-
most, bear round, expanded pads with terminal circumferential grooves;
fingers bear poorly developed lateral fringes; outer edge of forearm
lacking row of tubercles, antebrachial tubercle present; tarsus lacking
tubercles and folds, heel with one large and several small conical tuber-
cles; inner metatarsal tubercle large, oval, outer metatarsal tubercle
small, one-fourth size of inner metatarsal tubercle, conical, thenar
surface bearing numerous minute supernumerary tubercles, fewer
than six moderate-sized supernumerary tubercles; toes bearing prom1-
nent lateral fringes, lacking webbing, digital pads large, rounded;
dorsum brown mottled with dark brown and black; venter mottled
with brown; posterior flanks, groin, anterior and posterior surfaces
of thighs, and concealed surfaces of shank dark brown to black with
large white spots (yellow in life); limbs barred black on brown; adults
moderate-sized, males 19.9-23.6, females 23.8-28.5 mm SVL.

Description of E. nigrogriseus based on 9 fresh specimens. — Head
slightly wider than body; head as wide as long, or slightly wider than
long; head width of males 35.2 to 39.2 (mean 36.8), of females 38.0
to 41.5 (mean 39.6) per cent SVL (snout-vent length); snout subacu-
minate in dorsal view, somewhat truncate in lateral profile; canthus
rostralis well defined, prominently curved; loreal region concave,
sloping abruptly to lip, lips not flared; nostrils lateral, near tip of snout;
length of eye greater than distance between eye and nostril; width of
eyelid slightly greater than interorbital distance, 88.4 to 123.3 (mean
107.0) per cent interorbital distance, slightly higher values obtain in
males than in females; tympanum round, its horizontal diameter 28.2

22) Bulletin So. Calif. Academy of Sciences

to 35.5 (mean 32.3) per cent that of eye; tympanum is proportionately
smaller in juveniles; supratympanic fold present, poorly defined,
short; tongue large, oval, posterior one-third free, not notched pos-
teriorly; choanae relatively small, round, completely visible when roof
of mouth is viewed from directly below; dentigerous processes of pre-
vomers present, lying median and posterior to choanae, separated
medially, triangular in outline, each process bearing 4-6 teeth; male
lacking vocal sac and slits.

Skin of dorsum shagreened, bearing scattered tubercles or not,
lacking ridges, that of venter areolate; discoidal fold prominent pos-
teriorly, not extending onto thighs; anal opening not enclosed in sheath,
surrounded by tubercles; shank 49.9 to 55.8 (mean 53.6) per cent SVL;
forearm lacking tubercles along outer edge; small, but prominent ante-
brachial tubercle present on underside of forearm; three palmar tuber-
cles, inner largest; subarticular tubercles moderately large, round,
simple; thenar surface bearing numerous supernumerary tubercles
which do not extend onto digits; digital tips expanded, pads wider than
long, largest on outer fingers, not emarginate, bearing circumferential
groove; second finger slightly longer than first; fingers bear lateral
fringes.

Tarsus lacking tubercles and folds; one large, conical tubercle on
the upper edge of the heel, several smaller tubercles scattered on heel;
inner metatarsal tubercle large, oval, not compressed, three to four
times as large as conical outer metatarsal tubercle; plantar surface
bearing three to five flattened supernumerary tubercles; subarticular
tubercles round, simple; toes bearing lateral fringes which join to form
basal web; toe pads large, slightly wider than long, bearing circum-
ferential grooves.

Dorsum and limbs medium brown; dorsum flecked and spotted with
black; limbs barred with dark brown or black, dark bands slightly
narrower than interspaces; no discrete canthal or supratympanic stripes;
lips barred; flanks pale creamy brown barred with black, black bars
prominently slanted anteriorly, coalescing ventrally to form dark
brown to black field which extends across groin and anterior surface
of thighs; posterior surface of thigh and undersurfaces of limbs dark
brown; groin, posteroventral areas of flanks, anterior surfaces of
thighs, posterior surfaces of thighs spotted with white or cream; venter
dusky gray or pale cream, usually mottled with brown; throat more
heavily mottled with brown; edge of lower lip barred with dark
brown; dorsal surface of thighs barred with black, interspaces brown
anteriorly, white posteriorly, giving impression of large white or cream
spots on dorsal surfaces of thighs.

Frog from Ecuador 223

In life, the dorsum and limbs were olive green or yellow brown to
nearly black. The markings on the dorsum and limbs were black and
there were a few small yellow spots on the shank. The lower flanks were
yellow to creamy brown. The spots on the groins and thighs were
bright yellow on a field of black. The venter was tan to dark gray with
small white to cream spots. The iris was bright red in adults. The yellow
flank spots were discrete in adults whereas juveniles lack spots and
have yellow flanks.

Specimens examined: ECUADOR, Napo: S slope Cordillera del
Dué, 1150m, KU 123501. Pastaza: Abitagua, 1300 m, KU 120157-63,
KU 120164(2). Tungurahua: Banos, RMNH 1905 (1 adult and 5
juveniles; syntypes).

Remarks. — My observations on this species in life are confined
to observations made during two hours at night that I spent climbing
up and down a steep walled rocky ravine along the slopes of the valley
of the Rio Pastaza in Ecuador. William E. Duellman collected one
additional specimen of this species above the Rio Coca on the south
slope of the Cordillera del Dué in Napo Province, Ecuador.

The specimens seen in life did not call. No mating behavior or egg
clutches were found. The adult frogs were found sitting on small rock
ledges on the edges of the ravine. The juveniles were found on low
bushes (less than 50 cm above the ground) at the edge of the ravine.
The specimen collected by Duellman was sitting on a bush at night at
the edge of a rocky ravine.

Comparisons. —1 can offer little in the way of meaningful com-
parisons with other species at this time. Eleutherodactylus nigrogriseus
is probably closely related to E. bufonius, a sympatrant which is con-
siderably larger and has been confused with E. latidiscus. 1 am familiar
with many species of the genus in Amazonian Ecuador but as yet have
associated names with comparatively few of these. Eleutherodactylus
nigrogriseus bears no more resemblence to the frogs of the family
Hylidae than do most species of arboreal Eleutherodactylus.

ACKNOWLEDGMENTS

Field work in Ecuador was supported by a Watkins Museum of Natural History
Grant, University of Kansas. Through the courtesy of Greta Vestergren, Royal
Museum of Natural History, Stockholm, Sweden (RMNH), I was able to study
the type-series of Pseudohyla nigrogrisea. 1 was aided in my field work by Robert
Henderson and Gerald R. Smith. Specimens in the Museum of Natural History,
University of Kansas are identified with the prefix KU.

LITERATURE CITED

ANDERSSON, L. G., 1945. Batrachians from east Ecuador collected 1937, 1938 by
Wm. Clark-Macintyre and Rolf Blomberg. Arkiv for Zoologi, 37A (2):1-88.

224 Bulletin So. Calif. Academy of Sciences
Goin, C. J., 1961. Synopsis of the genera of hylid frogs. Ann. Carnegie Mus.,
36: 5-18.

Lyncu, J. D., 1968. Two new frogs of the genus Eleutherodactylus from eastern
Ecuador (Amphibia: Leptodactylidae). J. Herpetol., 2: 129-35.

1969. Identity of two Andean Eleutherodactylus with the description of
a new species (Amphibia: Leptodactylidae). J. Herpetol. 3: in press.

Accepted for publication September 17, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 225-228, 1969

A NEW SPECIES OF HEXIDIONIS
(ACARINA, TROMBICULIDAE)
FROM KANGAROO RATS (GENUS DIPODOM YS)
OF WESTERN NORTH AMERICA

RICHARD B. LOOMIS AND JAMES L. LUCAS
Department of Biology
California State College
Long Beach

ABSTRACT: Hexidionis harveyi, n. sp. is described from larvae
taken off the kangaroo rats Dipodomys m. merriami from
15.3 km SW Agua Prieta, Sonora, Mexico and Dipodomys s.
spectabilis from 4.8 km S Animas, Hidalgo Co., New Mexico.
It is similar to Hexidionis doremi (Brennan and Beck).

INTRODUCTION

Studies of chiggers taken from rodents of Sonora, Mexico and adjacent
states have revealed a new species of chigger which belongs to the
genus Hexidionis Vercammen-Grandjean and Loomis (1967). It
closely resembles Hexidionis doremi (Brennan and Beck), a chigger
known from southern Utah, Arizona, California and Sonora, Mexico.

The studies upon which this paper is based were supported by a
research grant AI-3407 from the National Institute of Allergy and
Infectious Diseases.

In the description below all measurements are in microns, and the
terminology follows that of Wharton, et. al. (1951).

It is our pleasure to name this new species after Dean E. Harvey of
California State College, Long Beach, who collected the type host as
well as numerous other vertebrates from which chiggers have been
recovered.

Hexidionis harveyi, new species
Figure |

Types. — Larvae, holotype and 13 paratopotypes from 15.3 km
southwest of Agua Prieta, Sonora, Mexico, elevation 1260 m, from
two Dipodomys merriami merriami Mearns (Merriam’s kangaroo rat)
taken 9 July 1965 by Dean E. Harvey, original numbers DEH650709-3
(holotype and 10 paratopotypes) and DEH650709-4 (3 paratopo-
types). The holotype and one paratopotype will be deposited in the

Pj)

226 Bulletin So. Calif. Academy of Sciences

Figure 1. Larva of Hexidionis harveyi, n. sp. A. Scutum and eyes. B. Gnatho-
soma, dorsal aspect. C. Palpotibia and tarsus, ventral aspect. D. Body setae (left
to right): posterior dorsal, first dorsal and humeral. E. Leg I, showing specialized
setae with measurements in microns. F. Leg II, as above. G. Leg III, as above.

New Species of Chigger 227,

Rocky Mountain Laboratory, Hamilton, Montana, and other parato-
potypes, now at California State College, Long Beach, will be distrib-
uted to appropriate institutions.

Diagnosis. — Similar to Hexidionis doremi in having three genualae
I with the distance between the dorsal genualae less than between distal
dorsal and lateral genualae; legs elongate with several bands in tarsi;
sensilla branched; differing from H. doremi in having lateropalpotibial
seta nude and with PL setae off scutum, and different dorsal body
setal formula.

Description of Holotype. — Body: Partly engorged, 684 by 446,
color in life orange; eyes 2/2, approximately equal in size, ocular plate
indistinct.

Dorsal setal formula 2 (humerals)— 2— 6— 6— 6, plus 8, total 30.
Measurements: humeral seta 38; seta of first posthumeral row 34.

Ventral setal formula 2—2, plus 18 preanal and 8 postanals, total
30. Measurements: first sternal seta 38, posterior ventral seta 29.

Scutum: Shape subpentagonal, with rounded posterior margins and
numerous puncta. Sensilla with approximately 20 branches on distal
half. PL seta separated by 12 microns (3 to 7 striae) from scutal plate
(Figure 1A).

Scutal measurements of holotype and (in parentheses) the mean and
extremes of 14 types unless otherwise noted: AW 76 (76, 72-82),
PW 105 (98, 87-109), SB 31 (31, 28-35), ASB 29 (29, 27-32), PSB 22
C272») Abas) (2825-52), AM 35)(G5; 33-36, 10) PAL 32 (29:
25-35), PL 49 (51, 48-54), S 82 (80, 76-84, 8).

Gnathosoma: Cheliceral blade with dorsal tricuspid cap and promi-
nent ventral tooth; cheliceral base and capitular sternum punctate.
Galeala branched. Palpal setal formula B/B/BNB; palpotibial claw
trifurcate.

Legs (specialized setae as follows): Leg I with 3 genualae, micro-
genuala; 2 tibialae, microtibiala; tarsala (18), microtarsala, subter-
minala, a branched seta adjacent to subterminala, and pretarsala. Leg II
with genuala, 2 tibialae, tarsala (17), microtarsala, and pretarsala.
Leg III with genuala, tibiala, and 2 mastitarsalae with several basal
barbs. Each leg terminating in 2 claws bearing 4 to 6 onychotriches
and a clawlike empodium with one onychotrich (Figure 1 E-G).

Leg measurements, holotype, and (in parentheses) mean and
extremes of 14 types: Leg I 345 (348, 330-388), Leg II 324 (313, 283-
353), Leg II 347 (356, 341-385), Total legs 1016 (1030, 965-1111).

Remarks. — Although Hexidionis harveyi has PL setae off the
scutum it closely resembles and belongs to the doremi group which
includes H. doremi, H. breviseta (Loomis and Crossley), and H. poly-

228 Bulletin So. Calif. Academy of Sciences

technica (Hoffmann). See Lucas and Loomis (1968) for a key to the
species of Hexidionis.

The type host kangaroo rats were captured at an abandoned rock
quarry where the extremely rocky substrate supported a few Acacia sp.
and Ocotillo (Fouquieria splendens). Larvae of H. harveyi were not
found on Dipodomys merriami trapped in an adjacent sandy wash
covered by creosote bush association. The known localities are in the
desert-grassland of the Upper Sonoran Life Zone (Lowe, 1964).

Specimens examined. — Total 20 larvae: MEXICO, Sonora, (14,
type series); 9.7 km S Agua Prieta, Sylvilagus audubonii, 9 July 1965
(1). USA, NEW MEXICO, Hidalgo Co., 4.8km S Animas, Dipodomys
s. spectabilis, 30 Aug. 1968 (5).

LITERATURE CITED
Lowe, C. H. 1964. The vertebrates of Arizona. Univ. Arizona Press, 259 p.

Lucas, J. L. AND R. B. Loomis. 1968. The genus Hexidionis (Acarina, Trombi--
culidae) with description of a new species from western Mexico. Bull. So.
Calif. Acad. Sci. 67: 233-239.

VERCAMMEN-GRANDJEAN, P. H. AND R. B. Loomis. 1967. Note on Hexidionis n. g.
and Pentidionis n. sg. Acarologia 9: 139-140.

WHARTON, G. W., D. W. JENKINS, J. M. BRENNAN, H. S. FULLER, G. M. KOHLs,
AND C. B. PuiLip. 1951. The terminology and classification of trombiculid
mites (Acarina, Trombiculidae). J. Parasitol. 37: 13-31.

Accepted for publication September 18, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 229-240, 1969

SERPULIDAE (ANNELIDA: POLYCHAETA)
FROM OAHU, HAWAII

DALE STRAUGHAN*
Allan Hancock Foundation
University of Southern California
Los Angeles, California 90007.

ABSTRACT: Twelve species fram seven genera are recorded
from various habitats on the island of Oahu in the Hawaiian
group. Nine have a cosmopolitan tropical distribution, two
have an eastern Pacific distribution, and only one has an Indo-
Pacific distribution.

INTRODUCTION

Oahu (Fig. 1) is the second largest island in the chain of Hawaiian
Islands which stretch from 178°W, 28’N to 154°W, 18’N. These
islands are located near the center of the tropical North Pacific Ocean.
California, the nearest continental area is more than 2,000 miles
away. Oahu (157°, 68’W 21°, 26’N), like the other large islands, has
intertidal areas which are volcanic in origin.

Hartman (1966) assembled all published records of polychaetous
annelids named from the Hawaiian Islands with the addition of some
unpublished littoral records. Prior to this date serpulids were men-
tioned by Edmondson and Ingram (1939), Treadwell (1943) and
Edmondson (1944).

Hartman (1966) noted the diversity of substrate in the islands.
Collections were made from as many localities as possible (Fig. 1)
around the island of Oahu in an attempt to cover all types of substrates
and habitats (Table 1). Collections housed at the Bernice P. Bishop
Museum, Honolulu, were also examined. Only the diagnostic features
are listed for most species and reference made to more complete
descriptions.

As far as possible, representatives of all species collected during
1968 were placed at the Hawaii Institute of Marine Biology and
University of Hawaii. The balance of the 1968 collections are housed
at the Allan Hancock Foundation, U.S.C. Los Angeles.

Spirorbinae from Hawaii are not included here. They are being
studied jointly by the author and Dr. Julie Bailey of the University of
Hawaii.

*Contribution No 342 from Hawaii Institute of Marine Biology, Coconut Is.,
Hawaii.

229

230

Figure 1.

of Oahu.

Ps (I)

3@)

4. (3)

De)

6. (5)

Bulletin So. Calif. Academy of Sciences

60° 159° 158° 157° 156°
ages |
= |e _i|__
Ee |
| |
Cechoanu
1 ERO

BOE aw

| oa

Sg
Same KAHUKU PT.

HAWAIIAN ISLANDS
o Mil 100

O A:-H-U

iKEWALO BASIN. = ==

SAS ALAY WAN BASIN. = op ST /

Map of Hawaiian Islands showing the collecting localities on the island.

KEY TO SERPULIDAE FROM OAHU
iubejcoledsbodyasymmetnicalla ee See Spirorbis sp.
ube noticoiled: body symmetrical’s-4-)- ae eee 2
Operculum present”, 0.2 3
Operculum*absent . 2... ee eee oe 10
@perculum with winged stalk >=. -=— 4-4.) -4 eee 4
Operculumiwithismoothistalk == 42 54.500 40> oe eee 5
Opercular plate flat to slightly concave with calcareous

PLOCESSCSeep ee eae Spirobranchus giganteus (Pallas, 1766).
Opercular plate flat to concave with no processes ..........
Beret ee LA As oars Pomatoleios kraussii (Baird, 1865).

@perculum’ witha simple funnel >>. >>>. 544 eee
MPP Shine e Fal ties Aa Oat Serpula vermicularis (Linnaeus, 1767).
Operculum with a funnel possessing upper crown of spines .. .
si Ate igi yo th Manan eae aaa need ee pa Ls Pearl al oy (Hydroides spp.) 6
Operculum vesicular and armed with hooks ..............
i Ree aT a ne oe Mercierella enigmatica Fauvel, 1923.
Operculum with a cup-shaped base and a conical or cylindrical
CHUIMOUS!CAP erate erase aye ee (Vermiliopsis spp.) 9

All opercularspines alike >> 3- 23554555 093 eee 7
@percularspmes notallalike {3424.55.25 see
SMe Se See ie aetcee on ae Hydroides brachyacantha Rioja, 1941.

Polychaetes from Hawati 231

7. (6) Many lateral spines on opercular crown .................
95. EE eee ee Hydroides norvegica Gunnerus, 1768.
One pair of lateral spines or processes on opercular crown . . 8

8. (7) Terminal lateral process on opercular crown .............
= gt aived Rsesie are eee na a Hydroidee lunulifera Claparede, 1870
Median lateral processes on opercular crown .............
2 6 ode Shea eae ani eR gET Hydroides crucigera Morch, 1863.

9.(5) Tube with dorsal ridge; opercular cap black, relatively long;
Moracicamenbrane extends toscement2 = 544-444 eee nee
6 6 OE ee ee Vermiliopsis hawaiiensis Treadwell, 1943.
Tube not as above; opercular cap brown, relatively squat;
fhonacicimembDrane extendsitomserinent eae eran ea cieeee
> 0: 6 ee ne Vermiliopsis torquata Treadwell, 1943.

LOC )}eeomirall inetubes forming colomiesms 4-4 45450 404s.
PN re er re eg Salmacina dysteri (Huxley, 1855).
Average sized tubes (to 40 mm long), not forming colonies .. .
MP ie ey Rk eG ears rac Al AE Protula atypha Bush, 1904.

Genus Serpula Linnaeus
Serpula vermicularis Linnaeus, 1767

Fauvel, 1927, pp. 351-2, fig. 20.

Diagnostic characters. Seven thoracic segments. Branchiae (16 to
32 pairs) with numerous pinnae and bare filamentous extremities.
Operculum funnel-shaped with 15 to 80 radii. Sides of thoracic
membrane joining ventrally posterior to thorax. Uncini with 4 to 8 teeth.

Material. B. P. Bishop Museum: Kaneohe, 1936 (5); Kaneohe,
April 9, 1937 (2); Kaneohe Bay, August 1936 (6); Pearl Harbor,
December 1940 (2), Edmondson; Pearl Harbor Barge VC-1024 Dry
Dock, January 5,.1948 (2) specimens; Pearl Harbor January 20,
1938; Oahu, 60 feet, serpulids 2-E, January 24, 1944; Oahu, 15 feet,
serpulids 1-B, January 24, 1944; Oahu, 45 feet, serpulids 2-D, January
24, 1944. Coconut Island, fouling plates at 10 feet, June 1968, 5
specimens, C. Corn; Maili Point, rubble, 20 to 80 feet, September 27,
1968 (6), J. McVey.

Previous records. Cosmopolitan, but not previously recorded from
Hawaii.

Discussion. None of these specimens were collected from natural
substrates. All were small (less than 20 mm long) and had few opercu-
Jar radii (1 8-26).

DED Bulletin So. Calif. Academy of Sciences

Genus Hydroides Gunnerus
Hydroides norvegica Gunnetrus, 1768

Fauvel, 1927, pp. 256-7, figs. 122 1-122 0

Diagnostic character. Radii of operculum form 22-36 lobes on edge
of funnel; crown with 14-20 spines with sharp lateral processes and
inner row of spines.

Material. B. P. Bishop Museum: Collections of numerous specimens
from Pearl Harbor in 1929, 1936, 1937, 1940, 1947, 1948. Coconut
Island, fouling plates at 3 to 10 feet for 10 weeks, June 20, 1968 (6),
C. Corn.

Previous records. Cosmopolitan.

Hydroides lunulifera (Claparede, 1868)

Day, 1967, p. 807, fig. 38. 4 j-k.
Diagnostic character. Opercular crown of spines each bearing
terminal pair lateral projections. ;

Material. B. P. Bishop Museum: Collections of numerous specimens
from Pearl Harbor, 1929, 1937; Kaneohe Bay 1936, 1937, 1937;
Kewola Basin 1943. Coconut Island, fouling plates at 3 to 5 feet for
10 weeks, June 20, 1968 (5), C. Corn; Coconut Island, intertidal on
coral rubble on reef flat, June 25, 1968 (2), D. Straughan.

Previous records: Cosmopolitan in warm seas.

Hydroides brachyacantha Rioja, 1941

Rioja, 1941, p. 169, pl. 3, fig. 2, pl. 4, figs. 1-9.

Diagnostic features. Operculum asymmetrical with 5-8 inwardly
curved spines on upper crown, with a gradation in size from smaller
spines on one side of the crown to larger spines on the other side.
Smallest spines have a blunt tooth projecting from the outside of the
curve.

Material. B. P. Bishop Museum: Black Point, March 9, 1939 (1)-

Previous records. Western Mexico (Rioja, 1941), Eastern Australia
(Straughan, 1967).

Hydroides crucigera (Morch, 1863)
Monrorl 933 pall sorsniea2o:
Diagnostic features. Opercular funnel with pointed spines. Oper-
cular crown with 9 thin spines bent towards centre of crown and with
a pair of medium lateral spines. (Fig. 2a)

Polychaetes from Hawaii 233

0.0 1.0 mm

Figure 2. a. Hydroides crucigerda operculum; b.

Vermiliopsis torquata operculum:
¢. V. hawaiiensis operculum.

234 Bulletin So. Calif. Academy of Sciences

Material. B. P. Bishop Museum: Pearl Harbor, April 11, 1937 (2);
Pearl Harbor, November 7, 1938 (2); Kaneohe Bay, 1936 (few);
Kaneohe Bay, February 1937 (1); Kaneohe Bay, August 5, 1937 (1),
Kaneohe Bay January 10, 1938 (few). Coconut Island, under coral
rubble on reef flat, June 25, 1968 (common), D. Straughan; Maili
Point, 20 to 85 feet, September 28, 1968 (5), J. McVey.

Previous records. Lower California (Treadwell, 1929), Mexico
(Rioja, 1941), Taboga Island (Monro, 1933).

Genus Mercierella Fauvel
Mercierella enigmatica Fauvel, 1923

Fauvel, 1923, p. 424, fig. 1.

Diagnostic characters. Tubes usually massed, each with several
collars along the length. Tubes white, animals with transversely
striped green and brown radioles. Operculum non calcareous with
one or several rows of spines. Collar setae large and serrated. Brackish -
water species.

Material. B. P. Bishop Museum: Alai Wai Canal 1947, (common);
Kewalo Basin, 1943 (common); Pearl Harbor, 1937 (common).

Previous records. Cosmopolitan, between 40° North and South
Latitudes in brackish waters.

Discussion. This species has been collected only from the area of
shipping harbors suggesting that it was probably introduced on ships.

Genus Vermiliopsis Saint Joseph
Vermiliopsis hawaiiensis Treadwell, 1943

Treadwell, 1943, pp. 3, 4, figs. 14, 15.

Diagnostic features. Operculum with a dark, almost black, cone-
shaped top with several internal partitions (Fig. 2c). Thoracic mem-
brane extends only to segment 2. Branchial tips not free. Smaller
species than V. torquata. (V. hawaiiensis-body length 3.5-4.5 mm;
V. torquata-body length 5.0-12.0 mm).

Material. B. P. Bishop Museum: Kaneohe Bay, April 8, 1937;
Maili Point, March 26, 1937 (2); Waikiki, April 14, 1937 (3); Waikiki,
December 31, 1937 (1); Waikiki, January 4, 1938 (5); Black Point,
April 2, 1937 (12); Black Point, April 8, 1937 (numerous). Nanakuli,
intertidally, June 28, 1968 (numerous), D. Straughan; Coconut Island,
fouling plates, June 1968 (numerous), C. Corn; Coconut Island, reef
edge, June 1968 (numerous), D. Straughan.

Previous records. Hawaii (Treadwell, 1943).

Polychaetes from Hawaii 235

Discussion. Hartman (1959, 1966) synonymised this species with
V. multiannulata. However, V. multiannulata has the thoracic mem-
brane extending as far as segment 5. As well as the different develop-
ment of the thoracic membrane, V. hawaiiensis is readily distinguished
from V. torquata by the differences in the operculum.

Vermiliopis torquata Treadwell, 1943.

Treadwell, 1943, p. 4, figs. 16, 17.

Diagnostic features. Operculum with a brown chitinous top. (Fig.
2b) Thoracic membrane extends to segment 5. Branchial tips not free.
Larger species than V. hawaiiensis. (V. hawaiiensis-body length 3.5-
4.5 mm; V. torquata-body length 5.0-12.0 mm).

Material. B. P. Bishop Museum: Kaneohe Bay, April 8, 1937,
Maili Point, December 21, 1937 (3); Waikiki, April 14, 1937, (6);
Waikiki, December 31, 1937 (6), Pearl Harbor, December 28, 1937
(1): Black Point, December 27, 1937 (1); Black Point, April 8, 1937
(1), Hanauma, April 4, 1937 (2). Coconut Island, reef edge, June
28, 1968 (2), D. Straughan; Maili Point, 45 feet, September 27, 1968
(1), J. McVey.

Previous records. Hawaii (Treadwell, 1943).

Discussion. Hartman (1959, 1966) synonymised V. torquata with
V. multiannulata. The species are similar in that both have brown
chitinous operculae and similar development of the thoracic mem-
brane. However the tips of the branchiae are free in V. multiannulata
and not free in V. torquata.

Genus Pomatoleios Pixell
Pomatoleios kraussii (Baird, 1865)

Day, 1967, pp. 800, 801, fig. 38. 3 a-f.

Diagnostic characters. Collar setae and eye spots absent. Uncini
with fairly numerous teeth, most anterior being larger and gouged.
Abdominal setae trumpet-shaped with one side produced into long
spine. Operculum flat with winged pedicle. Tube with flap over
entrance.

Material. Coconut Island, fouling plate at 3 feet for 10 weeks, 20
June 1968 (1), C. Corn: Coconut Island, fouling plate at 5 feet for 10
weeks, 20 June 1968 (1), C. Corn; Coconut Island, intertidal rocks
and coral rubble on reef flat in front of Hawaii Institute of Marine
Biology, 25 June 1968 (very common), D. Straughan.

Previous records. Tropical Indo-West Pacific.

236 Bulletin So. Calif. Academy of Sciences

Discussion. This species was only collected from Kaneohe Bay
(for further details see Straughan, 1969). Kaneohe Bay has a reef
across the mouth so that the Bay provides a sheltered habitat. In
eastern Australia P. Araussii occurs along the tropical coast sheltered
by the Great Barrier Reef and not on the Great Barrier Reef.

Genus Spirobranchus Blainville
Spirobranchus giganteus (Pallas, 1766)

Day, 1967, p. 803, fig. 38. 3 h-k.

Diagnostic characters. Opercular plate calcareous with 2 antler-
like processes which may branch close to their base. Opercular stalk
winged.

Material. B. P. Bishop Museum: Diamond Head, 60 to 70 feet,
1962 (1); Kaneohe Bay (1). Kaneohe Bay, reef rubble at 8 feet, June
28, 1968, J. Struhsaker; Maili Point, in Poroites elaborata from 20
to 45 feet, September 27, 1968 (common), J. McVey.

Previous records. Circumtropical.

Discussion. Tubes are thick, pink inside and generally have a
prominent dorsal spine.

Pomatoceras caeruleus (Schmarda | 861) (Hartman, 1966) originally
identified as Pomatocerus Strigiceps by Treadwell (1906) (Am. Mus.
Nat. Hist. No. 307) appears to be a specimen of Spirobranchus that
has lost its operculum.

Genus Salmacina Claparede
Salmacina dysteri (Huxley, 1855)

Fauvel, 1953, p. 477, fig. 250.

Diagnostic characters. Very slender, white massed tubes. Branchial
filaments with spatulate enlargements at their tips. Fin-like expansion
at base of collar setae with numerous more or less fine teeth. Sperma-
tozoa develop in segments anterior to those producing ova.

Material. B. P. Bishop Museum: Oahu from “Salpa”, September
21, 1961, L. G. Eldridge; Kaneohe Bay, May 10, 1937, Edmondson;
Kaneohe Bay, April 21, 1938, Edmondson; Black Point, on rocks,
March 27, 1937; Kaneohe Bay, September 6, 1936; Kaneohe Bay,
December 1936, Kaneohe Bay, October 8, 1937. Coconut Island,
just below Low Water Spring, under rubble on reef edge, June 1966,
D. Straughan.

Previous records. Cosmopolitan, in warm seas.

Polychaetes from Hawaii D3]

Genus Protula Risso
Protula atypha Bush, 1904

Bush, 1904, p. 228.

Diagnostic characters. Large thoracic membrane overlapping on
center of thoracic. Branchiae with paired filaments, short free tip.
Thoracic uncini with fine teeth, except for the stout elongate anterior
tooth.

Material. B. P. Bishop Museum: Kewalo, July 10, 1937 (6); Maili
Point, December 21, 1937 (numerous); Maili Point, December 28,
1937 (numerous); Black Point, April 2, 1937 (numerous); Waikiki,
March 31, 1937 (2); Waikiki, December 1937 (1); Hanauma Bay,
April 4, 1937 (numerous). Nanakuli, under rocks at low water, June
27, 1968 (4), D. Straughan; Coconut Is., under rocks seaward end of
island, June 28, 1968 (1), D. Straughan; Kewalo Basin end at Ala
Moana Beach, under rocks at tow water, July 25, 1968 (3), D.
Straughan.

Previous records. California

Description.

Tube. — White round, some growth lines.

Operculum. — Absent.

Branchiae. — 10 pairs arranged in a semi-circle; paired filaments,
free tips to branchiae, no interbranchial membrane.

Collar. — Three lobes continuous with large thoracic membrane which
unites posterior to thorax. Simple striated collar setae.

Thorax. — 7 segments, 6 pairs setae and uncini. Setae simple bladed
and capillary. Unicini with fine teeth and a long stout tooth projecting
anteriorly.

Abdomen. — Setae sickle shaped at anterior end and capillary at
posterior end. Uncini similar to those of thorax but smaller.
Coloration. — In life, branchiae clear with regular red and white spots.

Discussion. A brief description of the Hawaiian material is included
to augment prior descriptions of material from California. P. atypha
differs from P. superba Moore and P. palliata Willey in that there is
no bifid tip on the large anterior tooth.

DISCUSSION

The distribution of serpulids is shown in Table 1. Records of three
species, Hydroides brachyacantha, Protula atypha, and Pomatoleios
Kraussii, are confined to the littoral zone. However, only one specimen
of the former species is recorded. P. atypha is recorded from both
exposed and protected localities while P. kraussii is restricted to the

238

TABLE I
THE DISTRIBUTION OF SERPULIDS AND HABITAT DESCRIPTIONS

Bulletin So. Calif. Academy of Sciences

mw) | a4
“sqns "ye TS
4 ‘ PHOS n| n| a
| kp ‘a
BAR] 919qndg
PHOS a
ale el | 1 oz | gies |
[e105 21990g
PHOS n n n
3)
= nz
5 yoor J aiqqny
z yoraq POS | w»
A p9159}01d oa; | w A.) Qu} Qu
<
2 pasodxg | W ia} om) w wa)
ea
ee ysl yoeig mo; eo; a
= A|[euoseag
2 JULIE Z| =| =| 2] =| =| = =| =
é
& 1ISSNDAY “d or
O
w
= snajunsis 5 + ap ar ie
O
= DUUDIDAYIDAG “H ap
= 14aIsSAkp °§ ate =P A
a
es SISUIIIDMDY +A + aL ate ate mB
N
fe pyda1 ‘d he Pal) ee peda |) a +] 2]
ea}
3 pvipnbsiol +) + + or a
n ral [ =
w DAISIINAD “HY + ats yn
= + t
| SLIDJNINUAIA *§ + ms
oO
or CeCe
< 8 a
cog SEGEEE
a
a ‘GECC ala
5
> ae)
= ie)
ails eels £
ao) oa | =
3] S| &) =) <] 5] |S) 9) 212) |
i ml) cs) Sl) 4) fs) S| =| | ss] 6
S) ‘=| co 3 ba f=, SS
S| s| S| 6} =| S| s| S| 8) $] Ss] S| =
| MM] Xl | ml Ql S| <] Ml al Zl Sl 3

SL

Sublittoral

Polychaetes from Hawaii 239

protected waters of Kaneohe Bay. The latter settles subtidally but does
not survive competition from ascidians at these levels (Straughan,
1969).

Spirobranchus giganteus is recorded only from sublittoral coral.
S. giganteus commonly occurs on intertidal corals in tropical Australian
waters (Straughan, 1967). The limiting factor for S. giganteus on Oahu
appears to be the distribution of the host species of coral. These occur
only in the sublittoral zone around Oahu.

The eight remaining species occur both littorally and sublittorally.
Mercierella enigmatica is confined to sheltered seasonally brackish
areas. These are also the major port and marina facilities on the island.
This supports the theory that the present widespread distribution of
this species is a collorary to man’s shipping activities.

The seven remaining species occur on a variety of substrates. How-
ever, no serpulids are recorded from the beach rock at Kahuku or
the laval rock at Koko Head. Both these localities were visited on
several occasions. The two areas are exposed to heavy surf action and
the rocks do not provide the sheltered niches required by settling
serpulid larvae. Serpulids are excluded from these areas by physical
factors rather than substrate because they are recorded from beach
rock and lava at other localities.

Hartman (1966) stated that “the benthic faunas...may show
affinities with Indo-Pacific regions”. It is interesting to note that of 12
species reported here, only one Pomatoleios kraussii, has an Indo-
Pacific distribution. Protula atypha and Hydroides crucigera have an
eastern Pacific distribution while Hydroides brachyacantha has a
tropical Pacific distribution. Vermiliopsis torquata and V. hawaiiensis
are endemic to the Hawaiian Islands. The remaining species are
widespread in tropical and/or temperate waters.

ACKNOWLEDGEMENTS

This work was carried out while the author was the holder of the American
Association of University Women Fellowship. The author is indebted to the
Hawaii Institute of Marine Biology and Allan Hancock Foundation of the
University of Southern California for the provision of laboratory facilities. I
also wish to thank Carolyn Corn, June Harrigan, Dr. Alison Kay, Mr. Jim McVey,
and Dr. Jeannette Struhsaker for assistance in making field collections and Dr.
Dennis Devaney for assistance at the Bernice P. Bishop Museum. The illustrations
are by Jim Trask.

240 Bulletin So. Calif. Academy of Sciences

LITERATURE CITED

Busu, D. J., 1904. Tubicolous annelids of the tubes Sabellids and Serpulides
from the Pacific Ocean. Harriman Alaska Exped. N.Y., 12: 169-355.

Day, J. H., 1967. A Monograph of the Polychaeta of Southern Africa. Pt. 2
Sedentaria. British Mus. (Nat. Hist.) London.

Epmonpson, C. H., 1944. Incidence of Fouling in Pearl Harbor. B. P. Bishop
Mus. Occasional Pap., 18: 1-34.

EDMONDSON, C. H. AND INGRAM, W. M., 1939. Fouling Organisms in Hawaii
B. P. Bishop Mus. Occasional Pap., 14: 251-300.

FAUVEL, P., 1923. Un nouveau Serpulien d’eau saumatre Mercierella n.g., enig-
matica n. sp. Bull. Soc. Zool. Fr., 47: 424-430.

1927. Polychétes sedentaires. Addenda aux Errantes, Archiannélides,
Myzostomanes. Faune de France. 16: 1-494.

1953. Annelida Polychaeta. Jn The Fauna of India, including Pakistan,
Ceylon, Burma and Malaya. (The Indian Press: Allahahad). 507 p.

HARTMAN, O., 1959. Catalogue of the Polychaetous Annelids of the World, Part
II, Occ. Pap. Allan Hancock Fdn., 23: 568-609.

1966. Polychaetous Annelids of the Hawaiian Islands. B. P. Bishop Mus.
Occasional Pap. 23: 163-252.

Monro, C. C. A., 1933. The Polychaeta Sedentaria collected by Dr. C. Crossland
at Colon in the Panama Region and the Galapagos Islands during the
expedition of the S.Y. St. George. Zool. Soc. London, pt. 2, : 1039-1092.

Morcy, O., 1863. Reviso critica Serpulidacum. Naturh. Tidschr. (3) 1, 367, 470.

Rioga, E., 1941. Estudios anelidologicos II. Observaciones acerca de varias
especies del genero Hydroides Gunnerus (sensu Fauvel) de las cortas Mexi-
canas del Pacific. An. Inst. Biol. Univ. Mex. 12: 161-75.

STRAUGHAN, D., 1967. Marine Serpulidae (Annelida: Polychaeta) of Eastern
Queensland and New South Wales. Aust. J. Zool., 15: 201-61.

1969. Intertidal zone formation by Pomatoleios kraussii (Annelida:
Polychaeta). Biol. Bull. 136: 469-482.

TREADWELL, A. L. 1906. Polychaetous Annelids of the Hawaiian Islands. Bull.
U.S. Fish Commission for 1903 XXIII, pt. 111: 1165-1181.

1929. New species of polychaetous annelids in the collections of the
American Museum of Natural History, from Puerto Rico, Florida, Lower
California, and British Somaliland, Amer. Mus. Novitat. N.Y., No. 392, 13 p.

1943. New species of Polychaetous Annelids from Hawaii. American
Mus. Novitat. N.Y. No. 1233, 4 p.

Accepted for publication September 18, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 241-247, 1969
NEW NEOTROPICAL CURCULIONIDAE (COLEOPTERA)

ELBERT L. SLEEPER

Department of Biology

California State College
at Long Beach

ABSTRACT: Pissodes zitacuarense, n. sp. from near Zitacuaro,
Michoacan, Mexico, Sandrarhyncolus, n. gen., and Sandra-
rhyncolus dubius, n. sp. from La Junta, Limon Province, Costa
Rica are described and illustrated. Dioptrophorus fausti
Champion is reported and illustrated from Nevada de Colima,
Mexico, the first specific locality for this species. Both the Pis-
sodes and Dioptrophorus are reported as injuring Pinus.

INTRODUCTION

Two of the following species were submitted to the author by Mexican
forestry personnel for determination in order that they have names
available for publication. The third species is described to bring it to
the attention of workers on Neotropical Curculionidae. The author
wishes to acknowledge the aid of Eric M. Fisher, P. B. Pacheco and
Linda M. Williams. The following abbreviations are used: ELS, E. L.
Sleeper Collector; (ELS), E. L. Sleeper Collection.

Pissodes zitacuarense, new species (Pissodinae)
Figure 5

Holotype. MEXICO, Michoacan, 10 mi. E Zitacuaro, El. 2200 m,
[X-50, S. T. Winston, (ELS No. 83).

Female. Length 7.5 mm, width 3.1 mm. Robust, dark brown, dorsum
clothed with scattered setiform appressed grayish white scales, with
patches of broader, pale brown and white scales; the pale brown in a
large oblique spot anteriorly on each elytron and a small rounded spot
on each sixth interval anterior to declivity; the white scales forming
two small spots near the middle of pronotum, one in front of scutellum
and one each second, third and fourth elytral interval just anterior to
the declivity; venter clothed with coarse, oval, whitish and setiform
grayish white scales; the legs with setiform scales. Head and rostrum
rather coarsely, closely punctured; rostrum slightly longer than pro-
thorax (13:12); the antennae inserted at middle. Prothorax broader
than long (14:12) abruptly constricted anteriorly; pronotum closely,
rugosely punctured with the intervals between punctures alutaceous;

241

242 Bulletin So. Calif. Academy of Sciences

a raised longitudinal carina at middle; the hind angles distinct and
rectangular. Elytra two-thirds as wide as long, 2.6 times longer than
prothorax; elytral intervals 3 and 5 strongly, narrowly elevated, 7 and
9 feebly elevated, elevated intervals noticeably asperate, the others
feebly so; strial punctures large and rounded, encroaching upon adjacent
intervals. Venter coarsely, closely punctate.

Male. Similar to the female with slightly shorter rostrum (same
length as the prothorax), antennae inserted slightly before the middle
and with the first abdominal sternite feebly concave.

Type Material. Holotype and one paratype same data (ELS). One
male, one female paratype, Zitacuaro, VIII-21-68, P. B. Pacheco.
The latter were returned to the sender.

In Hopkins (1911) this species will key very readily to P. webbi
Hopk. from which it differs in the much more sharply costate intervals
3 and 5, the larger, deeper strial punctures which encroach upon the
adjacent intervals, the more slender rostrum, and the color (scale)
pattern. It differs from P. yosemite Hopk. in the same characters as it
does from webbi. In color pattern it resembles some examples of P.
canadensis Hopk., a species with broader, slightly elevated intervals
3 and 5 and a non-asperate, less deeply punctured disc of the elytra,
and a shorter more robust rostrum.

When the holotype and paratype were given the author by the collec-
tor several years ago, it was stated that they had been collected near
the bases of Pinus sp. on the slopes about 10 miles east of the town of
Zitacuaro. The holotype was subsequently examined by Sir G. A. K.
Marshall and stated to be near, but not the same as, the P. strobi popu-
lation mentioned in the Biologia Centrali-Americana by Champion
(1902:119). The other two specimens were sent for determination with
the information that they were causing severe damage to Pinus lawsonii
in the vicinity of Zitacuaro, and that a study of the biology of the weevil
was being undertaken.

Dioptrophorus fausti Champion (Hylobiinae)
Figures | and 2

Twenty-five specimens of this species were sent for determination.
In addition the author had on hand seven other specimens collected by
field parties from California State at Long Beach. All material came
from the State of Jalisco, Nevada de Colima between 2440 m and
3355p
Material collected by P. B. Pacheco was stated to have been “injuring

New Species of Coleoptera 243

young living pines” and taken in July 1968. Our material all came from
beneath the bark of dead pines, VI-27-65, 2440 and 3355 m, E. M.
Fisher, and VI-26-67, 2440 m, L. M. Williams. The type locality was
“Mexico”. It was described from a unique specimen.

At the 2115 m level a single specimen of what is apparently a small
D. simplex Faust was encountered by Williams the same date.

The two species have an overlapping distribution in central Mexico
and apparently occur in similar habitats. They can be easily separated,
however, in that D. simplex has tubercles at the declivity on the sutural
interval while they are entirely absent in D. fausti. In the latter the
tubercles on interval three are greatly enlarged.

Figures 1-6. 1. Dorsal view of Dioptrophorus fausti Champion. 2. Lateral view
(left side) of same. 3. Dorsal view of holotype of Sandrarhyncolus dubius, new
species. 4. Prosternal view of same. 5. Dorsal view of holotype of Pissodes zita-
cuarense, new species. 6. Head of holotype of Sandrarhyncolus dubius, new
species. Line in photographs 1, 3, and 5 equal one milimeter; other photographs
no scale.

244 Bulletin So. Calif. Academy of Sciences

Sandrarhyncolus, new genus (Hylobiinae)

Type species. Sandrarhyncolus dubius, new species.

Rostrum (Fig. 6) short, slightly more than one-half length of pro-
thorax from ocular lobe to base near humeri; mandibles robust, curved,
notched on inner edge, overlapping at tips. Scrobes oblique, deep,
narrow, feebly widening posteriorly passing inferiorly at base of ros-
trum, widely separated from the eye, at nearest point by more than
width of rostrum at base. Antennae inserted near middle of rostrum,
scape short, only as long as following 3 segments, fitting into lateral
part of scrobe only; funicle 7 segmented, segment | short and globose,
2 more slender and slightly longer than |, as long as 3 and 4 combined,
remaining segments a little wider than long. Club elongate-oval, densely
clothed with fine setae. Head rounded, continuous with rostrum. Eyes
slightly elevated above surface of head, round, separated by one and
one-fourth width of rostrum at antennal insertion and separated from —
anterior margin of prothorax by diameter of eye. Prothorax prolonged
over the head, feebly constricted apically, feebly setiferous and asperate,
ocular lobes present. Scutellum minute, rounded, smooth and shining.
Elytra nearly one-half longer than prothorax (including apical pro-
jection of latter), same width as prothorax, sides parallel, dorsal out-
line abruptly declivious in apical one-eighth, base strongly bisinuate,
10 striate, the tenth complete to apex. Venter with prosternum trans-
versely, feebly concave (Fig. 4) about one-half as long as fore coxae
are wide, passing between fore coxae; metepisterna and epimeron
fused, only a thin edge of metepisterna and the epimeron visible lateral
to the metacoxae; abdominal intercoxal process projecting deeply into
metasternum to in front of metacoxae; abdominal sternite 1 and 2
feebly convex, 2 slightly longer than | behind coxae, first two combined
twice as long as remainder combined, strongly raised above 3-5; three
slightly longer than 4, 5 slightly longer than 3 and evenly rounded at
apex; suture between | and 2 feebly arcuate at middle only, the remain-
ing sutures straight and very deep. Fore coxae separated by one-fourth
their diameter; mesocoxae by one-half their diameter; metacoxae by
width of coxae. Femora stout, the fore pair very strongly toothed, others
minutely toothed near middle of inner side. Tibiae | and 2 broad and
flat, strongly curved, more than one-half as long as femora, 3 straight,
about one-half length of femora; all strongly uncinate and mucronate;
3 with outer apical comb lateral of uncus; a few spines representing
dorsal comb present behind mucro. Tarsi 4-segmented; about one-half
as long as tibiae except 3rd pair which are as long as tibiae; tarsal seg-
ment | twice as long as 2, 3 very broadly bilobed; claw segment very

New Species of Coleoptera 245

slender, all but claw segment densely pubescent beneath. Claws con-
nate at base.

The subfamily placement of this genus presents several problems
and the present placement is somewhat arbitrary. It possesses character-
istics of several subfamilies, particularly the Cossoninae and Hylobii-
nae. The head, rostrum, and elytra are very like those encountered in
Rhyncolus and several closely allied genera. The prothorax, (particu-
larly the anterior dorsal projection), the legs and tarsi are similar to
conditions encountered in several genera of Hylobiinae. The vestiture
and habits of the type species at rest were as encountered in some
Cryptorhynchinae (Acamptini), and indeed at first glance would
appear to be of that tribe. Behavior while running and flying were
erratic as found in some Zygopinae. The prominently bilobed third
tarsal segment and the prominent, ascending outer apical comb lateral
of the uncus on the tibia 3 were the characteristics relied upon for
placement of the genus in the Hylobiinae. The name of the genus is an
arbitrary arrangement of letters.

Sandrarhyncolus dubius, new species
Figure 3

Holotype. COSTA RICA, Prov. Limon, La Junta, VI-22-46, ELS
(ELS No. 76).

Female. Length 6.5 mm, width 2.3 mm. Elongate-cylindrical, derm
reddish black to black, densely clothed with closely placed, overlapping
prostrate to semierect, flat, transparent, ribbed white, yellow and
brown scales, some of which form tufts on the elytra. Rostrum rather
cylindrical in cross-section, short, slightly more than one-half length
of prothorax from ocular lobes to base near humeri; sides convergent
from base to apex; dorsal aspect with base one-half wider than apex,
very densely punctate; mandibles very prominent, curved and emargi-
nate on inner edge; rostrum in lateral aspect with scrobes oblique, deep,
slightly widening posteriorly, passing inferiorly where the rostrum
joins the head and becoming evanescent; nearest point on scrobe to eye
one and one-half times diameter of eye distant; a narrow deep sulcus
below scrobe. Antennae inserted near middle of rostrum; except for
club, rather densely clothed with slender semierect scales; scape as
long as first four segments of funicle, funicular ratio 1.1:1.2:0.5:0.5:
0.6:0.6:0.8, segment | globose, 2 elongate slender, remainder robust,
increasing in width to club; segment 7 closely associated with the club,
but with different vestiture than latter. Club elongate-oval, very densely
clothed with short prostrate brownish setae. Head globose, continuous

246 Bulletin So. Calif. Academy of Sciences

with rostrum, dorsal outline of head and rostrum concave; front con-
cave; vertex with a transverse shallow depression passing to behind
eyes. Eyes very small, circular, slightly elevated above the head. Pro-
thorax, including projection over head, slightly longer than wide; sides
divergent from base to apex, apical constriction evident on sides but
not across dorsum; anterior projection over head bilobed and with a
triangular depression behind; pronotum convex, disc with punctures
very fine, deep and closely placed but obscured by vestiture; base
bisinuate with a feeble bilobed projection that encloses the scutellum
in part; postocular lobes present as small projections with seta-like
scales and small teeth. Scutellum minute, rounded, smooth and shining.
Elytra nearly twice as long as wide, as wide as prothorax; derm minutely
granulate beneath dense vestiture; humeri not prominent, base with
large oblique elevations extending from scutellum to interval 5; dorsal
outline abruptly declivious, nearly perpendicular, in apical one-eighth,
declivity with prominent tubercles on intervals 2 and 4 and quadri-
tuberculate at apex; striae not impressed, their punctures separated —
by nearly twice their diameter, most of the intervals with small tubercles,
these often more prominent on the even intervals. Venter clothed as
dorsum, with a waxy bloom intermixed, except on the abdominal
sternite 5, 5 sparsely setose; thoracic sterna punctured as disc of pro-
notum; sternites of abdomen alutaceous; prosternum very short extend-
ing between fore coxae to near their middle, mesosternum very narrow,
only as long as diameter of mesocoxae; metasternum, between meso-
and metacoxae, about one-third longer than diameter of mesocoxae,
extending between mesocoxae to near middle. Abdominal sternites
convex, sternite 1 very convex, the intercoxal process very long and
strongly rounded; 2 moderately convex, suture between | and 2 very
feebly arcuate and moderately evident; 3 longer than 4; 5 longer than 3;
sutures between 2-5 very deep. Femora | robust, with a prominent
tooth near middle, 2 and 3 less robust and armed with a minute denticle
near middle. Tibiae | and 2 slightly more than one-half as long as
femora, strongly curved, very flattened and broad, with a denuded
groove on inner edge; apical comb ascending near inner base of uncus
on tibia 1, on outer edge on tibia 2; tibia 3 short, straight, slightly more
than one-half as long as femora 3, inner edge with a glabrous flat area,
apical comb at outer apex. Tarsi robust, densely clothed dorsally with
narrow and broad scales; ventrally with dense setose pads, which on
segment | are small at inside apically, pads completely covering venter
of 2 and 3, 4 without pads, segment ratio 5:2:3:3:3.8. Claws connate
to near middle.
Male. Unknown.

New Species of Coleoptera 247

Type Material. Holotype unique. The elytra, metasternum and
abdomen of a second specimen were found beneath the bark of a fallen
tree. The holotype was taken at a light along the Rio Reventazon, about
1 km NE of La Junta.

LITERATURE CITED

CHAMPION, G. C., 1902 (1902-1906). Curculionidae. Coleoptera. Biologia Cen-
trali-Americana. 4: 92-95, 119-120.

Hopkins, A. D., 1911. Contributions toward a monograph of the bark beetles of
the genus Pissodes. U.S. Dept. Agriculture, Tech. Paper 20(1): 68 p.

Accepted for publication September 18, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 248-251, 1969

THE RECENT INTRODUCTION OF
WATERSIPORA ARCUATA BANTA
(BRYOZOA, CHEILOSTOMATA)

AS A FOULING PEST IN SOUTHERN CALIFORNIA

WILLIAM C. BANTA
U.S. National Museum
Washington, D.C.

ABSTRACT: Available evidence indicates that Watersipora
arcuata is not indigenous to southern California, and that it
has been introduced, probably since 1963. Its distribution
suggests it originated in western Mexico, spread to Australia
and New Zealand, and was subsequently introduced into Cali-
fornia. The species is an important fouling pest in Australia
and New Zealand, and may cause similar problems here.

INTRODUCTION

In January, 1967, extensive growths of the encrusting cheilostome
bryozoan, Watersipora arcuata Banta (1969), were discovered near
Point Loma, San Diego, California. This record considerably extended
the northern limit of the range of the species. W. arcuata subsequently
has been found in abundance in fouling communities throughout
southern California (Table 1). This note presents evidence that W.
arcuata is not indigenous to California, but has been introduced,
probably since 1963. The presence of the species is important because
it has proven to be an important fouling pest in Australia and New
Zealand.

The first reasonably certain record of Watersipora arcuata (as W.
cucullata) is that of Hastings (1930:729, pl 15, fig. 101) from the Gala-
pagos Islands; she noted that some of Busk’s unpublished specimens
collected before 1900 from Cape San Lucas, near the tip of Baja Cali-
fornia, also possess a “‘straight or convex proximal border” to the aper-
ture (p. 730). Part of Canu and Bassler’s (1930) Pachycleithonia nigra
may also be of this species (Banta, 1969).

By 1940, W. arcuata was abundant and widely distributed in the
Gulf of California, at least as far north as Angel de la Gardia Island
(Osburn, 1952). Soule (1961) and Soule and Soule (1964) recorded it
from the Gulf of California and Scammon’s Lagoon, on the Pacific
side of Baja California. Meanwhile, W. arcuata became a common
fouling pest in Australia (Wisely, 1958). Allen (1953) records “W.
cucullata’” as having been introduced into Australia after 1889, but

248

Bryozoan Ecology 249

since he did not distinguish between forms with arcuate and “normal”
apertures, it is not certain whether or not this animal was W. arcuata.
According to Skerman (1960 a, b), “W. cucullata” was introduced
into Auckland Harbor, New Zealand, between 1956 and 1958. Sker-
man’s “W. cucullata” is identical to W. arcuata (Banta, 1969).

It is reasonably certain that before about 1960, W. arcuata was either
absent from southern California, or was present in such small numbers
that previous surveys did not record it. If earlier authors had found
the animal, it probably would have been recorded as Watersipora
cucullata, W. subovoidea, or W. nigra, or as these species in the genera
Dakaria, Schizoporella, or Smittia. Because of its dark color, W. arcuata
is quite distinctive, so there is little chance of its being confused with
other Bryozoa. The following are some of the more important surveys
of southern Californian waters in which W. arcuata would probably
have been recorded if it had been present.

OBSERVATIONS

Robertson (1908) reported on extensive bryozoan collections from
southern California, including much material from San Diego. Coe and
Allen (1937) made careful observations on a fouling environment at
La Jolla, near San Diego. Osburn (1952) recorded W. arcuata (as
W. cucullata nigra) as abundant elsewhere, but he did not find it in his

TABLE I
OCCURENCES OF WATERSIPORA ARCUATA
IN SOUTHERN CALIFORNIA

Locality Dates
Southwestern Yacht Club Marina, Jan., Feb., Mar., Apr.,
San Diego Bay (type locality). May, Nov., Dec., 1967;
Mar., Oct., 1968; Feb.,
1969.
Oceanside Marina, Oceanside* Feb., 1969
Long Beach Marina, Alamitos Bay, Jan., May, 1969.
Long Beach.
Naples May, 1969.
Redondo Harbor, Redondo. Feb., 1969
Marina del Rey, Venice. Apr., 1969

Absent: Dana Point, Balboa Island, Huntington Harbor, Surfside, San Pedro;
May, 1969,

*Variant form; see Banta, 1969:100.

250 Bulletin So. Calif. Academy of Sciences

large collections gathered from all over southern California. Reish
(1963; Bryozoa identified by J. D. Soule) studied a fouling environment
in Alamitos Bay, Long Beach; W. arcuata was not recorded, but it is
abundant there now (Table 1). W. arcuata has not been recorded as a
fossil, despite the extensive studies on Cenozoic Bryozoa by Soule and
Duff (1957) and Soule (1959, 1960).

Negative data of this sort are, of course, inconclusive. It will prob-
ably never be possible to exclude the possibility that W. arcuata has
always been present in California in small numbers, but that recent
changes in environment allowed it to undergo explosive population
growth. The evidence presented here, however, appears to support the
following hypothesis. W. arcuata was originally indigenous to the tropics
and subtropics of the eastern Pacific. It was, or has become, adapted to
fouling environments, and so became attached to bottoms of ships
sailing from America to Australia and New Zealand. It survived trans-
port across the Pacific and, by 1960, was able to establish itself in cooler
waters there. One to seven years later, the animal was introduced into
southern California. It is not obvious why the animal did not spread to
California sooner, despite early and constant shipping between the
Gulf of California and the major ports at San Diego and Los Angeles.
Perhaps the Australian-New Zealand form is a mutant better able to
survive cooler temperatures and pollution. If so, the local animal may
have been introduced from there, rather than from Mexico.

Wisely (1958) and Skerman (1960 a, b) studied growth and repro-
duction in W. arcuata, and report that the animal is an important fouling
pest. A significant feature is its ability to settle and grow on copper-
containing anti-fouling paints. Worse, it forms flat layers which cover
the protective paint and allow other fouling organisms to settle. It is
probable that W. arcuata will cause similar problems in southern
California.

ACKNOWLEDGMENTS

The manuscript benefited from the suggestions of Dr. John D. Soule, Dr. Dorothy
F. Soule, Dr. John L. Mohr, and Mr. Peter H. Benson. The research, conducted
at the University of Southern California, was supported in part by an NDEA
Title IV Graduate Fellowship. Allan Hancock Foundation contribution 332.

LITERATURE CITED

ALLEN, F., 1953. Distribution of marine invertebrates by ships. Australian J. Mar.
Freshwat. Res., 4: 307-316.

BanTa, W. C., 1969. Watersipora arcuata, a new species in the subovoidea-cucul-
lata-nigra complex (Bryozoa, Cheilostomata). Bull. So. Calif. Acad. Sci.,
68: 96-102.

Bryozoan Ecology 251

CANU, F. AND R. S. BASSLER, 1930. The bryozoan fauna of the Galapagos Islands.
Proc. U.S. Nat. Mus., 76: 1-78.

CoE, W. R AND W. E. ALLEN, 1937. Growth of sedentary marine organisms on
experimental blocks and plates for nine successive years. Tech. Bull. Univ.
Calif. Scripps Inst. Oceanogr. 4: 101-136.

HastTIncs, A. B., 1930. Cheilostomatous Polyzoa from the vicinity of the Panama
Canal collected by Dr. C. Crossland on the cruise of the S. Y. “St. George”.
Proc. Zool. Soc. London, 1929: 687-740.

OsBurRN, R. C., 1952. Bryozoa of the Pacific coast of America, part II, Cheilosto-
mata Ascophora. Allan Hancock Pacific Exped., 14: 271-611.

Reisu, D. J., 1963. Mass mortality of marine organisms attributed to the “red
tide’ in southern California. California Fish and Game, 49: 265-270.

ROBERTSON, A., 1908. Contributions from the laboratory of the Marine Biological
Association of San Diego. XX. The incrusting cheilostomatous Bryozoa
of the west coast of North America. Univ. California Publ. Zool., 4:253-344.

SKERMAN, T., 1960 a. The recent establishment of the Polyzoan, Watersipora
cucullata in Auckland Harbour, New Zealand. New Zealand J. Sci., 3: 615-
619.

1960 b. Ship-fouling in New Zealand waters: a survey of marine fouling
organisms from vessels of the coastal and overseas trade. New Zealand J.
Sci., 3: 620-628.

Soule, D. F. AnD J. D. SouLE, 1964. The Ectoprocta (Bryozoa) of Scammon’s
Lagoon, Baja California, Mexico. American Mus. Novit., No. 2199, 56 p.

SouLeE, J. D., 1959. Bryozoa. In G. Kanakoff and W. K. Emerson, Late Pleisto-
cene Invertebrates of the Newport Bay area, California. Los Angeles Co.
Mus. Contrib. Sci., 31-18-19.

1960. Phylum Bryozoa. In L. G. Hertlein and U. S. Grant IV, The geology
and paleontology of the marine Pliocene of San Diego, California. Mem.
San Diego Soc. Nat. Hist., 2: 85-87.

1961. Results of the Puritan-American Museum of Natural History
Expedition to Western Mexico, 13, Ascophoran Cheilostomata (Bryozoa)
of the Gulf of California. American Mus. Novit., No. 2053, 66 p.

SouLe, J. D. anD M. M. Durr, 1957. Fossil Bryozoa from the Pleistocene of
southern California. Proc. Calif. Acad. Sci., 29: 87-146.

WISELY, B., 1958. The settling and some experimental reactions of a bryozoan
larva, Watersipora cucullata (Busk). Australian J. Mar. Freshwat. Res.,
9: 362-371.

Accepted for publication September 17, 1969

Bull. So. Calif. Acad. Sci. 68(4): 252-256, 1969

THREE BRIEF NARROW-BAND SOUND EMISSIONS
BY A CAPTIVE MALE
RISSO’S DOLPHIN, GRAMPUS GRISEUS

DaviD K. CALDWELL, MELBA C. CALDWELL
AND
J. FRANK MILLER

Marineland Research Laboratory
St. Augustine, Florida 32084

ABSTRACT: Illustrated with a sonagram, three brief sound
emissions are described and discussed. The sounds were made
by a subadult male while stranded during venipuncture. It is
suggested that the emissions are fragmentary or abbreviated
whistle contours. The similarity of the three phonations sug-
gests that a “signature” may be present in the whistle of indi-
viduals of this species. The literature on vocalizations by this
species is summarized.

INTRODUCTION

Sounds produced by the cosmopolitan Risso’s dolphin, Grampus
griseus, have only briefly been mentioned in the ever-growing literature
on cetacean vocalizations. Schevill and Watkins (1962) and Tavolga
(1968) included data and sonagrams from recordings of both pulse
trains and whistles made by this species at sea off Delaware. Under
these conditions, size and sex of the emitter are rarely known. Without
sonagrams, Norris (1964) elaborated on some of the clicks produced
by the animals reported upon by Schevill and Watkins. Watkins (1967)
discussed pulse trains made by other Grampus at sea off New Jersey,
and included sonagrams. Poulter (1968), without sonagrams, cited
unpublished recordings apparently made in the wild, and noted that
this species makes a variety of sounds.

Hashimoto and Maniwa (1967) mentioned recordings made of
Grampus in Japan that had a wide frequency range, but those writers
did not note the kinds of sounds or whether or not the recordings were
made at sea or in captivity.

Evans (1967) noted that a captive Risso’s dolphin from the
Pacific coast of Mexico had been successfully recorded by T. Waller
of the U.S. Bureau of Commercial Fisheries, but no details or sona-
grams of the sounds were given. The Caldwells attempted to record
this same captive animal, an adult male that had stranded two weeks
before and lived only a short time at Sea World in San Diego,
California. No whistles were obtained.

252

Sounds from Dolphin 25)3)

OBSERVATIONS

Two subadult males that we attempted to record at Marineland of
Florida were part of a group of two males and two females that stranded
near there in early 1966. Although we did not attempt to record any
of these animals until the end of that year, it is our understanding that
several attempts had been made previously, but that because of the
presence of several Atlantic bottlenosed dolphins (Tursiops truncatus)
and at least one spotted dolphin (Stenella plagiodon), it was impossible
to ascertain which phonations, if any, had been emitted by the Grampus.

The Caldwells had the same problem in late 1966 when only the
two males remained alive. Further attempts were continued intermit-
tently, but with the addition to the community tank of eastern Pacific
pilot whales (Globicephala scammoni) from time to time and a Pacific
whitesided dolphin (Lagenorhynchus obliquidens) for most of the time,
the problem of matching phonations with emitters has been com-
pounded. In acommunity of such complex composition, positive identi-
fication would necessitate a concurrent phonation and release of air
bubbles from the blowhole of a particular animal. We observed this
on one occasion, but we were not recording at the time. This obser-
vation indicates that the males are capable of producing a presumably
harmonic whistle. On this occasion the larger male Grampus, after
about 2.5 years in captivity, was rapidly chasing a large adult male
Tursiops in the community tank. A clear loud whistle of very long

ides

Sipe

PES ‘Pian

Figure 1. Captive subadult male Grampus griseus (MLF 156). (Photograph cour-
tesy Marineland of Florida).

FREQ. (kHz)

254 Bulletin So. Calif. Academy of Sciences

duration (estimated to be at least one full second in duration) was
heard, and it could be correlated fully with a stream of air bubbles
flowing from the blowhole of the Grampus as it traversed the entire
width of the 75-foot tank. Other whistles apparently were produced
by the Grampus on this and other occasions, but the fact that he pro-
duced them was not established.

However, over a period of some 18 months, we had many occasions
to record each of the males in air when we have been sure that any
sounds recorded were their own. These instances included lowering of
the tank and stranding the animals for venipuncture, medication and/or
dentistry, and twice for transferring the smaller of the two animals
(MLF 156, 280 cm from tip of upper jaw to fluke notch, Fig. 1) to a
different tank. Although such treatment almost always elicits whistling
by most other delphinid species with which we have worked, never did
the small male emit any sound, and on only one occasion did the larger
male (MLF 155, 296 cm) do so. This occurred when the tank was

lowered at night and the animal was stranded for venipuncture. As he

was being bled, he emitted three, short, narrow-band emissions in close
succession 0.85 and 1.10 seconds between the end of one and the start
of the next. The last two of the three are pictured in Figure 2. The pri-
mary energy of each emission was from about 3.5 to 4.5 kHz, and the
emissions lasted about 0.25 to 0.38 seconds. While slightly longer in
duration (0.03 second longer), the contour of the third emission was

0 02 04 06 O08 0 2 14 6 te. oa

TIME (SEC.)

Figure 2. Phonations of Grampus griseus. Narrow-band sound emissions by a
captive subadult male (MLF 155) at night on 12 December 1968, while stranded
and during venipuncture. Effective filter bandwidth 300 Hz. (Photograph courtesy
Marineland of Florida).

|

Sounds from Dolphin DSS)

almost a duplicate of the first, and although the contours of these and
that of the second are not exactly the same, even with such a small
sample the upper portions containing the bulk of the energy are similar
enough to suggest a “signature” in the whistle for individuals of this
species.

It should be noted, however, that the three emissions are much more
abbreviated than our own subjective experience with the whistle of
this individual has shown. Thus the possibility should be considered
that these recordings could more properly be categorized as “chirps”
(Dreher, 1966), which we consider to represent only a fragmentary
whistle contour that under the conditions of this recording was termi-
nated prematurely by the animal under stress. The recordings of Gram-
pus whistles made in the wild, noted above as being depicted by Schevill
and Watkins (1962) and Tavolga (1968), generally appear to be in-
complete on their sonagrams, apparently running beyond the bound-
aries of the recording paper. Even if this is not the actual case, they
represent whistles that are at least twice as long in duration as the one
of the shortest duration that we recorded from our animal. The shortest
from the wild is still one-third longer than our longest recorded emis-
sion. Consequently these data tend to corroborate our belief that com-
plete Grampus whistles are usually longer in duration than the ones
0.25 to 0.38 seconds that we recorded and that ours therefore may well
be abbreviated or incomplete emissions.

SOUND EQUIPMENT

All of the recordings discussed in this paper were made at a tape speed
of 7.5 inches (19 cm) per second with a Uher 4000 Report-L recorder,
which at that tape speed had a frequency response of 40 to 20,000 Hz.
Sound spectrograms (sonagrams) were prepared on a Kay Sona-Graph
model 662A Sound Spectrograph Analyzer calibrated in two sections
from 85 to 12,000 Hz.

ACKNOWLEDGMENTS

Financial support for certain phases of this work came from the National Science
Foundation (grant no. GB-1189), the Office of Naval Research (contract no.
N00014-67-C-0358), and Marine Studios, Inc. The photographs are by William
A. Huck.

LITERATURE CITED

DREHER, J. J., 1966. Cetacean communication: small-group experiment. /n K. S.
Norris, editor, Whales, dolphins, and porpoises. Berkeley: Univ. California
Press, p. 529-543.

256 Bulletin So. Calif. Academy of Sciences

Evans, W. E., 1967. Vocalization among marine mammals. In W. N. Tavolga,
editor, Marine bio-acoustics. New York: Pergamon Press, 2: 159-186.

HASHIMOTO, T. AND Y. MANIWA, 1967. Research on the luring of fish shoals by
utilizing underwater acoustical equipment. Jn W. N. Tavolga, editor, Marine
bio-acoustics. New York: Pergamon Press, 2: 93-104.

Norris, K. S., 1964. Some problems of echolocation in cetaceans. In W. N. Tav-
olga, editor, Marine bio-acoustics. New York: Pergamon Press, 1: 317-336.

POULTER, T. C., 1968. Marine mammals. In T. A. Sebeok, editor, Animal com-
munication; techniques of study and results of research. Bloomington:
Indiana Univ. Press, p. 405-465.

SCHEVILL, W. E., AND W. A. WATKINS, 1962. Whale and porpoise voices. Woods
Hole Oceanographic Institution, phonograph record and 24-page booklet.

TavoLca, W. N. 1968. Marine animal data atlas. Technical Report: NAVTRA-
DEVCEN 1212-2, Naval Training Device Center, Orlando, Florida. 239 p.

WATKINS, W. A., 1967. The harmonic interval: fact or artifact in spectral
analysis of pulse trains. Jn W. N. Tavolga, editor, Marine bio-acoustics. New
York: Pergamon Press, 2: 15-43.

Accepted for publication October 8, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 257-259, 1969
RESEARCH NOTES

A RECORD OF THE ENTONISCID PARASITE,
PORTUNION CONFORMIS MUSCATINE
(CRUSTACEA: ISOPODA), INFECTING TWO
SPECIES OF HEMIGRA PSUS

A parasite closely related to the genus Portunion Giard and Bonnier
is mentioned by Light, et al. (1954) infecting Hemigrapsus oregonensis.
Muscatine (1956) described this parasite, Portunion conformis, and
increased the number of species in the genus to six.

During the summer of 1968, while at the Bodega Bay Marine Labo-
ratory, I noticed a parasite infecting the hepatic tissue of Hemigrapsus
nudus. Comparison with P. conformis found in H. oregonensis showed
the parasites to be the same. I collected 122 specimens each of H. ore-
gonensis and H. nudus from intertidal rocks 600 m south of the entrance
gate to the Bodega Bay Marine Laboratory. A paved road runs along
the shore above the splash zone. H. nudus were found closer to the
road than H. oregonensis, but there was no distinct border between
the two populations. The sex ratio in the sample of H. nudus was 76
male: 46 female and in H. oregonensis was 98 male: 24 female. Two
gravid females of H. oregonensis were found and none of H. nudus.

The carapace width of all crabs was measured to determine the size
distribution of the infected crabs. Female parasites were preserved in
10 per cent formalin. Male parasites were mounted on slides in CMC 10
medium. The data on infected crabs, summarized in Hubbs’ diagrams
(Hubbs and Perlmutter, 1942), were tested by Chi Square.

H. nudus

H. oregonensis
at 7 15 T6 17 18 T9 ZONZaL De D2 AY 25 2S 27 BX 2s) SO iw
Figure 1. Carapace width of infected crabs.

ZT

258 Bulletin So. Calif. Academy of Sciences

Many stages of development of the female parasite were observed.
The appendages of the female increase in size and complexity with
increasing maturity. Two male parasites were observed on the appen-
dages of the female parasites.

Forty-five Portunion conformis were found in the 244 crabs
examined. Nineteen per cent of the crabs were infected with more than
one parasite and these crabs averaged five mm wider than the animals
with only one parasite. Table 1 shows the frequency of infection for
the two species and Figure 1 compares the populations of infected
animals of each species.

The two crab populations are sympatric in the area in which they
were collected and therefore subject to the same invading parasites.
That no significant difference exists in the rate of infection between
the two host species is to be expected because of the close association
of the two populations.

Infection of the crabs is probably related to the age of the animals.
The smaller crabs had fewer well developed parasites, and the larger
crabs frequently had more than one parasite. The parasites in crabs
with multiple infections were not all at the same stage of maturity,
indicating the crabs are infected at various times during their lives.

ACKNOWLEDGMENTS

I am indebted to the staff of the Bodega Bay Marine Station for assistance in
locating specimens for this study. I wish to thank Dr. Henry E. Childs, Jr. for
the many hours spent giving me much needed assistance.

TABLE |
FREQUENCY OF INFECTION BY P. conformis

Per Cent Total
Infected Infected Examined

H. nudus DD) 18.0 122
Males 12 Sed 76
Females 10 Diieeii 46
H. oregonensis 15 12.3 122
Males 12 12.2 8
Females 3 12.5 24

Parasitic Isopods 259

LITERATURE CITED

Huss, C. L., AND A. PERLMUTTER, 1942. Biometric comparison of several sam-
ples, with particular reference to racial investigations. Am. Natur. 76: 582-
592.

Ligut, S. F., et. al. 1954. Intertidal Invertebrates of the Central California Coast.
Univ. Calif. Press, Berkeley, Calif. 446 p.

MUSCATINE, L. 1956. A new entoniscid (Crustacea: Isopoda) from the Pacific
Coast. J. Wash. Acad. Sci. 46: 122-126.

Fred M. Piltz, University of California, Bodega Bay, and University of
California, Irvine

Accepted for publication September 18, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 260-261, 1969

SURVIVAL OF WEEVILS THROUGH THE DIGESTIVE
TRACT OF AN AMPHIBIAN

A newly caught western toad, Bufo boreas Baird and Girard, defecate
nine bill bugs, Sphenophorus phoeniciensis Chitt, of which seven wer
alive. When the seven weevils were subsequently placed in a closec
container, they were dead within two days.

To test survival in the gut, 27 weevils of the same species were fe
to five B. boreas; ten weevils were passed through the toads alive. Thes
ten were then placed in a chamber in which the humidity exceeded 91
per cent; at all times the temperature was between 22 to 26°C.; in tw
days, four of the ten weevils had died. No further deaths occurre:
during the next 14 days. The six surviving weevils were then placed i
a less humid environment (39-43 per cent R. H.). They all died withi
four days. As a control, 12 weevils which had not been passed throug:
a toad were placed in a high humidity (above 90 per cent) for a perio
of 14 days; all survived. Twelve similar weevils placed in a lowere
humidity of 39-43 per cent were dead within five days. The lowere
humidity induced the death; death was not due to starvation as contrc
weevils survived unfed for more than 30 days. All weevils which passe:
through the toads, whether dead or alive, had intact appendages. How
ever, some of the survivors exhibited reduced activity. The wax epi
cuticle might have been damaged or removed. This removal woul
probably increase water loss from the animal and account for it
reduced survival at low humidities.

Bill bugs are generally found at the base of grasses where the humidit
is high. The high humidity would be conducive to survival by reducin
the rate of water loss during epicuticle resynthesis. B. boreas is ofte
associated with areas of plentiful moisture such as the soil at the bas
of plants and grasses. Therefore, ability of the weevil to withstan
predation by an animal with which contact is prevalent would be signif
cant in survival.

Twelve of the bill bugs were fed to three great plains toads, Buf
cognatus Say. Nine were dead after passage through the toads an:
three of them had lost limbs or were otherwise disarticulated. Th
reduced survival may suggest that B. cognatus may posses different c
stronger enzymes than B. boreas. The effect on survival by the amour
of food in the gut or the amount of time for passage through, the gut 1
not known; further investigation is obviously necessary.

The weevil is capable of flight and dispersal is most probabl
achieved through this mode. However, the interstate transport of anu
rans for purposes of research is not an infrequent occurrence. There

260

Survival of Weevils 261

fore, survival of the weevils through the digestive tract of a predator
has both survival value and possibly aides, though perhaps precari-
ously, the dispersal of the species.

ACKNOWLEDGMENTS

I am greatly indebted to Drs. Bayard H. Brattstrom and Phillip A. Adams for
their helpful suggestions and Dr. Elbert L. Sleeper for identification of the
weevils.

Jay W. Fair, Department of Biology, California State College, Fuller-
ton, California, 92631.

Accepted for publication March 20, 1969.

Bull. So. Calif. Acad. Sci. 68(4): 262-263, 1969

SCIENTIFIC NEWS AND COMMENTS
Santa Barbara Oil Leak

Because of the national and international interest generated by the
Santa Barbara oil spill during the winter of 1969, the Board of Directors
of the Academy requested Mr. John Fitch of the California Department
of Fish and Game to compile a list of the funded scientific research
projects involved in this event. In addition, many individuals are known
to be conducting research, which are not funded, on some aspect of
this oil leak. If the readers are aware of additional studies or they wish
to include additional information on the Santa Barbara oil leak, please
contact the Editor.

Allan Hancock Foundation, University of Southern California, “Bio-
logical and Oceanographic Effects of Oil Spillage in the Santa Barbara
Channel Following the 1969 Blowout,” Dale M. Straughan, Principal
Investigator, Western Oil and Gas Association, $220,000, | year.

University of California, Santa Barbara, “Microwave Radiometric
Measurements of Oil Slicks,” N. K. Sanders, Principal Investigator,
National Science Foundation, $36,424 first year’s budget.

University of California, Santa Barbara, “Investigation of Seismisity
and Earthquake Hazards in the Santa Barbara Channel, “Jan D. Riet-
man, Principal Investigator, National Science Foundation, $33,000,
first year’s budget.

University of California, Santa Barbara, “Fishes of the Kelp Beds,”
Al Ebeling, Principal Investigator, National Science Foundation,
$16,648, first year’s budget.

University of California, Santa Barbara, “Chemical Determination of
Pollutant Tars,’ Don D. Runnels, Principal Investigator, National
Science Foundation, $11,892 first year’s budget.

University of California, Santa Barbara, “Effects and Implications of
Petrol Pollutants on the Resources of the Santa Barbara Channel,”
Paul G. Mikolai, Principal Investigator, National Science Foundation,
$9,000 first year’s budget.

University of California, Santa Barbara, “Intertidal Survey,” Michael
Neushul, Principal Investigator, Federal Water Pollution Control
Administration, $7,000, 1 year.

University of California, Santa Barbara, “Initial Survey of the Affected
Area,” Al Ebeling, Principal Investigator, Federal Water Pollution
Control Administration, approximately $2,500, 1 year.

262

Scientific News and Comments 263

Battelle Memorial Institute, “Summation of the Santa Barbara Oil
Leak,” Contact David DesVoigne or Roy Nakatani for further infor-
mation.

HONORARY LIFE MEMBERSHIP

The Board of Directors of the Academy voted to confer an honorary
life membership to Mrs. Dorothy E. Martin in recognition of her
service to the Academy as librarian.

ANNUAL MEETING, 1970

The Board of Directors of the Academy accepted the invitation of Cali-
fornia State Polytechnic College at Pomona to hold its annual meeting
there on May 16, 1970. Vernon L. Gregory will serve as the local
chairman.

Scientific news or comments which are of interest to the readers of the
Bulletin may be included in this section by contacting the Editor. Please
allow a lead time of three to four months.

SOUTHERN CALIFORNIA ACADEMY OF SCIENCES
VOLUME 68, 1969

SUBJECT AND AUTHOR INDEX

Acarina, new species ... 36, 59, 138,
NDR atte Sen cd eaahtond let Ores 160, 187, 225

A comparison of the free amino
acids in two populations of the
polychaetous annelid Neanthes

SWIGCH WEG sdcte nese icosoe ue eee aio ceet ost 43
Allis alee aee ie ce Wan on cee ee 72, 199
Amastridium veliferum ........ 145
Amelogenesis in the trigger-fish

Biallits tGarey paused eunllee ecdeaey tee anlar 64
AIIM ORACIC Sie eee 43
PNMNO ONE, 666606 5005000% 219, 260

beh aviOmen ay aes oceans aioe 10

LOSS Ieee de eek eet tne lthonnieeacaens 121

ME WASDECICSEE IAI ane res ee 121
Amiphipoday 7s). wis 28 oan es ee l

An ecological study of the poly-
chaetous annelids associated with
fouling material in Los Angeles
Harbor with special reference to
POlUtOneA eee 169

A new species of Hannemania
(Acarina, Trombiculidae) from
Bufo punctatus of western North
America, with comments on
Hannemania hylae (Ewing) ... 160

A new species of Hexidionis (Aca-
rina, Trombiculidae) from kan-
garoo rats (Genus Dipodomys)
of western North America .... 225

A new species of Odontacarus
Ewing (Acarina: Trombiculidae)
from lizards of Baja California
SUDMICXI COMP ae eee 187

A new species of Speleocola (Aca-
rina: Trombiculidae), off a bat,
Pizonyx vivesi, from Baja Cali-
LOTMA VICXICON nen 36

Animal behavior .......... 131, 191

Another new species of Speleocola
Lipovsky (Acarina: Trombiculi-
dae) off Chiropternas from So-
MOlase MCX COR se ane ae 59

AT CHICO Cea ane 19, 103

A record of the entoniscid parasite,
Portunion conformis Muscatine

(Crustacea: Isopoda) infecting
two species of Hemigrapsus ... 257
A review of the colubrid snake
genus Amastridium ......... 145
A second record of the slender
mola, Ranzania laevis (Pennant),

from California ............. 115
A western yellov, bat in Los Angeles

County, California .......... 194
Banta, WieG ojo. eee 30, 96, 248
Barnard) Jie oc A eee 1

Biographical relationships of the
Salton Sea amphipod, Gammarus

MUCKONALUS Say... sane l
Brach; Viol ic.. 5 ee 119
Brachiopoda, fossil ............. 90
Bry.OZ0a.) ) asin. ape 199, 248

fOSSil) 2000. tok Sa ee 30

MC WASDECIES) uy ae ener 20, 96
Bryozoan-algal associations in

southern California waters .... 199
BufoyDOneas 3405 eee 10
BRO DIUVGLALUS | i eee eee 160
BullivantJeS) 3) 3 ee eee 86
Caldwell, D. K........ 112, 113, 252
CaldwellAMaGs = 3)... DSD
GentralyAmenica) =) ae 145
Gheloniarmydas \- eee 113
Chondnrichthyes 7-34 aaa 131
Coleoptera... 3. ae 260

NEWaeeNUSs are 244

MNEWASPECIES) a a eee 241, 245
Comstocks J: A. i. ee eee 54
Crane, JME JT...) eee 193
Crippen ReiWee noe 169
DailleyaMe Da) eee 82
Decapoda... 45.2 sat eee ee 19
Diaperoecia californica ......... 86
Dioptrophorus fausti .......... 242

Distribution and development of
mysids (Crustacea, Mysidacea)
from the Arctic Ocean and con-
MWENtSCAST ene eee 103

DOLE hE | Seis knee eee ed 10

Dudresnaya colombiana ......... U2
ECOISOMIam te ee es 123
PeCwterensiS..). 2 ss. Ba. ees 125
CUA OWUPREE ocr.) shee es Ae 219
PrdnianeD yO bc ee 112

Evidence of celestial orientation
by California toads (Bufo boreas)

during breeding migration ..... 10
iPtaire, J. MVS s 5 eg anes eae 260
Fishia evelina hanhami ......... 54
FRG n., US IER Sc cee ee 115
Foraminifera, fossil ............ 89

Further evidence of close relation-
ship of the trematopsid and dis-
sorophid labyrinthodont amphib-
ians with a description of a new

genus and new species ........ 121
Gammarus mucronatus .......... 1
GEIS BRee yen Sas 103
(GRATHDUSSOTISCUS) 2s is 32 2k 8s 252
(Gren \W/s Siesa: 5 ee 1
Gaulirol Califomia) . =. 5252552 525. 30
Hannemania bufonis .......... 161
[Ely UWE 5-355 6 eee 164

Hatchling green sea turtles, Che-
lonia mydas, at sea in the north-

eastern Pacific Ocean ........ 113
FAG ENS AED nen ae eo bis 19
PA AWAITS tones 2 Di as aS 229
Hemigrapsus nudus ........... 25) Tf
HARMON CLOMETISISI® oi. 0. ssi se a Fs 257
Hexidionis harveyi ............ 225
Hymenodora glacialis .......... 19
Fy imeCnOptchal ee sits 5 =.= csess etic S7
Hydroides crucigera ........... 232
PSO POC AMR tes so ens oe ses 21
NGhnsONnswRete sok. Pe 131
Lasiurus ega xanthinus ......... 194
Lepidochelys olivacea .......... 112
Lepidoptera, life history ......... 54
WMeuresthes tenuis... . 665+... 191
Loomis, R. B. .. . 36, 59, 160, 187, 225
MEIC USS ep lone aie ek ccc aes b-3 225
‘LSAPIGL TE, Isa DS ee ea ee ae ma 219

Mammalia =.) ee 119, 194
behavior een see Se oites 252
Mearns Ae decries eco Fe 43
Membranipora membranacea ... 201
Miivillosdaiss tone eae sone 202
MEXICODSE Serene oe aces sie ior 59
Meyer is Rein: 2 aphasia 145
Miller Jishi= sete ae icc 252
Molluscas:fossily ys: suet ts a: 87
Mowers Any sieges ce oes ete s ore 72
Mivysidacealian Ge ee ae eet 103
Neanthes succinea ............. 43
Nelson IDE Rie cee gas 131
INewellleales Mee ie ace oe 138
INewacenchar es eee eee 123, 244
New neotropical Curculionidae
(Coleoptera) ote eee 241
New records of marine algae from
southern California........... 2

New species 30, 36, 125, 140, 161, 187,
Res Ore iN ee eae (ioe c 225, 241, 245

Notes on the life history of Fishia
evelina hanhami (Lepidoptera) . 54

Notiosorex crawfordi .......... 119
Odontacarus robbinsi .......... 187
Osteichthyesse ee er ee 115
behavionn: cents, ee ee 191
LOCUS eis eh ey ee eed ee 64
Ostracodastossil nee eee 89

Pacific Ridley sea turtle, Lepido-
chelys olivacea in Puerto Rico . 112

Permian tossilsise eee eee 121
PaltzsB Mier Ste ice oe 257
Pimeliaphilus zeledoni......... 140

Pimeliaphilus zeledonin. sp. (Acari,
Pterygosomidae), a parasite of
Triatoma dimidiata (Latr.)

(Hemiptera, Reduviidae) ..... 138
Pinter Bee aise ee ye earn 199
Pissodes zitacuarense ......... 241
RIeistocene tOSsi|Seaee eee 86
Portunion conformis ........... 257
Rollitionswatehes eee 169
Polychactay se eee eee 229

AMINO acidSyy se ee eee 43

ECOlOBYses er Seer ieee 169
Pseudohyla nigrogrisea ......... 219
IRGAZANIGLACVISISEe ae 115

265

ReisheiDs Juss Srewae oe ers 43, 169

Reptilia ne WA, 3s, NAS

Response in Bahamian sharks and
groupers to low-frequency,

pulsedssounds#= nano eee 131
RorkeWisletscins a, cera eRe 19
Rey cksnmannts Reve Wr cicy secs qeegen tees 138
Saltomn¥Seauagorce i sens eee ree 1, 43
Sandrarhyncolus ............. 244
SAUD IUS Re oe OP ROS
Serpulidae (Annelida: Polychaeta)

from"iOahuws kaw alite wee 229
SleepenvE Slew friars eee 241
Snelling, ResRey nn) eee 57/

Some observations on a captive
desert whrew, Notiosorex craw-

ELON ey ee oe eR 119
Soule, JD sie. ache eet ee ee: 64
Spathe le 2. ee pen eit fer gee 187
Speleocola davisi .............. 59
SCO NECTAR oes eae 36
SPOLOGHIDUSIADOGUSHA Ee eee WS
StewandiG@Ree Ay ieee er 194
Stictodora ubelakeria .......... 82

Stictodora ubelakeria a new species
of heterophyid trematode from
the California sea lion (Zalophus
CAlifOnniGnis) ee ee 82
Straw chants D enn elo,
Survival of weevils through the
digestive tract of an amphibian . 260

i EtoUd oWeerartre' sauces Whehen Cuniara ree Ear ate 64

The bathhouse beach assemblage~. . 86

The identity of the frog, Pseudohyla
nigrogrisea of Ecuador ....... 219

The recent introduction of Watersi-
pora arcuata Banta (Bryozoa,
Cheilostomata) as a fouling pest

in southern California ........ 248
The response of male grunion to a
Wil Solin Sas tiCKe ea 191

Three brief narrow-band sound
emissions by a captive male
Risso’s dolphin, Grampus griseus

ETP RES as Gory G0 8 4 o DS
hinOGladiGuerassah I
Pracy, Co Resin eee 10
Trematoda, new species ......... 82
iriatomadimidiatd ae 138
Uscial cies 2 eee 30
mexicana 9.0... 35 Se eee 30

Uscia mexicana, new genus, new
species, a watersiporid bryozoan

with dimorphic autozoids ...... 30
Vaughn;P: iP. sae 121
Vermilliopsis torquata ......... 234
Waldrop: LiiG: 24 131
Watersipora arcuata ............ 96
W.., GV CUA. yn 3 ee 248

Watersipora arcuata, a new species

in the subovoidea-cucullata-

nigra complex (Bryozoa, Cheilo-

stomata)o.2). 222 eee 96
Webb; J.P; Jr eee 36, 59
Welbourn We G2 ieee 160
Widdowson} Ii Bia eae 2
Wilson, LDDs...) see eee 145
Zalophus californianus .......... 82

266

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MuLLETIN OF THE
? Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

_ VOL. 69 JANUARY-MARCH 1970 Part 1

CONTENTS

The Hylaeus of the Bonin Islands, Western Pacific Ocean (Hymen-
optera: Colletidae). Roy R. Snelling

Trace fossils of Trilobites from the Deadwood Formation (Upper
Cambrian) of Western South Dakota. George Callison

Epicaridea (Isopoda) of Hawaii. Charles G. Danforth

A small collection of Chiggers from Surinam (Acarina: Trombicu-
lidae). James M. Brennan

New Myrmecinae (Coleoptera: Curculionidae). Elbert L. Sleeper 38

Communication systems and organizational systems in three species
_ of rodents. George F. Fisler

A new subgenus and two new species of Hexidionis (Acarina, Trom-
biculidae) from North America. Richard B. Loomis and James
L. Lucas

Sexual differences in foraging behavior of white-headed woodpeck- t
ers. Robert Koch, Armand E. Courchesne and Charles T. Col-

Marcu 31, 1970

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BwweetiIN OF THE SOUTHERN CAEIFORNIA
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Vol. 69 JANUARY-MARCH No. 1

Bull. So. Calif. Acad. Sci. 69(1): 1-19, 1970

THE HYLAEUS OF THE BONIN ISLANDS,
WESTERN PACIFIC OCEAN
(Hymenoptera Colletidae)

Roy R. SNELLING
Entomology Section
Los Angeles County Museum of Natural History
Los Angeles, California 90007

ABSTRACT: Four species of Hylaeus are known to occur on
the Bonin Islands: H. (Paraprosopis) yasumatsui, n. sp., H.
ikedai (Yasumatsu), H. (Nesoprosopis) boninensis Yasumatsu
and H. incomitatus, n. sp. These bees appear to represent a
relict fauna with relationships from the Palearctic, Micro-
nesian and Oriental Regions. The zoogeographic peculiarities
of each species are discussed. All species are described and
illustrated in detail and a key for their separation is provided.

INTRODUCTION

The Bonin Islands are an archipelago representing the peaks of the
vast submarine volcanic ridge extending from Tokyo Bay in the
north to Guam in the south. They lie between 142° 08’ and 142° 12’
E and 26° 30’ and 27° 50’ N. The 97 islands and islets comprising
the Bonin Islands are divided into three discrete groups, from north
to south: the Muko Jima group, the Chichi Jima group and the Haha
Jima group. The combined land area for all the islands is but 72 square
kilometers.

The Bonin Islands are the northernmost of the Micronesian islands
and are drier than most parts of Micronesia. Warm temperatures
during the winter months are maintained through the influence of the
Kuroshio Current; average monthly temperatures range from 62° F
in January and February to 80° F in August. There is no pronounced
wet or dry season, but heaviest rainfall occurs in December, January

l

2 Bulletin So. Calif. Academy of Sciences

and March to August, with an average seasonal total of about 61
inches. The original vegetation was “subtropical jungle” (Gressitt,
1954).

Dr. Karl V. Krombein (1949, 1950) initiated a study of the Aculeate .
Hymenoptera of Micronesia and has amassed material from a number
of institutions. The Bonin Islands Hylaeus have been turned over to
me by Dr. Krombein and I wish to express my appreciation of his
generous cooperation. The material loaned for study included speci-
mens from the Bishop Museum, California Academy of Sciences and
Kyushu University. This has been supplemented by four specimens
in the Los Angeles County Museum of Natural History.

The figures accompanying this paper were prepared by Ruth Ann
DeNicola to whom I am grateful.

Two species of Hylaeus have been previously described; H. ikedai
(Yasumatsu, 1936) and H. boninensis Yasumatsu, 1955, both from
females. In the material now available there are four species, including
Yasumatsu’s species. The earlier described species are represented
by both sexes and I have described the males of these for the first time.
The two additional species are both new and are described below.

ZOOGEOGRAPHY

The Bonin Island insect fauna is a heterogenous assemblage with
endemic elements reflecting both Oriental and Micropolynesian rela-
tionships. There are also elements of clearly Palearctic origin, repre-
senting probable comparatively recent introductions from Japan. A
survey of the Bonin Islands floral and faunal relationships indicates
that “...the Bonins are more properly placed with Micronesia than
with the Palearctic Region or the Indo-Chinese or Malayan Subregions
of the Oriental Region.” (Gressitt, 1954)

The four species of Hylaeus presently known from the Bonin Islands
also reflect the heterogenous composition of this fauna. These species
do not show any close relationship to each other and two species (H.
incomitatus and H. ikedai) cannot now be placed in existing subgenera.
One of these, H. ikedai, is evidently related to a Japanese species. The
Hawaiian subgenus Nesoprosopis is represented on the Bonin Islands
by H. boninensis. This species, however, does not seem to belong to
any of the existing Hawaiian species groups. The Palearctic influence
is represented in H. yasumatsui, n. sp., a member of the Holarctic
subgenus Paraprosopis. This species is most intriguing from a zoo-
geographical viewpoint since it is not, apparently, related to any of
the Paraprosopis of Japan. The male terminalia are similar to those

Bees from Pacific Ocean 3

of a zoogeographically peculiar group including two Nearctic species,
H. calvus (Metz) and H. georgicus (Cockerell), and one Palearctic
species, H. ater (Saunders). This apparent relationship is borne out

morphological characters of the females. One species, H. incomi-
atus, 1s wholly enigmatic since it does not seem to be related to any
species or species groups known to me. This species is known from a
single female and, until the male is known, it is difficult to speculate
on its affinities. There is some indication that this species may be
related to H. meridianus Yasumatsu and Hirashima of the Ryukyu
Islands.

The Hylaeus fauna of the Bonin Islands may be a relict one. The
now largely Hawaiian Nesoprosopis possibly at one time occurred
over much of Micronesia but would appear to have been replaced,
through introduction, with other forms, and now survives at the extreme
poles of Micronesia. The subgenus Paraprosopis, a temperate Holarctic
group, is a primitive one and H. yasumatsui may be a survivor of a
once very extensively distributed group. The group represented by
H. ikedai and H. gnathylaeoides Bridwell (Japan) may be an endemic
one, locally evolved, but I suspect that its affinities may prove to be
Oriental.

In the descriptions which follow I have used code abbreviations
for some facial measurements. Some of the coded figures are given in
millimeters; others in unspecified units. The latter are microscope
objective units. Since the ratios involved are my major concern, I have
elected to use this system rather than millimeters. Different measuring
devices for microscopes will still yield the same ratios.

KEY TO CODED ABBREVIATIONS

ASD. Antennal Socket Diameter. The maximum measurable diameter, between
socket rims, in full face view (=“e” of Hurd and Moure, 1963, fig. 50).

BCW. Basal Clypeal Width. The maximum measurable width of the clypeal base,
between the subantennal sutures.

CAD. Clypeo-Antennal! Distance. The shortest distance between the juncture of
the clypeal and subantennal sutures and the rim of the antennal socket (=“y”
of Hurd and Moure, 1963, fig. 49).

COD. Clypeo-Ocular Distance. Measured from latero-basal clypeal angle and
nearest point on margin of compound eye.

HL. Head Length. In full frontal view, the distance from the uppermost part of
Visible occiput to clypeal apex, along midline.

HW. Head Width. In full frontal view, the maximum measurable head width,
including the eyes.

4 Bulletin So. Calif. Academy of Sciences

IAD. Inter-Antennal Distance. The least distance between the rims of the anten-
nal sockets (=“a@” of Hurd and Moure, 1963, fig. 50).

IOD. Inter-Ocellar Distance. The least distance between the inner margins of the
lateral (or posterior) ocelli (=“a@” of Hurd and Moure, 1963, fig. 50).

OD. Ocellar Diameter. Maximum diameter of middle (or anterior) ocellus as
seen in full frontal view (=“e” of Hurd and Moure, 1963, fig. 50).

OOD. Ocellar-Ocular Distance. Least distance between outer margin of lateral
(or posterior) ocelli and inner margin of compound eye (=“@” of Hurd and
Moure, 1963, fig. 50).

KEY TO SPECIES

1) Males, antennae with thinteeniseomicnts 25-5 45 eee 2,
Females; antennae with twelvescsments 32) 9 ieee 4

2. Scape greatly broadened and flattened, much broader than long,
with a deep transverse channel behind; third sternite with a large,
glabrous tubercule on middle of disc; fourth sternite with a low,
shining, arcuate tubercule basally; basal area of propodeum
about twice as long as metanotum in middle, roughened basally,
with sparse, irregular, longitudinal rugulae which do not reach
Ceclivityirs jceeak Fs ea Sear tiie hae epreie erieee aeae ikedai Yasumatsu

Scape as long as broad, or longer, not transversely channeled be-
hind; third and fourth sternites simple; basal area of propodeum
not as described’ above: <... 404.005. bs se So ee 3

3. Scape swollen, no longer than broad; thorax with abundant erect
fulvous pubescence; basal area of propodeum strongly sloping,
continuous with posterior face, basal triangle shiny, with a few
coarse irregular rugulae; pronotal collar largely yellow........

SOE LS ROR oh Ne le ic aay eT Nee ca eae boninensis Yasumatsu

Scape about twice as long as broad; thoracic pubescence sparse,
whitish, that of mesoscutum reclinate; basal area of propodeum
on thoracic dorsum, rounded behind into declivity, basal triangle
slightly shiny, tesselate, with numerous irregular, anastomosing
rugulae; pronotal collar immaculate or with two widely separated
laterallispots. 25.) kee ee tne eae a ee yasumatsuli, N. sp.

4. Abdomen ferruginous, apically infuscated; axillae and scutellum
maculate; propodeal triangle shiny, tesselate, with very short
TU CUlActateExtnenne lO aS a waar aaa ar incomitatus, nN. sp.

Abdomen wholly dark except translucent tergal margins; axillae
immaculate (except H. boninensis); propodeal triangle variable . 5

Bees from Pacific Ocean 5

5. Axillae, anterolateral mark on scutum, pre-episternum, yellow;
thorax largely with abundant long, fulvous pubescence, that of
scutum short; basal triangle bare, contrasting with otherwise
densely pubescent propodeum; tibiae largely ferruginous; basal
triangle of propodeum shiny, largely smooth, with scattered
ihe CMATMUPUIAC . = ue ek ae tee boninensis Y asumatsu

Axillae, scutum and pre-episternum immaculate; thoracic pubes-
cence sparse, white, propodeum very sparsely pubescent; tibiae
with small basal yellow spot; basal triangle moderately shiny,
tesselate and roughened, with fine, irregular rugulae.......... 6

6. Mesopleura shiny, with distinct, deep punctures separated by a
puncture diameter or less; basal face of propodeum as long as
scutellum in middle, with fine divergent rugulae on basal two-
thirds; pronotal collar immaculate or with two widely separated
FALE RAIRS IOUS Err seek ie Sos Bins § A aus ae eee ee ikedai Yasumatsu

Mesopleura moderately shiny, finely tesselate, punctures fine,
often obscure, separated by more than a puncture diameter; basal
face of propodeum shorter, little longer than metanotum, with
fine, irregularly anastomosing rugulae over most of its area;
pronotal collar with a continuous transverse stripe, sometimes
imtesnupredemedially ..24..5....66.++-65.- yasumatsui, Nn. sp.

Hylaeus (Paraprosopis) yasumatsui, new species

Diagnosis: From other Bonin Islands species H. yasumatsui may be
separated by the black integument with yellow maculae, the densely
tesselate and finely, closely punctate mesopleura and the short basal
area of the propodeum. The male may be separated from that of H.
ikedai by the unmodified antennal scape.

MALE (Holotype): Measurements: HL=1.31 mm; HW=1.21
mm; antenna, scape to 2nd flagellar: 18:7:5:7; IAD=10; ASD=8;
CAD= 12; BCW= 13; COD= 12; OD=7; IOD= 14; OOD= 13;
wing length =3.7 mm; length, anterior ocellus to second tergite, 3.1
mm.

Head. Black, the following yellowish: irregular median longitudinal
stripe on clypeus; lateral face marks, filling area between eyes and
clypeus, terminating irregularly at level of middle of antennal sockets.
Mandibular apices ferruginous. Apical spot on first flagellar segment,
and entire underside of all succeeding segments, dull ferruginous.
Head a little broader than long, inner orbits rather strongly convergent
below, UFW 1.8 X LFW. Antennal scape stout, about 1.8 times longer

6 Bulletin So. Calif. Academy of Sciences

than greatest width, dorsal surface concave, shiny, Clypeus dull,
closely and finely tesselate, with fine punctures separated by twice or
more times a puncture diameter on disc, becoming coarser and
closer peripherally; maculate areas of face shiny, with sparse, fine
punctures. Supraclypeal area high, abruptly narrowed between anten-
nal sockets, rugulose, posterior face steeply sloping. Nonmaculate
areas of face slightly shiny, more so below, densely tesselate, punctures
a little coarser than on clypeus, punctures contiguous except below
where they are separated by about a puncture diameter. Genae, in
profile, about half as broad as eyes.

Thorax. Mesoscutum dull, finely and closely punctate, the punctures
separated by one-half or less a puncture diameter; scutellum flat,
slightly shiny, punctures in center distinctly larger than those of meso-
scutum, separated about a puncture diameter; metanotum dull, rugo-
sopunctate; pre-episternum and mesopleura slightly shiny, closely and
finely tesselate, with fine, obscure punctures separated by about one-
half to a full puncture diameter; metapleura duller than mesopleura, -
with a few obscure longitudinal rugulae, otherwise densely tesselate
and roughened with scattered fine punctures. Propodeal sides shiny,
with obscure punctures about equal to those of scutellum, separated
by one-half a puncture diameter or less; horizontal basal area a little
longer than metanotum, with numerous fine, anastomosing rugulae
basally, most of which fail to reach summit of declivity; oblique and
transverse carinae absent, lateral carina present, strong; declivitous
face and area of basal face between lateral carina and margins of basal
triangle slightly shiny, irregularly roughened and tesselate, but without
evident punctures. Black, the following yellowish: linear spots laterally
on pronotal collar, minute apical spot on fore femora, broad external
stripe on fore tibiae, minute basal spot on mid tibiae and short basal
stripe on hind tibiae. Wings hyaline, brownish, veins and stigma brown.

Abdomen. First tergite shiny, weakly tesselate, with scattered fine,
piligerous punctures; second tergite duller, more tesselate, with abun-
dant shallow piligerous punctures which are distinctly larger than
those of first segment; third to sixth tergites much as second, but
punctures more obscure; third and fourth sternites simple; sternites
weakly tesselate and shiny, with abundant coarse, piligerous punctures.
Terminalia: Fig. Ic-e.

Pilosity. Hairs sparse on head, those of face and genae whitish, those
of vertex and scape fulvous; some on scape as long as maximum scape
width. Erect hairs of thorax variable, with abundant short, fulvous
hairs, especially dorsally; longer, weakly barbed whitish hairs scattered
on dorsum, especially on scutellum and pleurae; propodeal sides and

Bees from Pacific Ocean 7

interior with abundant weakly plumose, suberect to erect, pubescence
which does not obscure surface. Abdomen with numerous long, simple
fulvous hairs, a little denser on tergal margins, appressed basally,
becoming more nearly erect caudad; ventrally with scattered reclinate
to erect whitish and fulvous hairs intermixed.

FEMALE (Allotype): Measurements: HL= 1.36 mm; HW = 1.49
mm; antenna, scape to 2nd flagellar, 25:9:7:6; IAD= 14; ASD=8;
CAD=7; BCW=21; COD=15; OD=8; IOD=14; OOD= 14;
wing length=4.3 mm; length, anterior ocellus to margin of second
tergite, 4.1 mm.

Head. Black, a short longitudinal median stripe on clypeus and
broad lateral face marks ending acutely at eye margin slightly above
level of upper margin of antennal sockets, yellowish. Head a little
broader than long, inner orbits convergent below, UFW 1.4 times
LFW. Mandibles broad, apically bidentate, apical tooth short, tri-
angular, inner margin of inner tooth oblique. Clypeus 1.15 times
longer than wide, slightly shiny, finely and closely tesselate, with
scattered fine, obscure punctures on disc, preapically with punctures
coarser and closer; apical margin distinctly emarginate, the emargina-
tion weakly angulate. Maculate areas of sides of face and lower face
of supraclypeal area finely and closely tesselate, slightly shiny, with
fine obscure punctures, mostly separated by a puncture diameter or
more. Nonmaculate areas of face more coarsely, subcontiguously
punctate, interspaces dull, densely tesselate, especially on frons; vertex,
between eyes and ocelli, a little more shiny, punctures sparse; occipital
area moderately shiny, punctures finer than those of frons, separated
by about half a puncture diameter. Genae, in profile, a little narrower
than eyes, slightly shiny, finely longitudinally striolate, with sparse,
fine, obscure punctures. Facial foveae above curved away from eye
margin, ending about midway between eyes and ocelli.

Thorax. Black, elongate maculae on pronotal collar, attenuated
toward middle and separated by about one-half their length, posterior
half of pronotal lobe and basal spot on all tibiae, yellowish. Meso-
scutum dull, very densely tesselate, finely punctate, punctures separated
by a puncture diameter or less. Scutellum shinier, punctures distinctly
coarser than those of mesoscutum, separated by a puncture diameter
or less. Metanotum matt, very finely tesselate and roughened, with
some fine, obscure punctures. Mesopleura and pre-episternum slightly
shiny, tesselate, with punctures about as fine as those of mesoscutum,
separated by one to two puncture diameters. Metapleura with very
fine longitudinal striae, roughened and irregularly finely punctate.
Propodeal sides shiny, with close, coarse punctures larger than those

8 Bulletin So. Calif. Academy of Sciences

Figure 1. H. (Paraprosopis) yasumatsui, n. sp.: a, male face; b, female face; c,
sternite VIII; d, sternite IX; e, genitalia, right half dorsal aspect, left half ventral
aspect. H. incomitatus, n. sp.: f, type female face.

of scutellum; basal triangle duller, more densely tesselate, basal two-
thirds with abundant moderately coarse anastomosing rugae, a few of
which attain summit of declivity; lateral portions of basal area and
declivitious face slightly shiny, tesselate and roughened, with scattered
punctures and fine rugulae, especially laterally; lateral carina present,

Bees from Pacific Ocean y

oblique and transverse carinae absent. Tibial spurs dirty-white. Wings
brownish hyaline, veins and stigma brown.

Abdomen. First tergite polished, impunctate over much of area,
with a few fine piligerous punctures at sides; second tergite duller, but
still shiny, finely and lightly tesselate, with numerous fine, obscure
piligerous punctures; succeeding tergites similar to second but be-
coming progressively duller caudad.

Pilosity. Similar to that of male, but denser on propodeum; inner
side of hind basitarsi with dense, white, flattened reclinate pubescence.

HOLOTYPE male and allotype (U.S. National Museum, No.
70756), Okimura, Haha Jima, Bonin Islands, April 26 to June 9, 1958
(F. M. Snyder).

Paratypes: 1 3,3 9°, same data as holotype; | 3, 1 2, Yoake Yama,
Chichi Jima, April 21, 1958 (F. M. Snyder); 13, 2 29, “camp beach,”
Omura, Chichi Jima, May 5 to June 9, 1958 (F. M. Snyder); 3 29,
“mulberry beach,” Chihiro-iwa, Chichi Jima, April 11-12, 1958
(F. M. Snyder); 3 92, SE Bay, Tatsumi Wan, Chichi Jima, April
11-22, 1958 (F. M. Snyder); 2 2°, Chichi Jima, July 10, 1951 (R. M.
Bohart). Paratypes are deposited in the collections of the Bishop
Museum, California Academy of Sciences, Los Angeles County
Museum of Natural History and United States National Museum.

Paratypic variation. The few available males of this species are,
for the most part, fairly uniform. One specimen, from Omura, is
much smaller than the other males. The length of this specimen, from
the anterior ocellus to the margin of the second tergite is only 2.0 mm,
versus 3.1 to 3.2 for the other males. There are, of course, corre-
sponding differences in head proportions. Within the series of males,
the head width ranges from 1.16 mm to 1.44 mm; the upper facial
width/lower facial width figures extend from 47/25 to 52/31.

There is some variation in the extent of the maculae. The paratype
male from Okimura has the lateral face marks short, failing to reach
the level of the lower margin of the antennal sockets. In this same
specimen, the pronotal collar is immaculate, the mark on the pronotal
lobe is reduced to a small spot on the lower margin and the hind tibiae
are without a basal spot. At the opposite extreme is the male from
Yoake Yama in which the clypeus is largely yellow (black only along
the sutures), the pronotal collar maculae are separated by only one-
half their lengths, all tibiae have large basal maculae (the left mid
tibia has a narrow yellowish stripe along its entire length), and the hind
basitarsi are yellowish on the basal one-third.

The larger series of females exhibits a greater range of variation.
Length, as defined above, varies from 3.5-4.6 mm. Head width ranges

10 Bulletin So. Calif. Academy of Sciences

from 1.37 to 1.59 mm, with the Cephalic Index ( CI= 420% )
varying from 89.7 to 93.5. The upper facial width is from 1.3 to 1.4
times the lower facial width. Details of sculpturation and pilosity are
quite uniform. As is true of the males, there is considerable variation
in the extent of the maculae. In most of the females, the clypeal stripe
is restricted to the lower third, or less, of the median length, but two
have the stripe extending nearly the entire length, while others are
intermediate. The lateral face marks are more uniform, but in one
specimen do not extend above the antennal sockets. The two females
with the longest clypeal stripes (those collected by Bohart) are more
extensively maculate on the pronotal collar, as would be expected. In
one the pronotal collar mark is entire and in the other it is very narrowly
interrupted medially. The tegular maculae may be present or absent.
Some females have the tergal margins yellowish translucent; in others
they are brownish.

None of the above variations are correlated with distribution; this
species is so far known from two islands, Chichi Jima and Haha Jima.
The male of H. yasumatsui, in Bridwell’s (1919) key runs to “Hylaeus
sp.” in the last couplet. Bridwell’s comments on that species indicate,
by inference, that his specimen should belong to the subgenus Prosopis.
The present species, on the other hand, seems more nearly allied to the
H. calvus (Metz) group of the subgenus Paraprosopis. Included in this
group are H. calvus (Metz) and H. georgicus (Cockerell) in the Nearctic
Region and H. ater (Saunders) in the Palearctic Region. The distribu-
tion of the species in this group is now highly disjunct, indicating that
the group may once have been extensively distributed in temperate
areas. As the Hylaeus fauna of the world becomes better known it may
be that additional species may be placed in this group and its distri-
bution and evolution better understood.

This species is dedicated to Dr. Keizo Yasumatsu who has con-
tributed greatly to our understanding of the Hymenoptera of Asia.

Hylaeus ikedai (Y asumatsu)
Figure 2

Prosopis ikedai Yasumatsu, 1936.
Hylaeus ikedai, Yasumatsu, 1955.

Diagnosis: Male immediately separable from other Bonin Islands
species by the expanded scape which is much broader than long and
the presence of a polished, glabrous swelling on the third sternite. The
female most closely resembles H. yasumatsui but may be recognized

Bees from Pacific Ocean 11

by the shiny, densely punctate mesopleura and the long basal propodeal
area.

MALE: Measurements: HL = 1.34-1.44 mm; HW = 1.41-1.51 mm;
antenna, scape to 2nd flagellar: 23-25; 6-7:7:6-8; IAD= 12-13;
ASD = 8-9; CAD= 14-15; BCW = 13-15; COD= 15-16; OD=7-8;
IOD = 12-14; OOD= 13-17; wing length =3.7-4.1 mm; length, an-
terior ocellus to margin of second tergite, 3.2-3.7 mm.

Head. Black, the following pale yellowish: broad mandibular stripe;
labral tubercule; clypeus, except margins; broad lateral face marks,
ending bluntly slightly above level of antennal sockets; broad stripe
on ventral, narrow stripe on dorsal margins and most of inner face of
scape. A small yellow spot present on supraclypeal area; one specimen
(from Nishi Jima) possesses a small yellow spot on the gena at about
one-third of the distance from the lower to upper eye margins. Flagel-
lum light ferruginous beneath. Clypeus dull, closely tesselate, with
fine, close elongate punctures; supraclypeal area slightly shiny, finely
lineolate, with scattered obscure punctures; maculate areas of face
moderately shiny, closely tesselate, with fine scattered punctures;
non-maculate areas slightly shiny, densely and finely punctate, with
closely tesselate interspaces; area between eyes and ocelli slightly to
moderately shiny, tesselate, with well separated fine punctures; genae
moderately shiny, lightly tesselate and lineo-punctate. Eyes, in profile,
about 1.5 times broader than genae. Antennal scape expanded, from
1.2 to 1.4 times broader than long; inner face transversely concave,
concavity dull.

Thorax. Mesoscutum slightly shiny, lightly and closely tesselate,
finely punctate, punctures separated by a puncture diameter or more;
scutellum slightly shiny, lightly and closely tesselate, finely punctate,
punctures little, if any, larger than those of mesoscutum, irregularly
spaced from one-half to nearly two puncture diameters apart; meta-
notum flattened, very finely and closely tesselate, without evident
punctures; mesopleura moderately shiny with fine tesselation, closely
punctate, punctures much larger than those of mesoscutum, separated
by one-half to a puncture diameter; metapleura finely longitudinally
striate, densely tesselate and slightly shiny, with scattered obscure
punctures. Propodeal sides densely tesselate and slightly roughened,
slightly shiny, with obscure, shallow punctures; basal area of pro-
podeum very nearly as long as scutellum, basal two-thirds with fine
irregular anastomosing rugulae, slightly shiny, closely tesselate; latero-
basal area coarsely and closely punctate; remainder of propodeum
densely tesselate, slightly shiny, irregularly punctate and roughened;
lateral, oblique and transverse carinae absent. Black, with the following

12 Bulletin So. Calif. Academy of Sciences

yellowish: pronotal lobe; tegular spot; minute apical femoral spot;
complete outer stripe on fore tibia; basal and apical maculae on mid
and hind tibiae; all basitarsi. Remaining tarsal segments ferruginous,
becoming darker distally.

Abdomen. First tergite lightly tesselate, moderately shiny, with
sparse, fine, piligerous punctures; second tergite with strong gradular
carina, slightly and closely tesselate, slightly shiny, with coarser, closer
punctures than first tergite; succeeding tergites similar to second, but
punctures progressively more indistinct caudad; third sternite with a
large, ventrally flattened, glabrous semicircular basal tumescence;
fourth sternite with a short, transverse, glabrous preapical tumescence.
Blackish-brown, tergites and sternites with broad yellowish-translucent
apical margins. Terminalia: Fig. 2c-e.

Pilosity. Erect hairs sparse on face, short; vertex with numerous
much longer hairs; genae, especially below, with abundant long,
plumose pubescence; thoracic dorsum with sparse, simple, erect hairs
and scattered longer, simple hairs; thoracic and propodeal sides with
sparse, long, weakly to distinctly plumose pubescence; propodeal
interior with denser, shorter, plumose pubescence; first tergite with
sparse, short, erect hairs; second and third tergites with denser, longer
hairs, fourth and remaining tergites with hairs sparser; sternites with
long, sparse hairs; hairs and pubescence whitish, sometimes tinged with
fulvous, especially on tergites.

FEMALE. To the adequate characterization of the female of this
species given by Yasumatsu (1936) I wish to add the following:

Measurements. HL=1.19-1.40 mm; HW = 1.32-1.47 mm; [AD=
14; ASD= 7-8; CAD = 6-10; BCW = 17-20; COD = 15-17; OD= 6-7;
IOD= 13; OOD= 15-16.

In all females examined the pronotal collar is wholly black. The
preapical clypeal spot may be present or absent. Of the seven females
seen, two possess a distinct clypeal macula, four lack it and one has
the preapical area reddened. The mesopleural punctures are distinctly
coarser than those of the mesoscutum, separated by about a puncture
diameter, the interspaces lightly tesselate and shiny. None of the
variation noted for either sex seems correlated with distribution.

SPECIMENS EXAMINED. 1 2, Ogasawara, 1934? (Ikeda and
Okabe); 1 3, 2 2°, Chichi Jima, July 10, 1951 (R. M. Bohart); 13, 12,
Chichi Jima, June 1959 (J. Yoshiyama); 1 3, 1 2, ‘““camp beach,” Omura,
Chichi Jima, May 5-June 9, 1958 (F. M. Snyder); 1 $, Kammuri-iwa
(SW bay), Ototo Jima, June 3, 1958 (F. Snyder and W. Mitchell); 1,
Sen-zan (NE bay), Ani Jima, May 28, 1958 (F. M. Snyder); 13, Nishi

Bees from Pacific Ocean 13

Figure 2. H. ikedae Yasumatsu: a, male face; b, female face; c, sternite VIII; dl,
sternite IX, lateral (left) and apico-ventral (right) aspects; d2, sternite IX. dorsal
aspect; e, genitalia, right half dorsal aspect, left half ventral aspect.

14 Bulletin So. Calif. Academy of Sciences

Jima, May 22, 1958 (F. Snyder and W. Mitchell); 1°, Okimura, Haha
Jima, April 26-June 9, 1958 (F. M. Snyder).

Yasumatsu (1936) originally compared this species with H. paulus
Bridwell of Japan. The discovery of the male of H. ikedai has enabled
me to arrive at a closer comparison with another Japanese species.
Although I have not examined any material of H. gnathylaeoides
Bridwell, the original description of that species leaves little room for
doubt that H. ikedai is closely related. The male of H. gnathylaeoides
has the scape “enormously enlarged” and the “third sternite with a
spine on either side of the disc and connected by a ridge.”’ The descrip-
tion of the eighth and ninth sternites closely matches the basic charac-
ters of these structures in H. ikedai. The female of H. gnathylaeoides,
judging from the description, is very similar to that of H. ikedai; it
would be necessary to compare the two to be certain of differentiating
characters. In H. gnathlaeoides the pronotal collar is maculate (black
in H. ikedai), the clypeal macula is a broad longitudinal stripe (a
preapical spot, or absent, in H. ikedai), the metanotum is rugulose ~
(tesselate with scattered punctures in H. ikedai) and the mesopleural
punctation is similar to that of the mesoscutum (much coarser in
H. ikedai).

Together these species would seem to form a distinctive element
within the Micronesian fauna, one which may eventually prove worthy
of subgeneric recognition. I believe that until the entire Palaearctic,
Oriental and Micronesian Hylaeus fauna can be critically studied that
the erection of a new subgenus at this time might only add to the
confusion.

Hylaeus (Nesoprosopis) boninensis Y asumatsu
Figure 3

Hylaeus boninensis Yasumatsu, 1955.

Diagnosis: Easily separated from other Bonin Islands species by the
wholly maculate pronotal collar, wholly yellow or light ferruginous
legs, maculate axillae and dark abdomen. The mesopleura are shiny
and closely punctate in both sexes and the male antennal scape is
nearly as broad as long.

MALE: Measurements: HW = 1.61-1.85 mm; HL = 1.51-1.75 mm;
antenna, scape to 2nd flagellar: 2-26, 8, 5-6, 9-10; IAD=7-9; ASD =
11-12; CAD=15-19; BCW= 12-15; OOD= 15-17; OD=10-11;
IOD = 15-18; OOD = 15-18; wing length = 4.1-4.9 mm; length, front
ocellus to margin of second tergite, 4.0-4.6 mm.

Head. Black, the following yellowish-white: mandibles, except

Bees from Pacific Ocean 15

ferruginous apices; small mediobasal spot on labrum; clypeus; large
lateral face marks, ending abruptly on a level midway between antennal
sockets and ocelli; supraclypeal area, ending acutely between antennal
sockets; narrow ventral stripe on scape. Flagellar segments beyond
first dull ferruginous beneath. Head a little broader than long, inner
orbits distinctly convergent below (UFW about 1.5 times LFW).
Antennal scape broad, from 1.2 to 1.3 times longer than broad, some-
what concave on dorsal surface. Clypeus slightly shiny, finely tesselate,
with numerous fine, oval punctures becoming coarser and closer toward
apex; supraclypeal area (maculate portion) dull, finely lineolate, with
scattered fine punctures peripherally; sides of face, between antennae
and inner orbits distinctly longitudinally depressed, maculate areas
somewhat shiny, with scattered fine punctures; nonmaculate areas
finely, closely punctate, the interspaces slightly shiny; area between
eyes and ocelli polished, with scattered punctures; foveae above curved
away from eye margin, ending a little nearer to eyes than to ocelli;
genae about one-half as wide as eyes in profile, finely, densely punctate,
with shiny interspaces.

Thorax. Mesoscutum finely and closely punctate, punctures sepa-
rated by half a puncture diameter or less, interspaces shiny, very lightly
tesselate. Scutellum closely punctate, punctures subcontiguous and a
little coarser than those of mesoscutum, interspaces shiny and very
lightly tesselate. Metanotum rugulose, slightly shiny, closely tesselate.
Preepisternum and mesopleura closely punctate, punctures coarser
than those of scutellum, interspaces polished; metanotum with distinct
well spaced longitudinal raised striae, interspaces shiny, lightly tesse-
late, with shallow, obscure punctures. Propodeal triangle shiny, surface
lightly roughened, with a few coarse rugae defining several large
areolae, and with a few finer, irregular rugulae; lateral area coarsely
and closely punctate, with shining interspaces; propodeal declivity and
latero-basal areas slightly shiny, with variably spaced punctures of
several sizes, these more pronounced toward sides and base; lateral
carina high and sharp, oblique and transverse carinae absent; pits on
either side of abdominal insertion prominently carinate in front.

Black, the following yellow: anterior margin of pronotum; entire
dorsal surface of pronotal collar, confluent with macula of pronotal
lobe; large spot on antero-lateral corner of mesoscutum (absent in some
specimens); large tegular spot; axillar spot; apical spot on all femora;
ventral stripe on fore femora and obscure ventral blotch on mid
femora; all tibiae and tarsi (distitarsi darker ferruginous), the latter
tending to become light ferruginous. Wings faintly brownish-hyaline,
veins and stigma brown.

16 Bulletin So. Calif. Academy of Sciences

Abdomen. First tergite polished, with scattered, fine piligerous
punctures; second tergite shiny, with scattered piligerous punctures,
surface rather closely tesselate, gradulus sharply carinate; third and
following tergites similar to second, but duller, more densely tesselate
and with punctures more clearly defined; sternites more coarsely
punctate, moderately shiny. Terminalia: see fig. 3c-e.

Blackish-brown, apical margins of tergites and sternites broadly
yellowish-translucent.

Pilosity. Sparse on front of head, but clypeus with numerous re-
clinate, weakly barbulate yellowish-white hairs; vertex with abundant
erect hairs of variable length, these light fulvous, weakly barbulate;
genae with abundant long, erect yellowish-white pubescence; thoracic
dorsum with abundant short, erect fulvous weakly to moderately
barbulate hairs and scattered longer, weakly barbulate hairs; thoracic
sides with abundant long, fulvous pubescence; sides and interior of
propodeum with a dense covering of short, whitish pubescence and
abundant long, fulvous pubescence. Anterior and lateral faces of first ©
tergite with numerous short, erect simple to moderately barbulate
hairs; succeeding tergites with abundant long, reclinate fulvous hairs
and shorter, depressed whitish pubescence on margins; sternites with
scattered short, reclinate whitish to fulvous pubescence and scattered,
longer hairs.

FEMALE. Most details of the female have been adequately de-
scribed by Yasumatsu (1955). The following additional details will
supplement that description.

Measurements: HW = 1.86 mm; HL= 1.66 mm; I[AD= 17; ASD =
10; CAD= 11; BCW= 26; COD= 19; OD= 12; IOD= 17; OOD=
20; wing length, 5.1 mm; length, anterior ocellus to margin of second
tergite, 4.9 mm.

Upper facial width 1.25 times lower facial width; facial foveae
ending at about midpoint between eyes and ocelli; first tergite with
abundant erect weakly barbulate to plumose hairs; punctural inter-
spaces on thorax lightly tesselate, moderately to strongly shiny.

SPECIMENS EXAMINED: 1 2, Chichi Jima, July 10, 1951 (R. M.
Bohart); 1 3, 1 2, Chichi Jima, June, 1959 (J. Yoshiyama); 2 $4, “camp
beach,” Omura, Chichi Jima, May 5 to June 9, 1958 (F. M. Snyder).

This species seems to be fairly uniform in its characters; there is
some variation among the males in the extent of the mesoscutal macu-
lation. This maculation may be present as a conspicuous quadrate
mark, reduced to a small round spot or wholly absent. Larger series
would probably reveal more extensive variation.

The terminalia of the male, especially the configuration of the

Bees from Pacific Ocean IN 7/

Figure 3. H. (Nesoprosopis) boninensis Yasumatsu: a, male face; b, female face;
c, sternite VIII; d, sternite IX; e, genitalia, right half dorsal aspect, left half ventral
aspect.

18 Bulletin So. Calif. Academy of Sciences

eighth and ninth sternites, are very similar to those of species assigned
to the Hawaiian subgenus Nesoprosopis. I can find nothing at this time
to argue against inclusion of this species in that subgenus.

Hylaeus incomitatus, new species
Figure If

Diagnosis: This species may be immediately separated from its
congeners on the Bonin Islands by its small size, maculate axillae and
ferruginous abdomen.

FEMALE: Measurements: HL=0.95 mm; HW=1.08 mm; an-
tenna, scape to 2nd flagellar: 22:8:6:5; IAD= 16; ASD=8; CAD=
8; BCW = 22; COD= 14; OD=7; OOD = 14; IOD= 12; wing length
= 3.0 mm; length, anterior ocellus to margin of second tergite, 2.9 mm.

Head: Black, the following pale yellowish: irregular median longi-
tudinal stripe on apical three-fourths of clypeus and broad lateral face
marks, terminating bluntly at lower end of facial foveae; transverse -
basal spot on mandibles. Apical margin of clypeus and mandibular
apex ferruginous. Underside of scape and flagellum dull ferruginous,
upperside blackish-brown. Mandible broad, with two apical teeth.
Clypeal apex broadly concave, disc slightly shiny, densely tesselate,
with scattered obscure punctures; maculate areas of face slightly shiny,
densely tesselate, with scattered obscure punctures; supraclypeal area
less shiny, more densely and finely tesselate, with irregularly spaced
fine punctures at sides; frons and vertex finely, closely punctate, with
moderately shiny interspaces; occipital punctures separated by a punc-
ture diameter or more; facial foveae above ending near midpoint
between eyes and ocelli; genae as broad as eyes, moderately shiny,
with scattered, obscure fine punctures.

Thorax: Black, the following pale yellowish: anterior margin, collar
and posterior lobes of pronotum; anterior spot on otherwise transparent
tegulae; axillae; short, oblique line on scutellar sides; apical spot on all
femora; basal stripe on all tibiae. Legs otherwise dull to light fer-
ruginous. Mesoscutum and scutellum slightly shiny, with fine, close
punctures; metanotum duller, with a few obscure punctures; pre-
episternum and mesopleurae shinier, with fine punctures separated by
a puncture diameter or more, punctures somewhat obscured by dense
tesselation; metapleura moderately shiny, without striae, but with a
few fine, obscure punctures. Propodeum lacking lateral, oblique and
transverse carinae; basal area essentially horizontal, longer than
metanotum in middle, with a few short, irregular rugulae basally;
juncture of dorsal and posterior faces a well-rounded curve.

Bees from Pacific Ocean 19

Abdomen: Ferruginous, broad apical margins lighter, more yellow-
ish; apical segments darker; tergites shiny, very finely transversely
lineolate, with scattered very fine piligerous punctures.

Pilosity: Everywhere sparse, whitish, consisting of short, appressed
simple hairs and scattered longer simple hairs; propodeum, except
basal triangle, with denser, weakly plumose, reclinate pubescence
which does not obscure surface; abdominal tergites without marginal
fasciae, discs with scattered simple hairs which become longer, more
abundant and more erect caudad; ventral hairs similar.

HOLOTYPE female (United States National Museum, No. 70755),
Southwest Bay, Ani Jima, Chichi Jima Group, Bonin Islands, May 17,
1958, collected by F. M. Snyder.

This small species does not appear to be closely related to any of its
congeners on the Bonin Islands, nor does it show any obvious relation-
ship to the species of the Japanese Islands.

The specific name is a Latin word meaning unaccompanied or alone,
in reference to its lack of obvious relatives and to the lack of additional
specimens.

LITERATURE CITED

BRIDWELL, J. C. 1919. Miscellaneous notes on Hymenoptera, with descriptions
of new genera and species. Haw. Ent. Soc., Proc., 4: 109-179.

GressiTT, J. L. 1954. Insects of Micronesia. Introduction. /nsects Micron.,
1: 1-257.

Hurp, P. D., Jk. AND J. S. Moure. 1963. A classification of the large carpenter
bees (Xylocopini). Univ. Calif., Publ. Ent., 29: 1-365.

KROMBEIN, K. V. 1949. The aculeate Hymenoptera of Micronesia, I. Scoliidae,
Mutillidae, Pompilidae and Sphecidae. Haw. Ent. Soc., Proc., 13: 367-410.

1950. The aculeate Hymenoptera of Micronesia, II. Colletidae, Halicti-
dae, Megachilidae and Apidae. Haw. Ent. Soc., Proc., 14: 101-124.

Y ASUMATSU, K. 1936. Hymenoptera of the Bonin Islands. Nat. Hist. Soc. Formosa,
Trans., 26: 356-363.

1955. On the bee fauna of the Bonin Islands. Biogeogr. Soc. Japan, Bull.
16-19: 219-223.

Accepted for publication December 16, 1969.

Bull. So. Calif. Acad. Sci. 69(1): 20-26, 1970

TRACE FOSSILS OF TRILOBITES
FROM THE DEADWOOD FORMATION
(UPPER CAMBRIAN) OF WESTERN SOUTH DAKOTA

GEORGE CALLISON
Department of Biology
California State College

Long Beach, California 90801

ABSTRACT: Tracks of a vagile, epipsammitic trilobite are
reported from the Deadwood Formation (Upper Cambrian)
of the Black Hills. A new genus, with /xalichnus enodius as the
type species, has been established for these tracks. The tracks
suggest that /. enodius usually swam rather than crawled. This
is the first report of tracks of trilobites from the Deadwood
Formation. The tracks are associated with a Cruziana facies.

INTRODUCTION

Trace fossils attributable to trilobites have not been previously reported
from the Deadwood Formation (Upper Cambrian) despite the con-
siderable paleontological and geological work that has been conducted
on this formation (Darton, 1901 and 1909; Barragy, 1929; Furnish,
Barragy, and Miller, 1936; Meyerhoff and Lochman, 1936; Block,
1952; Lochman, 1957; Carlson, 1960; Cygan and Kouchy, 1963; and
Kulik, 1965). Six man hours of prospecting yielded three small
blocks of sandstone having trace fossils (resting tracks = cubichnia of
Seilacher, 1953) that could have been made by trilobites (Figs. 1-3).
Included in these blocks are feeding trails and dwelling burrows
(pascichnia and domichnia of Seilacher, 1953 and 1964) made by a
variety of other organisms. Bedding planes of the blocks are marked
by oscillation ripples. All numbers are those of the Museum of Geology,
South Dakota School of Mines and Technology, Rapid City. The
locality is designated by number only as a protective measure. More
complete locality information is available through the museun of
Geology.

Phylum ARTHROPODA
Subphylum TRILOBITOMORPHA Stgrmer, 1944
IX ALICHNUS, new genus

Type Species. — Ixalichnus enodius sp. nov.
Diagnosis. — Short track in exogene epirelief (both concave and
convex) preservation; general subrectangular shape formed by two

20

Trilobite Tracks 21

rows of 15-18 impressions; sediment displaced posteriad and mediad
from impressions, then carried anteriad and yet more mediad in con-
verging rows, the remainder of the sediment finally coming to lie in a
hemispherical mound about 43 of the way back from the anterior-most
pair of impressions; track is 50 mm long and 20 mm wide.

Figure 1. Trackway of Holotype of Ixalichnus enodius. Scale in mm.

Figure 2. Trackway of referred specimen of /. enodius. Scale in mm.

Figure 3. Trackway of a trilobite, perhaps /. enodius. Notice that the rear part
of the trackway has been partially erased. Scale in mm.

Ixalichnus enodius, new species

Etymology, — Greek: ixalos, springing; ichnos, footprint. Enodios,
wayside; referring to the type locality.

Holotype. — SDSMT 2072, short trackway on surface of block of
ripple-marked sandstone (Fig. 1).

Type locality. — SDSMT locality number V684. From laminated
sandstone facies of the Deadwood Formation, Pennington County,
South Dakota.

Referred specimen. — SDSMT 2073, short trackway on surface of
block of ripple-marked sandstone (Fig. 2). Locality is that of the Type.
Measurements. — In the type specimen of /xalichnus enodius the
widths of the trace at the levels of the various appendages from rear to
front range from 21 mm to about 10 mm. The stride (excursion of the
appendages) ranges from 6 mm at the rear to 3-4 mm in the mid-body
region to 2-3 mm at the anterior end. Widths in the referred specimen
range from 18 mm to about 16 mm. Strides in the referred specimen

2p) Bulletin So. Calif. Academy of Sciences

range from 7-8 mm at the rear to 6-7 mm at the front. A third specimen
(SDSMT 2074, Fig. 3), possibly referrable to J. enodius, has a maxi-
mum width of about 15 mm and strides measuring 7 mm in the rear
and about 3 mm in the front.

The size of the tracks suggests that the organism responsible for them
must be about 40-50 mm long and 15-20 mm wide. Of the adult trilo-
bites known from the Ptychaspis-Prosaukia zone of the Deadwood
Formation only Ptychaspis falls within this size range. Until more is
known about this genus as well as other trilobites of this zone it is
impossible to say definitely which trilobite actually made these tracks.
Nowhere in the literature were there references to tracks that closely
resembled those of /. enodius.

Ixalichnus enodius probably spent much of its time swimming (at
least in this particular environment), pausing only periodically to rest
on the substratum, then springing from it to begin swimming again. If
indeed SDSMT 2074 was made by J. enodius, then it can be said that
this organism did a limited amount of crawling. ;

Associated Ichnofauna. — Included on and in the blocks upon which
Ixalichnus enodius was found, as well as on and in adjacent blocks,
were other trace fossils. These fossils included three kinds of pascichnia
(two species of Planolites and one that compares with Ceratophycus)
and at least one kind of domichnia.

GEOLOGIC SETTING

Stratigraphy. — The tracks described in this paper were found on
three slabs of red sandstone. These slabs, ranged from 1 cm to about
7 cm in thickness. The sandstone is part of the Laminated Sandstone
Facies (Kulik, 1965) of the Upper Member of the Deadwood Forma-
tion, Franconian Stage (Ptychaspis-Prosaukia trilobite zone) of the
Cambrian System.

Kulik (1965) points out that the “...Deadwood Formation is
restricted to a dominantly sandstone facies of the Upper Cambrian in
the Black Hills, the Dakotas, and the eastern Powder River Basin and
the Williston Basin of the Dakotas.”

The Deadwood Formation is divided into lower, middle, and upper
members (Kulik, 1965). The Lower Member consists primarily of
sandstones, limestones, and limestone pebble conglomerates and is up
to 100 feet thick. The Middle Member gradually thickens from about
30 feet to 156 feet and consists of a sequence of shales interbedded

Trilobite Tracks 23}

with limestone pebble conglomerates. The Upper Member varies from
20 feet to about 160 feet in thickness and is comprised of a massive
red sandstone, flaggy sandstones and limestones, and commonly
limestone and siltstone pebble conglomerates (Kulik, 1965).

Kulik (1965) has found evidence for rapid facies changes in all
members of the Deadwood Formation and has described these changes
as follows. “Three transgressive-regressive depositional sequences are
represented in the Dresbachian, Franconian to Trempealeauan, and
Tremadocian stages. Initial transgression occurred in Cedaria zone
time with the establishment of bars, lagoons, beaches and tidal flats on
an embayed coastline. A minor regression was initiated in Crepicepha-
Jus zone time and continued into the overlying Aphelaspis zone time.
Following a quiescent period, northern downwarping triggered a
rapid inundation during Elvinia zone time. The Conaspis, Ptychaspis-
Prosaukia, and Saukia zone times experienced a regression and the
extensive development of sands. Lower Ordovician seas attempted a
feeble advance, but immediately retreating seas deposited the Scolithus
Sandstone which closed the final depositional chapter.”

Lithology. — The tracks of the type and referred specimens of /xalich-
nus enodius are found in bas-relief on the upper surfaces of blocks of
irregularly and thinly bedded, fine-grained sandstone. The several
laminae of this sandstone are separated by very thin siltstone partings.

The top millimeter or so of the sandstone blocks differs lithologically
from the central part of the block. The percentages of quartz to dolo-
mite to glauconite differ in the two parts, although throughout the block
the particles are of fine sand (range from 0.1 mm to 2.5 mm) size, are
subrounded to rounded and are practically exclusively quartz, dolo-
mite, and glauconite. On the surface about 41 per cent of the particles
are nonfrosted quartz, 42 per cent are pink dolomite, and 17 per cent
are glauconite. In the central parts of the blocks clear quartz grains
make up about 61 per cent of the particles, pink dolomite about 23
per cent, and glauconite remains nearly the same — 16 per cent. These
particles are cemented with a siliceous material. Burrows penetrating
the central regions of the blocks contain sand of the composition of the
surficial layer and, therefore, are seen as red streaks against a green
background. Despite the green color of freshly broken surfaces,
weathered blocks are completely pink to red.

The very fine siltstone (most particles are around 0.08 mm) partings
are very micaceous but contain scattered rhombs of pink dolomite
along with occasional particles of glauconite. These partings, too, are
pinkish in color and have particles joined by siliceous cement.

24 Bulletin So. Calif. Academy of Sciences

Environment. — Kulik (1965) states that “...deposition of the
Laminated Sandstone Facies occurred more likely on a tidal flat rather
than on a deltaic platform because of the presence of various sedimen-
tary bedding structures and pebble conglomerates. Most of the lami-
nated facies was deposited along the main tidal channels and occasional
worm-burrowed beds were deposited on higher flats away from the
main channels.” The specimens in this study most likely are from an
area away from the main channels.

DISCUSSION

The sand displaced by the flexing appendages is arrayed in cuneiform
ridges posteriorly, but mostly medial to the position of the extended
appendages. Two thirds of the distance from the posterior edge of
the track (Fig. 1) is a hemispherical mound of sand that apparently
formed as a result of the flexion of the appendages of the anterior third
of the animal and supplemented in its formation by the grains brought
up by the more posterior appendages when the animal was completing
its take-off. This mound may correspond to the position of the mouth
or may only represent the point at which the currents invading the
space just vacated by the animal formed an eddy and deposited some
sediment. The most plausible answer is that the hemispherical mound
of sand represents the point at which all of the flexing appendages
finally cleared the bottom. The mound can best be seen in the holotype
but is also present in the referred specimen. The third specimen does
not show this unusual accumulation of sand.

Tracks on the surface of a sediment are quite fragile, thus the mere
presence of these cubichnia indicates that there has been no secondary
displacement of the organism making the traces; subsequent sedimenta-
tion must have been rapid and very soon after the tracks were made.
The association of the other ichnofauna with [xalichnus enodius was
a natural one. [xalichnus enodius, along with the associated ichnofauna,
made up part of an actual benthonic community living in a single area
and at the same time.

There are no indications in these tracks that these trilobites used the
pygidium as a locomotory organ.

Seilacher (1964) has described the Cruziana Facies as being charac-
terized by the following:

Dominant Groups:

Cubichnia (resting tracks) of epipsammon Domichnia (dwelling
burrows) of suspension feeders (mainly in shallow, turbulent

Trilobite Tracks 25

zone) Fodinichnia (feeaing burrows) of deposit feeders (mainly
in deeper zone)
Diagnostic inorganic sedimentary structures:
Oscillation ripples
Dominant Lithology:
Well-sorted sandstones to shales; quartzites; detrital limestones
to marls.
Probable depth:
Littoral to sublittoral, above wave base.
The information gained from this study tends to support the conten-
tion that Ixalichnus enodius belongs to a Cruziana Facies.

LITERATURE CITED

BarraGy, E. J. 1929. Geology of the Deadwood Formation of the Lead Quad-
rangle of the Black Hills of South Dakota: Unpublished Masters Thesis,
State University of Iowa.

Biock, D. A. 1952. The geology of the Deadwood Formation between Bear Butte
and Spring Creeks, Black Hills, South Dakota: Unpublished Masters Thesis,
State University of Iowa.

Carson, C. G. 1960. The stratigraphy of the Deadwood and Winnipeg Forma-
tion in North Dakota. North Dakota Geol. Surv. Bull., 35: 1-149.

CyGan, N. E. AND Koucuy, F. L. 1963. The Cambrian and Ordovician rocks of
the east flank of the Big Horn Mountains, Wyoming. Northern Powder River
Basin Joint Guidebook, Wyoming Geological Assoc. and Billings Geological
Soc., p. 26-37.

Darton, N. H. 1901. Preliminary description of the geology and water resources
of the southern half of the Black Hills and adjoining regions in South Dakota
and Wyoming. U. S. Geol. Surv. 21st Ann. Rept., pt. 4, p. 502-508.

1909. Geology and water resources of the northern portion of the Black
Hills and adjoining regions in South Dakota and Wyoming. U. S. Geol.
Surv. Prof. Paper no. 65, 105 p.

FurnisH, W. M. BarracGy, E. J. AND MILLER, A.K. 1936. Ordovician fossils from
upper part of type section of the Deadwood Formation, South Dakota. Amer.
Assoc. Pet. Geol. Bull., 20: 1329-1341.

KULIK, J. W. 1965. Stratigraphy of the Deadwood Formation Black Hills, South
Dakota and Wyoming. Unpublished Masters Thesis, South Dakota School
of Mines and Technology.

LocuMaN, C. 1957. Paleoecology of the Cambrian in Montana and Wyoming.
Geol. Soc. Amer. Memoir 67, (2): 117-162.

MEYERHOFE, H. A. AND LocHMAN, C. 1936. Deadwood faunas in South Dakota
and eastern Wyoming. Geol. Soc. Amer. Proc., p. 386.

26 Bulletin So. Calif. Academy of Sciences

SEILACHER, A. 1953. Studien zur Palichnologie, 2. Die fossilen Ruhespuren
(Cubichnia). Newer Jahrbuch Geologie Palaontologie Abhandlung, 93: 421-
452.

1964 Biogenic sedimentary structures. In Imbrie, J. and Newell, N. D.
eds., Approaches to Paleoecology, p. 296-316 Wiley and Sons, N.Y.

Accepted for publication November 30, 1969.

Bull. So. Calif. Acad. Sci. 69(1): 27-31, 1970
EPICARIDEA (ISOPODA) OF HAWAITI

CHARLES G. DANFORTH
3612 Angelus Avenue

Glendale, California 91208

ABSTRACT: A new form of the bopyrid Jonella is described.
Tonella murchisoni, n. sp. is the sixth species of parasitic
isopod in the Epicaridea suborder to be reported from the
State of Hawaii, and is the first of this genus to be found out-
side of Chile.

INTRODUCTION

A new form of a previously monospecific genus of the Bopyridae is
here described from Hawaii. This represents the sixth genus of parasitic
epicarid isopods so far reported from this State. The Hawaiian speci-
mens described to date are:

Bopyridae:

Entophilus omnitectus Richardson, 1904.

Gigantione hawaiiensis Danforth, 1967.

Scyracepon hawaiiensis Richardson, 1911.
Cryptoniscidae:

Faba glabra Nierstrasz and Brender a Brandis, 1931.
Dajidae:

Zonophryxus retrodens Richardson, 1904.
Entoniscidae:

None.

Of the foregoing, Entophilus, Faba and Zonophryxus were also new
genera at the time of the erection of the species shown. References by
Richardson (1905, Figs. 630, 634) to Bopyroides hippolytes (Kr@yer)
on Hawaiian Spirontocaris securifrons hosts are apparently in error.

lonella murchisoni, new species

Ionella Bonnier 1900, p. 322.
Material: A pair of bopyrids.
Host: Callianassa sp.
Area: Sand Island, Kaneohe Bay, Oahu, Hawaii.
Date: 25 February 1965.
Collector: Earl Murchison.
Female. From the right gill chamber of the host shrimp; color bright
yellow in preservative, with whitish head and pleura; little lateral

aT

28 Bulletin So. Calif. Academy of Sciences

twisting, although the left side is larger than the right; general form
oval, with the long axis transversely oriented; no pigment spots evident;
length 3.2 mm, width 4.6 mm.

Head. Very large and square, with a slight posterior indication of
bilobed condition; no velum; no eyes; antero-lateral corners of the
cephalon project, 2 medial salients on the anterior border; antennae
large and visible from the dorsal aspect; color white in comparison to
the general yellow tone of the body proper.

Thorax. Seven segments with weakly indicated demarcations; only
thoracomere I can be traced from side to side, all others blend medially
into a slightly elevated, circular mass with no decipherable internal
structure; triangular pleural bosses and anvil-shaped coxal plates on
thoracomeres I-IV; segments V-VII terminate laterally in blunt antero-
lateral projections, each with a faint indication of a postero-lateral
lobe; seven pairs of small pereopods, II-VII having progressively larger
and unusual, swellings of basipodites and ischiopodites; marsupium
vaulted and completely covered by imbricating oostegites, pair V with
fine bordering hairs.

Pleon. Wide, flat and triangular, with no dorsal evidence of seg-
mentation; slight pleomere indications on the ventral aspect, with but
4 segments discernable; border essentially smooth, but with 8 knob-like
peripheral projections visible on each side from the dorsal view;
Pleopods not visible from the dorsum; individual pleopod parts diffi-
cult to analyze; the exopodite with an elongate, pinnate shape, and the
endopodite as 2 basal bulbs or tuberosities; these latter are quite similar
to the knob-like projections of the pleural piates on pleomeres I-II;
pleomere V a biramous digitation, with the medial process about 3
times as long as the lateral one. If the foregoing interpretation is correct,
the sixth segment is a very small mass between pleopods V, and has 2
minor plates projecting posteriad as the uropoda.

Male. Color pale yellow in preservative; body progressively wider
to thoracomeres VI-VII; length 2.3 mm, width 1.0 mm.

Head. Two large brown eye-spots along the posterior border; anten-
nae II visible from the dorsal aspect, quite long; antennae I short, 2-
jointed; oral cone with a brown-pigmented tip.

Thorax. Seven clearly delineated segments, with non-contiguous
ends; no dorsal pigment spots; seven pairs of large pereopods; no
ventral elevations in the mid-line.

Pleon. Six segments, VI very tiny and surrounded except at the
posterior, by V; definite pigment spots at the posterior margin of the
sternal-pleural plate contacts for pleomeres I-V; entire pleon rolled
under somewhat, so that the pigment spots on segment V appear similar

New Species of Isopod DS)

to eyes; pleural plates non-contiguous; five pairs of biramous pleopods,
each endopodite and exopodite pair arising from a common peduncle;
rami finger-like, with the medial larger than the lateral branch, and
overlapping its counterpart somewhat at the mid-line; uropods ex-
tremely tiny, as a short rod on the right and a slight swelling on the left.

Remarks. Bonnier (1900) established Jonella agassizi from Cal-
lianassa uncinata Milne-Edwards at Talcahuano (near Concepcion),
Chile. Shiino (1964a), studied examples of the same parasite species
from the same host species at Puerto Montt (about 300 miles south of
Talcahuano), Chile. There have been no other records of the form,
although Nierstrasz and Brender a Brandis (1929) mentioned Jonella
in one of their bopyrid keys. Consequently it is of considerable interest
to find Jonella at a locale distant from its original discovery area.

In general, the new species conforms to the description of J. agassizi,
with the pleon border and pleopoda of the female being the major
points of difference. As far as the male is concerned, the relative sizes
of the uropoda and pleopoda rami are at variance. In J. murchisoni,
uropoda, if present, are extremely tiny, while in /. agassizi the uropoda
are definite, small rods. With respect to the pleopoda of the male,
Bonnier indicated that the exopodites were slightly larger than the
endopodites for /. agassizi; the reverse is true for /. murchisoni. It is
of interest that Shiino (1964a) found in his specimens that there was no
common peduncle for the biramous pleopods; such a peduncle is
present in both Bonnier’s and the new species.

In the female, there are 2 major differences evident between /.
agassizi and I. murchisoni. The pleon border of the former is smooth
except for slight segmental notches, and the biramous pleopoda have
broadly foliaceous exopodites and similar (but 2-pointed) endopodites.
In the latter, the pleon border has bulbous swellings which diminish in
size from I to IV, and each of the biramous pleopoda has a pinnate
exopodite and a double-swelling representing the endopodite.

A change from a partially bilobed pleopod endopodite in /. agassizi
to a double-tuberosity in /. murchisoni would not be unusual among
bopyrids, but a change from a foliaceous to a pinnate pleopod exopo-
dite would be less expected. For comparison, the illustration of the
ventral pleon of Pseudione compressa Shiino (1964b, Fig. 2) is some-
what similar to the appearance of the same area of J. murchisoni.
However, many other features of both the male and female of Pseu-
dione compressa (pereopoda, male pleopoda, oostegites, dorsal pleon
of the female, dorsal pereon and coxal plates of the female, etc.) are
strikingly different.

I am indebted to Dr. Henry B. Roberts of the Smithsonian Institution

30 Bulletin So. Calif. Academy of Sciences

Figure 1. lonella murchisoni, n. sp. A. Dorsal view of adult female. B. Right
pereopod VI of female, showing unusual plates. C. Appendages of left pleomere
I of female. D. Appendages of left pleomere III of female. E. Appendages of left

l

es)

New Species of Isopod

for the identification of the host, which itself is apparently new. Dr.
Roberts wrote (letter of 12 April 1967) that the specimen “‘is distinctly
different from any of the nominate species of Callianassa that have
been reported from the Hawaiian region.”

The new Jonella is named after Mr. Earl Murchison, Zoology
Department, University of Hawaii, who has most kindly kept on the
lookout for my little parasites. Mr. Murchison reports that a second
infested host was accidently lost.

The female holotype and male allotype were deposited in the Allan
Hancock Foundation collection as catalog numbers 65/3 and 65/3a,
respectively.

LITERATURE CITED

Bonnier. J. 1900. Contribution a l’Etude des Epicarides: Les Bopyridae. Publica-
tions de la Station Zoologique de Wimereux. I. Travaux de la Station.
8: 1-478.

DaNFOoRTH, C. 1963. First record of a Hawaiian shore bopyrid (Isopoda: Bopyri-
dae). J. Parasitol., 49: 847-850.

1967. Northern Pacific Gigantione (Isopoda). Biol. Bull., 132: 147-155.

Nrerstrasz. H.. AND G. BRENDER A BRANDIS. 1929. Papers from Dr. Th. Morten-
sen’s Pacific Expedition. 1914-1916. Epicaridea I. Videnskabelige Med-
delelser fra Dansk naturhistorisk Forening i Kgbenhavn, 87(48): 1-44.

1931. Three new genera and five new species of parasitic Crustacea. Proc.
U. S. Nat. Mus., 77(9): 1-9.

RICHARDSON, H. 1904. Contributions to the natural history of the Isopoda. Second
Part. V. Isopod crustaceans of the Northwest coast of North America. Proc.
U. S. Nat. Mus., 27: 657-681.

1905. A monograph on the isopods of North America. Bull. U. S. Nat.
Muts., 54: 1-727.

1911. Description of a new parasitic isopod from the Hawaiian Islands.
Proc. U. §. Nat. Mus., 38: 645-647.

SHINO, S. 1964a. On two species of bopyrid isopods parasitic on Callianassa
uncinata Milne-Edwards from Chile. Report of Faculty of Fisheries, Pre-
fectural University of Mie, 5: 27-32.

1964b. Results of Amami Expedition. 5. Bopyridae. Report of Faculty of
Fisheries, Prefectural University of Mie, 5: 237-242.

Accepted for publication November 30. 1969.

pleomere IV of female. F. Left and right pleopoda V of female. with intervening
pleomere VI. G. Ventral pleon of female, left pleopoda I-IV removed. H. Dorsal
view of adult male. I. Ventral aspect of pleomeres II-VI of male, pleopoda V
removed.

Bull. So. Calif. Acad. Sci. 69(1): 32-37, 1970

A SMALL COLLECTION OF CHIGGERS FROM SURINAM
(ACARINA: TROMBICULIDAE)

JAMES M. BRENNAN
U.S. Department of Health, Education, and Welfare, Public Health Service,
National Institutes of Health, National Institute of Allergy and Infectious Dis-
eases, Rocky Mountain Laboratory, Hamilton, Montana 59840.

ABSTRACT: Nine species of chiggers, one of them new, are
recorded for the first time from Surinam. Arisocerus, new
genus is described for A. amapensis, n. sp., off rodents from
northeastern Brazil and Surinam (holotype off Oryzomys
macconnelli, Amapa, Brazil), and A. hertigi (Brennan and
Jones, 1964), new combination.

INTRODUCTION

All species of Surinam chiggers recorded below were received from
Dr. Rupert L. Wenzel, Field Museum of Natural History, Chicago
and were collected during the Museum’s Guianan Zoological Expedi-
tion, 1960-62. Dr. Thomas H. G. Aitken, Rockefeller Foundation,
Belém, Para, Brazil contributed the majority of specimens of Ariso-
cerus amapensis, new genus, new species.

Arisocerus, new genus

Type species: Arisocerus amapensis, Nn. sp.

Trombiculine larvae ectoparasitic on mammals. Leg segmentation
7-7-7; 3 genualae I, a genuala II and III, tibiala III, sub- and parasub-
terminala, microtarsala I distad of tarsala I; coxae unisetose. Scutum
twice as wide as long with strongly sinuous anterior and posterior
margins; 5 setae; sensillae expanded and asymmetrical. Eyes 2/2, in
a plate. Cheliceral blade with tricuspid cap. Galeal seta nude. Palpal
tibial claw trifurcate; palpal tarsus with 6 branched setae, a subter-
minala, and a tarsala.

Referred species: Euschoengastia hertigi Brennan and Jones, 1964.

Arisocerus is the only neotropical genus having expanded, lopsided
sensillae and palpal tarsus with 6 branched setae and a subterminala.
Both included species have less than 30 dorsal setae.

Aristocerus amapensis, new species
Figure 1

Type data: Holotype and 9 paratypes, RML 49368, off Oryzomys
macconnelli, Serra do Navio, ICOMI, Amapa, Brazil, 15 March 1968,
T. H. G. Aitken; 12 paratypes, same data but 1 February 1968.

32

x New Species of Chiggers 33

Figure 1. Arisocerus amapensis, gen. n., sp. n. Scutum, eyes and specialized setae
. of legs with measurements in microns.

34 Bulletin So. Calif. Academy of Sciences

Holotype and some paratypes in the Rocky Mountain Laboratory;
other paratypes to be deposited in the United States National Museum,
Field Museum of Natural History and British Museum (Natural
History).

Other material: Surinam: 3 larvae off Oryzomys laticeps and 1 off
Myoprocta acouchy, Paloemeu Airstrip, Tapanahoni River, 30 May
1961, H. A. Beatty.

Brazil: 38 off 5 Oryzomys capito, Serra do Navio, ICOMI, Amapa,
9 February to 11 March 1968; 10 off 2 0. capito, APEG Forest
(IPEAN), Belem, Para, 22 October 1968 and 29 April 1969; 5 off 0.
capito, Catu Forest (IPEAN); 2 off 0. capito, Jandiai, Caratateua,
Braganga, Para, 1 April 1968; 4 off 2 Proechimys guyannensis, APEG
Forest, 11 September and 29 October 1968; T. H. G. Aitken.

Diagnosis: Distinguished from A. hertigi by more slender sensillae,
lacking a mastitarsala III, and AM>AL.

Body: Pinkish white to yellowish white in life, broad ellipsoidal
with slight constriction when engorged. Eyes small, 2/2, in a plate.
Anus at next to last row of ventral setae. Length and width of holotype,
nearly engorged, 421 by 287 microns.

Gnathosoma: Moderately punctate. Blades with small tricuspid cap.
Galeal seta nude. Palpal setae B/B/NNN, tarsus with 6 branched
setae, a subterminala and a tarsala, tibial claw apparently trifurcate.

Scutum: As figured, moderately punctate, with sinuous margins;
sensillae asymmetrically lanceolate with longish setules (71); PL>
AM>AL, anteromedian and anterolateral setae set back of margin.
Scutal measurements of holotype: AW 48, PW 60, SB 27, ASB 17,
PSB 12, AP 20, AM 33, AL 21, PL 41,S 41 x9.

Legs: As figured, moderately punctate. Specialized setae as figured.
Non-specialized setae sparsely to moderately branched. Coxal III seta
on anteromedian margin.

Body setae: Dorsal setae: humerals 38, , dorsals 33 to 37, arranged
in holotype 2-6-6-6-2-2. Ventral setae 2-2 plus 16.

Odontacarus tubercularis (Brennan)
Acomatacarus tubercularis Brennan, 1952.

Four specimens off Dasyprocta sp., Surinam, 1961 (no other data
available).

Boshkerria punctata (Boshell and Kerr)

Trombicula punctata Boshell and Kerr, 1942.
One specimen off Dasyprocta sp., Kaiserberg Airstrip, east bank of
Zuid River, 900 feet, October 1960, H. A. Beatty.

New Species of Chiggers 35

Calicus icomi (Brennan)
Calicus icomi Brennan, 1970.

Twelve larvae off Oryzomys laticeps, Paloemeu, Tapanahoni River,
30 May 1961, H. A. Beatty; 9 off Agouti sp., same location and col-
lector, June 1961; 2 off Didelphis marsupialis, Nickerie, Wilhelmina
Mt., October 1961; 4 off Proechimys sp., Suriname River, Carolina
Kreek, 26 November 1961, P. Hershkovitz.

Euschoengastia oblonga (Fauran)

Euschongastia oblonga Fauran, 1959.

Six larvae off Agouti paca, Kaiserberg Airstrip, Zuid River, 900
feet, 21 October 1960, H. A. Beatty. First record of this species since
it was described off same host species, French Guiana.

Crotiscus desdentatus tissoti Fauran

Crotiscus desdentatus tissoti Fauran, 1960.
One larva off Myoprocta acouchy, Paloemeu Airstrip, Tapanahoni
River, May 1961, H. A. Beatty.

Eutrombicula alfreddugesi (Oudemans)

Microthrombidium alfreddugesi Oudemans, 1910.

Many larvae, mostly of the tropica form, off Agouti paca, Dasy-
procta sp., Proechimys sp. and Sciurus sp.; Kaiserberg Airstrip, east
bank of Zuid River, 900 feet; October and November 1960; H. A.
Beatty.

Eutrombicula goeldii (Oudemans)

Microthrombidium goldii Oudemans, 1910.

Numerous larvae, off Agouti paca, Myoprocta sp. and Sciurus sp.;
Kaiserberg Airstrip, east bank of Zuid River, 900 feet; October and
November 1960; Myoprocta acouchy, Dasyprocta sp. and Mazama
gouazoubira; Paloemeu Airstrip, Tapanahoni River; April to June
1961; H. A. Beatty.

Tecomatlana (Hooperella) saccopteryx (Brennan and Jones) Trom-
bicula saccopteryx Brennan and Jones, 1960.

Many larvae off 2 Saccopteryx bilineata, Kaiserberg Airstrip, east
bank of Zuid River, 900 feet, November 1960, H. A. Beatty; 35 larvae
off S. bilineata, Brokopondo, Loksie Hattie, Saramacca River, 21
December 1961, P. Hershkovitz.

36 Bulletin So. Calif. Academy of Sciences

Trombicula palmigera Fauran

Trombicula palmigera Fauran, 1960.

Two larvae off opossum, Didelphis marsupialia, Nickerie, Wil-
helmina Mt., October 1961. First record since described off Dasyprocta
aguti, French Guiana.

The unique broom-like sensillae distinguish 7. palmigera from
other chiggers of the Western Hemisphere. The species is obviously
misplaced generically, but I have retained it in Trombicula s.1. because
insufficient material (the 2 specimens above and a paratype) precludes
accurate interpretation of such fundamental structures as palpal tibial
claw and palpal tarsal setation.

Pseudoschoengastia tricosa (Brennan and Jones)

Vanidicus tricosus Brennan and Jones, 1961.

One larva off Oryzomys laticeps, Paloemeu Airstrip, Tapanahoni
River, 30 May 1961, H. A. Beatty.

I follow Geest and Loomis, 1968 who state, ““The absence of dif-
ferentiation in characters and the close similarity to P. abditiva Bren-
nan has prompted us to synonymize Vanidicus with the genus Pseudo-
schoengastia.”

LITERATURE CITED

BOSHELL, J., AND J. A. KERR, 1942. Veinticinco especies nuevas de Trombidiideos
en Colombia. Rev. Acad. Colomb. Cienc. Exacta, Fisico-Quim. y Nat.,
5: 110-127.

BRENNAN, J. M. 1952. Two new Venezuelan chiggers (Acarina: Trombiculidae).
J. Parasitol. 38: 143-146.

1970. Colicus, a new neotropical genus with descriptions of two new
species and a key to included species (Acarina: Trombiculidae). J. Med. Ent.,
7: 271-273.

BRENNAN, J. M., AND E. K. JONES, 1960. Chiggers of Trinidad, B.W.I. (Acarina,
Trombiculidae). Acarologia 2: 494-539.

1961. New genera and species of chiggers from Panama (Acarina, Trom-
biculidae). J. Parasitol. 47: 105-124.

1964. Five new species of chiggers from South America (Acarina: Trom-
biculidae). J. Med. Ent. 1: 307-310.

FAuRAN, P. 1959. Nouveaux Trombiculidae de Guyane frangaise. Arch. Inst.
Pasteur Guyane frang. et Inini, no. 457, pp. 3-15.

FauRAan, P. 1960. Description de quatre nouvelles espéces et d’une nouvelle sous-
espece de Trombiculides de Guyane frangaise. Ibidem, no. 459, pp. 2-20.

New Species of Chiggers 37/

GEEST, J. C., AND R. B. Loomis, 1968. Chiggers of the genus Pseudoschoengastia
(Acarina: Trombiculidae) from Costa Rica. Contri. Sci. Los Angeles Co.
Mus. Nat. Hist. No. 150, 49 p.

OupEMans, A. C. 1910. Acarologische Aanteekeningen XXXIII. Ent. Ber.,
3: 83-90.

Accepted for publication October 24, 1969.

Bull. So. Calif. Acad. Sci. 69(1): 38-42, 1970

NEW MYRMECINAE (COLEOPTERA: CURCULIONIDAE)

ELBERT L. SLEEPER
Department of Biology
California State at Long Beach
Long Beach, California 90801

ABSTRACT: Myrmex vandykei, n. sp. from Prittleville, Arizona
and Myrmex setosis, n. sp. from Los Mochis, Sinaloa, Mexico
are described and illustrated. The genus Micromyrmex Sleep-
er is redefined. Oopterinus convexipennis Sleeper is placed in
the genus Micromyrmex.

Due to a long delay in my revision of the Myrmecinae it has become
necessary to extract the following descriptions of new species and
information in order that the names of the following species and the
included information can be used by others in the publication of certain -
research data. The following abbreviations have been used for collectors
or collections: (AMNH), American Museum of Natural History;
(CALB), Entomological Collections, University of California at
Berkeley; ELS, E. L. Sleeper Collr.; (ELS), E. L. Sleeper Collections
at California State at Long Beach; (MCAS), Entomological Collec-
tions, California Academy of Sciences.

Myrmex vandykei, new species
Figure 2

Myrmex octolineatus Van Dyke, 1930. (nec. Champion)

Holotype. ARIZONA, Cochise Co., Prittleville, VII-20-42, C. W.
Jones Collr., (ELS No. 63).

Male. Length 8.4 mm, width 3.2 mm, elongate, subcylindrical;
black with antennae and tarsi dark reddish brown; densely clothed with
recumbent, coarse white and finer erect black and white setae; the
setae on the elytra condensed in lines on each interval, those of intervals
2, 4, 6, and 8 much more dense, the odd intervals with a single line of
pubescence.

Rostrum cylindrical, shorter than prothorax, densely punctured;
with a narrow mid-dorsal carina and two lateral carinae; moderately
sulcate laterally. Head finely, deeply, densely punctured; the frons
with a round, deep puncture. Eyes widely separated, strongly convex.
Prothorax cylindrical, longer than wide, sides arcuate, widest at apical
third; pronotum strongly convex, finely sparsely punctured, a smooth
median line apparent from base to apex. Scutellum clothed with dense

38

New Species of Coleoptera 39

grayish pubescence. Elytra much wider at base than base of prothorax,
sides feebly divergent to just beyond middle then convergent to apex;
humeri obtuse; striae not impressed, punctures distant, very little larger
than punctures of intervals, intervals 2, 4, 6, and 8 with three or four
lines of punctures, odd intervals on disc with a single line of punctures.
Ventral side finely, densely punctured, clothed with erect white
setae with a few scattered radiate-pectinate scales. Fifth abdominal
sternite emarginate at apex. Legs coarsely deeply punctured; densely
clothed. Femora with a moderately large tooth. Anterior tibiae straight,
feebly sinuate mesially at middle.

Female. Length 8.5 mm, width 3.3 mm. Differing from the male
only in the convex abdominal sternites and the evenly arcuate apical
margin of sternite 5.

Type material. ARIZONA, type locality, (holotype 3, allotype 2)
(ELS). Paratypes as follows: 2 2 2,Sunnyside, VII-22-42, W.A. Johnson,
(ELS); 2 292, 14 mi. SW Tubac, VIII-20-43, (ELS); 2 $3,192, 14mi.E
Oracle, VII-27-24, J. O. Martin, (MCAS); 238, 5 99, 14 mi. E
Oracle, VII-27-24, E. P. Van Duzee, (MCAS); 2 33, 2292, same
data (ELS); | 3, Chiricahua Mts., [X-8-27, J. A. Kusche, (MCAS);
2 22, Douglas, VII-22-33, W. W. Jones, 2 °°, Douglas, VII-27-
34, W. W. Jones, (CALB); 1 3, Douglas, VII-27-34, W. W. Jones,
(ELS). Other examples have been examined from the Huachuca,
Santa Rita, and Chiricahua Mts. in Arizona.

This species has been previously referred to as Myrmex octolineata
(Champion), but comparison of the material with the type of octo-
lineata, which was from Chilpancingo in Guerrero, Mexico, has
shown our species to be different. M. vandykei differs in that Octo-
lineata has stripes on the elytra about half the width of those of
vandykei, with the setae much denser and lying quite flat; the setae
are more conspicuously white; the prothorax is much narrower, almost
parallel-sided, the. punctures very sparse and almost obliterated; the
teeth on the anterior femora is much larger and broadly triangular.

This species is named in honor of Dr. E. C. Van Dyke who was of
so much assistance at the beginning of the study of the Myrmecinae.

Myrmex setosis, new species
Figure |

Holotype. MEXICO, Sinaloa, Los Mochis, VII-25-1922, E. P.
Van Duzee (MCAS No. 8993).

Male. Length 4.7 mm, width 1.9 mm, elongate, strongly convex;
shining, dark reddish black, with the antennae and tarsi reddish brown;

40 Bulletin So. Calif. Academy of Sciences

Figure 1. Dorsal view of Myrmex setosis Sleeper, paratype, San Carlos Bay,
Gulf of California, Mexico. Figure 2. Dorsal view of prothorax and elytra of —
Myrmex vandykei Sleeper, holotype, showing median pronotal carina and
arrangement of setae on elytra. Figure 3. View of head and prothorax of holotype
of Micromyrmex convexipennis Sleeper Line= 1.0 mm.

densely clothed with bristly white setae which are placed in confused
double or treble rows on all elytral intervals.

Rostrum three-fourths as long as prothorax, straight, cylindrical,
coarsely, deeply punctate-sulcate laterally, a smooth median line at
middle; sparsely clothed with erect white setae. Antennae inserted
just beyond middle; segment | of funicle robust, elongate, one-half
longer than 2; 2 elongate, a little longer than 3; the remainder subequal,
moniliform. Club ovate, moderately pubescent. Head coarsely, deeply
but not densely punctured; a small deep fovea between the eyes. Eyes
convex, separated by about their width. Prothorax longer than broad,
sides arcuate, basal constriction not very prominent; closely, coarsely,
deeply punctured throughout. Scutellum small, triangular and densely
clothed with white pubescence. Elytra elongate, the sides divergent to
near middle, then strongly rounded to apices; striae deeply impressed,
strial punctures round, coarse, deep, close-set, about their diameter
apart; intervals very strongly convex, with a few scattered minute
punctures. Ventral side sparsely clothed with long erect, fine white
setae and a few scattered radiate-pectinate scales. Abdominal sternites
sparsely, shallowly punctured; sternite 1 narrowly, longitudinally
depressed at middle, 5 feebly emarginate at apex. Legs sparsely
clothed with erect white setae. Femora with a moderately large tooth.
Anterior tibiae strongly sinuate within, broadest at middle.

New Species of Coleoptera 41

Allotype. Female. Differing from the male only in that the rostrum
is seven-eighths as long as prothorax, more slender, abdominal sternite
1 is strongly convex without a depression, and segment 5 is not emar-
ginate at apex. Length 4.6 mm, width 1.7 mm.

Type Material. MEXICO, type locality (holotype 3, allotype @)
(MCAS). Paratypes as follows: 1 3, San Caxlos Bay, Gulf of California,
VII-8-21, (ELS); 2 °°, Sonora, Nuevo Navojoa, Santa Rosa Ranch,
VII-1-52, P. & C. Vaurie, (AMNH); 1 3, Sonora, | mi. NW Navojoa,
VIIi-7-63, ELS, (ELS). The author has used the manuscript name of
the late Dr. E. C. Van Dyke for this species. He had apparently studied
it but failed to publish the results of his study.

This species is nearest M. pellicea (Rosensk.) but may be easily
separated by its smaller more elongate form, the strongly convex and
not confusedly punctured elytral intervals, the more erect white setae
and the absence of a depression in the middle of the fifth abdominal
sternite.

A single example from Santa Rosa Ranch has a few scattered erect
black setae at the declivity. Due to the prescence of these black setae
this example will key out near M. setiger (Champion). This species
differs from setiger in having fewer black setae on the dorsum, the
smaller femoral tooth, and the strongly convex elytral intervals.

Micromyrmex Sleeper

Micromyrmex Sleeper, 1953.

Type species. Otidocephalus poeyi Chevrolat.

Narrowly subcuneate, strongly convex, body nearly glabrous, a
few erect setae around apex and base of prothorax, a few thicker, long
erect white setae scattered over elytra. Rostrum of male short, from
one-half to two-thirds as long as prothorax, female two-thirds to
four-fifths as long as prothorax, slightly arcuate in both sexes. Antennal
club nearly as long as preceding 5 segments, strongly annulated. Eyes
large, prominent, separated by a little less than their own width. A
supraocular ridge with a ventral groove or sulcus extending laterally
behind eyes toward prothorax. Pronotum obovate, longer than wide,
strongly convex, strongly constricted at base. Scutellum distinct,
densely clothed with recumbent pubescence. Elytra oblong-oval, wider
than pronotum, strongly convex; disc with feebly impressed striae and
punctures. Prosternum very short in front of anterior coxae which are
contiguous; abdominal sternite 2 nearly as long as 3 and 4 combined,
suture between | and 2 almost obsolete. Legs long, slender; femora

42 Bulletin So. Calif. Academy of Sciences

completely unarmed, anterior tibiae straight within, not sinuate;
tarsal claws divergent, toothed.

As the genus has been redefined the following species should be
included within it: Micromyrmex cavirostris (Casey), insularis Sleeper,
poeyi (Chevrolat), pulicaria (Boheman), Otidocephalus formicarius
(Oliver), NEW COMBINATION, and Oopterinus convexipennis Sleeper,
NEW COMBINATION. Most Myrmecinae seen to present from the
Antilles belong in Micromyrmex.

Micromyrmex convexipennis Sleeper, NEW COMBINATION
Figure 3

Oopterinus convexipennis Sleeper, 1954.

This species was originally described in Oopterinus because of the
apparently effaced humeri on the holotype. Since the original descrip-
tion more material has been studied from the type locality. The humeri
are slightly more pronounced in the additional material and it is quite _
obvious that it is not an Oopterinus in which the humeri are entirely
effaced. The failure to associate the sulcus or groove behind the eye
with the genus Micromyrmex is rather embarassing and can be con-
sidered nothing other than a careless oversight.

This is to the present, the only known species of Micromyrmex
from either Central or South America. In the large volume of material
examined during revisionary studies no other species was detected.
Inasmuch as Puerto Bello (type locality) was the main port of com-
merce between the Antilles and Panama, this species may prove to be
an introduced species in that limited area from an, as yet, unknown
locality in the Antillean Chain. The removal of this species from
Oopterinus Casey now limits the range of that genus to the north of
Central Guatemala.

LITERATURE CITED

SLEEPER, E. L. 1953. New genera and species of Curculionidae with a new species
of Anthribidae. Ohio J. Sci. 53: 113-120.

1954a. New Myrmecinae from Central America. Ohio J. Sci., 54: 342-346.
1954b. New Myrmecinae from the Antilles. Ohio J. Sci., 54: 349-351.

Accepted for publication November 30, 1969.

Bull. So. Calif. Acad. Sci. 69(1): 43-51, 1970

COMMUNICATION SYSTEMS AND ORGANIZATIONAL
SYSTEMS IN THREE SPECIES OF RODENTS

GEORGE F. FISLER
Department of Biology
San Fernando Valley State College
Northridge, California 91324

ABSTRACT: Studies of intraspecific agonistic encounters be-
tween individuals of Cavia porcellus, Reithrodontomys mega-
lotis, and Meriones unguiculatus have shown that the number
and complexity of acoustical and visual signals is correlated
with the complexity of the organizational system of the species
involved. The signals as observed are listed and compared.
The greatest number of signals is used by the more complexly
organized Cavia, the least by the apparently unorganized
Meriones. Relatively complex signals can develop in groups
regardless of the primary sensory apparatus utilized.

INTRODUCTION

In a recent paper (Fisler, 1969), some possible stages in the continuum
of organizational systems of mammals, from species holding simple,
individual territories through those displaying dominant-subordinate
relations to those species exhibiting more complex group organizations,
have been outlined. Perusal of the tables which show various species
exhibiting these possible relationships between and among individuals
and groups reveals that acoustical and visual communication systems
are distributed from simpler to more complex arrangements in a
parallel manner, that is, the more complex communication systems are
found in those species with the more complex social relations. In
evolution of these signals, it is not unexpected that they should be
influenced by the nature of the organizational system utilized by each
species. This correlation also became obvious on review of my work
on harvest mouse (Reithrodontomys) societies in the laboratory and
field (1965), the nature of aggressive and submissive responses in
Reithrodontomys megalotis (unpublished), and studies of rhesus mon-
key (Macaca mulatta) behavior (1967). Work with Peromyscus mani-
culatus (Eisenberg, 1962) has also shown developments similar to
Reithrodontomys. Recent studies of primates (see Marler, 1965) have
shown the complexity to which animals in organized group situations
have evolved in their communication patterns, so far culminating in
the communication systems (natural and artificial) found in man. This
obvious phenomenon with regard to communication signals (acoustical

43

44 Bulletin So. Calif. Academy of Sciences

and visual) is best observed during agonistic encounters, and, because
few data or comparative studies are available, particularly for rodents,
I undertook a study of the aggressive-submissive postures and vocaliza-
tions in two additional species, the guinea pig (Cavia porcellus) and the
jird (Meriones unguiculatus). King (1956) has studied laboratory
guinea pigs in a seminatural environment and has described the social
organization of these animals, but has given only a brief account of
their acoustical and visual signals. Little information of this nature
exists for wild species of Cavia or Meriones (see Walker, et al., 1968).
Whether the sequences of behavioral events in agonistic encounters
as observed in the laboratory also occur in wild situations is uncertain.
King (1956) felt that studies of “domestic” forms would reveal the
basic social patterns of natural populations of Cavia, and I previously
pointed out (1965) that certain laboratory situations may tend to inten-
sify, but not obscure, behaviors which are natural in field encounters.

Therefore, a comparison among these rodents (Cavia, Reithro-
dontomys, and Meriones) with regard to the complexity of their
organizational systems and the complexity of communications signals
in agonistic encounters has been attempted. These species undoubtedly
rely on some olfactory signaling as well. Indeed, recent work (Ropartz,
1968) has shown that olfactory stimuli may release (hence control)
aggressive behavior in male mice (presumably Mus musculus), as
bulbectomized animals were totally nonaggressive. But the work of
Ropartz does not offer any analysis of olfactory communication per se,
and such analysis has rarely been accomplished for any species of
mammal. Therefore only acoustical and visual signals will be compared
here.

Also, since there is much data available on primate aggression,
social organization, and communication signals, with a similar correla-
tion between complexity of organization and communication signals,
an analogy will be drawn from lemur and rhesus monkey societies.

METHODS

The studies of Cavia porcellus consisted of observations of the estab-
lishment of hierarchies of both sexes (but particularly males) in a cage
measuring 4 x 8 x | feet. Three or four males were introduced simul-
taneously and observations were made on the aggressive encounters
between individuals until stability in the hierarchy was obtained. Nine
such experiments were observed for males, two for females, and three
for situations where both sexes were present. No animals were used
in experiments with animals to which they had previously been

Rodent Behavior 45

exposed. The results of these hierarchy studies will not be presented
here, as only the communication systems employed in their establish-
ment are pertinent.

The work with Reithrodontomys consisted of mate selection experi-
ments similar to those of Blair and Howard (1944) using two pairs of
sexually active mice in a four-compartmented cage (details in Fisler,
1965). In order to verify these earlier results concerning aggressive
encounters observed and inferences drawn from the selection cage
data, pairs of sexually active male R. megalotis were tested. Twenty-
three such encounters were staged in cages measuring 10 x 17 x 8
inches for periods of from two to seven days. None of the males used
had been caged together previously. Data from these cages were col-
lected by watching initial encounters (one to three hours), checking
for later evidence of fighting (cuts), and by observing subsequent
actions of the individuals, particularly the subordinate.

Studies of Meriones unguiculatus were exceedingly simple, since
little aggression was noted. Animals in varying numbers were main-
tained in the same cage (13 x 15 x 18 inches) and observations similar
to the preceding were made. Six pairings between males which had
never been caged together were also observed, with results comparable
to those of the multiple caging arrangement.

RESULTS AND CONCLUSIONS

The results of these observations are presented in Table 1 with com-
parative data for the rhesus monkey (modified from Altmann, 1962)
also included. The left-hand column of Table 1 contains a subjective
linear numerical scale (0-10, O- -10) showing degree of aggression or
submission. Highest intensity aggression and highest intensity sub-
mission have been arbitrarily assigned numerical values of 10 and
-10, respectively. This linear scale will assist in the equilibration of
different kinds of signals which are functionally identical and should
clarify interspecific comparisons. Perusal of the identifiable acoustical
and visual communication signals used in intraspecific aggressive
encounters shows that the signals of the organized group living species
(Macaca, Cavia) are more complex and extensive than are the signals
of the individualistic living forms (Reithrodontomys, Meriones).
Meriones exhibits little aggression (or submission). Individuals
in my colony are so docile that one wonders if there can be any hier-
archy or territory of any type in this species. Wechkin (1969) has also
surmised from laboratory studies that natural dominance hierarchies
are absent in this species. The closest thing to aggression observed in

Bulletin So. Calif. Academy of Sciences

46

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Rodent Behavior 47

my colony was the “nose push” which is simply a shoving of another
individual with the snout, which may or may not be successful in
“displacing,” or rather moving, the other animal slightly. If the receiver
moves away, this may indicate that the other animal (transmitter) is
dominant, but this was never clear nor consistent among individuals.
The only other signaling motion was a foot stomping (pattering) with
either hind foot, a movement common to many small rodent species.
This seemed to be either (or both) an interspecific or intraspecific
warning rather than an aggression-submission signal. No chasing, bit-
ing, or other destructive means of communication were noted in this
species. Indeed, even females with young did not prevent other individ-
uals of either sex or any age from entering the nest chamber. This type of
organizational system shown by Meriones in the laboratory seems to
fit the “undefended home range” category of Fisler (1969).

The series of aggressive and submissive signals of Reithrodontomys
megalotis closely follows those previously described for Peromyscus
maniculatus by Eisenberg (1962; 1968). The events of fighting for
mice have been described several times, particularly for Rattus and
Mus (for example, Scott and Fredericson, 1951; Barnett, 1963), so I
will not elaborate on these here. However, the defeat and submission
categories (Table 1) need explanation. Defeat (9) is signified by an
animal turning on its back voluntarily, open mouthed, and squealing.
Submission is the highest intensity submissive signal (-10) and occurs
when an animal cowers in a corner or in some semiprotected area in
the cage, becomes silent, and submits to any abuse that the aggressor
cares to inflict. The subordinate animal offers no resistance whatever.
(This usually appeases the aggressor and no further damage is done.)
In defeat, an animal still exhibits some threat, turning on its back and
“facing” the opponent. While this is usually thought of as submission,
the defeated animal is still exhibiting aggression to some degree. Total
submission elicits no defense at all, that is, no aggression. (Comments
on defense and aggression are given in Fisler, 1969.) Apparently, there
are few differences between Peromyscus maniculatus and Reithro-
dontomys megalotis in these actions.

Reithrodontomys megalotis and Peromyscus maniculatus show some
organization of individuals into territories (spatial or nidic territories,
Fisler, 1969) during the breeding season and concomitantly they also
have developed more overt means of communicating status to each
individual. But since these systems are found only during the breeding
season, and both species revert to an undefended home range (Fisler,
1969) during the nonbreeding season, elaboration of the communica-
tion system beyond its usefulness during breeding was not advanta-

48 Bulletin So. Calif. Academy of Sciences

geous. (The effect, if any, of nocturnality is not easily assessed.) There
has been no selection for more intricate social communication devices.
Simple approach, touch, bite, retreat, and cower activities suffice. Even
vocalizations seem restricted to cries of pain, or perhaps submission.

Species living in organized groups must continually communicate.

Even simple hierarchical systems as exhibited within a Cavia group
must be maintained by a more elaborate set of signals, including more
vocalizations (see Table 1), than found in the preceding species. Cavia
uses both visual and acoustical signals to maintain group order. Even
after establishment of hierarchies, frequent vocalization can be heard
when a subordinate animal does not move away from a dominant
individual quickly enough. In Reithrodontomys, displacement is
usually accomplished by a short “chase” (“turn toward,” level 3 of
Table 1), whereas in Cavia warning vocalizations occur before any
serious chasing occurs (level 3 of Table 1).

The following is a summary of the acoustical and visual aggressive

and submissive signals as seen in my experimental cages for Cavia.

Bites — obvious, includes fighting

Nibbles — “gentle” biting, preceding a fight

Chases actively — a fast-moving chase

Side display — as in other rodents (see Eisenberg, 1968)

Chatters teeth — obvious, clattering of teeth

Squeaks — an offensive squeak, not a submissive squeal

Head up — a display in which each animal appears to be trying to
keep its head above that of the other. Occasionally they will stand
on hind legs briefly, but this is not common. Also one may stand
with its fore feet on a raised object in the cage. This display is
sometimes accompanied by any of the preceding three displays.

Chases passively — this is a low intensity chase, slow moving, but
faster than normal walking, and is usually accompanied by
whimpering

Whimper — a nervous vocalization frequently given by guinea pigs
when in any stressful situation (probably “chirp” of King, 1956)

Ignores — neither appears to pay any attention to the other.

Avoids passively — the turn away of the other species compared
here (Table 1). Animal simply turns so that it is neither facing, nor
side presenting to the other animal.

Avoids actively — this is the antithesis of chasing passively; a slow-
moving retreat from the dominant but not much more rapid than
normal walking

Flees —a rapid flight from the dominant, may be accompanied by
squeals

Submission — as for Reithrodontomys

Rodent Behavior 49

Finally, the communication system in rhesus monkeys (and several
other primates) has been described and discussed (Altmann, 1962,
1965; Andrew, 1963, 1964; and others). Data from Altmann (1962)
are presented here to illustrate the refinement present in communica-
tion used by these monkeys in comparison to the rodents discussed
earlier and to show the effect of the primary sense used. Olfaction
has been superseded as a prime sense in this monkey (Napier and
Napier, 1967), and it has become essentially a visual animal with a
complex communication and organizational system. This could
indicate that the use of vision as the primary sense might be necessary
in order to develop complex organizational systems. However, this
can be refuted by a comparison between rhesus monkey societies and
lemur societies. The complexity of the organizational system and the
concomitant complexity of acoustical and visual signals in several
species of lemurs which are essentially animals using primarily a
chemical sense (Jolly, 1966), and hence more rodent-like in this regard
when compared to the macaques, shows that organizational complexity
is not limited by the primary sense involved exclusively, and complex
communication systems can develop where vision is not the primary
sense. Any complex society will have developed sufficient communi-
cation devices in order to inform each individual within that society of
its own place in relation to the remainder of that society, regardless of
the primary sense used or the taxon involved.

Marler (1965) has pointed out how the relatively ill-defined structure
of most sound signals in some monkeys is correlated with the close
knit social groups, a situation where shades of differences and mean-
ings (hence multiplication of the number of possible signals) can be
developed. However, where individuals are scattered in dense habitat
and hence not in close contact,visual signals are not useable and acous-
tical signals probably would only attract predators, particularly in
small, secretive prey species such as most rodents. Selection has not
favored the development of conspicuous signaling devices, and so
fewer signals have been available for use in intraspecific agonistic
encounters. Furthermore, development of obvious aggressive signals
solely for that purpose has not occurred because of the potential danger
from predation. However, complexity of signaling will increase with
the development of complexity of organization partly because grouping
loses much of the concealing effect afforded to scattered individuals
and more complex signals may be employed (as has been pointed out
here for Cavia). In the case of Meriones, however, grouping has
occurred but organization is minimal (status is apparently not impor-
tant for individual survival), so there has been no selection for increased
signaling.

50 Bulletin So. Calif. Academy of Sciences

Determination of the complexity to which any organizational system
will develop depends on the morphology, physiology, behavior, and
ecology of the species. The differences shown here among the systems
of Meriones, Reithrodontomys, and Cavia clearly illustrate that
communication complexity is correlated with organizational com-
plexity and that both, concomitantly developed with other adaptations,
will evolve in parallel regardless of which senses are used to transmit
and receive signals.

LITERATURE CITED

ALTMANN, S. A. 1962. A field study of the sociobiology of rhesus monkeys, Maca-
ca mulatta. Ann. New York Acad. Sci., 102: 338-435.

. 1965. Sociobiology of rhesus monkeys. II: Stochastics of social com-
munication. J. Theoret. Biol., 8: 490-522.

ANDREW, R. J. 1963. The origin and evolution of the calls and facial expressions
of the primates. Behaviour, 20: 1-109.

. 1964. The displays of the primates. In Buettner-Janusch, J., ed., Evolu-
tionary and genetic biology of primates, Academic Press, New York and
London. vol. 2: 227-309.

BARNETT, S. A. 1963. The rat: A study in behaviour. Aldine Publishing Comp.,
Chicago. 288 p.

Biair, W. F. AND W. E. Howarp. 1944. Experimental evidence of sexual isolation
between three forms of mice of the cenospecies Peromyscus maniculatus.
Contrib. Lab. Vert. Biol., Univ. Mich., No. 26, 19 p.

EISENBERG, J. F. 1962. Studies on the behavior of Peromyscus maniculatus gam-
belii and Peromyscus californicus parasiticus. Behaviour, 19: 177-207.

. 1968. Behavior patterns. /n King, J. A., ed., Biology of Peromyscus
(Rodentia), American Society of Mammalogists. p. 451-495.

FISLER, G. F. 1965. Adaptations and speciation in harvest mice of the marshes of
San Francisco Bay. Univ. Calif. Publ. Zool., 77: 1-108.

. 1967. Nonbreeding activities of three adult males in a band of free-
ranging rhesus monkeys. J. Mammal., 48: 70-78.

. 1969. Mammalian organizational systems. Contrib. Sci., Los Angeles
Co. Mus., No. 167, 32 p.

JoLty, A. 1966. Lemur behavior, a Madagascar field study. Univ. Chicago Press,
Chicago and London. 187 p.

KiNG, J. A. 1956. Social relations of the domestic guinea pig living under semi-
natural conditions. Ecology, 37: 221-228.

MARLER, P. R. 1965. Communication in monkeys and apes. Jn DeVore, I., ed.,
Primate behavior, Holt, Rinehart and Winston, New York. p. 544-584.

NaPIER, J. R. AND P. H. Napier. 1967. A handbook of living primates. Academic
Press, London and New York. 456 p.

Rodent Behavior 51

Ropartz, P. 1968. The relation between olfactory stimulation and aggressive
behaviour in mice. Anim. Behav., 16: 97-100.

Scott, J. P. AND E. FREDERICSON. 1951. The causes of fighting in mice and rats.
Physiol. Zool., 24: 273-309.

WALKER, E. P. et al. 1968. Mammals of the world. 2nd ed., J. L. Paradiso, ed.,
Johns Hopkins Press, Baltimore, Md. 2 vols., 1500 p.

WECHKIN, S. 1969. Social dominance in the Mongolian gerbil Meriones unguicu-
latus. Bull. Ecological Soc. America, 50: 89-90.

Accepted for publication November 30, 1969.

Bull. So. Calif. Acad. Sci. 69(1): 52-59, 1970

A NEW SUBGENUS AND TWO NEW SPECIES
OF HEXIDIONIS (ACARINA, TROMBICULIDAE)
FROM NORTH AMERICA!

RICHARD B. LOOMIS AND JAMES L. LUCAS
Department of Biology
California State College
Long Beach, California 90801

ABSTRACT: A new subgenus, Zosteridionis, is proposed for five
species, including the type species Hexidionis deserti, n. sp.,
type locality, 3 mi. SE Needles, San Bernardino Co., Cali-
fornia, off Dipodomys m. merriami. The subgenus Hexidionis
consists of five species including, Hexidionis macropus, N. sp.,
from La Burrera, Baja California Sur, Mexico, off Peromyscus
eremicus.

INTRODUCTION

Further studies of chiggers from western North America have un-
covered two additional species of the genus Hexidionis Vercammen-
Grandjean and Loomis.

In addition, the genus Hexidionis is divided into two subgenera
each with five species. The division is based upon larval characteristics.

Grateful acknowledgment for helping to assemble these and other
chiggers is extended to many individuals including: R. M. Davis, L. K.
Tanigoshi, L. C. Spath, W. L. Hunter, D. E. Harvey, K. D. Peyton,
J. P. Webb, Jr., W. J. Wrenn and Dr. E. L. Sleeper. We also wish to
thank Elaine Katzer for her excellent drawings.

Zosteridionis, new subgenus

Type species. — Hexidionis deserti Loomis and Lucas, new species.

Included species. — Trombicula polytechnica Hoffmann, 1963; T.
breviseta Loomis and Crossley, 1963; T. doremi Brennan and Beck,
1956; Hexidionis harveyi Loomis and Lucas, 1969.

Diagnosis. — Larva. Characteristics of genus Hexidionis, but dif-
fering from the subgenus Hexidionis in having ratio of distance between
dorsal genualae to length of genu I less than 0.3 (greater than 0.3 in
subgenus Hexidionis); more than 80 dorsal body setae (less than 80
dorsal body setae); with 3 genualae I (2 or 3 genualae I); and dorsal
proximal seta of palpal tarsus expanded at base with bifurcation of
distal half (seta with narrow base and without bifurcation).

1The studies upon which this paper is based were supported by a research grant
AI 03407 from the National Institute of Allergy and Infectious Diseases.

S72

New Species of Chiggers 5)3)

Remarks. — The major larval characters used to separate the two
subgenera are: 1) the distance between dorsal genualae as a ratio to
length of genu I; 2) the number of dorsal body setae; 3) the number of
setae on genu I; and 4) the size and shape of the dorsal proximal seta
on the palpal tarsus.

Initially Vercammen-Grandjean and Loomis (1967) proposed two
subgenera in Hexidionis, Hexidionis from North America and Penti-
dionis from northern Africa and Asia Minor. Lucas and Loomis (1969)
elevated Pentidionis to generic status based upon differences in larval
characteristics.

The five species of the subgenus Zosteridionis are known from
southern Nevada and southwestern Utah southward to central Mexico,
and there are a few known cases of sympatry. However, there are
numerous records of members of both subgenera occurring at the
same locality throughout southwestern United States.

Zosteridionis is a compound Greek word, zoster — band or girdle
and idion —a diminutive suffix. Literally translated, Zosteridionis
means “little girdle” and refers to the small bands, or girdles, seen in
the legs of larvae belonging to the genus.

Hexidionis (Zosteridionis) deserti, new species
Figure |

Types. — Holotype and 17 paratopotypes from 3 miles southeast
of Needles, 600 ft., San Bernardino Co., California; original numbers
WJW611014-18 (holotype and 5 paratopotypes), WJW611014-15
(5), WJW611014-14 (7); host Dipodomys merriami merriami (Mer-
riam’s kangaroo rat); taken 14 October 1961 by W. J. Wrenn and N.
G. Puckett.

Diagnosis. — Larva. Resembling Hexidionis doremi in having
similar scutal shape, gnathosomal setation and specialized setae on
legs; but differing from it in having longer dorsal body setae (25, )
only slightly expanded; total leg measurement greater than 1,000; and
humeral setae well-defined and longer than dorsal body setae.

Description. — Based on holotype with differences noted among
paratopotypes. All measurements are in microns.

Body: Nearly round; color in life orange; eyes 2/2, ocular plate
indistinct.

Gnathosoma: Cheliceral base punctate; blade slender with tri-
cuspid cap. Palpal setae B/B/NNB, palpal tarsal setae 7BS, palpal
tibial claw trifurcate. Galeala with numerous branches.

Scutum: About 1.5 width/length with posterior three-fourths punc-

54 Bulletin So. Calif. Academy of Sciences

tate. Lateral margins sinuous, anterior margin perpendicular to lateral
margins, posterior margin concave. Sensilla filiform with barbs on
proximal three-fourths and distal one-fourth having 8-10 branches.

Scutal measurements of holotype and (in parentheses) mean and
extremes of 10 types. AW 77 (77, 72-82), PW 85 (86, 83-91), SB 30
(31, 28-34), ASB 28 (30, 27-33), PSB 21 (22, 20-25), AP 17 (17, 16-
19), AM 41 (39-42, 8), AL 42 (38, 33-42, 9), PL 44 (44, 37-48), S 78
(80, 75-90, 9).

i oS
| BIN ~ : Os
SSIRIN GOST SI NORGE ARES

Figure 1. Hexidionis (Zosteridionis) deserti, n. sp. A. Scutum and eyes. B. Dorsal
aspect of gnathosoma. C. Ventral view of palpal tibia and tarsus. D. Leg I —
genu, tibia and tarsus with nude setae, bases of branched setae and with measure-
ments in microns. E. Leg II. F. Leg III. G. Representative body setae: /st, first
sternal; H., humeral; PD, posterior dorsal.

New Species of Chiggers SS)

Body setae: All body setae with many branches. Dorsal setal formula
for holotype 2 (humerals) -10-10-10 plus approximately 80; measure-
ment of humeral seta 39, posthumeral seta 25, posterior dorsal seta
36. Ventral setae 2-2 plus approximately 55 preanal setae, measure-
ment of first sternal seta 37, small posterior seta 27. Total body setae
approximately 171.

Legs: All coxae lightly punctate. Leg I with 3 genualae, subequal,
(18-19-21), microgenuala; 2 tibialae (15-15), microtibiala; tarsala
(27), microtarsala, subterminala (23), pretarsala (9). Leg II with
genuala (15); 2 tibialae, subequal, (15-17); tarsala (28), microtarsala,
pretarsala (9). Leg III with genuala (17); tibiala (19). All legs with
internal bands in genu (2-3), tibia (2-3) and tarsus (5-8). Each leg
having 2 claws with 2-5 onychotriches and a clawlike empodium with
2-3 onychotriches.

Leg lengths of holotype and (in parentheses) mean and extremes of
10 types: leg I 379 (396, 375-426), leg II 330 (346, 309-390), leg III
372 (390, 360-442), total leg lengths 1081 (1132, 1048-1248).

Remarks. — In Hexidionis deserti the two humeral setae are dis-
tinctly longer than the dorsal setae of the first posthumeral row;
whereas, in H. doremi all of these setae are approximately equal.

Ecological notes. — Hexidionis deserti is found throughout the
Mojave and Sonoran Deserts. Most of the larvae were from Dipo-
domys m. merriami and D. deserti. The principal parasitope is the
face, especially around the external nares and the margins of the cheek
pouches.

The larvae of H. (Z.) deserti were found on hosts in the cooler
months between September and June.

The type locality had a few Ocotillo (Fouquieria splendens) and
Creosote bushes (Larrea divaricata), along sandy dry washes with
steep clay banks containing mammal burrows.

Specimens examined (520).

Hexidionis (Zosteridionis) deserti (513), all hosts Dipodomys mer-
riami, unless otherwise noted. USA. ARIZONA-Pima Co.: 1 mi. N
Montezuma’s Head, Organ Pipe Cactus Natl. Mon., 9 Nov. 1962 (18).
CALIFORNIA-San Bernardino Co.: 3 mi. SE Needles, 14 Oct. 1961
(38, including types); 8 mi. S Barstow, 4 Nov. 1962 (7), 5 Nov. 1962
(9), 21 Nov. 1962 (4), 26 Jan. 1963 (4), 2 Sept. 1963 (25), 24 Jan.
1964 (4), 22 Feb. 1964 (3); 0.7 mi. N Morongo Valley, 20 July 1962
(9), 19 May 1962, Perognathus longimembris (1); Giant Rock, 23
Sept. 1961 (7); Indian Cove, in Joshua Tree Natl. Mon., 22 Jan. 1961
(1). Kern Co.: 17 mi. W Rosamond, 23 Sept. 1964 (16). Riverside Co.:
9.1 mi. NE Desert Center, 3 May 1964 (4), (the following all from
Joshua Tree Natl. Mon.), Pinto Wash Well, 6 Aug. 1965 (16), 13 Nov.

56 Bulletin So. Calif. Academy of Sciences

1966 (1); 4.5 mi. S Cottonwood Spring, 12 March 1966 (8); 4.2 mi.
NE Old Dale Jct., 20 May 1961, Perognathus formosus (4), 2 Dec.
1963 (69); 7 mi. N Cottonwood Spring, 23 Jan. 1961 (42); Pleasant
Valley, 26 Nov. 1962 (46); Long Canyon, 16 March 1963 (10), 20
April 1963 (2), Perognathus fallax (2). Imperial Co.: 10.5 mi. S, 2.5
mi. W Plaster City, 30 Jan. 1965 (47); 12 mi. S Palo Verde, 2 Nov.
1964 (1). San Diego Co.: Anza Borrego Desert State Park, 16 Nov.
1958 (1); 0.1 mi. SW Ranger Station, 13 June 1961, Perognathus
fallax (3). NEVADA-Nye Co.: 15 mi. N Death Valley Jct. (T & T
Ranch), 19 Oct. 1963 (7). MEXICO. SONORA: 55 mi. SE San Luis,
30 Nov. 1964 (11); 10 mi. N Puerto Penasco, 30 June 1965, Dipo-
domys deserti (11); 4 mi. SE San Luis, 29 June 1965, D. deserti (3).
BAJA CALIFORNIA NORTE: 30 mi. S San Felipe, 21 Dec. 1960
(79).

Hexidionis (Zosteridionis) doremi (7). UTAH-Washington Co.:
Rockville, 6 Sept. 1951, Dipodomys merriami (1 paratype). CALI-
FORNIA-Inyo Co.: Grandview Camp, White Mountains, 14 Aug.
1964, Perognathus parvus (6)

Subgenus Hexidionis Vercammen-Grandjean and Loomis

Hexidionis (Hexidionis) Vercammen-Grandjean and Loomis,
1967: 139-140.

Type species. — Trombicula jessiemae Gould, 1956.

Included species. — Trombicula allredi Brennan and Beck, 1956;
T. lacerticola Loomis, 1964; Hexidionis navojoae Lucas and Loomis,
1968; H. macropus, Nn. sp.

Diagnosis. — Larva. Ratio of distance between dorsal genualae to
length of genu I greater than 0.3; less than 80 dorsal body setae; with
2 or 3 genualae I.

Hexidionis (Hexidionis) macropus, new species
Figure 2

Types. — Holotype and 13 paratopotypes from La Burrera, Baja
California Sur, Mexico; host Peromyscus eremicus eva Thomas
(Cactus Mouse); original numbers RMD670706-23 (holotype and
3 paratopotypes), RMD670706-22 (2), RMD670706-20 (6), and
RMD670706-19 (2); taken on 6 July 1967 by R. M. Davis, E. M.
Fisher and L. W. Robbins.

Diagnosis. — Larva. Similar to Hexidionis jessiemae (Gould), 1956,

New Species of Chiggers 57

but differing from H. jessiemae in having shorter PL setae (less than
50) off scutal plate.

Description. — Based on holotype with differences noted among
14 paratopotypes. All measurements are in microns.

Body: Nearly round; color in life orange; eyes 2/2, ocular plate
indistinct.

Gnathosoma: Cheliceral base punctate, blade slender with tricuspid
cap. Palpal setae B/B/BBB, palpal tarsal setae 7BS, palpal tibial claw
trifurcate. Galeala with numerous branches.

Figure 2. Hexidionis (Hexidionis) macropus, n. sp. A. Scutum and eyes. B. Dorsal
aspect of gnathosoma. C. Ventral view of palpal tibia and tarsus. D. Leg I —
genu, tibia and tarsus with nude setae, bases of branched setae and measure-
ments in microns. E. Leg II. F. Leg III. G. Representative body setae: /st, first
sternal; H, humeral; PD, posterior dorsal.

58 Bulletin So. Calif. Academy of Sciences

Scutum: About 1.5 width/length with posterior two-thirds punctate.
Lateral margins sinuous; anterior margin perpendicular to lateral
margin; posterior margin concave. Sensilla filiform with barbs on
proximal half and distal half having 10-12 branches.

Scutal measurements of holotype, and (in parentheses) mean and
extremes of 14 types. AW 60 (60, 58-63), PW 72 (77, 72-93), SB 19
(20, 19-22), ASB 31 (31, 27-34), PSB 20 (21, 19-23), AP 31 (31, 26-
37), AM 49 (49, 46-53), AL 39 (37, 34-45), PL 41 (43, 38-47), S 60
(61, 58-66, 5).

Body setae: All body setae with many branches. Dorsal setal formula
for holotype, 4 (humerals)-6-4-6-6-6-6-6 plus approximately 43;
measurements of humeral seta 43, posthumeral seta 36, posterior
dorsal seta 39. Ventral setae 2-2 plus approximately 25 preanal setae,
measurements of first sternal seta 36, small posterior seta 24. Total
body setae approximately 116.

Legs: All coxae lightly punctate. Leg I with 3 genualae (14-14-14),
microgenuala; 2 tibialae, subequal, (8-9), microtibiala; tarsala (21), .
microtarsala, subterminala (19), pretarsala (9). Leg II with genauala
(11); 2 tibialae, subequal, (7-8); tarsala (27), microtarsala, pretarsala
(10). Leg III with genuala (14); tibiala (13). All legs with internal
bands in genu (2-3), tibia (3-4), tarsus (5-8). Each leg having 2
claws with 3-5 onychotriches and a clawlike empodium with 2-3
onychotriches.

Leg lengths of holotype and (in parentheses) mean and extremes
of 14 types: leg I 411 (398, 372-411); leg II 366 (349, 321-397); leg
III 420 (398, 384-421), total leg lengths 1197 (1132, 1032-1197).

Remarks. — This species closely resembles Hexidionis jessiemae
in the large size of the larva and in many other characters.

Ecological notes. — The type locality at La Burrera at an elevation
of 1600 feet, is in the Arid Tropical Zone according to Nelson (1922).

Specimens examined (22).— MEXICO, BAJA CALIFORNIA
SUR, La Burrera, 6 July 1967, Peromyscus eremicus eva, (22, in-
cluding 14 types).

LITERATURE CITED

BRENNAN, J. M. anp D. E. BEcx. 1956. The chiggers of Utah (Acarina, Trombi-
culidae). Great Basin Nat., 15: 1-29.

GouLp, D. J. 1956. The larval trombiculid mites of California (Acarina, Trombi-
culidae). Univ. Calif. Publ. Ent. 11: 1-115.

HOFFMANN, A. 1963. Contribuciones al conocimiento de los trombiculidos mexi-
canos (Acarina, Trombiculidae). An. Esc. Nac. Cienc. Biol. Mex. 12: 101-
109.

New Species of Chiggers SY)

Loomis, R. B. 1964. A new species of chigger (Acarina, Trombiculidae) from
lizards of western North America. Great Basin Nat. 24: 13-17.

Loomis, R. B. AND D. A. CRossLEy, JR. 1963. New species and new records of
chiggers (Acarina, Trombiculidae) from Texas. Acarologia 5: 371-383.

Loomis, R. B. AND J. L. Lucas. 1969. A new species of Hexidionis (Acarina,
Trombiculidae) from kangaroo rats (Genus Dipodomys) of western North
America. Bull. So. Calif. Acad. Sci. 68: 225-228.

Lucas, J. L. AND R. B. Loomis. 1968. The genus Hexidionis (Acarina, Trombi-
culidae) with the description of a new species from western Mexico. Bull.
So. Calif. Acad. Sci. 67: 233-239.

NELson, E. W. 1922. Lower California and its natural resources. Natl. Acad.
Sci (First Memoir) 16: 1-194.

VERCAMMEN-GRANDJEAN, P. H. AND R. B. Loomis. 1967. Note on Hexidionis
n. g. and Pentidionis n. sg. Acarologia 9: 139-140.

Accepted for publication November 30, 1969.

60 Bull. So. Calif. Acad. Sci. 69(1): 60-64, 1970

SEXUAL DIFFERENCES IN FORAGING BEHAVIOR OF
WHITE-HEADED WOODPECKERS

ROBERT F. KOCH, ARMAND E. COURCHESNE,
AND

CHARLES T. COLLINS

Department of Biology

California State College
Long Beach, California 90801

ABSTRACT: Field observations of White-headed Woodpeckers
(Dendrocopos albolarvatus) in Southern California are de-
scribed. A pronounced sexual difference in foraging behavior
was noted with males utilizing the upper portions and cones of
Colter Pines and females the lower portions of the main trunk.
These differ somewhat from previous observations of other
species of sexually dimorphic woodpeckers.

INTRODUCTION

The possibility that sexual dimorphisms in birds may be adaptive in
reducing intraspecific competition for food resources has been sug-
gested by several authors (Storer, 1952, 1966; Rand, 1952) and ex-
tensively reviewed by Selander (1966). Sexual dimorphism in bill
size is particularly noticeable in woodpeckers of the genera Centurus
and Dendrocopos and seems to be correlated with intraspecific dif-
ferences in foraging behavior that reduce intersexual competition
for food (Selander and Giller, 1963; Selander, 1965, 1966). Recent
field studies by Ligon (1968a, 1968b) have provided additional infor-
mation on such intersexual differences in foraging behavior for three
Dendrocopos species. This study was undertaken to examine the
situation of the White-headed Woodpecker (Dendrocopos albolarvatus
(Cassin)), a species exhibiting a pronounced sexual dimorphism in
bill size but for which no detailed information on foraging behavior
has been published.

METHODS AND MATERIALS

The White-headed Woodpecker is widespread in the mountainous
areas of western United States from southern British Columbia and
Idaho to Southern California (A. O. U., 1957). The birds of this species
inhabiting the San Gabriel, San Bernardino, San Jacinto, Santa Rosa,
Volcan and Cuyamaca mountains of Southern California have been
attributed to a distinctly large-billed race D. a. gravirostris (Grinnell).

Woodpecker Behavior 61

The males of this race are only slightly larger than females in most
linear dimensions but have 8.3% longer bills (see Ridgway, 1914:
267).

White-headed Woodpeckers in Southern California are commonly
found in the transition zone at altitudes of 6000 to 8500 feet (Grinnell
and Miller, 1944). This study was conducted at the Upper and Lower
Chilao Flats of Angeles National Forest in the San Gabriel Mountains,
Los Angeles County, California. The Chilao flats exhibit characteristics
of both transition and upper sonoran life zones. The prominent trees
were Coulter Pine (Pinus coulteri), Ponderosa Pine (P. ponderosa),
and oaks (Quercus sp.). Elements of the chaparral-sonoran life zone
were present on the dryer south facing slopes.

The woodpeckers were observed to feed almost exclusively on
Coulter Pine and only occasionally on Ponderosa. In this area Colter
Pines average approximately 75 feet in height. During the period
from March to June 1969, 6 trips were made to the study areas and 23
bird-observations were made on woodpeckers (15 males and 8 females).
A stopwatch was used to determine the length of time a woodpecker
spent foraging in various areas of a tree. A maximum period of 2
minutes per bird, while on a single tree, was arbitrarily established to
prevent any particular observation from becoming excessively in-
fluential on the results.

After several periods of observation woodpecker foraging move-
ments seemed characterized best in terms of 3 zones. The pine trees
were thus divided into (1) lower, (2) middle, and (3) upper zones. The
ground up to and including the first few lateral branches was desig-
nated as zone |. The remaining area of both trunk and branches was
divided in half with the lower area being considered as zone 2 and the
upper portion as zone 3. The lateral branches were not considered as a

TABLE |
Use of Foraging Zones by Dendrocopos albolarvatus

Males Females

Time In Time In
Location Seconds % Seconds %
Trunk and Limbs (Zone 1) 350 22 973 90
Trunk and Limbs (Zone 2) 492 20 75 07
Trunk and Limbs (Zone 3) 785° 48 38 03

4356 seconds (40% ) of the time spent by males in Zone 3 was on cones. Females
spent no time on attached cones.

62 Bulletin So. Calif. Academy of Sciences

distinct zone as most foraging by White-headed Woodpeckers was
done on the main trunk and the proximal portions of lateral branches.
Particular note however was made of the time spent foraging on the
greater concentration of cones found in zone 3.

The woodpeckers were most active in the early morning and late
afternoon so most observations were made during these periods. Since
no pronounced changes in foraging behavior were noted during the
study period, the observations from all trips were combined and are
summarized in Table 1.

RESULTS

As indicated in Table 2, male White-headed Woodpeckers foraging on
Coulter Pine were found to utilize the entire tree but were concen-
trated in the upper third (zone 3). Usually landing in zone 2 they would
begin foraging upward. Compared to the females, foraging males
moved about more rapidly, seemingly searching more superficially, ©
and thus covered a larger area of the tree in comparable time intervals.
Upon reaching the upper third of the tree the males generally proceeded
out the short branches and concentrated their foraging efforts on the
terminal clusters of cones, which they diligently hammered open.
Afterwards males usually flew to zone 2 of the same or of a different
tree and again foraged upward.

Females foraged in a noticeably different location, almost exclu-
sively on the main trunk in the lower third (zone1) of the Coulter Pines
with some activity on the proximal portions of the lowermost lateral
branches. Usually starting near the ground, females moved up, down,
and around the trunk in their foraging. They often stopped to peer,
probe, and gently flake away pieces of bark. Seemingly being more
thorough, the females required more time to search a given area. They
appeared to cover the tree more rapidly as they approached the middle
third (zone 2). On 2 occasions females were observed on dislodged
cones that showed evidence of having been opened by squirrels; one
cone was balanced on a lower limb and one was on the ground. As with
the males, hammering activity was pronounced. That no female was
observed on an attached or whole cone seems significant.

DISCUSSION

Field studies on other species of Dendrocopos woodpeckers have
revealed pronounced sexual differences in foraging behavior. In D.
villosus and D. arizonae, species with a pronounced sexual dimorphism

ee ee a ee

Woodpecker Behavior 63

in bill size, the larger billed males tended to utilize the lower trunk
and branches while the smaller billed females foraged more commonly
in the higher parts of the trees and among the terminal branches and
twigs (Kilham, 1965; Ligon, 1968a). A similar foraging pattern has
been noted for D. stricklandi although “.. . beak-length dimorphism
is not pronounced” in this species (Ligon, 1968b). Observations on the
isomorphic D. borealis indicated foraging behavior more similar to
that here reported for D. albolarvatus in that the males forage higher
in the trees than the females and also utilize the lateral branches to a
great extent.

Males of most species of woodpeckers are larger and, in some
Dendrocopos species, dominant to the females (Kilham, 1965; Ligon,
1968a). Accordingly the males utilize this advantage “. . . to forage in
the most productive portions of the trees, with the female giving way
and feeding in less desirable areas” (Ligon, 1968a:211). In most cases
this has resulted in the males taking over the lower portions of the main
trunks and the females utilizing the upper limbs and twigs. It is likely
that the smaller bill of the females is due to selection favoring a reduc-
tion in size for more effective foraging in these areas, as “bill size
appears to be rapidly and strongly influenced by natural selection in
some woodpeckers” (Ligon, 1968a:211). It is also possible that “the
tendency for larger size and longer bills in males may have been
accentuated by selection” in some species or populations (Ligon,
1968a:211).

In D. albolarvatus in this study, the most productive foraging sites
thus would seem to be the particularly large spiked cones of the Coulter
Pine which are utilized by the males. The females restrict their foraging
to the lower main trunk which in other species is utilized by large-
billed males. It is likely that selection for an efficient bill size for the
exploitation of the large Coulter Pine cones by males and the remaining
portion of the trunk by females would result in somewhat larger bills
for each sex in this population of White-headed Woodpeckers. As noted
earlier, D. a. gravirostris has been characterized as being distinctively
larger-billed (Grinnell, 1902).

As pointed out by Selander (1966) and Kilham (1965) regional
differences in intraspecific foraging behavior may be expected among
species with extensive geographic ranges. This seems to be true in D.
borealis (Ligon, 1968a) and probably also in D. albolarvatus. Observa-
tions of the latter species in Idaho (Ligon, pers. Commun.) indicated
that in April, both sexes foraged on cones of the Ponderosa Pine
whereas in June they both utilized terminal needle clusters, especially
on the higher branches. Such differences may be due to a variety of

64 Bulletin So. Calif. Academy of Sciences

factors including the quality and quantity of food available, competi-
tors, and population size of both prey and predator. Further study of
these differences may greatly increase our understanding of the
evolution of sexual dimorphisms and sexual differences in foraging
behavior patterns.

ACKNOWLEDGEMENTS

We are grateful to J. David Ligon for permission to include his observations
on these woodpeckers and to Stuart L. Warter for comments on the manuscript.

LITERATURE CITED

AMERICAN ORNITHOLOGISTS’ UNION, 1957. Check-list of North American Birds.
Fifth Edition. Baltimore.

GRINNELL, J. AND A. H. MILLER, 1944. The distribution of the birds of California.
Pacif. Coast Avifauna, 27: 1-608.

KiLtHaM, L. 1965. Differences in feeding behavior of male and female Hairy -
Woodpeckers. Wilson Bull., 77: 134-145.

Licon, J. D. 1968a. Sexual differences in foraging behavior in two species of
Dendrocopos woodpeckers. Auk, 85: 203-215.

1968b. Observations on Strickland’s Woodpecker, Dendrocopos strick-
landi. Condor, 70: 83-84.

Ranp, A. L. 1952. Secondary sexual characters and ecological competition.
Fieldiana Zool. 34: 65-70.

RipGway, R. 1914. The birds of North and Middle America. Part 6. Bull. U.S.
Nat. Mus., 50: 1-882.

GRINNELL, J. 1902. The southern White-headed Woodpecker. Condor, 4: 89-90.

SELANDER, R. K. 1965. Sexual dimorphism in relation to foraging behavior in the
Hairy Woodpecker. Wilson Bull., 77: 416.

1966. Sexual dimorphism and differential niche utilization in birds.
Condor, 68: 113-151.

SELANDER, R. K. AND D. R. GILLER, 1963. Species limits in the woodpecker genus
Centurus (Aves). Bull. Am. Mus. Nat. Hist., 124: 213-274.

STORER, R. W. 1952. Variation in the resident Sharp-shinned Hawks of Mexico.
Condor. 54: 283-289.

1966. Sexual dimorphism and food habits in three North American
accipiters. Auk, 83: 523-438.

Accepted for publication December 16, 1969.

Southern California
Academy of Sciences

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Sear iLETIN OF THE

Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

VOL. 69 APRIL-SEPTEMBER 1970 ParRT 2

‘CIBRAR

Nov 20 1870

ene YORE
BOTANICAL GAR

CONTENTS

Three new species of Hannemania (Acarina, Trombiculidae)
from Amphibians of western Mexico. W. C. Welbourn, Jr.
and Richard B. Loomis

A new Spionid (Annelida: Polychaeta) from the Gulf of Cali-
fornia. William J. Light

Alternation of neural spine height in certain Early Permian
Tetrapods. Peter Paul Vaughn

The effect of temperature on the setal characteristics in Poly-
noidae (Annelidae: Polychaeta). Kenneth A. Hillger and
Donald J. Reish

Revival of the monotypic genus Boshellia Ewing, 1950 (Acarina:
Trombiculidae). James M. Brennan and Paul H. Vercam-
men-Grandjean

The organic matrix in developing dental enamel and dentin
studied by scanning electron microscopy. John D. Soule ...

Research Notes:

A note on the hydroid Dipurena reesi Vannucci and a me-

dusae of the genus Cladonema collected together near Los

Angeles. J. S. Bullivant

The status of the Southern Yellow Bat in California. Suzanne

I. Bond

Tantilla brevicauda: An addition to the snake fauna of

Guatemala with comments on its relationships. Larry David
Wilson “

OCTOBER 30, 1970

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BUwwoe LIN TOF THE SOUTHERN CALIFORNIA
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Vol. 69 APRIL-SEPTEMBER No. 2

Bull. So. Calif. Acad. Sci. 69(2): 65-73, 1970

THREE NEW SPECIES OF HANNEMANIA
(ACARINA, TROMBICULIDAE)
FROM AMPHIBIANS OF WESTERN MEXICO.!

W.C. WELBOURN, JR. AND RICHARD B. LOOMIS
Department of Biology,
California State College
Long Beach, California 90801

ABSTRACT: Hannemania anurae, n. sp. is described from 1 km
NE Santa Lucia, Sinaloa, Mexico, type host Syrrhophus
modestus pallidus; other hosts are Hyla arenicolor, Hyla
eximia, Rana montezumae, Rana pipiens, Rana pustulosa,
Rana sinaloae, and Rana tarahumarae; and also known from
Nayarit and Jalisco. Hannemania monticola, n. sp. is from
1.6 km W Buenos Aires, Durango, Mexico, type host Hyla
eximia and other hosts are Ambystoma rosaceum and Tomo-
dactylus saxatilis. Hannemania saxicola, n. sp. is from 23.5
km SW Buenos Aires, Durango, Mexico, type host Tomo-
dactylus saxatilis.

INTRODUCTION

Investigations of the chiggers from amphibians taken in western North
America have revealed a number of species belonging to the genus
Hannemania. Recently, Loomis and Welbourn (1969) redescribed H.
hylae (Ewing) and named H. bufonis, both from southwestern United
States and Sonora, Mexico. The present paper describes three new
species of Hannemania from the Mexican states of Durango, Jalisco,
Nayarit and Sinaloa.

The genus Hannemania was proposed by Oudemans (1911) and has
been placed in the subfamily Leeuwenhoekinae. The larvae of this
genus can be distinguished from other similar genera by the presence of
a distally expanded flange possessing recurved teeth on the cheliceral

1Studies upon which this report is based were supported by a Research Grant
AI-3407 from the National Institute of Allergy and Infectious Diseases.

65

66 Bulletin So. Calif. Academy of Sciences

blade, an anteromedian projection of the scutum, and lack of stigmata
and tracheae. The larvae of this genus have been found imbedded in
the skin of amphibians of the New World.

We wish to thank numerous students in Biology at California State
College, Long Beach who assisted in collecting the amphibians as well
as the preparation of the chiggers, including S. William Agnew,
Richard M. Davis, Julius C. Geest, David G. Marqua, P. H. Sullivan,
Linda M. Williams and William J. Wrenn. We are grateful to L. M.
Hardy and Dr. J. Knox Jones, Jr. of The University of Kansas for
amphibians collected under U.S. Army Research and Development
Command Contract DA49 192 MD 2215. We are also grateful to
Elaine Katzer for the fine illustrations.

For the permits to collect amphibians in Mexico we are indebted to
Sr. Dr. Rodolfo Hernandez Corzo, el Director General, Direccion
General de Caza, Departamento de Conservacion de la Fauna Silvestre,
Secretaria de Agricultura y Ganaderia.

Hannemania anurae, new species
Figure 1

Types. — Holotype and 10 paratypes from 1 km NE Santa Lucia,
1128 m, Sinaloa, Mexico, from Syrrhophus modestus pallidus Duell-
man, original numbers WJW630725-4 and WJW630725-5, collected
25 July 1963 by W. J. Wrenn, R. B. Loomis and R. M. Davis.

Diagnosis. — Larva similar to Hannemania hylae and H. bufonis
in having one genuala II and III, and lacking femoralae, but differing
from H. hylae and H. bufonis in having tarsala II longer than tarsala I
and coxa III with two or more setae.

Description of the holotype (all measurements in microns). — Body:
Fully engorged, 1095 by 682, color in life orange; eyes 2/2, equal,
ocular plate present.

Dorsal setal formula 2-4-10-8+ 41, total 65. Measurements: Hu-
meral seta 59, seta of first posthumeral row 44 to 48, posterior dorsal
seta 48 to 51.

Approximately 50 ventral setae. Measurements: Sternal seta 42,
posterior ventral seta 33 to 37.

Scutum: Punctate, anteromedian projection without puncta, sensilla
filiform (see Figure 1).

Scutal measurements of holotype (with mean and extremes of 10
paratypes unless otherwise noted): AW — (48, 45-53, 9), PW 67 (66,
62-72, 9), SB 26 (27, 26-29), ASB — (59, 56-62, 6), PSB 27 (28, 25-
31, 8), AP 22 (19, 16-22, 9), AM 34 (34, 30-40, 6), AL 47 (42, 39-47,
8), PL 63 (66, 62-74, 8), S— (88, 81-93, 4).

New Species of Chiggers 67

Figure 1. Hannemania anurae, n. sp. A. Scutum and eyes. B. Dorsal view of
gnathosoma. C. Ventral aspect of palpotibia and tarsus. D. Representative body
setae; PD, posterior dorsal, H, humeral, 1ST, first sternal. E. Leg I; genu, tibia and
tarsus with nude setae and bases of branched setae, with measurements in microns.
F. Leg II. G. Leg III. H. Coxa III with branched setae.

68 Bulletin So. Calif. Academy of Sciences

Gnathosoma: Cheliceral base and capitular sternum punctate. Ga-
leala branched. Palpal formula B/B/BNB; palpal tarsus with 5
branched setae, and tarsala (13); palpotibial claw trifurcate.

Legs with specialized setae as follows: Leg I, with 8 (6-9) genualae
and microgenuala; 2 tibialae and microtibiala; tarsala 22 (22, 21-23),
microtarsala, subterminala, parasubterminala (occasionally branched)
and pretarsala. Leg II, with genuala; 2 tibialae; tarsala 25 (25, 24-27),
microtarsala and pretarsala. Leg III, coxa with 2 branched setae;
genuala; tibiala. All legs with 6 punctate segments and terminating in
2 claws and clawlike empodium with onychotriches.

Leg measurements: I, 341 (310-360); II, 278 (250-287); III, 316
(271-335); total, 935 (831-982).

Ecological notes. — Hannemania anurae has been found on a
variety of hosts in a wide range of habitats in western Mexico. Almost
all hosts of H. anurae also had another species (undescribed) of Hanne-
mania. Notable exceptions were all four specimens of Syrrhophus
modestus pallidus, one Rana pipiens and the one Rana montezumae.

Hannemania anurae has been taken from Rana pipiens, Rana
pustulosa, Rana sinaloae, and Syrrhophus modestus pallidus in Sinaloa,
and Hyla arenicolor and S. m. pallidus in Nayarit, both in the Subtropi-
cal Dry Forest vegetation (Hardy and McDiarmid, 1969). In the Pine-
Oak Forests (Leopold, 1959) H. anurae was taken from Rana pipiens
and Hyla eximia southeast of Tepic, and from R. pipiens and Rana
tarahumarae in Jalisco.

The specific name of H. anurae refers to the numerous species of
anuran hosts.

Specimens examined (53). — SINALOA: 6.4 km SE Santa Lucia,
1341 m, 20 Aug. 1963, Hyla arenicolor (2); Santa Lucia to 2.2 km NE,
4 July 1962, Rana sinaloae (5), 11 July 1963, R. sinaloae (6), 13 July
1963, Syrrhophus modestus pallidus (1), 26 July 1963, Rana pipiens
(5), 28 July 1963, R. sinaloae (1), 29 July 1963, R. pipiens (4), 9 Dec.
1964, R. sinaloae (1); 4.6 km W Santa Lucia, 29 July 1963, R. pipiens
(2); 8.1 km SW Santa Lucia, 29 July 1963, Rana pustulosa (3).
NAYARIT: 4.2 km E San Blas, 2 July 1962, Syrrhophus modestus
pallidus (4); 35.7 km SE Tepic, 1410 m, 19 July 1962, Hyla eximia
(2), R. pipiens (1). JALISCO: 8 km W Ameca, 21 June 1967, R.
pipiens (5), Rana tarahumarae (1); 1.6 km N Encarnacion, 6 Aug.
1962, Rana montezumae (10).

Hannemania monticola, new species
Figure 2
Types. — Holotype and 9 paratypes from 1.6 km W Buenos Aires

New Species of Chiggers 69

(53 km W El Salto) on Mexican Hwy. 40, Durango, Mexico, 2300 m,
from 8 Ayla eximia Baird, original number WJW620705-4, collected
5 July 1962 by W. J. Wrenn, and party.

Diagnosis. — Larva, similar to Hannemania anurae, H. bufonis
and H. hylae in having one genuala on legs II and III and lacking
femoralae; but differing from H. anurae in having one seta on coxa III,
from H. bufonis in having ocular plate 30 x 13 (average in H. bufonis
22 x 9), from H. hylae in having PL’s long 63-79 (39-54 in H. hylae).

Description of holotype (all measurements in microns). — Body:
Fully engorged, color in life orange; eyes 2/2, equal, ocular plate
present.

Dorsal setae about 53. Measurements: Humeral seta 68, seta of first
posthumeral row 54-59, posterior dorsal seta 50-56.

About 45 ventral seta. Measurements: First sternal seta 43, posterior
ventral seta 31-45.

Scutum: Punctate except for anteromedian projection, sensilla filli-
form (see Figure 2).

Scutal measurements of holotype (with mean and extremes of 9
paratypes unless otherwise noted): AW 53 (55, 51-62), PW 71 (75, 71-
86), SB 27 (29.5, 27-35), ASB 62 (63, 56-64) 8), PSB 28 (28, 25-31,
AP 19 (21, 19-25), AM 31 (35, 31-45, 7), AL 39 (41, 39-47, 6), PL 63
(76, 63-79, 8), S— (91, 84-99, 3).

Gnathosoma: Cheliceral base and capitular sternum punctate.
Galeala branched. Palpal formula B/B/BNB; palpal tarsus with 5
branched setae, tarsala 12; palpotibial claw trifurcate.

Legs with specialized setae as follows. Leg I with 5 (3-7) genualae
and microgenuala; 2 tibialae and microtibiala; tarsala 28 (26, 24-30),
microtarsala, subterminala, parasubterminala, and pretarsala. Leg II,
with genuala and microgenuala; 2 tibialae; tarsala 27 (26, 25-28),
microtarsala and pretarsala. Leg III, coxa with one branched seta;
genuala; tibiala. All legs with six punctate segments and terminating in
2 claws and clawlike empodium with onychotriches.

Leg measurements: I, 412 (316-412); II, 344 (273-350); II, 369
(226-381); total, 1125 (815-1143).

Ecological notes. — Hannemania monticola has been taken only in
the pine-oak forest (Baker and Greer, 1962) of western Durango.
Eight of 39 Hyla eximia (including the type host) collected in rain pools
along Highway 40 had H. monticola, although only two of them had
more than one larva. One salamander, Ambystoma rosaceum, found
under a log at the type locality, had a single H. monticola. Twenty-four
specimens of H. monticola were taken from one specimen of Tomo-
dactylus saxatilis along with the following species of Hannemania.

70 Bulletin So. Calif. Academy of Sciences

Figure 2. Hannemania monticola, n. sp. A. Scutum and eyes. B. Dorsal view of
gnathosoma. C. Ventral aspect of palpotibia and tarsus. D. Leg I; genu, tibia and
tarsus with nude setae and bases of branched setae, with measurements in microns.
E. Leg II. F. Leg III G. Representative body setae; 1ST, first sternal, H, humeral,
PD, posterior dorsal.

New Species of Chiggers Tal

The specific name of H. monticola alludes to the type locality which
is high in the Sierra Madre Occidental.

Specimens examined (46). — DURANGO: 23.5 km SW Buenos
Aires (75 km W EI Salto), 10 June 1963, Tomodactylus saxatilis (24);
64.7 km W EI Salto, 30 June 1967, Hyla eximia (2); 1.6 km W Buenos
Aires (53 km W EI Salto), 5 July 1962, 8 H. eximia (17), 18 Aug. 1963,
Ambystoma rosaceum (1); 3.5 km W La Ciudad, 21 Aug. 1968, H.
eximia (2).

Hannemania saxicola, new species
Figure 3

Types. — Holotype and 7 paratypes from 23.5 km SW Buenos Aires
(75 km W EI Salto), Durango, Mexico, from Tomodactylus saxatilis
Webb, original number DGM630610M-4, collected 10 June 1963 by
D. G. Marqua and P. H. Sullivan.

Diagnosis. — Larva, similar to Hannemania eltoni in having 8-10
genualae I and legs II and III with 4-7 genualae, but differing from
H. eltoni in having PL long (71-84, H. eltoni 45-50), leg III with 1-3
femoralae (few H. eltoni with femoralae III) and parasubterminala I
branched (nude in H. eltoni).

Description of holotype (all measurements in microns). — Body:
Fully engorged, 1736 by 1230, color in life orange; eyes 2/2, equal,
ocular plate present.

Dorsal setal formula 2-4-8-8 + 23, total 45. Measurements: Humeral
seta 66, seta of first posthumeral row 50-57, posterior dorsal seta
58-62.

Approximately 62 ventral setae. Measurements: Sternal seta 50,
posterior dorsal seta 37-43.

Scutum: Punctate, anteromedian projection without puncta; widest
between PL’s being slightly longer than wide, sensilla filiform.

Scutal measurements of holotype (with mean and extremes of the 7
paratypes in parentheses unless otherwise noted): AW 54 (54, 51-58,
6), PW 74 (76, 74-84, 4), SB 28 (30, 28-34, 5), ASB 69 (70, 67-74, 3),
PSB 27 (29, 27-32, 4), AP 24 (24, 22-28, 5), AM 45 (48, 44-54, 6), AL
47 (51, 47-54, 6), PL 75 (79, 71-84, 6), S — (97-105, 2).

Gnathosoma: Cheliceral base and capitular sternum punctate. Ga-
leala branched. Palpal formula B/B/BNB; palpal tarsus with 5
branched setae, and tarsala (15); palpotibial claw trifurcate.

Legs with specialized setae as follows: Leg I, with 10 (6-10) genualae
and microgenuala; 2 tibialae and microtibiala; tarsus with tarsala, 29
(30, 27-33), microtarsala, subterminala, parasubterminala branched

72 Bulletin So. Calif. Academy of Sciences

Figure 3. Hannemania saxicola, n. sp. A. Scutum and eyes. B. Dorsal view of
gnathosoma. C. Ventral aspect of palpotibia and tarsus. D. Leg I; genu, tibia, and
tarsus with nude setae and bases of branched setae, with measurements in microns.
E. Leg II. F. Leg III; femur, genu, tibia and tarsus. G. Representative body setae;
1ST, first sternal, H, humeral, PD, posterior dorsal.

SSS
~ —_—— SSS ee

New Species of Chiggers 73

and pretarsala. Leg II, with 5 (3-5) genualae; 2 tibialae; tarsala, 28
(28.3, 27-29), microtarsala and pretarsala. Leg III, coxa with one
branched seta; one femorala (one paratype with 3); 8 (5-9) genualae;
tibiala. All legs with six punctate segments with 2 claws and clawlike
empodium with onychotriches.

Leg measurements: I, 446 (381-465); II, 372 (350-394); III, 403
(301-419); total, 1221 (1032-1278).

Ecological notes. — Hannemania saxicola was found in association
with 24 specimens of H. monticola on the type host, Tomodactylus
saxatilis, which has been found in rocky areas of the Mixed-Tropical
habitat (Webb, 1962). The specific name H. saxicola was derived from
the specific name of the type host, which refers to the known host
habitat.

Taxonomic notes. — The presence of at least one femorala on leg
III is a diagnostic character of H. saxicola. Loomis (1956) found that
H. eltoni, a similar species, only occasionally had a femorala on one
leg III, and the femorala presumably replaced a branched seta as three
rather than the normal four branched setae were present. In H. saxicola
the femorala on leg III does not replace a branched seta as there are the
normal four branched setae on femur III.

LITERATURE CITED

BAKER, R. H. and J. K. GREER., 1962. Mammals of the Mexican state of Durango.
Publ. Mus. Mich. State Univ. Biol. Ser. 2: 29-154.

Harpy, L. M. anp R. W. McDiarmMip., 1969. The amphibians and reptiles of
Sinaloa, Mexico. Univ. Kansas Publ. Mus. Nat. Hist. 18: 39-252.

LEOPOLD, A. S., 1959. Wildlife of Mexico, the game birds and mammals. Univ.
Calif. Press, 568 p.

Loomis, R. B., 1956. The chigger mites of Kansas (Acarina, Trombiculidae).
Univ. Kansas Sci. Bull. 37: 1195-1443.

Loomis, R. B. AND W. C. WELBOURN, JR., 1969. A new species of Hannemania
(Acarina, Trombiculidae) from Bufo punctatus of western North America,
with comments on Hannemania hylae (Ewing). Bull. So. Calif. Acad. Sci.
68: 161-169.

Oupemans, A. C., 1911. Acarologische Aanteekeningen XXXVI. Ent. Bericht.
Amsterdam 3: 137-139.

WEsB, R. G., 1962. A new species of frog (genus Tomodactylus) from western
Mexico. Univ. Kansas Publ. Mus. Nat. Hist. 15: 175-181.

Accepted for publication March 20, 1970.

Bull. So. Calif. Acad. Sci. 69(2): 74-79, 1970

A NEW SPIONID (ANNELIDA: POLYCHAETA)
FROM THE GULF OF CALIFORNIA

WILLIAM J. LIGHT
Department of Biological Sciences
Simon Fraser University
Burnaby 2, British Columbia

ABSTRACT: Polydora wobberi sp. nov., is described from Bahia
de San Francisquito on the eastern side of Baja California,
where it inhabits burrows bored into the white gorgonacean,
Lophogorgia sp. It is related to another species of Polydora (in
press) which is known only as a commensal within the
coenosteum of certain hydrocorals from central California to
British Columbia, and to Polydora cavitensis Pillai from the
Philippine Islands.

INTRODUCTION

In May of 1969, several examples of the white gorgonian, Lopho-
gorgia sp. (Coelenterata: Anthozoa), were recovered from depths of
6-10 m in Bahia de San Francisquito on the Gulf side of Baja California
(lat. 28° 30’ N.; long. 112° 50’ W.) with SCUBA. This material
contained small spionids living in U-shaped burrows along the lengths
of short branches which arise from the bases of the coelenterate
colonies; these polychaetes were determined to represent a heretofore
undescribed species. The specimens were collected by Don R. Wobber,
Department of Biology, San Francisco State College, after whom Iam
pleased to name the new species.

Family SPIONIDAE Grube 1850
Genus Polydora Bosc 1802

Polydora wobberi, new species
Figures 1-2

Type material — Holotype: California Academy of Sciences, De-
partment of Invertebrate Zoology No. 304. Paratypes: One broken,
but complete, specimen, fragments of three other individuals and two
egg cocoons, as well as slide mounted material, have been placed in the
Allan Hancock Foundation, University of Southern California.

Type locality — Bahia de San Francisquito, Baja California, Méxi-
co; from 6-10 m, burrowing in Lophogorgia sp.

74

New Spionid 75

Figure I. Polydora wobberi, n. sp.: a, anterior end, right lateral view, right palp

removed; b, same, dorsal view, setae and left palp removed: c. posterior end. left
latero-ventral aspect. Scale 1 mm.

a

ae A —f

Figure 2. Polydora wobberi, n. sp.: a, neuropodial crotchet, lateral view, scale
equals 1 mm; b, tip of modified major spine of fifth setiger, lateral view, scale

equals 0.02 mm; c, older, worn spine, lateral view; d, younger spine, ventral
aspect, scale 0.02 mm.

DIAGNOSIS

Peristomium anteriorly prolonged beneath prostomial ridge to form a
bluntly rounded leading edge; this anterior margin ventrally produced
into a thick fleshy roll of tissue, which sweeps laterally and ventrally
to enclose the mouth. Prostomium long, thin, feebly notched anteriorly,

76 Bulletin So. Calif. Academy of Sciences

not readily visible against the underlying peristomial projection in
dorsal view; caruncle to middle of setiger 4. Modified fifth setiger
heavily creased dorso-laterally; modified major spines simple, some-
what falcate, with slight lateral flarings forming a subdistal concavity. A
prominent webbing, often pleated, joining adjacent branchiae from
setiger 12, continuing almost to pygidium. Body dorso-ventrally
flattened in posterior region; sharply attenuated over the last few
pre-pygidial segments — closely resembling the caudal end of Boc-
cardia hamata (Webster), but lacking stout notopodial hooks (see
below). Pygidium a thickened ring, much reduced.

EXTENDED DESCRIPTION

The holotype measures 27 mm long by 0.9 mm wide (anterior seg-
ments) over 134 segments, and the single complete paratype, 26 mm
by 1.1 mm over 137 segments. The widths of the expanded caudal
regions are 1.1 and 1.4 mm, respectively.

The prostomium is narrow, high, and faintly notched on the anterior.
margin. The caruncle rises abruptly to a high dome just over the region
of the second setiger and then slopes sharply downward, terminating at
about the middle of setiger 4 (Fig. la, b). Anteriorly, the prostomium is
mounted atop a prominent forward extension of the peristomium,
which gives a distinctly rounded, prow-like appearance to the pros-
tomial region when viewed from above. This peristomial projection is
produced laterally and ventrally into thick fleshy lips which sweep
down to enclose the buccal opening, which in this form consists of a
closed longitudinal slit. In ventral aspect, a swollen mound of peris-
tomial tissue juts out from the mouth much like a proboscis; this
mound is confluent with the roof of the mouth and the thick peristomial
lips just described. A kodachrome of a living specimen kindly provided
by Mr. Wobber indicates that this peristomial structure is not an artifact
of preservation. Four subdermal eyes are arranged trapezoidally, the
anteriormost pair the further apart.

The palps are short and thick with the median groove bordered on
either side by thick ridges, distinctly marked with small blotches of
dark-brown (Fig. lb). A dark W-shaped haemal loop can be seen on
either side through the transluscent tissues of the peristomial lateral
cephalic lobes.

There are no notosetae on the first setiger. The postsetal notopodial
lamellae are well developed on setigers 1-4, and from the sixth, almost
to the end. Neuropodial lamellae are well developed on setigers 1 and 2,
reduced on 3, and almost lacking on 4 (Fig. la); they are completely

New Spionid 77

absent thereafter. With the exception of the modified spines and
companion setae of setiger 5 and the hooded hooks, the setae all consist
of limbate forms in both rami of the parapodia of the type commonly
found in this genus (Mesnil, 1896, Pl. 12, Figs. 5, 6); posteriorly, the
notosetae form fine elongate capillaries which have the barest trace of
a limbate tip (Mesnil, 1896, Pl. 12, Fig. 8). Prominent transverse
ciliary bands are present over the dorsum of all setigers, except 5 and 6.

The fifth setiger is heavily modified and distinctly folded dorso-
laterally. A large ridge extends across the dorsum and passes down on
each side to enclose the major spine series (Fig. la). The modified major
spines, themselves, are slightly falcate structures, 8-9 in a series, with
a slight lateral flange forming a concavity subdistally (Fig. 2b, d).
These spines, especially the older and more weathered ones (Fig. 2c)
resemble those of Polydora cavitensis Pillai (1965, Fig. 17-D) and a
recently described form found in some eastern Pacific hydrocorals of
the genus Allopora (Light, in press). The companion setae are lanceo-
late and project beyond the tips of the major spines. Two very minute
fascicles are present both dorsal and ventral to the major spine series,
both bearing limbate setae.

Branchiae begin on setiger 7 and are fully developed from that
setiger almost to the end, where they become quite reduced (Fig. Ic).
From setiger 12 in both the holotype and the one complete paratype,
prominent webs of connecting tissue extend between the gills (Fig. 1c),
and only the distal portion of the branchiae project freely from these
septa. These septa are generally longer than the intervening inter-
branchial spaces so that they tend to be folded or pleated in the median
segments. This webbing is a highly unusual feature among the poly-
dorids and appears to be of diagnostic significance.

Hooded neuropodial crotchets (Fig. 2a) begin on setiger 7, and
number 6 per series. They increase in number over the next few somites
to 11-12 per ramus; this may persist over a number of segments, but the
count gradually decreases posteriorly, until there are but 2-3 in each
series over the last few segments. The beak forms a more or less acute
angle back against the main shaft, and a distinct manubrial swelling is
present. These crotchets are quite similar to those of Polydora caviten-
sis as well as those of the hydrocoral-dwelling species from the eastern
Pacific; to a lesser extent they also resemble those of Polydora hornelli
Willey from India and Ceylon and P. pacifica Takahashi from Palau
Island (Light, in press).

Very faint mid-ventral blotches can be seen in the median segments
of P. wobberi. These dark-brown markings are reminiscent of the

78 Bulletin So. Calif. Academy of Sciences

“butterfly” or “fleur-de-lis” pattern seen in the Allopora-dwelling
species from California. Color in alcohol: opaque white; living animals
are of a more fleshy hue.

The body is distinctly flattened dorso-ventrally and sharply atten-
uated over the last few posterior segments. It is very similar in appear-
ance to the caudal region of Boccardia hamata (Webster) Blake (1966),
but there is no trace of the large, curved posterior notopodial “boat-
hooks.” The pygidium is extremely reduced and consists of a thickened
ring surrounding the anal opening (Fig. Ic).

DISCUSSION

Polydora wobberi appears to be most closely related to P. cavitensis
from the Philippine Islands, and to a new species found in hydrocorals
ranging from central California at least as far north as the southern
portion of Vancouver Island (Polydora sp. n., Light, in press). These
three species are to a lesser extent also related to P. hornelli and P.
pacifica. Polydora wobberi may be distinguished from the other four
species by the unique forward projection of the peristomium, the
presence of interbranchial septa, and the extremely reduced pygidium.

Within the more closely related group, P. cavitensis differs from P.
wobberi in having a caruncle which extends to the posterior margin of
setiger 3 and in bearing a distinct occipital cirrus. The Allopora-
dwelling polydorid from California differs from P. wobberi in having
but one pair of eyes and a dorsally corrugated caruncle which extends
to the anterior border of setiger 5, and in exhibiting a prominent sheath
overlying the prostomium, formed by a forward extension of the
caruncle. The prostomium is also anteriorly entire in the California
species; in all the other forms mentioned, including P. wobberi, the
prostomium is anteriorly notched, and there is no overlying sheath.

The pygidium of P. cavitensis consists of a fleshy triangular-shaped
pad (Pillai, 1965, Fig. 17-G); in the hydrocoral-dwelling species it
forms a thick flat disk which is densely studded with minute papillae
on its posterior surface.

Polydora wobberi, P. cavitensis and the California species all differ
from P. hornelli and P. pacifica, in that their modified fifth setiger
spines lack the subdistal constriction or “neck” found in P. hornelli,
and the lateral spur found in P. pacifica.

Polydora wobberi attains a length of 27 mm, and in size more closely
resembles P. cavitensis (15 mm) and P. hornelli (31 mm over 92
segments). The hydrocoral-burrowing polydorid and P. pacifica are
both considerably larger, reaching 75 mm and 85 mm, respectively.

New Spionid 79

Like the hydrocoral-living form, P. wobberi may be an obligate
commensal within a coelenterate host, in this case, a gorgonacean. It is
more specialized than the species discussed above by virtue of the
configuration of the peristomium, the interbranchial septa and the
reduced pygidium. It causes more structural damage to the coelenterate
colony than does the species from California and the woody central
“stems” of the Lophogorgia are entirely missing in infected branches;
the limited data available suggest that neither species seems to seriously
affect the overall well-being of its hosts.

Polydora wobberi was found inhabiting narrow U-shaped burrows
which open to the exterior at the tips of short stubby branches of the
gorgonian which are about 20-30 cm in length. These short branches
usually arise within 5-10 cm of the basal holdfast of the gorgonian
colony; the longer, uninfected branches may reach 70 cm in height
(Wobber, personal communication). There may be from 10-16 spionids
per host colony, all of which seem to occupy individual burrows. In one
burrow from the type lot, egg cocoons were found adhering to the tube
wall by fine mucus strands. The largest cocoon measured 7.5 mm in
length and comprised one large chamber, tightly packed with many
granular eggs; such a size is unusual for polydorid egg cases.

ACKNOWLEDGMENTS

I am indebted to Don R. Wobber for the specimens and for the detailed field data
upon which this paper is based. I would also like to thank my good friends at the
California Academy of Sciences, James T. Carlton and Dustin D. Chivers, who
have provided me with so much help and information.

LITERATURE CITED

BLakE, J. A., 1966. On Boccardia hamata (Webster), new combination (Poly-
chaeta, Spionidae). Bull. So. Calif. Acad. Sci., 65: 176-184.

Licut, W. J., Polydora alloporis, new species, a commensal spionid (Annelida,
Polychaeta) from a hydrocoral off central California. Proc. Calif. Acad. Sci.,
(in press).

MEsNIL, F., 1896. Etudes de morphologie externe chez les annélides. I. Les
spionidiens des cotes de la Manche. Bulletin Scientifique de la France et de
la Belgique, 29: 110-285.

Pitval, T. G., 1965. Annelida Polychaeta from the Philippines and Indonesia.
Ceylon J. Sci., Biol. Sci., 5: 110-177.

Accepted for publication February 26, 1970.

Bull. So. Calif. Acad. Sci. 69(2): 80-86, 1970

ALTERNATION OF NEURAL SPINE HEIGHT IN
CERTAIN EARLY PERMIAN TETRAPODS

PETER PAUL VAUGHN

Department of Zoology

University of California
Los Angeles, California 90024

ABSTRACT: The neural spines of successive dorsal vertebrae in
specimens of the Early Permian cotylosaur Captorhinus aguti
alternate in height. The pattern of alternation is almost, but
apparently not quite, completely regular. The difference in
height between successive neural spines is greater in the
anterior part of the column, becoming less pronounced
posteriorly. This condition occurs also in another captorhino-
morph cotylosaur, Captorhinikos sp., and is similar to the
pattern recently described in the microsaur Pantylus cordatus
by Carroll. Detailed features of the higher spines indicate
that this condition was associated with modification of the
system of supraspinal and interspinal ligaments and that these
ligaments may have acted as posterior extensions of the nuchal
ligament, possibly in correlation with a relatively large skull.

INTRODUCTION

In his recent description of the postcranial skeleton of the Early
Permian microsaurian amphibian Pantylus cordatus Cope, Carroll
noted a fascinating peculiarity in the heights of the neural spines of
successive dorsal vertebrae. As he described it (1968, p. 1178), in one
specimen “‘Vertebrae 2, 4, 6, and 8 have very short neural spines, while
those of 3, 5, and 7 are longer and rugose, indicating the attachment of
interspinous ligaments. None of the specimens shows the vertebrae in
dorsal view the entire length of the column but... [one] includes
seven vertebrae just anterior to the sacrum which exhibit the same
characteristic. Presumably the entire trunk region was specialized in
this manner.” Carroll’s figures of the specimens show this condition
quite clearly, justifying the illustration of this phenomenon in his
reconstruction of the skeleton.

It seems noteworthy that the same condition occurs in specimens of
the Early Permian captorhinomorph cotylosaur Captorhinus aguti
(Cope). It is remarkable that this has not been noticed heretofore in this
species, which has been the subject of much attention for many years
and has been cited in innumerable papers as a classic representative of
primitive reptiles. There is no mention of the phenomenon in the recent

80

Permian Tetrapods 81

study of the osteology of this species by Fox and Bowman, but these
authors point out (1966, p. 48) that in the materials that were available
to them, “The dorsal extent of the spines is indeterminable; all have
been broken off near the base in the many specimens examined in this
study.”

ALTERNATION OF SPINE HEIGHT IN Captorhinus

Indications of alternating neural spine height in Captorhinus aguti
can be seen among loose, disarticulated dorsal vertebrae found by the
late Dr. F. E. Peabody in the Lower Permian fissure deposits near
Richard’s Spur in Comanche County, Oklahoma (Gregory, Peabody
and Price, 1956; this site is also known as the Fort Sill locality); these
materials are part of the vertebrate paleontological collection of the
University of California, Los Angeles (UCLA VP). Some of these
vertebrae have high spines, and in others the spines are short or almost
nonexistent. The patterns of the processes for the ribs make it clear that
vertebrae from the same regions of the column show these two condi-
tions; the observed difference is obviously not due to gradual change
through the total dorsal column. A clear example of the alternation is
seen in UCLA VP 1735 from the Richard’s Spur deposits (Fig. 1). This
specimen consists of three dorsal vertebrae in articulation. The second
vertebra in the series bears a prominent neural spine, but the spines of
the first and third vertebrae are virtually nonexistent. Another series
of three vertebrae of C. aguti from the Richard’s Spur deposits, sent to
me by Dr. W. W. Dalquest, shows essentially the same pattern, but the
difference between the “low-spined” and “high-spined” vertebrae is
not as marked; the low-spined vertebrae do show substantial develop-
ment of the spine — but these spines are low and somewhat blade-like,
unlike the stouter and higher spine of the middle vertebra of the series.
The small size of the costal facets shows that the vertebrae collected by
Dalquest are from a serial position well posterior to that occupied by
UCLA VP 1735.

FM UR 118, which I have borrowed from the Field Museum in
Chicago, includes a partial skull, parts of lower jaws, thirteen or more
presacral vertebrae, and other, more fragmentary, remains found by
Dr. E. C. Olson at a site in the Vale Formation, Clear Fork Group of
north-central Texas. There is no doubt that these materials are of C.
aguti, and they were so identified by Olson (1954). Eleven of the
vertebrae are in one articulated string, and these show the pattern of
alternation in height of neural spine. They also show that the pattern
was not completely regular. Vertebrae | through 7 of this string show

82 Bulletin So. Calif. Academy of Sciences

Figure 1. Left lateral view of UCLA VP 1735, a series of three dorsal vertebrae
of Captorhinus aguti from the Lower Permian fissure deposits near Richard’s
Spur, Oklahoma. Unshaded areas between vertebrae represent matrix. Size
indicated by 5-mm scale.

regular alternation, beginning and ending with “low,” and so do
vertebrae 9 and 10, high and low. The neural arch of vertebra 8 is,
unfortunately, missing, but whether its spine was high or low (or
intermediate in height), the regular pattern was interrupted. The upper
part of the neural arch of vertebra 11 is incomplete.

FM UR 118 shows another interesting feature: the difference in
height of the spines between successive vertebrae is seen to become
gradually less as the column is followed posteriorwards. This is con-
sonant with the apparent serial position of the Richard’s Spur vertebrae
collected by Dalquest.

Of the various vertebral materials of Captorhinus aguti at hand and
noted above, UCLA VP 1735, the illustrated series of three vertebrae
from the Richard’s Spur deposits, is the best preserved. The general
features of these vertebrae can be easily seen in the illustration (Fig. 1),
and only certain details require further description. As already noted,
the shape and extent of the processes for the ribs indicate a serial
position somewhere in the anterior part of the dorsal column. The
vertebrae are in very nearly their original positions relative to one

Permian Tetrapods 83

another, but the first has undergone slight rotation with the result that
part of the dorsal surface of its neural arch can be drawn in the same
illustration that shows the second and third vertebrae in strictly lateral
view. The intercentra have suffered greater displacement.

On the anterior, as well as the posterior, edge of the high, stout spine
of the second vertebra in the series, there is a pair of vertical ridges
(not seen in Fig. 1) separated by a narrow median groove. These ridges
would seem to have served for the attachment of a bilaminar interspinal
ligament that passed over the virtually spineless neural arches of the
adjacent vertebrae. On the dorsal surfaces of the arches of the first and
third vertebrae there are faint paired ridges that mark the passage, and
partial attachment, of such a ligament. The distal part of the spine of the
second vertebra has small swellings that indicate a differentiated,
band-like supraspinal ligament — as distinct from the bilaminar inter-
spinal ligament; the supraspinal ligament could not have been attached
to the first and third vertebrae. On each of the vertebrae, both fore and
aft, there is a small, triangular median fossa, with dorsal apex, above
the neural canal. The pitted inner surfaces of these fossae indicate the
presence of strong intervertebral ligaments at this level, that is, ventral
to the interspinal ligament. There is a difference between the fossae of
the “low-spined” and “‘high-spined” vertebrae. As shown by UCLA VP
1735, on the low-spined vertebrae there is a short median spur at the
apex of each fossa, but there are no such spurs on the high-spined
vertebra.

As already mentioned, in the articulated Richard’s Spur vertebrae
collected by Dalquest, which are from a farther posterior region of the
dorsal column, the spines of the low-spined vertebrae are better
developed, but they are still markedly shorter than that of the high-
spined vertebra in the same series. FM UR 118, from the Vale Forma-
tion of Texas, also shows that there is a gradual decrease posteriorly of
the difference in height between spines of successive vertebrae. At first
sight, the difference in height between successive spines in FM UR 118
seems less pronounced than in UCLA VP 1735, but closer inspection
shows that the spines end rugosely in the former, indicating incom-
plete ossification; the smooth surfaces in UCLA VP 1735 denote
complete ossification.

TENTATIVE INTERPRETATION

It would be highly desirable to be able to dissect a modern form that
shows a similar condition, but such seems not to be available. Dr. J. M.
Savage, University of Southern California, has kindly searched through

84 Bulletin So. Calif. Academy of Sciences

his extensive collection of skeletons of modern amphibians and reptiles,
without finding any sign of alternation in spine height. Nevertheless,
some attempt at functional interpretation seems required.

The accentuation of difference in height between successive neural
spines in the anterior part of the column suggests that the supraspinal
and interspinal ligaments of the dorsal region may have acted as
posterior extensions of the nuchal ligament. There are further reasons,
admittedly indirect, for thinking that they may have served such a
function. In Pantylus at least, the spine of the axis rises high above that
of the next succeeding vertebra, and its rugose upper edge indicates
that it may have been continued still higher in cartilage (see figures in
Carroll, 1968; note that the atlas and axis are fused in Pantylus). The
higher parts of the complex of supraspinal and interspinal ligaments
must have passed over at least several of the cervical vertebrae without
attachment. Unfortunately, the pertinent details of the anteriormost
vertebrae in Captorhinus are not as well known, but the decrease -
posteriorly in the difference between heights of spines would seem to
indicate a posteriorwards tapering of the “extended nuchal ligament,”
which probably ended shortly before the sacrum. A ligament of this
kind may have been correlated with the large size of the head relative to
the rest of the body in Captorhinus and, especially, Pantylus; but it is
extremely difficult to account for this apparently rare “solution” except
for the weak suggestion that it was perhaps a short-lived “experiment”
among various early tetrapods. Perhaps it is significant that this condi-
tion is not evident, at least not clearly, in large captorhinomorphs with
wide, swollen neural arches such as Labidosaurus (see figures in Case,
191 1a).

This would still, of course, not satisfactorily explain the actual
alternation in spine height. The best I can tentatively offer is that, with
a system of strong supraspinal and interspinal ligaments such as is
envisioned here, firm attachment of these ligaments to only alternate
vertebrae would have averted excessive rigidity of the vertebral
column. As possible corroboration may be cited the presence of a single
much shortened neural spine in the cervical region of such greatly
different tetrapods as the labyrinthodont amphibian Eryops and the
therapsid reptile Moschops (see figures in Case, 1911b and Gregory,
1926).

An alternative explanation would involve differences in the number
of vertebral segments spanned by elements of the epaxial musculature.
This would imply differences in locomotory patterns between those
captorhinomorphs — and microsaurs — that show alternation in neu-
ral spine height and those that do not. Unfortunately, the distribution

ive)
‘mn

Permian Tetrapods

of the phenomenon is at present too poorly understood to permit the
correlations that would be required to substantiate this theory. The in-
dicated system of ligaments seems, to me, to favor the first explanation.

The distribution of the phenomenon of alternation of neural spine
height is puzzling. As far as I know, it has been reported heretofore only
in Pantylus. Dr. E. C. Olson has recently shown me that it occurs also in
a specimen of Captorhinikos sp. from the Hennessey Formation of
Oklahoma. This is its known extent: one Early Permian microsavrian
amphibian and two Early Permian captorhinomorph cotylosaurs of the
family Captorhinidae. Carroll (1969) did not observe it in the much
earlier and more primitive romeriid captorhinomorph Paleothyris
acadiana from the Middle Pennsylvanian, a species known from an
almost complete skeleton. White (1939) noticed certain variations in
the neural spines along the column of the labyrinthodont amphibian
Seymouria baylorensis — in which some of the spines are bifid — but
he also noted that there is no apparent regularity in the occurrence or
position of the bifid spines.

It is, of course, possible that the condition does occur but has simply
been overlooked in various other known primitive tetrapods, possibly
due to incompleteness and disarticulation of vertebrae in which case
alternation may have been mistaken for gradual serial change, possibly
due in instances to recalcitrant matrices in which case small differences
in spine height may have been minimized through preparation tech-
niques. It would certainly seem worthwhile to re-examine other
microsaurs and cotylosaurs in hopes of reaching a better functional
explanation of this apparently rare phenomenon.

ACKNOWLEDGEMENTS

I extend my thanks to Drs. W. W. Dalquest, E. C. Olson and J. M. Savage for
assistance noted in the text, to Dr. R. Zangerl of the Field Museum for the loan
of materials under his care, to Mr. K. S. Pogany who drew the illustration, and
to the National Science Foundation for aid received through grant GB-7784.

LITERATURE CITED
CaRROLL, R. L., 1968. The postcranial skeleton of the Permian microsaur Panty-
lus. Canadian J. Zool., 46: 1175-1192.

1969. A Middle Pennsylvanian captorhinomorph, and the interrelation-
ships of primitive reptiles. J. Paleont., 43: 151-170.

Case, E. C., 191la. A revision of the Cotylosauria of North America. Carnegie
Inst. Wash., Publ. No. 145, 122 p.

1911b. Revision of the Amphibia and Pisces of the Permian of North

America. Carnegie Inst. Wash., Publ. No. 146, 179 p.

86 Bulletin So. Calif. Academy of Sciences

Fox, R. C., anpD M. C. Bowman, 1966. Osteology and relationships of Captorhinus
aguti (Cope) (Reptilia: Captorhinomorpha). Univ. Kansas Paleont. Contrib.,
Vertebrata, Art. 11, 79 p.

Greoory, J. T., F. E. PEABODY AND L. I. PRICE, 1956. Revision of the Gymnarthri-
dae, American Permian microsaurs. Peabody Mus. Nat. Hist., Yale Univ.,
Bull. 10, 77 p.

Grecory, W. K., 1926. The skeleton of Moschops capensis Broom, a dinocepha-
lian reptile from the Permian of South Africa. Bull. Amer. Mus. Nat. Hist.,
56: 179-251.

OLson, E. C., 1954. Fauna of the Vale and Choza: 9, Captorhinomorpha. Fieldi-
ana, Geol., 10: 211-218.

WHuitE, T. E., 1939. Osteology of Seymouria baylorensis Broili. Bull. Mus. Comp.
Zool., Harvard Coll., 85: 325-409.

Accepted for publication January 29, 1970

Bull. So. Calif. Acad. Sci. 69(2): 87-99, 1970

THE EFFECT OF TEMPERATURE ON THE
SETAL CHARACTERISTICS IN POLYNOIDAE
(ANNELIDAE: POLYCHAETA).

KENNETH A. HILLGER AND DONALD J. REISH
Department of Biology
California State College, Long Beach
Long Beach, California 90801

ABSTRACT: The parapodia of two species of polynoid poly-
chaetes, Halosydna brevisetosa and H. johnsoni, were ampu-
tated and allowed to regenerate under varying temperature
conditions to test the validity of the structure of the neurosetae
as a systematic character. H. brevisetosa has entire neurosetae
and inhabits water 5 to 6°C colder than H. johnsoni. This
latter species has bifid neurosetae. Trends toward bifid setae
were noted when regeneration of parapodia occurred at warm
temperatures and entire setae developed at cold temperatures.
The authors concluded that H. johnsoni is a synonym of H.
brevisetosa.

INTRODUCTION

The type, distribution, and characteristics of setae found in poly-
chaetous annelids are of particular importance in distinguishing
families, genera, and species. They are especially convenient charac-
teristics since they are one of the few hard parts found in polychaetes;
they lend themselves to easier description and figuring than soft parts
such as parapodia or anterior regions. A seta is composed of a chitin-
protein complex which is secreted by a single setal follicle cell. Setae
are constantly being formed to replace ones that are discarded (Bobin,
1944). As the animal grows to maturity, the particular setal type
becomes larger with each replacement (Reish, 1954a). Variations of a
particular setal type are known to vary not only with age but also with
body region (Reish, 1954a). The importance of these variations is
undoubtedly one of the principle reasons for differences of opinion
between “lumpers” and “splitters” in polychaete systematics. Since the
distinction of polychaete species is based on preserved material, it is
difficult to know for sure whether such setal variations are individual
or specific differences. The analysis of offspring from one laboratory
mating of a nereid polychaete indicated that at least three species had
been described earlier on the basis of individual variation (Reish,
1954b).

87

88 Bulletin So. Calif. Academy of Sciences

The influence of water temperature on the distribution of marine
organisms is well known. Acclimation by an organism to temperature
and salinity depends upon genetic background, environmental history,
physiological condition and life history (Kinne, 1963). Since it is
impossible to isolate a given factor in studying genetic or non-genetic
adaptions under field conditions, a laboratory study was selected to
test the stability of setal characteristics utilizing temperature as the
variable.

Two species of the polynoid genus Halosydna are commonly en-
countered in the intertidal zone along the eastern Pacific coast; H.
brevisetosa Kinberg is typically present north of Point Conception and
H. johnsoni (Darboux) south of this locality. Their recorded distribu-
tions overlap, however, with H. brevisetosa reported from Alaska to
southern California and H. johnsoni from southern California, the
Pacific side of Mexico and Panama, Galapagos Islands, and Peru
(Hartman, 1968; Hartmann-Schréder, 1960). These two species have
been separated on the basis of the nature of the distal portion of neuro-
setae; they are bifid in H. johnsoni (Fig. 1) and entire in H. brevisetosa
(Fig. 2). The distinction of these two forms as valid species has been
questioned previously but not resolved. Berkeley and Berkeley (1941)
conducted a comparative study of H. insignis [=H. brevisetosa] and
H. johnsoni from collections made in southern California. They noted
considerable similarity between the two species, and they were of the
opinion that a transition from a typical H. brevisetosa to a typical H.
jJohnsoni exists along the west coast of North America with intermedi-
ates occurring in southern California. Pettibone (1953) wrote that
these two species are so closely related that they may prove to be
synonymous; Hartmann-Schroder (1960) was of the same opinion.
Earlier Monro (1928) stated that because of small differences in
characteristics such as size, shape, and abundance of tubecules on the
elytrae the genus Halosydna was in need of revision. He concluded
that the nature of neurosetae seemed to be a more dependable and
constant character.

Since many names have been applied to both species in the past, the
principle citations included herein are:

Halosydna brevisetosa Kinberg, 1855

Halosynda brevisetosa Kinberg, 1855; Hartman, 1939; Berkeley and
Berkeley, 1948; Pettibone, 1953.

Lepidonotus insignis Baird, 1863.

L. grubei Baird, 1863.

Effect of Temperature on Setae 89

Polynoe brevisetosa (Kinberg). Johnson, 1897.

P. insignis (Baird). Johnson, 1901.

Halosydna insignis (Baird), Moore, 1910; Berkeley and Berkeley,
1941.

Halosydna johnsoni (Darboux) 1899

Polynoe reticulata Johnson, 1897, p. 170 [not P. reticulata Claparéde,
1870, p. 374].

Lepidonotus johnsoni Darboux, 1899. [new name for Polynoe reti-
culata Johnson, a homonym].

Polynoe californica Johnson, 1901.

Halosydna californica (Johnson). Moore, 1910.

Halosydna macrocephala Essenberg, 1917.

Halosydna johnsoni (Darboux). Hartman, 1939; Hartmann-Schréder,
1960.

The recognition of the previously questioned taxonomic status of
these two species and the existence of a temperature gradient along the
distribution of these species led us to ascertain whether or not a rela-
tionship could be demonstrated between the form of the neurosetae and
water temperature. Both field and laboratory investigations were
conducted in this study. The primary difference between these two
species is the presence or absence of the subspiral tooth on neurosetae
(Figs. 1-2); this characteristic proved a convenient tool to investigate
the importance of temperature upon setal structure.

MATERIALS AND METHODS

Collections of H. brevisetosa were made from floating boat docks in
Morro Bay, California and of H. johnsoni from the same ecological
niche at Playa del Rey Marina, Alamitos Bay, and Huntington Harbour
Marina. Specimens from these localities were used in laboratory
regeneration experiments. Survey collections were made monthly at
Playa del Rey Marina from October 1966 through December 1967.
Bimonthly collections were made from floating docks at the marina in
Oxnard, California from February 1967 through April 1968.
Regeneration Experiments. In the laboratory individual specimens
were placed in 500 ml erlenmeyer flasks with 50 ml of sea water. A
minimum of 10 specimens were used for each experiment. They were
anesthetized in a solution of 5 per cent ethanol in sea water. A single
parapodium was removed with scissors under a dissecting microscope
and preserved. The worm was placed in a petri dish containing sea

90 Bulletin So. Calif. Academy of Sciences

water until it revived; it was then returned to the erlenmeyer flask.
Specimens were fed frozen brine shrimp as needed. Water was changed
at intervals of 3 to 8 days.

After the techniques were perfected, six experiments were con-
ducted: four with H. johnsoni and two with H. brevisetosa. Each
experiment was designed to ascertain the effect of temperature on
neurosetal development from a particular body region. Single para-
podia were removed from the anterior, mid-, and posterior regions of
H. johnsoni, but only from the anterior and posterior end of H. brevi-
setosa. Parapodia were removed and examined on three different
occasions: (1) after initial removal from a recently collected specimen,
(2) after regeneration of a parapodium, and (3) after a second regenera-
tion of a parapodium from the same segment but at a different tempera-
ture. Regeneration experiments were conducted with H. johnsoni at
room temperature (23.0-26.5°C) and at 16-18°C. Experiments with
H. brevisetosa were conducted at 16-18°C and 18-20°C. Specimens of
H. brevisetosa did not survive room temperatures of 23.0-26.5°C.

Survey Collections. Collections were made from the two localities
listed above. All fouling organisms were removed from the side of a
boat float. Sub-surface water temperature was recorded at the time of
collection. All specimens of Halosydna were preserved and representa-
tive parapodia examined.

Method of Analysis. The Neurosetae from amputated parapodia
were recorded to one of three structural catagories: bifid (Fig. 1), entire
(Fig. 2), or intermediate (Fig. 3). This latter type of seta was defined as
one with an obscure or indistinct subapical tooth.

The hypothesis that water temperature influenced the form of
neurosetae was tested by three methods. The first method utilized the
standard error of proportion to determine the probability of obtaining
differences as great or greater than expected by chance alone. Using
this method, it was possible to determine whether or not the tempera-
ture conditions to which the animals were subjected during regenera-
tion had any influence on the form of neurosetae produced. The 95 per
cent confidence level was computed for each of the experiments and
survey collections.

The second method compared per cent bifid, intermediate and
entire neurosetae regenerated with those present prior to amputation.
The numbers of setae in each category were divided by the total and
multiplied by 100 to obtain the per cent of the total.

The third method attempted to show trends toward development of
a setal type in either cold or warm temperature conditions during
regeneration. This was achieved by comparing the per cent of total of

Effect of Temperature on Setae 91

l 2 3

Figures 1-3. Neurosetae from amputated parapodia: Figure 1, bifid; Figure 2,
entire; Figure 3, intermediate.

bifid, intermediate and entire setal forms produced in the cold bath and
at room temperature. At the conclusion of the experimental period the
setae of non-regenerating parapodia adjacent to those regenerating
were examined and compared.

DATA

The data for the setal analysis of Halosydna are summarized in Tables
1-4. Table 1 represents the results from field collections made over a
period of 14 months at two localities in southern California. Tables 2
and 3 summarize the results of regeneration experiments in H. johnsoni
and Table 4 includes the results for H. brevisetosa.

Field Collections. All specimens collected from Playa del Rey were
identified as H. johnsoni (Table 1) although 8.4 per cent of the setae of
the posterior end were entire. An increase in the percentage of bifid and
intermediate setal forms were noted proceeding posteriorly. Both
species were present at Channel Islands Harbor. Here again the trend
towards the greater per cent bifid and intermediate setal forms in the
posterior region was noted with H. johnsoni. Such was not the case
with H. brevisetosa. The average water temperature was 2.5°C higher
at Marina del Rey than Channel Islands Harbor.

Bulletin So. Calif. Academy of Sciences

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Effect of Temperature on Setae 93

Regeneration Experiments with H. johnsoni. The influence of water
temperature on setal characteristics is indicated in Table 2 in which
regeneration occurred initially at 16-18°C then after the second
removal, the parapodia were allowed to regenerate at 23-26.5°C. The
number of bifid setae decreased at the colder temperature and then
increased at room temperature; however, the percentage of bifid setae
did not attain the number present initially (Table 2). A greater number
of entire setae occurred in the posterior parapodia at all temperatures.
The results for the reverse experiment, that is, parapodia regenerated
at 23-26.5 then at 16-18°C, did not demonstrate the influence of
temperature on setal form (Table 3). Fewer bifid setae with corre-
sponding increases in intermediate and entire setae occurred in these
regenerating parapodia. All neurosetae present on parapodia adjacent
to regenerating parapodia did not undergo these changes.

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conducted with this species indicated an increase in the per cent occur-
rence of bifid setae in warmer temperatures (Table 4). The temperature

of the second regenerating experiments varied from 14 to 20°C which
_ was greater and less than the first experiment, but, nevertheless, the per
cent occurrence of bifid setae increased (Table 4). All neurosetae
present on parapodia adjacent to regenerating parapodia remained
unchanged.

DISCUSSION

The working hypothesis was that if a number of specimens of H. brevi-
setosa and H. johnsoni were subjected experimentally to temperature
conditions congruent with that of their natural environment and
allowed to regenerate amputated parapodia, the neurosetae produced
would be entire and bifid in structure, respectively. Furthermore, if they
were subjected to varying temperature conditions, the colder the
temperature, the greater the percentage of regenerated entire setae,
regardless of which species. The basis for this hypothesis was the earlier
reports by Berkeley and Berkeley (1941), Pettibone (1953), and
Hartmann-Schréder (1960) who questioned the validity of these two
forms as separate species. Halosydna brevisetosa is generally collected
from water which is 5 to 6°C colder than that of H. johnsoni. There are
locations, nevertheless, in southern California, such as Channel Islands
Marina, where both species are found living together (Table 1). It is, of
course, possible that we have two species whose distribution overlap
in southern California.

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Bulletin So. Calif. Academy of Sciences

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Effect of Temperature on Setae 97

neurosetal variation, both species were subjected to varying tempera-
ture conditions as described above. The data presented in Table 2 in
which the parapodia of H. johnsoni regenerated first at a cold tempera-
ture then at room temperature indicated statistically significant differ-
ences. The average percentage of entire setae regenerated was higher
in colder temperatures than at room temperatures. The reverse experi-
ment (Table 3), in which the parapodia were regenerated first at room
temperature then at a cold temperature, did not follow the predicted
results. A significant reduction in the per cent occurrence of bifid setae
were observed along with a corresponding increase in the presence of
intermediate setae. The results in this last experiment (Table 3), while
difficult to interpret in terms of initial hypothesis, do indicate the lack
of stability of this character as taxonomic difference. It is of interest
to note that while setae were being continually formed on the undis-
turbed parapodia during the experiment, the setae of these parapodia
did not change from their original pattern.

Regeneration experiments with H. brevisetosa were not possible at
room temperature, but the number of bifid setae increased significantly
at both temperatures studied experimentally (Table 4).

While it was not possible to change all specimens from one “species”
to another, the fact that differences could be induced experimentally
indicate that the nature of the tip of the neurosetae is neither a valid nor
a reliable systematic character. Since the structure of the neurosetae is
the only morphological character known to distinguish these two
“species” it is therefore the opinion of the authors that Halosydna
brevisetosa and H. johnsoni are the same species. Their differences are
probably the result of the effect of an environmental factor, in this case,
temperature. Therefore, as outlined in the synomies above, H. johnsoni
becomes a synonym of H. brevisetosa. Since this constitutes the first
known case of temperature regulating the structure of setae in poly-
chaetes, the authors cannot help wondering whether or not this occurs
in other species of polychaetes.

SUMMARY

1. Regeneration experiments were conducted with the polynoid poly-
chaetes Halosydna brevisetosa, a species inhibiting colder waters,
and H. johnsoni, a species inhabiting warmer waters, to determine
the effect of temperature on the form of the neurosetae.

2. Single parapodia were amputated from different body regions and
allowed to regenerate at varying temperatures. Neurosetae were

98 Bulletin So. Calif. Academy of Sciences

examined before and after amputation and the results analyzed
statistically.

3. Extensive variation in the neurosetal form was noted in both species;
however, trends were noted toward the development of bifid setae at
warmer temperatures and entire setae at cold temperatures. These
trends corresponded to what was observed in field collections taken
at various localities.

4. It was concluded that the neurosetal form of H. brevisetosa and H.
jJohnsoni is temperature regulated and, therefore, on the basis of this
study, that H. johnsoni is a synonym of H. brevisetosa.

LITERATURE CITED

BAIRD, W., 1863. Descriptions of several new species of worms belonging to the -
Annelida Errantia and Sedentaria or Tublcola of Milne Edwards. Zool. Soc.
London, Proc., p. 106-110.

BERKELEY, E. AND C. BERKELEY, 1941. On a collection of polychaeta from south-
ern California. Bull. So. Calif. Acad. Sci. 40: 16-60.

1948. Annelida, Polychaeta errantia. Canad. Pac. Fanna. no. 9b(1). Fish.
Res. Bd. Canad. 100 p.

BoBIn, G., 1944. Morphogéneése des soies chez les Annélides polychetes. Inst.
Océanogr. Paris, Ann. 22: 1-106.

CLAPAREDE, E., 1870. Les Annélides Chétopodes du Golfe de Naples. Soc. Phys.
Geneve, Mém. 20: 365-542.

Darsoux, J. G., 1899. Recherches sur les Aphroditiens. Inst. Zool. Univ., Mont-
pellier, Trav., ser. 2, Mém. No. 6, 276 p.

ESSENBERG, C., 1917. Description of some new species of Polynoidae from the
coast of California. Univ. Calif. Publ. Zool. 18: 45-60.

HarTMAN, O., 1939. Polychaetous annelids — pt. 1 Aphroditidae to Pisionidae.
Allan Hancock Pacific Exped. 7: 1-156.

HARTMANN-SCHRODER, G., 1960. Zur polychaeten-fauna von Peru. Beitrage. zur
Neotropischen Fauna. 2: 1-44.

Jounson, H. L., 1897. A preliminary account of the marine annelids of the Pacific
coast with descriptions of new species. Euphrosynidae, Amplinomidae,
Palymipridae, Polynoidae and Sigalionidae. Calif. Acad. Sci. Zool., Proc.
1: 153-190.

1901. The polychaeta of the Puget Sound region. Boston Soc. Nat. Hist.,
Proc. 29: 381-437.

KINBERG, J. G. H., 1855. Nya slagten och arter af Annelider. Oefv. Vet. Akad.
Stockholm, Forh. 12: 381-388.

Effect of Temperature on Setae 99

KINNE, O., 1963. The effects of temperature and salinity on marine and brackish
water animals. Jn Oceanography and Marine Biology, H. Barnes, Editor,
George Allen and Unwin, Ltd., London. 1: 301-340.

Monro, C. C. A., 1928. Polychaeta of the families Polynoidae and Acoetidae from
the vicinity of the Panama Canal, collected by Dr. C. Crossland and Dr. Th.
Mortensen. Linn. Soc. J. Zool. 36: 553-576.

Moore, J. P., 1910. The polychaetous annelids dredged by the U.S.S. “Albatross”
off the coast of southern California in 1904: II. Polynoidae, Aphroditidae,
and Segalionidae. Proc. Acad. Nat. Sci., Phila. 62: 328-402.

PETTIBONE, M. H., 1953. Some scale-bearing polychaetes of Puget Sound and
adjacent waters. Univ. Wash. Press, 89 p.

REISH, D. J., 1954a. The life history and ecology of the Ploychaetous annelid
Nereis grubei (Kinberg). Allan Hancock Found. Publ., Occasional Paper No.
14, 75 p.

1954b. Nomenclatural changes and redescription of two nereids (Anne-

lida, Polychaeta) from the eastern Pacific. Bull. So. Calif. Acad. Sci. 53: 99-

106.

Accepted for publication January 26, 1970.

Bull. So. Calif. Acad. Sci. 69(2): 100-103, 1970

REVIVAL OF THE MONOTYPIC GENUS
BOSHELLIA EWING, 1950
(ACARINA: TROMBICULIDAE)

JAMES M. BRENNAN
AND
PAauL H. VERCAMMEN-GRANDJEAN

U.S. Department of Health, Education, and Welfare, Public Health Service,
National Institutes of Health, National Institute of Allergy and Infectious
Diseases, Rocky Mountain Laboratory, Hamilton, Montana 59840 and the
George Williams Hooper Foundation, University of California, San Francisco
Medical Center, San Francisco, California 94122.

AsstractT: Boshellia Ewing is resurrected from synonymy and
redescribed. The type species Neoschoengastia hirsuta Boshell
and Kerr is also redescribed and a lectotype designated.

INTRODUCTION

Ewing, 1950, described Boshellia, monotypic for Neoschoengastia
hirsuta Boshell and Kerr, 1942. Wharton and Fuller, 1952, treated the
genus with some doubt as a synonym of Euschoengastia with which,
according to present concepts, it has almost no affinities. They stated,
“Boshellia might be recognized as a subgenus of Euschongastia, but to
do so would necessitate dividing Euschdngastia into a large number of
subgenera if consistent treatment were to be followed. This course
seems to be unjustified at the present time.”

We now regard Boshellia as a unique and valid genus, as will be seen
from the redescription below. Further, we are unaware of any species
other than the type species which fits our concept of the group.

Boshell and Kerr based their description of Neoschoengastia hirsuta
on 19 specimens mounted on a single slide labelled “cotype,’” USNM
No. 53018. Two specimens represent other species, Eutrombicula
goeldii (Oudemans) and Colicus colombiae (Boshell and Kerr). The
remaining 17 are N. hirsuta. All have now been remounted on separate
slides to avoid confusion in indicating the lectotype, here designated as
a dorsally mounted specimen on the only slide bearing the original
Boshell and Kerr labels with “‘lectotype” added. All specimens are in
good to excellent condition.

100

Revival of Boshellia 101

Boshellia Ewing

Boshellia Ewing, 1950.

Euschongastia, Wharton and Fuller, 1952.

Type species: Neoschongastia hirsuta Boshell and Kerr, 1942.

No other species known.

Neotropical trombiculine larvae ectoparasitic on rodents. Leg seg-
mentation 7-6-6; 3 genualae I, a genuala I] and III, tibiala III, sub- and
parasubterminala, microtarsala I papilliform and proximad of tarsala
I; coxae unisetose; coxa III with angular posteromedial projection.
Scutum wider than long, with 5 setae and expanded sensillae. Eyes
2/2. Cheliceral blade with tricuspid cap. Galeal seta nude. Palpal
tibial claw trifurcate; palpal tarsus with 5 branched setae, a subter-
minala and a tarsala.

Boshellia is distinguished from the related Pseudoschoengastia
Lipovsky and Cordiseta Hoffmann by palpal tarsus with a subter-
minala, coxa III with posteromedial lobe, microtarsala I papilliform,
and lacking setae between coxae II and III.

Boshellia hirsuta (Boshell and Kerr)
Figure |

Neoschongastia hirsuta Boshell and Kerr, 1942 (reprint).
Boshellia hirsuta, Ewing, 1950.

Euschéngastia ? hirsuta, Wharton and Fuller, 1952.
Euschongastia hirsuta, Fauran, 1959.

Type data: Lectotype and 16 paralectotypes, United States National
Museum No. 53018, off Proechimys chrysaeolus, Restrepo, Meta,
Colombia, 16 July 1937, Moyano, collector.

Other material: Eleven specimens off 2 Oryzomys albigularis, Pico
Rengifo, 1370 m, La Macarena, Meta, Colombia, 24 and 25 March
1957, Field Museum of Natural History.

Diagnosis: Readily distinguished from other neotropical chiggers
having leg segmentation 7-6-6 by the large, conspicuous, shallow pits
encircling the numerous body setae and by the posteromedial angular
lobe of coxa III.

Body: Ovate, becoming ellipsoidal with engorgement. Eyes 2/2,
subequal, in a plate, diameter of anterior eye 11,. Length and width of
practically unengorged lectotype, 285 by 235,. Anus at approximate
fifth row from posterior extremity.

102 Bulletin So. Calif. Academy of Sciences

Figure 1. Boshellia hirsuta (Boshell and Kerr). Scutum, eyes, anteromedial dorsal
setae, and legs I to III with specialized setae showing measurements in microns.

Gnathosoma: Moderately to heavily punctate. Cheliceral blades with
tricuspid cap. Palpal setae branched, the genual seta with the least
branches; tarsis with 5 branched setae, a subterminala and a tarsala;
tibial claw trifurcate. Galeal seta nude.

Scutum: As figured, fairly deep, wider than long with shallow
curving non-sinuous posterior margin, rather densely punctate. An-
teromedian seta set back from margin, anterolaterals with very long
barbs on basal half. Sensillae broad-ovate, long setules on basal part of
heads, short coarse barbs on stems. Measurements of lectotype: AW 49,
PW 63, SB 17, ASB 24, PSB 20, AP 26, AM 31, AL 38, PL 40, S31 X
14.

Legs: Segmentation 7-6-6, basifemur and telofemur of legs II and III
fused. Coxae densely, other segments moderately to sparsely punctate.

Revival of Boshellia 103

Specialized setae as figured, microtarsala I papilliform and proximad of
tarsala I. Nonspecialized setae moderately to rather heavily branched.
Coxa III with posteromedial angular lobe, coxal III seta at antero-
medial margin.

Body setae: Similar to posterolateral scutal setae, about 200 dorsally
and somewhat fewer ventrally, all with normal bases but arising from
large and conspicuous circular pits. Humerals 48, , other dorsals sub-
equal in length, 24 to 26, , except a few in anterolateral area, up to 35,.
The two distinct sternals 38, and with long barbs. Ventrals extend to
level of coxae II, 20 to 25,, postanals not structurally differentiated.

LITERATURE CITED

BOSHELL, J. AND J. A. KErRR., 1942. Veinticinco especies nuevas de Trombidiideos
de Colombia. Rev. de la Acad. Colombiana de Ciencias Exactas, Fisico-
Quimicas y Naturales, Bogota, 17: 110-127 (in reprint, 3-38).

Ewin, H. E., 1950. A redescription of four genera of chigger mites, together with
a redescription of a new genus and subgenus. Proc. Ent. Soc. Wash. 52: 291-
299.

Fauran, P., 1959. Nouveaux Trombiculidae de Guyane francaise. Arch. de I’ Inst.
Pasteur Guyane francaise et Inini No. 457, 15 p.

WHARTON, G. W. AND H. S. FULLER., 1952. A Manual of the Chiggers. Mem. No. 4
Ent. Soc. Wash., 185 p.

Accepted for publication March 20, 1970.

Bull. So. Calif. Acad. Sci. 69(2): 104-111, 1970

THE ORGANIC MATRIX IN DEVELOPING
DENTAL ENAMEL AND DENTIN STUDIED BY
SCANNING ELECTRON MICROSCOPY

JOHN D. SOULE*
Department of Histology
School of Dentistry
University of Southern California
Los Angeles, California 90007

ABSTRACT: Sections of the matrix of developing dentin and
enamel from the foetal pig, alligator lizard, bullfrog and
trigger-fish were examined with scanning electron microscopy.
The major difference appears to be in the number and size of
the tubules that permeate the matrices. The pre-dentin matrix
is a loose meshwork of fibrillae surrounding the area of the
dentinal tubules. The older circumpulpal dentin intertubular
matrix is fibrillar, with the interstices of the matrix filled with
an amorphous ground substance. The enamel organic matrix
has a fibrillar appearance, with no evidence of rod structure
being seen.

Observed for the first time is an apparent system of micro-
tubiculi with diameters of about 0.24 permeating the enamel
matrix. Such a system of microtubiculi would provide a
pathway for diffusion of inorganic salts and for the removal
of soluble organic material during amelogenesis. The simi-
larity of development and structure in amphibians and reptiles
suggests the possibility of utilizing these animals in experi-
mental mineralization studies.

INTRODUCTION

The organic matrix of developing dental enamel and dentin in several
species of lower vertebrates was studied, utilizing the scanning electron
microscope. Representative material from bony fish, amphibians and

reptiles was examined and compared with that of the mammal.

These investigations, coupled with other studies of fish, amphibians
and reptiles, have revealed that the organic matrix of developing
enamel is formed by the ameloblasts of the enamel organ, and that the
matrix of the dentin is formed by the odontoblasts of the dental papilla.
Thus it is established that amelogenesis and dentinogenesis in lower

*Editor’s Note:

Publication costs funded by the School of Dentistry, University of Southern

California.

104

Developing Teeth 105

vertebrates occurs in a manner very similar to, if not identical to, the
enamel and dentin synthesis found in mammals (Kvam, 1958a, 1958b;
Kerr, 1960; Soule, 1966, 1969a, 1969b; Miller, 1969; Smith and
Miles, 1969).

Knowledge of the structure of the organic matrix of vertebrate dental
enamel and dentin during tooth formation has been based in the past
upon histological and histochemical studies utilizing the light micro-
scope, and upon ultrastructure studies employing transmission electron
microscopy. Boyde and Stewart (1963) described the surface features
of the developing front of enamel, showing the pattern of depressions
made by Tomes’ processes of the ameloblasts by use of the scanning
electron microscope.

METHODS AND MATERIALS

The jaws of a trigger-fish (Balistes bursa), an alligator lizard (Ger-
rhonotus scinicicauda), a bullfrog (Rana catesbeiana), and a foetal pig
(Sus domestica) with a crown-rump length of 160 mm were fixed in
neutral formolsaline and demineralized in 5% trichloracetic acid.
Selected labiolingual sections, cut at six microns, were deparaffinized,
slowly air dried, and then vapor coated with pure gold 300 Angstroms
in thickness under vacuum in a JEE-4B vacuum evaporator.

The sections were examined and photographed at an accelerating
voltage of 25 kilovolts with a JSM-2 scanning electron microscope,
manufactured by the Japan Electron Optics Laboratory Company,
Ltd. Low power (X150-X210) photomicrographs were used for orien-
tation, and high power (X2,280-X15,200) photomicrographs for
structural details. Illustrations from 35 mm film were enlarged to the
same degree so that size relationships remain constant. Alternate
sections were processed with standard histological stains for compara-
tive purposes.

RESULTS

The organic enamel matrix and dentin matrix are structurally uniform
throughout the representatives of the vertebrate classes investigated,
within the limitations imposed by tooth size. The major difference is
found in the degree of porosity, which is a reflection of the number and
size of the tubules present.

Under low magnifications of the scanning electron microscope
(S.E.M., X150-X210), the sections of the organic matrix of developing
dentin have a comparatively smooth, homogenous appearance. Numer-
ous, uniformly scattered apertures are observed which mark the

106 Bulletin So. Calif. Academy of Sciences

presence of the dentinal tubules. Under higher S.E.M. magnifications
(X4,560-X 15,200), striking differences become apparent between the
area of the matrix of the pre-dentin and the matrix of the more mature
circumpulpal dentin.

Best seen in the material from the foetal pig, the organic matrix of
the pre-dentin is a complex meshwork of delicate, branching pre-
collagenic and collagenic fibrillae with small, irregularly shaped in-
terstices and a minimum of amorphous organic deposits. The pre-
dentin matrix is sharply distinguished from the intertubular matrix of
the circumpulpal dentin. (Figs. 1, 2)

There is a notable increase in the amount of an amorphous organic
substrate deposited among the fibrillae, obliterating the interstices. The
circumpulpal dentin intertubular matrix has an irregular, coarse,
fibrillar character at magnifications of X4,560 and above. The open-
ings made by the dentinal tubules that contain the odontoblastic
processes (Tomes’ dentinal fibrillae) are seen throughout this area, as
well as in the pre-dentin (Fig. 3). .

In the demineralized material, the diameter of the dentinal tubules
ranges from 6 to 8x. The odontoblastic processes within the dentinal
tubules are from | to 2, in diameter. The space immediately surround-
ing the odontoblastic processes was produced by the demineralization
of the hypermineralized peritubular dentin. This leaves a sparse,
delicate, fibrillar meshwork with highly irregular interstices, and
accounts for the increased size of the dentinal tubules in decalcified
material. The thin lateral branches of the odontoblastic processes are
also found within that space, and they extend into the intertubular
dentinal matrix within very narrow channels that range in diameter
from 0.5 0.7, .

The dentin matrix of the developing teeth in the fish, amphibians
and reptiles investigated is similar to that found in developing mam-
malian teeth. The scanning electron microscopy done shows that all
have a fibrillar appearing intertubular matrix permeated by dentinal
tubules which contain odontoblastic processes and the slender collat-
eral tubules. In the lower vertebrates, the dentinal tubules are much
narrower in diameter than those seen in mammalian teeth at compa-
rable levels, ranging from 0.8 to 2.0, in diameter.

The enamel matrix has a fibrillar appearance under low S.E.M.
magnifications which becomes pronounced as the magnifications are
increased to X7,600 and above. This is particularly evident in mam-
malian material. At higher S.E.M. magnifications (X7,600 to X 15,200)
the organic matrix is seen to be rough and coarsely fibrillar. The cut

Developing Teeth 107

Figure 1. Odontoblasts, pre-dentin, and circumpulpal dentin. Dentinal tubules
with odontoblastic processes in the pre-dentin and in the intertubular matrix of
the circumpulpal dentin. Foetal pig. X2,280 Figure 2. Fibrillar pre-dentin
matrix with irregular interstices and developing dentinal tubules. Odontoblastic
processes partially pulled away. Foetal pig. X7,600 Figure 3. Circumpulpal
dentin matrix with dentinal tubules and odontoblastic processes. Note lateral
branches of odontoblastic processes, and the tubuli in the dentin matrix for these
collateral branches. Foetal pig. X4,560. Figure 4. Young enamel matrix
showing fibrillar character and scattered microtubiculi. Foetal pig. X7,600.

108 Bulletin So. Calif. Academy of Sciences

Figure 5. Older crown enamel matrix with scattered microtubiculi. Foetal pig.
X7,600. Figure 6. Dentino-enamel junction. Dentin matrix with dentinal
tubules. Marked fibrillar appearance of enamel matrix partially obscures micro-
tubiculi. Alligator lizzard. X7,600. Figure 7. Dentino-enamel junction. Dentin
matrix with dentinal tubules, and young enamel matrix with microtubiculi.
Bullfrog. X7,600. Figure 8. Dentino-enamel junction. Dentin matrix with
dentinal tubules, and young enamel matrix with microtubiculi. Trigger-fish.
X7,600.

Developing Teeth 109

surfaces of the sections seen at high magnifications are highly irregular,
with many well defined depressions and hillocks. No evidence of rod
structure can be seen in the developing enamel matrix of the material
examined (Figs. 4, 5).

Scattered throughout the enamel matrix in all of the mammalian
sections examined are numerous pore-like openings, with diameters
of 0.2,,. These are well below the resolving power of the light micro-
scope, and have not been previously reported in the literature. The
openings apparently mark the presence of a system of microtubiculi.
Similar minute openings on the cut surfaces of the developing enamel
matrix were found in the sections of the fish, amphibian and reptilian
material examined. In the lower vertebrates, the microtubiculi measure
0.24 in diameter, the same as those in the enamel matrix, but the
number of tubiculi present is reduced (Figs. 6, 7, 8).

DISCUSSION

The phenomenon of permeability of mature dental hard tissues has
received the attention of a series of investigators for many years. Much
of this work has been summarized by Allan, by Gustafson, and by
Stack in their articles in Miles, 1967, and by Gaunt, Osborn and Ten
Cate, 1967.

The mechanisms for passage of fluid through the system of tubules in
the dentin is well known. Less is known about fluid passage through
enamel. It has been suggested that the fluid pathways in mature enamel
are narrow “pores” (Poole and Stack, 1965); “microcapillaries”
(Linden, 1968); or a system of “micropores” (Gaunt, Osborn and Ten
Cate, 1967).

As shown by the scanning electron microscope, in the sections of
developing enamel matrix of all the vertebrate classes examined, the
microtubiculi appear to be part of a network of fine channels. The
presence of microtubiculi during tooth development would provide
pathways for the diffusion of inorganic salts into the organic matrix,
and a pathway for the removal of soluble organic matter during the
mineralization phase of amelogenesis. Such passageways would also
provide a means of explaining transport rates which have been recorded
and are incompatible with the current concepts of enamel structure.
Certainly further investigation is necessary to determine the extent of
the tubicular system.

The number of investigations which have now been completed on
lower vertebrates confirms the similarity of developmental structures
between the dental! hard tissues of mammals and those of lower verte-

110 Bulletin So. Calif. Academy of Sciences

brates. It refutes, rather conclusively the previously held concept that
the formation of lower vertebrate enamel differs significantly from that
of mammals. This similarity opens up the possibility of the use of
amphibians and of reptiles for studies of mineralization and transport.

ACKNOWLEDGMENTS

The author gratefully acknowledges the aid of Dr. Henry Lee, who made available
the scanning electron microscope at the facilities of the Research and Develop-
ment Center of the Epoxylite Corporation, South El Monte, California, and Mr.
Malcolm R. Kateley, who performed the technical services.

Supported, in part, by Grant 04-69, from funds provided by the General
Research Support Grant, United States Public Health Services.

C — collateral branch of dentinal tubule; D — circumpulpal dentin matrix; E
— enamel matrix; F — odontoblastic process (Tomes’ dentinal fibril); H — area
of hypermineralized peritubular dentin; K—von Korffs fibers; M — micro- -
tubiculi (arrow); O — odontoblast; P — pre-dentin; T — dentinal tubule.

Magnifications indicated are those at which the photomicrographs were taken.

LITERATURE CITED
BoybDE, A., AND A. D. G. STEWART, 1963. Scanning electron microscopy of the
surface of developing mammalian dental enamel. Nature 198: 1102-1103.

GaunT, W. A., J. W. OsBorn, AND A. R. TEN CaTE, 1967. Advances in dental
histology. John Wright and Sons, Bristol, 1-104.

Kerr, T., 1960. Development and structure of some actinopterygian and urodele
teeth. Proc. Zool. Soc. London 133: 401-424.

KvaM, T., 1958a. The teeth of Alligator mississippiensis Daud. I1. Development
of dentin. J. Dent. Res. 37: 532-539.

1958b. The teeth of Alligator mississippiensis Daud. III. Development of
enamel. J. Dent. Res. 37: 540-546.

LINDEN, L. A., 1968. Microscopic observations of fluid flow through enamel in
vitro. Odont. Revy. 19: 349-365.

Mites, A. E. W., 1967. Structural and chemical organization of teeth. Academic
Press, New York 1: 1-525; 2: 1-489.

MILLER, W. A., 1969. Tooth enamel of Latimeria chalumnae (Smith). Nature
221: 1244.

PooLe, D. F. G., AND M. V. Stack, 1965. The structure and physical properties of
enamel. Jn Tooth Enamel (M. V. Stack and R. W. Fearnhead, eds.). John
Wright and Sons, Bristol 1-219.

SMITH, M. M., anD A. E. W. MILEs, 1969. An autoradiographic investigation with
the light microscope of prolie-H3 incorporation during tooth development in
the crested newt (Triturus cristatus). Arch. Oral Biol. 14: 479-490.

Developing Teeth 111

SouLE, J. D., 1966. Origin of the enamel matrix in developing amphibian teeth.
Bull. So. Calif. Acad. Sci. 65: 193-201.

1969a. Origin of the enamel matrix in trigger-fish dentition. Anat. Rec.

163: 2680269 (abstract).

1969b. Amelogenesis in the trigger-fish Balistidae. Bull. So. Calif. Acad.

Sci. 68: 64-71.

Accepted for publication April 2, 1970.

Bull. So. Calif. Acad. Sci. 69(2): 112-114, 1970

RESEARCH NOTES

A NOTE ON THE HYDROID DIPURENA REESI VANNUCCI
AND A MEDUSAE OF THE GENUS CLADONEMA
COLLECTED TOGETHER NEAR LOS ANGELES

In the course of a study of feeding in bryozoans, a collection of epi-
faunal organisms was made in July 1965 from the pontoons in the small
boat marinas at Redondo Beach and Playa del Ray, Los Angeles
County, California. A day or two later three specimens of a small
medusae were noticed in an aquarium (Fig. 1). The medusae disap-
peared after a few days. Some weeks later a small hydroid was found
living in one of these aquaria. This hydroid lived for several months
and liberated a number of medusae over that period.

The hydroid (Fig. 2) was first placed in the genus Cladonema as the .
polyp appeared to be almost identical with the polyp of Cladonema
radiatum and the medusae which were collected in the field resembled
the medusae of that species. However the medusae (Fig. 3) of the
hydroid produced in the aquarium were different in structure having
four simple tentacles and a narrow manubrium.

Vannucci (1956) described a hydroid found in aquaria at Sao Paulo,
Brazil, which although having, as she pointed out, polyps like Cla-
donema radiatum, liberated medusae like the medusae liberated by the
species considered here. She named the species Dipurena reesi and
distinguished it in a key from three other species of Dipurena.

Brinckmann and Petersen (1960) recorded, the discovery of a
hydroid identified as Dipurena reesi from the Gulf of Naples. The
hydroid was collected in shallow water and the medusae were found
in the surface plankton as well as being liberated by the hydroid in
aquaria. They compared the polyps of Dipurena reesi and Cladonema
radiatum, and drew attention that the medusae belonged to two dif-
ferent families.

Both polyps have four capitate oral tentacles and a basal whorl of
four filiform tentacles. Brinckmann and Petersen found that the polyps
of Dipurena ressi could be distinguished from those of Cladonema
radiatum because they had buttonlike and not cone-shaped knobs on
the oral tentacles, these tentacles had each a row of about 18 endo-
dermal cells instead of 7-8. The nature of the nematocysts was dif-
ferent and the filiform tentacles lacked a small knob on the end and
arose from the mid-height of the column and not towards the base.

Vannucci (1956) published photographs of the polyp of Dipurena

12

A Hydroid and Medusae from near Los Angeles 113

I
{

i}

|
jf

Figure 1. Cladonema sp. medusae. Figure 2. Dipurena reesi Vannucci, polyp.
At the right an unusual polyp of this species with five capitate and three filiform
tentacles (not to same scale). Figure 3. Dipurena reesi Vannucci, medusae.

ressi. The knobs on the capitate tentacles are mostly button-like but
may be cone-shaped. In one polyp the endodermal cells in the capitate
tentacles are partly visible and appear to number about nine. The
filiform tentacles arise toward the base of the column and terminate
in a minute knob. The polyps then of Dipurena reesi Vannucci (1956)
differ from the polyps of D. reesi of Brinckmann and Petersen in these
features but cannot be distinguished from the polyps of Cladonema
radiatum of these authors. Likewise the polyps of the species con-
sidered here, cannot be distinguished from those of Dipurena reesi of
Vannucci in these features. However neither Vannucci nor the present
author examined the nematocysts.

In the present instance the medusae liberated in the aquarium did
not develope mature gonads and although there were copepods and
algal cells present, they did not feed extensively; rarely were small
Particles seen in the manubrium and canals. The polyps of the colony

114 Bulletin So. Calif. Academy of Sciences

were seen with small metazoans in their coelenterons, probably rhab-
docoels or copepods, and once two nematodes were observed on the
oral disc which were repeatedly touched by the oral tentacles but with
no effect.

This note extends the known range of the hydroid Dipurena ressi,
previously reported from Sao Paulo, Brazil, and possibly Naples, to
California, and draws attention to anomalies in the description of the
species given by Brinckmann and Petersen (1960). Whether there is
any significance in the occurrence of the Cladonema sp. medusae in the
collection with the hydroid, awaits further observations. The possession
of bifurcated tentacles makes these medusae resemble Cladonema
californica Hyman, 1947.

LITERATURE CITED

BRINCKMANN, A. AND K. W. PETERSEN, 1960. On some distinguishing characters
of Dipurena reesi Vannucci 1956 and Cladonema radiatum Dujardin 1843.-
Pubbl. Staz. Zool. Napoli, 31: 386-392.

Hyman, L. H. 1947. Two new hydromedusae from the California coast. Trans.
Amer. Microsc. Soc. 66: 262-268.

Vannuccl, M. 1956. Biological notes and description of a new species of Dipurena
(Hydrozoa, Corynidae). Proc. zool. Soc. Lond. 127: 479-487.

J. §S. Bullivant, New Zealand Oceanographic Institute, P.O. Box
8009, Wellington, N.Z.

Accepted for publication October 24, 1969.

Bull. So. Calif. Acad. Sci. 69(2): 115-117, 1970

THE STATUS OF THE
SOUTHERN YELLOW BAT IN CALIFORNIA

The Southern Yellow Bat, Lasiurus ega, ranges from southwestern
United States southward to northern Argentina. Lasiurus ega xanthi-
nus, which occurs in the southwestern United States, Baja California,
and southward to Costa Rica (Hall and Jones, 1961), is presently
known in California from only three specimens: a female taken on 3
November 1945, at Palm Springs, Riverside County (Constantine,
1946), a male taken on 2 August 1962, at Joshua Tree National
Monument, Riverside County (Loomis and Stephens, 1964), and a
male taken on 22 January 1969, at Pomona, Los Angeles County
(Stewart, 1969).

Annually in recent years the San Diego Society of Natural History
has received specimens from Borrego Springs, San Diego County,
California, through the efforts of Maurice H. Getty. Among these have
been six specimens of the Yellow Bat. The first five specimens were
females taken during June and July of 1967, 1968 and 1969. The sixth
specimen was a male taken in October 1969. The details are as follows.

-On_6 June 1967, an adult female was found near a Washington Fan
Palm (Washingtonia filifers) in Borrego Springs. No embryo or signs
of lactating were found (SDSNH no. 21392; skin and skull).

On 9 June 1968, another adult female was found dying at the
Anza-Borrego Desert State Park Headquarters at Borrego Springs
near some Western Sycamore (Platanus racemosa) and Fremont
Cottonwocd (Populus fremontii). This specimen (SDSNH no. 21445;
skin and partial skeleton) contained a 16 mm embryo in the left uterine
and a 14 mm embryo in the right horn. On 1 July 1968, another adult
female bat (SDSNH no. 21446; skin and skull) was found dead near a
Washington Fan Palm in Borrego Springs. This bat had no embryo
but it was lactating.

In 1969 three additional bats were found dead. A desiccated adult
female was found under a Washington Fan Palm on 9 June in Borrego
Springs (SDSNH no. 21559; skeleton), and an adult female containing
an 18 mm embryo in the left uterine horn and a 17 mm embryo in the
right horn was found under a Washington Fan Palm also in Borrego
Springs (SDSNH no. 21558; skeleton). On 7 October, an adult male
was found dead at the Park Headquarters near some Western Sycamore
and Fremont Cottonwood (SDSNH no. 22018; skin and skull).

In the closely related and migratory Hoary Bat (Lasiurus cinereus)
spatial segregation of the sexes occurs during the spring and early
summer, with the females moving northward and the males scattering

115

116 Bulletin So. Calif. Academy of Sciences

far from areas where the females might be expected to rear young
(Dalquest, 1943). Vaughan and Krutzsch (1954) suggest that in the
Hoary Bat there may also be an altitudinal segregation in late spring
with “the males occurring in the foothills and mountains and the
females in the lowlands and coastal valleys.”’ Findley and Jones (1964)
suggest that female Hoary Bats precede the males in spring migration
and that the females are already pregnant and the males play no part
in the spring reproductive activities.

Little is known about the biology of Lasiurus ega, but the limited
data suggest that its breeding biology may be similar to that of Lasiurus
cinereus. The data are not sufficient to establish altitudinal segregation
of the sexes; however, seasonal segregation may occur in California
and Arizona. In these states the sex ration is approximately 1:1
throughout the year, except from April through June when only females
occur (Cockrum, 1961; Constantine, 1966; this paper). This suggests a
sexual segregation during the parturition period and possibly in spring
migration, with females arriving in spring followed by males in late
summer. However, the few specimens collected in New Mexico (Mum-
ford and Zimmerman, 1963) do not follow this pattern.

LITERATURE CITED
CockRuM, E. L. 1961. Southern yellow bat from Arizona. J. Mammalogy, 42: 97.

CONSTANTINE, D. G. 1946. A record of Dasypterus ega xanthinus from Palm
Springs, California. Bull. So. Calif. Acad. Sci. 45: 107.

1966. New bat locality records from Oaxaca, Arizona and Colorado.
J. Mammalogy, 47: 125-126.

DaALQuEsT, W. W. 1943. Seasonal distribution of the hoary bat along the Pacific
coast. Murrelet, 24: 20-24.

FINDLEY, J. S. AND C. J. JoNEs, 1964. Seasonal distribution of the hoary bat. J.
Mammalogy, 45: 461-470.

HALL, E. R. AND J. K. JONES, Jr., 1961. North American Yeollow Bats, “Dasyp-
terus,” and a list of the named kinds of the genus Lasiurus Gray. Univ.
Kansas Publ., Mus. Nat. Hist., 14: 73-98.

Loomis, R. B. 1964. The southern yellow bat in Joshua Tree National Monument,
California. Bull. So. Calif. Acad. Sci., 63: 26.

MuMForbD, R. E. AND D. A. ZIMMERMAN, 1963. The southern yellow bat in New
Mexico. J. Mammalogy, 44: 417-418.

STEWaRT, G. R. 1969. A western yellow bat in Los Angeles County, California.
Bull. So. Calif. Acad. Sci., 68: 194-195.

Southern Yellow Bat 117

VAUGHAN, T. A. AND P. H. Krurzscu, 1954. Seasonal distribution of the hoary
bat in southern California. J. Mammalogy, 35: 431-432.

Suzanne I. Bond, Department of Birds and Mammals, San Diego
Natural History Museum, Balboa Park, P. O. Box 1390, San Diego,
California, 92112

Accepted for publication October 29, 1969

Bull. So. Calif. Acad. Sci. 69(2): 118-120, 1970

TANTILLA BREVICAUDA: AN ADDITION TO THE SNAKE
FAUNA OF GUATEMALA,
WITH COMMENTS ON ITS RELATIONSHIPS.

Mertens (1952b) described Tantilla brevicauda from El Grito, Finca
Los Angeles, Cumbre de Jayaque, 1510 m, Departamento de La
Libertad, El Salvador. Additional specimens were cited by Mertens
(1952b) from the following localities: Finca San José, Cumbre de
Santa Tecla, 1200 m, Departamento de La Libertad, and Finca El
Carmen, east slope of Volcan San Vicente, 1319 m, Departamento de
San Vicente. Uzzell and Starrett (1958) reported an additional speci-
men from near the Instituto Tropical de Investigaciones Cientificas of
the Universidad de El Salvador, about 600 m above sea level near the
city of San Salvador in the Departamento de San Salvador. No addi-
tional specimens have been reported and Tantilla brevicauda has been
considered endemic to El Salvador. .

While examining material for a systematic study of the members of
the Tantilla taeniata group, I encountered two specimens from Guate-
mala in the collections of the Carnegie Museum identified as Tantilla
Jani, one of the members of the taeniata group (this group also includes
T. taeniata, T. flavilineata, T. striata, T. reticulata, and an undescribed
species, fide Wilson and Meyer, in press). These two specimens did not
fit the description of Tantilla jani, however, and subsequent research
showed them to be representatives of T. brevicauda. These two speci-
mens (CM 41711-12), representing the first record of T. brevicauda
in Guatemala, were collected at Quisaché, Municipio de Acatenango,
Departamento de Chimaltenango. The specimens came from an
elevation of about 1750, undoubtedly on Volcan Acatenango.

Both Carnegie specimens agree well with the description given by
Mertens (1952a), having a brown dorsal groundcolor with a light
brown vertebral line occupying the middorsal row and a tan lateral
line occupying the upper half of row 3 and all of row 4. Head coloration
can be determined only on CM 41711, as the head of CM 41712 is
damaged. A complete light collar is present on the nape. The posterior
ventral and subcaudal surface is pink.

Scutellation of the two specimens falls within the ranges given by
Mertens (1952a) for T. brevicauda. Data for CM 41711, a female, are
as follows: ventrals 148; subcaudals 21; supralabials 7-7, 3rd and 4th
entering orbit; infralabials 6-6; preocular 1-1; postoculars 2-2; tem-
porals 1 + 1; nasal and preocular not in contact; first pair of infralabials
in contact medially; total length, 165 mm; tail length, 17 mm; relative
tail length 0.103.

118

Snake from Guatemala 119

Data for CM 41712, a male with a damaged head, are as follows:
ventrals 142; subcaudals 24; supralabials damaged; infralabials 6-6;
preocular 1-?; postoculars 2-?; temporals 1+ 1; nasal and preocular
in contact on left side, right side damaged; first pair of infralabials in
contact medially; total length, 163 mm; tail length, 18 mm; relative
tail length 0.110.

All localities for this species are within the northern portion of the
Volcanic Axis of Central America from elevations of 600 to 1750
meters.

Merten (1952a) believed 7. brevicauda to be closely related to
Tantilla phrenitica (= T. schistosa phrenitica) and T. schistosa (= T. s.
schistosa), but differing from them in having a higher ventral count,
a larger, more elongate second temporal, a lower number of subcaudals,
and a pigmented chin.

It is my opinion, however, that Tantilla brevicauda shares important
features with members of the taeniata group as well, specifically with
T. jani. As in the members of the taeniata group, and unlike any other
member of the genus, T. brevicauda has a light middorsal stripe,
resembling most closely that of T. jani, and a light lateral stripe. The
light middorsal stripe is variable in intensity in T. brevicauda, however,
and may be completely absent (Mertens, 1952a). There are no light
lines on the dorsum in the members of the schistosa group (containing
a single species, T. schistosa, as here conceived). T. brevicauda re-
sembles members of both the taeniata and schistosa groups in having a
light collar extending slightly onto the parietals. T. brevicauda differs
from the members of both groups, however, in having a lower number
of subcaudals (21 to 26 in brevicauda, 34 to 67 in the taeniata group,
24 to 44 in the schistosa group).

In summary, Tantilla brevicauda shows resemblances to both the
taeniata group and the schistosa group, as well as exhibiting distinctive
features. It seems most reasonable to regard T. brevicauda as a short-
tailed species related to both the taeniata and schistosa groups and
inhabiting the moderate elevations in the northern portion of the
Central American volcanic axis, an area largely uninhabited by mem-
bers of the taeniata and schistosa groups.

LITERATURE CITED

MERTENS, R. 1952a. Die Amphibien und Reptilien von El Salvador. Abhand-
lungen der Senckenbergischen Naturforschenden Gesellschaft, Frankfurt
am Main.

1952b. Weitere neue Reptilien aus El Salvador. Zoologische Anzeiger,
Leipzig, 149: 133-138.

120 Bulletin So. Calif. Academy of Sciences

UzzeELL, T. M., JR., AND P. STARRETT. 1958. Snakes from El Salvador. Copeia,
1958: 339-342.

Larry David Wilson, Department of Biology, University of South-
western Louisiana, Lafayette, Louisiana 70501.

Accepted for publication November 26, 1969.

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3-4

Vol. 69

Southern California
Academy of Sciences

LOS ANGELES, CALIFORNIA

OcTOBER-DECEMBER Nos. 3 AND 4

(otiaiuchimurzins

FEB iG (971

| NEW YORK
y BOTANICAL GARDE

CONTENTS

A Late Pliocene macrofossil fauna of Newport Beach, Orange County, Califor-
nia. William J. Zinsmeister

A survey of metazoan parasites infecting the California (Zalophus California-
nus) and Steller (Eumetopias Jubatus) sea lion. Murray D. Dailey and
Barry L. Hill

Four species of Microtrombicula (Acarina: Trombiculidae) from Mexico and
Nicaragua. James P. Webb, Jr. and Richard B. Loomis

Ancinus Seticomvus, n. sp. (Isopoda), from Santa Barbara, California.
Thomas Trask

Occurrence of a holotrichous ciliate in the intestine of the polychaete Hermo-
dice Carunculata of Puerto Rico. Ira Jones and Irma Rivera Rodrigues

The role of elytra in the movement of water over the surface of Halosydna
Brevisetosa (Polychaeta: Polynoidae). Jamson Lwebuga-Mukasa

Some helminths of the mudsucker fish, Gillichthys Mirabilis Copper. W. E.
Martin and Syed Multani

Establishment of non-breeding population of Mercierella Enigmatica (Anne-
lida: Polychaeta) upstream from a breeding population. Dale Straughan

A second species of Gerstaeckeria (Coleoptera: Curculionidae: Cryptorhyn-
chinae) from mainland South America. Elbert L. Sleeper

Research Notes:

Notes on the association between Hyperoche Medusarum A. Agassiz
(Amphipoda, Hyperiidea) and the ctenophore, Pleurobrachia Bachei
(Muller). Gary J. Brusca

An unusual pinna anomaly in Neotoma Lepida. Ross E. Dingman

A preliminary report on a Miocene flora from the Barstow formation,
Barstow, California. Raymond M. Alf

JANUARY 29, 1971

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Vol. 69 OCTOBER-DECEMBER No. 3 AND 4

Bull. So. Calif. Acad. Sci. 69(3-4): 121-125, 1970

A LATE PLIOCENE MACROFOSSIL FAUNA :
OF NEWPORT BEACH, ORANGE COUNTY, CALIFORNIA

WILLIAM J. ZINSMEISTER
Department of Geology
University of California

Riverside, California 92502

ABSTRACT: A new exposure of fossliferous sandstones of Upper
Pliocene age was uncovered during construction work in the
spring of 1968. A total 101 species of mollusks and fish
remains were recovered. The fauna indicates a moderately
deep-water deposit. The presence of a few shallow-water
forms suggests a mixing a faunas has occurred.

INTRODUCTION

This paper records the marine fauna from an Upper Pliocene sandstone
at the southern edge of the Newport Lagoon, Orange County, Cali-
fornia. The presence of similar deposits in the Newport Beach area
has been noted previously by Vedder (1960). This locality affords an
opportunity to evaluate the ecologic setting of the Pliocene in this part
of the Los Angeles Basin. In this respect, this deposit is unique. Inter-
pretations are based on 101 identified species. The fauna consists of
85 invertebrates and 16 vertebrates. Faunal comparisons were made
with the Lomita Marl of the Palos Verdes Hills and a number of faunal
similarities were observed. Material used in this study is deposited at
the University of California (UCRIP 4915) and the Los Angeles
County Museum (LACMIP 471).

The locality is situated at the top of a cliff on the south side of the
Newport Lagoon. A highly fossiliferous sandstone was uncovered
during construction work in the spring of 1968. This locality has since
been destroyed by the construction of a housing development. While
the site was exposed, John Fitch, California Department of Fish and
Game, and the author were able to remove approximately 300 pounds
of material. A similar amount was collected by the Los Angeles
County Museum staff.

Al

1 Bulletin So. Calif. Academy of Sciences

PREVIOUS WORK

The first mention of rocks of Pliocene age in the Newport Lagoon area
was in 1954 by Natland and Rothwell. They described these rocks and
the remainder of the Tertiary sequence, but did not name the Pliocene
unit. In 1957, Vedder et al. mapped the geology of the area under
investigation, and referred to the unit as an unnamed limy sandstone
of Pliocene or Pleistocene age. Later Vedder (1960) briefly described
the Pliocene marine fauna from the southern portion of Orange County.

STRATIGRAPHY

The stratigraphic sequence in the Newport Lagoon area consists of
Middle and Upper Miocene referred to as the Monterey Formation,
the Lower Pliocene Capistrano Formation, the unnamed limy sand-
stone of Pliocene age, and Pleistocene terrace deposits which form a
thin veneer over the entire area. The sediments and faunas of the
laminated diatomaceous shales of the Monterey indicate deep water
whereas those of the succeeding units represent progressively shallower
water facies culminating in the Upper Pleistocene Palos Verdes Sand.
The sequence appears to be conformable except for the Upper Pleisto-
cene terrace deposits which overlies the older formations with a
marked unconformity.

SIGNIFICANCE OF THE UPPER PLIOCENE NEWPORT LAGOON FAUNA

The collected fauna consists of 101 species of mollusks and fish. The
85 species of mollusks constitute the major part of the fauna with 50
species of gastropods and 35 species of bivalves. Of the remaining
taxa 17 are fish (represented by teeth and otoliths), one species of
brachiopod and unidentified fragments of echinoderms and ectoprocts.
The fauna is enumerated in table 1.

The general composition of the molluscan fauna suggests a moderate
water depth between 20 and 100 fathoms as indicated by the following
fossils which have living representives with a known moderately deep
water habitat.

Bivalvia

Eucrassatella flunctuata Carpenter, Glycymeris profunda Dall,
Nuculana spp., Thyasira gouldii Philippi.

Gastropoda:

Acmaea funiculata Carpenter, Boreotrophon stuarti Dall, Cida-
rina cf. C. cidaris Adams, Fusitriton orogonensis Redifield,
Neptunea tabulata Baird

Pliocene Macrofossil Fauna 123

This inference is supported by the presence of outer nertic fishes
which are common in the deposit. The myctophid (Stenobranchius
leucopsarus Eigenmann and Eigenmann) and the 100 fathom cod
(Physiculus rastrelliger Gilbert) are rarely found in water shallower
than 600 feet. Their presence in combination with deeper water
mollusks in a good confirmation of the water depth. The use of asso-
ciated fish faunas can be very useful in making paleoecologic inter-
pretations. Otoliths are generally present in shelly deposits such as the
Newport Lagoon locality. Until recently few investigators have realized
the value of fish fauna. This can be attributed to their generally small
size and the lack until recently of literature dealing specifically with
otoliths. Similar associated mollusks and fish faunas are found in the
Timms Point Silt and the Lomita Marl of the Palos Verdes Hills.

An interesting feature of this deposit is the occurrence of shallow-
water mollusks, several of which are commonly found intertidally.

Pelecypoda:

Hinnites giganteus Gray, Pseudochama exogyra Dall, Saxidomus
cf. S. nuttalli Conrad

Gastropoda:

Acmaea spp., Astrea undosa Wood, Conus californicus Hinds,
Cypraea spadicea Swainson, Mitra idea Melvill, Turritella co-
operi Carpenter

The shallow-water perch (Cymatogaster aggregata Gibbon) which
commonly occurs in the surf zone is also present. The presence of a
shallow-water element within the fauna does not detract from the
conclusion that the deposit represents a moderately deep water facies.
Their presence merely suggests that a mixing of faunas has occurred.
All of the shallower-water forms show a greater degree of erosion and
breakage than the deeper water forms substaniates the hypothesis of
reworking. No sedimentary structure could be seen in the limited
extend of the outcrops to suggest how this mixing was accomplished.

AGE AND CORRELATION

The Newport Lagoon fauna is quite similar tin composition to the
Lomita Marl fauna of the Palos Verdes Hills. Geologists and paleon-
tologists have agreed until recently that the Lomita Marl represented
the earliest Pleistocene. Recent work on the mollusk and fish fauna
suggests an age of Latest Pliocene for the Lomita Marl (Berry and
Fitch, personal communication and Kanakoff and McLean, 1966).
The close similarity of the two faunas in addition to the presence of

124 Bulletin So. Calif. Academy of Sciences

TABLE |
List of Macrofossils from the Late Pliocene of
Newport Beach, California.

Bivalvia:

Arca sisquocensis Reinhart

Cardita ventricosa Gould

Chione securis (Shumard)

Crenella decussata (Montagu)

Glycymeris profunda Dall

G. septentrionalis Middendorf

Hiatella arctica Linnaeus

Hinnites giganteus Gray

Lucina annulata Reeve

L. tenisculpta Carpenter

Miodontiscus prodlongatus
Carpenter

Midiolus cf. M. modiolus Linnaeus

Mytilus coalingensis Arnold

Nuculana acuta Conrad

N. hamata Carpenter

N. minuta v. praecursor Arnold

N. taphria Dall

Ostrea sp.

Pecten bellus Conrad

P. incongruus Dall

P. islandicus Muller

Pecten cf. P. healyi Arnold

P. randophi v. tillamookensis
Arnold

Petricola carditoides Conrad

Pododesmus maroschisma Deshayes

Pseudochama exogyra Conrad

Saxidomus cf. S. nuttalli Conrad

Transenella tantilla Gould

Thyasira disjuncta Gabb

T. gouldi Philippi

Gastropoda:

Acmaea funiculata Carpenter
A. mitra Eschscholtz

Acmaea spp.

Admete cymata Berry
Amphissa reticulata Dall
Astrea gibberosa Dillwyn

A. undosa Wood

Bittium rugatum Carpenter
B. ornatissima Bartsch
Boreotrophon macouni Dall
Callistoma cf. C. grantiaum Berry
Calyptraea fastigata Gould

C. trochiformis Gmelin
Cidarina cf. C. cidaria Adams
Clathurella conradana Gabb
Conus californicus Hinds
Crepidula onyx Sowerby

C. princeps Conrad

Cypraea spadicea Swainson

Exilioidea retircostris Carpenter

Fusinus spp.

Fusitriton oregonensis Redfield

Homalopoma grippi Dali

Lacuna unifasciata Carpenter

Mitra idae Melvill

Mitrella carinata Hinds

M. gouldi Carpenter

Neptunea tabulata Baird

Oenopta? O. fidicula Gould

Opalia cliacei Strong

Orilla empyrosia Dall

Petaloconchus complicatus Dall

Polinices draconis Dall

P. russa Gould

Pteropurpura cf. P. carpenteri Dall

Spirotropis perversa Gabb

S. renaudi Arnold

Taranis strongi Arnold

Tegula montereyi Fischer

Tegula spp.

Trifora stearni Bartsch

Trophon lasius Dall

T. stuarti Smith

T. trangulatus Carpenter

Trophenopsis multicostatus
Eschscholtz

Turritella cooperi Carpenter

Brachiopoda:

Laqueus cf. L. californianus Koch

Scaphopoda:

Dentalium neohexagonum Sharp
and Pilsbry

D. semipolitum Broderip and
Sowerby

Vertebrata:

Carcharhinus spp.

Carcharodon carcharias Gilbert

Cymatogaster aggregata Gibbons

Glyptocephalus zachirus Lockington

Isurus cf. I. glaucus Ayres
Malacocottius zonurus Gilbert and
Thompson
Merluccius productus Ayres
Microgadus proximus Giard
Lyspsetta exilis Jordan and Gilbert
Lycodopsis pacifica Collett
Otophidium taylori Ayres
Physiculus rastrelliger Gilbert
Radulinus asprellus Gilbert
Seriphus politus Ayres
Stenobranchius leucopsarus
(Eigenmann and Eigenmann)
Sebastodes spp.

Pliocene Macrofossil Fauna 125

several species which occur only in the late Pliocene (Mytilus coalin-
gensis, Opalia varicostata, and Patinopecten healyi) indicates a Late
Pliocene age for the Newport Lagoon fauna.

ACKNOWLEDGEMENT

The author acknowledges the help of L. G. Hertlein, California Academy of
Sciences, in reviewing the faunal list, J. G. Vedder, U.S. Geological Survey, for
suggestions and advice, E. C. Wilson, Los Angeles County Museum, for access
to the museum’s collections, J. E. Fitch, California Department of Fish and
Game, for identifying the fish material, and M. A. Murphy, University of Cali-
fornia at Riverside, for reviewing the manuscript. Lastly, I would like to thank
my wife Virginia for helping me collect the material used in this paper.

LITERATURE CITED

AppicoTT, W. O., 1966. Pleistocene Marine Paleoecology and Zoogeography in
Central California. U.S. Geol. Sury., Prof. Paper 523-C, 1-19.

CLARK, ALEX, 1931. The Cool-Water Timms Point Pleistocene Horizon of San
Pedro, California. San Diego Soc. Natl. Hist., 7: 1-44.

Fitcu, J. E., 1968. Otoliths and Other Fish from the Timms Point Silt (Early
Pleistocene) at San Pedro, California. Los Angeles County Museum, Contr.
Sci., 146: 1-29.

GRANT, U.S., IV, AND H. R. GALE, 1931. Pliocene and Pleistocene Mollusca of
California. San Diego Soc. Natl. Hist., Mem., 1: 1-1036.

HERTLEIN, L. G. AND U. S. GRanT, IV, 1960. The Geology and Paleontology of
the Marine Pliocene of San Diego, California. San Diego Soc. Natl. Hist.,
Mem. 2: 73-135.

KANAKOFFE G. P. AND W. K. EMERSON, 1959. Late Pleistocene Invertebrates of the
Newport Bay Area, California. Los Angeles County Museum, Contr. Sci.,
31: 5-45.

KANAKOFF, G. P. AND J. H. MCLEAN, 1966. Recognition of the Cancellariid Genus
Neadmete Habe, 1961, in the West American Fauna, with Description of a
New Species from the Lomita Marl of Los Angeles, County, California. Los
Angeles County Museum, Contr. Sci., 166: 1-6.

VEDDER, J. W., 1960. Previously Unreported Pliocene Mollusca from the
Southeastern Los Angeles Basin. U.S. Geol. Surv., Prof. Paper, 400-B (art.
151): 145-150.

VEDDER, J. W., R. F. YERKES, AND J. E. SCHOELLHAMER, 1957. Geologic Map of
the San Joaquin Hills — San Juan Capistrano Area, Orange County, Cali-
fornia. U.S. Geol. Surv., Oil and Gas Investiagations Map OM 193.

Accepted for publication January 2, 1970.

Bull. So. Calif. Acad. Sci. 69 (3-4): 126-132, 1970

A SURVEY OF METAZOAN PARASITES INFECTING THE
CALIFORNIA (ZALOPHUS CALIFORIANUS) AND
STELLER (EUMETOPIAS JUBATUS) SEA LION*

Murray D. DAILEY AND BARRY L. HILL
Department of Biology
California State College
Long Beach

ABSTRACT: Twenty three sea lions (14 Zalophus californianus,
9Eumetopias jubatus) from the coast of southern and central
California were examined for metazoan parasites. Z. cali-
fornianus was found infected with eight species of helminths
(Parafilaroides decorus, Contracaecum osculatum, Uncinaria
sp., Dipetalonema odendhali, Pricetrema zalophi, Stictodora
ubelakeri, Diphyllobothrium glaciale and Corynosoma ob-
tuscens), two species of acarines (Orthohalarachne diminuata
and Orthohalarachne attenuata), and one species of anopluran
(Antarctophthirius microchir). E. jubatus contained five
species of helminths (Parafilaroides sp., Contracaecum oscula-
tum, Pricetrema zalophi, Diphyllobothrium glaciale, Cory-
nosoma strumosum), two species of acari(Orthohalorachne
diminuata, O. attenuata) and one species of anopluran
(Antarctophthirius microchir).

INTRODUCTION

During the investigation on the morphology and life history of the
parasite causing lungworm disease in sea lions, it was necessary to
isolate and identify the causative agent or agents involved. This was
accomplished by a series of necropsies performed over a seven-month
period (March 22, 1968 to September 5, 1968) and included 23
animals (14 Zalophus californianus, Lesson, 1828, 9 Eumetopias
jubatus, Schreber, 1776) collected from southern to central California
(Alamitos Bay to Ano Nuevo Island). In as much as nearly all reports
of parasites from Eumetopias have been based on specimens collected
from Aleutian Islands, Alaska, or from museums, aquarias, or Zoos
and similarly, nearly all records of parasites from Zalophus have been
from captive animals, it is the purpose of this study to report all meta-
zoan parasites recovered during these necropsies.

*Supported in part by the Naval Undersea Research and Development Center,
Point Mugu, Marine Bioscience Facility under Contract No. N68530-68-C-0833.

126

Parasites of Sea Lions 127

MATERIALS AND METHODS

The lungs, bronchi, stomach, intestine, liver, heart, body cavity, tissues
and skin were examined for metazoan parasites. All parasites were
prepared and mounted on slides for identification. Nematodes were
killed, fixed and cleared in glycerin-alcohol, then mounted in glycerin
jelly. Cestodes, trematodes and acanthocephalans were fixed in AFA,
stained in Semichon’s carmine, celestine blue B or Van Cleave’s
combination hematoxylin (Van Cleave, 1953), dehydrated in ethanol,
cleared in xylene, and mounted in Piccolyte. Arthropods were fixed in
70 percent ethanol and mounted in PVA-LP. Mounted specimens
were studied under both phase-contrast and ordinary light microscopes.

RESULTS AND DISCUSSION

The results of parasitological examinations carried out on 23 sea lions
over a seven-month period are given in Tables I and II.

Nematoda: Parafilaroides decorus was first described by Dougherty
and Herman (1947) from the lungs of a captive California sea lion at
the San Diego Zoo. Three other species in this genus (P. nanus, P.
prolificus, P. sp.) have been reported from Steller’s sea lion. During
this study nine Steller’s sea lion were examined and Parafilaroides sp.
(Dougherty and Herman, 1947) was the only species found. No mixed
infections occurred in those animals examined. Host specificity seems
to exist, but further experimental proof through cross infections
is needed.

Contracaecum osculatum (Rudolphi, 1802) Baylis, 1920, has been
reported from the stomachs of Steller’s sea lion, harbor seal (Phoca
vitulina richardi), California sea lion, and elephant seal (Mirounga
angustirostris.) During this investigation it was the only ascarid-type
nematode found.

All adult hookworms (Uncinaria sp.) recovered during this study
were found in unweaned pups. Since all unweaned pups examined (3)
were infected, it is highly probable that this parasite infects nearly all
the pups at the San Nicolas Island rookery. Two species of Uncinaria
have been reported from pinnipeds. Uncinaria lucasi Stiles, 1901 was
described from the intestine of a young northern fur seal (Callorhinus
ursinus) and Uncinaria hamiltoni Baylis, 1933 was first reported from
the southern fur seal (Otaria byronia). Margolis (1954) lists this
hookworm from “(?) Eumetopias jubatus — Steller sea lion.” Baylis
(1933), while trying to redescribe U. lucasi received material from a
sea lion taken at Palo Alto, California. He was advised that the most

128 Bulletin So. Calif. Academy of Sciences

TABLE I
Parasites found in 14 Zalophus californianus

Organ Number Per cent
Parasites infected infected infected
Nematoda
Parafilaroides decorus lung 10 71.4
Contracaecum osculatum stomach and
small intestine 9 64.2
Unicinaria sp. small intestine 3 21.4
Dipetalonema odendhali tissue fascia 2 14.2
Trematoda
Pricetrema zalophi small intestine 4 28.5
Stictodora ubelakeri small intestine 1 7.1
Cestoda
Diphyllobothrium glaciale small intestine 4 28.5
Acanthacephala
Corynosoma obtuscens small intestine 1 7.1
Acarina
Orthohalarachne diminuata trachea and
bronchi 13 92.8
Orthohalarachne attenuata naso-pharynx 4 28.5
Anoplura
Antarctophthirus microchir skin 4 28.5

common sea lion in that area was the Steller’s, so he assumed this was
the host. However, the worms recovered from this animal did not fit
the measurements given for either U. lucasi or U. hamiltoni, but fall
somewhere between. Because he received only one male and two
females specimens he did not feel he could describe it as a new species.
This intermediate form was the hookworm recovered from the three
pups examined during this study.

Dipetalonema odendhali Perry, 1967 was found in the intermuscular
fascia throughout the cervical region in two animals. This worm was
described from four California sea lions from three different areas
(Santa Cruz Island, San Diego Zoo, and Ano Nuevo Island).

Trematoda: Pricetrema zalophi (Price 1932) Ciurea, 1933, has
been found in the California sea lion and the sea otter (Enhydra lutris)
(Margolis, 1954). During this study it was the most common trematode
found, parasitising 28.5 per cent of the animals necropsied. This fluke
has been reported from the National Zoological Park, Washington,
D.C. (Price, 1932), Aleutian Islands (Rausch and Locker, 1951), and
Alaska (Rausch, 1953).

Parasites of Sea Lions 129

TABLE II
Parasites found in 9 Eumetopias jubatus

Organ Number Per cent
Parasites infected infected infected
Nematoda
Parafilaroides sp. lungs 4 44.4
Contracaecum osculatum stomach 3 30.0
Trematoda
Pricetrema zalophi intestine 2 DDD
Cestoda
Diphyllobothrium glaciale intestine 1 11.1
Acanthocephala
Corynosoma stromosum intestine 1 11.1
Acarina
Orthohalarachne diminuata trachea and
bronchi 6 66.6
Orthohalarachne attenuata naso-pharynx 5 5)5)05)
Anoplura
Antarctophthirius microchir skin 5 S55)

Many specimens of another trematode were recovered from a dead
California sea lion that had washed ashore in Alamitos Bay, Los
Angeles County, California. These flukes were described as Stictodora
ubelakeri Dailey, 1969. It was the first report of a member of the genus
Stictodora from a marine mammal (Dailey, 1969). The members of
this genus are primarily parasites of marine birds, but have occasionally
been reported from dogs and cats.

Cestoda: Diphyllobothrium glaciale (Cholodkovsky, 1915) Mar-
kowski, 1952 was originally described from the northern fur seal
(Callorhinus ursinus) collected in the Pribilof Islands, Alaska. Large
numbers of this cestode were found in four California sea lions as well
as the one adult Steller’s sea lion examined.

Acanthocephala: Specimens of Corynosoma obtuscens Lincicome,
1943, and C. strumosum (Rudolphi, 1802) were recovered from a
single California and Steller sea lion respectively. These parasites have
both been reported previously from captive sea lions at the San Diego
Zoological Gardens, San Diego, California (Lincicome, 1943). Van
Cleave (1953) listed nine species of this genus existing in North
America, all of which are found in marine mammals.

Acarina: Orthohalarchne diminuata, the lung mite, was the most
prevalent parasite found during this study, occurring in large numbers

130 Bulletin So. Calif. Academy of Sciences

in all but four of the animals examined. All specimens were located
in the lumen of the bronchi and trachea. None were found in the lung
parenchyma or stroma. This parasite was described by Doetschman
(1941) from a California sea lion necropsied at the San Diego Zoo.

Orthohalarachne attenuata (Banks, 1916) Newell, 1947 can be
recovered only by splitting the skull and exposing the nasal-pharynx
of the animal. This parasite was originally reported from Steller’s sea
lion and the northern fur seal.

Anoplura: Antarctophthirius microchir (Trouessart and Neumann,
1888) Enderlein 1906 was recovered in large numbers from nine of
the animals examined. This ectoparasite is most abundant on the
muzzle and anal regions of young pups. This louse has been reported
from the California and Steller’s sea lion in California (Ferris, 1916,
1934, 1951) and the Pribilof Islands, Alaska (Jellison, 1952).

Continued examination and experimental work is needed, not only
in these two species but in pinnipeds as a group. We have very little
information on the total parasite problem in these animals.

SUMMARY

Fourteen Zalophus californianus and nine Eumetopias jubatus were
examined for metazoan parasites. Z. californianus was found to harbor
eight species of helminths (Parafilaroides decorus, Contracaecum
osculatum, Uncinaria sp., Dipetalonema odendhali, Pricetrema zalophi,
Stictodora ubelakeri, Diphyllobothrium glaciale and Corynosoma
obtuscens), two species of acarines (Orthohalarachne diminuata and
Orthohalarachne attenuata), and one species of anopluran (Antarc-
tophthirius microchir). Eumatopias jubatus contained five species of
helminths (Parafilaroides sp., Contracaecum osculatum, Pricetrema
zalophi, Diphyllobothrium glaciale, Corynosoma strumosum), two
species of acari (Orthohalorachne diminuata, O. attenuata) and one
species of anopluran (Antarctophthirius microchir). The most abun-
dant parasite was the lung mite, Orthohalarachne diminuata (92.8% in
Z. californianus, 66.6% in E. jubatus), followed by the lungworm
Parafilaroides decorus. P. decorus was found in all the adult (over 1 yr.)
Z. californianus examined (10), but was absent in the pups (4). These
pups could have been infected but at such a low level that adult or larval
worms could not be found without special techniques.

The stomach worm (Contracaecum osculatum) was recovered from
nine (64.2% ) of the adult California and three (30% ) Steller sea lions
examined. In two cases massive infections were found. In these cases,
large ulcerations in the stomach contained myriads of these nematodes.

Parasites of Sea Lions 131

The hookworm, Uncinaria sp. was found in 21.4% (all Z. cali-
fornianus pups); Dipetalonema odendhali in 14.2% (all Z. califor-
nianus); Pricetrema zalophi in four Z. californianus (28.5% ) and two
E. jubatus (22.2% ); Diphyllohothrium glaciale in four Z. californianus
(28.5%) and one E. jubatus (11.1%). The trematode, Stictodera ube-
lakeri, and the acanthocephalans, (Carynosoma obtuscens and C.
strumosum, were each found in a single animal, the first two from Z.
californianus and the latter from E. jubatus.

The skin louse, Antarctophirius microchir, was recovered from four
Z. californianus (28.5%) and five E. jubatus (55.5% ) while Ortho-
halarachne attenuata occurred in four Z. californianus (28.5%) and
five EF. jubatus (55.5%).

LITERATURE CITED

Bay Lis, H. A. 1933. A new species of nematode genus Uncinaria from a sea lion
with some observations on related species. Parasit., 25: 308-316.

DalLey, M. D. 1969. Stictodora ubelakeri a new species of heterophyid trematode
from the California sea lion (Zalophus californianus). Bull. So. Calif. Acad.
Sci. 68: 82-85.

DOoETSCHMAN, W. H. 1941. A new species of endoparasitic mite of the family
Halarachnidae (Acarina). Trans. Amer. Micro. Soc. 63: 68-72.

DOUGHERTY, E. C. AND C. M. HERMAN. 1947. New Species of the genus Para-
filaroides Dougherty, 1946 (Nematoda, Metastrongylidae), from sea lions,
with a list of the lungworms of the Pinnipedia. Proc. Helminth. Soc. Wash.,
14: 77-87.

Ferris, G. F. 1916. Anoplura from sea lions of the Pacific Ocean. Ent. News,
27: 366-370.

1934. Contributions toward a monograph of the sucking lice. Part 7.
Stanford Univ. Pub., Univ. Ser., Biol. Sci., 2: 471-526.
1951. The sucking lice. Mem. Pac. Coast Ent. Soc., 1: 1-320.

JELLISON, W. J. 1952. Anoplura from mammals of the Pribilof Islands. J. Parasit.,
38: 274-275.

Lincicome, D. R. 1943. Acanthocephala of the genus Corynosoma from the
California sea lion. J. Parasit., 29: 102-106.

Marco is, L. 1954. List of parasites recorded from sea mammals caught off the
west coast of North America. J. Fish. Res. Bd. Canada, 11(3): 267-283.

MARKOwsSKI, S. 1952. The cestodes of seals from the Antarctic. Bull. Brit. Mus.
(Nat. Hist.), Zool., 1: 125-150.

NEWELL, L. M. 1947. Studies on the morphology and systematics of the family
Halarachnidae Oudemans, 1916 (Acari, Parasitoidea). Bull. Bingham
Oceanogr. Coll., 10: 235-266.

132 Bulletin So. Calif. Academy of Sciences

Price, E. W. 1932. The trematode parasites of marine mammals. Proc. U.S. Nat.
Mus. 81: 1-68.

Rauscu, R. 1953. Studies on the helminth fauna of Alaska. XIII. Disease in the
sea otter, with special reference to helminth parasites. Ecology, 34: 584-
604.

Rauscu, R., AND B. Locker. 1951. Studies on the helminth fauna of Alaska. II. On
some helminths parasitic in the sea otter, Enhydra lutris (L.). Proc. Helm.
Soc. Wash., 18: 77-81.

STILES, C. W. 1901. Uncinariosis (Anchylostomiasis) in man and animals in the
United States. Texas Med. News, 10: 523-532.

VAN CLEAVE, H. J. 1953. Acanthacephala of North American mammals. Illinois
Biol. Monogr., 23: 1-179.

Accepted for publication June 5, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 133-144, 1970

FOUR SPECIES OF MICROTROMBICULA (ACARINA:
TROMBICULIDAE) FROM MEXICO AND NICARAGUA!

JAMES P. WEBB, JR. AND RICHARD B. Loomis
Department of Biology
California State College
Long Beach, California 90801

ABSTRACT: Four species of the genus Microtrombicula Ewing
are described: M. nicaraguae n. sp., host Sciurus variegatoides
from Nicaragua; M. paralios n. sp., host Pizonyx vivesi from
Baja California Norte, México; M. phyllodactyli n. sp., hosts
Phyllodactylus homolepidurus and P. tuberculosus from
Sinaloa and Sonora, México; and M. tragulata (Brennan and
Jones) NEW COMBINATION (formerly Euschoengastia
tragulata) is reported from Baja California, México and
Nicaragua.

INTRODUCTION

Studies of North American chiggers of the genus Microtrombicula
revealed three new species from México and Nicaragua, and a fourth
species, Euschoengastia tragulata Brennan and Jones, is transferred to
this genus.

All four species are described below and each new species is based
upon the holotype and available paratypes. The terminology usually
follows Wharton et al. (1951), Wharton and Fuller (1952), and Audy
(1954). All measurements are in microns. Common and scientific
names of the mammals are usually those of Hall and Kelson (1959).

Unless otherwise indicated, the specimens examined are in the
chigger research collection, California State College, Long Beach.
Paratypes will be deposited in the Rocky Mountain Laboratory,
Hamilton, Montana, and in other appropriate institutions.

Microtrombicula nicaraguae, new species
Figures | and 5

Types. — Larvae: Holotype and 4 paratypes from Finca Santa
Cecilia, 6.5 km SE Guanacaste, 660 m, Granada, Nicaragua, host
Sciurus variegatoides, variegated squirrel, original number RWT 267,
taken 13 June 1966 by R. W. Turner.

1Studies upon which this report is based were supported by a Research Grant
AI-03407 from the National Institute of Allergy and Infectious Diseases.

133

134 Bulletin So. Calif. Academy of Sciences

See J

NGA a TA
/ SG 2 p ; ; ; : os ms ‘ € g

LIN oe

IStr2 St mala

Figure 1. Microtrombicula nicaraguae n. sp. A. Scutum and eyes. B. Dorsal
aspect of gnathosoma. C. Ventral aspect of palpal tibia and tarsus. D. Representa-
tive body setae; 1 St, first sternal, 2 St, second sternal, PD, posterior dorsal, and
H, humeral. E. Leg I, genu, tibia, and tarsus with specialized setae and measure-
ments in microns, and bases of branched setae. F. Leg II, as above. G. Leg III,
as above.

Chiggers of Mexico 135

Diagnosis. — Larva, similar to Microtrombicula carmenae (Bren-
nan and Jones) but differs in having palpotibial claw bifurcate (tri-
furcate in M. carmenae), sensilla with 12-14 branches (M. carmenae
with 2-3 branches), and ASB< PSB (ASB = PSB in M. carmenae).

Description of holotype (with the mean and range of 5 types in
parentheses). — Body engorged, 320 by 215; eyes 2/2, anterior larger
and distinct, posterior lens and ocular plate indistinct.

Dorsal setae 2-6-6-6-4-4-2, total 30; measurements of humeral
seta 30, anterior dorsal seta 27, posterior dorsal seta 22.

Ventral setae 2-2 (sternals) 4-4+22, total 40; measurements of
anterosternal seta 19, posterosternal seta 17, posterior ventral seta 17.

Scutum: Subpentagonal, moderately punctate; sensilla flagelliform
with 12-14 branches.

Scutal measurements: AW 43 (43, 42-44), PW 52 (53, 51-55), SB
13 (14, 13-14), ASB 19 (19, 19), PSB 24 (25, 23-26), AP 21 (22, 21-
23), AM 24 (24, 23-26), AL 21 (22, 21-23), PL 32 (32, 30-34), S 37
(39, 36-43).

Gnathosoma: Cheliceral blade with tricuspid cap medium in size;
cheliceral base and capitular sternum lightly punctate. Galeala nude.
Palpal setae B/B/BBB (palpotibial setae nearly nude); palpotarsus
with 1 nude and 5 branched setae, and tarsala 6; palpotibial claw
bifurcate.

Leg I with 3 genualae and tarsala 10 (11, 10-12); leg II with tarsala
12 (12, 12) and pretarsala; leg III with coxa unisetose and 1 nude
mastitarsala.

Leg measurements: I, 175 (175, 167-180); II, 151 (152, 145-157);
Ill, 174 (174, 168-180); total, 500 (501, 492-506).

Microtrombicula paralios, new species
Figures 2 and 5

Types. — Larva: Holotype from Puertecitos, Baja California
Norte, Mexico, host Pizonyx vivesi, fish-eating bat, original number
WJW630529-13, taken 25 May 1963 by R. Hardy and H. E. Childs.

Diagnosis. — Larva, similar to Microtrombicula nicaraguae, new
species, but differing in scutal shape and having sensilla with 8-10
branches (12-14 branches in M. nicaraguae).

Description of holotype. — Body engorged, 435 by 240; eyes 2/2,
anterior larger, lens and ocular plate distinct.

Dorsal setae 2-6-6-6-4-4-2, total 30; measurements of humeral seta
35, anterior dorsal seta 26, posterior dorsal seta 24.

136 Bulletin So. Calif. Academy of Sciences

Figure 2. Microtrombicula paralios n. sp. A. Scutum and eyes. B. Dorsal aspect
of gnathosoma. C. Ventral aspect of palpal tibia and tarsus. D. Representative
body setae; 1 St, first sternal, 2 St, second sternal, PD, posterior dorsal, and H,
humeral. E. Leg I, genu, tibia, and tarsus with specialized setae and measurements
in microns, and bases of branched setae. F. Leg II, as above. G. Leg III, as above.

Chiggers of Mexico 137

Ventral setae 2-2 (sternals) 4-6-2-6-4 + 14, total 40; measurements
of anterosternal seta 19, posterosternal seta 21, posterior ventral
seta 23.

Scutum: Subpentagonal, moderately punctate; sensilla flagelliform
with 8-10 distal branches.

Scutal measurements: AW 48, PW 56, SB 15, ASB 22, PSB 26, AP
PM AMIPOv AT: 20; PL 32, S$ 38-

Gnathosoma: Cheliceral blade with medium sized tricuspid cap;
cheliceral base and capitular sternum lightly punctate. Galeala nude.
Palpal setae B/B/BBB; palpotarsus with 1 nude and 5 branched setae,
and tarsala 7; palpotibial claw bifurcate.

Leg I with 3 genualae and tarsala (13); leg II with tarsala (13) and
pretarsala; leg III with coxa unisetose, and 1 nude mastitarsala.

Leg measurements: I, 175; II, 146; III, 218; total, 539.

Taxonomic remarks. — This species name is from the Greek,
paralios, meaning by or near the sea in reference to the type locality.

Ecological notes. — The fish-eating bat, Pizonyx vivesi, was taken
from a rocky cliff crevice overlooking the Gulf of California. This same
series of bats also yielded the types of Speleocola cortezi Loomis and
Webb (1969). Although the single larva of M. paralios was recorded
from the nasal passage, it may not be a regular intranasal resident.

Microtrombicula phyllodactyli, new species
Figures 3 and 5

Types. — Larvae: Holotype and 17 paratypes from Topolobampo,
Sinaloa, México, host 2 Phyllodactylus h. homolepidurus, original
numbers WJ W640801-1 (holotype and 4 paratypes) and WJ W640801-
2 (13), taken 1 Aug. 1964 by R. E. Dingman, R. B. Loomis, L. K.
Tanigoshi, and W. J. Wrenn.

Diagnosis. — Larva, similar to those of Microtrombicula crossleyi
(Loomis) and M. trisetica (Loomis and Crossley) but differing in
having palpotibial claw trifurcate (bifurcate in M. crossleyi and M.
trisetica), and dorsal and lateral palpotibial setae nude (branched in
other two species).

Description of holotype (with the mean and range of 10 types, in
parentheses, unless otherwise indicated). — Body engorged, 425 by
255; color in life, red-orange; eyes 2/2, anterior larger, posterior lens
and ocular plate indistinct.

Dorsal setae 2-6-6-6-4-2-2, total 28; measurements of humeral seta
30, anterior dorsal seta 30, posterior dorsal seta 23.

138 Bulletin So. Calif. Academy of Sciences

Figure 3. Microtrombicula phyllodactyli n. sp. A. Scutum and eyes. B. Dorsal
aspect of gnathosoma. C. Ventral aspect of palpal tibia and tarsus. D. Representa-
tive body setae; PD, posterior dorsal, 1 St, first sternal, and H, humeral. E. Leg I,
genu, tibia, and tarsus with specialized setae and measurements in microns, and
bases of branched setae. F. Leg II, as above. G. Leg III, as above.

Chiggers of Mexico 139

IST A

Figure 4. Microtrombicula tragulata (Brennan and Jones). A. Scutum and eyes.
B. Dorsal aspect of gnathosoma. C. Ventral aspect of gnathosoma. D. Representa-
tive body setae; PD, posterior dorsal, | St, first sternal, and H, humeral. E. Leg I,
genu, tibia, and tarsus with specialized setae and measurements in microns, and
bases of branched setae. F. Leg II, as above. G. Leg III, as above.

140 Bulletin So. Calif. Academy of Sciences

. nicaraguae

. paralios

. phyllodactyli 1200 kms

3 tragulata 800 miles

Figure 5. Distribution of Microtrombicula nicaraguae, M. paralios, M. phyl-
lodactyli, and M. tragulata. Solid symbols indicate specimens examined and the
symbol within a symbol designates a type locality.

Ventral setae 2-2-2 (sternals) 4-4-4+ 14, total 32; measurements of
anterosternal seta 20, posterosternal seta 22, posterior ventral seta 21.

Scutal measurements: AW 49 (48, 45-51), PW 62 (61, 59-63), SB
20 (19.5, 17-21), ASB 22 (21, 19-23), PSB 21 (21, 19-23), AP 20 (21),
19-22), AM 20 (22, 20-23; 8), AL 23 (22, 20-24; 9), PL 35 (36, 34-
38), S 46 (49, 44-52; 7).

Chiggers of Mexico 141

Gnathosoma: Cheliceral blade with small tricuspid cap; cheliceral
base and capitular sternum moderately punctate. Galeala nude. Palpal
setae B/B/NNB; palpotarsus with 2 nude and 4 branched setae, and
tarsala 6; palpotibial claw trifurcate.

Leg I with 3 genualae and tarsala 17 (16, 13-19; 9); leg II with
tarsala 17 (16, 13-20) and pretarsala; leg III with coxa unisetose, and
1 nude or nearly nude mastitarsala in medial whorl.

Leg measurements: I, 189 (183, 166-198); II, 171 (166, 161-172);
Ill, 196 (187, 180-197); total, 556 (537, 508-556).

Ecological notes. — Larvae of M. phyllodactyli have been recovered
from two species of leaf-toed geckos, Phyllodactylus homolepidurus
and P. tuberculosus, which according to Dixon (1964) occupy similar
niches in rock outcroppings, cliffs, boulders, and stone bridges. Twelve
specimens of P. h. homolepidurus taken from rocky areas in Sinaloa
and Sonora, and 20 P. tuberculosus saxatilis from limestone ledges and
mines in southeastern Sonora each had numerous M. phyllodactyli all
over the body. Eighteen other P. t. saxatilis from buildings, bridges,
culverts, and trees had no chiggers. Larvae are recorded from March,
April, June, August, and December.

This species has as expanded tip on tarsala II, a condition reported
by Loomis (1964) for chiggers of five genera which regularly parasitize
lizards in Africa, the United States, and México.

Geographic distribution. — Known from central and southern
Sonora, and northwestern Sinaloa, México.
Specimens examined (93). — MEXICO. SINALOA: Topolo-

bampo, | Aug. 1964, 2 Phyllodactylus homolepidurus (18). SONORA:
13 km SE Alamos, 28 March 1961, 4 Phyllodactylus tuberculosus (3),
17 April 1962, P. tuberculosus (6), 4 Dec. 1964, 4 P. tuberculosus (30);
10 km S Hermosillo, 2 Dec. 1964, P. homolepidurus (4); 55 km §
Hermosillo, 17 June 1967, P. homolepidurus (4); La Aduana, 5 Aug.
1963, P. tuberculosus (2), 25 Aug. 1963, P. tuberculosus (2); San
Carlos Bay, 31 Dec. 1964, 3 P. homolepidurus (24).

Microtrombicula tragulata (Brennan and Jones),
New Combination
Figures 4 and 5

Euschoengastia tragulata Brennan and Jones, 1961: 110, type from
Barro Colorado Island, Canal Zone, Panama, host Nasua narica, Nov.
1956; Brennan and Yunker, 1966: 235.

Diagnosis. — Larva, similar to Microtrombicula carmenae (Bren-

142 Bulletin So. Calif. Academy of Sciences

nan and Jones) but differing in having an expanded, lanceolate, sensilla
(flagelliform in M. carmenae) and cheliceral blade with a prominent
dorsal projection (absent in M. carmenae).

Description of species (Based upon holotype, after Brennan and
Jones, 1961, and 2 paratopotypes, in parentheses, unless otherwise
noted). — Body slightly engorged, 225 by 155; eyes 2/2, anterior
larger, ocular plate evident.

Dorsal setae 2-6-6-6-4-2, total 26; measurements (2 paratopotypes)
of humeral seta (35, 36), anterior dorsal seta (28, 29), posterior dorsal
seta (24, 28).

Ventral setae 2-2 (sternals) 2-4-4-4-4-4, total 26; measurements of
anterosternal seta (17, 19), posterosternal seta (19, 19), anterior ventral
seta (19, 19) posterior ventral seta (22, 24).

Scutum: Subpentagonal, moderately punctate; sensilla lanceolate
and sparsely covered with setules.

Scutal measurements: AW 50 (45, 48), PW 60 (58, 60), SB 21 (20,
22), ASB 22 (23, 23), PSB 24 (24, 27), AP 26 (24, 27), AM 34 (27,
27), AL 23 (21, 22), PL 33 (32, 34), S 43 (41, 43). Scutal measure-
ments with the mean and extremes of 10 larvae from Nicaragua: AW
46, 42-49; PW 59, 56-63; SB 19, 16-23; ASB 22, 17-24; PSB 24, 22-
26; AP 25, 22-26; AM 28, 23-31; AL 22, 15-24; PL 35, 29-37;S 43.5,
43-44; 2. Baja California larva: AW 49, PW 66, SB 20, ASB 23, PSB
28, AP 28, AM 34, AL 24, PL 36, S 16 (inc.).

Gnathosoma: Cheliceral blade with small tricuspid cap; cheliceral
base and capitular sternum moderately punctate. Galeala nude. Palpal
setae B/B/BNN (ventral palpotibial seta nude in one paratopotype and
forked in other); palpotarsus with 1 nude and 5 branched setae, and
tarsala; palpotibial claw trifurcate.

Leg I with 3 genualae and tarsala 12 (12, 12); leg II with tarsala 13
(12, 12), and pretarsala; leg III with coxa unisetose, and | nude masti-
tarsala. Tarsala I and II measurements with the mean and ranges of 10
larvae from Nicaragua: T I, 11, 10-12; T II, 12, 12. Baja California
Specimens wile IS elie lise

Leg measurements of 2 paratopotypes: I, 161, 197; II, 139, 158; III,
162, 180; total, 462, 535. Baja California larva: I, 201; II, 179; III,
198; total, 578.

Remarks. — Only four of 13 examined specimens of M. tragulata
had at least one entire sensilla and five had only the basal segment of
one shaft remaining.

Ecological notes. — Ten larvae of M. tragulata were recovered from
a kinkajou, Potos flavus, captured in a tropical deciduous forest in

Chiggers of Mexico 143

Nicaragua. One larva was taken off a ringtail, Bassariscus astutus,
collected in a pine-oak meadow habitat, 1670 meters, in Baja Cali-
fornia Sur. The type series from a coati, Nasua narica, was obtained
from Barro Colorado Island where the vegetation was reported as
primarily evergreen or semievergreen seasonal forest. The known
hosts are medium sized mammals consisting of a porcupine, opossum,
and three procyonid carnivores. Larvae have been taken in February,
June, July, and November.

Geographic distribution. — Known from the Cape Region of Baja
California, México, Nicaragua, and the Canal Zone.

Specimens examined (13). — MEXICO. BAJA CALIFORNIA
SUR: La Laguna, 8 July 1967, Bassariscus astutus (1). NICARAGUA.
GRANADA: 6.5 km SE Guanacaste, 13 June 1966, Potos flavus (10).
PANAMA. CANAL ZONE: Barro Colorado Island, Nov. 1956,
Nasua narica (2 paratypes, RML).

Additional records (Brennan and Yunker, 1966).— PANAMA.
CANAL ZONE: Pina, 16 Feb. 1962, Didelphis marsupialis (1); Pedro
Miguel River, 21 Feb. 1962, 5 Coendou rothschildi (33).

ACKNOWLEDGMENTS

We extend our sincere thanks to Dr. J. Knox Jones, Jr. and others of The Uni-
versity of Kansas for specimens obtained in Nicaragua under United States Army
Medical Research and Development Command Grant DA-49-193-MD-2215,
and to Sr. Dr. Rudolfo Hernandez Corzo, el Director General, Direccion General
de Caza, Departamento de Conservacion de la Fauna Silvestre, Secretaria de
Agricultura y Ganaderia for permits to collect vertebrates in México. Paratypes
and referred slides of chigger larvae were graciously provided by Dr. James M.
Brennan of the Rocky Mountain Laboratory (RML), Hamilton, Montana. In
addition, we are grateful to the members of the chigger project and other students
and faculty in the Department of Biology, California State College, Long Beach,
who collected vertebrate hosts and their chiggers. Finally, we thank Elaine Katzer
and Lee C. Spath for the fine illustrations.

LITERATURE CITED

Aupy, J. R. 1954. Notes on the taxonomy of trombiculid mites, with description
of a new subgenus. Malaysian Parasites IX. Stud. Inst. Med. Res. Malaya,
(26): 123-170.

BRENNAN, J. M. AND E. K. Jones. 1960. Chiggers of Trinidad, B.W.1I. (Acarina:
Trombiculidae). Acarologia, 2: 493-540.

Dixon, J. R. 1964. The systematics and distribution of lizards of the genus
Phyllodactylus in North and Central America. New Mexico State Univ. Res.
Center Sci. Bull., 64: 1-139.

144 Bulletin So. Calif. Academy of Sciences

Ewina, H. E. 1950. A redescription of four genera of chigger mites, together with
a description of a new genus and subgenus (Acarina, Trombiculidae). Proc.
Entomol. Soc. Wash., 52: 291-299.

Hai, E. R. anp K. R. KELSON. 1959. The mammals of North America. The
Ronald Press Co., New York, 2 vols., 1083 pp.

Loomis, R. B. 1964. A new species of chigger (Acarina, Trombiculidae) from
lizards of western North America. Great Basin Natur., 24: 13-17.

Loomis, R. B. AnD J. P. WEBB, JR. 1969. A new species of Speleocola (Acarina:
Trombiculidae), off a bat, Pizonyx vivesi, from Baja California, Mexico.
Bull. So. Calif. Acad. Sci., 68: 36-42.

VERCAMMEN-GRANDJEAN, P. H. 1965. Revision of the genera: Eltonella Audy,
1956 and Microtrombicula Ewing, 1950, with descriptions of fifty new
species and transferal of subgenus Chiroptella to genus Leptotrombidium
(Acarina: Trombiculidae). Acarologia, 7(fasc. suppl.): 34-257.

WHARTON, G. W. AND H. W. FULLER. 1952. A manual of the chiggers. Mem.
Entomol. Soc. Wash., No. 4, 1-185.

WHARTON, G. W., D. W. JENKINS, J. M. BRENNAN, H. S. FULLER, G. M. KoHLs,
AND C. B. Puitip. 1951. The terminology and classification of trombiculid
mites (Acarina: Trombiculidae). J. Parasit., 37: 13-31.

Accepted for publication June 30, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 145-149, 1970

ANCINUS SETICOMVUS, n. sp. ISOPODA),
FROM SANTA BARBARA, CALIFORNIA

THOMAS TRASK*
Allan Hancock Foundation
University of Southern California University Park
Los Angeles, California 90007

ABSTRACT: Ancinus seticomvus, Nn. sp. is described from two
sandy beaches near Santa Barbara, California. It is very
similar to A. depressus (Say) from the East coast of North
America and the Gulf of Mexico.

INTRODUCTION

A sandy beach sampling program was initiated as part of a research
grant* awarded to the Allan Hancock Foundation following the blow-
out of Platform A in the Santa Barbara Channel. In the course of the
sampling program, an unknown sphaeromid isopod was recovered from
two of the three beaches being studied, Coal Oil Beach (just south of
Coal Oil Point), and Carpinteria State Beach (approximately 1/2 mile
south of the entrance gate). Personal communication with Dr. Robert
Y. George, Depart. of Oceanography, Florida State University, and a
search of the literature convinced me that it was a new species.

FLABELLIFERA
SPHAEROMIDAE
Genus ANCINUS Milne Edwards (1840)

A discussion of the characteristics of Ancinus Milne Edwards may
be found in Menzies and Barnard (1959) and Menzies and Frankenberg
(1966).

Ancinus seticomvus, new species
Figures 1 and 2

Material. Holotype male (AHF Arthropod Collection No. 692),
allotype female (AHF Arthropod Collection No. 692a), and 8 para-
types collected at Coal Oil Beach, Santa Barbara County, California,
July 29, 1969. Three additional specimens (not paratypes) from the
same locality, and one from Carpinteria State Beach, Ventura County,
California, October, 1969. Specimens collected with hand shovel in
lower intertidal areas of beaches.

*A study of the biological and oceanographic effects of oil spillage in the Santa
Barbara Channel following the 1969 blow-out, supported by the Western Oil
and Gas Association.

145

146 Bulletin So. Calif. Academy of Sciences

——_

Figure 1. A, holotype male, dorsal view; 10.5 mm long, 5.0 mm wide; B, anten-
nule; C, antenna D, mandible; E, maxilliped; F, first peraeopod; G, second
peraeopod of holotype. Each line equals 1.0 mm. Illustrations with similar
magnifications: A; B, C; D, E; F, G.

New Isopod 147

Figure 2. H, apex of seventh peraeopod; I, first pleopod; J, second pleopod of
holotype with appendix masculina; K, third pleopod; L, fourth pleopod; M, fifth
pleopod; N, apex of second peraeopod of allotype; O, second pleopod of allotype.
Each line equals 1.0 mm. Illustrations with similar magnifications: H; I, J; K, L,
M;N, O.

148 Bulletin So. Calif. Academy of Sciences

Diagnosis. Ancinus with proximal portion of propodite of second
peraeopod of male with a medially placed knob bearing from 5 to 7
setae.

Description. Length of anterior rostral process of cephalon about
1.7 times width (Fig. 1A). Area of cephalon adjacent to rostral process
and latero-posterior margins of cephalon excavated. Sides of peraeon
nearly parallel. Epimera visible on all peraeonal segments of both
sexes. Peraeonal segments subequal in width and length. Pleon
triangular-shaped, tapering to a notched apex, resembling a funnel.
First pelonal segment barely visible. Uropods uniramous.

Antennule (Fig. 1B) composed of a peduncle of 4 articles and a
flagellum of 8 articles. The two proximal articles subequal, both smaller
than following two subequal pedunculate articles. Antennules and
antennae about equal in length. Antenna with peduncle of 3 articles,
proximal article inflated; flagellum of 15-16 articles (Fig. 1C). Cutting
edge of mandible (Fig. 1D) bearing 4 teeth. Mandibular palp with 3
articles. Endite of maxilliped (Fig. 1E) bearing two coupling hooks;
maxillipedal palp consisting of 4 articles. First peraeopod (Fig. 1F)
sub-chelate in both sexes; second peraeopod prehensile in male,
ambulatory in female (Figs. 1G, 2N). Pleopods 1 and 3-5 (Figs. 21,
K-M) same in male and female; pleopod 2 (Fig. 2J) of male bearing
appendix masculina, with apex not reaching apex of endopod. Uropods
of male exceeding apex of pleon (Fig. 1A); female uropods approxi-
mately even with apex of pleon or shorter.

Measurements. Length of holotype male 10.5 mm, width 5.0 mm at
edges of first thoracic segment. Length of allotype female (ovigerous)
8.0 mm, width 4.0 mm at edges of first thoracic segment.

Color. Exoskeleton pigmented, giving both sexes a dark tan color.

Affinities. Ancinus seticomvus [seti- from Latin “seta” =a bristle;
comvus from Greek “Kombos” (comvos) = knob] is similar in appear-
ance to Ancinus depressus (Say). A comparison of the characteristics
and illustrations given here with those give for A. depressus in Menzies
and Frankenberg (1966) and Richardson (1909) would reveal close
agreement for most criteria mentioned. However, the two species differ
in at least two pertinent characters: (1) the knob located medially on the
proximal portion of the propodite of the second peraeopod in the male
is rounded and bears 5-7 setae in A. seticomvus (Fig. 1G), while it is
pointed and appears to bear but one stout spine in the male A. depres-
sus; (2) the dactylopodite of the same appendage is proportionately
much longer in A. seticomvus than in A. depressus, the ratio of
dactylopodite length to propodite length being 1.3 : 1 in the former and
1: 1 in the latter species. The second peraeopod of the male is pre-

New Isopod 149

sumably used as a clasping organ during mating in both species.
Differences in the structure of such an important appendage could
conceivably operate as effective mechanical, pre-mating, reproductive
isolating mechanisms.

Some parts of other extremities of A. seticomvus also appear to be
more elongate than corresponding parts of A. depressus, but this may
be a function of overall size. Thus the male A. depressus described by
Menzies and Frankenburg (1966) was 3 mm wide and 7 mm long, and
the uniramous uropods do not exceed the tip of the telson, whereas the
male A. seticomvus described herein is 5 mm wide and 10.5 mm long,
and the uniramous uropods exceed the tip of the telson by 1/6th to
1/Sth the total length of the uropod.

Distribution. While A. depressus is found on the East coast of North
American and in the Gulf of Mexico. A. seticomvus has been collected
only from two beaches in Santa Barbara, on the West coast of North
America, to date. Thus, in addition to morphological differences
between the two species, the differences in geographical distribution,
resulting in reproductive isolation, warrants considering the two
specifically distinct. If populations of the two species are later found
in close proximity to each other, a re-evaluation of the proposed
separation could then be undertaken.

The only other species in the genus is Ancinus daltonae, described
from the eastern Pacific by Menzies and Barnard in 1959. An examina-
tion of the illustrations of A. daltonae would indicate several morpho-
logical differences between it on the one hand, and A. seticomvus and
A. depressus on the other.

ACKNOWLEDGEMENTS

I am indebted to Dr. George for the help he gave me with the identification of
this isopod, and for graciously loaning me specimens of the East coast Ancinus
for comparative work. I am also indebted to Dr. John S. Garth and Dr. Kristian
Fauchald, Allan Hancock Foundation, for reviewing the manuscript. Financial
assistance provided by the research program mentioned above and directed by
Dr. Dale Straughan is hereby gratefully acknowledged.

LITERATURE CITED

Menzies, R. J., AND J. L. BARNARD. 1959. Marine lsopoda on coastal shelf bottoms
of Southern California: systematics and ecology. Pacific Nat. 1 (11-12): 3-35.

MENZIES, R. J., AND D. FRANKENBERG. 1966. Handbook on the common marine
isopod Crustacea of Georgia. Univ. Georgia Press, Athens,

RicHARDSON, H. 1909. The isopod crustacean, Ancinus depressus (Say). Proc.
U.S. Nat. Mus. 36: 173-177.

Accepted for publication April 17, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 150-153, 1970

OCCURRENCE OF A HOLOTRICHOUS CILIATE IN THE
INTESTINE OF THE POLYCHAETE HERMODICE
CARUNCULATA OF PUERTO RICO!

IRA JONES? AND IRMA RIVERA RODRIGUES
Department of Biology
Inter American University of Puerto Rico
San German, Puerto Rico

ABSTRACT: Hermodice carunculata, a tropical polychaete, was
collected along the southern coast of Puerto Rico during April
through July 1969. The intestinal contents of the worms were
examined and a holotrichous ciliate was found. Ninety-one
percent of 121 freshly collected worms harbored the ciliate.
Only 35% of 44 worms carried the protozoan when they were
maintained in the laboratory longer than three days. The
ciliate is pyriform, dorsoventrally flattened and its size ranged
from 40.95, x 34.584 to 72.804 x 45.50p.

INTRODUCTION

Intestinal examinations of the polychaete Hermodice carunculata from
the southern coast of Puerto Rico disclosed an interesting holotrichous
ciliate. From experimental evidence it seems that the protozoan is likely
a facultative commensal. Apparently there are no reports in the litera-
ture on ciliates of H. carunculata and very little is known concerning its
intestinal flora.

MATERIALS AND METHODS

Samples of Hermodice carunculata were obtained by digging in beds
of coral rubble of Porites porites on reefs in the vicinity of La Parguera,
Puerto Rico. One hundred and sixty five worms were examined during
April through July 1969. Routinely, the majority of the worms were
examined within five hours after each collection. A few were main-
tained up to 12 days in aerated sea water aquaria in our laboratory.
The worms were relaxed in ethanol diluted to 10% with sea water and
finally dipped into 70% ethanol to destroy protozoa which may have
been attached to their body surface. The digestive tract was then

1Supported by a grant from the Caribbean Institute and Study Center for Latin
America.

*Present Address: Department of Biology, California State College, Long Beach,
California, 90801.

150

A Ciliate in Hermodice 151

exposed and removed through a longitudinal incision. Smears were
made solely from the intestinal contents. Because examinations of
worms maintained under laboratory conditions for a few days revealed
a significant decrease in the abundance of the ciliate within their
intestine, the following procedure was employed. Worms were rinsed
in tap water to free them of possible body surface protozoa. Individual
worms were then put into petri dishes which contained sterile sea water.
The worms and sea water were examined approximately 24 hours later.

The ciliate was studied in both living and preserved states. Observa-
tions on the general morphology of the ciliate were made from per-
manent mounts fixed in either Schaudinn’s fluid or 10% formalin.
Either Heidenhain’s iron hematoxylin or Delafield’s hematoxylin were
used for staining. Due to numerous food vacuoles, the Feulgen reaction
was used to locate the micronucleus. Some cytochemical observations
were also made on the carbohydrate and lipid contents of the ciliate.
The procedures used for lipid studies were those of Lillie (1944),
Landing et al. (1952), McManus (1946) and Kluven and Barrera
(1953). Methods used for the detection of complex carbohydrates rich
in free acidic and vicinal hydroxyl groups were those of Mowry (1963).

RESULTS

One hundred and twenty one H. carunculata were examined within a
few hours after collection. Ninety-one percent of the worms harbored
an abundance of a holotrichous ciliate in their intestines. Samples of
the protozoan were found throughout the intestine, but were most
numerous in the posterior segment. A sharp decrease in the abundance
of the ciliate was observed when worms were maintained in the labora-
tory longer than three days. Only 35% of 44 laboratory maintained
worms were found harboring the ciliate, and the average numbers were
two to three per host. Experimentally, within 24 hours after the worms
were isolated into finger bowls, very active samples of the ciliate were
observed in sea water.

This protozoan is a pyriform, dorsoventrally flattened holotrichous
ciliate (Fig. 1). It is concaved on one side and slightly convexed on the
other. The concaved side, usually in contact with the substratum, is
considered to be the ventral side. Fifty fixed and stained specimens
were selected at random and measured. The ciliate ranged in size from
40.95u x 34.58. to 72.80. x 45.50,, and averaged approximately
59u X 41,4. The protozoan is covered with a thin pellicle. This covering
bears 15 to 18 longitudinal rows of cilia which converge in a charac-

IS2 Bulletin So. Calif. Academy of Sciences

Figure 1. Drawing of ciliate with aid of camera lucida. Cytostome at anterior
lateral region, macro and micro nuclei in center of cell and contractile vacuole at
posterior end. X430. Figure 2. Photograph of ciliate with many food vacuoles.
X451.

teristic pattern at the anterior end of the organism. The body ciliation
is uniform and complete. The cytostome is situated laterally near the
anterior end. The cytopharynx is well formed and terminates near the
macronucleus. Samples of the ciliate isolated from freshly collected
worms contained large numbers of food vacuoles. The latter and large
granules almost filled the lower three-fourths of the organism (Fig. 2).
Tests with the stain Oil Red O revealed dense droplets of lipid dis-
persed in the cytoplasm.

DISCUSSION

This seems to be the first report on a ciliate from H. carunculata. From
experimental observations, it appears that the ciliate is likely a faculta-
tive commensal. Its occurrence in the intestine of the polychaete could
be the result of one or more factors. The protozoan is a voracious feeder
and its presence is apparently associated with the feeding habit of its
host. Firstly, it could be that large numbers of the ciliate are ingested
by the worm during feeding. It survives in the intestine and eventually
escapes in the feces. Secondly, it could well be that the protozoan
becomes established in the intestine and remains there provided the
host maintains an adequate food intake.

A Ciliate in Hermodice 153

There is very little doubt that this ciliate is a new species. However,
we are now greatly removed from the habitat of H. carunculata and it
is not convenient to conduct silver impregnation tests needed to further
study the ciliature of this protozoan. Thus we hestitate to name the
ciliate.

ACKNOWLEDGEMENTS

The authors express thanks to the Department of Marine Science, University of
Puerto Rico, for providing collecting facilities.

LITERATURE CITED

KLuveER, H. AnD B. S. BARRERA, 1953. A method for the combined staining of
cells and fibers in the nervous system. J. Neuropath. Exp. Neurol., 12: 400.

LANDING, B. H., L. L. UZMAN, AND A. WHIPPLE, 1952. Phosphomolybdic acid as a
staining reagent for lipids. Lab. Invest., 1: 462.

Litue, R. D., 1944. Various oil-soluble dyes as fat stains in the supersaturated
isopropanol technic. Stain Technol., 19: 45.

McManus, J. F. A., 1946. The demonstration of certain fatty substances in
paraffin sections. J. Path. Bact., 85: 93-95.

Mowry, R. W., 1963. The special value of methods that color both acidic and
vicinal hydroxyl groups in the histochemical study of mucins. With revised
directions for the colloidal iron stain, the use of Alcian blue 8Gx and their
combination with the periodic acid-schiff reaction. Ann. N.Y. Acad. Sci.,
106: 402-423.

Accepted for publication May 14, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 154-160, 1970

THE ROLE OF ELYTRA IN THE MOVEMENT OF WATER
OVER THE SURFACE OF HALOSYDNA BREVISETOSA
(POLYCHAETA: POLY NOIDAE)

JAMSON LWEBUGA-MUKASA
Medical School
University of California, San Diego
Box 172
San Diego, California 92037

ABSTRACT: In intact worms ciliary tracts on the parapodial
lobes and dorsal body surface bring in a flow of water laterally
between parapodial lobes and carry it posteriorly along the
body dorsolaterally below each row of elytra. The elytrae are
not ciliated and exhibit no fanning or pumping motions, but
are so shaped as to direct the incoming lateral flow posteriorly,
and to contain and direct the posterior flow over the more or
less corrugated dorsolateral body surfaces. They also permit
the currents to operate effectively when worms are wedged
into the secluded crevices and situations which they tend to
seek during daylight hours. Thin areas of the body wall are
provided with an external flow of water moving in one
direction and an internal flow of coelomic fluid moving the
opposite direction, and are presumed to function in respiratory
gas exchange.

INTRODUCTION

Polychaetes of the Polynoidae and related families, bear a double row
of elytra or scales on the dorsal surface of the body. The elytra are
variously modified in different genera, and according to Pettibone
(1953) they may function as sensory structures, as a dorsal armour,
as respiratory structures which participate in pumping water over
the dorsum (Aphrodita aculeata, van Dam, 1940), as luminescent
organs (Lepidesthenia elegans and some species of Harmothoe) and
as a protective covering for developing eggs (Harmothoe imbricata).

Segrove (1938), in his account of surface ciliation in polychaetes,
has described water currents flowing below the elytra in Harmothoe
imbricata. He distinguishes three main currents: a medial current
moving posteriorly over the dorsum which is completely roofed over
by elytra; and two lateral currents, one on each side, which bring in
water from the region between parapodia to the lateral apertures
between elytraphores and dorsal cirri. The lateral currents are created
mainly by the action of cilia on the anterior faces of parapodia. A weak
current flows posteriorly over the head of the worm.

154

Water Movement in Halosydna 55)

Halosydna brevisetosa is one of the commonest and most con-
spicuous polynoid polychaetes on the Pacific coast. It occurs from the
Alaskan Peninsula to Southern California (Hartman, 1940), and is
frequently found under rocks in protected areas on the outer coast
(Ricketts and Calvin, 1939), in Mytilus beds, and in similar secluded
intertidal situations down to a depth of 28 m (Hartman, 1940). The
only published observation on the role of the elytra in this species
occurred in a figure caption in Meglitch (1967, p. 578), which stated:
“The elytra are tilted to maintain a respiratory current, fanning the
water toward the posterior end.” The observations presented below
were carried out to further elucidate the role of the elytra in Halosydna
brevisetosa.

All studies were carried out at the Hopkins Marine Station of Stan-
ford University, Pacific Grove, California. The animals used were
obtained from clusters of mussels, ascidians and Phyllochaetopterus
adhering to floats in the small craft harbor at Monterey, California,
and maintained for periods of up to a few days in running seawater at
15-18°C. Representative specimens were kindly identified by Dr.
Marian Pettibone, Smithsonian Institution, Washington, D.C. Most of
the observations were carried out on freshly collected individuals
2.5-5 cm long and up to | cm in width. Ciliary currents were observed
under a dissecting microscope, using fine graphite particles suspended
in seawater to indicate direction and intensity of water flow. Finer
details of currents were observed on worms relaxed by adding to the
seawater an isotonic solution of MgClo.

OBSERVATIONS

The elytra in Halosydna brevisetosa form a double row along the
dorsum. In each row, each elytrum (except the first) is overlapped by
the elytrum just in front of it, so a continuous roof of elytra extends
along each side of the body. However, the right and left rows of elytra
do not meet mid-dorsally, so a strip of dorsal body wall along the
mid-line remains uncovered unless the worm is contracted (Fig. 1).
While moving forward, H. brevisetosa holds its elytra close to the
dorsum. The elytra in this position move with the sinuous crawling of
the worm. When an individual is stationary, the elytra are elevated
above the dorsal body surface by the hydrostatic pressure of coelomic
fluid which enters and extends the relaxed elytrapohores. In a stationary
animal neither the elytra nor the dorsal body wall beneath was ever
observed to be pumping or undergoing any sort of a fanning motion.
Nevertheless, a clear posteriorly directed current can be detected along

156 Bulletin So. Calif. Academy of Sciences

the body on either side between elytra and dorsum, and water enters
dorsolaterally between adjacent parapodia. In general, the current
pattern described by Segrove (1938) for Harmothoe imbricata holds
also for Halosydna brevisetosa, but in the latter species the current
along the dorsum is split in two. Backward flow is intense below each row
of elytra, and some water escapes upward in the medial region along
the body.

Two adjacent elytra in the same row, about halfway back along the
body, were removed on one side, leaving the opposite side of the body
intact (Fig. 1). The antero-posterior current under the intact row
continued undisturbed, and continued to the posterior end. Most of the
anterior-posterior current under the other row escaped upward upon
reaching the region from which the elytra had been removed. This
observation suggests that the elytra are functioning to contain the
antero-posterior current.

A study of the dorsal surface of the body exposed by removal of
elytra shows that the dorsum of Halosydna brevisetosa, like that of
Harmothoe imbricata as described by Segrove (1938), exhibits shallow
oval depressions surrounded by transverse ridges that converge lat-
erally to enclose the depressions (Figs. 2, 3). The ridges are particularly
prominent in the region beneath the elytra, the region over which the
anterior-posterior currents flow. Water moving from front to rear thus

Figures 1-4. Halosydna brevisetosa. Figure I dorsal view. Left side: actual appear-
ance of an intact row of elytra. Right side: diagramatic representation of elytra;
two adjacent elytra have been removed from the row. Arrows indicate water
currents; note the upward escape on the antero-posterior current on reaching
region devoid of elytra. Figure 2. dorsal view of five segments from mid-region.
Left side: actual appearance of elytra. Right side: elytra shown is in outline —
the elytra overlap over the region of the antero-posterior current. Note the relation
of elytra to the prominent ridges —that enclose depressions. Figure 3. longi-
tudinal section: arrows show water currents. The region over which the antero-
posterior current flows is highly corrugated — the water current accelerates as it
descents into a depression then bounces off and flows upward with rise of next
ridge. The elytra deflect this upwardly directed current onto the dorsum. Figure
4. cross-section: view facing posteriorly. Larger arrows indicate direction of
lateral surface currents; smaller arrows indicate direction of coelomic fluid
currents. Left side: surface of parapodium is shown and lateral surface currents
are indicated by large arrows. The elytrum is shown as it actually appears. Right
side: cross-section of parapodium is shown and direction of coelomic currents is
indicated by the smaller arrows. The elytrum’s shown in section. Note its
“Sigmoid” shape. One of the cup-like regions of the elytrum arches over the
principal path of the antero-posterior current.

157

Water Movement in Halosydna

158 Bulletin So. Calif. Academy of Sciences

must pass over a series of alternating ridges and troughs as it flows. A
close study of the antero-posterior currents in regions from which
elytra were removed indicates that the flow accelerates as it descends
into a depression, and is then deflected sharply upward as it encounters
the next ridge. The elytra clearly serve to prevent water from escaping
upward at each ridge.

The shape of the elytra provides evidence in support of the function
described above. In transverse section (Fig. 4) it can be seen that the
elytra are not flat but rather sigmoid. The area on the underside of an
elytrum which overlies a transverse body ridge is cupped; the effect of
this concavity is to deflect the anterior-posterior flow downward again
as it passes each successive ridge on the body, providing a posteriorly
directed flow that undulates upward and downward as it moves along
the body. The effect of the elytra is passive, for there is no active
rhythmic action of these structures, and the elytra bear no cilia to
augment the current.

The curvature of the elytra likewise helps to direct the incoming
lateral currents which rise and move medially between adjacent
parapodial lobes. The upturned lateral edges of the elytra help to funnel
this water into the elytral tunnel on each side, and the concavities on
the lower surfaces of the elytra described above act, along with cilia on
the elytraphores and dorsal body surface, to deflect the laterally
entering currents posteriorly, into the main stream of the anterior-
posterior flow on each side. The elytra are admirably shaped for this
purpose, as well. Details of water flow are shown in three different
views in Figs. 2-4.

Some additional observations were made which support the sug-
gestion of Segrove (1938) that the ciliary currents and water flow are
related to respiratory exchange between the external medium and the
body fluid. In some places, as on the parapodia, the body wall is
sufficiently thin and transparent to permit clear vision of the circulation
of fluid-borne particles and eggs in the coelomic cavity of an intact
worm. The thin areas in the body wall suggest areas of gas exchange.
Studies were made of the circulation of fluid in the coelomic cavity,
both by observation through the body wall in otherwise intact worms
with some elytra removed, and in dissected worms. Coelomic circula-
tion within segments generally runs counter to the external flow of
water (Fig. 4), which would increase the efficiency of any respiratory
exchange.

Further insight into the role of elytra was provided by observations
on intact worms maintained in laboratory aquaria over periods of

Water Movement in Halosydna 52)

several days. Thirty active, freshly collected worms, of which 12 could
be recognized as individuals, were placed in a tank provided with
running seawater. The tank was provided with a variety of situations
(e.g., bare glass sidewalls, wooden endwalls and some exposed wooden
bottom, an area of sandy bottom | cm thick, rocks and shells loosely
embedded in sand, a large rock tilted to provide a protected space on
the under surface, and a cluster of Phyllochaetopterus tubes). Worms
were observed and their positions noted at 0700, 1200, 1800, and
2400 for four days.

The results showed that the worms crawled freely in the open areas
at night. During the day they retreated to sheltered places away from
light and strong currents, though no individual worm showed a tend-
ency to return to a particular sheltered “home”. In taking shelter the
worms tended to wedge themselves into narrow spaces. Numerous
individuals crept under rocks and shells loosely embedded in sand,
though none actually burrowed into loose sand alone. Several others
squeezed themselves down into the cluster of Phyllochaetopterus tubes.
The protected daytime situations selected by worms in the aquarium
corresponded more or less to the kinds of places where the species was
collected in the field. In such situations the elytra not only hold adjacent
materials away from the ciliated surfaces, permitting unobstructed
ciliary action, but they maintain open channels dorsolaterally through
which water currents can circulate freely over the body of the worm,
including the presumed respiratory areas. The water-directing actions
of the elytra appear to be enhanced rather than diminished when the
animals occupy narrow sheltered spaces. The ciliary currents not only
bring a fresh flow of water to the body surfaces, but also act to carry
away fine particulate materials which might otherwise tend to sediment
about the body. While the methods used by Halosydna brevisetosa are
somewhat different from those used by Aphrodita aculeata (van Dam,
1940) the end results attained are somewhat similar.

ACKNOWLEDGMENTS

I wish to thank Dr. Donald Abbott, Hopkins Marine Station, who suggested the
problem to me and provided encouragement and guidance. I would also like to
thank Dr. Marian Pettibone, Smithsonian Institution, for identifying the animals
used, and Drs. Oscar E. Schotté and Harold H. Plough, Amherst College, for
reading the manuscript and for constructive comments. My study at Hopkins
Marine Station was made possible by fellowships from Amherst College and the
African-American Institute.

160 Bulletin So. Calif. Academy of Sciences

LITERATURE CITED

HarTMaNn, O., 1939. Polychaetous Annelids. Part I. Aphroditidae to Pisionidae.
Allan Hancock Pac. Exped. 7: 1-155.

MEG.tItTcH, P. A., 1967. Invertebrate Zoology. Oxford Univ. Press. 961 p.

PETTIBONE, MaRIAN H., 1953. Some scale-bearing polychaetes of Puget Sound
and adjacent waters. Univ. Wash. Press, Seattle. 89 p.

RICKETTS, E. F. anpD J. CALVIN, 1939. Between Pacific Tides. Stanford Univ.
Press. 365 p.

SEGROVE, F., 1938. An account of the surface ciliation in some polychaete worms.
Proc. — Zool. Soc. London. 108: 85-107.

vAN Dam, L., 1940. On the mechanism of ventilation of Aphrodita aculeata. J.
Exp. Biol., 17: 1-7.

Accepted for publication May 14, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 161-168, 1970

SOME HELMINTHS OF THE MUDSUCKER FISH,
GILLICHTHYS MIRABILIS COOPER*

W. E. MARTIN AND SYED MULTANI
Department of Biology
University of Southern California

ABSTRACT: Gillichthys mirabilis Cooper (mudsucker, long-
jawed goby) collected at Baja California, Mexico, near
Scammon Lagoon, Salton Sea, Seal Beach and Newport
Bay, and San Francisco Bay, California were examined for
helminths. The monogenetic trematode, Gyrodactylus sp.,
was found on the gills of fish from all localities except the
Salton Sea. A small digenetic trematode was recovered from
the posterior intestine of fish from Baja California and is
described as Lecithaster minimus sp. n. Encysted trematodes
and larval cestodes also were found in fish from Baja Cali-
fornia and Seal Beach. An adult acanthocephalan, Microsentis
wardae Martin and Multani, 1966, was found in fish from
Baja California. A larval acanthocephalan was recovered from
the coelom of hosts from Seal Beach. The nematode, Vaso-
rhabdochona cablei Martin and Zam, 1967, was found in
certain blood vessels of fish from Baja California and Seal
Beach. Another nematode, Spirocamallanus pereirai (Anne-
reaux, 1946) was found in the intestine of fish from all
localities except the Salton Sea.

INTRODUCTION

The mudsucker or long-jawed goby, Gillichthys mirabilis Cooper, is
found along the western coast of United States and Baja California,
Mexico, in sloughs, bays, and estuaries. It is an important bait fish for
salt- and freshwater fishing being capable of living in both environ-
ments and of surviving for extended periods (one week) out of water if
kept moist. Collections of 172 fish, 116 from Baja California (near
Scammon Lagoon), 12 from the Salton Sea, 30 from estuaries at Seal
Beach and Newport Bay, and 24 from San Francisco Bay, have been
examined for helminths.

The helminths obtained were studied alive and as whole mounts and
serial sections. Heidenhain’s “‘Susa” fixative and either paracarmine,
Galigher’s haematoxylin, or Mallory’s triple stain was used. All
measurements are expressed in millimeters unless otherwise indicated.

*Supported by NSF GB 6962

161

162 Bulletin So. Calif. Academy of Sciences

Members of the following groups of helminths were found: Acantho-
cephala, Trematoda, Cestoda, and Nematoda.

ACANTHOCEPHALA

Microsentis wardae Martin and Multani, 1966 was found in the pos-
terior intestine of about 93% of the Gillichthys mirabilis collected near
Scammon Lagoon, Baja California but was not found in fish from any
other localities. The density of infection ranged from 1-60 worms per
fish. This genus and species were described by Martin and Multani
(1966).

A larval acanthocephalan (Fig. 4) was found in the coelom or
attached to mesenteries of fish collected in the Seal Beach area. They
are orange-red in life. Fourteen whole mounts stained with para-
carmine were measured. Body length 1.16-1.82, av. 1.38, maximum
body width 0.56-0.938, av. 0.823, spine lengths 0.028-0.037, spine
widths 0.006-0.016. The proboscis is thickly set with spines and there ©
are additional spines on the neck. Some larvae were fed to hatchery-
raised chicks with negative results. Nadakal (1963) studied the orange
pigment of the adult acanthocephalan, Pallisentis sp., from the intestine
of the fish Ophiocephalus and concluded that it was a carotenoid.

TREMATODA

Monogenetic trematodes, Gyrodactylus sp., were found on the gills of
fish from all localities except the Salton Sea.

A small adult trematode was found in the posterior intestine of 34%
of the fish from Baja California, but no other locality, that is described
as a new species. Fifty-four worms were found but only 10 were used
for the following description.

Lecithaster minimus, new species
Figures 1-3

Body length 0.322-0.7, av. 0.497; maximum body width 0.154-
0.252, av. 0.19; anterior body surface bears sensory papillae, oral
sucker length 0.047-0.084, av. 0.068; oral sucker width 0.05-0.087,
av. 0.068; pharynx length 0.031-0.05, av. 0.039; esophagus short, ceca
extend to near posterior end of body, cecal cells and lumen contain
globules; ventral sucker 0.062-0.143, av. 0.102 in diam.; right testis
length 0.059-0.093; right testis width 0.031-0.05, av. 0.042, left testis
length 0.059-0.081, av. 0.066; left testis width 0.03 1-0.056, av. 0.044;
testes at anterior margin of ventral sucker; seminal vesicle saccular,

WW OSL*0

Helminth Parasites

aS FIG.3

SS oO

FIG.1 Am

Figures 1-3. Lecithaster minimus, a new species of trematode.

163

164 Bulletin So. Calif. Academy of Sciences

about as long as ventral sucker and close to it; prostate cells free, large,
numerous, and with granular cytoplasm; vitellaria near posterior end
of body, seven lobed; ovary four-lobed, in posterior half of body;
seminal receptacle immediately anterior to ovary; uterus extends in
longitudinal loops from near posterior end of body to genital pore
where it joins the male duct to empty into a muscular, hermaphroditic
bulb averaging 0.03 long and 0.02 wide that in turn empties into the
genital pore; genital pore ventral a short distance posterior to cecal
bifurcation; eggs oval, with small operculum, length 18-21, av. 19, ;
width 6-9, av. 8u ; excretory vesicle saccular.

Type specimen deposited in the Hancock Foundation, Parasite
Collection no. 701.

This species is smaller than any previously described. The sucker
ratio is about 1:1.5 while in other species the ventral sucker is 2-4
times larger than the oral sucker.

The genus Lecithaster was erected by Liihe (1901) with L. bothryo-
phorus (Olsson) as type. Odhner (1905) declared L. bothryophorus a
synonym of L. gibbosus (Rud., 1802). Manter and Pritchard (1960)
considered the genus Mordvilkoviaster raised by Pigulewsky (1938) to
be a synonym of Lecithaster. Hunninen and Cable (1943) demonstrated
the life cycle of Lecithaster confusus Odhner, 1905 in which the snail,
Odostomia trifida (Totten), is first intermediate host, the copepod,
Acartia tonsa, is second intermediate host, and the stickleback, Apeltes
quadracus, is the definitive host. Boyce (1969) stated that Lecithaster
gibbosus (Rud., 1802) uses snails, Thais lamellosa Gmelin, 1792 and
T. emarginata Deshayes, 1839, as first intermediate hosts, the cope-
pods, Centropages abdominalis Sato, 1913 and Pseudocalanus minutus
(Krgyer, 1847) as second intermediate hosts, and salmon, Oncorhyn-
chus gorbuscha, as the definitive host. Boyce cites Arai (MS, 1967) as
listing the following additional definitive hosts: the kelp greenling,
Hexagrammos decagrammus, the shiner perch, Cymatogaster aggre-
gata Gibbons, 1854, and the tube snout, Aulorhynchus flavidus Gill,
1861.

The members of Lecithaster are widely distributed usually living in
marine fish but some have been reported from freshwater fish that
probably migrated from the sea. Species have been reported from
Canada, L. gibbosus, Boyce (1969); from the New England Coast of the
United States, L. confusus, Hunninen and Cable (1943); Florida, L.
acutus, Linton (1910), Manter (1947); Nile River, L. confusus, L.
gibbosus, L. stellatus, Looss (1907); England, L. gibbosus, Nicoll
(1907); European arctic, L. confusus, L. gibbosus, Odhner (1905);

Helminth Parasites 165

Figure 4. A larval acanthocephalan.

166 Bulletin So. Calif. Academy of Sciences

Black Sea, L. tauricus, Pigulewsky (1938); India, L. indicus, and L.
extralobatus, Srivastava (1935); South America, L. intermedius, Szidat
(1954); Hawaii, L. stellatus, Manter and Pritchard (1960); Australia,
L. testilobatus, Manter (1969); and Japan, L. stellatus, L. salmonis,
Yamaguti (1934), L. sayori (placed in synonymy with L. stellatus by
Manter and Pritchard, (1960) Yamaguti (1938).

King and Noble (1961) described a trematode related to the genus
Lecithaster from Gillichthys mirabilis collected at Morro Bay, Point
Mugu, and Goleta, California which they named Hysterolecitha trilo-
calis. We have not found this species in any of our collections. Manter
and van Cleave (1951) found a hemiurid trematode in the intestine of
Gillichthys mirabilis from the La Jolla, California area but it was too
immature to identify.

Several species of trematode metacercariae have been found from
time to time encysted in G. mirabilis tissues. About 43 % of this species
of fish from Baja California and Seal Beach had Renicola sp. encysted
in the liver. Stictodora (Parastictodora) hancocki were encysted in
tissues near the gills. The life cycle of this species was described by
Martin (1950). Occasionally, metacercariae of Ascocotyle sexidigita
were found encysted on the intestine. This species and part of its life
cycle were described by Martin and Steele (1970).

CESTODA

No adult cestodes were found in any of the G. mirabilis. However,
about 42% of these fish from Baja California and Seal Beach had larval
tetraphyllidean cestodes free in the lumen of the intestine and one, the
largest of all, was found in the gall bladder. These larvae probably use
small crustacea as intermediate hosts but apparently they will not
mature in this fish.

NEMATODA

About 62% of the fish from Baja California and the Seal Beach area
(but not from the other localities) harbored Vasorhabdochona cablei
in certain visceral blood vessels. This genus and species were described
by Martin and Zam (1967).

About 65% of the fish from Baja California, 40% of those from Seal
Beach and 15% from San Francisco Bay harbored Spirocamallanus
pereirai which was first described by Anneaux (1946) from smelt,
Atherinopsis californiensis Girard, collected at Bolinas Bay, Cali-
fornia. He placed the species in the genus Procamallanus. Olsen
(1952) erected the genus Spirocamallanus and transferred P. pereirai

Helminth Parasites 167

to it. Yamaguti (1961) listed Spirocamallanus as a synonym of
Procamallanus.

Noble and King (1960) examined 810 Gillichthys mirabilis collected
over a two-year period from Goleta slough near Santa Barbara, Cali-
fornia and found nearly 100% of them infected with Spirocamallanus
pereirai. They noted also. that changes in the salinity of the environ-
ment seemed to have no effect upon the fish or S. pereirai. They re-
ported that the following fish could also serve as definitive hosts for this
nematode: Leptocottus armatus, Fundulus parvipinnis, Atherinops
affinis, and Girella nigricans.

ABBREVIATIONS USED IN FIGURES 1-3

E=egg, ED=excretory bladder, GO= genital opening, GP= genital pore, HP=
hermaphroditic pouch, I=intestine, LT=left testis, O= ovary, OS=oral sucker,
P=pharynx, PC=prostate cell, PR=proboscis, RT=right testis, S=sperm,
SR=seminal receptacle, SV=seminal vesicle, U=uterus, V=vitellaria, VS=
ventral sucker.

All drawings made with the aid of a camera lucida except figure 3.

LITERATURE CITED

ANNEREAUX, R. F., 1946. A new nematode, Procamallanus pereirai, with a key to
the genus. Trans. Amer. Microsc. Soc. 65: 299-303.

Boyce, N. P. J., 1969. Parasite fauna of pink salmon (Oncorhynchus gorbuscha)
of the Bella Coola River, central British Columbia, during their early sea life.
J. Fish. Res. Bd. Canada 26: 813-820.

HUNNINEN, A. V. AND R. M. CaBLE, 1943. The life history of Lecithaster confusus
Odhner (Trematoda: Hemiuridae). J. Parasit. 29: 71-79.

Kina, R. E. AND E. R. NoBLE, 1961. A new species of Hysterolecitha (Trematoda:
Hemiuridae) from the mudsucker Gillichthys mirabilis Cooper. J. Parasit.
47: 465-468.

Linton, E., 1910. Helminth fauna of the Dry Tortugas. II. Trematodes. Carn. Inst.
Wash. Papers from the Tortugas Lab. 1V: 11-98.

MANTER, H. W., 1969. Some digenetic trematodes of marine fishes of New Cale-
donia. Part IV. Hemiuridae and Summary. Proc. Helm. Soc. Wash. 36: 194-
204.

MAnTER, H. W. AND M. H. PRITCHARD, 1960a. Some hemiurid trematodes from
Hawaiian fishes. Proc. Helm. Soc. Wash. 27: 87-102.

1960b. Additional hemiurid trematodes from Hawaiian fishes. Proc.
Helm. Soc. Wash. 27: 165-180.

MANTER, H. W. AND H. J. VAN CLEAVE, 1951. Some digenetic trematodes, including
eight new species, from marine fishes of La Jolla, Calif. Proc. U. S. Natl.
Mus. 101: 315-340.

168 Bulletin So. Calif. Academy of Sciences

Martin, W. E., 1950. Parastictodora hancocki n. gen. n. sp. Trematoda: Hetero-
phyidae), with observations on its life cycle. J. Parasit. 36: 360-370.

MartTIN, W. E. AND S. MULTANI, 1966. Microsentis wardae n.g., n. sp. (Acantho-
cephala) in the marine fish Gillichthys mirabilis Cooper. Trans. Amer.
Microsc. Soc. 85: 536-540.

MarTIN, W. E. AND D. F. STEELE, 1970. Ascocotyle sexidigita sp. n. (Trematoda:
Heterophyidae) with notes on its life cycle. Proc. Helm. Soc. Wash. 37: 101-
104.

MarTIN, W. E. AnD S. G. ZAM, 1967. Vasorhabdochona cablei, gen. et sp. n.
(Nematoda) from blood vessels of the marine fish, Gillichthys mirabilis
Cooper. J. Parasit. 53: 389-391.

NADAKAL, A. M., 1963. Observations on the pigmentation of Pallisentis sp.
(Pallisentidae: Acanthocephala), an intestinal parasite of the fish Ophio-
cephalus. Current Sci. 32: 220.

NIcoLL, W., 1907. A contribution towards a knowledge of the entozoa of British
marine fishes. Pt. I. Ann. Mag. Nat. Hist. ser 7, 19: 66-94.

NoBLE, E. R. AND R. E. KING, 1960. The ecology of the fish Gillichthys mirabilis
and one of its nematode parasites. J. Parasit. 46: 679-685.

ODHNER, T., 1905. Die Trematoden des arktischen Gebeites. Fauna Arctica 4: 291-
372.

OLSEN, L. S., 1952. Some nematodes parasitic in marine fishes. Publ. Inst. Mar.
Sci. U. Texas 11: 173-215.

PIGULEWSKY, S. W., 1938. Zur Revision der Parasiten-Gattung Lecithaster Lthe,
1901. Livr. Jubil. Prof. Travassos, 391-397.

SRIvASTAVA, H. D., 1935. New hemiurids (Trematoda) from Indian freshwater
fishes Part I. New distomes of the genus Lecithaster Ltihe, 1901, from
Clupea ilisha. Proc. Acad. Sci. India 4: 381-387.

SziwaT, L., 1954. Trematodes nuevos de pesces de aqua dulce de la Republica
Argentina. Rev. Inst. Nac. Inv. Cienc. Nat. Cienc. Zool. 3: 1-85.

YAMAGUTI, S., 1934. Studies on the helminth fauna of Japan. Part 2. Trematodes
of fishes, I. Jap. J. Zool. 5: 249-541.

1938. Studies on the helminth fauna of Japan Part 21. Trematodes of
fishes, IV. Kyoto, 139 pp.

1961. Systema Helminthum. Interscience Publishers, Inc. 3 (Nematodes),
1261 pp.

Accepted for publication March 20, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 169-175, 1970

ESTABLISHMENT OF NON-BREEDING
POPULATION OF MERCIERELLA ENIGMATICA
(ANNELIDA: POLYCHAETA) UPSTREAM FROM

A BREEDING POPULATION.

DALE STRAUGHAN

ABSTRACT: Salinity studies revealed that Mercierella were
surviving at salinities too low for the species to breed. The use
of a pollutant as a marker, showed that normal water currents
can disperse larvae upriver from a breeding population to
form a non-breeding population.

INTRODUCTION

In the distribution of sedentary estuarine species, one frequently finds
that the breeding population penetrates a certain distance along an
estuary and, beyond this, there is a fringe population, whose members
are often stunted and do not breed. It is usually assumed that these
latter individuals settled under a different salinity regime in the estuary.
For example, marine species penetrate further up an estuary during a
drought when there is a decrease in outflow from the estuary and a rise
in salinity (Straughan, 1967). Following return to “normal” conditions,
these individuals survive but do not reproduce. The reverse situation
occurs for freshwater species during an exceptionally wet period.
However, because the range of conditions over which these species can
survive is greater than that over which they can breed, it is possible
that the larvae may also be able to settle and survive over a wider range
of conditions than that, over which the adults breed.

In February 1961, a low tide survey of the North Pine River in
southern Queensland, Australia, revealed that Mercierella enigmatica
had such a fringe population in which the individuals were not breed-
ing. The fringe population was in rapidly flowing freshwater. Straughan
(1965) found that in the nearby Brisbane River, Mercierella tubes
disintergrate in rapidly flowing freshwater. Initially, it was decided to
study this population to determine why Mercierella was able to survive
in freshwater in the North Pine River and not in the Brisbane River.

Present address: Allan Hancock Foundation, University of Southern California,
Los Angeles, California 90007

169

170 Bulletin So. Calif. Academy of Sciences

During this study, effluents were released accidently from the settling
tanks at the Australian Paper Manufacturers Mill into the North Pine
River. This effluent was released at a point where breeding occurs in
the Mercierella population. Mercierella larvae are minute (Straughan,
1968), and while they swim using their prototroch, they are distributed
by water currents. Hence, the distribution of the A.P.M. effluent,
should provide some indication of the distribution of larvae from adults
breeding near the point where the effluent was released.

MATERIALS AND METHODS

The Pine River enters Moreton Bay (27°S latitude) a few miles north
of the Brisbane River. It is shallow, and at low tide, consists of a series
of deep holes separated by banks of small round rocks, up to 20 cms in
diameter. Tidal influence extents approximately 10 miles upriver.

Two pools (X and Y) at the upper limit of saline influence and near
the upper tidal limit were studied (Fig. 1). The tide does not enter the
upper pool Y on the neap tides but extends above it during spring tides.
The water level in pool X is affected by all high tides, about 1 hour
after predicted high tide at the river mouth. At low tide, pool X is
separated from the lower part of the river by rapids about 1 m high,
while a smaller set of rapids, about 30 cms high, separate pools X and
Y. There are further shallow rapids above pool Y. Pool X is shallow
with the depth at low tide averaging less than 1 m and reaching a maxi-
mum of 2 m. Pool Y has an average depth of 2 m and a maximum depth
of 6 m. The maximum width of pool X is 21 m and pool Y is twice as
wide.

The region is one of relatively dry winters and wet summers so that
salinities gradually rise during the winter months and fall abruptly with
the onset of summer storms. Summer storms usually commence in
September but in 1962 they did not commence until December.

Temperature and Salinity. Temperature and salinity readings were
recorded on transects A to M in pools X and Y using a temperature
compensated conductivity cell accurate to +0.1°/.o., (Hamon, 1956).
Readings were taken on high and low tides October 10, 1962 prior to
any summer storms, and on low tide December 10, 1962 after a summer
storm.

Dissolved Oxygen. The Winkler technique was used for surface and
bottom dissolved oxygen determinations at stations in December 1962.

Polychaete Ecology 171

RESULTS

Temperature and Salinity. Surface salinities were consistantly lower
than bottom salinities (Table 1). In pool X, surface salinities were
higher on high tides than on low tides but this was not always the case
in pool Y. In October, the lowest salinity recorded in pool X was
9.8°/oo and in pool Y was 7.8°/00. Following the December storm,
there was a surface layer of freshwater about 1 m deep in pools X and
Y. Salinities only approached pre-storm levels (20°/.. and above) at
depths of 9 feet or greater. Water temperatures were lower on the
surface than at a depth of 3 feet but generally fell again at greater
depths.

Dissolved Oxygen. No oxygen was detected in bottom water samples
at any stations. No oxygen was detected in the surface sample at A,
while low values, 2.0 to 2.4 p.p.m., were recorded in the surface
samples from the other 5 stations (D, F, G, I, J).

Pollution. Pollution occurred in September, 1962, as a result of an
escape of waste products from the A.P.M. Mill at Petri. This mill is
about two miles downriver from pool X. The polluting material was
mainly cellulose fiber with a little clay and small amounts of sulphate
ions and protein (information from A.P.M. chemists). This rotting
material produced hydrogen sulphide. The polluted material was
visible as a black sediment in the water. It was carried upriver on the
rising tide and settled out as the tide slackened. Some of this was
disturbed as the tide fell, but a black sediment remained on the bottom
of pool X and in the lower part of pool Y. The pollutant was diluted
rapidly in pool Y, so that half a mile upriver from the lower entrance,
no sediment was visible.

Distribution and Abundance of Mercierella. Mercierella was first
recorded from the mouth of the Pine River and as far as pool X in
October 1960 (Straughan, 1966). In February 1961, the Mercierella
population was sparce (<5/900 cm?) below the junction of the North
and South Pine Rivers, but further upriver, Mercierella was (20-
50/900 cm?). In these areas Mercierella occurred on the upper surface
of rocks from low water to a depth of about 46 cm (Straughan, 1968).
For the last mile before the upper limit of its range, Mercierella was
found in freshwater at low tide. Mercierella was common (20-50/900
cm2) on rocks below low water at the lower entrance to pools X and Y,
and on rocks in shallow areas throughout pool X.

Following the pollution, Mercierella was subjected to reduced
oxygen levels, high hydrogen sulphide concentrations, and polluted

172 Bulletin So. Calif. Academy of Sciences

rapids

200 0O ae

Scale in meters

Figure 1. Map of Pools X and Y on the North Pine River.

sediment. In October and December, 1962, adults were surviving under
these conditions, but no larval settlement occurred. In February, 1963,
no Mercierella remained in pools X and Y. In February 1965, the black
sediment was evident at low tide at the upper end of pool Y. No Mer-
cierella were found in the Pine River.

Temperature (°C) and salinity °/.o at transects A & M in pools X and Y

December

October

Salinity

Low Tide

Temp.

Low Tide
Salinity

Temp.

Salinity

High Tide
(ft) Temp.

Depth

Station

17.95

D3\3)9)

0.7-0.8

23.5
23.0-23.7

13.1-17.8
10.4-12.1

26.8-27.5
27.2-27.25

15.35-17.4
12.8-13.4

16.7

22.7-23.5

24.7-26.1
BS

13.6-14.2

27.6-27.9
D2)
D225

12.1-12.4

23.05-24.05

17.1
16.2
10.5

26.45

Polychaete Ecology

wW oO
to

0.5-0.6

0.6

23.1-23.3

DBRS
26.6
2

15.9
12.6-13.1
9.5-10.4

26.6
26.9-27.4
26.8-27.4

-1-10.5

'

al
moet
ANNA

Pict

21.85
9
6

-18.8

12.4-13.5

SUGGS
Soar
aaa

Va)
Sica
aa)
an
' '
POG
AAAAM
anaan

G

26.9-27.4
2

12 72187
8.6-12.0

12.1-12.6
13.1-13.3
10.6-12.1
16.4

28.4-28.6
26.3

9.3-11.7
16.5

a)
nN

6

25.9-27.4 1.7-3

22.8-23.5

12.9-14.0
9.9-12.6

26.9-27.4

13.2-14.3
10.7-11.0

foe)

0.3-0.0

27.6-28.1
27.1

F/B)

13.0
8.0-11.8

en
a)
NN

0.0

23.0

7.8-10.5

nN

cal
N

M

0.9

mn
al
NN

0

*This table is asummary of Table 58, Straughan, 1965.

174 Bulletin So. Calif. Academy of Sciences
DISCUSSION

While the advent of pollution terminated the study to determine how
Mercierella were able to survive in apparently freshwater conditions
in the North Pine River, it is tentatively suggested that these animals
were only exposed to freshwater conditions following storms. Dew
(personal communication) found that the rate of Mercierella tube
growth could be increased by adding calcium to the water. Bayly (1965)
noted the low amount of Ca++ in freshwater in the Brisbane River.
The North Pine River flows through areas of a similar geological
structure to the Brisbane River so that one would expect a similar
concentration of Ca++ in the freshwater. In the Brisbane River, it
took 4 to 9 weeks, and at times up to 18 weeks, for Mercierella tubes to
disintergrate (Straughan, 1965).

Adult Mercierella breed at water temperatures above 18°C (Straug-
han, 1965). Breeding commences in September or October and ceases
in May. All water temperatures in October and December 1962 were
above 20°C. There is no reason to suspect that water temperatures in
1962 were abnormally high. Therefore, breeding was apparently not
inhibited by low water temperatures. Straughan (1965) found that
Mercierella eggs develop at salinities above 7°/oo. Surface salinities
of 9°/.. and above were recorded in pools X and Y prior to summer
storms. After the onset of summer storms these areas are periodically
exposed to freshwater, as shown in December 1962. Between exposures
to freshwater, the salinity is unlikely to rise to the prestorm level.
During the breeding season, Mercierella in pools X and Y were exposed
to salinities too low to allow breeding, but not low enough for the
prolonged periods necessary to cause the tubes to disintergrate.

The distribution of the black sediment in pools X and Y correlated
closely with the distribution of Mercierella in the pools prior to pollu-
tion. The sediment extended further along pool B but there was no
rocky substrate in the area for Mercierella settlement. Therefore, it was
possible for Mercierella larvae to be carried passively upstream on the
rising tide into pools X and Y and not be washed downstream again by
the falling tide. This indicates that it is possible for Mercierella larvae
to penetrate further upriver than the breeding adults. Settlement and
survival is then dependant on factors such as salinity and substrate.
Hence, contrary to the common belief that upstream non-breeding
fringe populations of sedentary estuarine species are the result of
migration of free living larval stages associated with periodic changes
in salinity and water flow, the data presented here suggests that nor-

Polychaete Ecology LS

mal water currents also distribute larvae to form upstream fringe
populations.

ACKNOWLEDGEMENTS
Expenses were met by the University of Queensland Research Grants. I am
grateful to the late Oliver Wiseman for assistance with field work. The map was
drawn by Nancy Savage.

LITERATURE CITED

BAYLy, I. E. A., 1965. Ecological studies on the planktonic Copepoda of the
Brisbane River estuary with special reference to Gladioferens pectinatus
(Brady) (Calanoida). Aust. J. Mar. Freshwat. Res. 16: 315-350.

Hamon, B. V., 1956. A portable temperature-chlorinity bridge for estuarine
investigations and seawater analysis. J. Sci. Instrum. 33: 329-333.

STRAUGHAN, D., 1965. Studies on the Serpulidae of eastern Queensland and New
South Wales. Unpub. thesis Univ. Qd. 249 pp.

1966. Australian brackish water serpulids (Annelida Polychaeta). Rec.
Aust. Mus., 27: 139-146.

1967. Intertidal fouling in the Brisbane River, Queensland. Proc. Roy.
Soc. Qd. 79: 25-40.

1968. Ecological aspects of serpulid fouling. Aust. Nat. Hist. 16: 59-64.

Accepted for publication January 2, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 176-178, 1970

A SECOND SPECIES OF GERSTAECKERIA
(COLEOPTERA: CURCULIONIDAE: CRY PTORHY NCHINAE)
FROM MAINLAND SOUTH AMERICA

ELBERT L. SLEEPER
Department of Biology
California State College, Long Beach
Long Beach, California 90801

ABSTRACT: A second species of Gerstaeckeria is reported from
mainland South America. G. obrieni is described from Viche,
Esmeraldas Province, Ecuador, where it was encountered ina
sparse agriculture region beneath Opuntia bella. The type
locality is some 1400 km northwest of the previously known
South American range of the genus. Other species are known
from Peru, Galapagos Islands and Mexico.

INTRODUCTION

Originally this paper was submitted reporting the following described
species as the first record of this genus from mainland South America.
After submission, O’Brien’s paper (1969) reported G. peruana O’Brien
from Lachay, Peru. This paper was then withdrawn from press until it
was ascertained that the following species differed from peruana, and
subsequently was shortened so as to not repeat certain information in
O’Brien’s paper. The type locality of this species extends the known
range of the genus Gerstaeckeria northwestward on the mainland of
South America a distance of about 1400 km nearer the recorded range
of the major portion of the genus.

Gerstaeckeria obrieni, new species
Figures 1-4

Holotype: Male, Ecuador, Prov. Esmeraldas, Viche, VI-22-46, ELS
(ELSC No. 67). Length 3.5 mm, width 1.8 mm. Black, clothed with
sooty black and brown, pale brown and white scales.

Rostrum with carinae present nearly to apical fourth; basal two-
thirds sparsely clothed with black and brown scales, the apical third
glabrous with an occasional setae emerging from a puncture, moder-
ately coarsely, densely punctated throughout, punctures finer than on
prothoracic disc. Antennae reddish brown; club slightly less than 2x as
long as wide (3.3:1.8). Head moderately densely clothed with black
and brown and an occasional white scale; fovae between eyes very
shallow and, along with the punctures, concealed by scales. Prothorax
slightly wider than long (2.6:2.0) without evidence of a median carina;

176

New Species of Coleoptera 177

Figure I. Lateral view of Gerstaeckeria obrieni, holotype. Figure 2. Dorsal view
of same. Figure 3. Lateral view of aedeagus. Figure 4. Distal portion of aedeagus.
Scale: line equals 1.0 mm in Figs. 1-2.

moderately coarsely densely punctured (punctures coarser than on
rostrum and head, but much less coarse than those of the striae of
elytra); vestiture recumbent with only a scattered semierect scale;
clothed with black, brown and white scales with two white spots con-
densed in patches on the disc. Elytra with sides slightly inflated post-
humerally then gradually narrowing to apex; strial punctures large and
deep, but not as wide as the intervals; intervals feebly elevated, densely
clothed with recumbent black, brown and white scales; white scales for
the most part limited to white spots each side suture in basal third and a
conspicuous transverse stripe at declivity. Venter clothed with nar-
rower scales; the punctures of thoracic sterna coarse, of abdominal
sterna very fine fifth ventrite truncate apically. Legs clothed with
predominantly pale (mostly white) scales and setae; femora feebly
annulate; third tarsal segment much wider than second.

Allotype. Female, same data as holotype; length 4.5 mm, width 2.3

178 Bulletin So. Calif. Academy of Sciences

mm. Differing from the male only in the slightly longer rostrum and
slightly more convex first abdominal sternite.

Remarks. This species is extremely variable in form. It varies from
narrow-subparallel forms to forms more oval than the holotype. In most
the vestiture was recumbent, but in a few, somewhat suberect on elytra.
The holotype was selected as most representative of the population
examined in color, size, form and vestiture. No difference could be
found in the male genitalia or in any other constant morphological
feature.

Paratopotypes: 100 selected examples all same data as the holotype.
Size range 3.1-5.1 mm, width 1.5-2.7 mm, (mean length 3.6 mm, width
1.9 mm). Paratypes are placed in the following collections: American
Museum of Natural History; Dr. Horace Burke, Texas A&M; Cali-
fornia Academy of Sciences, San Francisco; California State College,
Long Beach; Los Angeles County Museum of Natural History, Los
Angeles; Dr. Charles W. O’Brien, Texas Tech. University, Lubbock;
The Ohio State University, Columbus, Ohio; and the United States -
National Museum.

This species was taken from the base and under debris beneath
Opuntia bella. The region is rather on the arid side, with sparse farming
and considerable grazing. Many specimens were taken from cacti in
fence rows or in abandoned fields. None were encountered beneath
cow dung or rocks.

This species is very unlike any of the members of the genus known
from South America (Peru, O’Brien, 1969) or the Galapagos Islands
(Van Dyke 1955). From G. peruana O’Brien, it can be readily distin-
guished by its darker more recumbent vestiture (peruana has the
vestiture pale brown and erect on the elytra; in obrieni it appears mostly
black and recumbent). From galapagoensis ssp. it can be readily
separated by the much larger size of the latter (smallest galapagoensis
examined 6.0 mm) more densely punctured prothorax, and prostrate,
broader scales on elytra.

It is with great pleasure I name this species in honor of Charles W.
O’Brien who has worked so diligently on the species of America north
of Mexico and who first recorded Gerstaeckeria from South America
(O’Brien, 1969).

LITERATURE CITED

O'BRIEN, C. W. 1969. A new species of Gerstaeckeria in Peru, first record for
South America (Coleoptera, Curculionidae). Coleopterists’ Bull., 23: 73-76.

VAN Dyke, E. C. 1955. The Coleoptera of the Galapagos Islands. Occ. Papers,
Calif. Acad. Sci., 22, 181 pp.

Accepted for publication June 5, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 179-181, 1970
RESEARCH NOTES

NOTES ON THE ASSOCIATION BETWEEN
HYPEROCHE MEDUSARUM A. AGASSIZ
(AMPHIPODA, HYPERIIDEA) AND THE CTENOPHORE,
PLEUROBRACHIA BACHEI (MULLER)

INTRODUCTION

Biologists have long recognized the association between certain hyperiid
amphipods and various other pelagic animals. Hyperoche medusarum
has been collected living with Aurelia aurita as reported by Stephensen
(1923) and Schellenberg (1942). It has also been noted to be associated
with Cyanea capillata and Tima formosa (Bowman et al., 1963). Associ-
ations between this amphipod and ctenophores have also been reported
by two authors. Stephensen observed H. medusarum in Beroe,
and Schellenberg examined an unspecified ctenophore housing the
amphipod.

During the spring of 1969 some of this author’s students discovered
specimens of the cydippid ctenophore, Pleurobrachia bachei, inhabited
by H. medusarum. After being led to some cognate literature through
personal correspondence with Dr. Thomas E. Bowman of the Smith-
sonian Institution, and with the welcome help of Mr. Robert Cimberg
of the University of Southern California, Department of Biology, it was
determined that the relationship was undescribed. The purpose of this
paper is to report the above mentioned association and present a few
descriptive notes.

DISCUSSION

Specimens of P. bachei, collected from the coastal waters off northern
California and preserved in 10% formalin solution, were examined for
the presence of H. medusarum.

A total of 135 ctenophores has been examined to date, 20 of which
housed amphipods. Four of those 20 animals were inhabited by two
amphipods each making a total of 24 H. medusarum collected. Twenty-
one of the amphipods were juveniles, ranging from 0.75 mm to 1.5 mm
in length. Three adults were examined, one male (2.5 mm), and two
females (2.75 and 3.0 mm). The smaller of the two females was carrying
ova in the brood pouch.

179

180 Bulletin So. Calif. Academy of Sciences

Figure 1: A dissected Pleurobrachia bachei showing the positions of the gut,
tentacular sheath, and a (2.75 mm) female Hyperoche medusarum imbedded in
the mesenchyme. This female was carrying eggs. Some of the amphipod’s appen-
dages are not included in the drawing.

Figure 2: An external view of a portion of the ctenophore near the mouth; show-
ing the head of a male Hyperoche medusarum protruding from an orifice in the
body wall of the host.

Amphipod and Ctenophore Association 181

All of the specimens examined were imbedded in the mesenchyme of
the ctenophores and were never very closely associated with organs
such as the tentacular sheaths or gut. In all cases save one, there appeared
to be no direct communication between the position of the amphipods
and the outside, that is, the amphipods were completely encased within
the host. Figure 1 illustrates one of the adult females inside the cteno-
phore. There did not seem to be any particular spot or spatial orienta-
tion preferred by the amphipods, as they were found in various parts of
the hosts’ bodies. The single adult male had the anterior part of its head,
including the antennae stuck out of the host’s body through a hole.
Figure 2 shows how precisely the head fit the aperture which indicates
that the animal must have formed the opening itself, but the significance
of the hole is unclear.

Any statements regarding the nature of the relationship between
P. bachei and H. medusarum are, at this point, purely speculative. It
appears that most of the amphipods enter the host as juveniles and that
they feed upon the mesenchymal contents of the ctenophore. Some
reach maturity within the host and ova production apparently occurs
there. H. medusarum is known to be free living as well as being associ-
ated with a number of pelagic animals. The adaptations as regards
feeding and reproduction are not completely known. Further study with
live animals will hopefully provide some information along this line.

LITERATURE CITED

BowMan, T., C. MEYERS, AND S. Hicks. 1963. Notes on associations between
hyperiid amphipods and medusae in Chesapeake and Narragansett Bays and
the Niantic River. Chesapeake Sci. 4: 141-146.

SCHELLENBERG, A. 1942. Die Tierwelt Deutschlands 40. IV: 243.

STEPHENSEN, K. 1923. The Danish Ingolf Expedition, Vol. II, Part 8, Crustacea
Malacostraca V. (Amphipoda I). Direction of the Zoological Museum of the
Univ. of Copenhagen. 15.

Gary J. Brusca, Department of Biology, Humboldt State College,
Arcata, California 95521

Accepted for publication May 14, 1970.

Bull. So. Calif. Acad. Sci. 69(3-4): 182, 1970

AN UNUSUAL PINNA ANOMALY IN NEOTOMA LEPIDA

The large pinnae of wood rats are frequently scarred or torn but to our
knowledge, no congenital malformations have been reported. On July
15, 1968, at a location 5 mi. east of El Rosario, Baja California del
Norte, Mexico, we captured a male Neotoma lepida with both pinnae
split anterior to the mid-line in a proximal-distal direction, giving
the animal an antlered appearance (see Figure 1). The right and left
anterior portions are symmetrical, as are the posterior. Close examina-
tion of the margins of the “split” reveals no evidence of scar tissue and
the symmetry of the pinnae precludes an accident as the cause of this
anomaly. If this is a somatic mutation, it is interesting to speculate at
what stage of development this occurred; certainly it must have been
very early in embryonic development before the symmetry of the head
was established. The possibility of a genetic mutation cannot be
eliminated, but we have not observed this condition in any of the other
woodrats from this area.

We wish to acknowledge the aid of Miss Patricia Ley and Mr. Dennis
Roberts in the field and Mr. Stan Williams for the photographic work.

Figure I. Anterior view of left and right pinnae of Neotoma lepida.

Ross E. Dingman, Dept. of Biology, University of San Diego, San
Diego, Calif. 92110; and Dennis Bostic, Palomar College, San Marcos,
Calif. 92069.

Accepted for publication December 16, 1969.

182

Bull. So. Calif. Acad. Sci. 69(3-4): 183-189, 1970

A PRELIMINARY REPORT ON A MIOCENE FLORA FROM
THE BARSTOW FORMATION, BARSTOW, CALIFORNIA

INTRODUCTION

The Barstow Formation of Miocene age consists chiefly of lacustrine
and fluviatile rocks. A rich vertebrate fauna has received much atten-
tion since the work of Merriam (1911). Lewis (1964) reviewed the
nomenclature and discussed the fauna. Sheppard and Gude (1969) have
made a comprehensive study of the rocks. Nowhere in these reports is
there mention of the flora. It is the purpose of this paper, therefore, to
make a preliminary report on the petrified wood and fossil leaves that
have recently been found.

My sincere thanks are extended to Robin Leggewie and the many
Webb School boys and masters who have participated in the field trips
to the Barstow area; to the United States Department of the Interior for
permits to carry on the research; to Dr. and Mrs. L. H. Daugherty for
studying the petrified wood; to Dr. D. I. Axelrod for visiting the
localities; to Mrs. Ruth Kirkby for consultations about the leaves; and
to Dr. D. A. Guthrie for criticizing this manuscript.

Location

The petrified wood has been found in the N.E. 4 of sect. 29, R. 1 W.,
T. 11 N., Opal Mountain Quadrangle, San Bernardino Co., California,
and in the N.E. %4 sect. 29, R. 1 W., T. 11 N., Lane Mountain Quad-
rangle, San Bernardino Co., California. The fossil leaves are found in
the western part of Rainbow Basin in the S.W. /% of sect. 24, R. 1 W.,
T. il N., Opal Mountain Quadrangle, San Bernardino Co., California.

Petrified Wood

One of the most conspicuous features of the stratigraphy of the Barstow
Formation is the Sky Line Tuff, mostly white in color characterized by
blocky and conchoidal fractures. At the above mentioned locality the
thickness is about three feet and scattered throughout are fragments of
petrified wood ranging in size from small twigs to small fragments two
inches in diameter.

In thin section the cellular structure shows clearly. From the small
tracheids, bands of parenchyma, and rather large interstitial spaces one
specimen is undoubtedly a small juniper (Fig. | a). Several other
specimens (Figs. 1 b, 2 a, c) show porous ring wood that resembles
poison oak (Rhus). Though preservation is poor, one specimen seems

183

184 Bulletin So. Calif. Academy of Sciences

Figure 1. Thin Sections
Ceanothus ?

GORE
gh AA Cet
as eee

> :
* Fae £

LEED mc Fk

of petrified wood, all 40x. a. Juniperus sp. b. Rhus

Miocene Fossils 185

Figure 2. Thin Sections of petrified wood, all 40x. a. and c. Rhus ? b. Unknown
shrub.

186 Bulletin So. Calif. Academy of Sciences

GEER pe

Figure 3. a. Portion of a palm frond b. and c. Unidentified leaves d. Quercus sp.,
similar to QO convexa.

Miocene Fossils

Figure 4. a. Quercus sp., similar to Q. dayana b. Quercus sp. c. Quercus sp.

187

188 Bulletin So. Calif. Academy of Sciences

similar to certain species of Ceanothus (Fig. 1 c) in the arrangement of
vessels in radial rows. Fig. 2 b is of an unknown shrub.

Fossil Leaves

At the fossil leaves locality there is a conspicuous outcrop of lacustrine
deposits of siltstones, mudstones, and calcareous mudstones in which
there are layers of floral debris. Most of this is unidentifiable, but
occasionally a leaf impression may be found that is clear enough for
identification.

Fig. 3 a shows a portion of a palm frond. Fig. 3 b and Fig. 3 c. show
small leaves that have not been identified. There seem to be several
species of oak. Fig. 3 d has been identified as Quercus similar to Q.
convexa and Fig. 4 a has been identified as Quercus similar to Q.
dayana. Fig. 4 b and Fig. 4 c. seem to be other variations of Quercus.

In addition to the leaves there are a number of seeds and a few
structures that resemble acorn cups.

In summary the flora seems to indicate a chaparral-like condition,
and it is hoped that others will continue the work better to under-
stand the ecological conditions of upper Miocene times in Southern
California.

LITERATURE CITED

Lewis, G. E. 1964. Miocene Vertebrates of the Barstow Formation in Southern
California. Art. 125, U.S. Geol. Prof. Paper 475-D, pp. D18-D23.

MERRIAM, J. C. 1911. A Collection of Mammalian Remains from the Tertiary
Beds on the Mohave Desert. Calif. Univ. Dept. Geol. Sci. Bull., 6: 167-169.

SHEPPARD, R. A., AND GUDE, III. 1969. Diagenesis of Tuffs in the Barstow Forma-
tion, Mud Hills, San Bernardino, California. U.S. Geol. Survey Prof.
Paper 634.

Raymond M. Alf, Webb School of California, Claremont, California
91711

Accepted for publication April 7, 1970.

SOUTHERN CALIFORNIA ACADEMY OF SCIENCES
VOLUME 69, 1970

SUBJECT AND AUTHOR INDEX

PN COMING Soe Gea se sare 100
Acarina, new species ......... 32, 66
A late pliocene macrofossil fauna

of Newport Beach, Orange

County, California........... 121
Alf, Raymond M. ............. 183
Alternation of Neural spine height

in certain early permian Tetra-

JOOGIS:’ * 6s. bie: Sraaemteee eet cenerar ara 80
Amphibian fossils ............ 80
Animal behavior .......... 43, 60
Ancinus seticomvus, n.sp. (Iso-

poda), from Santa Barbara,

@alhiformiaie tae ese Sse nas ee 145

Ancinus seticomvus, new species .. 145

A note on the Hydroid Dipurena
reesi vannucci and a medusae of
the genus Cladonema collected
together near Los Angeles .... 112

A new spionid (Annelida: Poly-
chaeta) from the Gulf of Cali-

NOMA es ics. Soest x 2 uoe Bs 74
A new subgenus and two new spe-
cies of MHexidionis (Acarina,
Trombiculidae) from North
PNIMCTICA MM ii ok bl oleae & 52

An unusual pinna anomaly in
Neotomalepida............. 182

A preliminary report on a Miocene
flora from the Barstow forma-

tion, Barstow, California ...... 183
Arisocerus, new genus ......... 32
Aristocerus [sic] amapensis ... 32
A second species of Gerstaeckeria

(Coleoptera: Curculionidae:

Cryptorhynchinae) from main-

land South America ......... 176

A small collection of chiggers from
Surinam (Acarina: Trombiculi-
dae)

A survey of meta 20 au parasites
infecting the California (Zalo-
phus califorianus) and _steller

(Eumetopias jubatus) sea lion .. 126

YAWES im pines era eae eee cus ces 60
| BY eee Ady ee gsc SN SEITE BORE cnt cr 115
Bonde S ilies cn esmieee es ae seer 117
Boshellia hirsuta ............. 101
Brennan, J. M:. .......:-. 32, 100
Brusca Gaya ere 179
BullivantsJa See ee 112
GallisoniG. Wane ones 20
Cambrian fossils .............. 20
Captorhinus aguti ............. 80
CHIGSETS AT Ae eae teres cree 100

Chiggers, new species .. . 32, 53, 56, 66

Cladonema radiatum ......... 112
Coleoptera, new species ...... 38, 39
GollhinS Goce eee es ee ere he eee 60

Communication systems and orga-
nizational systems in three spe-
CLESmOfenodentsie eae 43

@ounchesne yr Agee eee 60
Dailey, Murray D. ........... 126
DPanforthiGlGs, Gasca ones DY
Dendrocopos albolarvatus gravi-
KOSURUS anne nce setae ee 60
Dingman, Ross E. ............ 182
IDIDURCHGR CESIUM he eee 112
Epicaridea (Isopoda) of Hawaii .. 27
Establishment of non-breeding
population of Mercierella enig-
matica (Annelida: Polychaeta)
upstream from a breeding popu-
latiO nines cee Soe eee eens 169
islerGe Be ee on eee 43
Four species of Microtrombicula
(Acarina: Trombiculidae) from
Mexico and Nicaragua ....... 133

Gerstaeckeria obrieni, new species 176

189

Halosydna_brevisetosa
H. Johnsoni
Hannemania anurae, new species 66
H. monticola, new species ...... 68

ETS NC Ol a el Pen ars Aone ioe ced ess Fil
ill eBay Mes aes eos eae ete eas 126
Pet Ne Tee A ei he et cree ee 87
ly dnOZ Gay Rants ep ae eee 112
JE OVICITIS sea ha ea eae per ien pSnee eta 1
ENIGOIIS WECUITC .o6056005006600 10

Hylaeus incomitatus, new species. 18
Hylaeus (Nesoprosopis) boninensis

Spa EN eat Soa a aE nee ea canta erase Ye 14
livimenoOptenae narra ae l
Hymenoptera, new species 5, 18
MSE CIS eas tre ds se oe eae I
Insects, new species .......... Sls
fonella murchisoni, new species .. 27
Isopoda, new species .......... 7
Vomess olga ee aie yelsl en eae ee ale 150
Koch eRe ES ais ets moat tase 60
ILASTUTNS CBE oooccs0cvecccbdoc 115
Doh tee Wasi sete teens iene fare 74
Loomis, Richard B. ... 52, 65, 133
EU CaS pe MIG ie reel Fac cohen Sse SZ
Lwebuga-Mukasa, Jamson ...... 154
IMIENTNVOT EN: ts arse oie peaee ts. widts ia sc one 115
Martina Wor wc teeara- anew Siac 161
IVITCL OTN GLC eee 41
Micromyrmex convexipennis, new

combination sea 42
Microtrombicula nicaragual, new

SIDE CIESH a2 sunray eiih yada ames ons 133
Microtrombicula_ paralios, new

SPECIES Ei Gemeente: 135
Microtrombicua_ phyodactyi,

MC WAS DCCICS He ir rn near 137
Miultanite Syeda erence 161
Myrmex setosis, new species ... 39
Myrmex vandykei, new species .. 38
INIGHY SMS Golocccbaseboosooce 32
New Myrmecinae (Coleoptera:

Curculionidae) ............. 38
INEwSPeCiesse ae ea liSs Dil Die

32, 38, 39, 53, 56, 66, 68, 74, 133,
135, 137, 145, 176.

Notes on the association between
Hyperoche medusarum A.
Agassiz (Amphipoda, Hyper-
iidea) and the ctenophore, Pleu-
robrachia bachei (Miller) .... 179

Occurrence of a holotrichous cipi-
ate in the intestine of the poly-
chaete Hermodice Carunculata

OfsRuertosRico}ae eee 150
Renmian Eossilsiesee eee 80
Polydora wobberi, new species... 74
Polychaete, new species ........ 74
Poly chaetelsetaci ss -es ae ire 87
Reish; Di Je) £232. ke eee 87
Reptile s..0. 00s eee 118
Revival of the monotypic Genus

Boshella Ewing, 1950 (Aearina:

Trombiculidae) ............ 100
Rodents 4.5: 325 5c eee 43
Rodrigues, Irma Rivera ........ 150
Sexual differences in foraging be-

havior of white-headed wood-

peckers | 20.2). Ve Sein 60
Sleeper, Elibert ae 38, 176
Snakes. eae 118
Snelling RY Res) ae 1
Some helminths of the mudsucker

fish, Gillichthys mirabilis

Cooper os so he eee 161
Soule; J.-D) 2... eee 104
Straughn; Dale {ee 169
Tantilla brevicauda ........... 118
Tantilla brevicauda: an addition

to the snake fauna of Guate-

mala, with comments on its

relationships) 4.95 118
Teeth oe eS ee 104

The Effect of Temperature on the
setal characteristics in Polynoi-
dae (Annelida: Polychaeta) ... 87

The Hylaeus of the Bonin Islands
western Pacific Ocean

The organic matrix in Developing

190

dental enamel and dentin studied Cambrian) of western South

by Scanning Electron Micro- Dakota se eee 5 ane ate 20

SCOPV MIME nts fis cies hoe es ABS 104) “atraske Mihomas.: - sree oes nein ee 145
The role of elytra in the movement TIO DITES eee ree ce ee eee 20

of water over the surface of Trilobites, new species ......... 21

Halosydna brevisetosa (Poly-

chaeta: Polynoidae).......... 154 Watishinnibo PR: tales cee 80)
The status of the Southern Yellow Vercammen-Grandjean, P.H. ... 100

Bat in California ............ 115

Three species of Hannemania

(Acarma, Trombiculidae) from Webb, James |p. J cy eae 133

Amphibians of western Mexico Welbourn, W. Cc: sl fi Ra eee green oe ae 65

re 65 Wilson baiD i ae is LS
Trace fossils of Trilobites from the

Deadwood Formation (Upper Zinsmeister, William J. ........ 121

With sad regrets we announce the death of DR. JOHN ADAMS
COMSTOCK, December 25, 1970.

It is of interest to note that during his 50 years of membership in the
Academy, Dr. Comstock was elected to every office of the organization,
including Editor of the Bulletin, a position he held for 40 years (1921-
1961).

Those wishing to make a contribution in his memory to the Academy’s
Memorial Fund (a special publications fund) may do so by addressing
their contributions to Russell E. Belous, Treasurer, c/o Los Angeles
County Museum of Natural History (payable to So. California Academy
of Sciences).

19]

1MMmOoOO0O

Q)

STATEMENT OF OWNERSHIP AND MANAGEMENT

. Date of filing: September 28,1970.

. Title of publication: Bulletin of the Southern California Academy of Sciences.
. Frequency of issue: Quarterly — March, June, September, December.

. Location of known office of publication: 900 W. Exposition Blvd., Los An-

geles, California, 90007.

. Location of Headquarters: Same.
. Publisher: Southern California Academy of Sciences.

Editor: Donald J. Reish, Department of Biology, California State College at
Long Beach, Long Beach, California, 90804.

Managing Editor: Robert J. Lavenberg, 900 W. Exposition Blvd., Los Angeles,
California, 90007.

Owner: Southern California Academy of Sciences — A non-profit Corpora-
tion.

. Known bondholders, Montgages, and other security holders: None.

For completion for non-profit organization authorized to mail at special rates;
the purpose, which function, and non-profit status of this organization and
the exempt status for federal income tax purposes have not changed during
the proceding 12 months.

Average no.
copies each
issue during Single issue —
preceding 12 nearest to
months filing date
. Total No. copies printed 750 750
. Paid circulation
1. Sales through dealers and carriers, 6 0
street vendors and counter sales
2. Mail subscriptions 409 395
. Total paid subscriptions 415 395
. Free distribution 100 100
. Total distribution 515 495
. Office use, left over, unaccounted,
spoiled after printing 235 DS)5)
. Total 750 750

92

Southern California
Academy of Sciences

OFFICERS OF THE ACADEMY
BOARD OF DIRECTORS

PALE AIS MPEM VASUPIGI C118 chs cine) em ielern 6 Sie aklele Btnee a ieinieisisesd ce sé President
PMT WEIES PATROL. ye witcha tees c coolels Ws teeleia' so seers cae tes First Vice President
PRMEPERESICEDEE Fac. <5 ale cfelaja'sieis 0 ee os)cleleievarsters's ois 6 Second Vice President
PO ler CSM MIROZAITC 5c epee a clnioteer es ise eis, «Tastee Sia Sele wists sal dies Secretary
a bs8E 1 3, BEIT” 5 GARR SER Dele Ae le Ces Sea mS Treasurer
NCAT AL CIMIPMIN CISL see, st cele, « fopcharoreRHee at atar ees sorte abe vei eke Gals egies. ibveue ee Editor
Berets AVEMDELP, 6.5. coe eee scitivine cc ns cue cccieines Managing Editor
John J. Baird Jules Crane, Jr. J. R. MacDonald

Bayard H. Brattstrom John E. Fitch John L. Mohr

Donald B. Bright Takashi Hoshizaki John D. Soule

ADVISORY BOARD

The advisory board automatically consists of the past presidents of the society:
John A. Comstock, Theodore Downs, Hildegard Howard, Richard B. Loomis,
Jay M. Savage, Kenneth E. Stager, Richard H. Swift, Fred S. Truxal, Louis C.
Wheeler, John A. White, Sherwin F. Wood.

COMMITTEES

AAAS Award Library
Jules Crane, Jr., Chairman Betty Begun, Chairman

Annual Meeting Membership and Publicity
Jules Crane, Takashi Hoshizaki, Charles Rozaire, Chairman
Stuart Warter Nominating

Executive Committee Russell E. Belous, Chairman
John L. Mohr and Fred S. Truxal Program

Fellows Louis C. Wheeler, Chairman
Fred S. Truxal, Chairman Publications

Finances John E. Fitch, Chairman

Russell E, Belous, Chairman

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