Swimming Sea Cucumbers
(Echinodermata: Holothuroidea): ©
A Survey, with Analysis of
Swimming Behavior

in Four Bathyal Species

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SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES + NUMBER 35

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SMILHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES e NUMBER 35

Swimming Sea Cucumbers
(Echinodermata: Holothuroidea):
A Survey, with Analysis of
Swimming Behavior
in Four Bathyal Species

John E. Miller and David L. Pawson

HSONIAN INSTITUTION

SMITHSONIAN INSTITUTION PRESS
Washington, D.C.
1990

ABSTRACT

Miller, John E., and David L. Pawson. Swimming Sea Cucumbers (Echinodermata:
Holothuroidea): A Survey, with Analysis of Swimming Behavior in Four Bathyal Species.
Smithsonian Contributions to the Marine Sciences, number 35, 18 pages, 4 figures, 1990.—New
information on swimming behavior of four species of deep-sea holothurians has been obtained
using the research submersibles Johnson-Sea-Link (Harbor Branch Oceanographic Institution)
and Pisces V (University of Hawaii, HURL Program). Hansenothuria benti Miller and Pawson
and Enypniastes eximia Theel were studied off the Bahama Islands, Paelopatides retifer Fisher
off the Hawaiian Islands, and Pelagothuria natatrix Ludwig off the Galapagos Islands. Video
recordings were made of swimming behavior, and individuals of all species were collected at the
time of observation. Four contrasting life modes are represented: H. benti lives and feeds on the
seafloor, but when disturbed it can swim vigorously for several minutes by rapidly flexing the
anterior and posterior ends of the body into S curves. Enypniastes eximia swims almost
continuously, briefly settling to the seafloor to ingest surface sediments. The bulbous body is
propelled upwards by rhythmic pulsation of a webbed anterodorsal veil; stability during
swimming is maintained by counteractive flexing of posterolateral veils. Paelopatides retifer
lives on or near the seafloor and has been found up to 300 meters above the seafloor. The
swimming behavior of this species combines locomotory movements of the two preceding
species. An anterior veil pulsates, and the posterior half of the body flexes into S curves.
Pelagothuria natatrix is truly pelagic, floating or drifting near the seafloor or high in the water
column. Swimming is effected by infrequent and irregular pulsation of an enormous anterior
veil. There is no evidence to suggest that P. natatrix descends to feed on the seafloor.

Published data on the approximately 25 known species of swimming holothurians are
summarized. Probable reasons for swimming behavior are discussed. Swimming appears to be
most useful in predator avoidance, escape from physical hazards, locomotion, seeking out
suitable substrata for feeding, and dispersal of juveniles or adults.

OFFICIAL PUBLICATION DATE is handstamped in a limited number of initial copies and is
recorded in the Institution’s annual report, Smithsonian Year. SERIES COVER DESIGN: Seascape
along the Atlantic coast of eastern North America.

Library of Congress Cataloging-in-Publication Data

Miller, John E.

Swimming sea cucumbers (Echinodermata, Holothuroidea) : a survey, with analysis of swimming behavior in four

bathyal species / John E. Miller and David L. Pawson.

p. cm.—(Smithsonian contributions to the marine sciences ; no. 35)

Includes bibliographical references.

Supt. of Docs. no.: SI 1.41:35

1. Holothurians—Behavior. 2. Holothurians—Locomotion. I. Pawson, David L. (David Leo), 1938-.
II. Title. III. Series.

QL384.H7M55 1990 89-600398

593.9’6-dc20 CIP

Contents

Page

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ill

Swimming Sea Cucumbers
(Echinodermata: Holothuroidea):
A Survey, with Analysis of
Swimming Behavior
in Four Bathyal Species

John E. Miller
and David L. Pawson

Introduction

Holothurians have long been known to comprise an
important component of the deep-sea fauna (Théel, 1882). In
extensive areas they comprise up to 95% of the megafaunal
biomass, and they are abundant even at hadal depths (Heezen
and Hollister, 1971). The numerous epibenthic species are
mobile, and they are capable of ingesting and reworking
copious quantities of surface sediments; accordingly, the
holothurians are important reworkers of soft bottom habitats.

The ability of some sea cucumber species to leave the seabed
and venture upwards into the water column has been
documented numerous times over the 120 years since the first
report (Sars, 1867) of swimming in Bathyplotes natans Sars.
Although at least six shallow-water species have been reported
to swim, the true natatorial acrobats among the class
Holothuroidea are deep-sea species of the orders Aspidochi-
rotida and Elasipodida. Approximately 20 species in the
families Synallactidae, Psychropotidae, Elpidiidae, and
Pelagothuriidae have been captured or observed near the
bottom or at depths several hundred to several thousand meters
above the seafloor. A few deep-sea species have even been
found in surface waters.

Species that are capable of active swimming movements are
also the dominant megafaunal element at some localities in the
bathyal-abyssal zone. In general, holothurians that can swim
descend to the seabed to feed, and some species can transport

John E. Miller, Division of Marine Sciences, Harbor Branch
Oceanographic Institution, 5600 Old Dixie Highway, Fort Pierce,
Florida 34946. David L. Pawson, Department of Invertebrate
Zoology, National Museum of Natural History, Smithsonian institu-
tion, Washington, D.C. 20560.

surface sediments for considerable distances, both horizontally
and vertically, from the source area (Billett et al., 1985; Billett,
1986).

Several bathyal and abyssal species possess conspicuous
external features that appear to be morphological adaptations
for swimming, but they have not yet been captured or observed
in the water column. Pawson (1976) suggested that as many as
one-half of the approximately 110 species in the order
Elasipodida might be capable of swimming activity.

In past studies, very few species of deep-sea holothurians
had been observed to swim. Pérés (1965), reporting on
observations from the submersible Archimede in the Puerto
Rico Trench, mentioned a Benthodytes-like species swimming,
and Barnes et al. (1976) recorded the swimming behavior of
Peniagone diaphana from the submersibles Turtle and Seacliff
off Southern California. Pawson (1976, 1982) provided several
anecdotal notes on swimming in abyssal species from Alvin
dives in the Tongue of the Ocean, Bahamas, and on the
continental slope off the eastern USA. Otsuka (1987) reported
his observations on swimming in Enypniastes eximia from the
submersible Shinkai 2000 in the Suruga Trough, Japan.
Additional information on deep-water swimmers has been
compiled through chance collections in plankton nets (Hansen,
1975; Billett et al., 1985) and through deep-sea photography
(Ohta, 1983, 1985). Recently, Pawson and Foell (1986) based
the description of a new benthopelagic species, Peniagone
leander, solely on remotely collected photographs and vid-
eotapes of the holothurian.

With advances in the technology of manned submersibles
over the past 10-12 years, it is now possible to observe and
record in situ the swimming behavior of bathyal and abyssal

2

holothurians. In this paper, we describe the swimming activity
of four deep-sea species, Hansenothuria benti Miller and
Pawson, Enypniastes eximia Théel, Paelopatides retifer Fisher,
and Pelagothuria natatrix Ludwig, as analyzed through video
tapes made during submersible dives. In addition, a survey of
published accounts of swimming holothurians is included.

ACKNOWLEDGMENTS.—We thank our colleagues in the
Bahama Islands submersible project, Gordon Hendler (Los
Angeles County Museum of Natural History) and Porter M.
Kier (retired; formerly of National Museum of Natural History,
Smithsonian Institution) for their many contributions to the
swimming holothurian study over the past five years. Numer-
ous other researchers generously supplied us with information
and data. Video footage, photographs, or- specimens of
holothurians were kindly provided by the following individu-
als: R. Appeldoorn, B. Cutress (University of Puerto Rico): E.
Armstrong, L. Cameron, R. Harbison, S. Pomponi, C. Young,
M. Youngbluth (Harbor Branch Oceanographic Institution—
HBOJ); A. Carey (Oregon State University); I. MacDonald
(Texas A&M University); W. Nelson (National Marine
Fisheries Service, Mississippi). Funds to conduct submersible
dives were granted through the following organizations
(principal investigators in parentheses): HBOI (R. Harbison, J.
Miller, S. Pomponi, C. Young); National Cancer Institute (S.
Pomponi); National Oceanic and Atmospheric Administration/
National Undersea Research Program (R. Appeldoorn, L.
Cameron, I. MacDonald, W. Nelson, C. Young, M. Young-
bluth); National Science Foundation (L. Cameron, R. Harbison,
C. Young); Smithsonian Institution (J. Miller, D. Pawson).

We are grateful to the crews of the Johnson-Sea-Link
submersibles (JSL) and the research vessels Johnson, Seward
Johnson, and Edwin Link for their dedicated efforts on our
behalf. Constructive comments by G. Hendler (Los Angeles
County Museum of Natural History) and S.D. Cairns (National
Museum of Natural History, Smithsonian Institution) greatly
improved the text. Photographic assistance in construction of
figures was provided by T. Smoyer (HBOI). This paper is
HBOI Contribution No. 715 and Smithsonian Institution
Marine Station at Link Port Contribution No. 248. Contribution
No. 15—Studies on bathyal echinoderms of the Bahama
Islands, J. Miller (HBOI) Principal Investigator.

Methods

In situ observations, still and video photography, and
collection of live specimens of Hansenothuria benti, Enypnias-
tes eximia, and Pelagothuria natatrix were accomplished using
the research submersibles Johnson-Sea-Link I and IT. The JSL
submersibles permit four occupants to work at depths to 914 m
for 6-8 hrs in a 24-hour period. An externally mounted, Marine
Optical Systems color video camera (MOS 3000-Z) and a Sony
(BVU-50) 3/4” video recorder were used to tape swimming
sequences. Seafloor photographs (Figure la,c,d) were made
using a repackaged Benthos camera system (Model 372) with

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

an 85 mm Olympus lens and a 200-watt-second strobe (Model
383) with a modified reflector for telephoto photography. To
assure proper subject framing and camera-to-subject distance,
a helium-neon laser aiming system (HBOI, see Caimi and
Tusting, 1987) was used in conjunction with the camera
system. Additional information on the JSL submersibles can be
found in Askew (1984).

Data on swimming in Paelopatides retifer, including still
photographs, videotapes, and a preserved specimen, were
obtained during dives of the Pisces V, sponsored by NOAA’s
Hawaiian Undersea Research Laboratory (HURL) program at
the University of Hawaii.

Video recordings of behavioral sequences in all four species
investigated were analyzed by direct observation of the video
signal produced through a Sony video cassette deck (U-Matic
VO-5800) capable of slow-motion and still-frame sequencing
and equipped with a real-time clock. A Polaroid Freeze-Frame
Video Image Recorder (Polaroid Corp.) was used to transfer
swimming movements recorded on videotape to a 35 mm film
format (Figures le-g, 2-4).

The use of brand names in this publication is for descriptive
purposes only and does not constitute endorsement by the
Smithsonian Institution.

Voucher material of species studied during this research
have been deposited at the Indian River Coastal Zone Museum,
HBOI, or the National Museum of Natural History, Smith-
sonian Institution.

Morphology and Classification

Many bathyal and abyssal holothurians in the orders
Elasipodida and Aspidochirotida possess conspicuous external
features that appear to be. morphological adaptations to
swimming. Hansen and Madsen (1956) and Billett (1986)
discuss swimming abilities of holothurians. Pawson (1976)
suggested that as many as one-half of the approximately 110
species in the order Elasipodida have morphological features
that might enable them to swim, although so far only about 10
species have been captured or observed in the water column.
The species that have frequently been observed to swim share
some characteristics, the most conspicuous of which are veils
(Figure lc-g) or brims (Figure 2) that assist in swimming
activities by flapping or undulating, providing some upward lift
to the animal. A veil (or velum) is usually located on the
anterior dorsal surface of the body, and consists of a series of
enlarged and inflatable podia joined by a continuous or
discontinuous web (Figure 1d-e). There may be from 2 to more
than 20 podia in this anterodorsal veil. Brims are extensions of
the ventrolateral radii, comprising podia joined by webs. Brims
may be of constant width along each side of the body, or they
may vary in width, being widest towards the anterior and
posterior ends of the body.

Species that swim for the longest periods of time have very
fragile bodies and translucent or transparent body walls, and

NUMBER 35

they are more or less neutrally buoyant. Most swimming
species, when captured by conventional dredges and trawls, are
reduced to unrecognizable gelatinous lumps when they are
removed from the collection gear. The calcite skeletons are
usually reduced or absent in swimming forms; a notable
exception is Psychropotes hyalinus Pawson, which has an
armor of ossicles. Swimming movements usually involve
contraction of the radial longitudinal muscles; some species,
particularly in the aspidochirote family Synallactidae, possess
very well-developed radial muscles.

Of the six extant orders of holothurians, only three,
Elasipodida, Aspidochirotida and Apodida, include species that
are capable of active swimming movements. Only in the order
Elasipodida have some attempts have been made (as noted
below) to refer swimming species to special taxonomic
categories.

Ostergren (1938) noted that most species in the Family
Psychropotidae and some synallactids such as genus Paelopat-
ides are darker in color ventrally than dorsally. He suggested
that the differing colors may conceal swimming animals from
predators above and below. Hansen (1975) cited the case of the
known swimmer Galatheathuria aspera, which is dark all over,
and our investigations do not lend support to Ostergren’s
intriguing suggestion.

Ludwig (1894) erected the family Pelagothuriidae to include
his newly discovered Pelagothuria natatrix. Ostergren (1907)
erected the family Enypniastidae for Enypniastes eximia Théel.
Herouard (1923) erected the family Cyclionidae and included
Enypniastes and Euriplastes Koehler and Vaney, 1905
(= Enypniastes) in a subsection “Reptantia” and Pelagothuria
in a subsection “Natantia.” Ekman (1926) discussed the
assignment of swimming holothurians to new families by
previous authors. Heding (1950) diagnosed a new order
Pelagothurioida, equal to the order Elasipodida, and included
two families, Pelagothuriidae Ludwig, 1894, and Planktothu-
riidae Heding, 1950. Billett et al. (1985) agreed in principle
with Heding’s classification, but they favored lower taxonomic
levels, with the order Pelagothurioida reduced to family
Pelagothuriidae and included within the order Elasipodida. The
family currently includes two genera, Pelagothuria and
Enypniastes; in these, the tentacles are connected directly to the
water vascular ring canal, whereas in other Elasipodida they are
connected to the radial water vessels.

Behavioral Categories

For purposes of convenience, we assign the swimming
species to three broad behavioral categories:

Pelagic species spend their entire lives swimming and drifting
in the water column, feeding on resuspended sediments or
on the rain of detrital material from shallower depths. At
present, only the pelagothuriid elasipod Pelagothuria
natatrix (Ludwig) is known with certainty to fall into this
category.

Benthopelagic species swim for much of their lives, but depend
on seafloor sediments for sustenance. This category includes
not only adults that spend abbreviated periods feeding on the
seafloor (e.g., Enypniastes eximia Théel, Peniagone dia-
phana (Théel)), but also typically benthic species that spend
extended periods in the water column only as juveniles (e.g.,
Benthodytes typica Théel).

Facultative swimmers are benthic for the most part; these
species are able to swim, but usually swimming is an escape
response to a physical disturbance. It appears that some
synaptid species with swimming abilities swim in response
to environmental cues (see p. 5). Many deep-sea species and
all of the shallow-water swimming species fall into this
category.

Survey of Published Records

In the following survey, an attempt is made to list published
records of swimming activity for all swimming species. Under
each species the only references cited, apart from the original
description, are those that refer to swimming behavior. For
complete synonymies, relevant systematic literature should be
consulted.

Order ELASIPODIDA
Family PELAGOTHURIIDAE Heding, 1950

Pelagothuria natatrix Ludwig, 1894. Pelagic_——Ludwig,
1894, central East Pacific, 596-3298 m.—Chun, 1900
{as P. ludwigi, a synonym of P. natatrix according to
Heding, 1950], equatorial Atlantic, 200 m.—Clark,
1920, northeast of Marquesas Islands, Galapagos
Islands, tropical East Pacific, from surface to 4433 m.
Incorrect record: Lemche et al., 1976, South New
Hebrides Trench, 6758-6776 m, on seafloor [these
organisms are cnidarians, not holothurians; see page 14
herein].

Enypniastes eximia Théel, 1882. Benthopelagic.—Sluiter,
1901 [as Enypniastes ecalcarea], Ceram, Indonesia,
567 m, noted to have “large eggs.”—Koehler and
Vaney, 1905 [as Euriplastes obscura], west of the
Andaman Islands, 3245 m.—Herouard, 1906 [as
Pelagothuria bouvieri], central North Atlantic, pe-
lagic.—Koehler and Vaney, 1910 [as Enypniastes (?)
decipiens], northern Indian Ocean.—Mitsukuri, 1912,
Suruga Bay, Japan, 1080-1350 m.—Ohshima, 1915,
Japan, 369-427 m, eggs 3.0-3.5 mm in diameter.
Gilchrist, 1920 [as Planktothuria diaphana}, off South
Africa, depth unknown.—Heding, 1940 [as Euriplastes
atlanticus], North Atlantic——Hansen and Madsen,
1956 [as Enypniastes globosa], South China Sea,
3400-3800 m [bottom at 4390 m].—Pawson, 1976,
West Atlantic, 5689 m; 1982, West Atlantic, 1938-
2141 m, swimming, and feeding on seafloor—Ohta,
1983, Suruga Bay, Japan, abundant in 1200-1700 m;

1985, Suruga Bay and Sagami Bay, Japan, 516-1600
m, description of swimming behavior.—Billett et
‘al.,1985 [as Enypniastes diaphana], northeast Atlantic,
995-4980 m bottom depth, specimens captured from
0-3000 m above seafloor.—Otsuka, 1987, Suruga
Trough, Japan.

Family ELPIDIIDAE Théel, 1879

Peniagone leander Pawson and Foell, 1986. Ben-
thopelagic.—Pawson and Foell, 1986, central East
Pacific, 4000-5000 m.

Peniagone diaphana (Théel, 1882). Benthopelagic.—
Herouard, 1923 [as Scotoanassa translucida], North
Atlantic, from four pelagic stations (see Hansen, 1975)
at depths of 0-4900 m.—Hansen, 1975, noted that
specimens from Herouard’s (1923) pelagic stations
show “ability to lead a pelagic life... ..—Pawson, 1976
[as Scotoanassa translucida], western North Atlantic,
2450 m, 3-4 m above seafloor.—Barnes et al., 1976,
off California, 1900-2100 m, in immense numbers.—
Sibuet, 1977, Bay of Biscay, France.—Billett et al.,
1985, North Atlantic, 1500-4780 m depth, specimens
collected 0-1500 m above seabed, concluded that
individuals feed on seafloor.—Gage et al., 1985,
Northeast Atlantic, 4810 m; most abundant holothurian
below 4,000 m in Bay of Biscay.

Family PSYCHROPOTIDAE Théel, 1882

Psychropotes longicauda Théel, 1882. Benthopelagic
only as juvenile——Mortensen, 1927, speculated that
“The long tail probably is a swimming apparatus”; his
suggestion apparently true for juveniles of this species,
but not for adults.—Belyaev and Vinogradov, 1969 [as
Nectothuria translucida new genus, new species;
Hansen (1975) believed this to be juvenile of Psychro-
potes longicauda, but Billett et al. (1985) suggested that
it may be juvenile of another Psychropotes species].—
Billett et al., 1985, Northeast Atlantic, 7 of 8 juveniles
captured occurred greater than 500 m above seafloor, at

_ depths of 3470 to 4008 m.

Psychropotes depressa (Théel, 1882). Facultative
swimmer.—Arrhenius, 1963, seafloor photographs of

swimming specimens near seafloor at 1930 m off Baja
California [identified as possibly P. depressa by
Hansen (1975)].—Pawson, 1976 [as Euphronides sp.],
West Atlantic in 2450 and 2477 m; when disturbed,
specimens leapt from seafloor, moving forwards and
upwards by slow flexing of body in vertical plane,
similar to swimming of Bathyplotes natans M. Sars.—
Billett et al., 1985, North Atlantic, juveniles swimming
at depth of 1000-1500 m, 2500-3000 m_ above
seafloor.

Psychropotes hyalinus Pawson, 1985. Facultative
swimmer.—Pawson, 1985, single specimen captured in
trap set 5 m above seafloor at depth of 5891 m, North
Pacific, north of Hawaii.

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

Benthodytes typica Théel, 1882. Benthopelagic only as
juvenile—Grieg, 1921, North Atlantic, at depth of
1400 m, 1600 m above seafloor.—Billett et al., 1985,
East Atlantic off Ghana, at depth of 1205-1300 m,
3400 m above seafloor.

Benthodytes sordida (Théel, 1882). Benthopelagic only as
juvenile.—Billett et al., 1985 [as B. lingua R. Perrier,
1896], North Atlantic, at depth of 3485-3515 m,
575-605 m above seafloor [referred to B. sordida by
Tyler and Billett, 1987].

Benthodytes sanguinolenta Théel, 1882. Facultative
swimmer.—Pérés, 1965, observed Benthodytes-type
holothurians swimming in Puerto Rico Trench, at depth
of 3100 m.—Heezen and Hollister, 1971:84, showed
photographs of probably B. sanguinolenta, with one
end of body raised off of seafloor; commented on
swimming possibilities—Pawson, 1976 [as “probably
B. typica Théel”], numerous photographs of West
Atlantic specimens with one end of body raised off of
seafloor.—Pawson, 1982, swimming of several speci-
mens studied from submersible Alvin in West Atlantic
at depth of 1938-2141 m; noted S-shaped body
posture; swimming movements similar to those de-
scribed by Pawson (1976) for Psychropotes depressa
(Théel).

Order ASPIDOCHIROTIDA
Family SYNALLACTIDAE Ludwig, 1894

Galatheathuria aspera Hansen and Madsen, 1956. Ben-
thopelagic_—Hansen and Madsen, 1956, South China
Sea, seafloor depth 4390 m, specimen collected at
3400-3800 m depth.

Scotothuria herringi Hansen, 1978. Benthopelagic_—
Hansen, 1978, Northeast Atlantic, 100-3000 m above
seafloor; swims by lateral undulations; suggests that
Dendrothuria Koehler and Vaney, 1905, and Pseudo-
thuria Koehler and Vaney, 1905, also pelagic, for they
resemble Scotothuria.—Billett et al., 1985, Northeast
Atlantic, 1250-4980 m depth; specimens collected
from 0-3900 m above seafloor; also off Kenya
(Galathea collection) on seafloor in 3960 m, and
equatorial Atlantic (Swedish Deep-Sea Expedition)
[possible synonym of Dendrothuria similis Koehler and
Vaney, 1905].

Bathyplotes natans M. Sars, 1867. Facultative swimmer.—
Sars, 1867, observed swimming movements—flexing
of body in the vertical plane—in North Atlantic
specimens.—Ohta, 1983, noted that species often
photographed on seafloor in 400-700 m in Suruga Bay,
Japan, but seldom trawled; individuals probably swam
up and away when “bow wave” of trawl was detected,
or they were passively pushed aside by bow wave.

Hansenothuria benti Miller and Pawson (1989). Faculta-
tive swimmer.—Miller and Pawson (1989, and herein),
West Atlantic, 363-904 m.

NUMBER 35

Paelopatides gigantea (Verrill, 1884). Facultative
swimmer.—Grassle et al., 1975, observed to be
neutrally buoyant; specimen observed swimming “with
a ‘flip-flop’ motion over the bottom . . .” at depth of 1800
m in West Atlantic.—Pawson, 1976 [as Paelopatides
sp.], seafloor photograph shows swimming in this
species off Bahama Islands; swimming achieved by
sinusoidal undulation of lateral brim.

Paelopatides grisea R. Perrier, 1902. Facultative
swimmer.—Billett et al., 1985, photographs of speci-
mens on seafloor in Northeast Atlantic indicate that this
species swims in similar manner to P. gigantea; Billett
et al. suggest that these two species are synonymous.

Paelopatides retifer Fisher, 1907. Facultative swimmer.—
Miller and Pawson, herein, Hawaiian Islands, 405-
1900 m. .

Paelopatides confundens Théel, 1886. Facultative
swimmer.—Miller and Pawson herein, off northern
California, 500-1000 m above seafloor in 4200-4300
m depth.

Paelopatides species. Facultative swimmer.—Gage et al.,
1985; Northeast Atlantic, 1942-1949 m; large speci-
men photographed on seabed from trawl, but not
captured by trawl.

Kareniella gracilis Heding, 1940. Facultative
swimmer.—Miller and Pawson, herein [B. Cutress,
personal communication]; Puerto Rico, 544 m; vide-
otaped leaping off seabed and swimming by flexing
body in S-curves.

Family STICHOPODIDAE Haeckel, 1896

Astichopus multifidus (Sluiter, 1910). Facultative
swimmer.—Glynn, 1965; when disturbed, Puerto Rican
specimens made active “bounding” movements [undu-
lating in vertical plane], but almost always remained in
contact with substratum; observed on one occasion to
leave seafloor and “swim.”

Parastichopus californicus (Stimpson, 1857). Facultative
swimmer.—Margolin, 1976; when contacted by some
species of seastars, Californian specimens vigorously
swim for short distances by undulating bodies in
vertical plane.

Order APODIDA
Family SYNAPTIDAE Ostergren, 1898

“Synaptids.” Facultative swimmers.—Clark, 1907; young
synaptids “‘. . . up to 2 cm in length, are sometimes found
floating, if not swimming, in the water.”

Leptosynapta inhaerens (Miiller, 1776). Facultative
swimmer.—Costello, 1946; specimens swimming at
night near surface at Woods Hole, Massachusetts; when
swimming, specimens expanded, filled with seawater,
intestines empty; swimming movements involved flex-
ing of body into U-shape.

Leptosynapta albicans (Selenka, 1867). Facultative
swimmer.—Glynn, 1965, observed specimens swim-

5

ming at night near the surface in Monterey Bay,
California; swimming movements sinusoidal undula-
tions.

Labidoplax dubia (Semper, 1868). Facultative
swimmer.—Hoshiai, 1963, observed young specimens
swimming near surface, at night, off Asamushi, Japan;
like Leptosynapta inhaerens, specimens were ex-
panded, with empty intestines; swimming movements
involve sinusoidal undulations.

Results

Hansenothuria benti Miller and Pawson, 1989

FIGURES la, 2

MATERIAL EXAMINED, HABITAT, AND IN SITU OBSERVA-
TIONS.—Specimens of H. benti were first encountered south of
Great Abaco Island, Bahamas, during Dive No. JSL-II-808, 9
April 1984. One individual was photographed, videotaped, and
collected at 700 m, and two others were collected at 699 m and
683 m. The specimens were found on a 40 degree slope, which
was covered with a thick layer of fine sediment and Halimeda
sp. flakes. None of the specimens made any attempt to swim
while being collected, but after being placed in a holding
bucket, all three swam in the bucket by rolling and arching their
bodies. This behavior continued for at least two hours.
Members of the Division of Biomedical Marine Research,
HBOI, during a dive (JSL-I-1649, 13 August 1985) off
Crooked Island, Bahamas, videotaped a specimen of H. benti
swimming a few meters off the bottom at a depth of 791 m. The
swimming behavior was taped for two minutes. Commentary
on the video described other specimens in the vicinity,
swimming and “resting” on a 45 degree slope covered with fine
silt, loose rocks, and boulders. L. Cameron (HBOJ) collected
several specimens of H. benti from a sandy bottom (JSL-I-
1705, 10 November 1985) at depths of 691-762 m off San
Salvador Island, Bahamas. He noted that the specimens would
leave the bottom and swim in the water column with rapid
S-undulations when disturbed by the manipulator arm of the
submersible. During dives aboard JSL in the Bahamas,
1987-1988, the present authors and their colleagues encoun-
tered several additional specimens of H. benti at depths of
639-904 m. These specimens were found on shallow to steep
(20-60 degree) slopes with a moderate to thin layer of fine,
silty sand.

DESCRIPTION OF LIVING INDIVIDUALS.—Hansenothuria
benti is a holothurian of moderate size, ranging in length from
10 to 23 cm. The ventral surface is a flattened sole with minute
tube feet; dorsally the body wall is vaulted, with steep sloping
margins (Figure la). The ventrolateral margin is a brim
composed of webbed podia. The brim is widest along the
anterior and posterior ends of the body, where it aids in active
swimming movements. The anterior end is high and bluntly
rounded; the posterior end is abruptly tapered into a low short

6 SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

FIGURE 1.—In situ photographs of swimming holothurians discussed herein: a, Hansenothuria benti Miller and
Pawson, photographed in French Bay, San Salvador, Bahama Islands, 23°55.05’N, 74°31.67’W, at 694 m; b,
Paelopatides retifer Fisher, photographed off Kailua-Kona, Hawaii, at 1060 m (photo credit C. Young, L.
Cameron, HBOI); c,d, Enypniastes eximia Theel, photographed in Northwest Providence Channel off Stirrup
Cay, Berry Islands, Bahama Islands, 26°01.72’N, 78°04.94’W, 902-910 m; e-g, Pelagothuria natatrix Ludwig,
photographs transferred from videotape recorded off Isla San Cristobal, Galapagos Islands, at 542 m (video credit
E. Armstrong, HBOT).

“tail.” The two dorsal radii each carry a row of slender, erect, a distinct, shallow trough. Though relatively thick, the body
hair-like papillae with pointed tips. In each row there are 10-31 wall is transparent to translucent, and portions of the
papillae, nearly regularly spaced along the length of the body. _—_ sediment-filled intestine are usually visible through it. The
Between the rows of papillae, the mid-dorsal interradius forms body is a pale purplish blue with gray or black dorsal papillae.

For a detailed description of H. benti, see Miller and Pawson
(1989).

SWIMMING BEHAVIOR.—A powerful and active swimmer,
H. benti has been found to swim only in response to
disturbance. Observers in submersibles have not seen individu-
als that were swimming when first encountered. Video records
of this species confirm that it can maintain active swimming

FIGURE 2.—Sequence of active swimming movements in Hansenothuria
benti; this series of photographs was converted from videotape; exposures
were made at 0.3 second intervals; specimen videotaped off Crooked Island,
Bahama Islands, 22°47.75'N, 74°23.50’W, at 791 m (video credit, Division
of Biomedical Research, HBOI).

movements for at least two minutes, and individuals held in
collection containers have remained above the bottom of the
containers for two hours or more.

When provoked, H. benti pushes rapidly off the seafloor,
propelling itself upward with rapid flexing of the anterior and
posterior portions of its body. One specimen defecated after
completing several swimming strokes, at which point the sea

8

cucumber was approximately 3 m above the seafloor.

This species achieves vertical lift through the power strokes
of the anterior and posterior ends of the body. The power
strokes are staggered; the posterior power stroke begins as the
anterior recovery stroke is being completed. Likewise, at the
completion of the anterior power stroke, the posterior recovery
stroke is nearing completion. There is no glide period between
these complementary power strokes.

At the beginning of a swimming cycle, the anterior end of the
body is arched over the dorsal surface at a right angle to the
anterior-posterior axis, while the posterior one-third of the
body is strongly curled ventrally in the shape of a hook or C
(Figure 2a). Modified webbed podia, arising laterally from the
posterior body wall to form a conspicuous brim, function like
oar blades by increasing the surface area of the “tail.” The
posterior power stroke precedes the anterior power stroke and
is initiated by a rapid downward thrust of the posterior end
(Figure 2a-f) brought about by contraction of the dorsal
longitudinal muscles. Initiation of the anterior power stroke
occurs one second after initiation of the posterior power stroke.
At the onset of the anterior power stroke, the anterior end is
slightly arched dorsally, and the posterior end, which is nearing
the completion of its power stroke, is arched ventrally (Figure
2d). In this posture, the animal assumes a reversed S-shape. A
transparent veil of webbed podia completely surrounds the
anterior end of the body. As the dorsal longitudinal muscles
contract to curl the anterior end dorsally, the veil is expanded
and held erect; the power stroke progresses until the anterior
end contacts the mid-dorsal surface (Figure 27).

Staggering of the power strokes provides initial lift through
(1) the posterior stroke (averaging 1.0 sec), combined lift
through (2) a brief period of overlap of anterior and posterior
power strokes (each averaging 0.7 sec), and final lift through
(3) completion of the anterior stroke (averaging 1.0 sec). Thus,
anterior and posterior power strokes are of approximately equal
duration, each averaging 1.7 sec. Each coordinated power
stroke serves to move the animal obliquely (diagonally)
through the water column a distance approximately equal to
one-half of its body length. As the holothurian ascends, it
rotates slowly around its anterior-posterior axis, completing
one 360 degree rotation in 20 anterior and posterior power
strokes.

Both the anterior and posterior recovery strokes are effected
by contraction of the ventral longitudinal muscles. At the onset
of the posterior recovery stroke, the holothurian is mid-way
through the anterior power stroke. In this configuration, the
holothurian resembles an upside-down and reversed L, with the
anterior end set at a right angle to the anterior-posterior axis,
and the posterior end almost in line with the axis (Figure 2/).
In contrast, as the anterior recovery stroke is initiated, the
holothurian is mid-way through the posterior recovery stroke.
At this point in the swimming cycle, the anterior end is fully
folded dorsally to meet the mid-dorsal body wall, and the
posterior end is curled nearly 90 degrees to the anterior-

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

posterior axis (Figure 27). As both recovery strokes begin, the
webbed podia of the posterior and anterior brims are passively
appressed to the body wall by water resistance. Duration of the
anterior and posterior recovery strokes equals the duration of
the individual power strokes, which is 1.7 sec each. Thus, a
total cycle (power stroke plus recovery stroke) for the posterior
or the anterior end takes approximately 3.3 sec. However,
because the anterior power stroke is delayed by 1 sec beyond
initiation of the posterior power stroke, the total time for the
holothurian to complete both power and recovery strokes
equals 4.3 sec. The series of photographs in Figure 2 illustrates
a complete swimming cycle at 0.3 sec intervals, from initiation
of the posterior power stroke to completion of the anterior
recovery stroke.

Only one individual videotaped during swimming was
observed to slow the swimming cycle. The cycle slowed
approximately 2 minutes after swimming commenced; soon
afterwards active swimming movements ceased, and the
specimen assumed a horizontal posture. Thereafter, it started
passively rotating in a clockwise direction while slowly
descending towards the seabed.

DISTRIBUTION.—Hansenothuria benti is known only from
the Bahama Islands at depths of 639-904 m, and from St.
Vincent in the Lesser Antilles at depths of 363-447 m.
Bahamas specimens collected to date with the JSL submersi-
bles have been found off Great Abaco, Egg Island, Andros
Island, Black Rock, San Salvador, New Providence, Plana Cays
and Crooked Island. This species probably occurs on bathyal
slopes along many islands of the Greater and Lesser Antilles.

COMMENTS.—Hansenothuria benti can be relatively com-
mon at a given locality, but individuals are usually widely
scattered and solitary. Despite its rather sturdy appearance in
situ, H. benti is fragile, and captured specimens seldom arrive
at the surface intact. Usually during the ascent from the seafloor
to the surface, specimens will slough off (autotomize)
epidermal and dermal layers of bodywall. This self-mutilation
may be a response to increased temperature, decreased pressure
and/or increased light intensity. Following collection, the
specimens are well protected in Plexiglas containers; autotomy
does not appear to begin until the submersible is ascending to
the surface.

Paelopatides retifer Fisher, 1907
FIGURES 1b, 3

MATERIAL EXAMINED, HABITAT, AND IN SITU OBSERVA-
TIONS.—During a submersible dive in Pisces V (Dive No.
P5-047, February 1988) to investigate mid-water organisms off
Oahu, Hawaiian Islands, M. Youngbluth (HBOI) encountered
a specimen of Paelopatides retifer at 800 m depth. The
specimen was floating in an almost horizontal posture
approximately 300 m above the seabed. As the submersible
moved closer to videotape the specimen, it rotated to a vertical
position and began actively swimming. Additional specimens

NUMBER 35

of this species were observed, photographed, and videotaped by
C. Young and L. Cameron (HBOI) using Pisces V (Dive Nos.
P5-081, PS-082; July 1988) off Kailua-Kona, Hawaiian
Islands, at depths of 1060-1900 m. Specimens observed during
these latter dives were feeding on the seabed. One individual
actively swam upwards after being prodded with the submers-
ible’s manipulator arm. The substrate where the holothurians
were observed on Dive No. P5-081 consisted of a shallow slope
with occasional basalt outcrops, covered with silty sediment.
DESCRIPTION OF LIVING INDIVIDUALS.—This species
teaches a length of approximately 20-25 cm. The flattened
ventral surface is elliptical in outline. At the anterior and
posterior ends, the ventrolateral margins are composed of
webbed podia forming a distinct brim; the anterior brim is
twice as wide as the posterior. The body is arched, with high,
steeply sloping sides. Along each dorsal radius is a row of 4-6
almost evenly spaced papillae (Figure 1b). The papillae are
long and slender and supported on large, prominent, conical

FIGURE 3.—Sequence of active swimming movements in Paelopatides
retifer; this series of photographs was converted from videotape; exposures
were made at 1 second intervals; specimen videotaped off Oahu, Hawaiian
Islands at 800 m (video credit, M. Youngbluth, HBOI).

bases. In the middorsal interradius, the body wall is slightly
convex, forming a low but distinct rounded ridge. The anus is
conspicuous, situated high on the posterior end of the body.
The bodywall colors are various hues of purple.

SWIMMING BEHAVIOR.—Paelopatides retifer is a slow
swimmer that appears to combine swimming movements used
by both Hansenothuria benti (p. 5) and Enypniastes eximia (p.
10), that is, flexing of the posterior portion of the body and
rhythmic pulsation of the anterior brim. The holothurian
assumes a vertical posture for swimming. A videotape record of
this species shows that it can sustain active swimming
movements for more than 20 minutes.

Depending upon the amount of sediment in the intestine, P.
retifer appears to be neutrally buoyant or slightly negatively
buoyant. The single individual videotaped in the water column
often drifted motionless while maintaining a constant depth,
and specimens on the seafloor were swept away by the bow
wave of the approaching submersible.

10

Swimming is initiated by contraction of the dorsal longitudi-
nal muscles, which simultaneously pull the anterior and
posterior ends dorsally. As the anterior end curls backwards,
the anterior brim or veil is extended and held erect while
sweeping toward the dorsal surface. At the onset of the anterior
power stroke the mouth is in its normal ventral position (Figure
3a). However, when the anterior power stroke is complete, the
mouth, with partially extended tentacles, points directly
upwards in line with the anterior-posterior axis (Figure 3d). In
this posture, the anterior veil is fully appressed to the anterior
and dorsal body wall. The anterior brim is longer than the
posterior brim, and twice as wide. Accordingly, the anterior
brim contributes the majority of lift to the swimming
holothurian. The duration of the anterior power stroke is
approximately 3.5 sec.

The anterior recovery stroke is effected by contraction of the
ventral longitudinal muscles, which return the anterior end to
its normal position, with the mouth oriented ventrally.
Throughout the anterior recovery stroke (Figure 3e-i), the brim
remains partially appressed to the body, probably forced
backwards by water flowing over the animal. Even as the
anterior power stroke is initiated, the distal half of the brim lags
behind the proximal half, and the entire brim is not fully
inflated until 0.5-1.0 sec after the power stroke begins. The
duration of the anterior recovery stroke is greater than the
anterior power stroke, lasting approximately 5.5 sec. A
complete anterior cycle, from initiation of the power stroke to
completion of the recovery stroke, takes 9.0 sec.

The action of the posterior brim appears to contribute very
little to swimming in this species. During the posterior power
stroke, the posterior brim is pulled dorsally 12-15 degrees
beyond vertical (Figure 3d), and at the completion of the
posterior recovery stroke, the brim, curled slightly ventrally, is
positioned just 5 degrees beyond vertical (Plate 3/). In other
words, the posterior brim describes a maximum arc of only 20
degrees during its complete cycle of approximately 9.0 sec
duration.

DISTRIBUTION.—Paelopatides retifer is known from the
Hawaiian Islands at depths of 405-1900 m. The only other
report of this species is the original description by Fisher
(1907) of material collected by the Albatross off the islands of
Molokai, Bird (Mokumanu), Kauai, Hawaii, and Niihau.

COMMENTS.—According to C. Young and L. Cameron of
HBOI (personal communication), one individual of this species
defecated soon after swimming off the seabed. The distinctive
annulated fecal strand deposited on the seabed was similar to
numerous other fecal strands scattered on the seabed. This same
variety of fecal strand was frequently noted on both dives when
P. retifer was encountered, and on another dive (P5-080) when
no specimens were seen. Therefore, it is possible that fairly
large numbers of P. retifer occur around the Hawaiian Islands.

This species, like Enypniastes eximia, may spend the
majority of its life in the water column. Because we lack
empirical data to support this hypothesis, P. retifer has been

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

listed as a facultative swimmer in the survey (page 5). Other
species of Paelopatides, for example P. grisea and P. gigantea
from the Atlantic Ocean, have been reported as swimmers
(Pawson, 1976; Billett et al., 1985), but the swimming
movements, undulation of lateral brims, are so inefficient that
these congeners appear to be capable of ascending only a few
meters above the seafloor. In contrast, another Pacific Ocean
species, P. confundens Théel can venture great distances from
the seafloor. A. Carey (Oregon State University) collected a
specimen of this species off the northern California coast in a
midwater net trawling 500-1000 m above the seabed, which
lay at a depth of 4200-4300 m.

Enypniastes eximia Théel, 1882

FIGURES l1c,d, 4

MATERIAL EXAMINED, HABITAT, AND IN SITU OBSERVA-
TIONS.—Enypniastes eximia was first videotaped and collected
at 717 m on 7 April 1984 during Dive JSL-I-804 off Sandy
point, Great Abaco Island, Bahamas. The specimen was taped
for 12.3 minutes while actively swimming approximately
2.5-5.0 m above the seabed. Several other individuals were
noted in the vicinity. Another individual was observed briefly
at 622 m (Dive JSL-II-820) off Nassau, New Providence Island,
17 April 1984, swimming a few meters above the seabed.
Additional video records of E. eximia were made during three
dives in Johnson-Sea-Link off the Bahama Islands: JSL-II-
1495, 17 October 1987, off Stirrup Cay, Berry Islands,
900-910 m; JSL-I-2267 and JSL-I-2268, 15 September 1988,
off Crooked Island, 873-900 m. On each of these latter dives,
numerous individuals were observed feeding on the sediment
or swimming within several meters of the seabed. Interestingly,
the number of individuals encountered decreased dramatically
at depths shallower than 900 m, and none were noted in depths
of less than 873 m. All E. eximia were found on or above gently
sloping bottoms covered with a thick layer of silty sand up to
30 cm or more in depth.

Information on the behavior of E. eximia found off Puerto
Rico and in the Gulf of Mexico was made available through R.
Appeldoorn (University of Puerto Rico) and W. Nelson
(National Marine Fisheries Service, Mississippi) (JSL-II-1178,
12 October 1985, off La Parguera at 731 m), and I. MacDonald
(Texas A&M University) (JSL-I-2066, 17 June 1987, 716 m,
Green Canyon Lease Site No. 272) respectively.

DESCRIPTION OF LIVING INDIVIDUALS.—This species has a
distinctive bulbous, barrel-shaped body and a large anterior
webbed veil incorporating up to 12 conical podia (Figure 1d).
There are 2 rectangular posterolateral veils composed of 10-15
webbed podia. Individuals examined during this study ranged
from 6 to 20 cm in length, and Ohta (1985) reported that some
specimens can reach a length of 25 cm. Enypniastes eximia is
transparent; internal structures, especially the sediment-filled
coiled intestine, are readily visible through the body wall. The

NUMBER 35

coloration of the integument varies with body size; small
individuals are pale pink and large adults are dark brown-red to
crimson.

FEEDING AND SWIMMING BEHAVIOR.—As noted by previous
investigators (Pawson, 1976, 1982; Billett et al., 1985; Ohta,
1985), few individuals of this species were encountered on the
seabed; only two were videotaped landing on the seabed, and
two taking off. Apparently, E. eximia descends to the seabed
only to feed; non-feeding individuals were not observed on the
seabed.

When approaching the seabed to land, E. eximia reverses the
action of its anterior veil by holding the veil erect over the
anterior end and gently undulating the veil margin to thrust the
animal downwards. The undulations are waves initiated at the
ventral margins of the veil and passing dorsally until the tips of
the component podia meet above the anterior end of the body.
During descent, the posterolateral veils are erected, with the
pointed tips of the component podia slightly curled ventrally.
When contact is made with the seabed, the tips of these podia
are firmly planted into the soft substratum and the animal
“weathervanes” in the current until the anterior end of the body
is facing downcurrent. At the same time, the podia of the
anterior veil curl ventrally, causing the veil to collapse. Once
the animal is secured on the seabed, the anterior veil remains
pointed anteriorly (Ohta, 1985) or it is held erect above the
dorsal and lateral surfaces (Figure 1c).

Within seconds of touchdown, the bifurcate tentacles of the
holothurian extend and begin rapidly grasping small parcels of
sediment and transferring them to the mouth. We found no
evidence to suggest that E. eximia was selectively feeding on
sediment; particles of sediment were observed falling from the
tentacles as they were moved towards the mouth, and during
take-off, sediment continued to fall from the tentacles as they
were retracted. Although the movement of the tentacles during
feeding is very rapid compared to most shallow-water
sediment-ingesting holothurians (personal observations), it is
unlikely that E. eximia could fill its entire intestine during a
single visit to the seafloor; of those individuals observed to be
feeding, none remained on the seafloor for more than 64 sec.
During feeding, movement across the bottom is accomplished
by one or a combination of the following methods. In still
water, E. eximia gently undulates the ventrolateral margins of
the anterior veil, thus “rowing” itself forward. When a current
exists, the tentacles pull the animal downcurrent. Also, in this
situation, the anterior veil acts as a sail, and the curled podia of
the posterolateral veils act as brakes; they may be released from
the sediment to allow forward movement or set in the sediment
to slow or stop the animal’s progress. Forward movement is
also effected by pulling with the tentacles and pushing with
individual podia of the lateral veils. All of these methods of
benthic locomotion except the first (“rowing”) were hypothe-
sized by Ohta (1985).

A take-off involves action of the anterior and posterior veils,
which are simultaneously thrust ventrally by a strong contrac-

11

tion of the ventral longitudinal musculature. This action rapidly
propels the holothurian upwards and backwards, into the
current. Once clear of the seabed, E. eximia quickly retracts the
tentacles and then immediately reverses the stroke of the
anterior veil to propel itself upwards and downcurrent (Figure
1d). One individual videotaped soon after leaving the bottom
kept its tentacles fully extended, with the mouth agape for
several minutes, while the tentacles waved and curled towards
the mouth. This was not feeding activity; rather, it appeared to
be aberrant behavior caused by the intense video lights
illuminating the animal.

After leaving the seabed, E. eximia tends to remain erect in
the water column, with the anterior-posterior axis vertical
(Figure 1d). In this orientation, the coiled portion of the
sediment-filled intestine is situated in the posterior half of the
body, and may act as ballast, keeping the holothurian upright.
When not actually swimming, EF. eximia has been observed to
either maintain a constant altitude above the bottom, or slowly
sink; the rate of sinking is apparently dependent upon the
amount of sediment in the intestine.

Ascent in the water column is effected by the anterior veil,
which is pulled posteriorly to meet the anterodorsal surface of
the body (Figure 4a-e) by contraction of the ventral
longitudinal muscles. The water pushed posteriorly by the
anterior veil induces a sympathetic wave along the dorsal body
wall. This wave disappears near the posterior end of the body.
Both lateral veils move in unison as they are pulled dorsally by
their component podia (Figure 4a-e). The anterior 4-5 podia
bend sequentially to initiate the movement, while the more
posterior feet appear to be passively flexed by the action of the
veil. Lift is effected by the anterior veil; the lateral veils work
in unison to offset the disorienting effect of the anterior veil,
and keep the animal in its preferred vertical orientation.

In its recovery stroke, the anterior veil is pulled inwards
towards the body and upwards, by curling of the component
podia (Figure 4f-k). During this recovery phase the animal
glides upwards. Once the veil is extended by straightening of
the podia, the power stroke is initiated again. The recovery
stroke of the lateral veils is effected by the anteriormost 4-5
component podia, which pull the veils ventrally until they are
perpendicular to the lateral body wall (Figure 4k).

A complete cycle for the anterior veil (power stroke and
recovery stroke) takes an average of 8.7 sec. The lateral veils
initiate their power stroke approximately 1.0 sec before the
anterior veil, completing a full cycle in 7.5 sec. Thus, the cycles
for the anterior and lateral veils are precisely coordinated.

Some swimming specimens appeared to be disturbed by the
submersible’s lights or bow wave and slowed or stopped the
stroke cycle. One individual began swimming upwards with
very irregular movements, altered its strokes to descend, then
reversed course once more to ascend with regular strokes as
described above.

DISTRIBUTION.—Enypniastes eximia is cosmopolitan at
depths of 516-5689 m. Swimming specimens observed from

12

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

FIGURE 4.—Sequence of active swimming movements in Enypniastes eximia; this series of photographs was
converted from videotape; exposures were made at 1 second intervals; specimen videotaped off Great Abaco
Island, Bahama Islands, at 717 m.

submersibles or in seafloor photographs have always been
found within a few meters of the seabed. Our observations
confirm this finding. In contrast, Billett et al. (1985) have
collected juvenile specimens as much as 3000 m above the
seabed, and the same species has been reported (as Pelagothu-
ria bouvieri) at the surface (Herouard, 1923).

COMMENTS.—Through an excellent analysis of seafloor and
near-seafloor photographs taken in Suruga and Sagami Bays,
Japan, Ohta (1985) proposed a behavioral sequence for
swimming in E. eximia. Our results, based on real-time
observations and video recordings, support most of his
findings; some differences noted are discussed below.

Ohta (1985) suggested that E. eximia rises from the seafloor
by lifting its anterior end and stroking upwards with metachro-
nal fanning of the posterior webbed podia. In contrast, we
found that E. eximia leaves the seafloor after a strong

contraction of the ventral longitudinal muscles, which rapidly
pulls the anterior and posterior veils ventrally, thus thrusting
the holothurian upwards and backwards.

Ohta (1985) noted that during swimming, EF. eximia
ascended obliquely; we observed some individuals rising
obliquely when detectable currents were present; at localities
with little or no current, E. eximia ascended vertically. Pawson
(1982) also found E. eximia ascending vertically in the Tongue
of the Ocean, Bahamas.

In the opinion of Ohta, vertical propulsion during ascent was
accomplished by the power strokes of both the anterior and
posterolateral veils. He also assumed that the power stroke of
the anterior veil proceeded while the posterior veils were in
their recovery stroke and vice versa. Our findings show that
instead of contributing to lift through metachronal fanning, the
posterolateral veils act as opposed rudders, countering rota-

NUMBER 35

tional forces about the anterior-posterior axis. In addition, the
power and recovery strokes of the anterior and posterior veils
occur concurrently, and not in opposition, as. supposed by Ohta.

Ohta suggested that movement of the anterior veil during the
recovery stroke proceeded in a radial or undulatory manner by
serial curling of the component podia around the veil.
However, we observed a coordinated simultaneous ventral
curling of the podia, pulling the veil anteriorly to the level of
the mouth.

According to Ohta, E. eximia can hover or hang in the water
by “gentle undulation of the anterior velum” and a “gentle
metachronal fanning wave generated in the anterior part of the
posterior webs.” We have encountered numerous specimens
drifting in the water column while maintaining a constant
altitude, but in no case have we observed a gentle fanning of the
veils. It appears to us that E. eximia can regulate its buoyancy,
perhaps by unloading ballast through defecation. Ohta posited
that E. eximia descends in a “free fall,” by extending the
anterior veil anteriorly and sinking to the seafloor. We have
observed some individuals sinking slowly, but none held the
anterior veil anteriorly. Specimens would swim downwards to
the seafloor by extending the anterior veil anteriorly and
rhythmically undulating the veil.

Finally, Ohta states that “when the holothurian walks on the
bottom, the antero-dorsal velum is fully expanded forward.” In
contrast, we have observed feeding individuals with anterior
veils held erect and the component podia slightly curled
posteriorly into the current. The ability of the holothurian to
keep the anterior veil erect is most likely a function of current
velocity; undoubtedly it would be difficult for E. eximia to
maintain position on the seafloor in a strong current if the
anterior veil were held erect.

Pelagothuria natatrix Ludwig, 1894
FIGURE le-g

MATERIAL EXAMINED AND HABITAT.—A single individual
of this species and a short videotape of its swimming behavior
were loaned to us by S. Pomponi and E. Armstrong (HBOI).
The specimen was encountered and collected within a few
meters of the seabed at a depth of 542 m off Isla San Cristobal,
Galapagos Islands (JSL-I-1919, 17 November 1986). The
seabed at the dive site was a 5 degree slope covered with mud.

DESCRIPTION OF LIVING INDIVIDUALS.—Pelagothuria nata-
trix is perhaps the most bizarre holothurian species in existence.
Its shape is more reminiscent of a medusa (Figure le-g), and it
bears no obvious resemblance to most sea cucumbers. The
anterior end of the slender, conical body supports an enormous,
umbrella-like veil. The veil, composed of 12-16 large webbed
podia, is almost continuous, the web being absent only from the
ventral radius. With the veil fully extended anteriorly, the total
length of the specimen collected was 16 cm (veil 10 cm; body
6 cm). The (usually) 15 tentacles, approximately 2 cm in
length, surround the terminal mouth; they are bifurcate at their
tips and non-retractile. The body wall is transparent and

13

pigmented a pale violet or pink. Within the body cavity the
slender intestine is evident, and the dense yellow to white
gonad is clearly visible when ripe.

FEEDING AND SWIMMING BEHAVIOR.—After careful review
of the video record of this species, one might best characterize
Pelagothuria natatrix as a drifter instead of a swimmer.
Although the holothurian is quite capable of active swimming
movements, it appears to spend a great deal of time “hanging”
vertically in the water column. In this neutrally buoyant
posture, P. natatrix resembles an umbrella turned inside out by
a gusting wind (Figure le). It seems possible that the
holothurian uses its veil to collect or concentrate the rain of
detritus from shallower depths, or superficial sediments that
have been resuspended. Video footage clearly shows move-
ment of the tentacles when surrounded by the conical veil.

Due to inadequate illumination of the specimen while
recording, the video tape of this species was not of sufficient
quality to produce a full series of still photographs depicting
swimming behavior. However, the three photographs in Figure
1 illustrate the basic postures observed during drifting (Figure
le) and swimming (Figure If,g) activities. Swimming move-
ments appear to occur irregularly and infrequently, and they are
performed at a much slower rate than in the three preceding
species. A complete stroke cycle takes approximately 27 sec.

In altering its posture from drifting (feeding?) activity to
swimming activity, P. natatrix slowly curls the component
podia of the veil towards the mouth. When this inward curl has
reduced the veil to approximately one-half of its fully erect
height, the curling of the podia is reversed to an outward
direction. In this posture, the veil forms a ventrally cupped
collar around the anterior end, just above the level of the mouth
(Figure 1f). As the power stroke progresses, the entire veil is
pulled posteriorly by the podia, which remain curled until the
margin of the veil reaches the level of the posterior end of the
body (Figure 1g). By this time, the animal has started to rise
upwards as a result of the thrust created by the veil. As the
forward motion continues in a glide, the flow of water over the
veil causes it to collapse, causing the distal tips of the podia to
make contact below the posterior end of the body. Because the
veil does not completely encircle the anterior end, the thrust
created is not equal around the body, and the holothurian tends
to ascend obliquely, with the ventral surface facing downwards.
The recovery stroke is accomplished by a coordinated inward
curling of the podia; this returns the veil to its cupped posture
slightly above the anterior end of the body.

Because of their attachment to the base of the podia in the
veil, the tentacles are pulled upwards and outwards when the
veil is thrust posteriorly in the power stroke. Conversely, as the
recovery stroke progresses, the tentacles are moved inward and
downward toward the mouth. The fully extended tentacles can
be seen arising from the bases of the veil podia in Figure 1g.
During the power stroke, while the tentacles are pulled
outwards, the mouth is gaping, and it is assumed that some
ingestion of food occurs at this time.

DISTRIBUTION.—Ludwig (1894) reported on more than 34

14

specimens of Pelagothuria natatrix collected by the Albatross
between the Gulf of Panama and the Galapagos Islands at
depths of 605-3350 m. He also reported that the species was
found in surface waters off the west coast of Panama. Chun
(1900) reported this species (as Pelagothuria ludwigi) from the
Indian Ocean, near the Seychelles, depth “pelagic.” Heding
(1950) reduced P. ludwigi to synonymy with P. natatrix.

COMMENTS.—Both Herouard (1923) and Heding (1950)
reported that the veil of P. natatrix is not webbed in the
midventral radius. Hansen and Madsen (1956) confirmed that
the greatly enlarged laterodorsal veil is comparable to that
found in many benthic elasipods, and that “...hitherto
published figures of Pelagothuria are artistic reconstruct-
ions ....”

To date, Pelagothuria natatrix is the only known truly
pelagic holothurian. Previous reports on the intestine contents
of this species (Chun, 1900) provide no evidence that this
species derives its nourishment from the seafloor. Our
examination of the specimen at hand confirms this finding; the
intestine contents are unidentifiable fragments of particulate
matter, and some pteropod shells and tintinnid tests. There is no
unequivocal evidence of benthic organisms or sediment.

Lemche et al. (1976) suggest that P. natatrix descends to the
seafloor to feed, and they support this contention with two
seafloor photographs (their plate 20c,d) illustrating an inverte-
brate species perched on a rocky substratum at hadal depths in
the New Hebrides Trench. Although Lemche et al. believe the
organisms in the photographs to be specimens of P. natatrix,
we suggest that the animals in these photographs, as well as the
supposed brisingid asteroids in their Plate 17c-e are actually
deep-sea cnidarians, probably actiniarians. The “veil” in the
specimens illustrated by Lemche et al. shows “podia” of greatly
varying length, a trait not observed by us in either Pelagothuria
or Enypniastes. We believe that these holothurians cannot
strongly expand or contract the webbed podia comprising the
anterodorsal veil. The photographs show no evidence, on the
animal itself or in the shadow on the rocky substratum, of the
presence of the fragile web between the podia. After reviewing
the behavior of P. natatrix on videotape, we suspect that this
species is incapable of inverting itself to feed on the seafloor, as
stated by Lemche et al. (p. 289).

Discussion

Despite the growing body of information on the adaptations
of deep-sea holothurians, we can as yet only speculate upon the
significance of swimming in some species. The contrasting
swimming patterns, four of which are described in this paper,
provide further complications. Several working hypotheses
have been proposed to account for swimming ability, and we
discuss some of these here.

PREDATOR AVOIDANCE.—Margolin (1976) determined ex-
perimentally that the common eastern Pacific aspidochirote
Parastichopus californicus will consistently flee, and may

SMITHSONIAN CONTRIBUTIONS TO THE MARINE SCIENCES

vigorously swim, when contacted by sea stars. The swimming
behavior of Hansenothuria benti and Paelopatides retifer may
play a similar role in predator avoidance. Hansenothuria benti
was observed to swim only when stimulated, for example by
being prodded with the submersible’s manipulator arm. An
individual of P. retifer feeding on the seabed was provoked to
swim by physical contact with the submersible (C. Young, L.
Cameron, personal communication). The ability of both of
these species to swim actively for several minutes would be of
value in escaping potential benthic or bottom-feeding preda-
tors. Likewise, the brevity of the feeding period on the seabed
of Enypniastes eximia (see below) might play a role in predator
avoidance.

ESCAPE PHYSICAL HAZARDS.—The ability to leave the
seafloor and maintain an altitude above the substratum for
several minutes could also allow swimming species to escape
burial by sediment slumping or turbidity currents. Throughout
the Bahama Islands, the steep bathyal slopes are generally
covered by a thin sediment veneer. Areas of instability were
obvious during our submersible dives, and small rivulets of
sediment were often observed flowing downwards along the
limestone faces of steeper slopes.

Based upon our observations of the amount of perturbation
required to elicit a swimming response in Hansenothuria benti,
the bow wave created by an approaching sediment flow would
be sufficient stimulus to evoke a swimming response in this
species. Alternatively, as H. benti is nearly neutrally buoyant,
the bow wave of an approaching flow could provide the lift
necessary to carry the animal above the source of disturbance,
whence it could swim upwards and away from the area.

Heezen et al. (1955) suggested that turbidity currents may be
responsible for mass burial of benthic organisms inhabiting the
abyssal seafloor. Ohta (1983) found that Enypniastes eximia
was abundant at a locality where “turbidity currents and/or
slumping causes depauperation of nonmotile benthic organ-
isms.” He further suggested that the success of E. eximia in
areas of unstable sediments could be attributed to the
holothurian’s ability to remain above the seafloor by actively
swimming for extended periods of time (Ohta, 1985). In the
Tongue of the Ocean, Bahamas, this highly mobile species was
most common in canyon-like areas where slumping had
recently occurred (Pawson, 1982).

ACTIVE AND PASSIVE DISPERSAL.—The efficient use of
limited energy reserves may be an important consideration for
deep-sea holothurians that subsist on nutrient-poor sediments.
For some species, swimming or drifting as a means of dispersal
may require expenditure of a minimal amount of energy. We
have observed specimens of E. eximia being passively carried
along in near-bottom currents. In this species, and probably
also in P. retifer, horizontal displacement is more a function of
prevailing currents than active swimming movements.

The ability of some holothurians to enter the pelagic realm,
even temporarily, may provide an efficient means of long-
distance dispersal. This method is obviously employed in the

NUMBER 35

case of species that reside on the seafloor as adults but as
juveniles can be found several hundred to several thousand
meters above the seafloor (Hansen, 1975; Billett et al., 1985;
see also survey on page 3 of this paper). It also seems likely that
the commonly occurring large, yolky eggs of elasipodans are
buoyant and are dispersed by ocean currents. Hansen (1975)
states “the eggs in all families of Elasipoda are so large that
possible pelagic larvae are likely to be independent of the
plankton for food intake—thus serving only the dispersal of the
species.”

Hansen (1975) suggested that the similarity between abyssal
holothurian faunas of the North Atlantic and southwestern
Pacific may be attributed to pelagic transport of young stages
by deep-sea currents. At least three elasipodan species common
to both of these regions have been collected in mid-water trawls
as juveniles (Hansen, 1975).

Ohta (1985) posited that swimming activity in Enypniastes
eximia and Pelagothuria natatrix is an important long-distance
dispersal mechanism. His speculation was based upon pub-
lished records indicating that these species lack pelagic larvae,
and are supposedly viviparous. However, evidence for vivipar-
ity in E. eximia (Ohshima, 1915; Gilchrist, 1920) and P.
natatrix (Heding, 1940) is, at best, equivocal. Ohshima (1915)
reported large egg sizes (up to 3.5 mm diameter) in E. eximia.
Hansen (1975) and Tyler and Billett (1987) have shown that
very large eggs are common among elasipodans. Such large
eggs do not provide any proof of viviparity, but they suggest
that development may be entirely lecithotrophic. Large eggs,
with high content of lipids, and probably buoyant, could be
dispersed by currents. Young and Cameron (1987) and
Cameron et al. (1988) provide clear evidence that large
lecithotrophic eggs of two echinothuriid sea urchin species
from bathyal depths are positively buoyant in both in vitro and
in situ experiments.

In spite of attempts by several authors to split Enypniastes
into more than one species (see Heding, 1950; Hansen and
Madsen, 1956; Billett et al., 1985), examination of the literature
and of material at hand indicates that the genus is monotypic
and cosmopolitan in distribution. As stated above (page 14),
horizontal distribution in E. eximia is dependent largely upon
current flow; undoubtedly, oceanic current patterns play a
major role in the widespread geographic distribution of this and
other deep-sea holothurian species.

TRACKING EPHEMERAL FOOD SUPPLIES.—Deep-sea
holothurians may seek desirable substrata, as evidenced by
movement of epibenthic species towards sources of high
organic input. For example, numerous specimens of Scoto-
planes sp. were photographed moving towards a decaying fish
on the seabed (Pawson, 1976). In a later paper, Pawson (1982)
showed that short tracks and trails on the seabed are produced
by swimming holothurians that land on the seabed, feed for a
short time, and then move away, perhaps in search of more
Suitable sediments. Benthodytes sanguinolenta was observed to
make such short tracks. Recent studies by Ohta (1985), Pawson

15

and Foell (1986), and this paper confirm that Enypniastes
eximia and swimming Peniagone species have-a short resident
time on the seafloor. Sibuet (1985) found a significant
correlation between holothurian abundance and organic carbon
flux, percent organic carbon in the sediment and terrigenous
matter at 4000 m in the tropical Atlantic off French Guiana.

INCREASE EFFICIENCY OF DISSOLVED OXYGEN UPTAKE.—
Elasipodan holothurians usually possess unique external
structures such as brims or veils of webbed podia, elongate
sails, enormous podia (see Théel, 1882; Hansen, 1975), but
they lack respiratory trees, which shallow water aspidochirotes
and dendrochirotes use for gas exchange. Although no
empirical data exist to suggest that these modified structures
serve as sites of dissolved oxygen uptake, they might indeed
play an important role in gas exchange in these animals that
seem to lack specialized respiratory organs. It has been shown,
or suggested, that the tube feet of echinoderms aid in
respiration (see reviews in Hyman, 1955; Nichols, 1969;
Lawrence, 1987). If the modified webbed podia of elasipodans
are involved in respiration, perhaps exaggerated movement of
these structures during swimming activity improves respiratory
efficiency.

INCREASE EFFICIENCY OF DISSOLVED ORGANIC MATTER
(DOM) UPTAKE.—The uptake through the bodywall of DOM
(parenteral absorption) may be of considerable importance to
epibenthic organisms feeding on seafloor sediments with low
organic content. Considerable evidence has been presented for
epidermal absorption of DOM by echinoderms (Smith et al.,
1981; Ferguson, 1982; Bamford, 1982; Feral, 1985; Clements
et al., 1988) and other marine invertebrates (Southward and
Southward, 1970; Manahan and Crisp, 1982; Manahan, 1983,
and others). Again, empirical data for deep-sea holothurians are
lacking, but if indeed DOM contributes to nutritional require-
ments in these animals, then an increase in surface area of the
body wall should be advantageous. The extreme in modified
body wall structures appears to be reached in swimming
elasipods, especially pelagothuriids; possibly these animals are
best equipped to use dissolved organics.

In conclusion, active swimming movements in deep-sea
holothurians may serve a variety of functions, as suggested
above. Whatever the reasons might be, such behavior can have
significant and wide-ranging ecological effects on benthic and
pelagic areas in many parts of the world’s oceans. The
conventional view of one-way transport of particulate matter,
and ultimately, energy, downwards to the seafloor from the
waters above requires modification in light of the evidence that
swimming holothurians with intestines full of seafloor sedi-
ment can transport this material upwards for hundreds or even
thousands of meters. The ability of swimming holothurians to
transport large quantities of sediment, perhaps for great
horizontal distances from a source area, offers endless
complexities for organizations that are seeking suitable
deep-sea sites of “low biological activity” for dumping of
wastes, especially radioactive wastes!

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