First description of deepsea polyclad flatworms from the North Pacific: Anocellidus n. gen. profundus n. sp. (Anocellidae, n. fam.) and Oligocladus voightae n. sp. (Euryleptidae)
Author
Quiroga, Sigmer Y.
Author
Bolaños, D. Marcela
Author
Litvaitis, Marian K.
text
Zootaxa
2006
1317
1
19
journal article
10.5281/zenodo.173981
518e12ee-8606-468f-8535-9fa03089ab72
11755326
173981
Species:
voightae
n. sp.
(
Figs. 6–10
)
Type
material and locality:
a)
Holotype
, whole mount, one mature specimen (
12 mm
x
10
mm),
FMNH
12560, collected
30 August
, 2004 from Escanaba Trough,
20 m
N of Marker
6X
on Central Hill, from
3232 m
depth (
41° 00.272’N
127° 29.679’W
).
b)
Paratype
, one mature specimen as serial sagittal sections (
11 mm
x
9
mm),
FMNH
12464, collected with
holotype
30 August
, 2004 from Escanaba Trough,
20 m
N of Marker
6X
on Central Hill, from
3232 m
(depth
41° 00.272’N
127° 29.679’W
).
Distribution:
To date, found only at
type
locality
Etymology:
Species named in honor of Dr. Janet Voight of the Field Museum of Natural History, Chicago, Illinois.
Diagnosis:
Mouth anterior to the brain. Eyes, few and minute, scattered on the tentacles. Seminal vesicle connected posteriorly to an auxiliary storage vesicle containing a basophilic substance (possibly sperm). Auxilliary storage vesicle extends dorsally over the seminal vesicle. Posterior anal pore in main median branch of the intestine.
Description
External features:
Color —
preserved animals have a milky white dorsal surface with ovaries appearing as dark brown spots that form a radial pattern. White intestinal branches are visible through the epidermis. The ventral surface is white.
Form —
oval body shape, margins without folds except for the ones forming the tentacles. The two specimens measured
12mm
x
10
mm and
11 mm
x
9
mm, respectively. A very conspicuous sucker is located right in the center of the ventral surface, posterior to the pharynx (
Figs. 9
and
10
).
Tentacles —
Short (~600 µm), blunt, marginal tentacles formed mainly by the elongation of the body margin rather than the folding of it (
Fig. 6
).
Eyes —
Few and minute, scattered over the tentacles. Cerebral and marginal eyes absent.
Digestive system —
the mouth is a small opening, anterior to the brain (
Fig. 8
A). The very muscular and cylindrical pharynx is directed forward and located in the anterior half of the worm, just anterior to the sucker. It folds back on itself in an Sshape, possibly due to a preservation artifact (
Figs. 8
A and 10). The pharynx connects to a median intestinal branch which itself extents anteriorly dorsal to the brain, and posteriorly almost to the body margin. The posterior part of the median intestinal branch divides into 6 to 8 large, radial branches and 4 smaller ones just dorsal to the pharynx (
Fig. 7
). An anal pore is present on the medial intestinal branch just prior to the terminal end of the branch itself (
Fig. 7
). An anterior vesicle opening to the exterior was observed, but there is no evidence of it being connected or related to the digestive system.
FIGURE 6.
Whole mount of
Oligocladus voightae
n. sp.
; photomicrographs. A. Anterior end, showing tentacles (arrow heads), massive pharynx, and female reproductive structures. Scale bar = 1 mm. B. Higher magnification of anterior end. Arrow heads indicate putative pores of vesicular channel system. Note, channels are only found on one side of the animal. Scale bar = 1 mm.
FIGURE 7.
Sagittal section of
Oligocladus voightae
n. sp.
, showing details of intestine and characteristic anal pore (arrow). Scale bar = 1 mm.
Reproductive anatomy:
Gonopores —
pores are well separated from each other. The female pore is posterior to the male pore and located well anterior of the sucker.
Male copulatory apparatus —
testes are scattered ventrally all over the body but are especially concentrated in the posterior end. The male apparatus is rather small compared to the size of the animal. A free prostatic vesicle (125 µm) is located just dorsal to the male atrium (
Fig. 8
). The seminal vesicle is larger than the prostatic vesicle (175µm), and is located posterior to the atrium. In addition, the seminal vesicle is connected to an accessory storage vesicle containing a basophilic substance, possibly sperm (
Figs. 8
and
10
). This accessory vesicle wraps itself dorsally around the seminal vesicle. A deep atrium houses a pointed stylet (175µm).
Female copulatory apparatus —
The ovaries are dorsal and scattered over the entire body, fanning out in a radial pattern from the pharynx (
Fig. 6
A). Two small uterine trunks are present behind the pharynx. Numerous uterine vesicles are present (
Figs. 6
A and 9). The female atrium is not very deep and connected to a simple vagina, which in turn connects to oviducts.
Taxonomic remarks:
Both,
Faubel (1984a)
and
Prudhoe (1985)
are in agreement of the genus
Oligocladus
in the
Euryleptidae
. Therefore, either classification system may be used for its identification. Conspicuous characters such as a digestive system with a median main intestinal branch, a plicate, cylindrical pharynx extending anteriorly to the level of the brain, a male copulatory complex located anterior to the female one, and a true free prostatic vesicle, clearly place this species in the family
Euryleptidae
. Among the
Euryleptidae
, three genera share the possession of an anal pore in the main intestinal branch,
Oligocladus
,
Cycloporus
,
and
Leptoteredra
.
However, only
Oligocladus
and
Cycloporus
also possess a pair of uterine trunks with multiple uterine vesicles (Faubel 1984).
Oligocladus
and
Cycloporus
are distinguished by the presence of many peripheral vesicles opening to the exterior. In
Cycloporus
these vesicles have clear connections to the digestive system; in
Oligocladus
they do not. In one examined specimen, a vesicular channel system opening via several pores to the exterior was observed in the anterior portion, albeit only on one side of the worm. However, the relationship of this channel system to the digestive system is uncertain. In addition, an obvious anal pore opening dorsally from the caudal end of the main intestinal branch confirmed a placement into
Oligocladus
rather than
Cycloporus
.
FIGURE 8.
Oligocladus voightae
n. sp.
; photomicrographs. A. Sagittal histological section of the anterior end showing position of brain posterior to mouth and details of the male and female reproductive systems. Scale bar = 150 µm. B. Higher magnification sagittal section through male copulatory complex. Asterisk indicates the connecting duct between the seminal vesicle and the accessory storage vesicle. Scale bar = 100 µm.
Additionally,
Hadenfeldt (1929)
recognizes the position of the brain posterior to the mouth as unique to the genus
Oligocladus
, with only two species. According to Faubel (1984), the anatomy of
O. auritus
is not very well known, although
Lang (1884)
placed it into this genus because its brain is posterior to the mouth. Thus, the position of the brain of
O. voightae
supports the placement of this species in the genus
Oligocladus
. Furthermore, the general anatomy of
O. voightae
corresponds well with that of
O. sanginolentus
with the exception of the presence of two sharplydefined clusters of cerebral eyes and an anteriorly trifurcated intestinal trunk in the latter species (
Prudhoe, 1985
).
FIGURE 9.
Diagram of ventral view of
Oligocladus voightae
n. sp.
, showing position of male and female reproductive structures. Scale bar = 1 mm.
FIGURE 10.
Schematic sagittal representation of reproductive and digestive systems of
Oligocladus voightae
n. sp.
Scale bar = 250 µm.
Ecological remarks:
It is interesting to note that the two newly described species so far have been collected only from deepsea wood deployments heavily colonized by woodboring clams (species of which are currently being described, Dr. J. Voight, Chicago Field Museum, pers. comm.). Previously,
Turner (1978)
demonstrated the importance of deepsea wood deployments in the establishment of a highly diverse community, consisting of woodboring bivalves, predatory polychaetes and gastropods, galatheid crabs, echinoderms and most likely fish. With respect to flatworms,
Turner (1978)
reports a single specimen of a predatory turbellarian only; the most abundant taxa of her study being gastropods and polychaetes.
This contrasts sharply with polyclad densities found at Escanaba Trough and ODP. In
August 2004
,
149 specimens
were collected from four
18 inch
x
4
inch
x
4
inch pieces of lumber at Escanaba Trough that had been deployed there in
July 2002
, and in
July 2003
,
47 specimens
were collected from ODP 1026B and
33 specimens
from near Baby Bare Seamount off identical deployments made in
September 2002
(Dr. J. Voight, pers. comm.).
The ecological function of the two newly described species may be inferred from known predatory behavior of other polyclads. Acotyleans of the families
Leptoplanidae
and
Stylochidae
are known to prey on rock and pearl oysters (
Newman
et al.
1993
,
O'Connor & Newman 2001
), blue mussels (
Galleni
et al.
1980
,
Villalba
et al.
1997
), barnacles (
Murina
et al.
1995
), and cultured giant clams (
Newman
et al.
1993
). Their impact can be substantial, as they often feed exclusively on spat or juvenile bivalves, resulting in as much as 90% mortality (
Newman
et al.
1993
). Predation by a stylochid polyclad on oysters has been reported also for the
US
Atlantic and Gulf of
Mexico
coasts (
Provenzano 1961
,
Webster & Medford 1961
,
Christensen 1973
,
Chintala
et al.
1993
), and
Newell
et al.
(2000)
were able to show that small (<
5 mm
2) polyclads were instrumental in significantly reducing the numbers of young oyster spat (less than 3 weeks postsettlement) in Chesapeake Bay.
Recently,
RitsonWilliams
et al.
(2006)
described the predatory behavior of a planocerid, concluding that this flatworm uses tetrodotoxin to capture and kill its mollusk prey. From the observed ecological association of
Anocellidus profundus
and
Oligocladus voightae
with deepsea bivalves, it is tempting to speculate that the flatworms may use a toxin such as tetrodotoxin to subdue their prey. At this point, however, such predatorprey interactions, and the presence of toxins in deepsea flatworms remain to be demonstrated.