SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY NUMBER 7 SERIAL PUBLICATIONS OF THE SMITHSONIAN INSTITUTION The emphasis upon publications as a means of diffusing knowledge was expressed by the first Secretary of the Smithsonian Institution. In his formal plan for the Insti¬ tution, Joseph Henry articulated a program that included the following statement: “It is proposed to publish a series of reports, giving an account of the new discoveries in science, and of the changes made from year to year in all branches of knowledge.” This keynote of basic research has been adhered to over the years in the issuance of thousands of titles in serial publications under the Smithsonian imprint, com¬ mencing with Smithsonian Contributions to Knowledge in 1848 and continuing with the following active series: Smithsonian Annals of Flight Smithsonian Contributions to Anthropology Smithsonian Contributions to Astrophysics Smithsonian Contributions to Botany Smithsonian Contributions to the Earth Sciences Smithsonian Contributions to Paleobiology Smithsonian Contributions to Zoology Smithsonian Studies in History and Technology In these series, the Institution publishes original articles and monographs dealing with the research and collections of its several museums and offices and of profes¬ sional colleagues at other institutions of learning. These papers report newly acquired facts, synoptic interpretations of data, or original theory in specialized fields. These publications are distributed by subscription to libraries, laboratories, and other in¬ terested institutions and specialists throughout the world. Individual copies may be obtained from the Smithsonian Institution Press as long as stocks are available. S. Dillon Ripley Secretary Smithsonian Institution ERRATUM The lower two photographs of the two stereopairs of Figure 8 are reversed and give a negative image instead of a posi¬ tive image as was intended. This error was caught too late in the process of publication to be corrected. SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY NUMBER 7 Richard H. Benson A New Cenozoic Deep-Sea Genus, Abyssocythere (Crustacea: Ostracoda: Trachyleberididae), with Descriptions of Five New Species SMITHSONIAN INSTITUTION PRESS CITY OF WASHINGTON 1971 ABSTRACT Benson, Richard H. A New Cenozoic Deep-Sea Genus, Abyssocythere (Crustacea: Ostracoda: Trachyleberididae), with Descriptions of Five New Species. Smithsonian Contributions to Paleobiology, number 7, 25 pages, 1971.—The new genus Abys¬ socythere Benson has been erected to receive five new species and one described species of psychrospheric ostracode ranging in age from the Paleocene to the Recent. These species include Abyssocythere casca Benson, new species (Indian Ocean), herein designated the type species, A. pannucea Benson, new species (eastern Pacific), A. japonica Benson, new species (western Pacific), A. atlantica Benson, new species (Atlantic), A. australis (Southern Ocean), and A. trinidadensis (van den Bold) from the Caribbean region. Modern species are typical of the deep-sea floor and are common to depths below 2,000 meters. Fossils have been found in deep-water Paleocene and Miocene strata in Trinidad and in deep-sea cores in Pleistocene sediments. These species are thought to have descended from a yet unknown form of the complex of species assigned to the Cretaceous genus Cythereis (sensu lato). There seems to be an evolution of finer surface features of the carapace and an increase in size throughout the Cenozoic. Official publication date is handstamped in a limited number of initial copies and is recorded in the Institution’s annual report, Smithsonian Year. UNITED STATES GOVERNMENT PRINTING OFFICE WASHINGTON 1971 For sale by the Superintendent of Documents, U.S. Government Printing Office Washington, D.C. 20402 - Price 55 cents (paper cover) Richard H. Benson A New Cenozoic Deep-Sea Genus Abyssocythere (Crustacea: Ostracoda: Trachyleberididae), with Descriptions of Five New Species Introduction Over a five-year period I have obtained several hun¬ dred dredge and core samples containing ostracodes from the deeper parts of the world ocean. I have dis¬ cussed the nature of the fauna found in these samples in several preliminary reports (Benson, 1969, 1970), but a formal presentation of taxa is needed to make these forms useful and their names available. The purpose of this report is to record and describe five new species of a new deep-sea psychrospheric genus of ostracode and to assign to it one previously described fossil species. This is the first in a series of taxonomic reports of new ornate ostracodes typical of deep-sea sediments. Methods Because deep-sea ostracodes are difficult to obtain, there have been few efforts to describe them. The Challenger Report by Brady (1880) is still the most important descriptive work available. An indication of the morphologic complexity of deep-sea ostracode carapaces can be clearly seen in Brady’s plates. A spe¬ cies level comparison of such forms, however, is very Richard H. Benson, Department of Paleobiology, National Museum of Natural History, Smithsonian Institution, Wash¬ ington, D.C. 20560. difficult without the use of the Scanning Electron Microscope. One can compare the conventional optical photographic results of the present report with those of the Scanning Electron Microscope to see the im¬ portance of this latter instrument. Many new fea¬ tures can be seen in minute detail. For their descrip¬ tion I have used much of the terminology of Sylvester- Bradley and Benson (1971), as well as suggesting some new terms particularly applicable to this new genus. The collections of the specimens on which the pres¬ ent descriptions are based were obtained from piston cores trawl, grab and dredge, and outcrop samples (Table I). The small number of specimens obtained in these samples precluded estimation of variation or rel¬ ative abundance within the respective species popu¬ lations. In most instances only one or two specimens were found in a single sample. Relative to many other animal taxa described from the deep-sea floor, this is not an unusually small sample for taxonomic descrip¬ tion. The validity of these rare species as separate taxa is based primarily on morphologic distinctiveness. The ages of the Pleistocene and older specimens given in this report were supplied by David B. Erick¬ son and W. A. van den Bold from foraminiferal zona- tion. For the illustrations by conventional light photo¬ micrography (Plate 1) silver nitrate stain was used 1 2 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Table I .—Station and locality area Map Designation (See Fig. ) Station Number* Location Latitude Longitude Depth (in meters) Temp. (°c) Core Level (in cm.) Abyssocythere Species Specimens Age 1 CAP 38 BP l4°l6'S 119 ° 11 'W 3400 — 68-70 japonica 1 Late Quaternary 2 ALB 4693 26°30'S 105"45'W 2089 — Dredge pannucea 4 Recent 3 ALB 4611 10°32'N 88°25'W 3292 1.9 II 11 2 Recent U A 156-1 28°35.5'N 77°10'W 1005 -- 370 aff. trinidadensis 1 5 Renz 75 Trinidad outcrop -- Navet Fm. trinidadensis 1 U. Eocene Ky 7 11 11 -- -- II l U. Eocene RHC 1047 II II — Navet Fm. II l L.-M. Miocene RHC 1051 II II — — II l L.-M. Miocene RHC 1052 II If — — It 1 L.-M. Miocene RHC 1055 II II — — It l L.-M. Miocene B 6972 II II Lizard Springs Fm. II 1 Oligocene PM 995 If II — Cipero Fm. It l Oligo-Miocene GF 56a II II — It IT l Oligo-Miocene Wz 213 II II — Leugua Fm. 11 l U. Miocene 6 V16-200 l°58'N 37°04'W 4095 -- 710 atlantica 1 Sangamon Interglacial V16-200 1°58’N 37°o4'W 4095 -- 1080 atlantica 1 Illinoisan Glacial 7 V16-203 9°21'N 39°52'W 4l49 -- 800 II l Sangamon Interglacial 8 RC8-91 33°25'S 4l°54'W 2723 — 90 11 l Pleistocene 9 AII-155 0°3'S 27°48'W 3730-3783 — Dredge IT l Recent 10 V9-19 ll°23'S i4°15'W 3730 160-170-180 It l-l-l Sangamon Interglacial V9-19 11°23'S i4°15'W 3730 -- 260 It l Sangamon Interglacial V9-19 11°23'S i4°15'W 3730 -- 440-460 If l-l Illinoisan Glacial V9-19 11 ” 23 's i4°15'W 3730 -- 600-720 tr l-l Yarmouth Interglacial 11 V 19-297 2°37'N 12°00'W 4120 -- l4o 11 1 Yarmouth Interglacial 12 IIOE 361G 25°51'S 37°21'E 2750 2.5 Trawl casca l Recent 13 IIOE 363B 23°45'S 43°10'E 2980 2.0 Grab 11 2 Recent IIOE 363D 23°45’S 43°11'E 1605 3.6 Trawl 11 1 Recent IIOE 366c 23°09'S 43°07'E 2710 2.3 Trawl 11 1 Recent 14 IIOE 367C 22“37'S 4l°22'E 3250 1.9 Trawl it 2 Recent IIOE 367G 22 ° 42 ' S 39°19'E 3140 1.9 Grab 11 2 Recent 15 IIOE 4lOA 15°07'S 44°21'E 3100 2.2 Trawl 11 4 Recent 16 IIOE 4l6A 8°45'S 43"39'E 3850 1.4 Trawl n 1 Recent 17 RClO-161 35“05'N 158°00'E 3587 -- 80 japonica 1 Pleistocene RClO-161 35°05'N 158°00'E 3587 300 II 1 700,000 BP ( 3 I +0 cm) RClO-163 32°43'N 157°30'E 3550 — 430-520 11 1-1 Pliocene RC10-164 31°43’N 157”38'E 3766 — 250-260 II 1-1 Pleistocene RC10-164 31°43'N 157°38'E 3766 — 290 II 1 Pleistocene RC10-164 31°43’N 157°38'E 3766 — 420 II 1 Pleistocene 18 ELI 39-10 48°03.1'S 126‘‘17'E 3390 — Grab australis 20 Recent *See under Acknowledgments for sample source. NUMBER 7 3 (Benson 1965) and reduced by the heat of a very hot Bausch and Lomb microscope lamp, especially as¬ sembled for this purpose. The Leitz Panphot system with Ultrapack lenses was used with substage as well as incident lighting. The Kent-Cambridge “Stereo¬ scan” was used for the SEM photographs (all photo¬ graphs exclusive of Plate 1). Some specimens were coated with aluminum, others with gold. No discern¬ ible differences in the final product due to use of these different metals has been noted. In the section on “Systematics” the cataloged “para- types” refer only to figured paratypes. Other speci¬ mens belonging to the new species were indicated but not cataloged. The non types loaned by Dr. van den Bold reside in his collections, one holotype and para- type set ( Abyssocythere australis) is the property of the University of Kansas. Acknowledgments The author is indebted to W. A. van den Bold of Louisiana State University, Francis Parker of Scripps Institution of Oceanography (Capricorn sample, CAP 38BP), David B. Erickson and Goesta Wollin of Lamont-Doherty Oceanographic Laboratory (Vema and Chain core samples), Howard Sanders of Wood’s Hole Oceanographic Institution ( Atlantic II sample), and Meade Cadot of the University of Kansas ( Eltanin sample) for sample material and specimens. The samples of the International Indian Ocean Expedition were collected by me in 1964; the Albatross samples are property of the National Museum of Natural His¬ tory. Thanks are expressed to Joseph E. Hazel and Louis S. Komicker for their critical reviews of this manuscript and to Laurie Jennings and L. B. Isham who helped me prepare and illustrate the specimens. Work on this project and collections were funded through Smithsonian Research Foundation Grant SRF-436020 and National Science Foundation Grants GA-17325 and GA-12472. Biogeography Fossil specimens have been recovered in core and trawl or grab samples from twenty-five ocean floor localities in eighteen areas from throughout the world ocean, and from ten surface outcrops of “deep-water” strata in Trinidad (Figure 1, Table I). Sampling has been unevenly distributed, but thus far Abyssocythere seems to be: (1) cosmopolitan but restricted to sediments found in “deep” marine environments (depths usually greater than 2,000 meters and often greater than 3,000 meters; Figure 2); (2) absent (in about 50 samples) in the North Atlantic (except near the Blake Plateau in the North American Basin and'physiographically restricted deep basinal regions over 5,000 meters; and (3) divisible into distinct species, consistent morpho¬ logically and generally widely separated geographically (one in each ocean region; Figure 3). Although Abyssocythere is represented by fossils in at least eight localities in the deep sea of the equatorial and western Atlantic, ranging in age from Paleocene through late Pleistocene, only two Recent specimens have been found (one by Brady 1880, Challenger Sta¬ tion 323 off Uruguay, see discussion next section; an¬ other by me from near St. Paul’s Rocks, Station 9 of this report). Almost sixty Recent samples from the deeper parts of this region were examined in which this genus did not occur. Specimens appear concen¬ trated near the Yarmouth to Sangamon interglacial (including the Illinoisan glacial) time intervals (Table I). Abyssocythere was found at eight dredge stations in the western Indian Ocean (Mozambique Channel). No cores were examined from this area. All of the spe¬ cimens are presumed to be Recent in age. The lack of samples in the eastern Indian Ocean precludes an estimate of its importance there. But finding A. aus¬ tralis in abundance south of Australia suggests that in the future it may be found to be common in the Southern Ocean. There are obvious morphological similarities between the species of these two areas. Specimens from Pliocene and Pleistocene sediments in the Pacific are quite distinctive and morphologically distant from those found elsewhere. Two species were described from the eight Pacific stations in three regions. Solution of calcium carbonate in the great depths common to the North Pacific and lack of sam¬ ples from the South Pacific make the distribution of these species difficult to estimate. However, Abysso¬ cythere japonica was found in cores (localities 1, 3, and 17, Table I) on both sides of the Pacific. Specimens of Abyssocythere trinidadensis supplied to me by W. A. van den Bold came from ten outcrop samples ranging in age from Eocene to Miocene from Trinidad. This species was found with “Bradleya” hazelae, Krithe, and other forms characteristic of a deep marine environment and has been reported from SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Figure 1.—Localities of samples from which specimens of Abyssocythere were obtained (also see Table I) : 0 = core or outcrop (locality 5) localities; # = dredge or trawl sample localities; A = site of the JOIDES core (hole 12c, leg 2) given in Table I (Station 19) and discussed in the Addendum. strata as old as Late Cretaceous. The absence of shal¬ low benthic Foraminifera in these strata supports the hypothesis that A. trinidadensis has been a “deep¬ water” inhabitant since the Mesozoic. More data are required to determine the extent that this species and A. atlantica, which probably is a descendant, both lived in an abyssal depth. It is early yet to say, but from judgments of mor¬ phologic similarity, fossil and present distribution, some phyletic relationships among the species described here might be inferred. From the evidence at hand Abyssocythere seems to have lived on the deep-sea floor at the end or soon after the end of the Mesozoic (if the conjecture about the habitat of the Trinidad spe¬ cies is correct), and apparently it spread throughout the world ocean during the early and middle Cenozoic. During the Pleistocene it seemingly became rare and restricted in its distribution. Its present restriction to cold waters (4°C or less) is correlated with an increase in size (from about 0.9 mm to 1.1 mm) and the em¬ phasis of greater morphologic detail, including sec¬ ondary reticulation. Earlier in somewhat warmer oceans (assuming cooling of abyssal waters is a prod¬ uct of late Cenozoic history), its range was probably controlled more by substrate type and competition and less by psychrospheric conditions. Abyssocythere species are rare but widespread in deep-ocean samples. It is curious that such a morpho¬ logically complex form can be maintained through long periods of time over such great distances. There are NUMBER 7 5 60°S 30°S 0° 30°N 60°N Latitude Figure 2. —Distribution of Abyssocythere according to depth and latitude showing the tendency of the sample localities (Figure 1) to be concentrated in deep water irrespective of latitude: 0=core localities; # = dredge or trawl localities; ^===the JOIDES core sample (see Addendum). few such examples at present among other ostracode genera that admit of comparison with this one. Systematics Subclass OSTRACODA Latreille, 1806 Order PODOCOPIDA Pokorny, 1953 Suborder PODOCOPINA Sars, 1866 Family TRACHYLEBERIDIDAE Sylvester-Bradley, 1948 Abyssocythere, new genus Etymology. —Greek abyssos, Latin abyssus, deep sea. Type species. —Abyssocythere case a Benson, new species. Diagnosis. —Distinguished from other trachyleberid genera by the pattern described by its reticulum into six character complexes (described below). The retic¬ ulum varies in intensity from massive and seriform, somewhat erratic and only found associated with the character complexes, to being well developed and finely sculptured with complete primary mural nets and sec¬ ondary muri. The flange of the anterodorsum of the left valve is produced to become “eared.” The dorsal character complex has four bladelike bullae or mural processes. The anterior portion of the reticulum be¬ tween the muscle-scar node and the marginal rim is often raised (levatum). The anterior is usually rimmed and the posterior is blunt and subrectangular. The hinge has crenulate terminal elements. General outer carapace morphology.— The outer carapace can be divided into approximately six regions or character complexes (Figure 4). These fea¬ tures vary significantly from species to species. They include the reticulate marginal rim (mr), the anterior 6 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY c a s c a australis japomca Figure 3. —Five of the six species of Abyssocythere described herein as seen through variation in the patterns of the reticulum. o r Figure 4.— General morphology of the carapace exterior of Abyssocythere: or=ocular ridge; dbs=dorsal bullar series; pdb=posterodorsal bulla; gr—gamos ridge; ac=anal conulus; psn=postsulcular node; vrc=ventrolateral reticulate com¬ plex; lev= levatum; mr=marginal rim; msn= muscle-scar node. reticulate complex or levatum (lev; raised), the ven¬ trolateral reticulate complex (vrc), the muscle-scar node (msn), the postsulcular node (psn), and the dorsal bullar series (dbs) of which the aftermost, the posterodorsal bulla (pdb) is the most prominent. As stated above, the intensity of the expression of the reticulum varies within these six regions, making it possible to distinguish among species. The levatum (anterior reticulate complex) may be evenly reticulate joining the rest of the reticulum with¬ out a noticeable change in relief (as in Abyssocythere case a or A. australis) or may be raised and quadrafoil (A. atlantica ) or raised, seriform, and open (A. japonic a ). The tendency to form a discrete elevated reticulate complex, set apart from the rest of the reticu¬ lum, is distinctive of Abyssocythere. The ventrolateral ridge is comprised of a box-work structure (the ventrolateral reticulate complex, vrc) within which the reticulum forms the region of greatest carapace width. It usually has five rectangular fossae NUMBER 7 7 joined ventrally by a strong ventrolateral carina. This structure is especially well developed in casca (Plate 1: figure 4), and becomes narrowest in japonica. The muscle-scar node varies from a smooth bulbous prominence in A. trinidadensis to produced and later¬ ally elongate in australis to subdued, but murose, in casca and pannucea. The muscle-scar node is very poorly developed in japonica. The prisms of muscle scars generally interfere with both the primary and the secondary reticulation of this structure. Just posterior of the muscle-scar node and across the vertical row of fossae and laddered muri is a con¬ spicuous intramural pore on, what is called here, the postsulcular node. There are other intramural pore nodes, but this is one of the most conspicuous. From it (especially conspicuous in australis and trinidadensis) runs a ridge to the posterodorsal bulla. This “psn-pdb” ridge is called the gamos (union) ridge as it joins these other prominent features. In japonica it joins two other prominent vertical posterodorsal ridges. In australis and trinidadensis the gamos ridge is straight, whereas in the other four species it bends sharply at least once throughout its extent. In casca this bend comes at the point where a second pore (the “psn” pore being the first) interferes with continuity of the ridge. The dorsum is punctuated by the presence of the anterodorsal “ear” (prominent on the left valve only), the four mural processes of the dorsal bullae series (A, B, C, and the pdb), and the somewhat sharp posterior cardinal angle. The first (most anterior) two dorsal bullae (A, B) are usually the highest dorsally (espe¬ cially in casca) , the third (C) is often diminished (as in australis, pannucea, and trinidadensis), and the fourth or posterodorsal bulla (pdb) is the most promi¬ nent and massive (most in australis, least in atlantica). The anterodorsal bullae (A, B) are often bladelike (australis and japonica). They can be blunt or dimin¬ ished (trinidadensis) , attenuated and spinose (casca), or “cocked” (pannucea). The marginal rim is usually confined (in the left valve) to the anterior and venter (atlantica, australis, trinidadensis) ; however, japonica has both an anterior and posterior rim, whereas casca has only a trace of a rim on the anterior. The rim is crossed by muri from the reticulum. On its distal or outward margin it may have very irregular secondary reticulation. It grades anterodorsally into a flange or “ear” that is produced distally, but its relief and reticulate pattern is contin¬ uous with the main part of the carapace surface. This “ear” has a blunt spine in casca, pannucea, australis, and japonica (Indo-Pacific species) but is unadorned in the other known species (Atlantic species). In the area of the eye tubercule there is a bifurcated (ocular) ridge and the uppermost branch may be absent (pan¬ nucea), interrupted as a series of small spines (casca, and less so in japonica), or simple (atlantica, trinida¬ densis, and australis). Several pores (mostly intramural celate pores) are present in all species of Abyssocythere and are consid¬ ered homologous within the genus. One is found asso¬ ciated with the postsulcular node, usually at its ventral end. This could be homologous with the pore-conulus of Cythereis. A second prominent pore node is present in the posterior (Plate 2: figure 6) portion of the valve near the median line and is herein called the anal conulus as it occurs in the region of the anus, although its actual functional association with this organ is doubtful. Its prominence and consistency among species of Abyssocythere give reason to call attention to it as a special feature. Other pores are also present, but their homology is not yet traceable throughout all of the species with the material at hand. For further morphologic description see that discus¬ sion under the type species (A. casca). Comparisons.— Species of Abyssocythere are not demonstrably closely related to any genus known to the author. However, Abyssocythere is similar in many respects to Cythereis (sensu van Morkhoven 1963). Its hinge has crenulate anterior terminal elements (Figure 5). The median element is smooth and quite typical of Figure 5. —A diagram of the hinge of Abyssocythere showing the tooth (t) and socket (s) arrangement. 418-227 0 - 71 -2 8 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY a holamphidont hinge. The hinge is similar to that illustrated for “Cythereis” by Sylvester-Bradley in 1948 except that the posterior element is less boldly crenu- late. The anterior end is “eared” at the anterodorsal cardinal angle as is Cythereis, but its posterior is blunt rather than acuminate. The surface ornament of Abys- socythere, as described above, is unusual and diagnostic. The median ridge of Cythereis or other comparable genera is absent, but the muscle-scar node is in evi¬ dence. The V-shaped frontal scar and the four complete adductors with the lower two set somewhat oblique to the others suggest a primitive trachyleberine affinity (Figure 6). The significance of the offset of the lower m V Figure 6. —Muscle-scar pattern of the type species of Abyssocythere casca with the adductor scars (a—d), dorsal scars (d), frontal scar (f), and mandibular scar (m). two adductors is not yet understood. The surface sculp¬ ture of Abyssocythere differs from “Cythereis” (sensu Triebel 1940) in that the median ridge (mittelrippe) is poorly developed or absent (not homologous with the gamos ridge), the dorsal marginal ridge is replaced by several prominent tubercules or spines (dorsal bullar series), and the posterior marginal rim is subdued and rounded. The interior morphology of the two forms (as shown in comparison of Plate 1: figure 6 with Figure 2 of Triebel 1940) is quite similar, with the excepton of the snubbed posterior margin and less crenulate pos¬ terior tooth of Abyssocythere, as now conceived. In 1957, when van den Bold described Cythereis? trinidadensis, he made note of the distinctiveness of this form and then suggested that it may belong to a new genus. Because he had only the one species he deferred making a new taxon for which six species are now available: Abyssocythere casca Benson, new species; Madagascar Basin, Recent; herein designated the type species. A. pannucea Benson, new species; Eastern Pacific, Recent. A. atlantica Benson, new species; South Atlantic, Pleistocene. A. japonica Benson, new species; Northwest Pacific, Pleisto¬ cene. A. australis Benson, new species; South of Australia, Recent. A. trinidadensis (van den Bold), 1957, Trinidad, Paleocene to Lower Miocene. ?A. squalidentata (Brady), 1880, nomen dubium, Recent of the South Atlantic (35°S-50°W, Challenger Station 323, 1,900 fms.) ; lectotype British Museum 81.5.29 (Plate 1: figure 9). A whole specimen of an early instar with char¬ acteristics of Abyssocythere. With the immature and poorly preserved specimen at hand, it would be impractical to perpetuate this name to represent a valid species. I suggest that the name squalidentata should be suppressed. If mature specimens with soft-parts of species living in the South Atlantic are found, they should not be assigned to A. squalidentata. A new species should be described because association with the specimen in the Challenger collections would be difficult if not impossible to prove. The early instars do not possess the identifying characteristics of the different species, although they do have those of Abyssocythere. 1. Abyssocythere casca, new species Figure 7 ; Plate 1 : figures 1-8; Plate 2: figures 1-9 Etymology.— Latin casca, old. Holotype.— Left valve adult male; Plate 1: figures 1, 3, and 8; USNM 170276 (stained). Paratypes. —Left and right valves, adult female and male; Plate 1: figures 4-6; USNM 170277 (stained). Type locality.— Indian Ocean, Madagascar Basin off Tulear, Madagascar, in the vicinity of IIOE sample 363B; latitude 23°45'S, longitude 43°11'E. 2,980 meters depth; temperature approximately 2°G. Age.—R ecent; no living specimens were found. Diagnosis. —Distinguished from other species of Abyssocythere by its prominent and spinose dorsal bul¬ lar series, subdued or absent marginal rim, and high Figure 7. — Abyssocythere casca showing >f right valve; c, the hinge of the left valv cale = 100/0. 10 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY anterior. The anterodorsum of the left valve is “eared.” The anterior margin has no distinct rim and the reticu¬ late pattern of this region focuses on the muscle-scar node, with the intermediate mural design of the an¬ terior reticulate complex (levatum) suppressed in re¬ lief, but its member elements are well developed. Description. —General shape subquadrangular to subrectangular and moderately inflated as shown in Figure 7 and Plates 1 and 2. The left valve is strongly “eared” in the region of the anterior hinge element, which is crossed by a denticulate ridge. This feature is absent in the right valve. The posterior of the left valve appears blunted and is subround in lateral view because of a marginal protuberance that is missing in the right valve. The dorsal margin is marked in both valves by prominent dorsal bullae. The anterior and extreme posterior margins are denticulate. The spines of the latter regions are related to the commissure, whereas those of the dorsum emerge from the murae of the reticulum. The venter is marked by a series of subparallel ridges with the distal and strongest forming the ventrolateral ridge, the widest part of the carapace. Ornamentation. —The reticulum of the carapace (of which many aspects are discussed under the genus) consists of primary and secondary reticulation (one of the most conspicuous aspects of sculpture) with intra¬ mural pores and emergent processes forming spines, bullae, and bosses toward the dorsum and ventrolateral ridge areas. The reticulum is interrupted in the area of the muscle-scar node by the adductor and frontal muscle scars. Anterior to the muscle-scar node the reticulum is elevated to form an open to quadrafoil and multifoil pattern of muri. An intramural pore is present posteroventrally to the muscle-scar node (in the re¬ gion of the postsulcular node) and may be homologous with the pore conulus of Cythereis. No other general homology of sculptural detail is suggested. Two (celate sieve) pores (Plate 2: figures 7, 8) occur along the median line of the posterior region (Plate 2: figures 1, 6) and the one is found near the lower end of the vertical ridge of the posterodorsal bulla (Plate 2: figure 6). These latter pores are seen in A. pan- nucea from the eastern Pacific, and A. australis from the Southern Ocean. Positions of pores in the anterior regions may be conservative among other species of Abyssocythere but are not associated with prominent processes as in A. casca. The anal conulus pore is pres¬ ent as with all species of Abyssocythere. An eye tubercule is missing, and the animal is pre¬ sumed to be blind. The region of the eye tubercule is marked by an ocular ridge formed by a series of small spines (Plate 2: figure 5). This ridge is smooth, simple, or missing in other species. The ventrolateral ridge consists of an emphasized segment of the reticulum, of which the muri form a box-work structure (Plate 2: figure 4) with conjunc¬ tive intramural pores and disjunctive ventral spines. No pores seem to be associated with the spines. A larger posterior terminal spine is present. Hinge. —The hinge is mixed between holamphidont and lobodont (Figures 7b and c, Plate 1: figures 6 and 7) with the further addition of a tooth anterior to the front socket in the left valve. The anterior boss¬ like tooth of the right valve is frontally highest, lobate to crenulate with at least four well-defined subdivi¬ sions. The corresponding socket of the left valve is equally well formed with subdivisions to receive the crenulate tooth. The posterior tooth is smaller and crenulate with the subdivisions ill-defined and miss¬ ing in the corresponding socket. The median hinge element is typically holamphi¬ dont with a small, smooth anterior tooth in the left valve and with a crenulate posterior terminus. A small tooth is formed by the selvage just anterior to the socket in the left valve (first observed by van den Bold 1957 in A. trinidadensis) . Its corresponding socket is obscure in the right valve. Inner margin and duplicature. —The duplicature is typically trachyleberid with straight, moderately spaced radial pore canals. A vestibule is absent. The selvage is a simple continuation of the hinge. Muscle-scar pattern. —The frontal muscle scar is “V”-shaped; the adductors are undivided with the upper two oriented horizontally and the lower two somewhat oblique (Figure 6). Two other scars were noted above the adductors as was the presence of a small mandibular scar. Dimensions. —Adults are typically from 1.0 mm to 1.1 mm in length; 0.7 mm to 0.8 mm in height. The slightly more elongate forms are considered as males. Soft-part anatomy.— No living specimens with “soft-parts” were found. Material. —Fourteen recent specimens of this spe¬ cies were considered for this study, all obtained from dredges, trawls, and grabs from the depths of Mozam¬ bique Channel, in Madagascar Basin and North Madagascar Basin. Their localities are listed in Table I. NUMBER 7 11 Ecology. —With one exception (IIOE 363D, depth 1,605 meters) all specimens were found in depths greater than 2,700 meters with the deepest find at 3,850 meters. The sediment type was pelagic globig- erinid ooze. The temperature range was less than 2.0°C about a mean of about 2.0°C. This species is psychrospheric and abyssal. Remarks. — Abyssocythere casca , the type species of the genus and the best known of those described here, appears to be morphologically conservative over its range. The processes and reticulate pattern that distin¬ guish it from other species seem to be most like A. australis, which is closest in age and geography. This and other relationships are given above under consid¬ eration of variation within the genus. Van Morkhoven (1963) remarked that the crenu- late anterior hinge of Cythereis is always higher proxi- mally than it is distally. The significance of this obser¬ vation with regard to this hinge element in other genera is unclear. It may be noted, however, that in Abyssocythere casca the converse is true, with the anterior tooth higher distally. 2. Abyssocythere trinidadensis (van den Bold) 1957 Figures 8, 9; Plate 3: figures 4, 5, 6. Cythereis? trinidadensis van den Bold, 1957:8, pi. 3: figs. la—d; 1960:165. Holotype. —Whole specimen, originally designated by van den Bold 1957, is figured for the first time herein, Figure 8; Plate 3: figure 6; USNM 562037. The specimen figured by van den Bold (1957, pi. 3: fig. 1) was much younger (Oligo-Miocene; Cipero Fm.) than the holotype. Hypotypes. —Figured (Plate 3: figure 5) left valve; USNM 170278; right valve USNM 170279 (Figure 9; Plate 3: figure 4). Type locality.— The Navet Formation, lower and middle Eocene of southwestern Trinidad (San Fer¬ nando Bypass, RHG Sample 1047). Age. —According to van den Bold (1957) this spe¬ cies is found in strata ranging in age from Late Creta¬ ceous to Late Miocene. A form transitional between A. trinidadensis and A. atlantica was found (but later lost during examination) in the Pleistocene of the western portion of the North American Basin. Diagnosis. —Distinguished from other species of Abyssocythere by exterior features of the carapace such as its bulbous muscle-scar node, a massive anterior reticulate field (without a distinct levatum) between the muscle-scar node and the anterior marginal rim. It is usually somewhat smaller (length 0.8-0.9 mm) and more massive than the other species (average 1.1 mm in length). The straight gamose ridge and poste¬ rior marginal rim are pronounced in some older (Eocene) specimens, but less so to negligible in younger (Miocene) forms. The internal features of the cara¬ pace are similar to the type species and typical of the genus. Remarks. —In his original description van den Bold (1957) noted that Cythereis ? trinidadensis had “slightly grooved terminal teeth ... a crenulate ante¬ rior tooth . . . and a peculiar tooth in front of the ante¬ rior socket of the left valve,’' which separated this form from Cythereis. He also called attention to the poste¬ rior rim, the ridge connecting the muscle-scar node to the anteriormost member of the dorsal bullar series, and the reticulate ventrolateral ridge. Professor van den Bold kindly sent fourteen addi¬ tional specimens (belonging to him) of Abyssocythere trinidadensis, besides the type, to me for the writing of this report. These included specimens (see Table I) from the upper Eocene (samples Renz 75; see Plate 3: figure 5; Ky 7; see Figure 9 and Plate 3: figure 4, RHC 1051, 1052, and 1055); Lizard Springs, Oligo- cene (B6972); Cipero Formation, Oligo-Miocene, Globorotalia fohsi lobata Zone (PM 995 and GF 56a, Figure 3) ; and the Lengua Formation, upper Mio¬ cene, " Globorotalia menardii” Zone (Wz 213). Evolutionary change in the morphology of this spe¬ cies throughout the Cenozoic seems to be slight. The older Eocene specimens are generally ten percent shorter than Miocene forms and twenty percent shorter than known Pleistocene and Recent species. Features such as the gamos ridge, ventrolateral ridge, dorsal bul¬ lar series, and marginal rims are more discrete and pronounced on a generally more massive carapace (Figures 8 and 9). The larger younger forms assume a more delicate aspect but are still more massive and smaller than modern abyssal species. Abyssocythere trinidadensis seems to be ancestral to A. atlantica. A. atlantica originated from A. trinidaden¬ sis and became larger with a better developed sec¬ ondary reticulation and a generally finer, more delicate reticulum. The muscle-scar node of A. atlantica is at¬ tenuated compared with the bulbous node of trinida¬ densis. A specimen (now lost) of an intermediate form 12 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Figure 8.-—Stereophotographic pairs of the holotype (USNM 562037) of Abyssocythere trini- dadensis van den Bold as seen from the lateral, posterodorsal oblique, and ventrolateral oblique views (magnification X 80). of Pleistocene age was found in a core (Lamont A 156- 1, 370 cm) in 1,005 meters depth from the North Amer¬ ican Basin off Florida (Locality 4). This specimen was about 1.0 mm in length. It had the massive aspect of the younger (Miocene) trinidadensis, especially in the region anterior reticulate complex or field (compared to the emerging levatum of A. atlantica) ; its gamos ridge was diminished like atlantica; and there was a NUMBER 7 13 Figure 8.—Continued trace of the posterior rim remaining. The shallower depth (1,005 meters) may have influenced the size and massive aspect of the carapace of all of these older forms, but its development from a small and massive aspect, with prominent but fewer muri, to a larger form, with produced but more delicate prominences and secondary reticulation, is indicated by the speci¬ mens at hand. Morphological comparisons of this species with the others described herein are given under the discussion of the genus. Dimensions. —Length of holotype, 0.90 mm; height 0.58 mm. Length of hypotype figured herein 0.90 mm; height 0.60 mm. Material. —Only fossil specimens are known. Four¬ teen specimens from Trinidad ranging in age from Eocene to Miocene were considered (see Table I). Paleoecology. —Considering the size, architecture, and faunal association of the older specimens (Eocene) in comparison with the morphology and distribution of the youngest related (A. atlantica) species, one would estimate that A. trinidadensis was upper bathyal (500 to 1,000 meters) rather than abyssal. If, however, the waters were warmer during the Early Cenozoic, the animals could possibly have lived at greater depths. The present psychrospheric species are larger and more delicate, yet their general faunal association is similar. A. trinidadensis has no eye tubercule and is presumed blind, suggesting again a habitat at considerable depth. 3. Abyssocythere atlantica, new species Figure 10; Plate 3: figure 1 Holotype.— Left valve adult, sex unknown. Plate 3: figure 1;USNM 170280. Paratypes. —-USNM 170281. Type locality. —Equatorial and southern Atlantic in the region of Lamont core V9-19, latitude 11°23'S, longitude 14°15'W, depth 3,730 meters, horizon ap¬ proximately 460 cm down in core. Age. —Pliocene to Recent; found in JOIDES core in Cape Verde Basin (Hole 12c Core 4, 100-106 cm level, see Addendum; in Middle to Upper Pliocene strata; found in seven cores in strata dated as Pleisto- scene (Yarmouth, Illinoisian, Sangamon) by plank- 14 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Figure 9.—Stereophotographic pairs of a hypotype (USNM 170279), right valve of Abyssocythere trinidadensis from the upper Eocene of Trinidad (van den Bold locality Ky 7; magnification X 80). NUMBER 7 15 Figure 10.- — Stereophotographic pairs of the holotype (USNM 170281) of Abyssocythere atlantica, new species, a left valve from the Pleistocene of the equatorial Atlantic (see text) from lateral view and anteroventral oblique view (magnification X 80). 16 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY tonic Foraminifera (Erickson and Wollin 1964) and one Recent dredge sample. None have been found liv¬ ing at the time of this report. The range, in shallow core penetration (Pleistocene record) below sediment- water interface, is from 160 to 800 cm. Occurrence in deep penetration JOIDES core approximately 3,360 cm below sediment-water interface. Diagnosis. —This species of the genus Abyssocy- there can be distinguished by external carapace fea¬ tures such as its attenuated muscle-scar node (often spinose), a raised anterior reticulate complex (leva- tum), the presence of a murose anterior marginal rim but no posterior marginal rim (on the left valve), a suppressed gamos ridge, secondary reticulation, and prominent, yet spineless, anterodorsal “ear. 5 ' The in¬ ternal features are like that of the type species and typical of the genus. Remarks. —This species, which is thought to be a descendant of A. trinidadensis (see Remarks under that species), is large and delicately ornate. Its levatum is similar to that of A. japonica, except that it has inner muri, making it multifoil rather than seriform and open. Its ventrolateral reticulate complex is also well developed like A. case a, whose dorsal bullar series is more produced, and has no discrete anterior marginal rim. Its posterodorsal bulla is angular but less pro¬ duced than A. australis and is not as complex as A. japonica. Dimensions. —Holotype, length 1.15 mm; height 0.73 mm. Material. —Only fossil forms have been found, all from the equatorial and southern Atlantic. One Re¬ cent specimen (a right valve) was found, also from the equatorial Atlantic (locality 9, Figure 1). In all fif¬ teen specimens were found. Their localities and hori¬ zons are listed in Table I (see Addendum for data on JOIDES core specimen from Cape Verde Basin). Ecology. —Although no living specimens and only one Recent specimen were found, it seems unlikely that the older fossil specimens have ever been in an environment different than the one now extant in the area where they were found. With the exception of the transitional form discussed in the preceding section (Remarks; under Abyssocythere trinidadensis, which see), all occurred in depths greater than 2,700 meters and most samples (six of seven) were collected in depths greater than 3,700 meters. Three of the deep¬ est records of Abyssocythere were with this species, all over 400 meters (4,095, 4,120, 4,149, and 4,542 meters). The structure of the eye tubercule indicates the species was (is?) blind. A atlantica is presently considered a true psychrospheric, abyssal species. 4. Abyssocythere japonica, new species Figure 11; Plate 3: figure 3 Holotype. —Left valve adult, female(?); Plate 3: figure 3; USNM 170282. Paratype. —Right valve adult, male(?); USNM 170283. Type locality. —Northwestern Pacific, east of Ja¬ pan, vicinity of Lamont core RC10-163; latitude 32° 43'N, longitude 157°30'E; 3,550 meters depth. Age. —Pleistocene-Pliocene; holotype found at 430 cm below sediment-water surface in core (RG10-163), other specimens found in core samples ranging in sediment penetration from 80 to 420 cm (see below under Material). Diagnosis. —Distinguished from other species of Abyssocythere by external features of the carapace, such as the well-developed muri of the reticulum that form vertical ridges in the middorsal and posterodorsal region of the carapace running obliquely from the muscle-scar node and the postsulcular node to the posterior three members (B, C, and pdb) of the dorsal bullar series; by the open, seriform muri of the levatum; and especially by the presence of a posterior marginal rim (best developed in the right valve, present in both). The muscle-scar node is not well developed, the ventrolateral reticular complex is abbreviated. Internal features of the carapace are similar to the type species and typical of the genus. Remarks.— The presence of strong seriform mural ridges and marginal rims separates this species from others with sufficient morphologic difference to be recognized as a separate taxon, however, its geographic remoteness is enough reason to suggest its status as a separate species. As with the other Abyssocythere species found in the deep sea, it has secondary reticula¬ tion. The anterior and posterior teeth are both crenu- late but narrow. This species is an end member of a morphologic series. For more comparisons see discus¬ sion of morphologic features under the genus. Dimensions. —Holotype, 1.1 mm long, 0.6 mm high. Paratype, 1.2 mm long, 0.7 mm high. Material. —Only fossil specimens were found. Six specimens were found in three cores (RC 10-161, NUMBER 7 17 Figure 11.—Stereophotographic pairs of the holotype (USNM 170282) of Abyssocythere japonica , new species, a left valve from the northwestern Pacific (see text) from lateral view and anteroventral oblique view (magnification X 80). 18 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY 163, and 164) from the northwestern Pacific (locality 17, Figure 1) ; one specimen was found from a core (CAP 38P) from the east central Pacific (locality 1, Figure 1). Ecology. —Specimens from all four cores were ob¬ tained from depths exceeding 3,400 meters, in “glo- bigerinid” ooze. The average temperature is estimated at near 2°C. The great disparity in distance between the main group of samples and the one isolated sample is probably due to the lack of available samples and the scarcity of calcareous sediments from the central and northern Pacific. Abyssocythere japonica is probably widespread in the Pacific. It is blind, abyssal, and psychrospheric. 5. Abyssocythere australis, new species Figure 12; Plate 3: figure 7 Holotype. —Left valve, adult, sex unknown, Figure 12, Plate 3: figure 7, University of Kansas, Museum of Paleontology No. 1007897. Paratype. —Right valve, adult, sex unknown, KU 1007898. Type locality. —The Southern Ocean about half¬ way between Australia and Antarctica on the Indian- Antarctic Rise in the vicinity of Eltanin Station 39-10 (longitude 126°16.6'E, latitude 48°03.1'S) at a depth of 3,390 meters. Age. —Recent; no living specimens were found. Diagnosis. —Distinguished from other species of the genus Abyssocythere by its relatively bold general sur¬ face carapace features. The produced muscle-scar node slopes toward the anterior as a broad ridge sup¬ porting the reticulum until it diminishes beneath the anterior reticulate complex, which is without special relief. The dorsal bullar series is pronounced with a very pronounced posterodorsal bulla. The ventrolat¬ eral reticulate ridge also stands high in relief relative to the rest of the carapace. The anterior marginal rim is well developed but not pronounced; the posterior mar¬ ginal rim is absent. Secondary reticulation is present and more massive than in other species. The internal features are similar to those of the type species and typical of the genus. Remarks. — Abyssocythere australis has a boldness in the relief of the character complexes, characteristic of this genus, except for the anterior reticulate complex in which a levatum is absent. Whereas A. japonica has an emphasis in the development of muri, especially in the dorsomedian and posterodorsal areas, the relief boldness of A. australis underlies the muri from an enlargement deeper within the carapace wall struc¬ ture. This aspect is also noted in A. atlantica, but only in the region of the ventrolateral reticulate complex. Other comparisons are given in the discussion of gen¬ eral carapace morphology of the genus. Dimensions. —Holotype, length 1.1 mm, height 0.72 mm. Paratype, length 1.1 mm, height 0.6 mm. Material. —The one Recent sample '(Eltanin 39- 10) had 20 specimens, all fossil (see Table I). Ecology. —Blind, psychrospheric, abyssal. The sin¬ gle sample containing specimens came from 3,390 meters depth. No further environmental data is pres¬ ently known. 6. Abyssocythere pannucea, new species Plate 2 : figures 9-11; Plate 3: figure 2 Etymology. —Latin pannuceus, wrinkled. Holotype. —Left valve adult(?), presumed male; Plate 2: figures 9-11, USNM 170286. Paratype.— Right valve, adult, USNM 170287, Type locality. —Vicinity of U.S. Fisheries ship Albatross Station 4693 near Easter Island in the south¬ eastern Pacific (latitude 26°30'S, longitude 105°45'W, 2,089 meters depth, temperature approximately 2°C). Age. —Recent; no living specimens were found. Diagnosis. —The most elongate of all of the spe¬ cies of Abyssocythere; also distinguished by its broad anterior rim with irregular secondary reticulation, poorly defined anterior and posteroventral reticulate complexes, low dorsal profile, the absence of an ocular ridge, a second (B) “cocked” dorsal bulla, and even, uniform development of primary reticulation. Remarks.— Although only two specimens (two penultimate or possible adult instars), a left (holo¬ type) and a right (paratype) valve, were available for study, their outer surface was examined in considerable detail. This is the least secure species of the group de¬ scribed here. It has been given a name with the hope that what appear to be diagnosable differences in mor¬ phology will be confirmed by specimens yet to be found. The primary muri of the broad marginal rim are suppressed, and the secondary reticulation is very irregular. Most of the rest of the secondary reticula¬ tion is open and quite regular. The muscle-scar node is not prominent. An oblique ridge running between the adductor and frontal muscle-scar is conspicuous NUMBER 7 Figure 12.-—Stereophotographic pairs of the holotype (USNM 170284) of Abyssocythere australis, new species, a left valve from the Southern Ocean south of Australia (see text) from lateral view and anteroventral oblique view (magnification X 80). 20 as it is also in A. japonica and A. atlantica. The gamos ridge is straight, joining a moderate posterodorsal bulla. The second bulla of the dorsal series (B) is “cocked” posteriorly. This is especially pronounced in the right valve. In the rest of the species of Abyssocythere this particular bulla stands erect as a spine (A. case a) or simply as a ridge (A. trinidadensis and A. atlantica). Dimensions. —Holotype, length 0.93 mm; height 0.60 mm. Paratype, length 0.85 mm; height 0.55 mm. Material. —Five fossil specimens were obtained from the eastern Pacific in the vicinity of Easter Island and just west of Costa Rica (see Table I). Of these, only two, those illustrated (Plate 2: figures 9-11 and Plate 3: figure 2), were mature or near mature. Ecology. —Found in waters over 2,000 meters deep, one sample in almost 3,300 meters. Blind, psychro- spheric, abyssal. The ambient bottom temperature at one station (Table I) was 1.9°C. Addendum After the final typescript had been prepared, a single specimen of Abyssocythere atlantica was found in a JOIDES core ( Glomar Challenger Hole 12c of leg 2) in Cape Verde Basin (latitude 19°40'N, longitude 26° 01'W) at approximately 3,360 cm below the sediment- water interface (level 100-106 in Core 4). This hori¬ zon was identified as middle(?) Pliocene, probably Zone N. 20 or the upper part of Zone N. 19 on the basis of the Foraminifera present. The ocean floor in which the hole was drilled was 4,542 meters below the surface. This record of Abyssocythere atlantica represents its most northeastward, its deepest, and its oldest known occurrence. The specimen (USNM 170294), which was somewhat obscured by chalk or marl, nevertheless, was clearly identifiable as A. atlantica without notice¬ able difference from specimens found in Pleistocene sediments to the south and west. SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Literature Cited Benson, R. H. 1965. Photography of Microfossils. Handbook of Paleon¬ tological Techniques, pages 433—446. Edited by B. Kummel and D. Raup. San Francisco and Lon¬ don: W. H. Freeman and Co. 1969. Preliminary Report on the Study of Abyssal Ostra- codes. The Taxonomy, Morphology, and Ecology of Recent Ostracoda, pages 475-480. Edited by J. W. Neale. Edinburg: Oliver and Boyd. 1970. Architectural Solutions to Structural Stress in Rigid Micro-Organisms, Through SEM Examination. Proceedings of 3rd Annual Stereoscan Colloquium, 1970, pages 71-77, figures 1-13. Kent-Cambridge Scientific, Inc.. Private Publisher. Bold, W. A. van den 1957. Ostracoda from the Paleocene of Trinidad. Micro¬ paleontology, 3:1-18, plates 1-4. 1960. Eocene and Oligocene Ostracoda of Trinidad. Micropaleontology, 6:145-196, plates 1-8. Brady, G. S. 1880. Report on the Ostracoda Dredged by H.M.S. Challenger During the Years 1873—1876. Reports on the Voyage of H.M.S. Challenger, pages 1-184, plates 1—43. Erickson, D. B., and G. Wollin 1964. The Deep and the Past. 292 pages. New York: Alfred A. Knopf. Fisheries, United States 1906. Dredging and Hydrographic Records of the U.S. Steamer Albatross for 1904 and 1905. Bureau of Fisheries Document 604. Morkhoven, F. P. C. M. van 1963. Post-Palaeozoic Ostracoda: Their Morphology, Taxonomy and Economic Use. Volume 2. Amster¬ dam: Elsevier Publishing Co. Sylvester-Bradley, P. C. 1948. The Ostracode Genus “Cythereis.” Journal of Paleontology. 22:792-797, plate 1. Sylvester-Bradley, P. C., and R. H. Benson. 1971. Terminology for Surface Features in the Ornate Ostracodes. Lethaia, 38 pages. Triebel, E. 1940. Die Ostracoden der Deutschen Kreide. Senckenber- giana. 22:160-227, plates 1-9. Plate 1.— Abyssocythere casca, new species: exterior views of left (1) and right (2, 5) valves of paratypes (USNM 170277a); interior views of left (3) and right (6) valves with enlarge¬ ment of the anterior hinge tooth and postjacent socket (7) showing crenulation; exterior view (4) of holotype (USNM 170276). 8, Right valve of late instar Abyssocythere aff. A. japonica, new species, from the eastern Pacific (locality 3, see Table I). 9, Left valve of the lectotype (BM 81.5.29) of Abyssocythere squalidentata (Brady) 1880, designated nomen dubium herein, an early instar from Challenger Station 323 in the South Atlantic. All magnifications X 50 except Figure 7 which is X 160. Plate 2 .—Abyssocythere casca, new species: (1) left valve of paratype (USNM 170277b) with views of the posterodorsal bulla (2), the posterior (3), the ventrolateral reticulate complex (4), the ocular ridge (5), the posterodorsum with anal conulus arrowed (6), an intramural pore and detailed view of secondary reticulation (7), a. celate pore with sieve plate (8, enlargement of Figure 7). Abyssocythere pannucea, new species: left valve (9) of holotype (USNM 170286), the anterodorsum (10) showing a suppressed ocular ridge, the dorsocentral region of the same left valve (11) showing the fine structure of the reticulum on the muscle-scar node, the postsulcular node, three elements of the dorsal bullar series, and parts of the gamos ridge and ventrolateral reticulate ridge. The scales indicate 100/i, 10/t, and 1 ytt. Plate 3. —Abyssocythere atlantica, new species: 1, left valve, holotype (USNM 170280; X 80); 8, muscle-scar node and postsulcular node (X 180). Abyssocythere pannucea, new species: 2, right valve, paratype (USNM 170287; X 55). Abyssocythere japonica , new species: 3, left valve, upper Eocene (Ky 7) hypotype (USNM 170279; X 65) ; 5, left valve, Oligo-Miocene valve, holotype (USNM 170282; X 55). Abyssocythere trinidadensis van den Bold: 4, right (GF 56a; Cipero Fm) hypotype (USNM 170278; X 65); 6, left valve, holotype (USNM 562037; X 65). Abyssocythere australis, new species: 7, anterior portion of the holotype (USNM 170284) showing details of the reticulum (X 80). NUMBER 7 U. S. GOVERNMENT PRINTING OFFICE : 1971 0 - 418-227 Publication in Smithsonian Contributions to Paleobiology Manuscripts for serial publications are accepted by the Smithsonian Institution Press subject to substantive review, only through departments of the various Smithsonian museums. Non-Smithsonian authors should address inquiries to the appropriate department. 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