SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY NUMBER 11 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 mailing lists 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 G. Arthur Cooper SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY NUMBER 11 Homeomorphy in Recent Deep-Sea Brachiopods SMITHSONIAN INSTITUTION PRESS CITY OF WASHINGTON 1972 ABSTRACT G. Arthur Cooper. Homeomorphy in Recent Deep-Sea Brachiopods. Smithsonian Contributions to Paleobiology, number 11, 25 pages, 5 figures, 4 plates. 1972.—A col¬ lection of brachiopods from the Baja California Abyssal Plain forms a deep-sea assemblage unusual in that it contains three genera that are unrelated but externally almost identical; i.e., they .are homeomorphs. One is Neorhynchia, an impunctate rhynchonellid; the second, a punctate terebratulid with short loop, is called Abysso- thyris; and the third is referred to a new genus, Notorygmia, related to Macandreuia. A discussion of homeomorphy is followed by the systematics of the genera and species involved. Official publication date is handstamped in a limited numb ex of initial copies and is recorded in the Institution’s annual report, Smithsonian Year. UNITED STATES GOVERNMENT PRINTING OFFICE WASHINGTON : 1972 For sale by the Superintendent of Documents, U.S. Government Printing Office Washington, D.C. 20402 - Price 50 cents (paper cover) Contents Page Introduction . 1 Homeomorphy . 1 Sulcation . 3 Locality data . 4 Baja California Abyssal Plain . 4 West-southwest of Cortes Bank . 5 Of! Central California, South of Davidson’s Seamount . 5 Off Baja California . 5 Antarctica . 5 Systematics . 5 Neorhynchia strebeli (Dali) . 6 Neorhynchia profunda, new species. 6 Abyssothyris elongata, new species . 9 Notorygrnia, new genus . 13 Notorygmia diamantina (Dali) . 13 Notorygrnia abyssa, new species . 14 Waldheimia (?) wyvillei (Davidson) . 15 Appendix . 15 Pelagodiscus atlanticus King. 15 Literature cited . 15 G. Arthur Cooper Homeomorphy in Recent Deep-Sea Brachiopods Introduction The collection that forms the subject of this paper was sent to me by Mr. Spencer R. Luke of the Aquarium Museum, Scripps Institution of Oceanog¬ raphy, La Jolla, California. Most of the material was collected by Professor Carl Hubbs and collaborators of the Scripps Institution whose work was supported by NSF Grants Nos. GBS 13319 and GS 1300. Per¬ mission to describe the material was kindly granted by Dr. William A. Newman. I am grateful to all of these men for their generosity in permitting this study and for permitting retention of the type speci¬ mens and study set in the national collection. These specimens and those retained by Scripps constitute the finest collection of abyssal brachiopods yet made. Thanks are given to Dr. Helen McCammon, Field Museum of Natural History, Chicago, and to Dr. Richard E. Grant for critically reviewing this paper. Their suggestions proved helpful and valuable. Thanks are also due to Mr. Lawrence B. Isham, visual information specialist at the National Museum of Natural History for his fine drawings of the lophophore of Neorhynchia and Abyssothyris. Homeomorphy Homeomorphy, or convergence of exterior form, in Recent brachiopods occurs in three unrelated genera inhabiting the Baja California Abyssal Plain off the coast of California. Association of these genera is not confined to the Baja California Abyssal Plain but has been identified in the Pacific south of Cali¬ fornia to the Antarctic. The associated genera are Abyssothyris, Neorhynchia, and Notorygmia (a new G. Arthur Cooper, Department of Paleobiology, Smith¬ sonian Institution, Washington, D. C. 20560. genus for the species hitherto identified as Macan- drevict diamantina Dali). The homeomorphy ex¬ hibited by Abyssothyris and Neorhynchia was de¬ scribed by Muir-Wood (1960). The example from the Baja California Abyssal Plain is more remarkable because it involves three genera having almost iden¬ tical external form and representing two orders and three superfamilies of brachiopods. So precise is the homeomorphy that the first two genera were mis¬ taken and described under the name Terebratula wyvillii by Thomas Davidson (1878), a usually as¬ tute observer and the most widely informed brachio- pod worker of the last century. Homeomorphy is common among the brachiopods and has attracted considerable attention. Examples from the Paleozoic Era have been described by Cooper (1930), Ulrich and Cooper (1936), and Bell (1938); and from the Mesozoic by Cloud (1941) and Buckman (1901, 1906). Cooper (1970, p. 238) indicated homeomorphy in Tertiary and Recent brachiopods. Mimicry of external form in the brach¬ iopods often is so deceptive that it has led to diffi¬ cult problems in classification and identification. The confusion created by homeomorphy is nowhere bet¬ ter shown than that revealed by Muir-Wood in Abys¬ sothyris and Neorhynchia. Although this astute worker was aware of the pitfalls of homeomorphy, the third member of the trio mentioned above escaped her. Abyssothyris was proposed by Thomson (1927, p. 190) for the deep-sea species Terebratula wyvillii Davidson (1878) taken from collections made by the Challenger Expedition. Specimens were taken from depths ranging from more than 6,000 feet (1,830 m) to deeper than 17,000 feet (5,183 m). The species was named after Wyville Thomson, and the name was later corrected to T. wyvillei (Thom- 1 2 son, 1927, p. 199). In studying Davidson’s described and figured specimens in the British Museum (Nat¬ ural History), Muir-Wood discovered that another species, Neorhynchia strebeli (Dali), was misidenti- fied by Davidson as T wyvillei. Davidson’s speci¬ mens all came from the Southern Hemisphere off Australia, the Falkland Islands, and Chile. Neorhynchia also was named by Thomson (1915, p. 388), who selected Hemithyris strebeli Dali from the mid-Pacific as the type species. These two brach- iopods, A. wyvillei and N. strebeli, share a feature— their sulcate anterior commissure—that makes them similar in appearance and has caused the confusion between the genera. These brachiopods are anteriorly folded toward the ventral side; thus, the ventral valve has a marked median fold, and the dorsal valve has a median sulcus of varying depth. In a survey of the brachiopods in the National Museum, Dali (1920) designated type localities for each of the species. This was done in ignorance of the generic composition of the lots taken from some of the named localities. In the case of Terebratula (Abyssothyris) wyvillei, Dali (1920, p. 321) stated: “As Davidson appears to have selected no special locality among those he enumerates in the Challenger Report, I choose station 299, off Valparaiso, Chile in 2160 fathoms [12,960 feet], gray mud, bottom temperature 34°F.” Not realizing the role that home- omorphy can play in such matters, Dali inadvertently selected a locality where specimens of Neorhynchia misidentified by Davidson as Abyssothyris occur. Also taken at this station was another brachiopod, Waldheimia wyvillii Davidson, which will be referred to later. Muir-Wood (1960, p. 523) states: Unfortunately the only specimens preserved from here [Challenger station 299] are both Neorhynchia, one of which was figured by Davidson in 1880 (pi. 2, figs. 8, 8a), also in 1886 (pi. 2, fig. 9), no. ZB 1161 as T. [Terebratula, the generic name used by Davidson] wyvillei [Muir-Wood over¬ looked the occurrence of Waldheimia wyvillii at the same station]. If Dali’s selection is to be accepted then the type specimen of Terebratula wyvillei is a rhynchonellid and Abyssothyris would have to be replaced and become a synonym of Neorhynchia. Abyssothyris wyvillei would be¬ come Neorhynchia wyvillei. The terebratulid Abyssothyris sens. str. would be left without either a generic or specific name and would have to be renamed. Muir-Wood further points out that the question of inclusion of a type locality in the description of a new species was not embodied in the new Inter- SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY national Code of Zoological Nomenclature. She also indicates that inasmuch as “Dali’s selection was made in 1920 and that the rules of that date did not pro¬ vide for the definition of a nominal species by ref¬ erence to a type locality, the selection can be set aside, and a lectotype chosen from another Chal¬ lenger Station.” This recommendation was followed by the designation of specimen ZB 1160 (from Chal¬ lenger station 160 at 2,600 fathoms) as the lecto¬ type. 1 The type thus fixed is wider than long and has a narrow, deep fold on the ventral valve and a nar¬ row, deep sulcus on the dorsal valve. The lectotype measurements, in millimeters (taken from Muir- Wood, 1960, pi. 7, figs. 5a-c), are as follows: length 12.5, width 14.5, and thickness about 8.0. A second specimen (Muir-Wood, 1960, pi. 7, figs. 3a-c) has the following measurements: length 12.7, width 12.7, and thickness 8.0. Thus, the specimens are slightly wider than long or are equal in length and width, quite unlike those from the Baja California Abyssal Plain that are described below. An immature speci¬ men illustrated by Muir-Wood (1960, pi. 7, fig. 1) is slightly longer than wide: length 10.5mm and width 9.5 mm. Specimens of Neorhynchia misidentified by David¬ son as Terebratula wyvillii were taken by the Chal¬ lenger at station 184 south of New Guinea at 1,400 fathoms and at station 299 off Valparaiso, Chile, at 2,160 fathoms. A specimen from the former locality is 15 mm long by 16.5 mm wide, representing a shell with width greater than the length. The sulcus is broad and shallow and the fold low. Study of the specimens submitted by Scripps Insti¬ tution complicates matters still further. Comparison of the types of Terebratula wyvillii, Hemithyris ( Neorhynchia) strebeli Dali, and Macandrevia ( No - torygmia) diamantina with the specimens from the Baja California Abyssal Plain indicates that the latter are not the same as Davidson’s and Dali’s species. When plotted with the large collection of Neorhyn¬ chia from the Baja California Abyssal Plain, the specimen of N. strebeli falls entirely outside the range of variation of the largest California speci¬ mens. Examples of Macandrevia diamantina from off Cocos Island, west of Panama, the type locality, 1 Article 16(b) of the 1961 edition of the International Code of Zoological Nomenclature adopted by the XV International Congress of Zoology specifically rules out mention of a type locality as an “indication” in establishing a type species. NUMBER 1 1 3 are yellow, fiat, and expanded, whereas specimens from the Baja California Abyssal Plain are trans¬ lucent white, very deep, and elongated. Other speci¬ mens of this sulcate type of Macandrevia from loca¬ tions farther south and in Antarctic seas are similar to the California specimens rather than to those from off Cocos Island. Abyssothyris wyvillei, primarily a southern species, is deeply sulcate and wider than long. Dali’s specimens identified as A. wyvillei from southwest of the Galapagos are not like Davidson’s specimens, nor are they close to those from the Baja California Abyssal Plain. We do not have collections large enough from Dali’s localities or other areas yielding these three genera to discover the relation¬ ship of these species to those from the Baja California Abyssal Plain. All of the scattered specimens of these three genera are more like those of the Baja California Abyssal Plain than they are like Dali’s and Davidson’s type specimens. Sulcation The majority of articulate brachiopods (class Arti- culata) have a median fold—a device thought to facilitate filter feeding—separating the incoming streams with food from the excurrents bearing body waste. So many brachiopods are folded toward the dorsal side in the adult condition that this is re¬ garded as normal for articulate brachiopods. Folding in the opposite direction—toward the ventral side, the ventral valve having a fold and the dorsal valve an opposing sulcus—is rare in the adult condition of the articulate brachiopod. Among early brachio¬ pods many are ventrally folded in the young, but folding direction reverses in growth, and the more usual condition of uniplication, the dorsal valve with fold, is established in the adult. Heterochronous homeomorphs of Abyssothyris and Neorhynchia have existed since Silurian time. Of impunctate brachio¬ pods, Brachymimulus, a member of the Triplesiacea, has a form almost identical to that of Neorhynchia, but it has a long, forked cardinal process and en¬ tirely different ventral beak structures. In the Mis- sissippian the rhynchonellid Sanjuania is similar in shape to Neorhynchia, as is Paranorella of the Per¬ mian. Camarophorina is a smooth, sulcate steno- scismatacean from the Permian identical in form to Neorhynchia, Brachymimulus, and Sanjuania. No- rella is a sulcate rhychonellid of the Triassic. Thus, homeomorphs of Neorhynchia have existed since the Silurian. A similar series of heterochronous homeomorphs exists among the punctate brachiopods and dupli¬ cate the exterior form of Abyssothyris and Notoryg- mia. In the Permian, Cryptacanthia and Glossothy- ropsis are almost identical homeomorphs of the two modern genera. The loop of Glossothyropsis is like that of Notorygmia but it does not have a septal pillar in the initial stages of its development. Nu- cleata, Nucleatula, and Dinarella are short-looped punctate forms from the Mesozoic that ape Abys¬ sothyris. In the Pliocene of the Mediterranean region “Terebratula” meneghiniana Seguenza, because of its sulcate commissure, has been referred to Abys¬ sothyris (Muir-Wood, 1960, p. 524; Thomson, 1927, p. 201) even though its interior has not been analyzed. Of some interest in the Permian is an association like that of Abyssothyris and Neorhynchia. In the black shale and limestone of the South Wells Mem¬ ber of the Cherry Canyon Formation, Paranorella, a sulcate rhynchonellid, occurs with Glossothyropsis, a long-looped terebratulid. The fact that the homeomorphs of the Baja California Abyssal Plain are deep-water dwellers and that these genera are in deep water wherever found suggests that sulcation may be a phenomenon of deep water. This suggestion might also hold for the association of the homeomorphs Paranorella and Glossothyropsis in the Permian. The South Wells Member, in which this association occurs, is regarded in some quarters as of deep-water origin, but not abyssal as in the modern examples under discussion. Unfortunately for this idea, sulcation is not confined in modern brachiopods to the abyss or even to moderately deep waters. Shallow-water, sulcate genera are fairly common: Terebratella, Magellania, Tere- bratalia, and Waltonia to name the most conspicu¬ ous ones. Some of these, such as the last two, actually may live in the tidal zone. Among the fossil forms noted above, none save possibly Para¬ norella and Glossothyropsis can be connected with a deep-water environment. Glossothyropsis is fairly common in some normal marine environments that definitely can be identified as shallow water. This is true also of the Silurian and Mesozoic homeomorphs mentioned above whose associates and paleogeog- raphy indicate shallow-water environment. What¬ ever the evolutional pressure toward sulcation, it apparently is not great depth of water. 4 Locality data Baja California Abyssal Plain Locality S 1070-22.—Latitude, 31° 19.7' N to 31 °08.2' N; longitude, 119°39.2' W to 119°35.5' W. Depth, 3,601 to 3,687 m; 25-foot otter trawl. R/V Melville. Collectors: C. Hubbs, R. Wisner, S. Luke; December 18, 1969. The material from this collection, received in early 1970, consisted of 147 specimens of Abyssothyris elongata, 108 of Neorhynchia profunda, 8 of Noto- rygmia, and 4 of Pelagodiscus. The percentage rela¬ tionship of the homeomorphs— Abyssothyris, 55 per¬ cent; Neorhynchia, 42 percent; and Notorygmia, 3 percent—compares favorably to the associations seen at localities Mv 70—III—6 and Mv 70—III—8 but not with the collection from west-southwest of Cortes Bank. This is the only sample with a fair supply of young specimens of Abyssothyris and Neorhynchia. Locality Mv 70-1II-3.—Latitude, 31°24.0' N to 31 °28.8' N; longitude, 120° 14.5' W to 120° 10.3' W. Depth, 3,880 m; 25-foot otter trawl. R./V Melville. SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Collectors: R. Wisner, F. Rokop, and S. Luke; March 21, 1970. This collection, the smallest studied, numbers only 15 specimens: 4 of Abyssothyris , 1 of Notorygmia, 7 of Neorhynchia, and 3 of Pelagodiscus. The latter are attached to rock and soft tarry material (Emery, 1960, p. 322). This is the only locality in which Neorhynchia outnumbered Abyssothyris. Locality Mv 70—III—6. — Latitude, 31°36.0' N to 31° 14.4' N; longitude, 120°07.4' W to 120°09.6' W. Depth, 3,706—3,806 m; 25-foot otter trawl. R,/V Melville. Collectors: R. Wisner, F. Rokop, and S. Luke; March 23, 1970. A total of 314 specimens were taken here: 188 of Abyssothyris, 120 of Neorhynchia, 3 of Notorygmia, and 3 of Pelagodiscus. The percentage relationship of the homeomorphs—60 percent Abyssothyris, 39 per¬ cent Neorhynchia, and 1 percent Notorygmia —is like that of localities S 1070—22 and Mv 70—III—8. Some of the specimens were attached to soft, tarry ‘‘pebbles.” Locality Mv 70—III—8. — Latitude, 31°47.5' N to 32°00' N; longitude, 120° 19.0' W to 120° 18.0' W. 35 * 30 * 2 5 * Figure 1.—Locations from which the collections were taken. NUMBER 1 1 5 Depth, 3,916 m; 25-foot otter trawl. R/V Melville. Collectors: R. Wisner, F. Rokop, and S. Luke; March 23, 1970. Specimens were abundant at this locality, 270 in all: 150 of Abyssothyris, 109 of Neoihynchia, 1 of Notorygmia, and 10 of Pelagodiscus. The percentage relationship of the homeomorphs—58 percent Abys¬ sothyris , 41.6 percent Neorhynchia, and 0.4 percent Notorygmia —is like that of localities S 1070-22 and Mv 70—III—6. One Pelagodiscus is attached to a Neorhynchia, but all of the others are attached to tarry “pebbles” or small rock pebbles. West-Southwest of Cortes Bank Locality S 1067-547.—Latitude, 32°05' N to 32°03' N; longitude, 120°29.4' W to 120°30' W. Depth, 3,777—3,792 m; 40-foot otter trawl. Collec¬ tors: C. Hubbs, R. Wisner, and D. Perkins. This locality produced 335 specimens: 295 of Abyssothyris , 38 of Neorhynchia, and 2 of Notoryg¬ mia, showing an association unlike that of the above localities except in the small number of Notorygmia. The relationship percentages are: 88 percent Abys¬ sothyris, 11 percent Neorhynchia, and 1 percent Notorygmia. Although black, the pebbles to which some of the specimens are attached are not soft or tarry. Off Central California, South of Davidson’s Seamount Locality S 1067-103.—Latitude, 34°5T N to 35°05' N; longitude, 122°49' W. Depth, 3,878- 3,972 m. June 10, 1967. No other data. Only one Neorhynchia was taken at this locality. It was attached to a blackened pebble. Off Baja California Locality Mag Bay Exped. Sta. A-27.—Latitude, 24°30.5' N to 24°37.3' N; longitude, 113°28.7' W to 113°08.8' W. Depth, 3,564-3,574 m. Collector: H. Lowenstam. This collection consists of a single specimen each of Abyssothyris elongata, Neorhynchia abyssa, and Notorygmia, indicating the same grouping of homeo¬ morphs as occur farther to the north. Locality Mag Bay Exped. Sta. A-36.—Latitude, 24°45.2' N to 24°21.3' N; longitude, 113°25 / W to 113° 16.8' W. Depth, 3,039 m. Collector and donor: H. Lowenstam. This collection consisted of one specimen of each homeomorph: Neorhynchia, Abyssothyris, and No¬ torygmia. Antarctica Locality Eltanin Cruise 25 Sta. 364.—Latitude, 56° 17' S to 56° 19' S; longitude, 156° 13' W to 156° 18' W, South Pacific Ocean. The collection consisted of two specimens of No¬ torygmia: a large, nearly complete one (USNM 550406) 23 mm long, 19 mm wide, and about 13 mm thick, and a single smaller ventral valve. The larger specimen conforms to Notorygmia abyssa, new species, rather than to N. diamantina (Dali). Systematics The literature is replete with complaints against “unjustified” splitting. Many synonymies indicate the difference of opinion among authors as to the setting up of species. The problem of establishing species in connection with the homeomorphs from the Baja California Abyssal Plain is an excellent example of the difficulties faced by taxonomists. In this case the three species from the Baja California Abyssal Plain do not conform with the type species of the genera involved. None of the type species is represented by samples adequate to establish a species without ques¬ tion. Each of these lots of type species is represented by a few specimens only: Neorhynchia, 4; Noto¬ rygmia, 2; and Abyssothyris, 4 (three from Challenger Station 160 and another paratype from Challenger Station 302). Establishing species on these inadequate lots was fully justified at the time because these few specimens were all that were known. The deep-sea brachiopods from Baja California constitute adequate lots on which to base new species of Neorhynchia and Abyssothyris because each is represented by many specimens. In the case of Noto¬ rygmia, on the other hand, the total of all lots is not a good supply of specimens although it represents a much larger sample than that of the type species— Macandrevia diamantina. The lots of Abyssothyris and Neorhynchia from the Baja California Abyssal Plain, although showing some variation in many characters, are uniform in their general expression, i.e., elonga¬ tion of the shell. In this they are entirely unlike the 6 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY type species of their respective genera and thus de¬ serve another name. It will take a great deal of exploration of the deeps to collect material sufficient to demonstrate that these three genera really are each represented by a single species. This exploration may rather show that a number of races or subspecies are localized in the deeps. What localization seems apparent now is of one species of Neorhynchia off the Galapagos, one of Abyssothyris in the Northern Hemisphere, and an¬ other of Abyssothyris in the Southern Hemisphere. Notorygmia diamantina may be restricted because the isolated examples of this species outside the Baja Cali¬ fornia Abyssal Plain and off Cocos Island are most like Notorygmia from off California. In view of the above remarks there seems to be no choice other than to designate new species on the present adequate material rather than to include them in the hypodigm of the type species, thus distorting the conception of those species. Order RHYNCHONELLIDA Kuhn, 1949 Superfamily RHYNCHONELLACEA Gray, 1848 Family BASILIOLIDAE Cooper, 1959 Subfamily BASILIOLINAE Cooper, 1959 Genus Neorhynchia Thomson, 1915 Neorhynchia strebeli (Dali) Plate 1: figures 1-11 Hemithyris strebeli Dali, 1908, p. 441. Neorhynchia strebeli (Dali).—Dali, 1920, p. 290.—Thom¬ son, 1927, p. 149.—Hertlein and Grant, 1944, p. 57.— Cooper, 1959, p. 35.—Ager, in Williams et al., 1965, p. H622.—Muir-Wood, 1960, p. 524, pi. 7, figs. 7, 8a-d. Hitherto, this species and genus have been poorly known. Dali (1908) had four specimens: a large adult, the lectotype; a fragmentary paralectotype, partially broken; and two immature specimens. The holotype is wider than long but has a fairly strongly marked fold and sulcus. This specimen is one of the largest individuals of the genus yet seen, and its greater width than length set it strongly apart from the specimens from the Baja California Abyssal Plain. Dimensions of the type specimen when plotted on the same scatter diagram as those of the California specimen fall far away from the widest and largest individuals (see Figure 2). The specimen figured by Muir-Wood (1960, p. 524, pi. 7, figures 8a-d) likewise is wider than long but is more nearly equidimensional than the holotype. It is possible that specimens of Neorhynchia from the southern Pacific may belong to a third species. They are not elongated like the California species but they are much more broadly sulcate. Too few specimens are known at present to make a decision. Measurements in millimeters: Brachial USNM valve Thick- Apical specimen Length length Width ness angle 110741a (lecto- 17.4 15.4 19.2 10.5 104° type) Locality. —At 2.084 fathoms (3,801 m) in Glo- bigerina ooze, latitude 8°7'30" S, longitude 104° 10' W, southwest of the Galapagos Islands. Types. —Lectotype: USNM 110741. Figured para¬ lectotype: USNM 110741a. Neorhynchia profunda, new species Figure 3 a,b; Plate 1: figures 12-51; Plate 2: figures 1 - 22 . Description. —Medium size, outline elongate sub- triangular; profile sublenticular; valves unequal, the ventral valve having the greater depth. Widest at or slightly anterior to midvalve. Sides rounded; anterior margin varying from truncated to subnasute; postero¬ lateral margins forming an angle varying from 85° to 102° Beak nearly straight to suberect; foramen small, hypothyridid; deltidial plates small, disjunct. Pedicle usually very short, just protruding from the foramen but in rare examples moderately long (up to 3 mm). Shell very thin, translucent to transparent (especially when wet), pale brownish gray, glossy when dry; impunctate. Ventral valve gently convex in lateral profile, with the umbonal region the most convex; anterior pro¬ file strongly convex and with long, steeply sloping sides. Umbonal and median regions swollen, the swelling continuing anteriorly to form a fold at the front margin varying from broad to narrowly rounded and fairly convex in subnasute forms. NUMBER 1 1 7 ▲ WIDTH c n in LU o X Figure 2.—Scatter diagram showing the length/width (dots) and thickness/width (crosses) * relationships of Neorhynchia profunda, new species, from loc. S 1070—22. Triangle at top represents length/width of the lectotype, N. strebeli. Dorsal valve moderately convex in lateral profile and with the greatest convexity in the posterior half; anterior profile flatly convex and with the median part gently concave. Umbonal region moderately swollen; sulcus originating on the umbonal region, deepening and widening to the anterior margin where it occupies more than half the width. Flanks bounding sulcus swollen. Tongue moderately long and rounded. Ventral valve interior with strong narrow teeth bounding narrow transverse slits; teeth supported by stout dental plates; apical plate restricting foramen usually short when present; muscle area short, nar¬ row, anteriorly truncated. Dorsal valve interior with strong socket ridges bounding deep corrugated sockets; outer hinge plates concave, moderately broad and margined by narrow, slightly elevated crural bases; inner hinge plates lack¬ ing. Median ridge low, separating two elongate ad¬ ductor marks. Crura short, falcifer type. Brachium a loose spirolophe, partially uncoiled in many speci¬ mens (Figure 3 a,b). 8 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Measurements in millimeters: Dorsal USNM valve Thick- Apical specimen Length length Width ness angle 550391a 17.0 15.3 15.6 8.8 108° 550391c 16.5 14.4 13.5 8.5 o O Oh 550391d 550392d 19.2 17.1 17.0 12.1 111° (holotype) 17.7 15.9 16.9 9.4 91° 550392e 17.7 16.0 14.3 10.6 o Oh CO 550392g 15.2 14.0 12.4 7.2 hO o o 550393a 12.5 11.0 10.9 5.4 104° 550393f 17.0 15.3 15.2 9.0 108° 550394h 16.7 15.3 13.3 11.5 O CO CO 550394o 14.6 13.3 14.3 7.6 c r> 00 O 550394s 13.4 12.2 12.8 7.0 o o O Diagnosis. —Neorhynchia with length consistently greater than the width. Types.— Holotype: USNM 550392d. Figured para- types: USNM 550391i,j,m; 550392e,i; 550393e,m-s; 550394b,g,h,t; 550409; 550433—5. Unfigured para- types: USNM 550391a-h,k,l,n,o; 550392a-c,f-h; 550393a-d,f-l; 550394a,c-f,i-s,u. Localities.— S 1070-22; Mv 70—III—3; Mv 70- III—6; Mv 70-111-8; S 1066-547; S 1070-22; Mag Bay Exped. Sta. A—27; Mag Bay Exped. Sta. 36. Variation. —Neorhynchia profunda is variable in outline and thickness but it maintains well its elongate form. Out of 179 specimens measured, only 11 have a length/width ratio of one or less, indicating equal length and width or greater width than length. The range observed in the L/W ratio is from 0.92 to 1.35. The 39 specimens from locality Mv 70—III—6 in¬ cluded only one specimen wider than long. Localities Mv 70—III—8 and S 1066—547 had none wider than long. Locality S 1070—22 contained ten specimens that were wider than long but only three of these were immature specimens below 10 mm in length. The others ranged from 10.5 mm to 16.1 mm in length. This locality is the only one from which a fair num¬ ber of specimens below 10 mm in length were taken, but the large majority of these young specimens (L/W ratio, 1.04) are longer than wide and aver¬ age the same L/W ratio as the 58 percent of this sample measuring 10—15 mm. All of these specimens contrast strongly with the type specimen of N. strebeli, which is wider than long, more so than any speci¬ men from the Baja California Abyssal Plain. The lectotype has L/W ratio of 0.90. It is also a remark¬ ably thin shell for one of its size: length 17.4 mm, width 19.2 mm, and thickness 10.5 mm. The width of the lectotype nearly equals the length of the longest specimen of N. profunda from the Baja Cali¬ fornia Abyssal Plain. That specimen is 19.4 mm long but its width is only 15.6 mm. Most rhynchonellids, like most brachiopods, are variable in thickness. Neorhynchia is like most of its relatives in initially starting with a flattened shell and after a certain stage, depending on the kind of rhyn- chonellid, growing more rapidly at the anterior to en¬ large the body region. The thickness/width ratio of Neorhynchia is fairly uniform in all localities. At lo¬ cality S 1070—22 it averages 0.47, which includes about 20 percent of specimens below 10 mm. It aver¬ ages 0.57 at localities S 1066—547 and Mv 70—III—6 but 0.61 at locality Mv 70—III—8. The specimens from these three localities are mostly adults. The thicker specimens usually are more strongly folded at the anterior. Like in its homeomorph Abyssothyris, the variation in the folding of the anterior commissure in Neor¬ hynchia is evident to a marked degree. Most of the shells, after becoming adult, have a broad and gentle wave of the anterior margin, as USNM 550392d (Plate 2: figures 1—4), but ten (or about 5 percent are nasute like USNM 550394g (Plate 1: figures 17—19). Only four of the youngest specimens from locality S 1070—22 proved to be rectimarginate. Comparison. —When the type specimen of N. strebeli is compared with most specimens of N. pro¬ funda the differences are apparent. As mentioned above, N. strebeli is wider than long, whereas N. pro¬ funda is much longer than wide. Only a very small percentage (6 percent) of specimens of N. profunda proved to have length or width equal, or the width greater than the length. The sulcus of the majority of the specimens of N. profunda appears shallower and broader than that of the type specimen, although none of them attains the great width of the type. Discussion.— Prior to the collecting of the speci¬ mens on which the above description is based, Neor¬ hynchia was a very rare genus known only from the types and a few other individuals such as those misidentified as Abyssothyris (Muir-Wood, 1960). Order TEREBRATULIDA Waagen, 1883 Suborder TEREBRATULIDINA Waagen, 1883 Superfamily TEREBRATULACEA Gray, 1840 NUMBER 1 1 9 Family TEREBRATULIDAE Gray, 1840 Genus Abyssothyris Thomson, 1927 Abyssothyris elongata, new species Figures 3 c-e, 4; Plate 2: figure 39; Plate 3: figures 20-41; Plate 4: figures 1-52. Description. —Large for the genus; white to trans¬ lucent but with traces of a thin brown epidermis; outline variable, ranging from elongate-oval to roundly elliptical; strongly inequivalve, the ventral valve deeper, widest midvalve; sides broadly rounded; anterior narrowly rounded to subnasute; anterior commissure faintly to strongly sulcate; beak suberect, obliquely truncated. Apical angle varying from 70° to 95°. Foramen fairly large, moderately to slightly labiate, permesothyridid. Surface marked by con¬ centric lines and varices of growth. Symphytium thick, concave. Pedicle variable from restricted to the beak to at least 5 mm, the distal end tufted and frayed into fibers. Punctae averaging about 69/mm 2 . Ventral valve strongly but unevenly convex in lateral profile, the greatest convexity posterior to mid¬ valve; anterior profile strongly and narrowly convex with steep and nearly vertical sides. Beak narrowly swollen; umbonal region swollen and narrow, the swelling continuing anteriorly to the front margin, there forming a moderate to deep fold to receive the tongue of the dorsal valve. Dorsal valve moderately and fairly evenly convex in lateral profile, with the maximum convexity at about midvalve; anterior profile varying from gently to flatly convex to very gently concave, the sides short and steep. Umbonal region moderately swollen, the swelling extending to midvalve, rarely to the anterior margin, but usually flattening at midvalve and becoming slightly to moderately concave at the front margin; tongue moderately long and usually narrowly rounded. Flanks bounding sulcus incon¬ spicuous, rounded and with short, steep slopes. Ventral valve interior with small teeth unsup¬ ported or with slight anterior thickening; pedicle collar short, thick; muscle scars lightly impressed. Dorsal valve interior with strong, elevated socket ridges, short sockets, outer hinge plates broad and slightly concave; no inner hinge plates; crural base not elevated; loop short with length about equal to width and equal to less than one-fourth the shell length; crural processes short and blunt, originating immediately anterior to the anterior end of the outer hinge plate; transverse ribbon variable, fairly broad and with a low median angularity; anterolateral ex¬ tremities of the loop rounded and without anterior projections. Muscles. The diductors form the anteriormost pair; posterolateral to them are the adjustor muscles at¬ tached to the pedicle. The accessory diductor has an elongate attachment, very narrow, and extends pos- terodorsally to attach to a flat band of muscle tissue that ties the adductors together and attaches to the cardinal process. This broad band is attached on the whole surface of the cardinal process. All of the above muscles are brown in color. The adductors are white and situated between and just posterior to the diductors. The adductors divide about one-third their length toward the dorsal valve to form four muscles in that valve. The anterior pair is the larger. Lophophore. This is short and of the plectolophous type with two lobes on each side and two smaller ones in the middle. The larger lobe is attached to the anterior and concave lateral parts of the loop. The smaller lobe is recessed in a direction dorsal to the larger and is suspended from the anterior part of the crural process. The posterior part of the lophophore is suspended across the gap between the crural proc¬ esses. The filaments are about 3.5 mm long at the largest part of the lophophore (Figures 3c— e, 4). Measurements in millimeters: Dorsal USNM valve Thick¬ Apical specimen Length length Width ness angle 550550 19.4 17.7 14.8 12.0 o CO 550395d 18.7 16.5 14.0 11.2 67° 550397e 17.8 16.8 15.5 11.1 93° 550397h 17.1 14.8 14.0 9.6 o CO 500397j 550397m 16.7 15.3 12.6 10.0 81° (holotype) 18.6 17.1 15.0 12.0 kO 00 o 550398p 19.7 17.1 14.5 11.7 75° 550398q 17.8 16.5 11.7 11.2 77° 550398t 16.8 15.6 12.6 11.1 84° 550398w 19.0 16.8 13.7 11.9 72° 550400a 18.9 17.2 12.3 12.6 74° 550400c 19.3 17.8 16.4 12.3 92° Types. —Holotype: USNM 550397m. Figured paratypes: USNM 550397e,h,n,o,p; 550398i,n,p-s,v-y; 550400a,b; 550401a,b; 550436; 550437a-c. Unfigured paratypes: USNM 550397a-d,f,g,i-m,p,q; 550398a-h, j-m,o,t,u. 10 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Figure 3. —Lophophores (X 4) of Neorhynchia and Abyssothyris. a, b, of Neorhynchia pro¬ funda, new species, from loc. S 1070-22: a, dorsal view; b, ventral view, c-e, of Abyssothyris elongata, new species, from loc. S 1056-547: c, dorsal view; d, lateral view; e, ventral view. Comparison. —Specimens of Abyssothyris are known from widely scattered localities but an abund¬ ance of specimens such as that recorded here has not been taken hitherto. Two species of the genus are known at the present time—a fossil one, A. fijiensis Elliott (in Muir-Wood, 1960, p. 526, pi. 7) from the Miocene-Lower Pliocene of Fiji, and a Recent one, A. wyvillei (Davidson). The latter is known from off South Australia and northern Queensland, off the west coast of Patagonia, off Valparaiso, Chile, and near the Falkland Islands. All of the Recent speci¬ mens are from deep water, 1,893 to 5,305 m. Abyssothyris elongata differs from A. fjiensis in being larger, more elongate, and with much narrower fold. The beak of the Fiji species is more strongly labiate and the loop narrower. The fossil species is more like A. wyvillei from the Southern Hemisphere but has strong differences nevertheless. As described by Davidson (1880, p. 27, pi. 2, figs. 7-9) and Muir-Wood (1960), A. wyvillei is pre- NUMBER 1 1 11 Figure 4.—Pallial trunks (X 2) of Abyssothyris elongata, new species, from loc. Mv-70-III-6: a. ventral view; b, dorsal view. (See Plate 3: figures 21-24.) dominantly nearly equal in length and width and has a fairly strong median fold extending from near the middle of the ventral valve to the anterior margin. This is quite unlike A. elongata, which is elongate and does not have so prominent a fold, the folding being indicated by the long dorsal tongue and deep pedicle valve. The loop of A. elongata has strongly rounded an¬ terolateral extremities, whereas the same feature in the type of A. wyvillei is more elongated and angular. The Galapagos specimen is like Davidson’s species in this respect. The lophophore is unusual in having the lateral branches tightly coiled and directed inward rather than extending anteriorly to form a “horseshoe” as in many other terebratulids, such as Liothyrella notor- cadensis Jackson. Helmcke (1940, p. 257, fig. 20) illustrates a short lophophore like this one in Liothy¬ rella winteri Blochmann, which has a loop similar to that of Abyssothyris. Blockmann’s species is not a deep-sea form (depth, 672 m). Abyssothyris, identified as A. wyvillei, coming from the vicinity of the Galapagos Islands (lat. 10° 15' S, long. 95°41' W), is different from the new species here described and from A. wyvillei from more south¬ ern waters. The three specimens in the collection of the National Museum of Natural History are smaller than either of those figured by Davidson or those from the Baja California Abyssal Plain. Like David¬ son’s species, they are equidimensional in length and width, one being 11 mm by 11 mm and the other 13 mm by 13 mm. They are, however, rather compressed and the fold is broad, open, and prominent only at the anterior. This is a possible third species of Abys¬ sothyris, but much more material is needed to estab¬ lish this as a fact. The collection in the National Museum of Na¬ tional History includes a few other specimens of Abyssothyris from the Southern Hemisphere but they do not help in clarifying the species problem. Much more exploration of the deeps is needed. Variation.— Abyssothyris proves to be variable in some features but is fairly constant in its growth form, the creation of an elongate shell. Of 200 measured specimens from localities S 1070—22 and S 1066—547 only one specimen was wider than long (from S 1070-22) and had an L/W ratio of 0.95. The measured lot from locality S 1070—22 contains numerous immature specimens with lengths less than 10 mm but not one of them is wider than long although their L/W ratios are less than those of the adults. Twenty-one percent of the specimens in this lot measured 10 mm or less and their average L/W index was 1.12. Twenty-seven percent of this lot measured 10 to 15 mm and had an L/W ratio (1.16) slightly greater than the preceding group. Forty-seven percent, measuring between 15.1 mm and 18.9 mm, are still more elongate and have an L/W ratio of 1.28. Only five percent of the specimens measured above 19 mm, and these had an average L/W ratio of 1.37. Three specimens are almost exactly twice as long as wide but they are exceptions. The range of L/W ratio is 0.95 to 1.48 for the above collection. The lot from locality S 1066—547 consists almost wholly of large adults. Only one specimen was below 10 mm in length and only seven percent of the lot measured between 10 and 15 mm. This group aver¬ aged somewhat higher than specimens of the same range of measurements from locality S 1070—22. Sev¬ enty-eight percent of lot S 1066—547 consists of speci¬ mens from 15.1 mm to 18.9 mm, and their L/W ratios averaged 1.39, which is higher than for the corresponding group above. Fourteen percent meas¬ uring above 19 mm have an L/W ratio of 1.45. These specimens represented shells with length aver¬ aging nearly twice the width, and four specimens were more than twice as long as wide. The observed range of L/W ratio for specimens from this locality is 1.18 to 1.60. The elongate form of the species is very evident and is in strong contrast to the lectotype of A. wyvillei selected by Muir-Wood (1960, pp. 523, 525), which has an L/W ratio of 0.88. The anterior commissure of Abyssothyris elongata is variable from almost rectimarginate to nasute. As a 12 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY t n oo UJ * o i Figure 5.— Scatter diagram showing the length/width (dots) and thickness/width (crosses) relationships of Abyssothyris elongata, new species, from loc. S 1070-22. Triangle a top indicates length/width of A. wyvillei. general rule the smaller specimens are rectimarginate or nearly so and the larger ones usually are more strongly sulcate. USNM 550398p (Plate 4: figures 24—26) is a large adult with rectimarginate anterior commissure. A strongly nasute, narrow specimen in the same lot is USNM 550398r (Plate 4: figures 15—17). A strongly folded but wide specimen is USNM 550400a (Plate 4: figures 5—8). From lo¬ cality S 1070-22, specimen 550397o (Plate 4: fig¬ ures 43—46) is a large rectimarginate individual, but specimens 550397n (Plate 4: figures 38—41) and 550397q (Plate 3: figures 30—33) are narrowly elongate and nasute. Variation in the loop appears to be a function of age and calcification of the specimens. A few individ¬ uals have much wider transverse bands than usual (USNM 550398i) but the loop is remarkably uni¬ form in its characteristic features: shortness, and rounded anterolateral extremities. The median flexure of the transverse band is variable, stronger and sharper in some specimens than others, but always present. The crural processes vary from blunt and rounded to long and acute. Young specimens do not have a readily recognizable cardinal process, but in large, old individuals such as USNM 550398x (Plate 3: figure 25) it is a large boss with ragged edge. NUMBER 1 1 13 Suborder TEREBRATELLIDINA Muir-Wood, 1955 Superfamily TEREBRATELLACEA King, 1950 Family DALLINIDAE Beecher, 1893 Notorygmia, new genus Macandrevia Thomson, 1927, p. 239 (part). Description. —Moderately large, somewhat dia¬ mond-shaped to pentagonal in outline; valves un¬ equal in depth, the ventral valve deeper than the dorsal valve; shell usually thin, yellowish or white, and translucent to transparent; beak suberect; fora¬ men large, elongate, but open anteriorly; deltidial plates rudimentary or absent. Surface marked only by concentric growth lines. Punctae very fine but not crowded. Pedicle valve interior with strong teeth buttressed by short dental plates. Dorsal valve with strong socket ridges and small outer hinge plates. Crural bases supported by short sloping plates (inner hinge plates?) that meet the valve floor to bound a narrow notothyrial cavity. Loop long, free in adults, with short posterior crural processes and narrow descend¬ ing and ascending branches; anterior junction of branches with short, delicate spines. Type species. — Notorygmia abyssa, new species. Dicussion. —Internally, Notorygmia is exactly like Macandrevia in having plates (inner hinge?) attach¬ ing the crural bases to the valve floor. The loop is exactly like that of Macandrevia, and its develop¬ mental stages are known from two immature speci¬ mens of Macandrevia [Notorygmia] diamantina Dali described and figured by Jackson (1912, p. 380). The smallest individual showed the descending branches attached to a septal pillar and the presence of a small hood. The next larger stage revealed rem¬ nants of the processes that attached the loop to the septum in the terebrataliform loop stage. The character that sets this shell apart from other macandrevias is the strong sulcation of the anterior commissure. All other species of Macandrevia are rectimarginate or nearly so. A new species from the west coast of Africa actually shows a slight tendency toward sulcation but otherwise most specimens of all other species are rectimarginate. Strong sulcation is the homeomorphic character that confuses this genus with Abyssothyris and Neorhynchia. The confusion with the former is stronger because both genera are punctate. Notorygmia is a widely distributed brachiopod, ranging from latitude 31° north, in the Baja Cali¬ fornia Abyssal Plain south to the Gulf of Panama, and to latitude 56° south and longitude 156° west and finally to a point off Queen Mauds Land, Ant¬ arctica (Jackson, 1912). This vast expanse of sea is essentially the same as that in which Abyssothyris and Neorhynchia range. Throughout this region these genera are usually taken from great deeps. In any assemblage containing all three homeo- morphs, Notorygmia is readily distinguished from Neorhynchia by its punctate shell and lack of delti¬ dial plates; it differs from Abyssothyris, also punctate, in its suppression of deltidial plates and the presence of a long, recurved loop. The name of this new genus derives from the Greek notos (back) and orygma (trench). Notorygmia diamantina (Dali) Plate 2 : figures 30-38. Macandrevia diamantina Dali, 1895, p. 723, pi. 30, fig. 5; pi. 32, figs. 3, 6; 1908, p. 455.—Thomson, 1918, p. 34 (part); 1927, p. 240 (part). Examination of Dali’s type specimens of Macan¬ drevia diamantina reveals significant differences be¬ tween them and specimens taken from off Baja Cali¬ fornia and even south to the Antarctic. Dali’s types and two additional specimens from southeast of Cocos Island, Gulf of Panama, and one specimen from off Sechuca Point, Peru, are notable for their slender lateral profile and nearly equal length and width. Compared to specimens of Notorygmia from off California and Baja California that are deep and strongly elongated, the differences become striking. Measurements (in millimeters) of Dali’s specimens are as follows: USNM Dorsal valve Maxi¬ mum Thick¬ Apical L/W specimen Length length width ness angle ratio 122860a (type) 18.1 16.0 17.3 8.1 97° 1.05 122860b (paratype) 16.1 14.5 16.2 6.8 103° 0.99 110743 13.4 11.9 12.4 5.5 o o 1.08 223627 15.6 13.8 14.8? 6.2 o O o 1.05 Types. —Lectotype: USNM 122860a. Figured paralectotype: USNM 122860b. Discussion.— It is interesting that two species of Macandrevia occur off Cocos Island— M. craniella 14 Dali and M. americana Dali. Both occur in deep water, the latter at 1,175 fathoms (2,149 m) and the former at 1,672 fathoms (3,059 m). Macandrevia craniella was found with N. diamantina. Both M. craniella and M. americana are rectimarginate and in every way normal for Macandrevia. This reiterates the point previously made that sulcation appears not to be confined to brachiopods in abyssal waters. See also discussion (below) of Waldheimia wyvillei Davidson. Notorygmia abyssa, new species Plate 2: figures 23-29; Plate 3: figures 1-19. Macandrevia diamantina Jackson (not Dali), 1912, p. 379, pi. 2, figs. 15-19.—Thomson, 1927, p. 240 (part).— Hertlein and Grant, 1944, p. 157 (part). Macandrevia coatsi Jackson.—Helmcke, 1939, p. 251. Description. —Elongate-oval in outline, with max¬ imum width near midvalve; sides rounded; anterior nasute; posterolateral margins forming angle of 85°. Shell thin, translucent, glossy but with traces of a light brown periostracum. Anterior commissure strongly sulcate, producing an anterior projection of the ventral valve. Ventral valve with the umbo moderately convex and the anterior half nearly flat in lateral profile; strongly and somewhat narrowly domed in anterior profile, the crest of the dome narrowly rounded; sides sloping steeply. Fold originating posterior to mid¬ valve but broad and gentle, narrowing anteriorly. Dorsal valve evenly and gently convex in lateral profile but broadly and gently convex in anterior pro¬ file and with the median region narrowly sulcate. Sides narrowly rounded, slopes precipitous. Sulcus barely visible at midvalve, but deepening anteriorly to become a moderately deep and narrow groove; tongue long and narrowly rounded. Measurements in millimeters: USNM specimen Dorsal valve Length length Width Thick¬ ness Fold width Apical angle 550402a 19.6 18.0 16.9 11.6 11.6 85° 550402b 19.8 18.0 16.8 11.0 9.3 88° 550406 22.7 19.7 19.1 12.0 10.4 87° 549762 17.3 15.7 15.8 ? 11.2 92° 550404a 19.1 ? 16.5 9.1 10.0 86° 550404b 18.4 16.4 15.0 8.8 9.3 90° 550403 12.8 11.3 12.0 5.3 5.8 107° 550405 16.0 14.6 15.0 6.6 7.8 101° 550105 14.7 13.4 13.1 6.4 8.0 105° SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Diagnosis. —Elongate, narrow, and deep Notoryg¬ mia with strong sulcus. Localities. —SV 1066—547; S 1070—22; Mv 70— III—6; Mv 70—III—8; Mag Bay Exped. Sta. A27; Eltanin Cruise 25 Sta. 364. Types. —Holotype: USNM 550402b. Figured par- atypes: USNM 550402a, 550404, 550405. Discussion. —This species is distinguished by its elongate-oval to pentagonal outline, great depth of the adult, and strong, rather narrow fold. The type specimen of Macandrevia diamantina Dali appears to be a fully grown adult specimen. Its length and width are nearly equal and it has a very narrow pro¬ file. Its width is greater than most of the specimens of N. abyssa recorded above. In order better to com¬ pare the specimens of N. abyssa with Dali’s species a specimen (USNM 550402a) of M. diamantina was measured at three stages of its growth as indicated by varices on the shell. At 7 mm of length the width and length were equal; at 12.4 mm of length the width measured 11.5 mm, showing an already length¬ ening shell. At 16 mm the width was 14.3 mm but the shell had still 3.6 mm more of length to form a strongly elongated adult. Notorygmia diamantina is also much more diamond-shaped than N. abyssa, which has more rounded sides and is rather pentago¬ nal in outline. The fold and sulcus of N. abyssa are far more pronounced than those of Dali’s species. Other minor characters help to distinguish these species. The specimens from off Cocos Island are more opaque than N. abyssa and are somewhat yel¬ lowish in color. They do not show any traces of the dark brown periostracum similar to that appearing on parts of N. abyssa. Macandrevia coatsi Jackson is a name appearing in Helmcke’s list of brachiopods in the Zoological Museum of Berlin. The specimens come from the same locality, but not same depth, as listed by Jack- son for M. diamantina. It seems likely that Jackson intended to designate a new species for them but later changed his mind in favor of identification with Dali’s species. Jackson’s name is a nomen nudum. The validity of the name Notorygmia abyssa, new species, will hold unless or until it can be demon¬ strated that Waldheimia wyvillei Davidson, described below, can be proved to be sulcate and to belong to Notorygmia. More collecting off Chile will be needed to prove this point. NUMBER 1 1 15 Waldheimia ( = Macandrevia?) wyvillei (Davidson) Waldheimia wyuillii Davidson, 1878, p. 438; 1880, p. 44, pi. iii, figs. 13a, b; 1886, p. 66, pi. X, figs. 5, 6. The name given by Davidson is W. wyvillii but should be spelled wyvillei as explained by Thomson (1927, p. 199). This is a very poorly known species that has been overlooked and its correct genus not established. It was ignored by Thomson. The name is based on a single specimen dredged by the Challenger expedition from locality 229 (lat. 33°31' S, long. 74°33' W) at 2,160 fathoms off Valparaiso, Chile, the same locality that produced Neorhynchia misidentified as Abysso- thyris (Terebratula wyvillei). This specimen proves by its interior details to belong to Macandrevia or Notorygmia. Dr. C. Howard Brunton, Keeper of the Recent Brachiopoda at the British Museum (Natural His¬ tory), kindly examined this specimen for me, and later, in a hurried visit to the British Museum, I had opportunity to study it. Unfortunately, the specimen is badly damaged. Most of the ventral valve is broken away and the anterior margin has been destroyed. This damage has the advantage of giving a view of the interior where the critical characters reside but it obscures vital exterior characters. Dr. Brunton and I concur in our examination that the ventral valve has dental plates and that the long loop is unsup¬ ported. These two characters, combined with the open nature of the foramen, clearly indicate the diag¬ nostic characters of Macandrevia. But the question is: To what species of Macandrevia is Waldheimia wyvillei related, or is it the same or related to Ma¬ candrevia diamantina Dali, now placed in Notoryg¬ mia? As figured by Davidson, Waldheimia wyvillei seems to have a rectimarginate anterior commissure, and Davidson (1886, p. 67) stated unequivocally that the dorsal valve is “without sinus.” Moreover, Davidson remarked that his species suggests a thin or com¬ pressed Macandrevia cranium (Muller). It is possible that Waldheimia wyvillei is a small example of Ma¬ candrevia americana Dali, which is also known from the coast of Chile (Dali, 1920, p. 357). The fact that Waldheimia wyvillei occurs with Abyssothyris wyvil¬ lei suggests the possibility that it is a species of Noto¬ rygmia and another example of the homeomorphy that forms the subject of this paper, but Davidson’s unequivocal statement that his species is without a sinus rules out that possibility. According to Dali (1920, p. 357), Macandrevia americana has a wide bathymetric range, from 122 to 2,222 fathoms; con¬ sequently, the species is not out of place at Challen¬ ger locality 299. Appendix Pelagodiscus atlanticus King Plate 4: figures 53-56 For an extended synonymy see Helmcke (1940, p. 230). Although this species has no direct bearing on the problem discussed herein, figures of this interesting and ubiquitous brachiopod are included because it is the commonest deep-sea brachiopod and has been re¬ ported more widely than any other. It is shown at¬ tached to a specimen of Neorhynchia profunda (Plate 4: figures 53—56). Also shown is the ventral side, which usually is not seen. The large pedicle and the two sets of setae are clearly visible. Localities.— S 1067-103; S 1070-22; Mv 70- IH-3,6,8. Types. —Hypotypes: USNM 550391e (on Neo¬ rhynchia) ; USNM 550438. Literature cited Bell, W. C. 1938. Homeomorphy in the Brachiopod Genus Acrotreta. Bulletin of the Geological Society of America, 49:1909-1910. Buckman, S. S. 1901. Homeomorphy among Jurassic Brachiopods. Pro¬ ceedings of the Cotteswold Naturalists Field Club, 13:231-290. 1906. Brachiopod Homeomorphy: Pygope, Antinomia, Pygites. Quarterly Journal of the Geological So¬ ciety of London, 62:433—455. Cloud, P. E., Jr. 1941. Homeomorphy, and a Remarkable Illustration. American Journal of Science, 239:899—904. Cooper, G. A. 1930. The Brachiopod Genus Pionodema and Its Homeo- morphs. Journal of Paleontology, 4(4) : 369—382, plates 35-37. 1959. Genera of Tertiary and Recent Rhynchonelloid Brachiopods. Smithsonian Miscellaneous Collec¬ tions, 139(5): 1-90, 22 plates. 1970. Generic Characters of Brachiopods. Symposium, North American Paleontological Convention, Field Museum Natural History, September 1969, pages 194-263, 5 plates. 16 Dali, W. H. 1895. Scientific Results of Explorations by the U.S. Fish Commission Steamer Albatross. No. XXXIV.— Report on Mollusca and Brachiopoda Dredged in Deep Water, Chiefly near the Hawaiian Islands, with Illustrations of Hitherto Unfigured Species from Northwest America. Proceedings of the United States National Museum, 17(1032) :675— 733 plates 23-32. [Brachiopoda, pages 713-729, plates 30—32.] 1908. Reports on the Mollusca and Brachiopods [Alba¬ tross Dredging Operations in Western Pacific]. Bulletin of Museum of Comparative Zoology, Har¬ vard, 43 (6) : 205-487, 19 plates. [Brachiopods, pages 205-212], 1920. Annotated List of the Recent Brachiopoda in the Collection of the United States National Museum, with Descriptions of Thirty-three New Species. Proceedings of the United States National Museum, 57:261-377. Davidson, Th. 1878. Extract from Report to Professor Sir Wyville Thomson, F.R.S., on the Brachiopoda Dredged by H. M. S. Challenger. Proceedings of the Royal Society of London, 27( 188) :428—439. 1880. Report on the Brachiopoda Dredged by H. M. S. Challenger during the years 1873—1876. Report on the Scientific Results of the Voyage of H. M. S. Challenger, Zoology, 1: 1-67, 4 plates. 1886- A Monograph of Recent Brachiopoda. Transac- 1888. tions of the Linnaean Society of London, series 2, Zoology, 4: 1-248, 30 plates. Emery, K. O. 1960. The Sea off Southern California: A Modern Habi¬ tat of Petroleum. xii-|-366 pages. New York and London: John Wiley and Sons. Hclmcke, J. G. 1940. Die Brachiopoden der Deutschen Tiefsee-Expedi- tion. Wissenschaftliche Ergebnisse der deutschen Tief see-Expedition auf dem Dampfer Valdivia, 1898-1899, 24(3): 215-316, 43 figures. SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Hertlein, L. G., and U. S. Grant, IV 1944. The Cenozoic Brachiopoda of Western North America. Publications of the University of Cali¬ fornia at Los Angeles in Mathematical and Physical Sciences, 3:1-236, 21 plates. Jackson, J. W. 1912. The Brachiopoda of the Scottish National Ant¬ arctic Expedition (1902 to 1904). Transactions of the Royal Society of Edinburgh, 48(2)19:367—390, plates 1 and 2. Muir-Wood, H. M. 1959. Report on the Brachiopoda of the John Murray Expedition. The John Murray Expedition, 1933—34, Scientific Reports, 10(6) : 283—317, 5 plates. 1960. Homeomorphy in Recent Brachiopoda: Abyssothy- ris and Neorhynchia. [With an appendix by G. F. Elliott.] Annals and Magazine of Natural History, series 13:521-528, plate 7. Thomson, J. A. 1915. The Genera of Recent and Tertiary Rhynchonel- lids. Geological Magazine, new series, 6(2):387— 392. 1918. Brachiopoda. Australasian Antarctic Expedition, 1911-14, Scientific Reports, Series C, 4(3): 1-75, 4 plates, map. 1927. Brachiopod Morphology and Genera (Recent and Tertiary). New Zealand Board of Science and Art, Manual, 7: 1—338, 2 plates. Ulrich, E. O., and G. A. Cooper 1936. New Silurian Brachiopods of the Family Triplesii- dae. Journal of Paleontology, 10(5) :331—347, plates 48—50. Williams, A., et al. 1965. In R. C. Moore, editor. Treatise on Invertebrate Paleontology, Part H, Brachiopoda. 2 vols., 927 pages, 746 figures. New York: Geological Society of America (and University of Kansas Press). PLATES PLATE 1 Neorhynchia strebeli (Dali) Figures 1—11: 1-4, Anterior, dorsal, lateral, and ventral views (X 1) of the holotype (USNM 110741); 5, dorsal view (X 2) of the holotype; 6, 7, posteriorly tilted and dorsal views ( X 4) of the posterior part of the holotype showing the hypothyridid foramen, disjunct deltidial plates and dental plates; 8-10, ventral, posteriorly tilted, and laterally tilted views (X 4) of the cardinalia of the holotype showing the falcifer crura, slight median ridge, strong socket ridges, and outer hinge plates; 11, interior of the dorsal valve (X 4) of a paratype (USNM 110741a), younger than the holotype, showing cardinalia. Both specimens taken at a depth of 3,801 m in Globigerina ooze, lat. 8°7'30"S, long. 104°10'W, southwest of the Galapagos Islands. Neorhynchia profunda, new species Figures 12-25: 12-15, Anterior, lateral, dorsal, and ventral views (X 1) of a young adult (paratype, USNM 550394b); 16, dorsal view (X 2) of the preceding paratype; 17-19, anterior, lateral, and dorsal views (X 1) of a strongly folded individual (paratype, USNM 550394g); 20-22, anterior, dorsal, and lateral views (X 2) of the preceding paratype showing the growth lines; 23-25, lateral, dorsal, and anterior views (X 2) of another obese, strongly folded individual (paratype, USNM 550394h) showing the small beak and growth lines. All specimens from loc. MV 70—III—6. Figures 26-46: 26-28, Anterior, dorsal, and lateral views (X 2) of " top and left margins, submitted in ribbon copy with a carbon or duplicate, and accompa¬ nied by the original artwork. Duplicate copies of all material, including illustrations, should be retained by the author. There may be several paragraphs to a page, but each page should begin with a new paragraph. 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