Triassic Gastropods of the Southern Qinling Mountains, China P*. ' 4 '^jyW,' , 'W.. Tag 505%* ■ -j* •.. ojvj 1 . . ; - , >v *y ,; On. SERIES PUBLICATIONS OF THE SMITHSONIAN INSTITUTION Emphasis upon publication as a means of "diffusing knowledge” was expressed by the first Secretary of the Smithsonian. In his formal plan for the Institution, Joseph Henry outlined 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 theme of basic research has been adhered to through the years by thousands of titles issued in series publications under the Smithsonian imprint, commencing with Smithsonian Contributions to Knowledge in 1848 and continuing with the following active series: Smithsonian Contributions to Anthropology Smithsonian Contributions to Botany Smithsonian Contributions to the Earth Sciences Smithsonian Contributions to the Marine Sciences Smithsonian Contributions to Paleobiology Smithsonian Contributions to Zoology Smithsonian Folklife Studies Smithsonian Studies in Air and Space Smithsonian Studies in History and Technology In these series, the Institution publishes small papers and full-scale monographs that report the research and collections of its various museums and bureaux or of professional colleagues in the world of science and scholarship. The publications are distributed by mailing lists to libraries, universities, and similar institutions throughout the world. Papers or monographs submitted for series publication are received by the Smithsonian Institution Press, subject to its own review for format and style, only through departments of the various Smithsonian museums or bureaux, where the manuscripts are given substantive review. Press requirements for manuscript and art preparation are outlined on the inside back cover. Lawrence M. Small Secretary Smithsonian Institution SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY • NUMBER 92 Triassic Gastropods of the Southern Qinling Mountains, China Jinnan Tong and Douglas H. Erwin Smithsonian Institution Press Washington, D.C. 2001 ABSTRACT Tong, Jinnan, and Douglas H. Erwin. Triassic Gastropods of the Southern Qinling Mountains, China. Smithsonian Contributions to Paleobiology, number 92, 47 pages, 11 figures, 6 plates, 5 tables, 2001. Forty-eight species in 27 genera of gastropods, including 14 new species and one new genus, are described from early- to middle-Triassic (Scythian- to Ladinian-aged) rocks from the southern Qinling Mountains of Gansu and Sichuan provinces, China. This report expands the knowledge of the biogeographic distribution of gastropods during the recovery from the end-Permian mass extinction. The new taxa include Tongweispira sichuanensis, new genus and new species, and the following new species: Ananias guojiashanensis, Worthenia extendia, Gosseletina ? dangchangensis, Zygites laevigatus, Trochotoma ( Discotoma) gansuensis, Cheilotomona acutocarinata, Naticopsis ( Dicosmos ) compressus, Naticopsis {Dicosmos) sichuanensis, Naticopsis? ribletella, Neritopsis planoplicatus, Platychilina sinen¬ sis, Platychilina obliqua, and Omphaloptycha gansuensis. Official publication date is handstamped in a limited number of initial copies and is recorded in the Institution’s annual report, Annals of the Smithsonian Institution. Series COVER DESIGN: The trilobite Phacops rana Green. Library of Congress Cataloging-in-Publication Data Tong, Jinnan. Triassic gastropods of the southern Qinling Mountains, China / Jinnan Tong and Douglas H. Erwin. p. cm. — (Smithsonian contributions to paleobiology ; no. 92) Includes bibliographical references. 1. Gastropoda, Fossil—China—Qinling Mountains. 2. Paleontology—Triassic. 3 Animals, Fossil— China—Qinling Mountains. I. Erwin, Douglas H., 1958- II. Title. III. Series. QE701 .S56 no. 92 [QE808] 560 s—dc21 [564’.3] 00-068760 © The paper used in this publication meets the minimum requirements of the American National Standard for Permanence of Paper for Printed Library Materials Z39.48_1984. Contents Page Introduction. 1 Material. 1 Acknowledgments. 1 General Geology and Stratigraphy. 2 Gastropod Assemblages. 3 Lower Triassic Gastropods. 3 Middle Triassic Gastropods. 5 Anisian Gastropods. 5 Ladinian Gastropods. 5 Distribution. 7 Geological Distribution. 7 Paleobiogeographic Distribution . 7 Systematic Paleontology. 9 Class Gastropoda Cuvier, 1797. 9 Subclass EOGASTROPODA Ponder and Lindberg, 1995 . 9 Order Euomphalina de Koninck, 1881. 9 Superfamily Euomphaloidea de Koninck, 1881. 9 Family Euomphalidae de Koninck, 1881. 9 Tongweispira, new genus. 9 Tongweispira sichuanensis, new species. 10 Subclass Orthogastropoda? Ponder and Lindberg, 1995 . 10 Order VETIGASTROPODA? Salvini-Plawen, 1980 . 10 Superfamily Eotomarioidea Ulrich and Scofield, 1897 . 10 Family Eotomariidae Wenz, 1938. 10 Genus Ananias Knight, 1945 . 10 Ananias johannisaustriae (Klipstein, 1843). 10 Ananias guojiashanensis, new species. 11 Family Lophospiridae Wenz, 1938 . 11 Genus Wort hen ia de Koninck, 1883. 11 Worthenia extendia, new species. 11 Worthenia'? species indeterminate A. 12 Worthenia ? species indeterminate B. 12 Worthenia ? species indeterminate C. 12 Family GOSSELETINIDAE Wenz, 1938 . 13 Genus Gosseletina Bayle in Fischer, 1885. 13 Gosseletinal dangchangensis, new species. 13 Family Zygitidae Cox, 1960 . 13 Genus Zygites Kittl, 1891. 13 Zygites laevigatus, new species. 13 Family Phymatopleuridae Batten, 1956 . 14 Genus Euryalox Cossmann, 1896. 14 Euryalox species indeterminate. 14 Genus Codinella Kittl, 1899. 14 Codinellal species indeterminate. 15 Family Trochotomidae Cox, 1960 . 15 Genus Trochotoma Eudes-Deslongchamps, 1843 . 15 Subgenus Discotoma Haber, 1934 . 15 iii IV SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Trochotoma {Discotoma) gansuensis, new species. 15 Superfamily Trochoidea Rafinesque, 1815. 15 Family TROCHIDAE Rafinesque, 1815. 15 Genus Tylotrochus Koken, 1896. 15 Tylotrochus elongatus Bandel, 1993 . 15 Family TURBINIDAE Rafinesque, 1815. 16 Genus Natiria de Koninck, 1881. 16 Natirial species indeterminate. 16 Superfamily AMBERLEYOIDEA Wenz, 1938. 16 Family Amberleyidae Wenz, 1938 . 16 Genus Amberleya Morris and Lycett, 1851. 16 Amberleyal species indeterminate. 16 Genus Eunemopsis Kittl, 1891. 17 lEunemopsis dolomitica Kittl, 1891 . 17 Suborder Uncertain. 17 Superfamily Murchisonioidea Koken, 1896. 17 Family MURCHISONIIDAE Koken, 1896 . 17 Genus Cheilotomona Koken, 1889. 17 Cheilotomona acutocarinata, new species. 17 Unnamed Clade (Neritopsina + Cocculinoidea) Ponder and Lindberg, 1997 . 17 Superfamily Neritoidea Rafinesque, 1815. 17 Family NERITOPSIDAE Gray, 1847 . 18 Genus Marmolatella Kittl, 1894. 20 Subgenus Marmolatella Kittl, 1894. 20 Marmolatella {Marmolatella ) complanata (Stoppani, 1857). . . 20 Marmolatella {Marmolatella) obtusangula (Koken, 1897), new combination. 20 Genus Naticopsis M’Coy, 1844 . 20 Subgenus Dicosmos Canavari, 1890 . 20 Naticopsis {Dicosmos) applanatus Kutassy, 1937, new combination. 20 Naticopsis {Dicosmos) compressus, new species. 21 Naticopsis {Dicosmos) declivis (Kittl, 1894), new combi¬ nation . 21 Naticopsis {Dicosmos ) eyerichi (Noetling, 1880), new combi¬ nation . 21 Naticopsis {Dicosmos) impressa (Munster, 1841). 22 Naticopsis {Dicosmos) sichuanensis, new species. 22 Subgenus Vernelia Bohm, 1895 . 22 Naticopsis {Vernelia) sublimneiformis Kittl, 1894. 22 Subgenus Uncertain. 23 Naticopsis ? ribletella, new species. 23 Genus Neritopsis Grateloup, 1832 . 23 Neritopsis planoplicatus, new species. 23 Family NERITIDAE Rafinesque, 1815. 24 Genus Neritaria Koken, 1892 . 24 Neritaria cf. calcitica (Kittl, 1894). 24 Neritaria Candida { Kittl, 1894). 24 Neritaria ingrandita (Kittl, 1894). 25 Neritariaplicatilis (Klipstein, 1843). 25 Neritaria sphaeroidica Picard, 1903 . 25 Genus Platychilina Koken, 1892 . 25 Platychilina sinensis, new species. 26 NUMBER 92 v Platychilina obliqua, new species. 26 Order Apogastropoda Salvini-Plawen and Haszprunar, 1987, sensu Ponder and Lindberg, 1997. 27 Suborder Caenogastropoda Cox, 1960 . 27 Superfamily Loxonematoidea Koken, 1889. 27 Family Spirostylidae Cossmann, 1909. 27 Genus Spirostylus Kittl, 1894. 27 Spirostylus cf. linctus (Bohm, 1895). 27 Spirostylus species indeterminate. 27 Family COELOSTYLINIDAE Cossmann, 1909 . 27 Genus Toxoconcha Kittl, 1899. 27 Toxoconcha uniformis (Stoppani, 1858). 27 Genus Coelostylina Kittl, 1894 . 28 Coelostylina ahlburgi (Assmann, 1924), new combination.... 28 Coelostylina cf. waageni Kittl, 1894 . 28 Coelostylina ? species indeterminate. 28 Genus Omphaloptycha Ammon, 1892. 29 Omphaloptycha gansuensis, new species. 29 Genus Gradiella Kittl, 1899. 29 Gradiella species indeterminate. 29 Genus Trypanostylus Cossmann, 1895. 29 Trypanostylus konincki (Munster, 1841). 30 Trypanostylus cf. pseudoscalatus Assmann, 1924. 30 Superfamily PSEUDOMELANIOIDEA Fischer, 1885 . 30 Family Pseudomelaniidae Fischer, 1885 . 30 Genus Ramina Wenz, 1938 . 30 Raminaptychitica (Kittl, 1894) . 30 Subclass Heterostropha Fischer, 1885. 30 Superfamily STREPTACIDOIDEA Knight, 1931. 30 Family STREPTACIDAE Knight, 1931. 30 Genus Neodonaldina Bandel, 1996 . 30 Neodonaldina cf. elongata (Zardini, 1978). 31 Superfamily Mathildoidea Dali, 1889 .:. 31 Family Mathildidae Dali, 1889. 31 Genus and species indeterminate. 31 Plates 1-6. 32 Literature Cited. 44 Triassic Gastropods of the Southern Qinling Mountains, China Jinnan Tong and Douglas H. Erwin Introduction This is the first report of marine Triassic gastropods from the Qinling Mountains, Gansu and Sichuan provinces, northwest¬ ern China. Forty-eight species in 27 genera are described, of which 14 species and one genus are new. This assemblage is the most abundant marine Triassic gastropod fauna yet de¬ scribed from the northwestern China region and one of the most diverse Triassic gastropod faunas known worldwide. Triassic gastropods were first described from Middle and Upper Triassic rocks of the European Alps and neighboring areas during the mid-1800s (see the excellent catalogs of Diener, 1926, and Kutassy, 1937a, 1937b). Although many Late Triassic specimens have been discovered in North and South America (e.g., Haas, 1953; Erwin in Stanley et al., 1994), gastropods are relatively rare in Lower and Middle Tri¬ assic deposits (Batten and Stokes, 1986). In China, the earliest descriptions of Triassic gastropods were provided by Loczy (1899) from northern Yunnan Prov¬ ince (five species in four genera) and by Koken (1900) from Sizishan, Guizhou Province (eight species in six genera). Stud¬ ies of Triassic gastropods have been more common in the past 20 years, when Pan (1977, 1980, 1982a, 1982b) and Yin and Yochelson (1983a, 1983b, 1983c) described several abundant Jinnan Tong, China University of Geosciences, Wuhan 430074, Peo¬ ples Republic of China. Douglas H. Erwin, Department of Paleobiol¬ ogy, National Museum of Natural History, Smithsonian Institution, Washington, D.C. 20560-0121, U.S.A. Reviewers: Ellis L. Yochelson, Department of Paleobiology, National Museum of Natural History, Smithsonian Institution, Washington, D.C. 20560-0121, U.S.A.; Alex Niitzel, Department of Paleobiology, National Museum of Natural History, Smithsonian Institution [pres¬ ently at Palaontologisches Institut, Lowenichstrasse 28, D-91054 Erlangen, Germany]', Roger Batten, Phoenix, Arizona, U.S.A.; and Peter Wagner, Department of Geology, Field Museum of Natural His¬ tory, Chicago, Illinois, U.S.A. marine Triassic gastropod faunas in southwestern China. The relatively continuous Permian and Triassic depositional se¬ quence includes diverse assemblages of gastropods from the Upper Paleozoic to the Upper Triassic. The histories of these assemblages were summarized by Pan (1980), Pan and Erwin (1994), and Erwin and Pan (1995). The Triassic gastropod as¬ semblage from northwestern China differs markedly from the southwestern region of the country and has greater similarity to Tethyan regions than do the assemblages from southern China. Material. —All specimens described herein have been de¬ posited in the National Museum of Natural History (NMNH), Smithsonian Institution, and have been assigned USNM (col¬ lections of the former United States National Museum, now housed in the NMNH) catalog numbers. For many species, the total number of available specimens, including partial or in¬ complete specimens, is noted under “Material Examined” in the species account; only type specimens and specimens fig¬ ured or measured were given catalog numbers. All specimen measurements are given in millimeters (mm) unless indicated otherwise; in tables, a dash indicates a measurement was not taken. Acknowledgments. —Jinnan Tong acknowledges support of the Scholarly Studies Program of the Smithsonian Institu¬ tion, Professor Hongfu Yin for arranging this cooperation and for comments on this manuscript, the Qinling workgroup of China University of Geosciences (Wuhan) for collecting these fossils, and Mrs. Xinqi Xiong for repairing some fossil speci¬ mens. Elisabeth Valiulis digitized the images, prepared the plates, and aided in preparation of the final manuscript. The au¬ thors thank Roger Batten, Peter Wagner, Alex Niitzel, and Ellis L. Yochelson for discussions and review of the manuscript; they also acknowledge the Smithsonian Institution and the Exobiology Program of the National Aeronautics and Space Administration for their support. This research was also sup¬ ported by the National Natural Science Foundation of China (grant no. 49632070). 1 2 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY General Geology and Stratigraphy The fossils described herein were collected from two marine Triassic sections in northwestern China: Guojiashan, Qinyu Xiang (Town), Dangchang Xian (County), Gansu Province, and Saierlangshan, Hongxing Xiang, Zoige Xian, Sichuan Province (Figure 1). These two sections lie about 120 km apart in the southern Qinling Mountains. Both belong to the South Qinling tectonostratigraphic province (Yin et al., 1992)— Guojiashan is part of the northern zone whereas Saierlangshan lies in the southern zone (Figure 2). Their sedimentary se¬ quences and faunas are similar. The South Qinling tectono¬ stratigraphic province was a part of the Yangtze Platform dur¬ ing the Early to Middle Triassic and records a transition from carbonate to clastic rocks intercalated with bioclastic lime¬ stones. At the Guojiashan section, gastropods are both abun¬ dant and diverse in the Guojiashan Formation (Anisian age). At the Saierlangshan section, gastropods have been recovered at horizons ranging from Induan through Ladinian. The following overview of the stratigraphy and depositional environments is primarily based on the Saierlangshan section (Figure 3). The gastropods found in each section are listed in Table 1. Zalishan Formation (previously the Bobanshan Forma¬ tion).—The formation is composed of a gray and dark gray, thin- to medium-bedded and thick-bedded micrite, intercalated with purplish red thin-bedded argillaceous limestone and gray, medium- to thin-bedded bioclastic-bearing limestone; it is 693.5 m thick and conformable with the underlying Permian. Bivalves, gastropods, trace fossils, and elements of the bivalve Claraia hubeiensis assemblage, the Claraia stachei-C. aurita assemblage, and the Eumorphotis multiformis-E. inaequicos- tata assemblage are found at many horizons. At the type local¬ ity in Zalishan, Yiwagou, Tewo Xian, Gansu Province, the for¬ mation includes the Hindeodus parvus, Neospathodus dieneri, N. pakistanensis, and Pachycladina-Parachirognathodus co- nodont zones, documenting a range from early Induan to early Olenekian (for details of the assemblages and biostratigraphic correlations, see Yang and Li, 1992). Gastropods have been re¬ covered mostly from near the base of the section, but some were near the top as well. Maresongduo Formation. —This formation is composed of a yellowish gray and light gray, thin- to medium-bedded do¬ lomite intercalated with a few beds of light gray, medium- to thin-bedded dolomitic limestone and occasionally with a pos¬ sible evaporite solution breccia; the total thickness is 126.5 m. This formation contains only scattered bivalves and gastro¬ pods, including Chlamys ( Praechlamys ) weiyuanensis (Hsu). At the type locality in Yiwagou, Tewo Xian, the Neospathodus triangularis and N. hungaricus-N. homeri conodont zones in¬ dicate a late Olenekian age. Guojiashan Formation. —The lower part of this forma¬ tion is composed of gray, medium-bedded bioclastic dolomitic limestone; the middle part is a gray, medium-bedded algal FIGURE 1.—Location in China of the marine Triassic sections discussed in this paper. clastic micrite intercalated with stromatolitic limestone; and the upper part is a gray, medium- to thin-bedded micrite with intercalated gray, medium- to thick-bedded calcirudite; the to¬ tal thickness is 1424.5 m. Numerous fossil bivalves and gas¬ tropods and several brachiopods have been collected at many horizons in this formation; most of them are from beds in the lower and middle parts of the unit. The bivalves include the Plagiostoma beyrichii-Chlamys ruoergaiensis assemblage. At the type locality at Guojiashan, Dangchang Xian, many bi¬ valves, gastropods, brachiopods, ammonoids, and conodonts have been recovered. The conodonts are of the Neospathodus constricta zone and the ammonoids include Procladiscites, in¬ dicating an Anisian age. Guanggaishan Formation.— Only the lower unit is ex¬ posed in the Zoige Xian area (Lagecaimo) where it is com¬ posed of alternating beds of gray or grayish blue, fine quartzose sandstone and siltstone with thin-bedded, gray micrite interca¬ lated with a gray, medium- to thin-bedded intraformational breccia; the total thickness is 454 m. Although this unit is poorly fossiliferous, the matrix of one brecciola bed in the middle to upper part of this unit contains the Leptochondria seebachi-Entolioides subdemissus bivalve assemblage and a few brachiopods and gastropods. The corresponding strata have been described as the Qinyu Formation in the Dangchang area, where the conodonts Neogondolella mombergensis Tatge, N. navicula Huckriede, and N. excelsa Mosher have been dis¬ covered, indicating an early Ladinian age. NUMBER 92 3 105 FIGURE 2.—Distribution of Triassic rocks and tectonostratigraphic divisions of South Qinling. 1 = Upper Trias- sic, 2 = Middle Triassic, 3 = Lower Triassic, 4 = Lower-Middle Triassic, 5 = Indosinian intermediate-acid rocks, 6 = geological boundary, 7 = faulted zone, 8 = sections yielding gastropods; A = southern margin of North China Platform, B = northern zone of South Qinling tectonostratigraphic province, C = southern zone of Central Qinling province, D = northern zone of South Qinling province, E = southern zone of South Qinling province, and F = Bayan Har province. Gastropod Assemblages Previous studies of Triassic gastropods from China empha¬ sized the southwestern part of the country, and the reports on the Triassic gastropods of northwestern China are rare. In the southwest, Yin and Yochelson (1983a, 1983b, 1983c) listed 14 genera and 11 species from South Qingyan, Guizhou Province, and Wang and Qi (1986) studied 13 genera and 19 species from various areas of Qinghai Province. These reports are from scattered horizons deposited from the Early to the Late Triassic. Lower Triassic Gastropods The Saierlangshan section contains two beds containing gas¬ tropods of the Zalishan Formation but only four specimens from the Maresongduo Formation. Interestingly, many of these specimens are larger than those found in corresponding strata in the other areas on the world. No bellerophontids have been collected here. Zalishan Formation. —The Toxoconcha gastropod bed is located close to the base of the Zalishan Formation and is com¬ posed primarily of Toxoconcha uniformis\ other forms are rare, high-spired, and medium- to large-sized. The shells in this bed are of smaller size, which is quite different from shells in equivalent rocks from other areas. Although the assemblage is dominated by T. uniformis, which occurs in the Ladinian of the southern Alps, and by other species that also occur in younger rocks in Europe, the presence of the Claraia stachei-C. aurita bivalve assemblage demonstrates an Early Triassic age. No ev¬ idence of redeposition was observed. As discussed elsewhere, the stratigraphic evidence suggests these gastropod lineages occur earlier in northern China than in the Alps. Maresongduo Formation. —This formation was depos¬ ited under restricted conditions and contains very few fossils. There are only a few poorly preserved specimens of the 4 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Table I.— List of the Triassic gastropods found in southern Qinling, China. An asterisk (*) indicates holotype specimen; GS = Guojiashan section, Gansu Province; SC = Saierlangshan section, Sichuan Province; MF - Maresongduo Formation of Saierlangshan, Sichuan Province, but the exact bed no. is not known because the specimen was collected from a nearby section. Genus and species USNM catalog no. Section Bed no. Genus and species USNM catalog no. Section Bed no. Amberleyal sp. indet. 485537 SC 16-1 Naticopsis (Dicosmos) compressus, n. sp. 485581* GS 20 Ananias guojiashanensis, n. sp. 485500 GS 20 Naticopsis (Dicosmos) declivis (Kittl) 485547 GS 20 Ananias guojiashanensis, n. sp. 485502* GS 19-3 Naticopsis (Dicosmos) declivis (Kittl) 485548 GS 20 Ananias guojiashanensis, n. sp. 485503 GS 19-3 Naticopsis (Dicosmos) declivis (Kittl) 485549 GS 20 Ananias guojiashanensis, n. sp. 485509 GS 19-3 Naticopsis (Dicosmos) declivis (Kittl) 485550 GS 20 Ananias johannisaustriae (Klipstein) 485510 GS 19-3 Naticopsis (Dicosmos) eyerichi (Noetling) 485557 SC 55-1 Ananias johannisaustriae (Klipstein) 485511 GS 19-3 Naticopsis (Dicosmos) eyerichi (Noetling) 485558 SC 55-1 Ananias johannisaustriae (Klipstein) 485512 SC 59 Naticopsis (Dicosmos) eyerichi (Noetling) 485559 SC 55-1 Ananias johannisaustriae (Klipstein) 485513 SC 59 Naticopsis (Dicosmos) eyerichi (Noetling) 485560 SC 55-1 Ananias johannisaustriae (Klipstein) 485515 GS 18-1 Naticopsis (Dicosmos) eyerichi (Noetling) 485561 SC 55-1 Cheilotomona acutocarinata, n. sp., 485621 SC 58-3 Naticopsis (Dicosmos) impressa (Munster) 485553 SC 62-1 Cheilotomona acutocarinata, n. sp.. 485622 SC 58-3 Naticopsis (Dicosmos) impressa (Munster) 485554 SC 62-1 Cheilotomona acutocarinata, n. sp., 485623 SC 60-1 Naticopsis (Dicosmos) impressa (Munster) 485555 SC 62-1 Cheilotomona acutocarinata, n. sp. 485624 SC 58-3 Naticopsis (Dicosmos) impressa (Munster) 485556 SC 62-1 Cheilotomona acutocarinata, n. sp. 485625 SC 58-3 Naticopsis (Dicosmos) sichuanensis, n. sp. 485562* SC 62-1 Cheilotomona acutocarinata, n. sp. 485626* SC 58-3 Naticopsis (Dicosmos) sichuanensis, n. sp. 485563 SC 62-1 Cheilotomona acutocarinata, n. sp. 485627 SC 58-3 Naticopsis (Dicosmos) sichuanensis, n. sp. 485564 SC 62-1 Codinellal sp. indet. 485527 GS 19-3 Naticopsis (Dicosmos) sichuanensis, n. sp. 485565 SC 62-1 Codinellal sp. indet. 485528 GS 20 Naticopsis (Dicosmos) sichuanensis, n. sp. 485566 sc 62-1 Coelostylina ahlburgi (Assmann) 485637 SC 74-1 Naticopsis (Dicosmos) sichuanensis, n. sp. 485567 sc 62-1 Coelostylina ahlburgi (Assmann) 485638 SC 74-1 Naticopsis (Dicosmos) sichuanensis, n. sp. 485568 sc 62-1 Coelostylina ahlburgi (Assmann) 485639 SC 77-1 Naticopsis (Dicosmos) sichuanensis, n. sp. 485569 sc 62-1 Coelostylina cf. waageni Kittl 485640 GS 19-3 Naticopsis (Dicosmos) sichuanensis, n. sp. 485570 sc 95-1 Coelostylina cf. waageni Kittl 485641 SC 16-1 Naticopsis (Dicosmos) sichuanensis, n. sp. 485571 sc 95-1 Coelostylina1 sp. indet. 485644 SC 16-1 Naticopsis (Dicosmos) sichuanensis, n. sp. 485572 sc 77-1 1Eunemopsis dolomitica Kittl 485620 GS 19-3 Naticopsisl ribletella, n. sp. 485586* GS 20 Euryalox sp. indet. 485526 GS 20 Naticopsisl ribletella, n. sp. 485587 GS 20 Genus and sp. indet. 485654 GS 18-1 Naticopsis (Vernelia) sublimneiformis Kittl 485582 GS 19-3 Gosseletinal dangchangensis, n. sp. 485520* GS 20 Naticopsis (Vernelia) sublimneiformis Kittl 485583 GS 20 Gosseletinal dangchangensis, n. sp. 485521 GS 19-3 Naticopsis (Vernelia) sublimneiformis Kittl 485584 GS 19-3 Gosseletinal sp. indet. 485519 SC 55-1 Naticopsis (Vernelia ) sublimneiformis Kittl 485585 SC 95-1 Gradiella sp. indet. 485652 SC 16-1 Natirial sp. indet. 485538 MF - Gradiella sp. indet. 485653 SC 16-1 Neodonaldina cf. elongata (Zardini) 485645 GS 20 Marmolatella (Marmolatella) complanata 485539 GS 20 Neritaria cf. calcitica (Kittl) 485589 GS 19-3 (Stoppani) Neritaria cf. calcitica (Kittl) 485590 GS 19-3 Marmolatella ( Marmolatella ) complanata 485540 GS 20 Neritaria cf. calcitica (Kittl) 485591 GS 19-3 (Stoppani) Neritaria cf. calcitica (Kittl) 485592 GS 19-3 Marmolatella (Marmolatella) complanata 485541 GS 20 Neritaria Candida (Kittl) 485593 GS 19-3 (Stoppani) Neritaria Candida (Kittl) 485594 GS 19-3 Marmolatella ( Marmolatella ) complanata 485542 GS 20 Neritaria Candida (Kittl) 485595 GS 19-3 (Stoppani) Neritaria Candida (Kittl) 485596 GS 19-3 Marmolatella (Marmolatella) cf. complanata 485543 GS 20 Neritaria Candida (Kittl) 485597 GS 20 (Stoppani) Neritaria Candida (Kittl) 485598 GS 20 Marmolatella (Marmolatella) obtusangula 485551 GS 19-3 Neritaria ingrandita (Kittl) 485606 SC 58-3 (Koken) Neritaria ingrandita (Kittl) 485607 GS 20 Marmolatella (Marmolatella ) obtusangula 485552 GS 19-3 Neritaria plicatilis (Klipstein) 485608 SC 95-1 (Koken) Neritaria sphaeroidica Picard 485599 GS 20 Naticopsis ( Dicosmos ) applanatus Kutassy 485544 GS 19-3 Neritaria sphaeroidica Picard 485600 GS 20 Naticopsis (Dicosmos) applanatus Kutassy 485545 GS 19-3 Neritaria sphaeroidica Picard 485601 GS 20 Naticopsis (Dicosmos) applanatus Kutassy 485546 GS 19-3 Neritaria sphaeroidica Picard 485602 GS 18-1 Naticopsis (Dicosmos) compressus, n. sp. 485573 GS 20 Neritaria sphaeroidica Picard 485603 GS 18-1 Naticopsis (Dicosmos) compressus, n. sp. 485574 GS 20 Neritaria sphaeroidica Picard 485604 GS 18-1 Naticopsis (Dicosmos) compressus, n. sp. 485575 GS 20 Neritaria sphaeroidica Picard 485605 GS 19-3 Naticopsis (Dicosmos) compressus, n. sp. 485576 GS 19-3 Neritopsis planoplicatus, n. sp. 485588* GS 19-3 Naticopsis (Dicosmos) compressus, n. sp. 485577 GS 19-3 Omphaloptycha gansuensis, n. sp. 485642 GS 20 Naticopsis (Dicosmos) compressus, n. sp. 485578 GS 19-3 Omphaloptycha gansuensis, n. sp. 485643* GS 20 Naticopsis (Dicosmos) compressus, n. sp. 485579 GS 20 Platychilina obliqua, n. sp. 485615 SC 72-1 Naticopsis (Dicosmos) compressus, n. sp. 485580 GS 20 Platychilina obliqua, n. sp. 485616 GS 19-3 NUMBER 92 5 Table 1.—Continued. Genus and species USNM catalog no. Section Bed no. Genus and species USNM catalog no. Section Bed no. Platychilina obliqua, n. sp. 485617* GS 20 Toxoconcha uniformis (Stoppani) 485634 SC 16-1 Platychilina obliqua, n. sp. 485618 GS 20 Triassocirrus? sp. indet. 485499 GS 20 Platychilina obliqua, n. sp. 485619 GS 20 Trochotoma ( Discotoma ) gansuensis, n. sp. 485529 GS 20 Platychilina sinensis, n. sp. 485609 GS 20 Trochotoma ( Discotoma) gansuensis, n. sp. 485530* GS 20 Platychilina sinensis, n. sp. 485610 GS 20 Trochotoma (Discotoma) gansuensis, n. sp. 485531 GS 20 Platychilina sinensis, n. sp. 485611* GS 20 Trypanostylus konincki (Munster) 485647 GS 19-3 Platychilina sinensis, n. sp. 485612 GS 20 Trypanostylus konincki (Munster) 485648 GS 19-3 Platychilina sinensis, n. sp. 485613 GS 20 Trypanostylus konincki (Munster) 485649 GS 19-3 Platychilina sinensis, n. sp. 485614 GS 20 Trypanostylus konincki (Munster) 485650 GS 19-3 Ramina ptychitica (Kittl) 485656 SC 77-1 Trypanostylus cf. pseudoscalatus Assmann 485651 SC 35-1 Spirostylus cf. linctus (Bohm) 485629 SC 60 Tylotrochus elongatus Bandel 485532 SC 77-1 Spirostylus sp. indet. 485628 SC 16-1 Worthenia extenciia, n. sp. 485501 GS 19-3 Tongweispira sichuanensis, n. gen., n. sp. 485491 SC 58-3 Worthenia extendia, n. sp. 485504 GS 20 Tongweispira sichuanensis, n. gen., n. sp. 485492 SC 58-3 Worthenia extendia, n. sp. 485505* GS 20 Tongweispira sichuanensis, n. gen., n. sp. 485493 SC 58-3 Worthenia ? sp. indet. A 485506 SC 60-1 Tongweispira sichuanensis, n. gen., n. sp. 485494* SC 58-3 Worthenia ? sp. indet. A 485507 SC 60-1 Tongweispira sichuanensis, n. gen., n. sp. 485495 SC 58-3 Worthenia? sp. indet. A 485508 SC 60-1 Tongweispira sichuanensis, n. gen., n. sp. 485496 SC 58-3 Worthenia ? sp. indet. B 485514 GS 20 Tongweispira sichuanensis, n. gen., n. sp. 485497 SC 58-3 Worthenia? sp. indet. C 485516 GS 19-2 Tongweispira sichuanensis, n. gen., n. sp. 485498 SC 58-3 Worthenia? sp. indet. C 485517 GS 19-2 Toxoconcha brocchii brevis KittI 485635 SC 16-1 Worthenia? sp. indet. C 485518 GS 19-2 Toxoconcha uniformis (Stoppani) 485630 sc 16-1 Zygites laevigatus, n. sp. 485522 GS 20 Toxoconcha uniformis (Stoppani) 485631 sc 16-1 Zygites laevigatus. n. sp. 485523* GS 20 Toxoconcha uniformis (Stoppani) 485632 sc 16-1 Zygites laevigatus, n. sp. 485524 GS 20 Toxoconcha uniformis (Stoppani) 485633 sc 16-1 Zygites laevigatus, n. sp. 485525 GS 20 gastropod Gradiella and two better preserved shells similar to some species of Natiria. Middle Triassic Gastropods Anisian Gastropods Most of the fossils discussed in this paper are from the Anisian Guojiashan Formation of Saierlangshan, Sichuan Province, and of Guojiashan, Gansu Province. Saierlangshan Section. —Although gastropods are found at many horizons in the Guojiashan Formation, they are most common in the lower and middle units. This diverse as¬ semblage is dominated by three species: Naticopsis {Dicosmos) eyerichi, N. (D.) sichuanensis, new species, and Tongweispira sichuanensis, new genus, new species. Ananias johannisaus- triae, Worthenia? spp., Coelostylina ahlburgi, and Cheiloto- mona acutocarinata, new species, are also common. Naticop¬ sis ( Dicosmos ) eyerichi was previously described from the Muschelkalk and Coelostylina ahlburgi was described from the upper part of the Wellenkalk to the Muschelkalk of Eu¬ rope. Neritaria calcitica and Acilia cf. franciscae Bohm are found from the late Early Triassic to the Middle Triassic in Europe; the former was also discovered in the Naochuang- jiangou Formation (Middle Triassic) of Hongshuichuan, Du- lan Xian, Qinghai Province (Wang and Qi, 1986). In the Guo¬ jiashan Formation, however, some species such as Ramina ptychitica, Naticopsis ( Dicosmos) impressa, and Ananias jo- hannisaustriae occur in the Ladinian. In Europe, the gastro¬ pods found in these beds range from the late Early Triassic to the Ladinian. Guojiashan Section. —Of the four gastropod beds in the middle and upper parts of the Guojiashan Formation, the two lower beds yield relatively few fossils whereas the two upper beds contain a much richer gastropod assemblage. The pre¬ dominant members within these units are Marmolatella ( Mar- molatella) complanata, Neritaria sphaeroidica, Platychilina sinensis, new species, and Naticopsis ( Dicosmos ) compressus, new species. The less common species are Neritaria Candida, N. cf. calcitica, Platychilina obliqua, new species, Naticopsis {Dicosmos) declivis, N. {D.) applanatus, Trochotoma {Disco¬ toma) gansuensis, new species, and Trypanostylus konincki. Many of these species as well as rarer, coexisting forms such as Ananias johannisaustriae, Eunemopsis dolomitica, Nati¬ copsis {Vernelia) sublimneiformis, and Neodonaldina elongata have been reported from the Ladinian or younger units in Eu¬ rope. The associated bivalves, conodonts, and ammonoids in these beds suggest an Anisian age; thus, the unit may be some¬ what younger than the fossil beds in the Saierlangshan section. Ladinian Gastropods Gastropods of Ladinian age were found only in the lower part of the Guanggaishan Formation at the Saierlangshan section. One bed of this section is dominated by Naticopsis 6 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY NUMBER 92 7 ( Dicosmos ) sichuanensis, new species, but the species is not common; other taxa are even rarer. Naticopsis ( Dicosmos ) si¬ chuanensis, new species, is more abundant in the underlying Guojiashan Formation. The coexisting Naticopsis ( Vernelia) sublimneiformis and Neritaria plicatilis have been reported from the Ladinian and the Camian of the southern Alps. More than one-half of the Triassic gastropod species from the South Qinling stratigraphic province were first described from the European Alps or Polish Upper Silesia. Although the northern and southern China gastropod assemblages share some similarities, the differences are pronounced. Neriti- morphs predominate in this collection—perhaps for diagenetic reasons—and account for more than one-half of the total num¬ ber of specimens, which is similar to the Triassic fauna de¬ scribed from the South Qilian Mountains of northwestern China (Yang et al., 1983). Distribution Geological Distribution The conodonts and bivalves indicate an Anisian age for most of the gastropod assemblage, although the same gastropod spe¬ cies, or closely related species, are found in the Ladinian and Camian of Europe (Tables 2, 3). The Qinling fauna includes 38 species of Anisian age, three from the Ladinian, and only seven species from the Early Triassic. The abundant gastropods re¬ ported by Yin and Yochelson (1983a, 1983b, 1983c) from Qingyan, southwestern China, are also primarily from Anisian strata. These Chinese gastropod assemblages have extended the stratigraphic ranges of many genera into the Anisian and even down into the Early Triassic (Table 4), closing some of the gaps between Permian and Triassic faunas (Pan and Erwin, 1994; Erwin, 1996). A quarter of a century ago, most described Triassic gastro¬ pods were known from Ladinian, Camian, or younger units in Europe, and only a few had been described from the Early Tri¬ assic and Anisian; the situation is much the same today. Con¬ sequently, Batten (1973) viewed the Early Triassic and Ani¬ sian as a continuation of the end-Permian crisis for gastropods and suggested that gastropod recovery did not begin until after the Anisian. The results presented herein, however, together with those of Yin and Yochelson (1983a, 1983b, 1983c) dem¬ onstrate that the postextinction recovery was well underway by the Anisian. Work by Batten and Stokes (1986) suggests that the recovery may have begun by the end of the Early Tri¬ assic, at least in the western United States. As indicated by Yin and Yochelson (1983a), the large numbers of archaeogas- tropods within these Anisian gastropod assemblages makes them more similar to those of the Paleozoic than to later Me¬ sozoic gastropod assemblages. Thus, the extinction across the Paleozoic-Mesozoic boundary seems less significant for gas¬ tropods than it was for brachiopods, crinoids, or several other Table 2. —Distribution of previously described gastropod species collected from Qinling, northwestern China, showing their age and the age of the species in European and other Chinese faunas (A = Anisian, C = Camian, L = Ladin¬ ian, N = Norian, S = Scythian, T2 = Middle Triassic). A question mark (?) indi¬ cates species identification is uncertain at the location; ages in parentheses are for closely related species within the genus; a dash (-) indicates species was not collected from the region. European and other Chinese taxa are cited in the individual species accounts. Species Age by location Qinling, NW China Europe China SW China Acilia franciscae (A) L - - Ananias johannisaustriae A C - A Coelostylina ahlburgi A A-L - A Coelostylina waageni (S-A) (A)C - - lEunemopsis dolomitica ?A C - - Marmolatella ( Marmolatella ) complanata A L - - Marmolatella ( Marmolatella ) oblusangula A C-N - - Naticopsis ( Dicosmos ) applanatus A C - - Naticopsis ( Discosmos) declivis A L-N - - Naticopsis ( Dicosmos) eyerichi A A-L - - Naticopsis ( Dicosmos ) impressa A C - Naticopsis ( Vernelia ) sublimneiformis A-L L - - Neodonaldina elongata A C - - Neritaria calcitica (A) A-L T2 - Neritaria Candida A L - A Neritaria ingrandita A L - - Neritaria plicatilis L C-N - - Neritaria sphaeroidica A A - - Proturba intermittens A C - - Ramina ptychitica A L - Spirostylus linctus (A) L - - Toxoconcha brocchii S A-L - A Trypanostylus konincki A A-C - - Trypanostylus cf. pseudoscalatus ?S A - - Trypanostylus semiglaber (A) C - - groups (Erwin, 1993, 1994; Pan and Erwin, 1994). The new information presented herein suggests that many of the Trias¬ sic genera originated during the Early Triassic and the early Anisian (Table 4). Paleobiogeographic Distribution Unlike the Triassic gastropod faunas of southern China, those from Qinling share many species with European gastro¬ pod assemblages (Table 2). Many Chinese species, including new species, appear to be closely related to European forms (Table 3). In contrast, the relationships between the Chinese and European gastropods and the American taxa are weak; even at the generic level the similarity is very low (Table 4). These differences may be exacerbated by lack of recent sys¬ tematic treatment. Many European gastropod species were last studied more than 100 years ago and are only now undergoing reexamination (e.g., Bandel, 1988, 1991, 1992, 1993, 1994, 1995, 1996; Schwardt, 1992; Niitzel, 1997). Completion of this work will be necessary for more detailed consideration of the biogeographic relationships with Chinese taxa. Material in 8 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Table 3. —Geographic distribution and age of species probably related to those newly collected from Qinling, China. Age abbreviations: A = Anisian, C = Camian, L = Ladinian, N = Norian, S = Scythian; a dash (-) indi¬ cates species was not collected from the region. Data sources: Diener (1926), Kutassy (1937b), this paper, and Tong and Erwin, unpublished. Species from Qinling, China Age Probable related species Age by location NW SW Europe China China Ananias guojiashanensis, n. sp. A Worthenia marmolatae Kittl L - - Cheilotomona acutocarinata, n. sp. A Cheilotomona avisii Bohm, C. blumii (Wissmann) L-C - - Codinellal sp. indet. A Codinella leda (Kittl) L - - Coelostylinal sp. indet. S Coelostylina irritata Kittl L-C L - Euryalox sp. indet. A Euryalox subcancellata (d’Orbigny) C - - Gosseletina? dangchangensis, n. sp. A Gosseletinafasciolata (Munster) L-R - - Gosseletinal sp. indet. A Gosseletina calypso (Laube) C - - Gradiella sp. indet. S Gradiella semigradata (Kittl), G. gradata (Homes) L C - Naticopsis ( Dicosmos ) compressus, n. sp. A Naticopsis (D.) declivis L-N - - Naticopsis ( Dicosmos ) siehuanensis, n. sp. Omphaloptycha gansuensis, n. sp. A-L A N. (D.) cassiana (Wissmann), N. (D.) impressa Omphaloptycha jaworskii Haas, O. cochlea (Munster) L-N L-C — _ Platychilina obliqua, n. sp. A Platychilina tuberculata Kittl L - - Platychilina sinensis, n. sp. A Trachynerita nodifera Kittl L-C - - ' Spirostvlus sp. indet. S Spirostylus subcolumnaris (Munster) A-C - A Triassocirrus ? sp. indet. A Triassocirrus infracarinatum (Kittl) L - - Trochotoma {Discotoma) gansuensis, n. sp. A Discotoma planoconvexa Pan - - - Worthenia extendia, n. sp. A Worthenia conica Assmann A - A Worthenia ? sp. indet. B A Worthenia esinensis Kittl L - - Zygites laevigatas, n. sp A Zygites delphinula (Laube) C - - Table 4.—Age of genera found in Qinling, China, and their distribution by age and occurrence in other geo¬ graphic areas of the world. Ages are defined in Table 3. Symbols: + = occurrence of genus; * = specimens of indi¬ cated age found only in China to date; ? = forms found were of questionable identity; a dash (-) = no occurrence. Genus Age in Qinling Occurrence by age Occurrence by geographic area Pre- Triassic Scythian Anisian Ladinian Camian Norian, Rhaetian Post- Triassic Europe Western Asia Other areas in China Southeast Asia, Australia North and South America Ac ilia A - - * + + + - + - — — — Amber ley a S - * - + + + + - - - - Ananias A + - * - - - + - + + + Cheilotomona A - - + + + - - + - — — — Codinella ?A - - ?* + * - - — - + — — Coelostylina S, A - * * + + + + + + + + + Eunemopsis A - - * + + - - + - - - Euryalox A - - + + + + - + - + + — Gosseletina ?A + * + + + + - + - + - + Gradiella S - ♦ - + + + - + — + — + Marmolatella (Marmolatella ) A + - + + + - - + - + - + Naticopsis {Dicosmos) A-L - - + + + - - + - + + - Naticopsis {Vernelia) A-L + - * + + - - + - + - + Natiria ?S-A + + + + + + * + - + + + Neodonaldina A - - * + + - - + — — — _ Neritaria A-L - ♦ * + + + - + - + — + Neritopsis A - - * + + + + + + - - + Omphaloptycha A + * + + + + - + + + - + Platychilina A - - * + + - - + - - - — Proturba A - - ♦ - + - - + — — — — Ramina A - - ♦ + + - - + — — — ?+ Spirostylus S-A - * * + + - - + - ?+ — + Toxoconcha A - * + + + + - + - + — + Triassocirrus ?A - - + + + - — + — + _ _ Trochotoma {Discotoma) A - + - - + + + — + — — Trypanostylus A - + + + + + + - + - — Tylotrochus A - - * - + + + + - - — — Zygites A - - * + - - - + - + - - NUMBER 92 9 Timor, Indonesia, also has been restudied (Tichy, 1979, 1980a, 1980b, 1980c). Gastropods were diverse during the late Paleozoic, and abun¬ dant gastropods assemblages have been found worldwide. Many genera had a more extensive geographic distribution dur¬ ing the late Paleozoic than during the Triassic, suggesting the end-Paleozoic extinction had a major impact on gastropod bio¬ geography. Although the paucity of Triassic gastropod assem¬ blages limits the extent of any biogeographic analysis, southern China was perhaps the only region where a shallow sea existed continuously from the Permian into the Triassic, and diverse gastropod faunas are known throughout this interval (Pan and Erwin, 1994; Erwin and Pan, 1995). Early Triassic gastropods were very rare and limited. The earlier reappearance of diverse gastropod assemblages in China relative to the western Tethys Sea or western North American suggests that the eastern Tethys may have served as a refuge during the end-Permian mass extinction (see also Batten, 1985). Both southern China and alpine Europe were located in the Tethys Sea during the Triassic. This tropical sea lay more or less parallel to the paleoequator, and no significant barriers to migration have been identified within it. In contrast, the paleo- Pacific was a natural barrier between the Tethys and America, and latitudinal temperature gradients restricted migration along the circum-Pacific margins. The earlier occurrence of many gastropod genera and species in China relative to Europe sug¬ gests a possible westward migration of the fauna through the Tethys during the Triassic. This suggestion is supported by the analysis by Yin and Yochelson (1983a, 1983b, 1983c) of the gastropods of Guizhou Province and by analyses of many other fossil groups including foraminifera and bivalves (e.g., Yin, 1994). The distribution of these gastropods was rigidly controlled by sedimentary facies. Almost all known abundant and diverse gastropod fossil assemblages are connected with shallow-water carbonate platforms, especially platforms with carbonate build¬ ups or bioherms. Yin and Yochelson’s (1983a, 1983b, 1983c) Anisian gastropods of Qingyan were deposited in front of a carbonate build-up. Similarly, the richest Ladinian gastropod faunas of this region were also in the setting of a shallow bank (Tong and Huang, 1992). Gastropods are also found on carbon¬ ate platforms, but they are generally not very diverse; they are extremely rare in the terrigenous elastics (Tong, 1997, 1998). The Qinling gastropods reported herein are mostly from car¬ bonate platforms, with the richest assemblage found in the Ani¬ sian shallow bank of Guojiashan. In Saierlangshan, the richest gastropod assemblages are found on Early Triassic and Ani¬ sian, semi-closed to open, carbonate platforms. During the La¬ dinian, this area developed into a bathyal carbonate basin, in which gastropods became very rare, and then into a terrigenous clastic basin. In Europe the richest assemblages of gastropods were also located on carbonate platforms. Systematic Paleontology Class Gastropoda Cuvier, 1797 Subclass EOGASTROPODA Ponder and Lindberg, 1995 Order Euomphalina de Koninck, 1881 Superfamily Euomphaloidea de Koninck, 1881 Family Euomphalidae de Koninck, 1881 The euomphaloids were a major clade of Paleozoic gastro¬ pods (see Wagner, in press, for a phylogenetic analysis), but their phylogenetic relationships with Triassic forms remain poorly understood (e.g., Bandel, 1988). Most had well-devel¬ oped whorl angulations—interpreted as exhalant channels— but the outer whorl surfaces were commonly smooth and with¬ out evident sculpture. Many Mesozoic euomphaloids differ from the Paleozoic forms in whorl features and ornament, rais¬ ing the uncertainty regarding the connection between the two groups. Mesozoic euomphaloids had been divided into two groups. The first group was characterized by increased devel¬ opment of shell sculpture, including nodes, ribs, and even spines, and included Woehrmannia, Discohelix, Triassocirrus, and Platybasis. Bandel (1993), however, transferred Woehr¬ mannia to the Trochomorpha, and Schroder (1995) transferred Discohelix to the new family Discohelicidae within the Tro- choidea. The second group maintained a smooth shell, but the whorl angulation became round as in Coelodiscus and the new genus Tongweispira. Bandel (1988) argued that none of these Mesozoic forms belong to the Euomphaloidea; rather, the gen¬ era belong to a variety of other groups including the Allogas- tropoda, the Trochoidea, the neogastropods, and an uncertain group of Vetigastropoda. Bandel, however, has not discussed any of the forms described herein, or any close relatives. Al¬ though recognizing the considerable uncertainties about the phylogenetic relationships of the group, we have elected to place them within the Euomphalidae as they appear to be more closely related to demonstrable Permian euomphalids than to any of the genera discussed by Bandel. We note, however, that Tongweispira may not be a euomphalid at all and may have close affinities with some trochids. Determining the relation¬ ship among the two groups, and between them and the Paleo¬ zoic lineages, will require detailed phylogenetic study beyond the scope of this contribution. Tongweispira, new genus Type Species. — Tongweispira sichuanensis, new genus, new species; by original designation. DIAGNOSIS. —Subdiscoidal to hemispherical euomphalids with depressed spire. Base convex and mostly embraced. Outer whorl face with one rounded angulation on middle to upper part. Umbilicus round and deep; width about one-third diameter of shell; umbilical angulation narrowly rounded. No prominent ornament. Aperture long and narrow but curved; holostomous. 10 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Discussion. —This genus is characterized by a depressed spire and a convex and entirely embraced base, producing a narrow umbilicus. Mesozoic low-spired discoidal genera in¬ clude the euomphalids Coelodiscus and Woehrmannia, but these all have protruding spires. Shells with a depressed spire occurred in some Paleozoic groups, such as the Permian genera Planotectus and Euomphalus; however, these Paleozoic genera have a marked outer-whorl angulation that might indicate a quite different ecological habit. This angulation is also similar to the Jurassic Coelodiscus and other younger shells and might suggest a link between some Paleozoic and Mesozoic forms. This new genus is also similar to ICondonella, a poorly known genus from the Upper Cretaceous. ETYMOLOGY. —The genus is named in honor of Jinnan Tong’s daughter Tongwei, who was born when these fossils were discovered. Tongweispira sichuanensis, new species Plate 1: figures 1-9 Diagnosis.—A s for the genus. Description. —Small- to medium-sized, subdiscoidal to hemispherical gastropod with widely depressed spire and markedly convex base. Sutures deeply impressed. Apex de¬ pressed. Shell of more than five whorls, not embraced on the adapical side but which almost entirely embrace earlier whorls at base; thus all whorls visible on spiral side and only final whorl and a round phaneromphalous umbilicus visible on basal side. Whorl profile crescentic; an obvious but rounded angula¬ tion at outer-upper edge; upper surface between angulation and suture flat to slightly concave; lateral face extending in -50° angle with upper face; lateral to lower surface evenly arched and continuously curved to base. Umbilicus round and deep; its width less than one-third diameter of shell; umbilical angula¬ tion narrowly rounded; no obvious ornament except for very faint, obviously opisthocline collabral lines, visible only on up¬ permost outer-wall layer of final whorl. Aperture long, narrow, and trapezoidal, narrowing at base; holostomatous. Shell wall of two almost equally thick layers; layers considerably thick¬ ened close to aperture. Material Examined. —Fifteen mostly well-preserved specimens from the lower part of the Guojiashan Formation at Saierlangshan. Type Specimens.— Holotype: USNM 485494; Para- types: USNM 485491-485493, 485495^185498. Measurements.— As follows: USNM catalog no. Shell height (mm) Shell width 485491 3.6 6.3 485492 8.8 19.0 485493 3.5 5.7 485494 5.4 8.8 485495 8.7 13.6 485496 5.0 7.3 485497 4.2 7.2 485498 5.4 7.9 Discussion. —The features distinguishing this species from other described genera are the widely depressed spire, strongly convex and embraced base, obtuse angulation of the middle to upper whorl, and lack of ornament. Etymology. —The species is named for the Chinese prov¬ ince where the specimens were discovered. Subclass Orthogastropoda? Ponder and Lindberg, 1995 Order Vetigastropoda? Salvini-Plawen, 1980 Superfamily Eotomarioidea Ulrich and Scofield, 1897 The affinities of the Eotomarioidea within modem gastropod classification remain unclear. They could fall within the Veti¬ gastropoda or may be paraphyletic relative to the Vetigas¬ tropoda. Family Eotomariidae Wenz, 1938 Genus Ananias Knight, 1945 TYPE Species. — Phanerotrema ? welleri Newell, 1935; by original designation. Discussion. —This genus is characterized by a moderately high-spired and gradate shell, which distinguishes this taxon from Glabrocingulum Thomas, 1940 (see Schindel, 1982). The narrow, concave selenizone at or immediately below the whorl shoulder distinguishes this species from the convex peripheral selenizone of Worthenia. Ananias is common in many late Paleozoic assemblages and has been traced into the Triassic by Yin and Yochelson (1983a). The genus is closely related to Raphistomella, whose Paleozoic forms are generally placed in Glabrocingulum. Earlier species of Ananias were generally or¬ namented and exhibited well-developed funicles, but in Perm¬ ian species the ornament and funicle became rare and weak. The Triassic Ananias were faintly ornamented and generally lacked funicles. We follow Batten (1989) in considering this a separate genus from Glabrocingulum in light of the evidence for a lengthy independent history. The relationships between Worthenia, Platyworthenia, and Wortheniella are discussed by Niitzel and Senowbari-Daryan (1999). Ananias johannisaustriae (Klipstein, 1843) Plate 1: figures 10-12 Pleurotomaria johannisaustriae Klipstein, 1843:161, pi. 10: fig. 13. [For intervening synonymy see Diener, 1926, and Kutassy, 1937b.] Worthenia apunctata Kittl, 1894b.—Zardini, 1978:20, pi. 5: fig. 8. Ananias joannis-austriae (Klipstein).—Yin and Yochelson, 1983a: 167, fig. 4I-K [lapsus calami], Wortheniella joannisaustriae (Klipstein).—Schwardt, 1992:41, pi. 5: fig. 1 [lapsus calami]. Description.— Small- to medium-sized, moderately spired pleurotomarioid. Pleural angle about 90°. Shell of four rapidly expanding whorls. Two strong, acute keels at upper and lower NUMBER 92 11 margin of outer whorl face. Sutural grooves narrow and shal¬ low. Sutural ramp obviously concave, about as wide as lateral face. Selenizone narrowly band-like and somewhat concave immediately below upper keel, observed in only two speci¬ mens. Lateral face nearly flat to slightly concave. Base low, convex, and rounded. Spiral threads regular, well and acutely protruded, covering whole shell surface including base; two prominent threads below sutures. Growth lines faint but gener¬ ally visible. Aperture quadrangular to circular. Outer lip angu¬ lar. Anomphalous and lacking funicle. Material Examined.— Eight specimens from the middle part of Guojiashan Formation of Guojiashan, Gansu Province, and two specimens from the lower part of Guojiashan Forma¬ tion of Saierlangshan, Sichuan Province: USNM 485510- 485513,485515. DISCUSSION. —Kittl (1894b) named Worthenia apunctata but did not give a useful description of the species and only figured a broken specimen. He distinguished the species from W. sub- punctata (Klipstein) and from W. marmolatae Kittl but not from Pleurotomaria joharmisaustriae Klipstein, although he noted the resemblance between them and suggested they might be united (Kittl, 1894b: 113). The present specimens coincide with both Klipstein’s and Kittl’s shells in the distinguishing characters of spiral ornament and lateral keels, which indicate the two species should be synonymized. Ananias guojiashanensis, new species Plate 1: figures 13-16 DIAGNOSIS. —Acutely pyramidal pleurotomarioids of six gradually enlarging whorls with pleural angle of 60° Whorl profile showing two prominent keels with lower keel acute and slightly stronger than upper one. Lateral face concave and ramp steep. DESCRIPTION. —Small- to medium-sized, acutely pyramidal shell with lateral face flattened. Sutural grooves shallow. Two prominent, acute keels on whorls; lower keel a little stronger and forming periphery. Selenizone concave and quite narrow, immediately below upper keel, bordered by peripheral keel and a lira. Lateral face concave; ornamented with faint, irregular spiral threads. Ramp slightly concave and steeply inclined, al¬ most equal in width to lateral face; one or two obvious spiral threads visible below sutures; occasionally also with very faint spiral threads. Left ramp projects at high angle from seleni¬ zone. Suture descends with age. Base nearly flat and smooth. Umbilicus narrow, without funicle. Material Examined. —Six well-preserved specimens plus several partial specimens from the middle part of Guojiashan Formation at Guojiashan. Type Specimens. — Holotype: USNM 485502; Paratypes: USNM 485500, 485503, 485509. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) Pleural angle (°) 485500 10.0 8.3 62 485502 10.5 8.8 55 485503 - 4.5 58 Discussion. —The typical characters of this species are the high-spired, turreted shell with strong keels, steep sutural ramp, and concave lateral face. In overall shape this species is similar to “Worthenia ' marmolatae Kittl (1894b: 112, pi. Lfigs. 6, 7) except for the obviously larger pleural angle. On the other hand, features of the selenizone are unclear for both Kittl’s spe¬ cies and Bohm’s (1895) later descriptions and figures of this and related species. The selenizone is not clearly exposed in several of the Chinese specimens, so combining all of these specimens into a single species is not justified with the current material. This species is more pyramidal and less trochiform than the preceding species. Etymology.— The species name is based on the locality from which the material was recovered. Family Lophospiridae Wenz, 1938 Genus Worthenia de Koninck, 1883 Discussion.— This large, well-known Late Paleozoic genus is marked by a convex selenizone at the upper peripheral keel. Although some workers did not believe the genus extended into the Triassic, (e.g., Knight, 1945; Haas, 1953), Yin and Yochelson (1983a, fig. 3) showed the genus persisted into the Middle and early Late Triassic, following a gap near the Permo-Triassic boundary. Triassic species are usually much smaller than Permian forms (Yin and Yochelson, 1983a). Al¬ though the selenizones in the specimens described herein lack the typical crenulated selenizones of many species of Worth¬ enia, they are very similar to those of Worthenia corrugata Chronic, 1952, as discussed by Batten (1989), and we follow Batten in assigning them to Worthenia. Worthenia extendia, new species Plate 1: figures 17-20 Diagnosis. —Small- to medium-sized, moderately spired, trochiform shell with 75° pleural angle and greatly enlarged fi¬ nal whorl. Selenizone convex and smooth at upper peripheral angulation. Ornament of closely spaced fine spiral threads and growth cords. Description.— Small- to medium-sized, medium-spired, trochiform pleurotomarioid. Pleural angle about 75° Sutural grooves shallow. Shell of five gradually increasing whorls and a rapidly expanding final whorl. Earlier whorls smoothly arched without distinct angulations. Two prominent keels on two final whorls, low and rounded. Selenizone apparently at upper keel, convex with faint crescent lines but not crenulated. 12 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Ramp nearly equal in width to lateral face in spire whorls, but wider than lateral face in final whorl (5:4), and both flat to slightly concave. Whorls embracing at about mid-whorl. One weak and blunt spiral ribbon under suture. Shell of fine, regu¬ lar, and closely spaced spiral threads and growth lines. Base convex with no spiral threads. Anomphalous. Material Examined. —Five specimens from the middle and upper parts of Guojiashan Formation at Guojiashan. TYPE Specimens. — Holotype: USNM 485505; Paratypes: USNM 485501, 485504. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) Pleural angle n Apical angle, spire (°) 485501 8.0 7.5 70 58 485504 22.0 22.2 80 70 485505 16.5 16.0 75 65 DISCUSSION.— This species is similar to Worthenia conica Assmann (1924:9, pi. 1: figs. 11, 12) in the development of the keels, but W. conica exhibits a larger pleural angle and a nar¬ rower ramp on the spire whorls, and it lacks subsutural nodes (Yin and Yochelson, 1983a: 171). As noted previously, this spe¬ cies differs from the typical Worthenia in the lack of a crenu- lated selenizone but is otherwise very similar to W. corrugata Chronic. The selenizone is very faint and is best seen after the specimen is coated with ammonium chloride. Etymology. —The species is named for the extended final whorl. Worthenia ? species indeterminate A Plate 1 : figures 21,22 Description. —Small, moderately spired, trochiform shells of five rapidly expanding whorls. Pleural angle 80°-90°. Su¬ tural grooves shallow. No marked spiral elements except for fine, nodose cord under suture. Two blunt keels on convex whorls. Ramp and lateral face each flat to slightly convex. Ramp of final whorl almost as wide as lateral face, but ramp of penultimate whorl wider than lateral face. Base roundly convex and anomphalous. Ornament of fine, closely and regularly spaced spiral threads, clearer on base. Material Examined. —Three specimens from the lower part of Guojiashan Formation: USNM 485506-485508. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) Pleural angle n 485506 4.95 5.00 90 485507 2.25 2.15 80 485508 4.75 5.15 87 Discussion. —This form is characterized by the ramps being wider than the lateral faces until the final whorl, in which the ramp width is equal to that of the lateral face. The shape is sim¬ ilar to some Permian species described by Batten (1989) from the southwestern United States, but the earlier whorls of Bat¬ ten’s specimens were smooth, and the final whorl in these Chi¬ nese specimens is greatly expanded, although not as broadly as in Worthenia extendia. These specimens are also similar to Worthenia pura (Assmann, 1924:10, pi. 1: fig. 14) from the Up¬ per Wellenkalk (Muschelkalk, Middle Triassic) of Upper Sile¬ sia; however, the shells have been recrystallized and the seleni- zones are unknown, making assignment to W. pura doubtful. Worthenia ? species indeterminate B Plate 1: figure 23 Description. —Medium-sized, low-spired shell. Pleural an¬ gle 75°. Sutural grooves shallow. Whorls very convex and en¬ larging quickly, with sutural ramp twice as wide as lateral face. Ramp divided into two concave bands by strong, sharp spiral ridge. Selenizone convex and smooth at upper peripheral angu¬ lation. Lateral face slightly concave; lower keel rounded. Very fine spiral cords visible on lateral face. Base low, convex, and anomphalous. Material Examined. —One partly broken specimen from the middle to upper part of the Guojiashan Formation at Guo¬ jiashan: USNM 485514. DISCUSSION. —This specimen has a low-spired shell and three almost equally spaced strong keels or ridges on the whorls, similar to Worthenia esinensis Kittl (Kittl, 1899:12, pi. 1: figs. 8-10) from the Esino Bed and the Marmolata Bed of the southern Alps. The European specimens, however, have one more keel under the lower keel, and their spiral elements are much more marked. Moreover, this specimen with a smooth, poorly defined, and convex selenizone differs from typical Worthenia species, which have the characteristic no¬ dose selenizone, and from typical Ananias species, which have a concave selenizone. Worthenia ? species indeterminate C Plate 1: figures 24, 25 Description. —Small, moderately spired wortheniid with obtuse apex. Pleural angle -55° Sutures depressed. Shell of four to five whorls enlarging evenly in width but more slowly in height. One prominent but blunt keel on lower to middle whorls. Selenizone probably situated on upper keel, convex, and recognized by opisthocyrt growth lines without lirae. Su¬ tural ramp broad, concave, and steeply inclined. Lateral face narrow and concave as a groove. Ramp almost twice as wide as lateral face. Subsutural row of tubercles found on some speci¬ mens. Ornament of very faint spiral threads. Aperture subqua- drangular. Base convex, anomphalous. Material Examined. —Three specimens from the middle part of Guojiashan Formation of Guojiashan. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) Pleural angle o 485516 ~8.0 5.3 57 485517 - ~5.0 52 485518 3.8 3.0 55 NUMBER 92 13 DISCUSSION. —The assignment of these specimens to Worth - enia is questionable; although they have a relatively narrow, convex selenizone, it is smooth, lacks crenulations, and is lo¬ cated low on the whorl. Family Gosseletinidae Wenz, 1938 Genus Gosseletina Bayle in Fischer, 1885 TYPE Species. — Pleurotomaria callosa de Koninck, 1843; by objective synonymy (Knight, 1841:138). DISCUSSION. —The type species from the Lower Carbonifer¬ ous of Belgium has a smooth surface, but the other species in this genus generally have spiral and collabral ornament. This genus is largely confined to the Carboniferous with a few spe¬ cies known from the Permian. Several Ladinian and Upper Tri- assic forms from the southern Alps have been referred to this genus (Kittl, 1891; Haberle, 1908; Bandel, 1991), although Koken (1897:30) questioned the assignment of these species to Gosseletina. The genus has also been reported from the Seven Devils material in Idaho, although these reports have not yet been published (Erwin, unpublished notes), and from south¬ western China (Pan, 1977). No Early Triassic or Anisian forms have been previously reported. Specimens are placed in this genus with considerable uncertainty. They have smooth shells similar to ? Gosseletina fasciolata (Munster, 1841), but the final whorls are not as well inflated and lack the subsutural nodose row generally present in Paleozoic Gosseletina. Gosseletina ? dangchangensis, new species Plate 1 : figures 26, 27 DIAGNOSIS. —Small, ovoid, turbiniform pleurotomarioid; pleural angle -60°. Spire small, final whorl remarkably high, and periphery at base of whorl. Selenizone flat to slightly con¬ vex in middle part of whorl. Shell surface smooth. DESCRIPTION.— Apex obtuse and rounded. Spire small, only one-fourth height of shell. Sutural grooves shallow; very nar¬ row and abaxial subsutural ramp under suture. Five whorls flat to slightly convex, gradually enlarging but increasing relatively rapidly in height. Selenizone narrow, nearly flat to slightly con¬ vex, and bordered by two fine lirae, with upper lira more prom¬ inent. Final whorl large, up to three-fourths height of entire shell. Periphery at base of final whorl, keeled. Shell surface smooth except for faint, strongly opisthocyrt growth lines. Base low, convex. Aperture circular with obvious labral slit. Thin inductura covering inner lip and umbilical area. Material Examined. —Four specimens from the middle to upper part of Guojiashan Formation of Guojiashan: USNM 485520,485521. Type SPECIMENS. — Holotype: USNM 485520; Paratype: USNM 485521. Measurements. —As follows: USNM Shell height Shell width Final-whorl Pleural angle catalog no. (mm) (mm) height (mm) (°) 485520 8.0 6.2 6.2 60 DISCUSSION. — Gosseletina fasciolata (Munster) from a St. Cassian Formation of the southern Alps (Kittl, 1891; Bandel, 1991) is the only similar species; the two share a conical shell, obtuse spire, and a narrow selenizone at the middle of the whorl. The new species, however, has a higher spire, a nearly flat lateral whorl face, less swollen final whorl, a periphery at the base of the final whorl, and a somewhat cyrtoconoid form. These characters even indicate that it may not belong to the genus Gosseletina. In overall shape, these shells are very sim¬ ilar to the type species of the trochid Cirsostylus Cossmann, Trochus glandulus Laube (1868:38, pi. 34: fig. 7), but are clearly distinguished from trochids by the presence of a sele¬ nizone. ETYMOLOGY. —The species is named for the local county, Dangchang, where the fossils were collected. Family Zygitidae Cox, 1960 Genus Zygites Kittl, 1891 TYPE Species. —Pleurotomaria delphinula Laube, 1868; by original designation. DISCUSSION. —Only the type species was assigned to this genus until Yin and Yochelson (1983a) reassigned two species to the genus and described a single new species, extending the range of Zygites from Anisian to Camian. The specimens de¬ scribed herein are similar to the type species of Zygites in hav¬ ing a dome-like apex, wide umbilicus, and comb-like umbili¬ cal angulation—all important characters that define this genus (Kittl, 1891:200). Batten (pers. comm., 1998) noted that Zyg¬ ites is remarkably similar to Eirylsia Batten, 1956, and likely to be synonymous. We agree with this assessment, but the cur¬ rent material seems insufficient to warrant synonymizing the two genera. Zygites laevigatus, new species Figure 4; Plate 1: figures 28-35 DIAGNOSIS. —Dome-like, low-spired shell. Slightly convex selenizone on middle to upper whorl face, visible on most whorls. Surface glossy; only ornament consisting of lower sub¬ sutural nodes. Umbilicus wide; smooth circular keel. DESCRIPTION. —Medium-sized, low-spired, nearly gradate pleurotomarid, slightly wider than high. Apex obtuse and rounded. Pleural angle ~90°. Sutures impressed but shallow. Shell of six whorls, evenly convex, gradually enlarging. Seleni¬ zone narrow and slightly convex, evenly curved with outer whorl surface, visible on earlier whorls. Two fine lirae bounding selenizone and a third within lower portion of selenizone. Orna¬ ment mostly of very fine growth lines extending prosoclinally, 14 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY FIGURE 4. —Selenizone of Zygites laevigatus, new spe¬ cies (not to scale). widely curving to selenizone and nearly straight close to sutures above selenizone; deep opisthocyrt on selenizone; growth lines forming several low, subsutural nodes. Sixteen subsutural nodes on final whorl. Periphery low on final whorl, narrowly rounded. Base low, convex. Umbilicus funnel-like, wide and deep, with an acute circumbilical keel. Aperture evidently subcircular to subquadrangular. Material Examined. —Four specimens from the middle to upper part of the Guojiashan Formation of Guojiashan. Type Specimens.— Holotype: USNM 485523; Paratypes: USNM 485522, 485524, 485525. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) Pleural angle (°) 485522 >14.0 >17.0 92 485523 10.0 12.2 89 485525 >11.0 12.2 91 DISCUSSION. —The gradually expanding whorls, wide umbi¬ licus, and marked subsutural nodes easily distinguish this spe¬ cies from forms assigned to Gosseletina and Codinella, many of which have a similar shape. This species lacks the cancellate characteristic of Zygites delphinula (Laube) (Laube, 1868:65, pi. 27: fig. 9; see also Kittl, 1891:200; Bandel 1991, pi. 1: figs. 7, 8), but the remaining characters support placement within the genus. Etymology.— The species name is derived from the poor ornamentation of the whorls. Family Phymatopleuridae Batten, 1956 Genus Euryalox Cossmann, 1896 Type Species. —Sagana juvavica Koken, 1894; by original designation. DISCUSSION.— This Triassic form is characterized by a wide peripheral selenizone that extends to the earlier whorls, an open umbilicus with an angular margin, and a reticulate ornament. Most of the species assigned to this genus have a swollen final whorl as occurs in the type species; however, Pleurotomaria subcance/lata (d’Orbigny), assigned to Euryalox by Yin and Yochelson (1983a), has a less extended final whorl. The speci¬ men from Qinling also lacks the swollen final whorl. FIGURE 5. —Ornament and selenizone of Eury¬ alox species indeterminate. S = sutural ramp; L = lateral face; B = base (not to scale). Euryalox species indeterminate Figure 5; Plate 2: figure 1 Description. —Moderately large, turbinate pleurotomarid. Spire obtusely conical. Sutures deeply impressed. Shell of more than four convex whorls, extending rapidly in width. Spire profile evenly curved. Final whorl with two prominent keels at middle of upper and lower whorl faces. Upper keel sharp, forming a shoulder, and lower keel narrowly rounded. Sutural ramp and lateral face join at 110° angle. Ramp slightly concave. Lateral face and base somewhat convex. Selenizone in middle of whorl face, ~1 mm wide, bounded by two promi¬ nent lirae. Shell entirely covered by fine, regular spiral threads. Growth lines faint and irregular, straight on ramp and base; opisthocyrt on lateral face, especially near selenizone, and within selenizone. Lunulae more widely spaced than growth lines, suggesting variable depth to slit. Umbilical opening deep, one-fourth diameter of shell. Material Examined. —A single well-preserved specimen from the middle to upper part of the Guojiashan Formation of Guojiashan: USNM 485526. Discussion. —The moderately high-spired shell, relatively unexpanded final whorl, and delicate ornament differ from most species of Euryalox other than E. subcancellata (d’Or¬ bigny) (Laube, 1869:80, pi. 27: fig. 1); however, the rela¬ tively narrow selenizone of E. subcancellata does not lie ex¬ actly at the periphery of the whorl, and as figured by Laube it has no ramp. Genus Codinella Kittl, 1899 Type Species. — Trochus generelli Stoppani, 1858; by origi¬ nal designation. DISCUSSION. —This genus is characterized by a high spire with numerous whorls, which is unusual for Triassic gastropods with a selenizone. The type species is anomphalous and has smaller, wider whorls and a small laterally elongated aperture. Some species referred to this genus by Kittl (1894b) have taller whorls and a wider aperture (e.g., Codinella mammiformis NUMBER 92 15 (Kittl) (Kittl, 1894b: 115, pi. 1: fig. 24)) or an umbilicus (e.g., C. leda (Kittl) (Kittl, 1894b: 115, pi. 1: fig. 13)). Codinella 1 ! species indeterminate Plate 2: figures 2^1 DESCRIPTION. —High-spired shell with bluntly rounded apex. Sutural grooves deep. Shell of six whorls, with earliest three increasing rapidly in width followed by transition to more rapid growth in whorl height. Earlier whorls evenly arched. Fi¬ nal whorl with two blunt keels; whorl profile generally convex but with concave lateral face between keels. Moderately wide selenizone at upper keel. Growth lines fine and closely spaced, prosocyrt on concave lateral face, and opisthocline upward and downward, and then orthocline. Base convex. Umbilicus small but evident. Material Examined. —Two specimens from the middle to upper part of the Guojiashan Formation of Guojiashan: USNM 485527,485528. DISCUSSION. —The final whorls of these shells are similar to Codinella leda (Kittl) from the Alpine Marmolata bed, but that specimen lacks a spire and its upper keel is more sharply de¬ fined. The generic description of Codinella (Kittl, 1899:15) mentions an anomphalous umbilicus, although Kittl’s descrip¬ tion and figures of C. leda (Kittl, 1894b: 115, pi. 1: fig. 13) in¬ dicate a wide umbilicus and serve as a key character to distin¬ guish it from C. mammiformis (Kittl) (Kittl, 1899:17). These specimens have taller whorls, an aperture similar to C. mam¬ miformis, but a small umbilicus like C. leda. Because these species differ markedly from the type species, they may repre¬ sent a different clade, or the definition of the genus should be revised. Family Trochotomidae Cox, 1960 Genus Trochotoma Eudes-Deslongchamps, 1843 Subgenus Discotoma Haber, 1934 TYPE Species. — Ditremaria amata d’Orbigny, 1850; by original designation. DISCUSSION. —The low-spired turbiniform shells have trans¬ verse folds on the upper face. Discotoma was first reported from the Jurassic; the Chinese species Trochotoma ( Disco¬ toma) I gansuensis, new species (described below), extends the range of this subgenus downward into the Middle Triassic. Trochotoma (. Discotoma ) gansuensis, new species Plate 2: figures 5-10 Diagnosis. —Low-spired shell with small spire and acute apex. Row of low and slightly opisthoclinally elongated nodes on upper whorl face. Cancellate ornament well developed. Widely phaneromphalous. Description. —Medium-sized to large, low-spired form with acute apex. Sutural grooves deep. Shell of five highly con¬ vex whorls with slightly angular upper whorl face, enlarging and rapidly expanding. Cancellate ornament of fine and regu¬ lar, closely spaced spiral threads and nearly straight collabral lines. A row of low, rough, and slightly opisthoclinally elon¬ gated nodes on upper face. Spiral threads passing through no¬ dose surfaces. Base convex. Umbilicus open and wide, about one-half diameter of shell. Material Examined. —Four specimens from the middle to upper part of the Guojiashan Formation of Guojiashan: USNM 485529-485531. Type Specimens.— Holotype: USNM 485530; Paratypes: USNM 485529, 485531. DISCUSSION. —This new species can only be confused with the Middle Triassic Discotoma planoconvexa Yu, Pan, and Wang (Yu et al., 1974:322, pi. 171: figs. 1-3) from Qingyan, Guizhou Province, southwestern China. The Guizhou species has a much lower spire, blunt apex, and less well-defined spiral ornament. Etymology. —The species name is derived from Gansu Province, where the specimens were collected. Superfamily TROCHOIDEA Rafinesque, 1815 Family Trochidae Rafinesque, 1815 The relationship between Paleozoic and early Mesozoic “tro- chids” and the modem Trochoidea remains disputed. Genus Tylotrochus Koken, 1896 Type Species.— Trochus konincki Homes, 1856; by original designation. Discussion. —The collection from Qinling includes a single small specimen allied to this genus. Tylotrochus elongatus Bandel, 1993 Figure 6; Plate 2: figure 11 Ziziphinus semipunctatus Zardini, 1978, pi. 14: fig. 13 [nomen nudum].— Bandel, 1993:929. Tylotrochus elongatus Bandel, 1993, pi. 7: figs. 3, 5. DIAGNOSIS. —Very small conical shell with acute apex and flat sides. Six low, wide whorls, with well-developed spiral threads on earlier whorls but only on lower part of last two whorls. Description. —Pleural angle 58°. Sutures impressed but grooves shallow. Shell of six low and wide whorls, increasing rapidly in width and slowly in height. All whorls flat with fine and closely spaced spiral threads; lowest one or two spiral threads more prominent and acute than upper ones. On early whorls, all spiral threads clear and regular, but on last two whorls only lowest three to four spiral threads prominent; 16 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY FIGURE 6.— Tylotrochus elongatus (not to scale). upper spiral threads on last whorls faint or absent. Peripheral angulation at base of final whorl. Base low and evenly convex. Material Examined. —A single specimen from the middle part of the Guojiashan Formation of Saierlangshan. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) 485532 2.45 2.00 Material Examined. —Two specimens from the Mare- songduo Formation at Saierlangshan: USNM 485538. Discussion. —These two specimens have some small pieces of very thin shell wall, which, associated with the rela¬ tively thin inductura on the inner lip, suggest that they are not neritoids despite their more embraced whorls and naticiform shape. The shell wall and the ornament are similar to those of Natiria costata (Munster) (Freeh, 1912:43, pi. 7: fig. 3). In the type species of Natiria the whorls are barely in contact and the ornament is composed of sparsely spaced laminar collabral flanges; these may have had a very different ecological func¬ tion from ordinary ribs. We do not know whether the faint rib- lets on the steinkerns reflect the presence of flanges on the shells. Superfamily Amberleyoidea Wenz, 1938 Family Amberleyidae Wenz, 1938 Discussion. —This conical shell with very low and wide whorls and prominent spiral threads is similar to the many “Tectus ” species of the northern Alps (a group in need of rede¬ scription), most of which are currently placed in Dimorpho- tectus. The Chinese species, however, has a lower spire, fewer whorls, less-distinguished spiral ornament on the final whorls, and a less-developed keel above the suture. The specimen is re¬ markably similar to Bandel’s Tylotrochus elongatus, so we have assigned this small specimen to that species. Family TURBINIDAE Rafinesque, 1815 Genus Natiria de Koninck, 1881 Type Species. —Natica lirata (Phillips, 1836); by monotypy. DISCUSSION.— The Early Carboniferous type species of Natiria is characterized by whorls only barely in contact and by widely spaced laminar collabral or transverse flanges. Yin and Yochelson (1983b) transferred it to the Family Turbinidae from the Family Craspedostomatidae (Knight et al., 1960), compar¬ ing it with Eucycloscala and Liontina. Batten and Stokes (1986) followed Yin and Yochelson’s family assignment but compared Natiria with Col Ionia and placed the genus in a dif¬ ferent subfamily. Natirial species indeterminate Plate 2: figures 12-14 Description. —Medium-sized, globular, naticiform shell. Spire protruding but obtuse. Sutures impressed. Four strongly convex whorls extending obliquely. Final whorl inflating abax- ially, width greater than its height. Pronounced growth lines and faint, widely spaced transverse riblets visible on preserved steinkerns. Aperture large and subcircular. Central chink on base possibly an umbilicus. Inner lip not obviously thickened. Genus Amberleya Morris and Lycett, 1851 Type Species. — Amberleya bathonica Cox and Arkell, 1950; by original designation. Discussion. —This genus is distinguished from Eunemopsis by the columellar lip and umbilicus. Amberleya has a smooth concave columellar lip and no umbilicus whereas Eunemopsis has a denticle on the upper part of the columellar lip and a nar¬ row umbilicus. In addition, Eunemopsis generally has two to three rows of laterally extended nodes with a more complicated ornament than Amberleya. Amberleya ? species indeterminate Figure 7; Plate 2: figures 15, 16 Description. —Moderately pyramidal shell with acute apex. Sutures indistinct. Whorls convex, with two rows of strongly protruded nodes. Upper row of nodes very rough and rounded; lower row weaker and spirally elongated; both rows almost combined into one row on earlier whorls. Growth lines faint and straight. Base convex. Umbilical area shallowly depressed. Very thick shell. Material Examined.—A single partial specimen with a broken aperture and four whorls, from the lower part of the Zalishan Formation at Saierlangshan: USNM 485537. Discussion. —The Qinling collection includes a single spec¬ imen with two rows of loose nodes that is referred to Amber- Figure 7.— Amberleya ? species indeterminate (not to scale). NUMBER 92 17 leya. Although the aperture is broken and the columellar lip is not preserved on this specimen, the relatively simple ornament suggests assignment to Amberleya. Most species of Amberleya, however, have more ornamentation than this specimen al¬ though they are usually not so elaborate as Eunemopsis. DISCUSSION. —This Triassic genus, which probably arose from Paleozoic murchisoniids, is characterized by a peripheral keel in the middle of the whorl that forms the lower border of the selenizone. These easily identified specimens display exten¬ sive morphological variation in pleural angle at a single locality. Genus Eunemopsis Kittl, 1891 Type Species. — Turbo epaphus Laube, 1869; by subsequent designation (Cossmann, 1916). Discussion. —These small shells have a delicate ornament. They became common after the Middle Triassic but were rare in the Paleozoic. Glyptospira from the Permian is quite similar, and the single specimen of Eunemopsis from this collection may represent a member of that clade. ?Eunemopsis dolomitica Kittl, 1891 Figure 8; Plate 2: figure 17 Eunemopsis dolomitica Kittl, 1891:257, pi. 7: fig. 30. —Zardini, 1978:31, pi. 16: figs. 6-8.—Bandel, 1993:45, pi. 13: figs. 1, 6, 8, 9. Description.— Small, medium-spired, conical trochid. Su¬ ture deeply impressed. Transverse ribs prosoclinal, weakly ex¬ tending on concave lateral face and ending in nodules near each suture. Base convex with marked spiral ribbons. Narrowly pseudomphalous. Aperture subcircular. Material Examined. —One partial specimen with the final two of six original whorls; other whorls broken during prepara¬ tion. From the middle part of the Guojiashan Formation of Guojiashan: USNM 485620. DISCUSSION. —The reconstruction of the shell is shown in Figure 8. The relatively large pleural angle and stronger upper row of nodes differentiate this shell from the other species of this genus (e.g., Eunemopsis epaphus (Laube) and E. praecur- rens Kittl). Cheilotomona acutocarinata, new species Plate 2: figures 18-23 Diagnosis.— Acutely conical shell with pleural angle of 45°-65° and with four to six strongly convex whorls divided by deep sutural grooves. Three prominent keels with middle keel forming whorl periphery. Spiral threads very fine and regular. Description. —Small- to medium-sized, high-spired, acutely conical shells. Sutures deeply impressed. Keel at mid-whorl very prominent and acute, forming periphery; two weaker keels above and below this keel; faces between three keels slightly concave. Obscure selenizone between upper and middle keels. Subsutural face sloped, narrow, and feebly convex between up¬ per keel and suture. Other ornament of very fine, regular, and closely spaced spiral threads; growth lines faint. Base low, con¬ vex, anomphalous. Aperture unknown. Material Examined. —Fourteen specimens from the lower part of the Guojiashan Formation of Saierlangshan. Type Specimens. — Holotype: USNM 485626; Paratypes: USNM 485621-485625, 485627. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) Pleural angle (°) 485621 >4.7 4.3 55 485622 6.5 5.5 65 485623 6.2 5.1 55 485624 >9.2 7.2 40 485626 7.4 5.2 45 485627 10.5 7.8 45 FIGURE 8. —?Eunemopsis dolomitica, with outline of portions (in dotted lines) broken during preparation of specimen (not to scale). Suborder Uncertain Discussion. —Cheilotomona avisii Bohm (1895:227, pi. 15: fig. 21) from the Marmolata bed and C. blumii (Wissmann) (Laube, 1868:89, pi. 28: fig. 7) from the St. Cassian Formation of the Alps share the acute and conical shell and mid-whorl keel with this Chinese species. The Chinese species has a larger pleural angle, deeper sutural grooves, and stranger and more acute keels than C. avisii, whereas C. blumii has a much more prominent ornament but only one extra middle keel and no dis¬ tinct upper or lower keels. Etymology.—T he species name is based on the acute and strong keel at mid-whorl, which differentiates it from most other species of the genus. Superfamily Murchisonioidea Koken, 1896 Family Murchisoniidae Koken, 1896 Genus Cheilotomona Koken, 1889 TYPE Species. — Pleurotomaria blumi Munster, 1841; by subsequent designation (Diener, 1926). Unnamed Clade (Neritopsina + Cocculinoidea) Ponder and Lindberg, 1997 Superfamily Neritoidea Rafinesque, 1815 DISCUSSION. —More than one-half of the gastropods in the West Qinling collection are neritoids, which likewise comprise 18 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY a very important part of Early Triassic assemblages worldwide and of Middle and Late Triassic gastropods assemblages in Europe. Distinguishing the many described genera and species in this group has been a difficult and confusing problem for more than 100 years. Despite much discussion (Koken, 1892b, 1897, 1898; Kittl, 1894b, 1899; Bohm, 1895; Cossmann, 1925; Wenz, 1938; Haas, 1953; and Yin and Yochelson, 1983b) this taxonomic morass persists. The characters initially chosen to discriminate taxa in this clade were difficult to apply in practice, and their claimed phy¬ logenetic significance was seldom demonstrated. The inner re¬ sorption of the early whorls was considered a key character dis¬ tinguishing the Family Neritopsidae from the Family Neritidae. The teeth or protuberances on the inductura of the inner lip along with resorption of the inner whorl were used as the most important markers dividing genera. Yet observation of inner- whorl resorption on internal casts is not reliable, and sufficient numbers of well-preserved specimens have rarely been avail¬ able to allow serial sectioning. Moreover, the teeth or protuber¬ ances on the inner lip lie immediately inside the aperture and are not continuous spiral ridges; thus observing this feature re¬ quires preservation of undamaged apertures. Because the char¬ acters that serve to define many genera or higher taxa can rarely be observed, it is hardly surprising that the taxonomy of this group has a troubled history. Even Kittl, who continuously emphasized the importance of these characters, actually de¬ scribed and figured these characters only in few species, and he surely did not see them in many of his type specimens. Further¬ more, Kittl (1894b: 138-139) suggested that some species of Naticopsis and Hologyra exhibited partial to complete inner re¬ sorption of the early whorls. At present the phylogenetic signif¬ icance of these characters is unknown; detailed phylogenetic analysis of the group, beyond the scope of this study, will be re¬ quired to fully resolve these problems. In living neritoids, folds on the inductura of the inner lip en¬ hance the positioning of the operculum within the aperture and are related to the ecology of the animal. These folds, however, differ from the inductural teeth or protuberances on the Triassic forms in shape and growth; the latter appear to be too small and isolated to strengthen the articulation. Kittl (1899:27) noted that his subgenus Marmolatella has two teeth or tubercles as well as the abaxially extended final whorl and long, straight columellar lip. No teeth or tubercles have been noted on speci¬ mens of apparent Marmolatella from the well-silicified speci¬ mens from the Permian of West Texas or from the Triassic Chi¬ nese collections. In the well-silicified Permian specimens of Naticopsis from West Texas, one clear tooth is seen inside the aperture in some specimens although many other specimens have only a smooth inductura. The evident variability in the presence or absence of teeth or tubercles on the inductura sug¬ gests this character may not be useful in distinguishing genera. Finally, Haas (1953:159) wrote that “the shell substance re¬ gained goes into the callosity of the inner lip,” suggesting a re¬ lationship between inner-whorl resorption and the inductura; yet, inductura formation also occurs in naticopsids in which no resorption of inner wall is known. The remarkable abundance of neritomorphs in this collection is significant. A. Niitzel (pers. comm, to Erwin, 1999) sug¬ gested the calcitic outer shell layer may have enhanced the preservation potential of this group relative to other groups. Family Neritopsidae Gray, 1847 DISCUSSION. —The Neritopsidae are distinguished from the Neritidae by the neritopsids’ resorption of the inner wall during ontogeny. Nonetheless, recognition of many genera in this fam¬ ily is difficult. Forms such as Neritopsis and Trachyspira are recognizable from their peculiar ornament, whereas Fromba- chia and Pachyomphalus are distinguished by their unique shape. The classification of the Naticopsis-like group without distinctive ornament remains unresolved. The other naticopsid genera are characterized by seemingly more reliable characters and have received less attention. We cannot resolve this prob¬ lem, but we do suggest a practical way to distinguish these gen¬ era and subgenera. The more difficult Triassic naticopsid genera (and their type species) include Naticopsis M’Coy, 1844 (type species Nati¬ copsis phillipsii M’Coy), Dicosmos Canavari, 1890 ( Dicosmos pulcher Canavari), Hologyra Koken, 1892b (Hologyra alpina Koken), Marmolatella Kittl, 1894b ( Naticopsis (Marmolatella ) applanata Kittl), Fedaiella Kittl, 1894b ( Natica cuccensis Mojsisovics), Vernelia Bohm, 1895 ( Natica fastigata Stoppani = Natica excelsa Hauer), Planospirina Kittl, 1899 ( Nerita esin- ensis Stoppani), and Auricularia Tichy, 1979 ( Marmolatella auriculata Koken). These genera were based on variable characters including the umbilicus, pseudoumbilicus, funicle (which varies during on¬ togeny), callosity of the inner lip, and teeth or tubercles on the inner lip, which may be difficult to observe. By the 1890s Ko¬ ken (1892b, 1897), Kittl (1894b, 1899), and Bohm (1895) had recognized that inadequate description had caused problems in identifying the genera or subgenera they had each described. It is not clear that these workers actually understood the differ¬ ences between these taxa themselves. For example, Bohm (1895:250) distinguished his Vernelia from Hologyra by the absence of the umbilical funicle because Koken (1892b: 193-194) only emphasized the existence of the juvenile umbi¬ licus; but Kittl (1899:49) noted that the umbilicus of Hologyra was closed in the adult shell, so he did not admit Bohm’s Ver¬ nelia. Koken (1892b: 193-194) did not discuss the relationship of his Hologyra to Canavari’s Dicosmos when he established the former. After Bohm (1895:257) reclarified the characters of Dicosmos, Koken (1897:69) realized that his Hologyra had the same umbilical characters as Dicosmos, and he rejected Cana¬ vari’s Dicosmos. Yin and Yochelson (1983b:517, table 1) dis¬ tinguished the four most troublesome taxa, but the characters used sometimes varied from the initial diagnoses of the genera. For instance, Hologyra was listed as having tubercles or teeth NUMBER 92 19 on the inner lip, yet Koken (1892b: 193) clearly wrote “ohne Zahne und Kerben” (no teeth and troughs), and many later au¬ thors (e.g., Kittl, 1899:49; Schmidt, 1928:226) also noted “no teeth.” Although this group clearly needs a thorough phylogenetic analysis, as a step in that direction we provide herein a compre¬ hensive discussion of the characters. Among the other, less dif¬ ficult neritopsid genera, basic shell form and whorl geometry appear to be useful. For example, Planospirina typically has a flat apex, Pachyomphalus has a medium-sized spire, and Mar- molatella (and Auricularia ) possesses a unique ear-like shell. Table 5 compares characters of the type species of nine taxa in¬ cluding Dicosmos, Hologyra, Vernelia, and Fedaiella as well as Naticopsis sensu stricto; the indices used are defined and il¬ lustrated in Figure 9. Although Kittl (1899:27) compared these taxa by integrating characters including shell form, apex, and upper whorl face, the characters played a minor role in his tax¬ onomic decisions. Pachyomphalus is distinguished by its high spire (large ratio of spire height to total height and relatively low ratio of aper- tural height to total height). The eight remaining forms fall into two groups based on shell shape: Marmolatella, Auricularia, and Planospirina all have a small ratio of spire height: total height (flattened or depressed spire) and a large ratio of aper- tural height:total height (high aperture); the second group in¬ cludes the naticiform or globular Naticopsis, Fedaiella, Holo¬ gyra, Dicosmos, and Vernelia. Because of the intergradations of form within these groups, we accord each group generic rank ( Marmolatella and Naticopsis, respectively) and accord subgeneric rank within the groups. Hologyra and Dicosmos, however, have few differences and are considered synonyms, with Dicosmos being the senior synonym. Similarly, Naticopsis and Fedaiella are very similar and can be distinguished only in features of the columella and umbilicus. This suggests that the Paleozoic Naticopsis sensu stricto may extend into the Triassic, with Fedaiella being the postextinction part of the lineage. Table 5. —Comparison of characters among type species of selected genera and subgenera in Neritopsidae (s, h, a, b, w, e, and r are defined in Figure 9 legend; * = specimen could not be measured). Descriptive characters Measured indices Genus or subgenus Type species Apex shape Suture Umbilicus Columellar lip s/h a/h b/w e/w r, shape Marmolatella Naticopsis ( Marmolatella) applanata Flat Deep None Nearly straight 0 0.97 0.13 0.25 >90°, round Auricularia Marmolatella auriculata Sunken Deep None Curved, long -0.13 1.15 0.16 0.24 >90°, round Planospirina Nerita esinensis Flat Deep None Curved, short 0.08 0.93 0.21 0.27 >90°, angular Naticopsis N. phillipsii Acute Shallow None Curved, short 0.07 0.81 * 0.37 90°, angular Fedaiella Natica cuccensis Mojsis- ovics Acute Deep Open Straight, long <0.10 >0.86 0.25 0.37 90°, angular Hologyra H. alpina Obtuse Shallow Closed Curved, short 0 0.89 0.19 0.24 <90°, round Dicosmos D. declivis 1 Obtuse Shallow Closed Curved, short 0.07 0.86 0.21 0.32 <90°, angular Vernelia Natica fastigata = N. excelsa Acute Deep None Curved, short 0.18 0.63 0.38 0.31 <90°, acute Pachyomphalus P. concinnus Bohm Acute Deep Unknown Curved, short 0.27 0.50 0.48 0.33 <90°, acute *Not the type species; used in place of type species because it shows all characters. FIGURE 9. —Character measurements used in Table 5. Abbreviations: a = apertural height, b = spire width, e = spire radius, h = total height, r = pleural angle, s = spire height, and w = total width. k-w-* 20 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Both lineages are represented from the Permian into the Tri- assic. The Marmolatella- group seemingly developed from the earlier Naticopsis in the Late Paleozoic via Planospira, ex¬ panded in the Triassic, and produced Auricularia in the Middle Triassic. The Naticopsis-gxoup generated a high-spired sub¬ group in the Late Paleozoic, including Jedria, Vernelia, and the Triassic Pachy omphalus, but its major expansion was in the Middle Triassic with a flattening of the spire and development of a globular and oblique shell, producing huge Fedaiella and Dicosmos. Genus Marmolatella KittI, 1894 Subgenus Marmolatella KittI, 1894 Marmolatella ( Marmolatella ) complanata (Stoppani, 1857) Plate 2: figures 24-31 Marmolatella complanata Stoppani, 1857 [In Stoppani, 1858-1860].—KittI, 1899:46, pi. 8: figs. 7, 8; pi. 9: figs. 7-10. Naticopsis (Marmolatella) planoconvexa KittI, 1894b: 144, pi. 4: figs. 1-3.— KittI, 1899:46 [placed in synonymy]. Marmolatella planoconvexa (KittI).—Bohm, 1895:255, pi. 10: figs. 15, 16b—f. Description.— Medium-sized auricular naticopsid. Small spire, only slightly protruding from final whorl. Sutures deep and distinct. Whorls expanding rapidly, particularly abaxially and abapically. Final whorl expanding more rapidly than pre¬ ceding whorls, with smoothly arched side surface. Shell wall composed of very thin outer layer (probably calcitic) and much thicker inner layer, with fine collabral ornament clearly ob¬ served on both; ornament seemingly slightly stronger on the outer layer. Collabral ornament irregular but tending to gather into bands. A few dark bands usually visible. Aperture large and oviform, narrowing at base but slightly produced anteri¬ orly. Columellar lip straight and long, inner lip reflexed and markedly thickened by inductura, covering umbilical area; no teeth observed. Outer lip thin and circularly curved. Material Examined. —Six specimens, most complete, from the middle to upper part of the Guojiashan Formation of Guojiashan. A seventh specimen from the same locality (USNM 485543) is assigned to the species with less certainty. Measurements. —As follows (in mm): USNM catalog no. Shell height Shell width Final- whorl height Spiral- base width Aperture height Aperture width 485539 21.3 29.8 21.0 10.7 19.8 17.2 485540 24.0 31.0 22.0 11.4 20.0 16.5 485541 22.3 24.9 21.9 7.8 20.1 13.5 485542 32.0 36.0 29.0 10.5 27.0 25.0 Discussion. —These specimens coincide with the southern Alpine specimens in all features except for the slightly higher spire of these, which is insufficient to separate the Chinese forms from the Alpine. Naticopsis ( M .) planoconvexa was es¬ tablished by KittI (1894b) who later (1899:46) recognized that it has the same deep sutures and dark bands as M. (M.) compla¬ nata and synonymized the two species. Marmolatella ( Marmolatella ) obtusangula (Koken, 1897), new combination Plate 2: figure 32 Hologyra obtusangula Koken, 1897:72, pi. 13: fig. 10. Description. —Medium-sized auricular naticopsid. Spire obtuse and nearly flat. Width of shell close to height. Sutures canaliculate but very shallow and narrow, sinking close to ap¬ erture. Three and one-half rapidly expanding whorls largely embracing earlier whorls. Final whorl expanding abaxially and extending abapically. Growth lines faint, straight, and slightly prosoclinal. Aperture highly hemicircular, narrowed abapi¬ cally. Inner lip long and almost straight, extending to the abap- ical terminal of shell. Inductura long and narrow, spreading in¬ side aperture; flat but with a fold under umbilical area. Anomphalous. Material Examined. —Five specimens from the middle to upper part of the Guojiashan Formation. Measurements.— As follows (in mm): Final- Spiral- USNM Shell Shell whorl base Aperture Aperture catalog no. height width height width height width 485551 12.2 11.2 10.6 3.4 - - 485552 5.2 5.7 4.9 1.9 4.4 2.5 Discussion. —These specimens have a nearly flat upper sur¬ face but an obtuse and slowly elevating spire, coinciding with Koken’s species. Genus Naticopsis M’Coy, 1844 Subgenus Dicosmos Canavari, 1890 Naticopsis ( Dicosmos ) applanatus Kutassy, 1937, new combination Plate 2: figures 33-36 Dicosmos applanatus Kutassy, 1937a:47, pi. 1: figs. 84-86. Description. —Medium-sized, globular, naticiform shell. Apex obtuse; spire small but markedly protruding. Sutures im¬ pressed with narrow grooves. Shell of four rounded whorls. Fi¬ nal whorl expanding and evenly arched. Growth lines closely spaced, straight, and prosoclinal, but curved forward close to sutures. Aperture nearly hemicircular. Outer lip thin and sharp. Inductura mainly covering parietal lip, flat, and slightly con¬ cave in lower part. Umbilical chink visible. Material Examined. —Six specimens from the middle to upper part of the Guojiashan Formation: USNM 485544- 485546. Discussion.— These specimens coincide with Kutassy’s species and are distinguished from N. (D .) impressa (Munster) NUMBER 92 21 by their elevated and pointed spire, evenly arched whorl pro¬ file, and prominent growth lines. Naticopsis ( Dicosmos ) compressus, new species Plate 2: figures 37-43; Plate 3: figures 1-6 DIAGNOSIS. —Spire very depressed, producing a wide, con¬ tinuously curved upper whorl surface. Final whorl strongly arched. Columellar lip long and nearly straight. Inductura thin and wide. DESCRIPTION. —Small- to medium-sized, subglobular nati- copsid. Upper surface a continuous curve formed by small, low, obtuse spire and shallow, flat sutural grooves. Three to four whorls rapidly expanding laterally and markedly embrac¬ ing preceding whorls. Final whorl expanding both abaxially and abapically; outer whorl strongly bowed. Growth lines fine, closely spaced, and straight, tending to gather close to upper edge of aperture. Aperture oviform, pointed adapically. Outer lip thin and sharp. Inductura on inner lip, mainly on parietal lip, thin and wide, smoothly convex, with no teeth. Umbilical area entirely covered. Material Examined. —Ten specimens from the middle to upper part of the Guojiashan Formation: USNM 485573- 485581. Type Specimen. — Holotype: USNM 485581. Measurements. —As follows (in mm): USNM catalog no. Shell height Shell width Final- whorl height Spiral- base width Aperture height Aperture width 485573 11.4 12.7 10.9 3.9 10.0 7.4 485574 14.6 14.5 13.9 4.7 11.7 8.6 485575 9.3 10.7 9.2 3.9 7.8 5.8 485577 14.1 15.6 14.0 4.6 11.4 10.0 485578 10.0 11.1 9.8 3.8 8.2 6.2 485579 12.0 13.8 11.8 4.1 10.7 8.2 DISCUSSION.— Naticopsis ( Dicosmos) declivis Kittl (1894b: 140, pi. 4: figs. 10-14) is the most similar species to this form in overall shell shape, but the Chinese species has a more de¬ pressed spire, a more curved final whorl, and a longer and straight columellar lip. ETYMOLOGY. —The species name is derived from the short spire, which produces a compressed shape. Naticopsis ( Dicosmos ) declivis (Kittl, 1894), new combination Plate 3: figures 7-11 Hologyra declivis Kittl, 1894b: 140, pi. 4: figs. 10-14. Dicosmos declivis (Kittl).—Tommasi, 1913:40, pi. 3: fig. 17. Description. —Large, oval but compressed naticopsid. Out¬ line of upper surface of whole shell a smooth curve formed by low, obtuse apex and spire and by flush suture. Four adpressed whorls enlarging obliquely and extending adapically to em¬ brace most part of preceding whorl. Final whorl inflating with slightly concave upper outer surface. Base convex. Surface or¬ namented with crowded growth lines and dark bands. Growth lines slightly curved and prosoclinal. Aperture large and ovoid, pointed adapically at suture. Inner lip sigmoid. Inductura very thick and wide, mostly thickened at meeting of parietal and columellar lips so that inductural surface almost flat; teeth ab¬ sent. Umbilical area entirely covered. Material Examined. —Five mostly well-preserved speci¬ mens from the middle to upper part of the Guojiashan Forma¬ tion. Measurements. —As follows (in mm; pleural angle in de- grees): USNM catalog no. Shell height Shell width Final- whorl height Spiral- base width Aperture height Aperture width Pleural angle 485547 >24.0 >30.0 >22.0 9.5 24.0 >22.0 126 485548 >25.0 33.0 >25.0 10.0 22.0 24.0 125 485549 25.0 -28.0 24.0 8.5 19.0 -19.0 130 485550 21.0 20.0 19.5 7.2 - - 124 Discussion. —This species is characterized by a compressed globular shell, flat sutures, low and very blunt spire, and a short but broadened final whorl with a flat to slightly concave sutural face. Naticopsis ( Dicosmos ) eyerichi (Noetling, 1880), new combination Plate 3: figures 12-16 Natica eyerichi Noetling, 1880:330, pi. 16: fig. 9. Hologyra eyerichi (Noetling).—Picard, 1903:485, pi. 11: fig. 3. Description. —Small to very small, globular, naticiform shell. Spire small but protruding slightly. Sutures impressed and grooves shallow, but suture on final whorl obviously en¬ larged. Three to four whorls evenly arched and extending ob¬ liquely, partly embracing preceding whorl. Final whorl inflated with height nearly equal to width. Growth lines closely spaced, regular, straight, and nearly orthoclinal. Aperture large, subcir¬ cular. Outer lip thin and sharp. Inner lip curved and thickened by an inductura. Umbilicus covered. Material Examined. —Many specimens in the limestone of the lower part of the Guojiashan Formation: USNM 485557-485561. Measurements. —As follows (in mm): Final- Spiral- USNM catalog no. Shell height Shell width whorl height base width Aperture height Aperture width 485557 4.0 4.2 3.8 1.7 3.2 2.4 485560 6.0 6.0 5.7 3.0 4.6 3.9 485561 4.2 4.5 3.9 2.0 3.2 2.6 DlSCUSSlON. —The oviform shape, small but conically rais¬ ing spire, markedly impressed final whorl suture, and the thick inductura coincide with Picard’s (1903) specimens from the Lower Muschelkalk. 22 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Naticopsis (Dicosmos ) impressa (Munster, 1841) Plate 3: figures 17-22 Natica impressa Munster, 1841:99, pi. 10: fig. 9—Laube, 1868:37, pi. 21:fig. 13. Naticopsis impressa (Munster).—Kittl, 1892:81, pi. 7: figs. 13, 15-17. Hologyra impressa (Munster).—Kittl, 1899:49 [no figures]. Description. —Medium-sized to large, hemispherical to subspherical, naticiform gastropod. Spire obtusely protruding and low. Shell of more than three abutted convex whorls. Body whorl extending upward and covering about two-thirds of ear¬ lier whorl, forming a flattened to slightly concave upper sur¬ face below suture. Final whorl expanding obliquely. Base con¬ vex. Growth lines irregular although almost straight and prosoclinal. Aperture large, subcircular to ovoid. Outer lip thin and sharp, with upper margin inclined to axis. Inner lip re¬ flexed, covered by a low and narrow inductura. Material Examined. —Five specimens, three of which are well preserved, from the lower part of the Guojiashan Forma¬ tion of Saierlangshan: USNM 485553^185556. Measurements. —As follows (in mm): Final- Spiral- USNM Shell Shell whorl base Aperture Aperture catalog no. height width height width height width 485553 15.0 6.5 14.0 6.1 10.0 10.0 485554 13.5 13.3 13.0 5.5 11.2 8.6 DiSCUSSlON. —These specimens have a whorl shape similar to Naticopsis ( Dicosmos ) sichuanensis, new species, from the same locality. The major differences distinguishing the two species are the oblique upper margin of the aperture in N. ( D .) impressa versus the abaxial (horizontal) upper margin in and the less stair-like upper surface of the shell in N. ( D .) sichuan¬ ensis, new species. Additionally, these specimens of N. (D .) im¬ pressa display a flattening or depression below the suture on the final whorl. Naticopsis ( Dicosmos ) sichuanensis , new species Plate 3: figures 23-34 DIAGNOSIS. —Spire low but clearly protruding on upper sur¬ face of shell. Apex obtuse. Upper side of shell stair-like. Upper margin of aperture extending abaxially. Inductura narrow and rib-shaped. DESCRIPTION. —Small- to medium-sized, nearly hemispheri¬ cal, naticiform shell. Spire small, low, obtuse, and protruding. Sutures shallow and impressed. Shell of three and one-half whorls, enlarging abaxially; strongly convex in middle to upper whorl face such that upper surface appears stair-like. Growth lines faint, almost straight, and slightly prosoclinal. Inner lip curved. Aperture large and subcircular, strongly expanding abaxially. Outer lip sharp and thin, broadly curved with nar¬ rowly rounded shoulder; upper and middle margins of outer lip divided by this shoulder. Inductura narrow and rib-like, extend¬ ing from parietal lip to columellar lip and covering most of um¬ bilicus but preserving an umbilical chink. Material Examined. —Thirty specimens from the lower and middle parts of the Guojiashan Formation of Saierlangshan and two from the lower part of the Guanggaishan Formation of Lagecaimo, Zoige Xian, Sichuan Province: USNM 485562— 485572. Type Specimen. — Holotype: USNM 485562. Measurements. —As follows (in mm): USNM catalog no. Shell height Shell width Final- whorl height Spiral- base width Aperture height Aperture width 485562 9.3 10.3 8.8 3.6 7.4 6.8 485563 9.0 9.0 8.4 3.6 7.1 6.1 485565 6.6 7.3 6.5 2.8 5.9 5.0 485568 6.9 7.9 6.8 3.0 6.7 5.5 485569 3.9 4.0 3.8 1.8 3.4 3.2 485570 9.5 11.9 9.2 4.4 8.8 8.0 485571 7.2 7.0 6.9 2.9 5.5 4.3 DISCUSSION.— These specimens are similar to Naticopsis (Dicosmos) cassiana (Wissmann) (Laube, 1869:36, pi. 21: fig. 10; Kittl, 1892:80, pi. 7: figs. 18-21) and Naticopsis (Dicos¬ mos) impressa (Munster) (Laube, 1869:37, pi. 21: fig. 13; Kittl, 1892:81, pi. 7: figs. 13, 15-17), both of the Alpine St. Cassian Formation and Raibl bed, in the possession of a low and small but protruding spire, large aperture, and narrow but elongate inductura. The Chinese forms differ in having an obtuse but markedly protruding spire and a wider final whorl and aperture than in the Alpine species. The upper margin of the aperture also extends further abaxially in the Chinese forms rather than obliquely as in the two European species. Etymology. —This species is named for the Chinese prov¬ ince where the Guanggaishan Formation is located. Subgenus Vernelia Bohm, 1895 Naticopsis ( Vernelia) sublimneiformis Kittl, 1894 Plate 3: figures 35-40 Naticopsis sublimneiformis Kittl, 1894b: 147, pi. 3: figs. 23,25,26 [not fig. 24], Hologyra (Vernelia) sublimneiformis (Kittl).—Bohm, 1895:250, pi. 15: fig. 24. Hologyra sublimneiformis (Kittl).—Kittl, 1899:52, pi. 4: fig. 10. Description. —Moderately high naticiform shell. Shell higher than wide. Spire conical and protruding. Pleural angle about 100°. Sutures impressed. Shell of four evenly convex whorls enlarging obliquely and rapidly in height and partly em¬ bracing about one-third of preceding whorl. Last whorl in¬ flated, a little higher than wide. Middle to lower part of whorl mostly convex. Growth lines faint, nearly straight, slightly prosoclinal, and closely spaced. Aperture ovoid with slightly narrowly rounded front. Outer lip somewhat thickened, with obliquely extending upper margin. Inner lip covered by smooth, concave inductura. Umbilical area depressed but with¬ out funicle. NUMBER 92 23 Material Examined. —Five specimens, including a very small one, from the middle and upper parts of the Guojiashan Formation of Guojiashan and two specimens from the lower part of the Guanggaishan Formation of Lagecaimo, Sichuan Province. Measurements. —As follows (in mm; pleural angle in de¬ grees; all specimens listed below are from Guojiashan): Final- Spiral- USNM catalog no. Shell height Shell width whorl height base width Aperture height Aperture width Pleural angle 485582 12.7 11.6 10.3 4.2 9.5 7.7 105 485583 10.2 7.2 8.8 3.6 7.3 5.0 101 485584 4.5 3.5 4.1 1.9 3.1 1.5 97 485585 15.0 12.0 13.0 5.0 10.8 7.8 93 DlSCUSSlON.— In his definitions of Naticopsis ( Vernelia ) pseudoangusta and N. ( V ) sublimneiformis, Kittl (1894b: 147) noted that the only distinguishing character between the two species was the relatively broader shell in the former species. The Chinese specimens are generally intermediate between Kittl’s two species, although they seem closer to N. ( V ) sublim¬ neiformis ; this may suggest that N. ( V) pseudoangusta and N. (V.) sublimneiformis are the same species. Kittl (1894b, pi. 3: fig. 22) figured a small, possibly juvenile, specimen of N. (V.) pseudoangusta with a highly oviform shell. The smallest speci¬ men in this collection (USNM 485584) is similar, although slightly broader than Kittl’s. Subgenus Uncertain Naticopsis ? ribletella, new species Plate 3: figures 41^44 DIAGNOSIS. —Small naticiform shell with a low but elevated spire and abaxially extended final whorl. Sutures impressed, grooves shallow. Collabral riblets closely and regularly spaced. Aperture hemicircular with thick, wide inductura entirely cov¬ ering parietal and columellar lips. Description. —Small naticiform shell with obtusely conical apex and small but markedly protruding spire. Three whorls in¬ creasing quickly in size with evenly curved side. Final whorl expanding abaxially, ornamented with uniform, closely spaced, and nearly orthoclinal riblets. Riblets narrow and round; inter¬ grooves wide and flat-bottomed. Aperture large, highly hemi¬ circular. Inner lip widely thickened by inductura; umbilical area completely covered by inductura with strong fold out of columellar lip. Umbilical area entirely covered. Material Examined. —One well-preserved specimen and one with the apex broken, from the middle part of the Guojia¬ shan Formation: USNM 485586, 485587. Type Specimen. — Holotype: USNM 485586. Measurements. —As follows (in mm): Final- Spiral- USNM Shell Shell whorl base Aperture Aperture catalog no. height width height width height width 7.3 4.6 DISCUSSION. —This new species is characterized by the orna¬ ment of regular riblets, which is similar to some species of Natiria, especially to N. costata (Munster) (Laube, 1868:43, pi. 22: figs. 11, 12) but these shells have a remarkable callosity on the inner lip that spreads over the umbilical area. The type spe¬ cies of Natiria, Natica lirata (Phillips) from the Lower Carbon¬ iferous (Knight, 1941), differs significantly from these speci¬ mens in its loosely spired whorls with deeply sunken sutures. The inductura of Natiria is very weak according to the generic diagnosis (e.g., Wenz, 1938:410; see also Knight, 1941) and in the species referred to Natiria. Therefore, both the inductura and the naticiform shell of these specimens support their as¬ signment to the Neritimorpha. Etymology. —This species is named for the close and regu¬ larly spaced riblets on the specimens. Genus Neritopsis Grateloup, 1832 TYPE Species.— Neritopsis monoliformis Grateloup, 1832; by original designation. DISCUSSION. —The ornament of this neritopsid easily distin¬ guishes members of the genus from the smooth naticopsids. The genus may have originated from Naticopsis or Trachydo- mia or from a related clade during the Triassic recovery. This lineage survived the end-Triassic mass extinction, when most neritopsids became extinct. Neritopsis planoplicatus, new species Plate 3: figure 45; Plate 4: figures 1,2 Diagnosis. —Naticiform. Final whorl ornamented with reg¬ ular cancellate sculpture produced by spiral ribbons and promi¬ nent growth lines. Spiral ribbons low and wide with flat top; grooves shallow and flat-bottomed, as wide as ribbons. Induc¬ tura smoothly concave and extending inside aperture. Description.— Medium-sized, globular, naticiform gastro¬ pod. Shell width slightly greater than height. Spire small and obtuse but protruding. Sutures impressed; whorls abutted. Shell of four rapidly expanding convex whorls. Final whorl expand¬ ing abaxially with step-like upper surface, turning evenly to lat¬ eral face and to base. No visible ornament on spire, but cancel- late sculpture covering final whorl. Spiral bands with wide, flat tops and bottoms of grooves with steep lateral sides; spiral rib¬ bons low, as wide as grooves. Collabral elements more or less variable, mostly riblets with flat tops; riblets prosoclinal on up¬ per part of final whorl. Aperture subcircular. Outer lip thick, having an oblique and sharpened margin; inner lip thickened by a thin inductura mainly on parietal lip. Inductura smoothly concave, extending inside aperture and covering umbilical area; inductura in umbilical area thin, forming a shallow pit. Material Examined.—A single well-preserved specimen from the middle part of the Guojiashan Formation in Guojia¬ shan. Type Specimen. — Holotype: USNM 485588. 485586 8.8 8.7 7.7 2.7 24 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Measurements. —As follows (in mm): USNM Shell Shell catalog no. height width Final- Spiral- whorl base Aperture Aperture height width height width 485588 13.7 14.0 12.5 5.5 10.0 8.8 DISCUSSION. —The naticiform shell, marked spiral ornament, and concave inductura mark this specimen as belonging to Ner- itopsis. Although we normally oppose describing a new species based on only a single specimen, the very low and wide spiral ribbons and equally wide grooves (sometimes appearing as dark bands) distinguish this new species from any others within the genus. Etymology. —The species name is derived from the wide, flat spiral ornament. inductura can be seen on others. The smallest shell has an un¬ usual, very strong, highly elevated inductura completely cover¬ ing the parietal and columellar lips, but with a small umbilical chink. Although slightly deformed, these specimens reveal a depressed shell shape (especially the final whorl) without a horizontal ramp below the barely impressed sutures, which are the major characters that Kittl (1894b: 129) emphasized in es¬ tablishing Neritaria calcitica, and that distinguish this species from the similar N. incisa (Kittl, 1894b: 131, pi. 2: figs. 29-31) and N. papilio (Stoppani) (Kittl, 1899:64). The inducturas of these Chinese specimens differ from those of N. calcitica; in¬ ducturas in Kittl’s Alpine specimens, although thickened, cover the umbilical area flatly. Family Neritidae Rafinesque, 1815 Genus Neritaria Koken, 1892 TYPE Species. — Neritaria similis Koken, 1892b (=. Natica plicatilis Klipstein, 1843); by original designation. DISCUSSION.— The taxa assigned to this genus exhibit no significant differences from the unornamented neritopsids in external form, but the resorption of the inner wall on the early whorls is the standard character distinguishing this taxon from other groups in the clade. As noted earlier, the phylogenetic significance of resorption is unclear and requires further study. We have assigned several taxa to this group based on similarity of the external shell features to previously described European specimens. Neritaria cf. calcitica (Kittl, 1894) Plate 4: figures 3-10 Protonerita calcitica Kittl, 1894b: 129, pi. 2: figs. 18-22. Neritaria calcitica (Kittl).—Kittl, 1899:64, pi. 3: figs. 7, 8.—Assmann, 1924: 19, pi. 2: fig. 8. Description. —Small- to medium-sized compressedly nat¬ iciform shell with an enlarged aperture. Spire small and low. Three adpressed whorls with rapid whorl expansion; final whorl greatly expanded. Spire height increasing more slowly, resulting in a compressed naticiform shell. Whorl profile round except for very convex upper part in final whorl. Shell surface smooth except for very fine collabral lines. Apertural plane highly inclined to columellar axis; aperture obliquely oviform, broadened at base, and narrowed adapically. Base clearly um- bilicate. Material Examined. —Six deformed specimens from the middle and upper parts of the Guojiashan Formation of Guojia- shan and additional, broken specimens from other beds at the same locality: USNM 485589^485592. DISCUSSION.— The inducturas are not well preserved except on the smallest specimen (Plate 4: figure 9), but the trace of an Neritaria Candida (Kittl, 1894) Plate 4: figures 11-19 Protonerita Candida Kittl, 1894b: 130, pi. 2: fig. 23. (For further synonymies see Diener, 1926:101; Kutassy, 1937b:320, 325.] Neritaria Candida (Kittl).—Yin and Yochelson, 1983b:535, fig. 3A-C, E-G. Description. —Small globular neritopsid of three preserved whorls. Spire markedly protruding with obtusely conical apex. Pleural angle about 90°. Whorls rapidly enlarging in both height and width; even but strongly convex whorl profile. Final whorl expanding abaxially and obliquely. Shell surface smooth, whorls adpressed, with no visible collabral ornament. Aperture oviform and narrowed at base. Inner lip moderately thickened; inductura smooth, not very broad, and largely con¬ fined to the parietal lip. Material Examined. —Seven mostly well-preserved speci¬ mens; four have a flat sutural profile and three have a grooved sutural profile. Four shells have long, straight columellar lips. All are from the middle part of the Guojiashan Formation: USNM 485593^485598. Measurements. —As follows (in mm): Final- Spiral- USNM catalog no. Shell height Shell width whorl height base width Aperture height Aperture width 485593 8.8 7.9 6.5 4.0 5.5 3.7 485595 8.2 8.1 7.7 3.5 6.3 5.3 485596 6.2 5.8 5.8 2.7 4.2 3.2 485597 7.4 7.8 6.3 3.2 5.6 4.2 485598 6.0 6.4 5.0 2.7 4.2 3.7 DiSCUSSlON. —The distinctive characters of this species are the conical apex, tall shell shape producing a pleural angle less than 90°, and shallow sutures. The specimens from Qinling have a pleural angle of about 90° and a slightly larger final whorl, but it is appropriate to include them in this species. Of other similar species, N. calcitica (Kittl, 1894b: 129, pi. 2: figs. 18-22) has a much lower shell and larger pleural angle, and N. papilio (Stoppani) (Kittl, 1899:65, figs. 9-12) has a smaller spire and more impressed sutures. NUMBER 92 25 Neritaria ingrandita (Kittl, 1894) Plate 4: figures 20-23 Protonerita ingrandita Kittl, 1894b: 132, pi. 3: fig. 1. Neritaria ingrandita (Kittl).—Bohm, 1895:236, pi. 11: fig. 3. Description.— Medium-sized to large, hemispherical, broad naticiform gastropod. Spire low and only slightly protruding with an obtusely round apex. Sutural grooves narrow and shal¬ low but deepening close to aperture. Two to three whorls evenly convex and enlarging quickly. Final whorl broad and markedly expanding laterally. Growth lines closely spaced and irregularly prominent, straight but shifting slightly forward below sutures; occasional dark bands parallel to growth lines. Shell wall thick. Aperture subcircular, extending obliquely. Outer lip thin and sharp. Inner lip covered with thin, wide, smooth, and markedly concave inductura covering umbilicus but forming wide de¬ pression in umbilical area. Material Examined. —Six specimens from the lower and middle parts of the Guojiashan Formation, Guojiashan, and one from the lower part of the Guojiashan Formation, Saierlang- shan. Measurements. —As follows (in mm): Final- Spiral- USNM Shell Shell whorl base Aperture Aperture catalog no. height width height width height width 485606 21.2 24.4 20.8 8.2 18.1 -16.2 485607 17.3 20.1 16.9 7.3 13.9 13.0 DlSCUSSlON. —These specimens are identical to Neritaria ingrandita (Kittl) in the broad naticiform shape, fewer whorls, and sunken suture close to the aperture. The type specimen of N. ingrandita (Kittl, 1894b: 132, pi. 3: fig. 1) has a slightly convex inductura, and the Chinese specimens have markedly concave inducturas. However, Kittl (1894b: 132) emphasized the sutural character in naming the species, and in his descrip¬ tion the inductura is variable (“abgeplattet, flach oder wenig convex”). Neritaria plicatilis (Klipstein, 1843) Plate 4: figures 24-26 Naticaplicatilis Klipstein, 1843:195, pi. 13: fig. 9. Neritaria plicatilis (Klipstein).—Kittl, 1892:88, pi. 7: figs. 34—36. Neritaria similis Koken, 1892b: 192-193, pi. 12: figs. 1-6, 9. Protonerita plicatilis (Klipstein).—Kutassy, 1937a:55, pi. 2: figs. 29-31. DESCRIPTION. —Medium-sized, hemispherical, naticiform gastropod. Spire small but markedly protruding. Sutures im¬ pressed, grooves narrow and shallow. Three whorls strongly and evenly convex, enlarging quickly. Final whorl considerably inflated and outside profile widely curved. Collabral ornament fine, crowded, straight, and prosoclinal, with some faint growth rugae. Aperture highly oviform but base unknown. Outer lip thin and sharp. Inductura on inner lip strong and rib-like. Um¬ bilicus partly covered, occupied by a long, narrow depression. Material Examined. —A single specimen from the lower part of the Guanggaishan Formation, Lagecaimo, Sichuan Province: USNM 485608. Discussion. —The shell shape and the markedly protruding spire of this specimen supports its assignment to Neritaria pli¬ catilis, an intermediate form between N. mandelslohi (Klip¬ stein), with a lower shell and smaller spire, and N. angusta (Munster), with a higher shell and more protruding spire (Kittl, 1892:88-89). Another related species in this series is N. tran- siens (Kittl) with an even higher shell and spire. Neritaria sphaeroidica Picard, 1903 Plate 4: figures 27-40; Plate 5: figures 1, 2 Neritaria sphaeroidica Picard, 1903:490, pi. 11: fig. 7. Description. —Medium-sized, globular, naticiform shell with an obtuse apex and low, conical spire. Sutures flush. Four adpressed whorls enlarging obliquely and extending adapically, embracing most of preceding whorl. Final whorl convex, strongly expanding abaxially such that upper surface slightly concave. Growth lines closely spaced, faint, irregular, and prosocyrt. Aperture large and more oval, pointed adapically at suture. Outer lip thin and sharp. Inner lip curved with smooth, moderately wide, and slightly convex inductura, mainly on parietal lip. Material Examined. —Seventeen generally well-preserved specimens from the middle and upper parts of the Guojiashan Formation, Guojiashan. MEASUREMENTS.—As follows (in mm; pleural angle in de¬ grees): Final- Spiral- USNM catalog no. Shell height Shell width whorl height base width Aperture height Aperture width Pleural angle 485599 16.4 - 15.6 7.0 — — — 485600 12.0 15.5 11.8 5.1 10.8 10.2 124 485601 13.8 17.4 13.8 5.2 12.5 11.2 — 485602 9.5 9.1 9.3 3.2 7.4 5.9 128 485603 8.1 8.7 7.8 3.1 7.4 6.2 118 485604 7.2 9.0 7.1 3.2 6.2 5.7 130 485605 8.2 9.5 8.0 3.3 — _ _ DISCUSSION. —The spherical shape, flat upper surface of fi¬ nal whorl, and adapically acute aperture are distinctive in this species. Our specimens from Qinling coincide with Picard’s (1903) description except that some specimens are slightly larger than Picard’s. Genus Platychilina Koken, 1892 Type Species. — Platychilina woehrmanni Koken, 1892b; by original designation. Discussion. —This genus is characterized by a strong, later¬ ally extended final whorl producing a very eccentric low spire and a very wide sutural ramp, as well as by nodose ornament. The West Qinling collections include two species assigned to 26 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY this genus, although the nodose ornament is not as well devel¬ oped as in other known species of this genus (see discussion of Platychilina sinensis, new species). Previously described La- dinian and Camian species of Platychilina have two or more rows of nodes. Species with a single row of nodes are found only in the Anisian. Kittl (1899:28) outlined the evolutionary relationships among some genera of neritoids. He placed Platychilina in a different lineage from Naticopsis and considered it a descen¬ dant of the Paleozoic Platycheilus Gemmellaro ( -Trachyspira Gemmellaro) and Trachydomia Meek and Worthen. However, the latter two genera have a more constant increase in whorl expansion during shell growth; that is, the pattern of their shell growth is different from Platychilina. Our two Chinese species suggest the Triassic Platychilina may have a similar evolution¬ ary history to Trachynerita (Kittl, 1894b: 133), being derived from Naticopsis and distinguished by the development of more complex ornament during the Triassic. Platychilina sinensis, new species Plate 5: figures 3-11 Diagnosis. —Final whorl expanding abaxially. Sutural ramp very wide. Lateral whorl face only slightly convex. One row of opisthoclinally elongated nodes on periphery of final whorl. Description. —Medium-sized, globular, naticiform gastro¬ pod. Spire small but protruding with a rounded apex. Sutures shallow. Three to four whorls expanding rapidly and forming stair-like whorl profile. Final whorl strongly expanding later¬ ally. Angle between sutural ramp and lateral face 110°. Sutural ramp very wide, flat, and extending obliquely (abaxially). Lat¬ eral whorl face flat to slightly convex. Obscure collabral orna¬ ment on spire. Angular periphery of final whorl bearing a row of seven to 10 strong nodes elongated opisthoclinally and im¬ bricated. Final whorl covered with crowded and regular, straight, and prosoclinal growth riblets passing through nodes with angle of 50° to elongation of nodes. Base strongly convex with narrowly round transitional band between lateral face and base. Aperture oval to subquadrangular with narrowly round abapical margin. Outer lip thin. Inductura narrow, smooth, and slightly concave, extending inside aperture from parietal to col- umellar lips with thickened inner margin. Umbilicus covered. Material Examined. —Twenty specimens from the middle to upper part of the Guojiashan Formation, Guojiashan: USNM 485609-485614. Type Specimen. — Holotype: USNM 485611. Measurements. —As follows (in mm): USNM catalog no. Shell height Shell width Final-whorl height Spiral-base width 485609 17.5 15.4 15.6 5.8 485610 10.8 9.5 9.8 3.9 485611 14.5 12.4 13.0 6.0 485612 15.5 12.8 14.0 5.2 485614 11.2 9.4 10.0 4.1 DISCUSSION. —This new species is similar to Trachynerita nodifera Kittl (1894b: 136, pi. 3: figs. 15, 16) in the presence of only one row of nodes and the step-like whorl profile. The new Chinese species differs from T. nodifera in having a laterally extended final whorl, whereas T. nodifera has a more regular rate of whorl expansion. The type species of Trachynerita, T. fornoensis Kittl (1894b), has the same shell outline as T. nodifera, but the differences in whorl and spire morphology ex¬ clude these specimens from this genus. Other genera with simi¬ lar shell growth patterns to these Chinese specimens (very ec¬ centric spire and very wide ramp), as well as nodose ornament, are Platychilina Koken and Delphinulopsis Laube. The type species of Delphinulopsis, D. binidosa (Munster), has open- coiled whorls, as emphasized by Laube (1870 [1869], pi. 33: fig. 3) when he established this genus. The type species of Platychilina, P. woehrmanni Koken (1892b, pi. 11: figs. 5-8), has three rows of nodes on the final whorl, although in his de¬ scription Koken did not discuss the nodes on the final whorl. Because of the significance of shell growth patterns in distin¬ guishing genera (see “Discussion” in the superfamily Neri- toidea), we include our specimens in the genus Platychilina. Etymology. —The species name is derived from the prefix “Sino-,” of Greek and Arabic origin, meaning Chinese. Platychilina obliqua, new species Plate 5: figures 12-18 Diagnosis. —Apex acute. Spire small and conical, eccentric. Peripheral angulation widely rounded, with few opisthoclinally elongated nodes. Final whorl extending obliquely. Description. —Moderately depressed naticiform gastro¬ pod. Spire very small but obviously protruding, with acute apex. Sutural grooves shallow. Four whorls enlarging rapidly in width. Final whorl strongly extended obliquely to axis of coil¬ ing; width two times greater than base. Periphery widely rounded and lacking keel. Sutural ramp very wide, slightly convex, and extending abaxially. Lateral face strongly convex, turning evenly to basal surface. Periphery of last half of final whorl carrying row of low, but distinct, opisthoclinally elon¬ gated nodes; nodes absent on earlier whorls. Growth lines fine and closely spaced, straight and prosoclinal, passing through nodes, and only covering final whorl. Aperture oviform, ex¬ tending obliquely. Outer lip thin and sharp. Inner lip sigmoid. Inductura narrow and long, concave and smooth, spreading mainly on parietal lip, and extending inside aperture to col- umellar lip. Umbilical area covered. Holotype displaying a color pattern of spiral stripes. Material Examined. —Six specimens from the middle part of the Guojiashan Formation of Guojiashan, and one from the middle to upper part of the Guojiashan Formation of Saierlang- shan: USNM 485615-485619. Type Specimen. — Holotype: USNM 485617. NUMBER 92 27 Measurements.—A s follows (in mm): USNM catalog no. Shell height Shell width Final-whorl height Spiral-base width 485616 ~6.0 5.5 ~5.5 2.4 485617 13.2 11.4 12.0 4.0 485619 13.0 11.2 12.0 4.2 Discussion. —Most specimens have very rare (one to three) but distinct nodes. A few specimens have five to six smaller nodes. All nodes are solid and cannot be seen on the steinkems. This species is similar to Platychilina tuberculata Kittl from the Alpine Marmolata bed (Kittl, 1894b: 126, pi. 2: fig. 12) in having a small and conical spire, rounded peripheral angula¬ tion, and obliquely extended final whorl. The Alpine species, however, is richly ornamented. This new species is distin¬ guished from P. sinensis, new species, by the small spire, sharpened apex, round periphery, and poorly developed nodes. ETYMOLOGY. —The species name is derived from the ob¬ lique extension of the final whorl. Order APOGASTROPODA Salvini-PIawen and Haszprunar, 1987, sensu Ponder and Lindberg, 1997 Suborder Caenogastropoda Cox, 1960 Superfamily Loxonematoidea Koken, 1889 Family Spirostylidae Cossmann, 1909 Genus Spirostylus Kittl, 1894 TYPE Species.— Melania subcolumnaris Munster, 1841; by subsequent designation. DISCUSSION. —This genus was established by Kittl (1894b: 197), and the type species was subsequently designated by Cossmann (1909:73). The genus may have originated from Coelostylina (Kittl, 1899:101) in the Triassic or earlier. We have a single specimen that preserves the key last two whorls and matches well the characters of the type species. A second specimen differs only in the slightly larger pleural angle and the wider whorls. Spirostylus cf. linctus (Bohm, 1895) Plate 5: figure 20 Omphaloptycha lincta Bohm, 1895:277, pi. 14: fig. 2. Omphaloptychaporrecta Bohm, 1895:280, pi. 15: fig. 7b,c.—Kittl, 1899:103. Spirostylus linctus (Bohm).—Kittl, 1899:103. Description. —Small, acutely conical shell with 32° pleural angle. Sutures shallowly impressed. Shell of more than seven gradually enlarging whorls; earlier whorls flat; final two to three whorls widely and evenly depressed in upper part and convex in middle and lower parts of whorl profile. Whorls twice as wide as high. Ornament only of faint spiral threads on middle and upper faces of two final whorls and weak sinuous growth lines. Base highly arched. Material Examined. —One specimen from the lower part of the Guojiashan Formation, Saierlangshan: USNM 485629. Discussion. —This shell differs from most species of Spiro¬ stylus in its relatively larger pleural angle and smaller ratio of whorl height to width, but the twisted whorl face, sinuous growth lines, and extended base of this specimen are all key features of this genus. The specimen is most similar to those of Bohm (1895) from the Alpine Marmolata bed that were as¬ signed to Spirostylus linctus (Bohm) by Kittl (1899:103). Spirostylus species indeterminate Plate 5: figure 19 DESCRIPTION. —Small, high-spired loxonematid. Sutural grooves narrow and oblique. Whorls slightly wider than high, with widely and evenly concave upper face and convex middle to lower surface. Base highly arched, anomphalous. Growth lines faint, nearly straight, and slightly prosoclinal. Aperture ovoid with adapical angulation. Outer lip round, parietal lip relatively straight, and columellar lip extending at an inclined angle. Material Examined. —One specimen consisting of two well-preserved final whorls from the lower part of the Zalishan Formation, Saierlangshan, Sichuan Province: USNM 485628. Discussion. —The shape of the whorl surface and base and the character of the aperture coincide with Spirostylus subco¬ lumnaris (Munster) (Kittl, 1894a: 198, pi. 7: fig. 28). Because the earlier whorls are unknown, no species name is given here. Family Coelostylinidae Cossmann, 1909 Genus Toxoconcha Kittl, 1899 Type Species. — Chemnitzia brocchii Stoppani, 1858-1860; by subsequent designation. DISCUSSION.— This large Triassic form is easily identified by the high-spired shell with flattened whorl sides, a flat base but extended columellar lip, and commonly marked subsutural facelets. Kittl (1899) noted that the open columella of this genus served to separate Toxoconcha from Undularia, Anoptychia, and Atorcula. Members of the genus were common in the Mid¬ dle and Upper Triassic, and these Chinese specimens extend the range of the genus into the Early Triassic; no specimens as¬ signed to the genus have been reported from the Paleozoic. Toxoconcha uniformis (Stoppani, 1858) Plate 5: figures 21-25 Chemnitzia uniformis Stoppani, 1858-1860:32, pi. 7: fig. 23. Undularia ( Toxoconcha ) uniformis (Stoppani).—Kittl, 1899:168, pi. 12: fig. 28.—Tommasi, 1913:59, pi. 4: fig. 12. Toxoconcha uniformis (Stoppani).—Wenz, 1938:395. Description. —Medium-sized to large, high-spired, conical turitelliform with a 35° pleural angle. Sutural grooves shallow. Subsutural facelet quite narrow and distinct only in final whorl. 28 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Whorl sides flattened, twice as wide as high. No marked orna¬ ment observed. Peripheral angulation acute at base of final whorl, separating low convex base from flat apical lateral sur¬ face. Aperture oval, with angularly adapical end and narrowly rounded basal margin. Outer lip curved; inner lip thickened and reversed to cover umbilical area. Columellar lip extending straight at about 15° angle with coiling axis. Material Examined. —Seven specimens from the lower part of the Zalishan Formation, Saierlangshan: USNM 485630-485634. DISCUSSION. —These shells are very similar to Toxoconcha uniformis in the possession of shallow sutural grooves, less de¬ veloped subsutural facelets, and the basal angulation in the fi¬ nal whorl. The evident subsutural facelets, relatively lower spire, and larger pleural angle identify USNM 485635 (Plate 5: figure 26) as Kittl’s subspecies (or variety) T. brocchii brevis. This specimen, however, has a basal angulation, but it may have been intensified by preservation. Genus Coelostylina Kittl, 1894 TYPE Species. — Melania conica Munster, 1841; by original designation. DISCUSSION.— Distinguishing this genus from Omphalopty- cha Ammon has long been confusing, largely because the forms are intergrading and especially because Ammon’s types are not well known (A. Niitzel, pers. comm, to Erwin, 1999). Koken (1898:34, 35) separated the genera based on the exist¬ ence or absence of the subsutural facelets; however, Cossmann (1909:42, 45) differentiated the two genera based on the ratio of the final whorl to the spire without discussing the relation¬ ship between his standard and Koken’s. With some species, each definition gives the same generic assignment; with others the taxonomic assignments are ambiguous. Because Cossmann (1909) assigned a type species for each genus whereas Koken (1898) did not, later workers have tended to use Cossmann’s definition to separate the two genera (e.g., Wenz, 1938; Haas, 1953; Yin and Yochelson, 1983c; Batten and Stokes, 1986; Erwin in Stanley et al., 1994), with the relatively low-spired forms assigned to Ompha/optycha and the higher spired forms assigned to Coelostylina. Coelostylina ahlburgi (Assmann, 1924), new combination Figure 10; Plate 5: figures 27, 28 Omphaloptycha ahlburgi Assmann, 1924:33, pi. 3: figs. 31-33.—1937:88, pi. 16: figs. 33-35. Omphaloptycha ecki Assmann, 1924:35, pi. 3: fig. 37.—[Not Hohenstein, 1913] [new synonymy]. DESCRIPTION. —Small loxonematid with an acute apex. Pleu¬ ral angle about 30°. Sutural grooves shallow. Subsutural face- lets indistinct. Shell of five to six whorls, lower face convex, about twice as wide as high, gradually enlarging except for rel- FlGURE 10. —Coelostylina ahlburgi (not to scale). atively higher final whorl. Base slightly convex. Growth lines faint and slightly opisthocyrt. Aperture unknown. Material Examined. —Three specimens from the middle part of the Guojiashan Formation, Saierlangshan. Measurements. —As follows: USNM catalog no. Shell height (mm) Shell width (mm) Pleural angle (°) 485637 4.2 1.9 28 485638 4.2 2.1 30 485639 4.2 2.8 33 Discussion. —Although the apertures of these specimens are not preserved, the acute apex, pleural angle, slightly larger final whorl, and whorl shape support their assignment to C. ahlburgi. Coelostylina cf. waageni Kittl, 1894 Plate 5: figures 29, 30 Coelostylina waageni Kittl, 1894a: 188, pi. 5: fig. 47 [not fig. 48], —Zardini, 1978:45, pi. 29: fig. 8; pi. 30: fig. 4. DESCRIPTION. —Small- to medium-sized, conical caenogas- tropod with no distinct subsutural ramps. Sutures widely and shallowly impressed. Whorls smoothly arched. Final whorl slightly inflated. Spiral whorls twice as wide as high. No dis¬ tinct ornament. Base convex with umbilical chink. Aperture oviform with an acute adapical end and narrowly rounded abapical edge. Material Examined. —One specimen from the lower part of the Zalishan Formation, Saierlangshan, and one from the middle part of the Guojiashan Formation. Both have only the last three whorls preserved: USNM 485640, 485641. Discussion. —These shells coincide with Kittl’s description of Coelostylina waageni Kittl (1894a: 188, pi. V: fig. 47) al¬ though they are incomplete. Figure 48 of Kittl, however, differs from our specimens in that the increase of the last two whorls is incompatible with its earlier whorls. Because the Chinese spec¬ imens are not fully preserved, we are unable to comment fur¬ ther on the species. Coelostylina ? species indeterminate Plate 5: figure 31 DESCRIPTION.— Relatively large Coelostylina having shallow sutural grooves. Whorls flat to slightly convex. Final whorl con¬ vex and roundly curved to low pyramidal base. No marked or- NUMBER 92 29 nament except for faint sigmoidal growth lines. Aperture evi¬ dently hemicircular and strongly extended abapically with an acute adapical end. Material Examined. —A single specimen preserving the final one and one-half whorl, from the lower part of the Zali- shan Formation, Saierlangshan: USNM 485644. DISCUSSION. —The progressive increase of the preserved whorls suggests assignment to Coelostylina. This specimen is similar to Coelostylina irritata Kittl (Kittl, 1894a: 159, pi. 5: figs. 16, 17, 19) except for the final whorl, which differs in the Chinese specimen from those in the Alps. Genus Omphaloptycha Ammon, 1892 TYPE Species. —Chemnitzia nota Ammon, 1878; by original designation. DISCUSSION.— This genus is distinguished from Coelostylina by the expanded final whorl as discussed under Coelostylina. This genus is rare in China although specimens have been found at many horizons. For example, Pan (1977) examined two specimens of this genus from the Upper Triassic of Yun¬ nan; Yin and Yochelson (1983c) described a species from the Middle Triassic of Guizhou; Wang and Qi (1986) reported a steinkem from the Middle Triassic of Qinghai; Pan (1982b) distinguished a species from the Lower Triassic of Sichuan; and Wang (1982) assigned a specimen from the Upper Permian of Guangxi Province to the genus. Omphaloptycha gansuensis, new species Plate 5: figures 32, 33 DIAGNOSIS. —Moderately high-spired omphaloptychid with acute apex and pleural angle of 50°. Four to five whorls with constant whorl expansion, and a final whorl slightly higher than the whole spire. Spiral whorls strongly convex; final whorl with flattened upper surface and convex middle and lower parts. Description. —Acutely conical shell. Sutures impressed. Spiral whorls evenly but strongly convex. Final whorl inflated. Ornament of faint, slightly prosocyrtal growth lines and fainter spiral threads. Base strongly convex. Material Examined.— Two specimens from the middle to upper part of the Guojiashan Formation: USNM 485642, 485643. Type Specimen. — Holotype: USNM 485643. Discussion. —Although this new species has an enlarged fi¬ nal whorl, it is only slightly higher than the spire. In Ompha¬ loptycha similar forms have been assigned to Phasianella muensteri Wissmann (Laube, 1869:18, pi. 31: fig. 5), a syn¬ onym of Omphaloptycha jaworskii Haas (Haas 1953:137), and Omphaloptycha cochlea (Munster) (Laube, 1869:40, pi. 25: fig. 2). This species is distinguished from others by the flat¬ tened upper part and convex middle and lower parts of the final whorl, imparting a slight twist to the whorl. It is uncommon in our collection from Qinling. ETYMOLOGY. —The species name is derived from the Chi¬ nese province where it was discovered. Genus Gradiella Kittl, 1899 Type Species. — Chemnitzia gradata Homes, 1856; by origi¬ nal designation. Discussion. —This genus is easy to identify by the gradate shell with pronounced subsutural ramps having an angular edge; the final whorl is almost one-half of the shell height. This genus is rarely found in China. One specimen was reported from the Upper Triassic of Qinghai (Wang and Qi, 1986). Gradiella species indeterminate Plate 5: figures 34, 35 DESCRIPTION. —Small- to medium-sized, gradate, conical gastropod. Sutures canaliculate. Four whorls rapidly enlarging. Whorls low and wide with low, convex to flat lateral face. Sub¬ sutural ramps wide and extending abaxially with narrowly rounded to angular edge. Final whorl obviously expanding, nearly as high as spire. Base arched. Material Examined.— Three partial specimens from the lower part of the Zalishan Formation and from the upper part of the Maresongduo Formation: USNM 485652, 485653. Discussion. —The Qinling collection includes a few stein- kerns from the Lower Triassic, but they are usually more or less broken and often associated with larger gastropods. The gradate conical shell and the wide and horizontally extended subsutural ramps are characteristic of Gradiella and are similar to Gradiella semigradata (Kittl) (Kittl, 1894b: 163, pi. 6: fig. 10; 1899:148, pi. 15: figs. 22, 23) and the type species Chem¬ nitzia gradata Hdmes (Kittl, 1899:152, pi. 15: fig. 24). Be¬ cause the final whorls and aperture of these shells are not well preserved, no species identification can be made. Genus Trypanostylus Cossmann, 1895 TYPE Species. — Eustvlus militaris Kittl, 1894b; by original designation. DISCUSSION. —This Triassic genus was established by Coss¬ mann (1895:63), who had distinguished two groups within the genus Eustylus Kittl (1894a: 192). Blaschke (1905) proposed the subgeneric name Turristylus for Kittl’s Eustylus triadicus group, although this proposal has not been followed by later au¬ thors. Cossmann doubted the separation of Turristylus (the Eustylus triadicus group) from Trypanostylus (the Eustylus mil¬ itaris group), suggesting the solid or hollow columella might not reflect a clear division within this genus. Haas (1953) ex¬ tracted the genus Kittlistylus based on Turritella flexuosa Mun¬ ster (= Eustylus flexuosus Kittl, 1894a), which has an ornament “dominated by a rather dense though not prominent transverse costa which persists throughout development” (Haas, 1953: 244). More recently, Bandel (1995) observed a heterostrophic 30 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY larval shell in Turristylus and placed this genus within the Mathildoidea (Heterostropha). Trypanostylus konincki (Munster, 1841) Plate 6: figures 1-3 Melania koninekeana Munster, 1841.—Kittl, 1894a:194, pi. 6: figs. 39-47. Melania konninkeanu Munster, 1841:95, pi. 9: fig. 25 [lapsus calami],—Kittl, 1894a: 194, pi. 6: figs. 39-41. Melania longissima Munster, 1841:95, pi. 9: fig. 24.—Kittl, 1894a: 194, pi. 6: figs. 39-47. Eustylus konincki (Munster).—Kittl, 1894a: 194, pi. 6: figs. 39-47.—Koken, 1898:33, pi. 5: figs. 3,4. Trypanostylus konincki (Munster).—Kittl, 1899:95, pi. 11: figs. 20, 21.—Ass- mann, 1924:28, pi. 3: figs. 1, 2, 4-6. DESCRIPTION.— Small to medium-sized, slender loxonema- tid. Sutures markedly impressed. Whorls flat to slightly convex in the middle to lower part; ratio of whorl height to width slowly and gradually increasing from 1:2 to 2:3. Growth lines very faint and slightly opisthocyrt. Base convex without any umbili¬ cus. Aperture narrowly oviform with narrow rear channel. Material Examined. —Six specimens from the middle part of the Guojiashan Formation of Guojiashan: USNM 485647- 485650. DISCUSSION.— Kittl (1894a: 194) listed six key features aiding identification of this species; our specimens concur with these, although they are not as tall as the figure given by Kittl (1894b, fig. 39). Trypanostylus cf. pseudoscalatus Assmann, 1924 Plate 6: figure 4 Trypanostylus pseudoscalatus Assmann, 1924:28, pi. 3: figs. 3, 7-9. Description. —Medium-sized, slender, high-spired gastro¬ pod with deeply engraved sutures and eight weakly convex whorls. No ornament observed on steinkem. Peripheral angula¬ tion at base of final whorl. Base slightly convex. Aperture sub- quadrangular. Material Examined. —A single deformed steinkem from the upper part of the Zalishan Formation, Saierlangshan: USNM 485651. DISCUSSION. —The specimen is similar to Trypanostylus pseudoscalatus Assmann (1924) from Upper Silesia, Poland. Superfamily PSEUDOMELANIOIDEA Fischer, 1885 Family Pseudomelaniidae Fischer, 1885 Genus Rantina Wenz, 1938 Type Species. — Macrochilina ptychitica Kittl, 1894b; by subsequent designation. DISCUSSION. —The generic name was proposed by Wenz (1938:370) to replace Rama of Bohm (1895). Confusion devel¬ oped when Kittl’s figures of the type species Macrochilina pty¬ chitica were assigned to this genus by Cossmann (1909:119). Kittl’s figures were cited by Bohm (1895) when he established Rama, but Bohm reversed the order of the text-figures to Kittl’s plates. That is, Bohm’s text-figure 88 is Kittl’s figure 30 of plate 6, and Bohm’s text-figure 89 is Kittl’s figure 29. This re¬ version was not noticed by Kittl (1899) when he revised his 1894 figures and assigned his figure 30 (that is, text-figure 88 of Bohm, 1895) to a new species of a different genus: Euchrys- alis laevis Kittl, 1899. Wenz (1938) did not notice the problem when he renamed Bohm’s genus, resulting in an incorrect fig¬ ure of the type species and an improper generic diagnosis. Kittl’s mistake had been noticed by Cossmann (1909), so we return to Cossmann’s (1909:119) diagnosis for this genus. As Haas (1953) noted, Wenz’s generic name is still available. Ramina ptychitica (Kittl, 1894) Figure 11; Plate 6: figure 6 Macrochilina ptychitica Kittl, 1894b: 173, pi. 6: fig. 29 [not fig. 30]. Rama ptychitica (Kittl).—Bohm, 1895:295, fig. 89, pi. 14: figs. 3, 3a [not fig. 88 or pi. 14: lower two figures]. Ramina ptychitica { Kittl).—Wenz, 1938:370, fig. 875. Description. —Small, high-spired shell with acute apex. Pleural angle about 30°. Sutural grooves narrow and shallow. Shell of more than six whorls; earlier whorls increasing fast in width and later in height. Proportions of height to width in last four whorls separately as follows: 1:2, 1.5:2, 1.8:2, and 2:1.8. Final whorl almost equally high to spire. Upper face of whorls slightly concave; lower face convex. Base roundly arched. No ornament but very faint spiral threads near base. Material Examined.— One specimen from the middle part of the Guojiashan Formation of Saierlangshan. DISCUSSION.— This specimen is conspecific to fig. 29 of Kittl (1894b) and the upper two figures of Bohm’s (1895) fig. 3 for the type species Ramina ptychitica (Kittl). The lower two figures of Bohm (1895) have a larger final whorl and are much different from this specimen. FIGURE 11. — Ramina ptychitica (not to scale). Subclass Heterostropha Fischer, 1885 Superfamily Streptacidoidea Knight, 1931 Family STREPTACIDAE Knight, 1931 Genus Neodonaldina Bandel, 1996 Type Species. —Spirocyclina elongata Zardini, 1978; by subsequent designation. NUMBER 92 31 DISCUSSION. —Only the type species of Spirocyclina had been reported until Zardini (1978) named another species. Ban- del (1996) created the new genus Neodonaldina based on Zard¬ ini’s species. The genus is characterized by an anomphalous shell with deep sutures, inflated whorls, and prominent spiral threads. The second species shares these characters with the type species but has an obviously higher and narrower shell than the latter. Neodonaldina cf. elongata (Zardini, 1978) Plate 6: figure 5 Spirocyclina elongata Z ardini, 1978:55, pi. 40: fig. 5a,b. Neodonaldina elongata (Zardini).—Bandel, 1996:335, fig. 5a-e. DESCRIPTION. —Medium-sized, high-spired streptacid with deeply impressed sutures and strongly and evenly convex whorls. Whorls enlarging gradually. Final whorl twice as high as wide. Ornament of regular spiral threads and faint, slightly opisthocyrtal growth lines. Base pyramidal and anomphalous. Material Examined. —One specimen with only the last five whorls; from the middle to upper part of the Guojiashan Formation, Guojiashan: USNM 485645. Discussion.— This specimen is most similar to Zardini’s Spirocyclina elongata, and although the aperture is not pre¬ served, it is clearly different from the Spirocyclina type spe¬ cies, S. eucycla (Munster), which has a relatively lower shell, more rapidly enlarging whorls, and a stronger spiral ornament (Laube, 1869:14, pi. 30: fig. 8). Superfamily Mathildoidea Dali, 1889 Family Mathildidae Dali, 1889 Genus and species indeterminate Plate 6: figure 7 Description. —Medium-sized, conical mathildid with deeply impressed sutures. Whorls convex, gradually enlarging, with two prominent spiral carinae at lower and upper whorl margins; upper one stronger and acute, forming periphery. A third prominent carina positioned between two margined cari¬ nae, but lying closer to lower one. Subsutural face somewhat sloped, with a carina in the middle. In addition to fine carinae, closely spaced spiral threads cover surface including base. Growth lines clear, slightly curved. Base convex and anompha¬ lous, with cancellate ornament. Aperture subcircular, with zig¬ zag outer lip and long columellar lip. Material Examined.— One partial specimen of last three whorls, from the middle part of the Guojiashan Formation: USNM 485654. DISCUSSION. —This specimen is similar to Proturba intermit¬ tens (Kittl, 1894a), which is known only from the type species, three specimens of Kittl (1894a) from the St. Cassian Forma¬ tion of the southern Alps, and one steinkern described by Kutassy (1937) from the upper Camian of Transylvania. The Qinling collection includes one specimen that is very similar to Kutassy's specimen, but it dates from the Anisian. 32 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY PLATE 1 Figures 1, 2.— Tongweispira sichuanensis, new species, USNM 485493: apical and abapertural views, respec¬ tively (x56). FIGURES 3-5.— Tongweispira sichuanensis, new species, USNM 485494, holotype: apical, apertural, and basal views (x35). FIGURES 6, 7. — Tongweispira sichuanensis, new species, USNM 485495: apical and basal views (x21). FIGURE 8.— Tongweispira sichuanensis, new species, USNM 485496: apical view (x34). FIGURE 9.— Tongweispira sichuanensis, new species, USNM 485498: apical view (x47). FIGURE 10.— Ananias johannisaustriae, USNM 485511: abapertural view (x2.5). FIGURE 11.— Ananias johannisaustriae, USNM 485513: apertural view (x5.6). FIGURE 12. — Ananias johannisaustriae, USNM 485515: abapertural view (x2.7). FIGURE 13.— Ananias guojiashanensis, new species, USNM 485500: apertural view (x2.7). FIGURES 14, 15.— Ananias guojiashanensis, new species, USNM 485502, holotype: abapertural and basal views (X2.7). FIGURE 16.— Ananias guojiashanensis, new species, USNM 485509: abapertural view (x2.6). FIGURES17—19. — Worthenia extendia, new species, USNM 485505, holotype: abapertural, apical, and apertural views (x2.2). FIGURE 20.— Worthenia extendia, new species, USNM 485501 : abapertural view (x3.1). Figure 21.— Worthenia ? species indeterminate A, USNM 485506: apertural view (x5.0). Figure 22.— Worthenia ? species indeterminate A, USNM 485508: abapertural view (x4). FIGURE 23.— Worthenial species indeterminate B, USNM 485514: abapertural view (x3.2). FIGURE 24.— Worthenial species indeterminate C, USNM 485516: apertural view (x3.5). FIGURE 25.— Worthenial species indeterminate C, USNM 485518: apertural view (x7.1). FIGURE 26.— Gosseletina1 dangchangensis, new species, USNM 485520, holotype: apertural view (x3.2). FIGURE 27.— Gosseletina1 dangchangensis, new species, USNM 485521: abapertural view (x3.9). FIGURES 28-30.— Zygiles laevigatas, new species, USNM 485523, holotype: apertural, basal, and apical views (x2.9). Figures 31, 32.— Zygites laevigatus, new species, USNM 485522: apical and abapertural views (xl .7). FIGURES 33, 34.— Zygites laevigatus, new species, USNM 485525: abapertural and apical views (x2.3). Figure 35.— Zygites laevigatus, new species, USNM 485524: abapertural view (x2.4). NUMBER 92 33 34 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY PLATE 2 FIGURE 1.— Euryalox species indeterminate, USNM 485526: abapertural view (xl). FIGURE 2.— Codinellal species indeterminate, USNM 485527: abapertural view (x2.4). FIGURES 3, 4.— Codinellal species indeterminate, USNM 485528: abapertural and apertural views, respectively (xl.9). Figure 5.— Trochotoma (Discotoma)gansuensis, new species, USNM 485529: apical view (xl.3). FIGURES 6-8.— Trochotoma (Discotoma) gansuensis, new species, USNM 485530, holotype: apical, apertural, and basal views (xl .4). FIGURES 9, 10.— Trochotoma (Discotoma) gansuensis, new species, USNM 485531: apical and basal views (xl-2). FIGURE 11.— Tylotrochus elongatus, USNM 485532: oblique abapertural view (x2.6). Figures 12-14.— Natirial species indeterminate, USNM 485538: apical, abapertural, and apertural views (xl.5). FIGURES 15, 16.— Amberleyal species indeterminate, USNM 485537: apical and abapertural views (xl.5). FIGURE 17.— lEunemopsis dolomitica, USNM 485620: abapertural view (x4.2). Figure 18.— Cheilotomona acutocarinata, new species, USNM 485626, holotype: oblique abapertural view (x2.9). FIGURE 19.— Cheilotomona acutocarinata, new species, USNM 485624: apertural view (x2.5). FIGURE 20.— Cheilotomona acutocarinata, new species, USNM 485622: oblique abapertural view (x3). FIGURE 21.— Cheilotomona acutocarinata, new species, USNM 485623: oblique abapertural view (x2.9). FIGURE 22.— Cheilotomona acutocarinata, new species, USNM 485625: abapertural view (x2.7). Figure 23.— Cheilotomona acutocarinata, new species, USNM 485627: oblique abapertural view (x2.7). FIGURES 24—26.— Marmolatella (Marmolatella) complanata, USNM 485539: apical, apertural, and abapertural views (xl.3). FIGURES 27-29.— Marmolatella (Marmolatella) complanata, USNM 485541, apical, apertural, and abapertural views (xl). FIGURES 30, 31.— Marmolatella (Marmolatella) complanata, USNM 485542: abapertural and apertural views (x0.8). FIGURE 32.— Marmolatella (Marmolatella) obtusangula, USNM 485551: abapertural view (x2.1). Figures 33-35.— Naticopsis (Dicosmos) applanatus, USNM 485544: apical, apertural, and abapertural views (x2.3). FIGURE 36.— Naticopsis (Dicosmos) applanatus, USNM 485546: abapertural view (x2.4). FIGURES 37-39.— Naticopsis (Dicosmos) compressus, new species, USNM 485581, holotype: apical, apertural, and abapertural views (x2.1). FIGURES 40—42.— Naticopsis (Dicosmos) compressus, new species, USNM 485573: apical, apertural, and abap¬ ertural views (x2.2). FIGURE 43.— Naticopsis (Dicosmos) compressus, new species, USNM 485574: apical view (xl.8). NUMBER 92 35 36 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY PLATE 3 Figures 1, 2.— Naticopsis (Dicosmos) compressus, new species, USNM 485574: apertural and abapertural views, respectively (x2.3). FIGURES 3, 4.— Naticopsis ( Dicosmos) compressus, new species, USNM 485578: apertural and abapertural views (x2.2). FIGURE 5.— Naticopsis ( Dicosmos) compressus, new species, USNM 485579: apertural view (x2). FIGURE 6.— Naticopsis ( Dicosmos) compressus, new species, USNM 485580: abapertural view (x2.8). FIGURES 7-9.— Naticopsis ( Dicosmos ) declivis, USNM 485547: apical, apertural, and abapertural views (x0.9). FIGURES 10, 11.— Naticopsis (Dicosmos) declivis, USNM 485548: apertural and abapertural views (x0.88). FIGURES 12-14. —Naticopsis (Dicosmos ) eyerichi, USNM 485557: apical, apertural, and abapertural views (x3.9). FIGURES 15, 16.— Naticopsis ( Dicosmos ) eyerichi, USNM 485560: apical and abapertural views (x3.6). FIGURES 17-19.— Naticopsis (Dicosmos) impressa, USNM 485553: apical, apertural, and abapertural views (xl.6). FIGURES 20-22. —Naticopsis (Dicosmos ) impressa, USNM 485554: apical, apertural, and abapertural views (x2.1). Figures 23-25.— Naticopsis ( Dicosmos) sichuanensis, new species, USNM 485570: apical, apertural, and abap¬ ertural views (x2.3). FIGURES 26-28.— Naticopsis (Dicosmos ) sichuanensis, new species, USNM 485563: apical, apertural, and abap¬ ertural views (x2.5). FIGURES 29-31. — Naticopsis (Dicosmos ) sichuanensis, new species, USNM 485565: apical, apertural, and abap¬ ertural views (x3). Figures 32, 33.— Naticopsis ( Dicosmos ) sichuanensis, new species, USNM 485566: apical and abapertural views (x4.3). FIGURE 34. —Naticopsis (Dicosmos) sichuanensis, new species, USNM 485571: abapertural view (x3.3). FIGURES 35-37.— Naticopsis (Vernelia) sublimneiformis, USNM 485583: apical, apertural, and abapertural views (x2.3). FIGURES 38—40.— Naticopsis (Vernelia) sublimneiformis, USNM 485585: apical, apertural, and abapertural views (xl.8). FIGURES 41^13.— Naticopsis ? ribletella, new species, USNM 485586, holotype: apical, apertural, and abaper¬ tural views (x2.6). Figure 44. — Naticopsis ? ribletella, new species, USNM 485587: oblique apertural view (x2.8). Figure 45.— Neritopsis planoplicatus, new species, USNM 485588, holotype: apical view (x2.2). NUMBER 92 37 38 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY PLATE 4 FIGURES 1, 2.— Neritopsis planoplicatus, new species, USNM 485588, holotype: apertural and abapertural views, respectively (x2). FIGURES 3-5.— Neritaria cf. calcitica, USNM 485589: apical, apertural, and abapertural views (x2.3). FIGURES 6, 7.— Neritaria cf. calcitica, USNM 485590: abapertural and apertural views (x2.1). FIGURE 8.— Neritaria cf. calcitica, USNM 485591: apertural view (x2.1). FIGURES 9, 10.— Neritaria cf calcitica, USNM 485592: apertural and abapertural views (x4). FIGURES 11, 12.— Neritaria Candida, USNM 485593: abapertural and apertural views (x3.1). FIGURES 13, 14.— Neritaria Candida, USNM 485596: apical and abapertural views (x4.5). FIGURES 15-17.— Neritaria Candida, USNM 485597: apical, apertural, and abapertural views (x2.7). Figures 18, 19.— Neritaria Candida, USNM 485598: apertural and abapertural views (x3.4). FIGURE 20.— Neritaria ingrandita, USNM 485606: abapertural view (x3.3). FIGURES 21-23.— Neritaria ingrandita, USNM 485607: apical, apertural, and abapertural views (xl.5). FIGURES 24—26.— Neritariaplicatilis, USNM 485608: apical, apertural, and abapertural views (xl.9). FIGURES 27, 28.— Neritaria sphaeroidica, USNM 485599: apical and abapertural views (xl.5). FIGURES 29-31. — Neritaria sphaeroidica. USNM 485600: apical, apertural, and abapertural views (xl .9). FIGURES 32, 33.— Neritaria sphaeroidica, USNM 485601: abapertural and apertural views (xl.7). FIGURES 34-36.— Neritaria sphaeroidica, USNM 485602: apical, apertural, and abapertural views (x2.7). FIGURES 37, 38.— Neritaria sphaeroidica, USNM 485603: apertural and abapertural views (x3). FIGURES 39, 40.— Neritaria sphaeroidica, USNM 485604: apertural and abapertural views (x2.7). NUMBER 92 39 40 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY PLATE 5 FIGURES 1, 2.— Nehtaria sphaeroidica, USNM 485605: apical and abapertural views, respectively (x2.6). FIGURES 3-5.— Platychilina sinensis, new species, USNM 485611, holotype: apical, apertural, and abapertural views (xl.8). FIGURES 6, 7.— Platychilina sinensis, new species, USNM 485609: apical and apertural views (xl .7). FIGURES 8, 9.— Platychilina sinensis, new species, USNM 485612: apical and abapertural views (x2.1). FIGURES 10, 11.— Platychilina sinensis, new species, USNM 485613: apertural and abapertural views (x2.3). FIGURES 12-14.— Platychilina obliqua, new species, USNM 485617, holotype: apical, apertural, and abapertural views (x2.1). FIGURE 15.— Platychilina obliqua, new species, USNM 485616: apertural view (x3.6). FIGURES 16-18.— Platychilina obliqua, new species, USNM 485618: apical, apertural, and abapertural views (x2.2). FIGURE 19.— Spirostylus species indeterminate, USNM 485628: abapertural view (x2.7). FIGURE 20.— Spirostylus cf. linctus, USNM 485629: oblique abapertural view (x2.9). FIGURE 21.— Toxoconcha uniformis, USNM 485630: abapertural view (xl.5). Figure 22.— Toxoconcha uniformis, USNM 485631: abapertural view (xl.6). FIGURE 23.— Toxoconcha uniformis, USNM 485632: abapertural view (x2.1). FIGURE 24.— Toxoconcha uniformis, USNM 485633: apertural view (x2.1). FIGURE 25.— Toxoconcha uniformis, USNM 485634: apertural view (xl.7). FIGURE 26.— Toxoconcha brocchii brevis, USNM 485635: oblique abapertural view (xl.8). FIGURE 27.— Coelostylina ahlburgi, USNM 485637: oblique abapertural view (x7.6). FIGURE 28.— Coelostylina ahlburgi, USNM 485639: oblique abapertural view (x6.2). Figure 29.— Coelostylina cf. waageni, USNM 485640: apertural view (x2.7). FIGURE 30.— Coelostylina cf. waageni, USNM 485641: abapertural view (x5.9). FIGURE 31.— Coelostylina ? species indeterminate, USNM 485644: apertural view (xl. 1). FIGURE 32.— Omphaloptycha gansuensis, new species, USNM 485643, holotype: abapertural view (x2). FIGURE 33.— Omphaloptycha gansuensis, new species, USNM 485642: abapertural view (xl.5). FIGURE 34. —Gradiella species indeterminate, USNM 485652: abapertural view (x2.9). Figure 35.— Gradiella species indeterminate, USNM 485653: oblique abapertural view (x2.8). NUMBER 92 41 42 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY PLATE 6 FIGURE 1. —Trypanostylus konincki, USNM 485647: abapertural view (x2.3). Figure 2. —Trypanostylus konincki, USNM 485648: abapertural view (x5). FIGURE 3.— Trypanostylus konincki, USNM 485650: apertural view (x3.1). FIGURE 4.— Trypanostylus cf. pseudoscalatus, USNM 485651: abapertural view (x2.4). FIGURE 5.— Neodonaldina cf. elongata, USNM 485645: apertural view (xl .9). FIGURE 6.— Raminaptychitica, USNM 485656: abapertural view (x4). Figure 7.—Mathildidae genus and species indeterminate, USNM 485654: apertural view (xl.9). NUMBER 92 43 Literature Cited Ammon, J.G.F.L. von 1878. Die Gasteropoden des Hauptdolomites und Plattenkalkes der Alpen. Abhandlungen der Zoologisch-Mineralogischer Verein in Regens¬ burg, 11:1-72. 1892 (“1893”). Die Gastropodenfauna des HochfellenKalkes und iiber Gastropoden-Reste aus Ablagerungen von Adnet, vom Monte Nota und den Raibler Schichten. Geognostische Jahreshefte (Munchen), 5(1892): 161-219. [Date on title page is 1893; actual date of publica¬ tion is 1892.] Assmann, P. 1924. Die Gastropoden der oberschlesischen Trias. Jahrbuch der Preussis- chen Geologischen Landesanstalt (Berlin), 44:1-50. 1937. Revision der Fauna der Wirbellosen der oberschlesischen Trias. Jahrbuch der Preussischen Geologischen Landesanstalt, new series, 170:1-134. Bandel, K. 1988. Reprasentieren die Euomphaloidea eine natiirliche Einheit der Gas¬ tropoden. Mitteilungen aus dem Geologisch-Palaontologischen In- stitut der Universitat Hamburg, 67:1-33. 1991. Schlitzbandschnecken mit perlmutteriger Schale aus den trias- sischen St. Cassian-Schichten der Dolomiten. Annalen des Naturhistorischen Museums (Wien), 92:1-53. 1992. Platyceratidae from the Triassic St. Cassian Formation and the Evo¬ lutionary History of the Neritomorpha (Gastropoda). Palaontolo- gische Zeitschrift, 66(3/4):231-240. 1993. Trochomorpha (Archaeogastropoda) aus den St.-Cassian-Schichten (Dolomiten, Mittlere Trias). Annalen des Naturhistorischen Muse¬ ums (Wien), 95:1-99. 1994. Triassic Euthyneura (Gastropoda) from the St. Cassian Formation (Italian Alps) with a Discussion on the Evolution of the Heterostro- pha. Freiberger Forschungshefte, 2:79-100. 1995. Mathildoidea (Gastropoda, Heterostropha) from the Late Triassic St. Cassian Formation. Scripta Geologica, 111: 1-83. 1996. Some Heterostrophic Gastropods from Triassic St. Cassian Forma¬ tion with a Discussion on the Classification of the Allogastropoda. Palaontologische Zeitschrift, 70(3/4):325-365. Batten, R.L. 1956. Some New Pleurotomarian Gastropods from the Permian of West Texas. Journal of the Washington Academy of Sciences, 46(4): 42-44. 1973. The Vicissitudes of the Gastropods during the Interval of Guadalu- pian-Ladinian Time. In L. Logan and L.Y. Hills, editors, The Perm¬ ian and Triassic Systems and Their Material Boundaries. Memoirs, Canadian Society of Petroleum Geologists, 2:596-607. 1985. Permian Gastropoda from Perak, Malaysia, 3: The Muchisoniids, Cerithiids, Loxonematids and Subulitids. American Museum Novi- tates, 2829:1-70. 1989. Permian Gastropoda of the Southwestern United States, 7: Pleuroto- mariacea: Eotomariidae, Lophospiriidae [sic], Gosseletinidae. American Museum Novitates, 2958:1-64. Batten, R.L., and W.L. Stokes 1986. Early Triassic Gastropods from the Sinbad Member of the Moen- kopi Formation, San Rafael Swell, Utah. American Museum Novi¬ tates, 2864:1-56. Blaschke, F. 1905. Die Gastropodenfauna der Pachycardientuffe der Seiseralpe in Siidtirol. Beitrage zur Palaontologie und Geologie Osterreich- Ungarn.'i und des Orients, 17:161-221. Bohm, J. 1895. Die Gastropoden des Marmolatakalkes. Palaeontographica, 42: 211-308. Canavari,M. 1890. Note di malacologia fossile. Bollettino Societa Malacologica Ital- iana, 15:214-219. Chronic, H. 1952. Molluscan Fauna from the Permian Kaibab Formation, Walnut Can¬ yon, Arizona. Bulletin of the Geological Society of America, 63:95-166. Cossmann, A.E.M. 1895-1925. Essais de paleoconchologie comparee. Volume 1(1895): 159 pages.; volume 2(1896): 179 pages; volume 8(1909): 348 pages; volume 10(1916 [“1915”]): 292 pages; volume 13(1925): 345 pages. Paris: Presses Universitaires de France. [Date on title page for volume 10 is 1915; actual date of publication is 1916.] Cox, L.R. 1960a (“1959”). Thoughts on the Classification of the Gastropoda. Pro¬ ceedings of the Malacological Society of London, 33:239-261. [Date given for the Caenogastropoda, including Cox’s contribution to the Treatise (Cox, 1960b) is 1959; actual date of publication is I960.] 1960b. General Characteristics—Gastropoda. In J.B. Knight, L.R. Cox, A.M. Keen, A.G. Smith, R.L. Batten, E.L. Yochelson, N.H. Lud- brook, R. Robertson, C.M. Yonge, and R.C. Moore, Treatise on In¬ vertebrate Paleontology, Part I: Mollusca I, pages 184-1168. Lawrence, Kansas: Geological Society of America and University of Kansas Press. Cox, L.R., and W.J. Arkell 1950. A Survey of the Mollusca of the British Great Oolite Series, Part 2, 105 pages. London: Palaeontographical Society. Cuvier, G. 1797. Tableau elementaire de l 'histoire naturelle des animaux. 1 10 pages. Paris. Dali, W.H. 1889. Reports on the Results of Dredging, under the Supervision of Alex¬ ander Agassiz, in the Gulf of Mexico (1877-78), and in the Carib¬ bean Sea (1879-80), by the U.S. Coast Survey Steamer ‘Blake,’ Lieut.-Commander C.D. Sigsbee, U.S.N., and Commander J.R. Baartlett, U.S.N., Commanding. XXIX. Report on the Mollusca, 2: Gastropoda and Scaphopoda. Bulletin of the Museum of Compara¬ tive Zoology, 18:1 -492. Diener, C. 1926. Glossophora Triadica. Fossilium Catalogus, 1 (Antmalia)2>4: 1-242. Erwin, D.H. 1993. The Great Paleozoic Crisis: Life and Death in the Permian. 327 pages. New York: Columbia University Press. 1994. The Permo-Triassic Extinction. Nature (London), 367:231-236. 1996. Understanding Biotic Recoveries: Extinction, Survival, and Preser¬ vation during the End-Permian Mass Extinction. In D. Jablonski, D.H. Erwin, and J.H. Lipps, editors, Evolutionary Paleobiology, pages 398-418. Chicago: University of Chicago Press. Erwin, D.H., and Huazhang Pan 1995. 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Faune du calcaire carbonifere de la Belgique, 4: Gasteropodes (suite et fin). Annales du Musee Royal d Histoire Naturelle de Belgique, Paleontologie, 8:201-222. Kutassy, A. 1937a. Triadische Faunen aus dem Bihar-Gebirge I, Teil: Gastropoden. Geologica Hungarica, Series Palaeontologica, 13:1-80. 1937b. Glossophora Triadica II. Fossilium Catalogus, I ( Anima - lia) 81:243-477. Laube, G.C. 1868. Die Fauna der Schichten von St. Cassian: Ein Beitrage zur Palaon- tologie der alpinen Trias, III: Abtheilung: Gastropoden, Halfte I. Denkschriften der Akademie der Wissenschaften, Mathematisch- Naturwissenschaftliche Klasse, 28(2):29-94. 1869 (“1870”). Die Fauna der Schichten von St. Cassian: Ein Beitrage zur Palaontologie der alpinen Trias, IV: Abtheilung: Gastropoden, Halfte II. Denkschriften der Akademie der Wissenschaften, Mathe- matisch-Naturwissenschaftliche Klasse, 30(2): 1-48. [This volume has a date of 1870 but is variously cited as 1869 and 1870 by Euro¬ pean authors; it may have been originally issued in parts.] Loczy, L. von 1899. Die mittel Triadischen Littoralfauna von Tschung-Tzen. Wissen- schaftliche Ergebnischen der Reise des Grafen Belu Szechenyi in Ostasien, 1877-1880:137-140. M’Coy, F.K.C.M.G. 1844. A Synopsis of the Characters of the Carboniferous Limestone Fos¬ sils of Ireland. 207 pages. Dublin: R.J. Griffith. Morris, J., and J. Lycett 1851. A Monograph of the Mollusca from the Great Oolite, Chiefly from Minchinhampton and the Coast of Yorkshire, Part 1: Univalves. Palaeontographical Society (Monographs), 130 pages. Munster, G.G. 1841. Beschreibung und Abbildung in den Kalkmergelschichten von St. 46 SMITHSONIAN CONTRIBUTIONS TO PALEOBIOLOGY Cassian gefundenen Versteinerungen. Beitrdge zur Petrefacten- Kunde, 4:25-152. Newell, N.D. 1935. 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