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Quaternary colonization or Paleogene persistence?: historical biogeography of skates (Chondrichthyes: Rajidae) in the Antarctic ichthyofauna

Published online by Cambridge University Press:  08 February 2016

Douglas J. Long
Douglas J. Long*
Affiliation:
Department of Integrative Biology and the Museum of Paleontology, University of California, Berkeley, California 94720
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Abstract

Seven endemic species of skates (Chondrichthyes: Rajidae) represent the only family of elasmobranchs currently known to live in Antarctic continental waters. Many previous authors believed skates colonized Antarctic waters from Patagonia during interglacial periods in the Quaternary. However, recent fossil material collected from the middle Eocene La Meseta Formation of Seymour Island, Antarctic Peninsula, indicates that they may have persisted in Antarctic waters since the Paleogene. Additionally, oceanographic barriers present in the Neogene and Quaternary would have prevented dispersal from southern continents to Antarctica. A revised dispersal scenario, based on skate fossils, biology, paleogeography, and present centers of skate diversity, suggests that skates evolved in the western Tethys and North Boreal seas of western Europe in the Late Cretaceous and early Paleogene and emigrated into Antarctica during the early to middle Eocene via a dispersal corridor along the continental margins of the western Atlantic Ocean. Skates probably populated the Pacific Basin by passing from this dispersal corridor through the Arctic Ocean. Vicariant events, such as opening of the Drake Passage, the development of the Circum-Antarctic Current, and formation of deep and wide basins around Antarctica in the late Paleogene, created barriers that isolated some species of skates in Antarctica and prevented movement of other species of skates into Antarctica from northern areas. Skates are the only group of fishes known to have survived the Oligocene cooling of Antarctica that killed or extirpated the Paleogene ichthyofauna; they persisted by a combination of cold-tolerance, generalized diet, and unspecialized bathymetric and habitat preferences.

Type
Articles
Information
Paleobiology , Volume 20 , Issue 2 , Spring 1994 , pp. 215 - 228
Copyright
Copyright © The Paleontological Society 

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References

Literature Cited

Ajayi, T. O. 1982. Food and feeding habits of Raja species (Batoidei) in Carmarthen Bay, Bristol Channel. Journal of the Marine Biological Association of the United Kingdom 62:215223.CrossRefGoogle Scholar
Anderson, M. E. 1988. Studies on the zoarcidae (Teleostei: Perciformes) of the Southern Hemisphere. I. The Antarctic and subantarctic regions. Biology of the Antarctic seas XIX, Antarctic research series, 47:59113. American Geophysical Union.CrossRefGoogle Scholar
Anderson, M. E. 1990. The origin and evolution of the Antarctic ichthyofauna. Pp. 2833in Gon, and Heemstra, 1990.Google Scholar
Anderson, M. E., Crabtree, R. E., Carter, H. J., Sulak, K. J., and Richardson, M. D. 1985. Distribution of demersal fishes of the Caribbean Sea found below 2000 meters. Bulletin of Marine Science 37:794807.Google Scholar
Andriashev, A. P. 1965. A general review of the Antarctic fish fauna. Pp. 491550in Van Mieghem, J., Van Oye, P., and Schell, J., eds. Monographiae biologicae, Vol. 15. Biogeography and ecology in Antarctica. Junk Publishers, The Hague.CrossRefGoogle Scholar
Andriashev, A. P. 1977. Some additions to schemes of the vertical zonation of marine bottom fauna. Pp. 351360in Llano, G. A., ed. Adaptations within Antarctic ecosystems. Proceedings of the Third Scientific Committee for Antarctic Research Symposium on Antarctic Biology. Smithsonian Institution, Washington D.C.Google Scholar
Andriashev, A. P. 1990. On the probability of the transoceanic (non-Arctic) dispersal of secondarily deepwater fish species of Boreal-Pacific origin into the depths of the North Atlantic and Arctic Ocean (family Liparididae, as example). Journal of Ichthyology 30:19.Google Scholar
Andriashev, A. P. 1991. Possible pathways of Paraliparis (Pisces: Liparididae) and some other North Pacific secondarily deep-sea fishes into North Atlantic and Arctic depths. Polar Biology 11:213218.CrossRefGoogle Scholar
Arnaud, P. M., and Hain, S. 1992. Quantitative distribution of the shelf and slope molluscan fauna (Gastropoda, Bivalva) of the eastern Weddell Sea. Polar Biology 12:103109.CrossRefGoogle Scholar
Berg, L. S. 1934. Uber die amphiboreale (discontinuierliche) Verbreitung der Meeresfauna in der Nordlichen Hemisphare. Zoogeographica 2:393409.Google Scholar
Bigelow, H. B., and Schroeder, W. C. 1953. Fishes of the western North Atlantic, Pt. 2: sawfishes, guitarfishes, skates, and rays. Memoir, Sears Foundation for Marine Research, Yale University.Google Scholar
Bigelow, H. B., and Schroeder, W. C. 1965. Notes on a small collection of rajids from the subantarctic region. Limnology and Oceanography 10(Suppl. 2):3949.CrossRefGoogle Scholar
Briggs, J. C. 1974. Marine zoogeography. McGraw-Hill, New York.Google Scholar
Cappetta, H. 1980. Les selaciens du Cretace superieur du Liban. II: Batoides. Paleontographica Abt. A. 168:149229.Google Scholar
Cappetta, H. 1987. Handbook of paleoichthyology, Chondrichthyes II: Mesozoic and Cenozoic elasmobranchii. Fischer Verlag, New York.Google Scholar
Compagno, L. J. V. 1990. Sharks. Pp. 8185in Gon, and Heemstra, 1990.Google Scholar
Compagno, L. J. V., Ebert, D. A., and Smale, M. J. 1989. Guide to the sharks and rays of southern Africa. New Holland Publishers, London.Google Scholar
DeWitt, H. H. 1971. Coastal and deep-water benthic fishes of the Antarctic. American Geographical Society. Antarctic Map Folio Series, folio 15:110.Google Scholar
Eastman, J. T. 1991. The fossil and modern fish faunas of Antarctica: evolution and diversity. Pp. 116130in Prisco, G., Maresca, B., and Tota, B., eds. Biology of Antarctic fish. Springer, New York.CrossRefGoogle Scholar
Eastman, J. T., and Grande, L. 1989. Evolution of the Antarctic fish fauna with emphasis on the Recent notothenioids. Pp. 241252in Crame, J. A., ed. Origins and evolution of the antarctic biota. Geological Society Special Publication no. 47.Google Scholar
Eastman, J. T., and Grande, L. 1991. Late Eocene gadiform (Teleostei) skull from Seymour Island, Antarctic Peninsula. Antarctic Science 3:8795.CrossRefGoogle Scholar
Ebert, D. A., Cowley, P. D., and Compagno, L. J. V. 1991. A preliminary investigation of the feeding ecology of skates (Batoidea: Rajidae) off the west coast of southern Africa. South African Journal of Marine Science 10:7181.CrossRefGoogle Scholar
Eschmeyer, W. N., Herald, E. S., and Hammann, H. 1983. A field guide to Pacific coast fishes of North America. Peterson Field Guide Series. Houghton Mifflin, Boston.Google Scholar
Foster, T. D. 1984. The marine environment. Pp. 345372in Laws, R. M., ed. Antarctic ecology, Vol. 2. Academic Press, London.Google Scholar
Gon, O., and Heemstra, P. C., eds. 1990. Fishes of the Southern Ocean. Smith Institute of Ichthyology, Grahamstown, South Africa.CrossRefGoogle Scholar
Gordon, J. D. M., and Duncan, J. A. R. 1989. A note on the distribution and diet of deep-water rays (Rajidae) in an area of the Rockall Trough. Journal of the Marine Biological Association of the United Kingdom 69:655658.CrossRefGoogle Scholar
Grande, L. 1985. The use of paleontology in systematics and biogeography, and a time control refinement for historical biogeography. Paleobiology 11:234243.CrossRefGoogle Scholar
Grande, L., and Eastman, J. T. 1986. A review of Antarctic ichthyofaunas in the light of new fossil discoveries. Palaeontology 29:113137.Google Scholar
Grover, C. A. 1972. Population differences in the swell shark Cephaloscyllium ventriosum. California Fish and Game 58:191197.Google Scholar
Hacunda, J. S. 1981. Trophic relationships among demersal fishes in an area of the Gulf of Maine. Fishery Bulletin 79:775788.Google Scholar
Herman, J. 1986. Additions to the Eocene fish fauna of Belgium, 8. A new rajiform from the Ypresian-Paniselian. Tertiary Research 8:3342.Google Scholar
Hubbs, C. L. 1952. Antitropical distribution of fishes and other organisms. Proceedings of the Seventh Pacific Science Congress 3:324330.Google Scholar
Hulley, P. A. 1972. The origin, interrelationships and distribution of Southern African Rajidae (Chondrichthyes: Batoidea). Annals of the South African Museum 60:1103.Google Scholar
Ishiyama, R. 1958. Studies on the rajid fishes (Rajidae) found in the waters around Japan. Journal of Shimonoseki College of Fisheries 7:193394.Google Scholar
Jerzmanska, A. 1991. First articulated teleost fish from the Paleogene of west Antarctica. Antarctic Science 3:309316.CrossRefGoogle Scholar
Kennett, J. P., and Barker, P. F. 1990. Latest Cretaceous to Cenozoic climate and oceanographic developments in the Weddell Sea, Antarctica: an ocean drilling perspective. Pp. 937960in Barker, P. F. and Kennett, J. P., eds. Proceedings of the Ocean Drilling Project, Scientific Results, 113. Ocean Drilling Program, College Station, Texas.Google Scholar
Kock, K.-H. 1985. Marine habitats—Antarctic fish. Pp. 173192in Bonner, W. N. and Walton, D. W. H., eds. Key environments—Antarctica. Pergamon, New York.Google Scholar
Lawver, L. A., Royer, J.-Y., Sandwell, D. T., and Scotese, C. R. 1990. Evolution of the Antarctic continental margins. Pp. 533539in Thomson, M. R. A., Crame, J. A., and Thomson, J. W., eds. Geological evolution of Antarctica. Proceedings of the Fifth International Symposium on Antarctic Earth Science. Cambridge University Press, Cambridge.Google Scholar
Lawver, L. A., Gahagan, L. M., and Coffin, M. F. 1992. The development of paleoseaways around Antarctica. Antarctic Research Series 56:730.Google Scholar
Long, D. J. 1991. Fossil cutlassfish (Perciformes: Trichiuridae) teeth from the La Meseta Formation (Eocene), Seymour Island, Antarctic Peninsula. PaleoBios 13:36.Google Scholar
Long, D. J. 1992a. The shark fauna from the La Meseta Formation (Eocene), Seymour Island, Antarctic Peninsula. Journal of Vertebrate Paleontology 12:1132.CrossRefGoogle Scholar
Long, D. J. 1992b. An Eocene wrasse (Perciformes; Labridae) from Seymour Island. Antarctic Science 4:235237.CrossRefGoogle Scholar
Long, D. J. 1992c. Paleoecology of Eocene Antarctic sharks. Antarctic Research Series 56:131139.Google Scholar
Long, D. J. 1993a. Late Miocene and early Pliocene fish assemblages from the north central coast of Chile. Tertiary Research 14:117126.Google Scholar
Long, D. J. 1993b. Preliminary list of the marine fishes and other vertebrate remains from the late Pleistocene Palos Verdes Sand Formation at Costa Mesa, Orange County, California. PaleoBios 15:913.Google Scholar
Lutjeharms, J. R. E. 1990. The oceanography and fish distribution of the Southern Ocean. Pp. 627in Gon, and Heemstra, 1990.Google Scholar
McEachran, J. D., Boesch, D. F., and Musick, J. A. 1976. Food division within two sympatric species-pairs of skates (Pisces: Rajidae). Marine Biology 35:301317.CrossRefGoogle Scholar
McEachran, J. D., and Miyake, T. 1990a. Phylogenetic interrelationships of skates: a working hypothesis (Chondrichthyes, Rajoidei). Pp. 285304in Pratt, et al. 1990.Google Scholar
McEachran, J. D., and Miyake, T. 1990b. Zoogeography and bathymetry of skates (Chondrichthyes, Rajoidea). Pp. 305326in Pratt, et al. 1990.Google Scholar
Menzies, R. J., George, R. Y., and Rowe, G. T. 1973. Abyssal environment and ecology of the world oceans. Wiley, New York.Google Scholar
Miller, R. G. 1987. Origins and pathways possible for the fishes of the Antarctic Ocean. Proceedings of the Fifth Congress of European Ichthyologists, Stockholm, pp. 373380.Google Scholar
Nakaya, K., and Shirai, S. 1992. Fauna and zoogeography of deep-benthic chondrichthyan fishes around the Japanese Archipelago. Japanese Journal of Ichthyology 39:3748.CrossRefGoogle Scholar
Permitin, Y. E. 1970. The consumption of krill by Antarctic fishes. Pp. 177182in Holdgate, M. W., ed. Antarctic ecology, Vol. I. Academic Press, London.Google Scholar
Permitin, Y. E., and Tarverdiyeva, M. I. 1972. Feeding of some species of Antarctic fishes in the South Georgia Island area. Journal of Ichthyology 12:104114.Google Scholar
Prasad, G. V. R., and Cappetta, H. 1993. Late Cretaceous selachians from India and the age of the Deccan Traps. Palaeontology 36:231248.Google Scholar
Pratt, H. L., Gruber, S. H., and Taniuchi, T., eds. 1990. Elasmobranchs as living resources: advances in the biology, ecology, systematics, and status of the fisheries. National Oceanic and Atmospheric Administration Technical Report, National Marine Fisheries Service 90, U.S. Department of Commerce.Google Scholar
Reif, W.-E., and Saure, C. 1987. Shark biogeography: vicariance is not even half the story. Neues Jahrbuch für Geologie und Paläntologie, Abhandlungen 175:117.Google Scholar
Richardson, M. D., and Hedgepeth, J. W. 1977. Antarctic softbottom, macrobenthic community adaptations to a cold, stable, highly productive, glacially affected environment. Pp. 181196in Llano, G. A., ed. Adaptations within Antarctic ecosystems. Proceedings of the Third SCAR Symposium on Antarctic Biology. Smithsonian Institution, Washington, D.C.Google Scholar
Robichaud, D. A., Elner, R. W., and Bailey, R. F. J. 1991. Differential selection of crab Chonoecetes opilio and Hyas spp. as prey by sympatric cod Gadus morhua and thorny skate Raja radiata. Fishery Bulletin 89:669680.Google Scholar
Rodhouse, P. G. 1990. Cephalopod fauna of the Scotia Sea at South Georgia: potential for commercial exploitation and possible consequences. Pp. 289298in Kerry, K. R., and Hempel, G., eds. Antarctic ecosystems. Ecological change and conservation. Springer, Berlin.CrossRefGoogle Scholar
Roper, C. F. E., Sweeny, M. J., and Nauen, C. E. 1984. Food and Agriculture Organization Species Catalogue, Vol. 3. Cephalopods of the World. An Annotated and Illustrated Catalogue of Species of Interest to Fisheries. F.A.O. Fisheries Synopsis 125:1227.Google Scholar
Sadler, P. M. 1988. Geometry and Stratification of uppermost Cretaceous and Paleogene units on Seymour Island, northern Antarctic Peninsula. Pp. 303320in Feldmann, R. M. and Woodburne, M. O., eds. Geology and Paleontology of Seymour Island, Antarctic Peninsula. Geological Society of America, Memoir169.CrossRefGoogle Scholar
Springer, S. 1971. Three species of skates (Rajidae) from the continental waters of Antarctica. Biology of the Antarctic seas IV, Antarctic research series. American Geophysical Union 17:110.Google Scholar
Springer, V. G. 1982. Pacific Plate Biogeography, with special reference to shorefishes. Smithsonian Contributions to Zoology 367:1182.CrossRefGoogle Scholar
Stehmann, M. 1986. Notes on the systematics of the Rajid genus Bathyraja and its distribution in the world oceans. Pp. 261268in Uyeno, T., Arai, R., Tanuichi, T., and Matsuura, K., eds. Indo-Pacific fish biology: proceedings of the Second International Conference on Indo-Pacific Fishes. Ichthyological Society of Japan, Tokyo.Google Scholar
Stehmann, M., and Burkel, D. L. 1989. Rajidae. Pp. 163196in Whitehead, P. J. P., Bauchot, M.-L., Hureau, J.-C., Nielsen, J., and Tortonese, E., eds. Fishes of the north-eastern Atlantic and the Mediterranean: Vol. 1. United Nations Educational, Scientific and Cultural Organizations, Paris.Google Scholar
Stehmann, M., and Burkel, D. L. 1990. Rajidae. Pp. 8697in Gon, and Heemstra, 1990.Google Scholar
Templeman, W. 1973. First records, description, distribution, and notes on the biology of Bathyraja richardsoni (Garrick) from the Northwest Atlantic. Journal Fisheries Research Board of Canada 30:18311840.CrossRefGoogle Scholar
Ward, D. J. 1984. Additions to the fish fauna of the English Paleogene. 5. A new species of Raja from the London Clay. Tertiary Research 6:6568.Google Scholar
Ward, D. J., and Grande, L. 1991. Chimaeroid fish remains from Seymour Island, Antarctic Peninsula. Antarctic Science 3:323330.CrossRefGoogle Scholar
Ward, D. J., and Wiest, R. L. Jr. 1990. A checklist of Paleocene and Eocene sharks and rays (Chondrichthyes) from the Pamunkey Group, Maryland and Virginia, USA. Tertiary Research 12:8188.Google Scholar
Welton, B. J. 1972. Fossil sharks in Oregon. The Ore Bin 34:161170.Google Scholar
Welton, B. J., and Zinsmeister, W. J. 1980. Eocene neoselachians from the La Meseta Formation, Seymour Island, Antarctic Peninsula. Contributions in Science, Natural History Museum of Los Angeles County 329:110.Google Scholar
Williams, R. 1988. Antarctic fish. Australian Natural History 22:518521.Google Scholar
Woodburne, M. O., and Zinsmeister, W. J. 1984. The first land mammal from Antarctica and its biogeographic implications. Journal of Paleontology 58:913948.Google Scholar
Zinsmeister, W. J. 1982. Late Cretaceous-early Tertiary molluscan biogeography of the southern circum-Pacific. Journal of Paleontology 56:84102.Google Scholar
Zorzi, G. D., and Anderson, M. E. 1990. Summary of records of the deep-water skates Raja (Amblyraja) badia Garman, 1899 and Bathyraja abyssicola (Gilbert, 1896), in the eastern North Pacific. Pp. 389390in Pratt, et al. 1990.Google Scholar