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The oldest record of Eschrichtiidae (Cetacea: Mysticeti) from the Late Pliocene, Hokkaido, Japan

Published online by Cambridge University Press:  14 July 2015

Hiroto Ichishima
Affiliation:
Fukui Prefectural Dinosaur Museum, Terao 51-11, Muroko, Katsuyama, Fukui 911-8601, Japan,
Eri Sato
Affiliation:
Hamochi Elementary School, Hongo 559-1, Hamochi, Sado, Niigata 952-0504, Japan,
Tsumoru Sagayama
Affiliation:
Department of Marine Geoscience, Geological Survey of Hokkaido, Chikko 3-1, Otaru, Hokkaido 047-0008, Japan,
Masaichi Kimura
Affiliation:
Hokkaido University of Education, Ainosato 5-3, Kita-ku, Sapporo, Hokkaido 002-8502, Japan,

Abstract

A new eschrichtiid mysticete was recovered from the Late Pliocene Yuchi Formation, Teshio Town, Hokkaido, Japan. The specimen is relatively well preserved, comprising a posterior part of the skull, periotics and tympanic bullae, several incomplete cervical and thoracic vertebrae, ribs, and forelimb elements including scapula, humerus, ulna, and several phalanges. Its small size, unfused epiphyses of vertebrae and long bones (humerus, radius, and ulna) indicate that the individual is physically immature. It is identified as eschrichtiid based on diagnostic characters, including paired occipital tuberosities, large occipital condyles, the posteriorly concave exoccipital lateral to the occipital condyle, the cochlear portion of the periotic extending anteromedially, the relatively small and somewhat triangular anterior process of the periotic, and the proportionally large vertebral foramen relative to the vertebral body. Because all verified eschrichtiids are of Pleistocene age, the Teshio eschrichtiid significantly extends the temporal range of the group.

Type
Research Article
Copyright
Copyright © The Paleontological Society 

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References

Adegoke, J. A., Árnason, Ú., and Widegren, B. 1993. Sequence organization and evolution, in all extant whalebone whales, of a DNA satellite with terminal chromosome localization. Chromosoma, 102:382388.CrossRefGoogle ScholarPubMed
Akiba, F. 1999. Neodenticula seminae and Proboscia curvirostris (diatom) from the Yuchi Formation of the Tenpoku area, northwestern Hokkaido, and their biostratigraphic implications. Journal of Geological Society of Japan, 105:733736. (In Japanese with English abstract) Google Scholar
Akiba, F., and Ichinoseki, T. 1983. The Neogene micro- and chronostratigraphies in Hokkaido—special reference to those of the southwestern part of the Kushiro Coal Field Area, eastern Hokkaido, Japan. Journal of Japanese Association of Petroleum Technology, 48:4961. (In Japanese with English abstract) Google Scholar
Akiba, F., Hiramatsu, C., Tsoy, I. B., Ogasawara, K., and Amano, K. 2000. Diatom biostratigraphy and geologic age of the Maruyama and Kurasi formations, southern Sakhalin, and their correlation to the Neogene of the Tenpoku area, Hokkaido. Journal of Geography, 109:203217. (In Japanese with English abstract) CrossRefGoogle Scholar
Akishima, Chigaku Kenkyukai (a research group). 1966. Scientific Report of Akishima Whale. Akishima City Board of Education, Tokyo, 22 p. (In Japanese) Google Scholar
Andrews, R. C. 1914. The California gray whale (Rhachianectes glaucus Cope). Memoirs of the American Museum of Natural History, 1:229287.Google Scholar
Árnason, Ú., and Best, P. B. 1991. Phylogenetic relationships within the Mysticeti (whalebone whales) based upon studies of highly repetitive DNA in all extant species. Hereditas, 114:263269.CrossRefGoogle Scholar
Árnason, Ú., and Gullberg, A. 1994. Relationship of baleen whales established by cytochrome b gene sequence. Nature, 367:726728.CrossRefGoogle ScholarPubMed
Árnason, Ú., and Gullberg, A. 1996. Cytochrome b nucleotide sequences and the identification of five primary lineages of extant cetaceans. Molecular Biology and Evolution, 13(2):407417.CrossRefGoogle ScholarPubMed
Árnason, Ú., and Ledje, C. 1993. The use of highly repetitive DNA for resolving cetacean and pinniped phylogenies, p. 7480. In Szalay, F. S., Novacek, M. J., and McKenna, M. C. (eds.), Mammal Phylogeny: Placentals. Springer-Verlag, New York.CrossRefGoogle Scholar
Árnason, Ú., Ledje, C., and Widegren, B. 1993. Cetacean mitochondrial DNA control region: sequences of all extant baleen whales and two sperm whale species. Molecular Biology and Evolution, 10(5):960970.Google ScholarPubMed
Barnes, L. G., and Mcleod, S. A. 1984. The fossil record and phyletic relationships of gray whales, p. 332. In Jones, M. L., Swartz, S. L., and Leatherwood, S. (eds.), The Gray Whale: Eschrichtius robustus . Academic Press, New York.CrossRefGoogle Scholar
Braham, H. W. 1984. Distribution and migration of gray whales in Alaska, p. 249266. In Jones, M. L., Swartz, S. L., and Leatherwood, S. (eds.), The Gray Whale: Eschrichtius robustus . Academic Press, New York.CrossRefGoogle Scholar
Brandt, J. F. 1873. Untersuchungen über die fossilen und subfossilen Cetaceen Europa's. Mit Beiträgen von Van Beneden, Cornalia, Gastaldi, Quenstedt und Paulson nebst einem geologischen Anhange von Barbot de Marny, G. v. Helmersen, A. Geobel und Th. Fuchs. Mémoires de l'Académie Impériale des Sciences, St. Petersbourg, series 7, 20(1):iviii + 1–372.Google Scholar
Brisson, M. J. 1762. Regnum animale in classes IX distributum, sive synopsis methodica sistens generalem animalium distributionem in classes IX & duarum primarum classium, quadripedum scilicet & cetaceorum, particularum, divisionem in ordines, sectiones, gebera, & species. Editio altera auctior [= Edition 2]. Theodorum Haak, Lugduni Batavorum, Leiden, 296 p.Google Scholar
de Muizon, C. 1987. The affinities of Notocetus vanbenedeni, an Early Miocene platanistoid (Cetacea, Mammalia) from Patagonia, southern Argentina. American Museum Novitates, 2904:127.Google Scholar
Dooley, A. C. Jr., Fraser, N. C., and Luo, Z.-X. 2004. The earliest known member of the rorqual-gray whale clade (Mammal, Cetacea). Journal of Vertebrate Paleontology, 24(2):453463.CrossRefGoogle Scholar
Ellerman, J. R., and Morrison-Scott, J. C. S. 1951. Checklist of Palaearctic and Indian Mammals, 1758–1946. British Museum (Natural History), London, 810 p.Google Scholar
Flower, W. H. 1864. Notes on the skeletons of whales in the principal museums of Holland and Belgium, with descriptions of two species apparently new to science. Proceedings of the Zoological Society of London, 1864:384420.Google Scholar
Fordyce, R. E., and Barnes, L. G. 1994. The evolutionary history of whales and dolphins. Annual Review of Earth and Planetary Sciences, 22:419455.CrossRefGoogle Scholar
Fujie, T., and Uozumi, S. 1957. On the historical change of the molluscan fauna in Neogene deposits of Hokkaido, Japan, Pt. 1, General characters and distribution of the molluscan fauna. Cenozoic Research (Shinseidai no kenkyu), 23:3237. (In Japanese) Google Scholar
Gatesy, J., Matthee, C., DeSalle, R., and Hayashi, C. 2002. Resolution of a supertree/supermatrix paradox. Systematic Biology, 51(4):652664.CrossRefGoogle ScholarPubMed
Geisler, J. H., and Luo, Z. 1996. The petrosal and inner ear of Herpetocetus sp. (Mammalia: Cetacea) and their implications for the phylogeny and hearing of archaic mysticetes. Journal of Paleontology, 70(6):10451066.CrossRefGoogle Scholar
Geisler, J. H., and Sanders, A. E. 2003. Morphological evidence for the phylogeny of Cetacea. Journal of Mammalian Evolution, 10:23129.CrossRefGoogle Scholar
Gray, J. E. 1846. On the British Cetacea. Annals and Magazine of Natural History, 1(17):8285.CrossRefGoogle Scholar
Gray, J. E. 1864a. On the cetacea which have been observed in the seas surrounding the British islands. Proceedings of the Zoological Society of London, 1864:195250.Google Scholar
Gray, J. E. 1864b. Notes on the whalebone-whales; with a synopsis of the species. Annals and Magazine of Natural History, 3(14):345353.Google Scholar
Gray, J. E. 1865. Notice of a new whalebone whale from the coast of Devonshire, proposed to be called Eschrichtius robustus . Proceedings of the Zoological Society of London, 1865:4043. (With the same title and content, this article was published in the same year in Annals and Magazine of Natural History, 3(15):492–495.) CrossRefGoogle Scholar
Hata, M., Ueda, Y., Matsuda, T., and Sugaiyama, T. 1969. Geological Map of Japan 1:200,000, Teshio. Geological Survey of Japan.Google Scholar
Iwaki Educational and Cultural Corporation. 1989. Excavation Report of Fossil Whales from Yotsukura-cho, Iwaki City. Board of Education, Iwaki City, Fukushima Prefecture, Japan, 33 p. (In Japanese) Google Scholar
Jousé, A. P. 1959. Osnovnie etapi razbitija flori morskikh diatomovikh vodoroslei (Diatomeae) na Dalbnem Vostok V. tretichnom i chetvertichnom periodakh. Baton Zhurnal, 44:4455.Google Scholar
Kanno, S., Noda, H., Amano, K., Majima, R., and Ito, M. 1980. Preliminary report on the geology and paleontology of the environs of Teshio, Hokkaido, Pt. 1. Human Culture and Environmental Studies in Northern Hokkaido, 1:521, pls. 1–4. (In Japanese) Google Scholar
Kasuya, T. 1973. Systematic consideration of recent toothed whales based on the morphology of tympano-periotic bone. Scientific Reports of the Whales Research Institute, 25:1103.Google Scholar
Kellogg, A. R. 1928. The history of whales—their adaptation to life in the water. Quarterly Review of Biology, 3:2976,174–208.CrossRefGoogle Scholar
Kellogg, A. R. 1934. A new cetothere from the Modelo Formation at Los Angeles, California. Carnegie Institution of Washington Publication, 447:83104, pl. 1.Google Scholar
Kikuchi, T. 1991. Geology of the Tama River bed, from which the tusk of Stegodon aurorae was recovered [Tamagawa kasho, Akebonozou Sesshi kaseki sanshutsuchi no Chishitsu]. Bulletin of the Hinocity Furusato Museum, 1:2542. (In Japanese) Google Scholar
Kimura, M. 1992. The Study of the Fossil Whale from Shintotsukawa Town. Koukoku Press, Sapporo, 56 p. (In Japanese) Google Scholar
Kimura, T., and Ozawa, T. 2002. A new cetothere (Cetacea: Mysticeti) from the early Miocene of Japan. Journal of Vertebrate Paleontology, 22(3):684702.CrossRefGoogle Scholar
Koizumi, I. 1981. Investigation of diatom fossils in Chikubetsu river and Toikanbetsu routes, p. 1011. In Tanai, T. (ed.), Circular: Neogene biostratigraphy of Hokkaido, Hokkaido University, 1. (In Japanese) Google Scholar
Lacépède, B. G. E. 1804. Histoire Naturelle des Cétacées. Paris, 412 p.CrossRefGoogle Scholar
Lilljeborg, W. 1861. Hvalben funna i jorden på Gräsön i Roslagen i Sverige. Föredrag vid Naturforskaremotet i Köpenhamn, 1860:599616.Google Scholar
Linnaeus, C. 1758. Systema Naturae per Regna Tria Naturae (editio decima, reformata). Volume 1. Regnum Animale. Laurentii Salvii, Stockholm, 824 p.Google Scholar
Maiya, S. 1979. Embetsu area, Hokkaido, p. 58. In Tsuchi, R. (ed.), Fundamental data on Japanese Neogene bio- and chronostratigraphy. IGCP-114 National Working Group of Japan. (In Japanese) Google Scholar
Masuda, F., Amano, K., Katsura, Y., and Ito, M. 1981. Shallow marine facies of Neogene and Quaternary strata at the Northwest and Southeast parts of Teshio Town in Hokkaido. Human Culture and Environmental Studies in northern Hokkaido, 2:141. (In Japanese) Google Scholar
Mchedlidze, G. A. 1984. Fossilized Whale from the Miocene Deposits in the Environs of the Village of Otradnaya (Northern Caucasus). “Metsniereba” Press, Tbilisi, 64 p.Google Scholar
McKenna, M. C. 1987. Molecular and morphological analysis of higher-level mammalian interrelationships, p. 5593. In Patterson, C. (ed.), Molecules and Morphology in Evolution: Conflict or Compromise? Cambridge University Press, Sydney.Google Scholar
Mcleod, S. A., Whitmore, F. C. Jr., and Barnes, L. G. 1993. Evolutionary relationships and classification, p. 4570. In Burns, J. J., Montague, J. J., and Cowles, C. J. (eds.), The Bowhead Whale. Society for Marine Mammalogy Special Publication, 2.Google Scholar
Mead, J. G., and Mitchell, E. D. 1984. Atlantic gray whales, p. 3353. In Jones, M. L., Swartz, S. L., and Leatherwood, S. (eds.), The Gray Whale: Eschrichtius robustus . Academic Press, New York.CrossRefGoogle Scholar
Nikaido, M., Hamilton, H., Makino, H., Goto, M., Kanda, N., Patene, L. A., Kato, H., Fordyce, R. E., and Okada, N. 2002. Phylogenetic reconstruction and detection of an ancient incomplete lineage sorting among mysticetes (baleen whales) based on SINE insertion analysis. Abstracts of the Secondary Adaptation to Life in Water, 34.Google Scholar
Nishiwaki, M., and Kasuya, T. 1970. Recent record of gray whale in the adjacent waters of Japan and a consideration on its migration. Scientific Reports of the Whales Research Institute, 22:2937.Google Scholar
Noda, H., Amano, K., Majima, R., Ito, M., and Kanno, S. 1982. Preliminary report on the geology and paleontology of the environs of Teshio, Hokkaido, Pt. 3, Pliocene molluscan fossils from Bakkai. Human Culture and Environmental Studies in Northern Hokkaido, 3:115. (In Japanese) Google Scholar
Noda, H., Amano, K., Majima, R., Ito, M., and Kanno, S. 1983. Preliminary report on the geology and paleontology of the environs of Teshio, Hokkaido, Pt. 4. Human Culture and Environmental Studies in Northern Hokkaido, 4:112. (In Japanese) Google Scholar
Oishi, M., and Hasegawa, Y. 1994. Diversity of Pliocene mysticetes from eastern Japan. The Island Arc, 3:436452.CrossRefGoogle Scholar
Oishi, M., Fujii, H., and Tagusari, S. 2001. Pliocene cetaceans from Shiriuchimachi, Hachinohe City, Northeast Japan (Pt. 2). Research Report of the “Fossil Hachinohe Whales,” II:722. Hachinohe Children's Science Museum.Google Scholar
Oka, T., and Igarashi, Y. 1993. Plio–Pleistocene in the Toikanbetsu tectonic basin, northern Hokkaido—sedimentary facies and pollen stratigraphy. Journal of the Geological Society of Japan, 99(5):365389. (In Japanese with English abstract) Google Scholar
Omura, H. 1975. Osteological study of the minke whale from the Antarctic. Scientific Reports of the Whales Research Institute, 27:136, pls. 1–16.Google Scholar
Omura, H., Ichihara, T., and Kasuya, T. 1970. Osteology of pygmy blue whale with additional information on external and other characteristics. Scientific Reports of the Whales Research Institute, 22:127.Google Scholar
Perrin, W. F. 1975. Variation of spotted and spinner porpoises (genus Stenella) in the eastern Pacific and Hawaii. Bulletin of the Scripps Institution of Oceanography, 21:1206.Google Scholar
Rice, D. W. 1967. Cetaceans, p. 291324. In Anderson, S. and Jones, J. K. Jr. (eds.), Recent Mammals of the World. Ronald Press, New York.Google Scholar
Rice, D. W., and Wolman, A. A. 1971. The life history and ecology of the gray whales (Eschrichtius robustus). The American Society of Mammalogists Special Publication, 3.CrossRefGoogle Scholar
Sagayama, T. 1993. Geologic age of molluscan fossil Fortipecten takahashii (Yokoyama)-bearing horizon from northern Japan to southern Sakhalin. Prof. Jiro Ishii Memorial volume, p. 169176. (In Japanese) Google Scholar
Sagayama, T. 2003. Geologic age of boundary part between Embetsu Formation–Koetoi Formation and Yuchi Formation, northern Hokkaido, Japan—Rubeshube River and Kaminukanan River routes. Journal of the Geological Society of Japan, 6:310322, pl. 1. (In Japanese with English abstract) Google Scholar
Sanderson, S. L., and Wassersug, R. 1993. Convergent and alternative designs for vertebrate suspension feeding, p. 37112. In Hanken, J. and Hall, B. K. (eds.), The skull. Volume 3. Functional and Evolutionary Mechanism. The University of Chicago Press, Chicago.Google Scholar
Sato, E., Kimura, M., and Furusawa, H. 1999. A fossil gray whale (Cetacea; Eschrichtidae [sic]) from the late Pliocene Yuchi Formation, Teshio-cho, northern Hokkaido, p. 1849. In Kimura, M. (ed.), Reports on the Excavation of the Fossil Whale from Teshio Town. Teshio Board of Education, Sapporo. (In Japanese) Google Scholar
Satoguchi, Y., Nagahashi, Y., Kurokawa, K., and Yoshikawa, S. 1999. Tephrostratigraphy of the Pliocene to lower Pleistocene formations in central Honshu Japan. Earth Science (Chikyu Kagaku), 53:275290.Google Scholar
Slijper, E. J. 1936. Die Cetaceen, vergleichend anatomisch und systematisch. Capita Zoologica, 6:ixv + 1–590.Google Scholar
Sumich, J. L., Goff, T., and Perryman, W. L. 2001. Growth of two captive gray whale calves. Aquatic Mammals, 27(3):231233.Google Scholar
Suzuki, A., Kimura, M., Sato, E., Sagayama, T., and Uchida, J. 1999. Geology around Teshio-cho, northern Hokkaido, p. 517. In Kimura, M. (ed.), Reports on the Excavation of the Fossil Whale from Teshio Town. Teshio Board of Education, Sapporo. (In Japanese) Google Scholar
Takano, S. 1994. Stratigraphy of the Lower Pleistocene Kazusa Group in the Tama Hills, central Japan. Journal of Geological Society of Japan, 100(9):675691.Google Scholar
Taru, H., and Hasegawa, Y. 2002. The Plio–Pleistocene fossil mammals from the Kasumi and Tama Hills. Memoirs of the National Science Museum, Tokyo, 38:4356.Google Scholar
True, F. W. 1904. The whalebone whales of the western North Atlantic, compared with those occurring in European waters, with some observations on the species of the North Pacific. Smithsonian Contributions to Knowledge, 33:1331.Google Scholar
Uemura, K. 1925. Research report of Haboro Coal Field in Tenpoku district. Geological Survey of Japan Mineral Research Report, 36, 40 p. (In Japanese) Google Scholar
Ujiié, H., Saito, T., Kent, D. V., Thompson, P. R., Okada, H., Klein, G. De V., Koizumi, I., Happer, H. E. Jr., and Sato, T. 1977. Biostratigraphy, paleomagnetism and sedimentology of late Cenozoic sediments in northwestern Hokkaido, Japan. Bulletin of the National Science Museum, series C (Geology and Paleontology), 3:49102, pls. 1–7.Google Scholar
van Deinse, A. B., and Junge, G. C. A. 1937. Recent and older finds of the California gray whale in the Atlantic. Temminckia, 2:161188, pls. 4–11.Google Scholar
Watanabe, H. 1914. Research report of Soya Coal Field in Kitami district. Geological Survey of Japan Mineral Research Report, 19, 68 p. (In Japanese) Google Scholar
Watson, A. G., and Fordyce, R. E. 1993. Skeleton of two minke whales, Balaenoptera acutorostrata, stranded on the south-east coast of New Zealand. New Zealand Natural Sciences, 20:114.Google Scholar
Wheeler, J. F. G. 1930. The age of fin whales at physical maturity, with a note on multiple ovulations. Discovery Reports, 2:403434, pl. 5.Google Scholar
Whitmore, F. C. Jr. 1994. Neogene climatic change and the emergence of the modern whale fauna of the North Atlantic Ocean. Proceedings of the San Diego Society of Natural History, 29:223227.Google Scholar
Winge, H. 1921. A review of the interrelationships of the Cetacea. Smithsonian Miscellaneous Collections, 72(8):197.Google Scholar
Wolman, A. A. 1985. Gray whale, Eschrichtius robustus (Lilljeborg, 1861), p. 6790. In Ridgway, S. H. and Harrison, R. (eds.), Handbook of Marine Mammals. Volume 3. The Sirenians and Baleen Whales. Academic Press, San Diego.Google Scholar
Yamaguchi, S., and Suda, Y. 1981. Geological Map of Japan 1: 200,000, Esashi. Geological Survey of Japan.Google Scholar
Yanagisawa, Y., and Akiba, F. 1998. Refined Neogene diatom biostratigraphy for the Northwest Pacific around Japan, with an introduction of cord numbers for selected diatom biohorizons. Journal of Geological Society of Japan, 104:395414.Google Scholar
Yokoyama, M. 1930. Tertiary Mollusca from south Karafto. Tokyo Imperial University, Faculty of Science Journal, 2(11):407418.Google Scholar