Three new bivalve genera from Triassic hydrocarbon seep deposits in southern Turkey

• Autorzy: Kiel S.
• Języki publikacji: EN

Abstrakty

EN

Three new bivalve genera and species are described from Upper Triassic hydrocarbon seep deposits from the Kasımlar shales in the Taurus Mountains in southern Turkey. Terzileria gregaria and Kasimlara kosuni belong to the carditiid family Kalenteridae, and Aksumya krystyni belongs to the anomalodesmatan superfamily Pholadomyoidae. A single specimen is described in open nomenclature as Kasimlara sp. due to its significantly more angular shell profile compared to K. kosuni. The kalenterids Terzileria and Kasimlara narrow the stratigraphic gap between two seep-inhabiting “modiomorphid” clades: the Silurian–Devonian Ataviaconcha and the Late Jurassic–Cretaceous Caspiconcha. This raises the questions whether these four genera are members of a single phylogenetic lineage that continuously inhabited deep-sea hydrocarbon seeps from the Silurian to the Cretaceous (the “single lineage hypothesis”), or are repeated offshoots of various lineages that convergently developed similar morphological adaptations to this habitat (the “repeated colonization hypothesis”). Aksumya represents the first anomalodesmatan genus that appears to be restricted to the seep environment, considering that all previous claims of seep-inhabiting anomalodesmatans are questionable.

• Wydawca: -
• Czasopismo: Acta Palaeontologica Polonica
• Rocznik: 2018
• Tom: 63
• Numer: 2
• Opis fizyczny: p.221-234,fig.,ref.

Twórcy

autor

Kiel S.

• Swedish Museum of Natural History, Department of Palaeobiology, Box 50007,10405 Stockholm, Sweden

Bibliografia

• Agassiz, L. 1842–1845. Études critiques sur les Molluscques Fossiles. Monographie des Myes. 287 pp. H. Wolprath, Neuchâtel.
• Ager, D.V., Gutnic, M., Juteau, T., and Monod, O. 1978. New early Mesozoic brachiopods from southern Turkey. Bulletin of the Mineral Research and Exploration Institute of Turkey 91: 59–75.
• Amano, K. and Jenkins, R.G. 2011. Fossil record of extant vesicomyid species from Japan. Venus 69: 163–176.
• Amano, K. and Kiel, S. 2007. Fossil vesicomyid bivalves from the North Pacific region. The Veliger 49: 270–293.
• Broili, F. 1903. Die Fauna der Pachycardientuffe der Seiser Alp. Palaeontographica 50: 145–227.
• Campbell, H.J. 1984. New records and taxa of Permian and Triassic fossils from New Caledonia and New Zealand. Alcheringa 8: 151–167.
• Campbell, K.A. and Bottjer, D.J. 1995. Brachiopods and chemosymbiotic bivalves in Phanerozoic hydrothermal vent and cold seep environments. Geology 23: 321–324.
• Chavan, A. 1969. Superfamily Carditacea Fleming, 1820. In: R.C. Moore (ed.), Treatise on Invertebrate Paleontology Part N, Mollusca 6, Bivalvia Volume 2, N543–N561. The Geological Society of America, Boulder and The University of Kansas, Lawrence.
• Chen, Y., Krystyn, L., Orchard, M.J., Lai, X.-L., and Richoz, S. 2015. A review of the evolution, biogstratigraphy, provincialism and diversity of Middle and early Late Triassic conodonts. Papers in Palaeontology 2: 235–263.
• Childress, J.J., Fisher, C.R., Brooks, J.M., Kennicutt, M.C.I., Bidigare, R.R., and Anderson, A.E. 1986. A methanotrophic marine molluscan (Bivalvia, Mytilidae) symbiosis: mussels fueled by gas. Science 233: 1306–1308.
• Covacevich, V., Pérez, E., and Escobar, F. 1991. Presencia del género Kalentera Marwick, 1953 (Mollusca: Bivalvia) en el Sinemuriano al Sur de Taltal, Chile. Sexto Congreso Geológico Chileno (Viña del Mar), Actas 1: 68–71.
• Dall, W.H. 1889. Reports on the results of dredging, under the supervision of Alexander Agassiz, in the Gulf of Mexico (1877–1878) and in the Caribbean Sea (1879–1880), by the U.S. Coast Survey steamer “Blake” XXIX. Report on the Mollusca. Part 2, Gastropoda and Scaphopoda. Bulletin of the Museum of Comparative Zoology, Harvard University 18: 1–492.
• Damborenea, S.E. 2004. Early Jurassic Kalentera (Bivalvia) from Argentina and its palaeobiologeographical significance. Ameghiniana 41: 185–198.
• Distel, D.L., Baco, A.R., Chuang, E., Morrill, W., Cavanaugh, C.M., and Smith, C.R. 2000. Do mussels take wooden steps to deep-sea vents? Nature 403: 725–726.
• Grant-Mackie, J.A. 1979. On a new Kalentera (Pelecypoda: Cypricardiacea) from the Upper Triassic of New Zealand. New Zealand Journal of Geology and Geophysics 3: 74–80.
• Gray, J.E. 1847. A list of the genera of Recent Mollusca, their synonyma and types. Proceedings of the Zoological Record of London 15: 129–219.
• Griffin, M. and Pastorino, G. 2006. Madrynomya bruneti n. gen. and sp. (Bivalvia: ?Modiomorphoidae): a Mesozoic survivor in the Tertiary of Patagonia? Journal of Paleontology 80: 272–282.
• Gutnic, M., Monod, O., Poisson, A., and Dumont, J.F. 1979. Géologie des Taurides occidentales (Turquie). Mémoir de la Société géologique de France (nouveau series) 137: 1–109.
• Harper, E.M., Dreyer, H., and Steiner, G. 2006. Reconstructing the Anomalodesmata (Mollusca: Bivalvia): morphology and molecules. Zoological Journal of the Linnean Society 148: 395–420.
• Hautmann, M. 2001. Die Muschelfauna der Nayband-Formation (Obertrias, Nor-Rhät) des östlichen Zentraliran. Beringeria 29: 3–181.
• Healey, M. 1908. The fauna of the Napeng-beds or the Rhaetic beds of upper Burma. Palaeontologia Indica, New Series II (4): 1–88.
• Hryniewicz, K., Amano, K., Jenkins, R.G., and Kiel, S. 2017a. Thyasirid bivalves from Cretaceous and Paleogene cold seeps. Acta Palaeontologica Polonica 62: 705–728.
• Hryniewicz, K., Jakubowicz, M., Belka, Z., Dopieralska, J., and Kaim, A. 2017b. New bivalves from a Middle Devonian methane seep in Morocco: the oldest record of repetitive shell morphologies among some seep bivalve molluscs. Journal of Systematic Palaeontology 15: 19–41.
• Irwin, H., Curtis, C., and Coleman, M. 1977. Isotopic evidence for source of diagenetic carbonates formed during burial of organic-rich sediments. Nature 269: 209–213.
• Jakubowicz, M., Hryniewicz, K., and Belka, Z. 2017. Mass occurrence of seep-specific bivalves in the oldest-known cold seep metazoan community. Scientific Reports 7: 14292.
• Jenkins, R.G., Kaim, A., Hikida, Y., and Kiel, S. 2018. Four new species of the Jurassic to Cretaceous seep-restricted bivalve Caspiconcha and implications for the history of chemosynthetic communities. Journal of Paleontology [published online, doi: 10.1017/jpa.2018.7]
• Jenkins, R.G., Kaim, A., Little, C.T.S., Iba, Y., Tanabe, K., and Campbell, K.A. 2013. Worldwide distribution of modiomorphid bivalve genus Caspiconcha in late Mesozoic hydrocarbon seeps. Acta Palaeontologica Polonica 58: 357–382.
• Johnson, S.B., Krylova, E.M., Audzijonyte, A., Sahling, H., and Vrijenhoek, R.C. 2017. Phylogeny and origins of chemosynthetic vesicomyid clams. Systematics and Biodiversity 15: 346–360.
• Johnson, S.B., Warén, A., Lee, R.W., Kano, Y., Kaim, A., Davis, A., Strong, E.E., and Vrijenhoek, R.C. 2010. Rubyspira, new genus and two new species of bone-eating deep-sea snails with ancient habits. Biological Bulletin 219: 166–177.
• Kaim, A., Hryniewicz, K., Little, C.T.S., and Nakrem, H.A. 2017. Gastropods from the Late Jurassic–Early Cretaceous seep deposits in Spitsbergen, Svalbard. Zootaxa 4329: 351–374.
• Kaim, A., Jenkins, R.G., and Warén, A. 2008. Provannid and provannid-like gastropods from Late Cretaceous cold seeps of Hokkaido (Japan) and the fossil record of the Provannidae (Gastropoda: Abyssochrysoidea). Zoological Journal of the Linnean Society 154: 421–436.
• Kaim, A., Jenkins, R.G., Tanabe, K., and Kiel, S. 2014. Mollusks from late Mesozoic seep deposits, chiefly in California. Zootaxa 3861: 401–440.
• Kase, T., Kurihara, Y., and Hagino, K. 2007. Middle Miocene chemosynthetic thraciid Nipponothracia gigantea (Shikama, 1968) from central Japan is a large lucinid bivalve (Lucinoidea; Mollusca). The Veliger 49: 294–302.
• Kelly, S.R.A., Blanc, E., Price, S.P., and Withham, A.G. 2000. Early Cretaceous giant bivalves from seep-related limestone mounds, Wollaston Forland, Northeast Greenland. In: E.M. Harper, J.D. Taylor, and J.A. Crame (eds.), The Evolutionary Biology of the Bivalvia. Geological Society of London, Special Publication 177: 227–246.
• Kenk, V.C. and Wilson, B.R. 1985. A new mussel (Bivalvia: Mytilidae) from hydrothermal vents in the Galapagos Rift Zone. Malacologia 26: 253–271.
• Kiel, S. 2013. Lucinid bivalves from ancient methane seeps. Journal of Molluscan Studies 79: 346–363.
• Kiel, S. 2015. Did shifting seawater sulfate concentrations drive the evolution of deep-sea vent and seep ecosystems? Proceedings of the Royal Society B 282: 20142908.
• Kiel, S. 2016. A biogeographic network reveals evolutionary links between deep sea hydrothermal vent and methane seep faunas. Proceedings of the Royal Society B 283: 20162337.
• Kiel, S. and Amano, K. 2013. The earliest bathymodiolin mussels: Evaluation of Eocene and Oligocene taxa from deep-sea methane seep deposits in western Washington State, USA. Journal of Paleontology 87: 589–602.
• Kiel, S. and Little, C.T.S. 2006. Cold seep mollusks are older than the general marine mollusk fauna. Science 313: 1429–1431.
• Kiel, S. and Taviani, M. 2017. Chemosymbiotic bivalves from Miocene methane-seep carbonates in Italy. Journal of Paleontology 91: 444–466.
• Kiel, S., Campbell, K.A., and Gaillard, C. 2010. New and little known mollusks from ancient chemosynthetic environments. Zootaxa 2390: 26–48.
• Kiel, S., Krystyn, L., Demirtaş, F., Koşun, E., and Peckmann, J. 2017. Late Triassic mollusk-dominated hydrocarbon-seep deposits from Turkey. Geology 45: 751–754.
• King, W. 1850. A monograph of the Permian fossils of England. Monograph of the Palaeontographical Society 3: xxxvii + 258.
• Koninck, L.G. de 1885. Faune du calcaire carbonifère de la Belgique. 5e partie: Lamellibranches. Annales du Musée royal d’Histoire naturelle de Belgique, Série Paléontologique 11: 1–283.
• Leanza, A.F. 1940. Myoconcha neuquena n. sp. del Lias de Piedra Pintada en el Neuquén. Notas del Museo de La Plata, Paleontología 5: 123–131.
• Likharev, B.K. 1925. Zur Frage über das Alter der Perm-Kalksteine der Onega-Dwina Wasserscheide. Mémoires de la Société Russe de Minéralogie 54: 109–152.
• Linnaeus, C. 1758. Systema naturæ per regna tria naturæ, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis,-locis. Vol. 1. Editio decima. 824 pp. Laurentius Salvius, Holmiae.
• Little, C.T.S. and Vrijenhoek, R.C. 2003. Are hydrothermal vent animals living fossils? Trends in Ecology and Evolution 18: 582–588.
• De Loriol, P. and Cotteau, G. 1868 Monographie paléontologique et géologique de l’étage portlandien du département de l’Yonne. Bulletin dela Société des Sciences historiques et naturelles le l’Yonne 1: 1–260.
• Lorion, J., Kiel, S., Faure, B.M., Masaru, K., Ho, S.Y.W., Marshall, B.A., Tsuchida, S., Miyazaki, J.-I., and Fujiwara, Y. 2013. Adaptive radiation of chemosymbiotic deep-sea mussels. Proceedings of the Royal Society B 280: 20131243.
• Lukeneder, S., Lukeneder, A., Harzhauser, M., İslamoğlu, Y., Krystyn, L., and Lein, R. 2012. A delayed carbonate factory breakdown during the Tethyan-wide Carnian Pluvial Episode along the Cimmerian terranes (Taurus, Turkey). Facies 58: 279–296.
• Marwick, J. 1953. Divisions and faunas of the Hokonui System (Triassic and Jurassic). New Zealand Geological Survey Palaeontological Bulletin 21: 1–141.
• Matos, S.A., Warren, L.V., Fürsich, F.T., Alessandretti, L., Assine, M.L., Riccomini, C., and Simoes, M.G. 2017. Paleoecology and paleoenvi ronments of Permian bivalves of the Serra Alta Formation, Brazil: Ordinary suspension feeders or Late Paleozoic Gondwana seep organisms? Journal of South American Earth Sciences 77: 21–41.
• Morris, N.J. and Dickins, J.M. 1991. Upper Palaeozoic anomalodesmatan Bivalvia. Bulletin of the British Museum (Natural History) Geology 47: 51–100.
• Murchison, R.I., Keyserling, A.F.M.L.N.A., Graf von, and de Verneuil, E. 1845. Géologie de la Russie d’Europe et des montagnes de l’Oural. 511 pp. J. Murray, London.
• Newell, N.D. 1957. Notes on certain primitive heterodont pelecypods. American Museum Novitates 1857: 1–14.
• Newell, N.D. 1969. Superfamily Pholadomyacea Gray, 1847. In: R.C. Moore (ed.), Treatise on Invertebrate Paleontology Part N, Mollusca 6, Bivalvia Vol. 2, N818–N843. The Geological Society of America and The University of Kansas, Lawrence.
• Peckmann, J. and Thiel, V. 2004. Carbon cycling at ancient methane-seeps. Chemical Geology 205: 443–467.
• Peckmann, J., Kiel, S., Sandy, M.R., Taylor, D.G., and Goedert, J.L. 2011. Mass occurrences of the brachiopod Halorella in Late Triassic methaneseep deposits, Eastern Oregon. Journal of Geology 119: 207–220.
• Peek, A.S., Feldman, R.A., Lutz, R.A., and Vrijenhoek, R.C. 1998. Cospeciation of chemoautotrophic bacteria and deep sea clams. Proceedings of the National Academy of Sciences of the USA 95: 9962–9966.
• Roemer, F.A. 1836–1839. Die Versteinerungen des norddeutschen OolithenGebirges. 218 pp. Hahn, Hannover.
• Saether, K.P., Little, C.T.S., Campbell, K.A., Marshall, B.A., Collins, M., and Alfaro, A.C. 2010. New fossil mussels (Bivalvia: Mytilidae) from Miocene hydrocarbon seep deposits, North Island, New Zealand, with general remarks on vent and seep mussels. Zootaxa 2577: 1–45.
• Sibuet, M. and Olu, K. 1998. Biogeography, biodiversity and fluid dependence of deep-sea cold-seep communities at active and passive margins. Deep-Sea Research II 45: 517–567.
• Sowerby, J. de C. 1824. The Mineral Conchology of Great Britain 5 (81): 99–114. Sherwood and Co., London.
• Sowerby, J. de C 1826. The Mineral Conchology of Great Britain 6 (87): 1–12. Sherwood and Co., London.
• Squires, R.L. and Goedert, J.L. 1991. New Late Eocene mollusks from loca lized limestone deposits formed by subduction-related methane seeps, southwestern Washington. Journal of Paleontology 65: 412–416.
• Taylor, J.D. and Glover, E.A. 2010. Chemosymbiotic bivalves. In: S. Kiel (ed.), The Vent and Seep Biota, 107–136. Springer, Heidelberg.
• Taylor, J.D., Williams, S.T., Glover, E.A., and Dyal, P. 2007. A molecular phylogeny of heterodont bivalves (Mollusca: Bivalvia: Heterodonta): new analyses of 18S and 28S rRNA genes. Zoologica Scripta 36: 587–606.
• Tekin, U.K. 1999. Biostratigraphy and systematics of late Middle to Late Triassic radiolarians from the Taurus Mountains and Ankara region, Turkey. Geologisch-Paläontologische Mitteilungen Innsbruck (Special Issue) 5: 1–296.
• Trechmann, C.T. 1917. The Trias of New Zealand. Quarterly Journal of the Geological Society of London 73: 165–246.
• Tunnicliffe, V. 1992. The nature and origin of the modern hydrothermal vent fauna. Palaios 7: 338–350.
• Tunnicliffe, V., Fowler, M.R., and McArthur, A.G. 1996. Plate tectonic history and hot vent biogeography. In: J.C. MacLeod, P.A. Tyler, and C.L. Walker (eds.), Tectonic, Magmatic, Hydrothermal and Biological Segmentation of Mid-Oceanic Ridges. Geological Society, Special Publication 118: 225–238.
• Van Dover, C.L. 2000. The Ecology of Deep-Sea Hydrothermal Vents. 424 pp. Princeton University Press, Princeton.
• de Verneuil, E. and Murchison, R.I. 1844. Note sur les équivalents du système permien en Europe, suivie d’un coup d’œil général sur l’ensemble de ses fossiles, et d’un tableau des espèces. Bulletin de la Société géologique de France, Série 2 1: 475–517.
• Vrijenhoek, R.C. 2013. On the instability and evolutionary age of deepsea chemosynthetic communities. Deep-Sea Research II 92: 189–200.

Identyfikatory

DOI

10.4202/app.00466.2018