Hostname: page-component-78c5997874-t5tsf Total loading time: 0 Render date: 2024-11-09T08:12:50.043Z Has data issue: false hasContentIssue false

Star-shaped trace fossil and Phymatoderma from Neogene deep-sea deposits in central Japan: probable echiuran feeding and fecal traces

Published online by Cambridge University Press:  11 October 2016

Kentaro Izumi
Affiliation:
Center for Environmental Biology and Ecosystem Studies, National Institute for Environmental Studies, 16-2 Onogawa, Tsukuba, Ibaraki 305-8506, Japan 〈[email protected]
Kazuko Yoshizawa
Affiliation:
Department of Earth and Planetary Science, The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-0033, Japan 〈[email protected]

Abstract

A co-occurrence of the ichnogenus Phymatoderma and a star-shaped horizontal trace fossil was discovered from Neogene deep-marine deposits (Misaki Formation, central Japan), and is described herein for the first time. Phymatoderma consists of a straight to slightly curved tunnel that shows first- or second-order branches. The tunnels are 5.30–27.25 mm in diameter and are filled with ellipsoidal pellets. The relatively well-preserved star-shaped trace fossil is a large horizontal structure (~18 cm×19 cm) that consists of at least 10 spokes with diameters ranging from 11.49–20.96 mm. As compared to modern analogous surface-feeding traces produced by abyssal echiuran worms and their burrow morphology, it is highly likely that the star-shaped trace fossil and Phymatoderma found from the Misaki Formation are feeding and fecal traces of ancient deep-sea echiurans, respectively. Difference in preservation potential between surface and subsurface traces may result in rare occurrence of star-shaped trace fossils as compared to Phymatoderma. Microscopic observation of the pelletal infill of Phymatoderma also reveals that the trace-maker fed on organic debris and microorganisms such as diatoms and radiolaria.

Type
Articles
Copyright
Copyright © 2016, The Paleontological Society 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Akimoto, K., Uchida, E., and Oda, M., 1991, Paleoeovironmental reconstruction by benthic foraminifers from middle to late Miocene in the Misaki Formation, southern Miura Peninsula: Chikyu Monthly, v. 13, p. 2430 [in Japanese].Google Scholar
Alldredge, A.L., and Cohen, Y., 1987, Can microscale chemical patches persist in the sea? Microelectrode study of marine snow fecal pellets: Science, v. 235, p. 689691.Google Scholar
Armstrong, R.A., Lee, C., Hedges, J., Honjo, I.S., and Wakeham, S.G., 2001, A new, mechanistic model of organic carbon fluxes in the ocean: based on the quantitative association of POC with ballast minerals: Deep Sea Research, v. 49, p. 219236.Google Scholar
Berggren, W.A., Kent, D.V., Swisher, C.C., and Aubry, M.P., 1995, A revised Cenozoic geochronology and chronostratigraphy, in Berggren, W.A., Kent, D.V., Aubery, M.P., and Hardenbol, J., eds., Geochronology, Time Scales and Global Stratigraphic Correlation, Tulsa, Society for Sedimentary Geology, Special Publication 54, p. 129212.Google Scholar
Bromley, R.G., 1996, Trace Fossils: Biology, Taphonomy and Applications, London, Chapman and Hall, 361 p.Google Scholar
Brongniart, A.T., 1849, Tableau des generes de végétaux fossils considérés sous le point de vue de leur classification botanique et de leur distribution géologique: Dictionnaire Universel Histoire Naturelle, v. 13, p. 127.Google Scholar
Buatois, L.A., and Mángano, M.G., 2011, Ichnology: Organism–Substrate Interactions in Space and Time, New York, Cambridge University Press, 370 p.Google Scholar
Clifton, H.E., and Thompson, J.K., 1978, Macaronichnus segregatis: a feeding structure of shallow marine polychaetes: Journal of Sedimentary Petrology, v. 48, p. 12931302.Google Scholar
de Vaugelas, J., 1989, Deep-sea lebensspuren: remarks on some echiuran traces in the Porcupine Seabight, northeast Atlantic: Deep-Sea Research, v. 36, p. 975982.Google Scholar
Ekdale, A., and Berger, W.H., 1978, Deep-sea ichnofacies: modern organism traces on and in pelagic carbonates of the western equatorial Pacific: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 23, p. 263278.Google Scholar
Elders, C.A., 1975, Experimental approaches in neoichnology, in Frey, R.W., ed., The Study of Trace Fossils, New York, Springer-Verlag, p. 513536.Google Scholar
Fu, S., 1991, Funktion, Verhalten und Einteilung fucoider und lophocteniider Lebensspuren: Courier Forschung-Institut Senckenberg, v. 135, p. 179.Google Scholar
Furnas, M.J., 1990, In situ growth rates of marin phytoplankton: approaches to measurement, community and species growth rates: Journal of Plankton Research, v. 12, p. 11171151.Google Scholar
Fürsich, F.T., and Bromley, R.G., 1985, Behavioural interpretation of a rosette spreite trace fossil: Dactyloidites ottoi (Geinitz): Lethaia, v. 18, p. 199207.Google Scholar
Gage, J.D., and Tyler, P.A., 1991, Deep-Sea Biology, A Natural History of Organisms at the Deep-Sea Floor, Cambridge, Cambridge University Press, 504 p.Google Scholar
Gaillard, C., 1991, Recent organism traces and ichnofacies on the deep-sea floor off New Caledonia, southwestern Pacific: Palaios, v. 6, p. 302315.Google Scholar
Gibert, J.M, de, Martinell, J., and Domènech, R., 1995, The rosette feeding trace fossil Dactyloidites ottoi (Geinitz) from the Miocene of Catalonia: Geobios, v. 28, p. 769776.Google Scholar
Hall, J., 1886, Note on some obscure organisms in the roofing slate of Washington County, New York: New York State Museum of Natural History, Annual Report, v. 39, p. 1160.Google Scholar
Herring, P., 2002, The Biology of the Deep Ocean, Oxford, Oxford University Press, 328 p.Google Scholar
Honjo, S., Manganini, S.J., Krishfield, R.A., and Francois, R., 2008, Particulate organic carbon fluxes to the ocean interior and factors controlling the biological pump: a synthesis of global sediment trap programs since 1983: Progress in Oceanography, v. 76, p. 217285.Google Scholar
Hüneke, H., and Henrich, R., 2011, Pelagic sedimentation in modern and ancient oceans, in Hüneke, H., and Mulder, T., eds., Deep-Sea Sediments, Amsterdam, Elsevier, p. 215352.Google Scholar
Izumi, K., 2012, Formation process of the trace fossil Phymatoderma granulata in the Lower Jurassic black shale (Posidonia Shale, southern Germany) and its paleoecological implications: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 353–355, p. 116122.Google Scholar
Izumi, K., 2013, Geochemical composition of faecal pellets as an indicator of deposit-feeding strategies in the trace fossil Phymatoderma : Lethaia, v. 46, p. 496507.Google Scholar
Izumi, K., and Uchman, A., 2015, Occurrence of faecal pellet-filled simple and composite burrows in cold seep carbonates: A glimpse of a complex benthic ecosystem: Comment: Marine Geology, v. 364, p. 6567.Google Scholar
Izumi, K., Rodríguez-Tovar, F.J., Piñuela, L., and García-Ramos, J.C., 2014, Substrate-independent feeding mode of the ichnogenus Phymatoderma from the Lower Jurassic shelf-sea deposits of central and western Europe: Sedimentary Geology, v. 312, p. 1930.Google Scholar
Jones, D., and Thompson, A.I., 1977, Echiura from the Pennsylvanian Essex Fauna of northern Illinois: Lethaia, v. 10, p. 317325.Google Scholar
Kanie, Y., and Hattori, M., 1991, Report of the symposium on ‘Chronology and paleoenvironmental aspects of the Miura Group, Central Japan’ held at the 97th annual meeting of the Geological Society of Japan in 1990: The Journal of the Geological Society of Japan, v. 97, p. 849–864 [in Japanese with English abstract].Google Scholar
Kanie, Y., Okada, H., Sasahara, Y., and Tanaka, H., 1991, Calcareous nannoplankton age and correlation of the Neogene Miura Group between the Miura and Boso Peninsulas, Southern-Central Japan: The Journal of the Geological Society of Japan, v. 97, p. 135155 [in Japanese with English abstract].Google Scholar
Kepkay, P.E., 1994, Particle aggregation and the biological activity of colloids: Marine Ecology Progress Series, v. 109, p. 293304.Google Scholar
Kitazato, H., 1997, Paleogeographic change in Central Honshu, Japan, during the Cenozoic in relation to the collision of the Izu-Ogasawara arc with the Honshu arc: Island Arc, v. 6, p. 144157.Google Scholar
Kitchell, J., Kitchell, J.F., Johnson, G.L., and Hunkins, K.L., 1978, Abyssal traces and megafauna: comparison of productivity, diversity and density in the Arctic and Antarctic: Paleobiology, v. 4, p. 171180.Google Scholar
Klass, C., and Archer, D.E., 2002, Association of sinking organic matter with various types of mineral ballast in the deep sea: implication for the rain ratio: Global Geochemical Cycles, v. 16, p. 1116.Google Scholar
Kodama, K., Oka, S., and Mitsunahi, T., 1980, Geology of the Misaki District, Tokyo, Geological Survey of Japan, Quadrangle series, 93 p.Google Scholar
Kotake, N., 1989, Paleoecology of the Zoophycos producers: Lethaia, v. 22, p. 327341.Google Scholar
Kotake, N., 1990, Mode of ingestion and egestion of the Chondrites and Zoophycos producers: The Journal of the Geological Society of Japan, v. 96, p. 859868 [in Japanese with English abstract].Google Scholar
Kotake, N., 1991, Packing process for the filling material in Chondrites : Ichnos, v. 1, p. 277285.Google Scholar
Kotake, N., 1992, Deep-sea echiurans: possible producers of Zoophycos : Lethaia, v. 25, p. 311316.Google Scholar
Kotake, N., 1995, The trace fossil Zoophycos: A fossil record of excretory behavior controlled by foraging behavior of the producer: The Journal of the Geological Society of Japan, v. 101, p. XVXVI [in Japanese].Google Scholar
Lee, I.T., and Ogawa., Y., 1998, Bottom-current deposits in the Miocene–Pliocene Misaki Formation, Izu forearc area, Japan: Island Arc, v. 7, p. 315329.Google Scholar
Levinton, J.S., 1989, Deposit feeding and coastal oceanography, in Lopez, G., Taghon, G., and Levinton, J., eds., Ecology of Marine Deposit Feeders, New York, Springer-Verlag, p. 123.Google Scholar
Lima, J.H.D., and Netto, R.G., 2012, Trace fossils from the Permian Teresina Formation at Cerro Caveiras (S Brazil): Revista Brasileira de Paleontologia, v. 15, p. 522.Google Scholar
Lopez, G., and Levinton, J.S., 1987, Ecology of deposit-feeding animals in marine sediments: The Quarterly Review of Biology, v. 62, p. 235260.Google Scholar
Margalef, R., 1979, Life-forms of phytoplankton as survival alternations in an unstable environment: Oceanologica Acta, v. 1, p. 493509.Google Scholar
Mayer, L.M., 1989, The nature and determination of non-living sedimentary organic matter as a food source for deposit feeders, in Lopez, G., Taghon, G., and Levinton, J., eds., Ecology of Marine Deposit Feeders, New York, Springer-Verlag, p. 98113.Google Scholar
Mazumdar, A., Joshi, R.K., and Kocherla, M., 2011, Occurrence of faecal pellet-filled simple and composite burrows in cold seep carbonates: A glimpse of a complex benthic ecosystem: Marine Geology, v. 289, p. 117121.Google Scholar
MillerW., Ш. W., Ш., 2011, A stroll in the forest of the fucoids: Status of Melatercichnus burkei Miller, 1991, the doctrine of ichnotaxonomic conservatism and the behavioral ecology of trace fossil variation: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 307, p. 109116.Google Scholar
MillerW., Ш. W., Ш., and Aalto, K.R., 1998, Anatomy of a complex trace fossil: Phymatoderma from Pliocene bathyal mudstone, northwestern Ecuador: Paleontological Research, v. 2, p. 266274.Google Scholar
MillerW., Ш. W., Ш., and Vokes, E.H., 1998, Large Phymatoderma in Pliocene slope deposits, Northwestern Ecuador: Associated ichnofauna, fabrication, and behavioral ecology: Ichnos, v. 6, p. 2345.Google Scholar
Nara, M., 1995, Rosselia socialis: a dwelling structure of a probable terebellid polychaete: Lethaia, v. 28, p 171178.Google Scholar
Nara, M., 2006, Reappraisal of Schaubcylindrichnus: A probable dwelling/feeding structure of a solitary funnel feeder: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 240, p. 439452.Google Scholar
Nickell, L.A., Atkinson, R.J.A., Hughes, D.J., Ansell, A.D., and Smith, C.J., 1994, Burrow morphology of the echiuran worm Maxmuelleria lankesteri (Echiura: Bonelliidae), and a brief review of burrow structure and related ecology of the Echiura: Journal of Natural History, v. 29, p. 871885.Google Scholar
Ohta, S., 1984, Star-shaped feeding traces produced by echiuran worms on the deep-sea floor of the Bay of Bengal: Deep Sea Research, v. 31, p. 14151432.Google Scholar
Olivero, E.B., and López Cabrera, M.I., 2010, Tasselia ordamensis: A biogenic structure of probable deposit-feeding and gardening maldanid polychaetes: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 292, p. 336348.Google Scholar
Olivero, E.B., Ponce, J.J., López Cabrera, M.I., and Martinioni, D.R., 2004, Phymatoderma granulata from the Oligocene–Miocene of Tierra del Fuego: Morphology and ethology, in Buatois, L.A., and Mángano, M.G., eds., Ichnia 2004—The First International Congress on Ichnology, Abstract Book: Trelew, Argentina, p. 63.Google Scholar
Pickerill, P.K., 1982, Glockerichnus, a new name for the trace fossil ichnogenus Glockeria Książkiewicz, 1968: Journal of Paleontology, v. 56, p. 816.Google Scholar
Seike, K., 2007, Palaeoenvironmental and palaeogeographical implications of modern Macaronichnus segregatis-like traces in foreshore sediments on the Pacific coast of Central Japan: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 252, p. 497502.Google Scholar
Seike, K., 2008, Burrowing behaviour inferred from feeding traces of the opheliid polychaete Euzonus sp. as response to beach morphodynamics: Marine Biology, v. 153, p. 11991206.Google Scholar
Seike, K., Yanagishima, S., Nara, M., and Sasaki, T., 2011, Large Macaronichnus in modern shoreface sediments: Identification of the producer, the mode of formation, and paleoenvironmental implications: Palaeogeography, palaeoclimatology, Palaeoecology, v. 311, p. 224229.Google Scholar
Seilacher, A., 2007, Trace Fossil Analysis, Berlin, Springer-Verlag, 226 p.Google Scholar
Simpson, S., 1957, On the trace fossil Chondrites : Quarterly Journal of the Geological Society, v. 112, p. 475499.Google Scholar
Soh, W., Taira, A., Ogawa, Y., Taniguchi, H., Pickering, K.L., and Stow, D.A., 1989, Submarine depositional process for volcaniclastic sediments in the Mio-Pliocene Misaki Formation, Miura Group, central Japan, in Taira, A., and Masuda, F., eds., Sedimentary Facies in the Active Plate Margin, Tokyo, Terra Scientific Publishing Company, p. 619630.Google Scholar
Stow, D.A.V., Taira, A., Ogawa, Y., Soh, W., Taniguchi, H., and Pickering, K.T., 1998, Volcaniclastic sediments, process interaction and depositional setting of the Mio-Pliocene Miura Group, SE Japan: Sedimentary Geology, v. 115, p. 351381.Google Scholar
Taniguchi, H., Ogawa, Y., and Soh, W., 1991, Tectonic development of the Izu arc and Proto-Izu Arc: Journal of Geography, Tokyo Geographical Society, v. 100, p. 514529.Google Scholar
Turner, J.T., 2002, Zooplankton fecal pellets, marine snow and sinking phytoplankton blooms: Aquatic Microbial Ecology, v. 27, p. 57102.Google Scholar
Uchman, A., and Gaździcki, A., 2010, Phymatoderma melvillensis isp. nov. and other trace fossils from the Cape Melville Formation (Lower Miocene) of King George Island, Antarctica: Polish Polar Research, v. 31, p. 8399.Google Scholar
Uchman, A., and Pervesler, P., 2007, Palaeobiological and palaeoenvironmental significance of the Pliocene trace fossil Dactyloidites peniculus : Acta Palaeontologica Polonica, v. 52, p. 799808.Google Scholar
von Schloteim, E.F., 1822, Nachträge zur Petrefactenkunde, Gotha, Becker, 100 p.Google Scholar
Wetzel, A., 2008, Recent bioturbation in the deep South China Sea: A uniformitarian ichnologic approach: Palaios, v. 23, p. 601615.Google Scholar
Wetzel, A., 2010, Deep-sea ichnology: Observations in modern sediments to interpret fossil counterparts: Acta Geologica Polonica, v. 60, p. 125138.Google Scholar
Wilmsen, M., and Niebuhr, B., 2014, The rosetted trace fossils Dactyloidites ottoi (Geinitz, 1849) from the Cenomanian (Upper Cretaceous) of Saxony and Bavaria (Germany): ichnotaxonomic remarks and palaeoenvironmental implications: Paläontologische Zeitschrift, v. 88, p. 123138.Google Scholar
Yamamoto, Y., Nidaira, M., Ohta, Y., and Ogawa, Y., 2009, Formation of chaotic rock units during primary accretion processes: Examples from the Miura-Boso accretionary complex, central Japan: Island Arc, v. 18, p. 496512.Google Scholar
Yoshida, S., Shibuya, H., Torii, M., and Sasajima, S., 1984, Post-Miocene clockwise rotation of the Miura Peninsula and its adjacent area: Journal of Geomagnetism and Geoelectricity, v. 36, p. 579584.Google Scholar