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A late Miocene astropectinid (Echinodermata, Asteroidea) and associated ichnofossils from Liessel, province of Noord-Brabant, the Netherlands

Published online by Cambridge University Press:  24 March 2014

J.W.M. Jagt*
Affiliation:
Natuurhistorisch Museum Maastricht, de Bosquetplein 6-7, NL-6211 KJ Maastricht, the Netherlands
R.H.B. Fraaije
Affiliation:
Oertijdmuseum De Groene Poort, Bosscheweg 80, NL-5283 WB Boxtel, the Netherlands
B.W.M. van Bakel
Affiliation:
Oertijdmuseum De Groene Poort, Bosscheweg 80, NL-5283 WB Boxtel, the Netherlands
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Abstract

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A fragmentary and partially dissociated arm of an astropectinid starfish, assigned to the genus Astropecten Gray, 1840, is recorded from decalcified and limonitised, fine-grained sandstone concretions and slabs of late Miocene (Tortonian) age, collected from the former gravel and sand pit ‘de Hoogdonk’ near Liessel, province of Noord-Brabant. Added are two examples of the ichnofossil Asteriacites lumbricalis von Schlotheim, 1820, both preserved in convex hyporelief and co-occurring with other, indeterminate traces. Although astropectinids have been recorded previously from Miocene and Pliocene deposits in the Netherlands, the present is the first record of fossilised traces of starfish.

Type
Geo(Im)pulse
Copyright
Copyright © Stichting Netherlands Journal of Geosciences 2009

References

Bell, C.M., 2004. Asteroid and ophiuroid trace fossils from the Lower Cretaceous of Chile. Palaeontology 47: 5166.Google Scholar
Bertling, M., Braddy, S.J., Bromley, R.G., Demathieu, G.R., Genise, J., Mikuláš, R., Nielsen, J.K., Nielsen, K.S.S., Rindsberg, A.K., Schlirf, M. & Uchman, A., 2006. Names for trace fossils: a uniform approach. Lethaia 39: 265286.Google Scholar
Binder, H., 2002. Asteroidea aus dem Karpatium des Korneuburger Beckens (Untermiozän; Niederösterreich). In: Sovis, W. & Schmid, B. (eds): Das Karpat des Korneuburger Beckens, Teil 2. Beiträge zur Paläontologie 27: 317323.Google Scholar
Blake, D.B., 1973. Ossicle morphology of some Recent asteroids and description of some west American fossil asteroids. University of California Publications in Geological Sciences 104: iv + 159.Google Scholar
Blake, D.B., 1989. Asteroidea: functional morphology, classification and phylogeny. In: Jangoux, M. & Lawrence, J.M. (eds): Echinoderm Studies 1. A.A. Balkema (Rotterdam/Brookfield): 179223.Google Scholar
Blake, D.B., 1990. Adaptive zones of the class Asteroidea (Echinodermata). Bulletin of marine Science 46: 701718.Google Scholar
Breton, G., Fily, G., Cousin, R. & Maurizot, P., 2001. Asteriacites lumbricalis von Schlotheim, 1820. Trace de repos ou d’enfouissement d’ophiure préservée dans le Calcaire de Creully, Bathonien moyen du Calvados (Normandie). Bulletin trimestriel de la Société géologique de Normandie et Amis Muséum du Havre 87 (2000): 9798.Google Scholar
Bromley, R.G., 1996. Trace fossils. Biology, taphonomy and applications (Second edition). Chapman & Hall (London): 361 pp.Google Scholar
Chamberlain, C.K., 1971. Morphology and ethology of trace fossils from the Ouachita Mountains, southeast Oklahoma. Journal of Paleontology 45: 212246.Google Scholar
Dam, G., 1990. Taxonomy of trace fossils from the shallow marine Lower Jurassic Neill Klinter Formation, East Greenland. Bulletin of the Geological Society of Denmark 38: 119144.Google Scholar
Ekdale, A.A., Bromley, R.G. & Pemberton, S.G., 1984. Ichnology. The use of trace fossils in sedimentology and stratigraphy. Society of Economic Petroleum Mineralogists, Short Course 15: 1317.Google Scholar
Ensom, P.C., 1984. Examples of the trace fossil Asteriacites sp. or tool marks from the Starfish Bed (Middle Lias) near Thorncombe Beacon. Proceedings of the Dorset Natural History and Archaeological Society 105(1983): 165168.Google Scholar
Forbes, E., 1839. On the Asteriadae of the Irish Sea. Memoirs of the Wernerian Natural History Society 8: 113130.Google Scholar
Gibert, J.M. de, Domènech, R. & Martinell, J., 2004. An ethological framework for animal bioerosion trace fossils upon mineral substrates with proposal of a new class, fixichnia. Lethaia 37: 429437.Google Scholar
Gibert, J.M. de & Ekdale, A.A., 2002. Ichnology of a restricted epicontinental sea, Arapien Shale, Middle Jurassic, Utah, USA. Palaeogeography, Palaeoecology, Palaeoclimatology 183: 275286.Google Scholar
Gray, J.E., 1840. A synopsis of the genera and species of the class Hypostoma (Asterias Linn.). Annals and Magazine of Natural History (1) 6: 175–184, 275290.Google Scholar
Heller, C., 1858. Über neue fossile Stelleriden. Sitzungsberichte der kaiserlichen Akademie der Wissenschaften, mathematisch-naturwissenschaftliche Classe (I) 28: 155170.Google Scholar
Herman, J. & Marquet, R., 2007. Observations paléontologiques réalisées dans les terrains néogènes belges de 1971 à 2004 entre Kallo et Doel, Port d’Anvers, Rive gauche (Flandre-Orientale, Belgique). Le Miocène du Deurganckdok à Doel. Memoirs of the Geological Survey of Belgium 54: 148.Google Scholar
Jagt, J.W.M., 1991. Early Miocene luidiid asteroids (Echinodermata, Asteroidea) from Winterswijk-Miste (the Netherlands). Contributions to Tertiary and Quaternary Geology 28: 3543.Google Scholar
Jagt, J.W.M. & Codrea, V., in press. A goniasterid starfish (Echinodermata, Asteroidea) preserved in a mid-Miocene rhyolitic ignimbrite, northwest Romania. Acta Geologica Polonica.Google Scholar
Janssen, R., 1972. Beiträge zur Kenntnis der Bryozoa, Vermes, Crustacea u. Echinodermata aus dem nordwestdeutschen Mittel- und Obermiozän. Veröffentlichungen aus dem Überseemuseum Bremen A4: 71108.Google Scholar
Kaczmarska, G., 1987. Asteroids from the Korytnica Basin (Middle Miocene; Holy Cross Mountains, central Poland). Acta Geologica Polonica 37: 131144.Google Scholar
Kroh, A., 2007. Climate changes in the Early to Middle Miocene of the Central Paratethys and the origin of its echinoderm fauna. Palaeogeography, Palaeoclimatology, Palaeoecology 253: 185223.Google Scholar
Kutscher, M., 1980. Die Echinodermen des Oberoligozäns von Sternberg. Zeitschrift für geologische Wissenschaften 8: 221239.Google Scholar
Kutscher, M., 1985. Die Echinodermen des Magdeburger Grünsandes (Mittel-Oligozän). Abhandlungen und Berichte zu Naturkunde und Vorgeschichte (Magdeburg) 12: 314.Google Scholar
Larsen, J.G., 2005. Sporfossiler. Natur og Museum 4: 135.Google Scholar
Lewarne, G.C., 1964. Starfish traces from the Namurian of County Clare, Ireland. Palaeontology 7: 508513.Google Scholar
Linnaeus, C., 1758. Systema naturae, per regna tria naturae, secundum classes, ordines, genera, species cum characteribus, differentiis, synonymis, locis. Editio decima, reformata 1(6). Laurentii Salvii (Holmiae): iii + 824 pp.Google Scholar
Mángano, M.G. & Buatois, L.A., 2004. Ichnology of Carboniferous tide-influenced environments and tidal flat variability in the North American Midcontinent. In: McIlroy, D. (ed.): The application of ichnology to palaeoenvironmental and stratigraphic analysis. Geological Society London, Special Publications 228: 157178.Google Scholar
Mortensen, T., 1977. Handbook of the echinoderms of the British Isles. W. Backhuys (Leiden): ix + 471 pp.Google Scholar
Nosowska, E., 1997. Asteroids from the Nawodzice Sands (Middle Miocene; Holy Cross Mountains, central Poland). Acta Geologica Polonica 47: 225241.Google Scholar
Pennant, T., 1777. British zoology, IV. Crustacea, Mollusca, Testacea 4. J. Walker (London): vii + 136 pp.Google Scholar
Peters, N., 2009. Brabant tussen walvissen en mastodonten. Fossielen uit Liessel. Nationaal Beiaard- en Natuurmuseum Asten/Oertijdmuseum De Groene Poort (Asten/Boxtel): 1110.Google Scholar
Pickerill, R.K., 1994. Nomenclature and taxonomy of invertebrate trace fossils. In: Donovan, S.K. (ed.): The palaeobiology of trace fossils. Wiley (Chichester): 342.Google Scholar
Radwański, A. & Wysocka, A., 2001. Mass aggregation of Middle Miocene spinecoated echinoids Echinocardium and their integrated eco-taphonomy. Acta Geologica Polonica 51: 295316.Google Scholar
Radwański, A. & Wysocka, A., 2004. A farewell to Swiniary sequence of mass-aggregated, spine-coated echinoids Psammechinus and their associates (Middle Miocene; Holy Cross Mountains, Central Poland). Acta Geologica Polonica 54: 381399.Google Scholar
Rioult, M. & Bulow, M., 1988. Pentasteriacites nov. ichnogenus, trace de repos d’une étoile de mer fossilisée dans le Calcaire d’Auberville (Oxfordien moyen, Normandie). Bulletin de la Société linnéenne de Normandie 112/113: 115120.Google Scholar
Savrda, C.E., 2007. Taphonomy of trace fossils. In: Miller, W. III (ed.): Trace fossils. Concepts, problems, prospects. Elsevier (Amsterdam): 92109.Google Scholar
Seilacher, A., 1953. Studien zur Palichnologie. II. Die fossilen Ruhespuren (Cubichnia). Neues Jahrbuch für Geologie und Paläontologie, Abhandlungen 98: 87124.Google Scholar
Smith, A.B. & Crimes, T.P., 1983. Trace fossils formed by heart urchins – a study of Scolicia and related traces. Lethaia 16: 7992.Google Scholar
Verrill, A.E., 1899. Revision of certain genera and species of starfish with descriptions of new forms. Transactions of the Connecticut Academy of Arts and Sciences 10: 145234.Google Scholar
Von Schlotheim, E.F., 1820. Die Petrefaktenkunde auf ihrem jetzigen Standpunkte, durch die Beschreibung seiner Sammlung versteinerter und fossiler Überreste des Thier- und Pflanzenreiches der Vorwelt erläutert. Becker (Gotha): lxii + 437 pp.Google Scholar
Wienberg Rasmussen, H., 1951. An Oligocene asteroid from Denmark. Meddelelser fra Dansk geologisk Forening 11: 588589.Google Scholar