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Myriapodous arthropods from the Viséan of East Kirkton, West Lothian, Scotland

Published online by Cambridge University Press:  03 November 2011

William A. Shear
Affiliation:
Department of Biology, Hampden-Sydney College, Hampden-Sydney, Virginia 23943, U.S.A.

Abstract

Several specimens of myriapodous arthropods have been discovered at the early Carboniferous East Kirkton site near Bathgate, West Lothian, Scotland. None is particularly well preserved, but they are the earliest known Carboniferous myriapods, filling the time gap between the Old Red Sandstone of the early Devonian and the abundant myriapod faunas of the late Carboniferous (Pennsylvanian). One of the specimens, a milliped, provides the earliest evidence for both ozopores (repugnatorial gland openings) and spiracles. A second milliped specimen has some characteristics of the living Order Glomeridesmida, and hence of Enghoff's (1990) ‘ground plan’ of chilognathan millipeds. Aspects of these forms and a third suggest a novel early Carboniferous fauna clearly different from both earlier and later ones. The taxon name ‘Myriapoda’ should be abandoned, since it covers a group now recognised as paraphyletic. ‘Archipolypoda’ is probably synonymous with Order Euphoberiida, Class Diplopoda.

Type
Research Article
Copyright
Copyright © Royal Society of Edinburgh 1993

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References

Almond, J. E. 1985. The Silurian-Devonian fossil record of the Myriapoda. PHIL TRANS ROY SOC LONDON (B) 309, 227–37.Google Scholar
Almond, J. E. 1986. Les Arthropleurides du Stephanien de Monceau-les-Mines, France. BULL SOC NAT HIST AUTUN 115, 5960.Google Scholar
Boudreaux, H. B. 1979. Arthropod phytogeny, with Special Reference to Insects. New York: Wiley-Interscience.Google Scholar
Brauckmann, C. & Kemper, M. 1985. Ein Tausendfüssler (Myriapoda: ?Archipolypoda) aus dem Namurian B von Hagen-Vorhalle (unt. Ober-Karbon; West-Deutschland). DORTMUNDER BEITR. LANDESKDE. NATURWISS. MITT. 19, 65–9.Google Scholar
Burke, J. J. 1973. Notes on the morphology of Acantherpestes (Myriapoda, Archypolypoda [sic]) with the description of a new species from the Pennsylvanian of West Virginia. KIRTLANDIA 17, 124.Google Scholar
Burke, J. J. 1979. A new milliped genus, Myriacantherpestes (Diplopoda, Archipolypoda) and a new species, Myriacantherpestes bradebirksi, from the English coal measures. KIRTLANDIA 30, 130.Google Scholar
Dohle, W. 1980. Sind de Myriapoden eine monophyletische Gruppe? Eine Diskussion der Verwandtschaftsbeziehungen der Antennaten. ABH NATURWISS VER HAMBURG (NF) 23, 45104.Google Scholar
Dohle, W. 1988. Myriapoda and the ancestry of insects. Manchester: British Myriapod Group and Manchester Polytechnic.Google Scholar
Dzik, J. 1975. Spirobolid millipedes from the late Cretaceous of the Gobi Desert, Mongolia. PALAEONTOL POLONICA 33, 1724.Google Scholar
Dzik, J. 1981. An early Triassic milliped from Siberia and its evolutionary significance. N JB GEOL PALÄONT MH 1981, 395404.Google Scholar
Eisner, T., Alsop, D., Hicks, K. & Meinwald, J.. 1978. Defensive secretions of millipeds. In Bettini, S. (Ed.) Arthropod venoms, 4172. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Enghoff, H. 1984. Phylogeny of millipedes—a cladistic analysis. Z F ZOOL SYSTEMATIK EVOLUTIONSFORSCH 22, 826.CrossRefGoogle Scholar
Enghoff, H. 1990. The ground-plan of chilognathan millipeds (external morphology). PROC INTERNAT CONGR MYRIAPODOL 7, 121.Google Scholar
Fritsch, A. 1899. Fauna der Gaskohle und der Kalksteine der Permformation Böhmens, 4. Prague: Privately published.Google Scholar
Gupta, A. P. (Ed.) 1979. Arthropod Phylogeny. New York: Van Nostrand Reinhold.Google Scholar
Hannibal, J. T. & Farago, K. M. 1984. Fossil millipeds and centipeds: a review (abstract). PROC INTERNAT CONGR MYRIAPODOL 6, 21.Google Scholar
Hannibal, J. T. & Feldmann, R. M. 1981. Systematics and functional morphology of oniscomorph millipeds (Arthropoda: Diplopoda) from the Carboniferous of North America. J PALEONTOL 54, 730–46.Google Scholar
Hannibal, J. T. & Feldmann, R. M. 1988. Millipeds from Late Paleozoic limestones at Hamilton, Kansas. KANSAS GEOL SURV GUIDEBOOK SER 6, 125–31.Google Scholar
Hennig, W. 1981. Insect Phylogeny. Translated and edited by Pont, A. C., revisionary notes by Schlee, D.. New York: John Wiley and Sons.Google Scholar
Hoffman, R. L. 1963. New genera and species of upper Paleozoic Diplopoda. J PALEONTOL 37, 167–74.Google Scholar
Hoffman, R. L. 1969. Myriapoda, exclusive of Insecta. In Moore, R. (Ed.) Treatise on invertebrate paleontology R572-R606. Lawrence: Geological Survey of America and University of Kansas.Google Scholar
Hopkin, S. P. & Read, H. J. 1992. The biology of millipedes. Oxford: Oxford University Press.CrossRefGoogle Scholar
Jeram, A. J., Selden, P. A. & Edwards, D. 1991. Land animals in the Silurian: arachnids and myriapods from Shropshire, England. SCIENCE 250, 658–61.CrossRefGoogle Scholar
Kraus, O. 1974. On the morphology of Palaeozoic diplopods. SYMP ZOOL SOC LONDON 32, 1322.Google Scholar
Kukalová-Peck, J. 1992. The Uniramia do not exist: the ground plan of the Pterygota as revealed by Permian Diaphanopterodea from Russia (Insecta: Palaeodictyopteroidea). CAN J ZOOL 70, 236–55.CrossRefGoogle Scholar
Mundel, P. 1979. The centipedes (Chilopoda) of the Mazon Creek. In Nitecki, M. (Ed.) Mazon Creek fossils, 361–78. New York: Academic Press.CrossRefGoogle Scholar
Rolfe, W. D. I. 1969. Arthropleurida. In Moore, R. (Ed.) Treatise on invertebrate paleonotology, R607-R625. Lawrence: Geological Survey of America and University of Kansas.Google Scholar
Rolfe, W. D. I. 1988. Early life on land-the East Kirkton discoveries. EARTH SCI CONSERV 25, 22–8.Google Scholar
Rolfe, W. D. I., Durant, G. P., Baird, W. J., Chaplin, C., Paton, R. L. & Reekie, R. J. 1994. The East Kirkton Limestone, Viséan, West Lothian, Scotland: introduction and stratigraphy. TRANS R SOC EDINBURGH: EARTH SCI 84, 177188.Google Scholar
Santiago-Blay, J. A. & Poinar, G. O. Jr. 1992. Millipeds from Dominican Amber, with the description of two new species (Diplopoda, Siphonophoridae). ANN ENTOMOL SOC AMER 85, 363–9.CrossRefGoogle Scholar
Scudder, S. H. 1882. Archipolypoda: a subordinal type of spined myriapods from the Carboniferous formation. MEM BOSTON SOC NAT HIST 3, 143–82, pls 10-13.Google Scholar
Secretan, S. 1980. Les arthropodes du Stephanien de Montceau-les-Mines. BULL. SOC. D'HIST. NAT. AMIS MUS. D'AUTUN 94, 2335.Google Scholar
Shear, W. A. & Bonamo, P. M. 1988. Devonobiomorpha, a new order of centipeds (Chilopoda) from the Middle Deveoian of Gilboa, New York State, USA, and the phylogeny of centiped orders. AMER MUS NOV 2927, 130.Google Scholar
Shear, W. A., Hannibal, J. T. & Kukalová-Peck, J. 1992. Terrestrial arthropods from Upper Pennsylvanian rocks at the Kinney Brick Quarry, New Mexico. In Zidek, J. (Ed.) Geology and Paleontology of the Kinney Brick Quarry, Late Pennsylvanian, Central New Mexico. MEXICO BUR MINES MINER RES BULL 138, 135–41.Google Scholar
Shear, W. A. & Kulkalová-Peck, , 1991. The ecology of Paleozoic terrestrial arthropods: the fossil evidence. CAN J ZOOL 68, 1807–34.CrossRefGoogle Scholar