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Climatic implications of latest Pleistocene and earliest Holocene mammalian sympatries in eastern Washington state, USA

Published online by Cambridge University Press:  20 January 2017

R. Lee Lyman
R. Lee Lyman*
Affiliation:
Department of Anthropology, 107 Swallow Hall, University of Missouri, Columbia, MO 65211, USA
*
*E-mail address:lymanr@missouri.edu
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Abstract

For more than fifty years it has been known that mammalian faunas of late-Pleistocene age are taxonomically unique and lack modern analogs. It has long been thought that nonanalog mammalian faunas are limited in North America to areas east of the Rocky Mountains and that late-Pleistocene mammalian faunas in the west were modern in taxonomic composition. A late-Pleistocene fauna from Marmes Rockshelter in southeastern Washington State has no modern analog and defines an area of maximum sympatry that indicates significantly cooler summers than are found in the area today. An earliest Holocene fauna from Marmes Rockshelter defines an area of maximum sympatry, including the site area, but contains a single tentatively identified taxon that may indicate slightly cooler than modern summers.

Keywords

Area of sympatryEastern Washington StateEquable climatesMarmes RockshelterNonanalog mammalian faunas
Type
Original Articles
Information
Quaternary Research , Volume 70 , Issue 3 , November 2008 , pp. 426 - 432
Copyright
University of Washington

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References

Aubry, K.B., (1984). The recent history and present distribution of the red fox in Washington. Northwest Science 58, 6979.Google Scholar
Bell, C.J., Lundelius, E.L. Jr., Barnosky, A.D., Graham, R.W., Lindsay, E.H., Ruez, D.R. Jr., Semken, H.A. Jr., Webb, S.D., Zakrzewski, R.J., (2004).The Blancan, Irvingtonian, and Rancholabrean mammal ages. Woodburne, M.O. Late Cretaceous and Cenozoic Mammals of North America Columbia Univ. Press, New York.232314.Google Scholar
Blair, W.F., (1958). Distributional patterns of vertebrates in the southern United States in relation to past and present environments. Hubbs, C.L. Zoogeography American Association for the Advancement of Science Publication 51, Washington, DC.433468.Google Scholar
Caulk, G.H., (1988). Examination of Some Faunal Remains from the Marmes Rockshelter Floodplain.. Unpublished Master of Arts thesis, Department of Anthropology, Washington State Univ., Pullman.Google Scholar
Dixon, S.L., Lyman, R.L., (1996). On the Holocene history of elk (Cervus elaphus) in eastern Washington. Northwest Science 70, 262272.Google Scholar
Falk, C.R., Semken, H.A. Jr.(1998). Taphonomy of rodent and insectivore remains in North American archaeological sites: selected examples and interpretations. Saunders, J.J., Styles, B.W., Baryshnikov, G.F. Quaternary Paleozoology in the Northern Hemisphere Illinois State Museum Scientific Papers 27, Springfield.285321.Google Scholar
FAUNMAP Working Group(1996). Spatial response of mammals to Late Quaternary environmental fluctuations. Science 272, 16011606.CrossRefGoogle Scholar
Fryxell, R., Keel, B.C., (1969). Emergency Salvage Excavations for the Recovery of Early Human Remains and Related Scientific Materials from the Marmes Rockshelter Archaeological Site, Southeastern Washington. Washington State Univ. Department of Anthropology, Final Report to the U.S. Army Corps of Engineers, Walla Walla, WA.Google Scholar
Fryxell, R., Bielicki, T., Daugherty, R.D., Gustafson, C.E., Irwin, H.T., Keel, B.C., (1968). A human skeleton from sediments of mid-Pinedale age in southeastern Washington. American Antiquity 33, 511515.CrossRefGoogle Scholar
Graham, R.W., (1985a). Response of mammalian communities to environmental changes during the late Quaternary. Diamond, J., Case, T.J. Community Ecology Harper and Row, New York.300313.Google Scholar
Graham, R.W., (1985b). Diversity and community structure of the late Pleistocene mammal fauna of North America. Acta Zoologica Fennica 170, 181192.Google Scholar
Graham, R.W., (1986). Plant–animal interactions and Pleistocene extinctions. Elliott, D.K. Dynamics of Extinction Wiley, New York.131154.Google Scholar
Graham, R.W., (1990). Evolution of new ecosystems at the end of the Pleistocene. Agenbroad, L.D., Mead, J.I., Nelson, L.W. Megafauna and Man: Discovery of America's Heartland. Mammoth Site of Hot Springs, South Dakota, Scientific Papers Vol. 1, 5460.Google Scholar
Graham, R.W., (1992). Late Pleistocene faunal changes as a guide to understanding the effects of greenhouse warming on the mammalian fauna of North America. Peters, R.L., Lovejoy, T.E. Global Warming and Biological Diversity Yale Univ. Press, New Haven, Conn..7687.Google Scholar
Graham, R.W., (2005). Quaternary mammal communities: relevance of the individualistic response and non-analogue faunas. Lieberman, B.S., Stigall, A.L. Paleobiogeography: Generating New Insights into the Coevolution of the Earth and Its Biota. Paleontological Society Papers 11 Yale Univ., New Haven, Conn..141158.Google Scholar
Graham, R.W., Grimm, E.C., (1990). Effects of global climate change on the patterns of terrestrial biological communities. Trends in Ecology and Evolution 5, 289292.Google Scholar
Graham, R.W., Mead, J.I., (1987). Environmental fluctuations and evolution of mammalian faunas during the last deglaciation. Ruddiman, W.F., Wright, H.E. Jr. North American and Adjacent Oceans during the Last Deglaciation. Geology of North America vol. K-3 Geological Society of America, Boulder, CO.371402.Google Scholar
Graham, R.W., Semken, H.A. Jr.(1987). Philosophy and procedures for paleoenvironmental studies of Quaternary mammalian faunas. Graham, R.W., Semken, H.A. Jr., Graham, M.A., Late Quaternary Mammalian Biogeography and Environments of the Great Plains and Prairies Illinois State Museum Scientific Paper 22, Springfield., 117.Google Scholar
Guilday, J.E., (1962). The Pleistocene local fauna of the Natural Chimneys, Augusta County, Virginia. Annals of the Carnegie Museum 36, 87122.Google Scholar
Gustafson, C.E., (1972). Faunal Remains from the Marmes Rockshelter and Related Archaeological Sites in the Columbia Basin.. Unpublished Doctoral dissertation, Department of Zoology, Washington State Univ., Pullman.Google Scholar
Gustafson, C.E., Wegener, R.M., (2004). Faunal remains. Hicks, B.A. Marmes Rockshelter: A Final Report on 11,000 Years of Cultural Use Washington State Univ. Press, Pullman.253317.Google Scholar
Hall, E.R., (1981). The Mammals of North America. 2nd Ed.Wiley, New York.Google Scholar
Hibbard, C.W., (1952). Vertebrate fossils from late Cenozoic deposits of central Kansas. Univ. of Kansas Paleontology Contributions. Vertebrata 2, 114.Google Scholar
Hibbard, C.W., (1955). The Jinglebob interglacial (Sangamon?) fauna from Kansas and its climatic significance. Contributions from the Museum of Paleontology 12, Univ. of Michigan, Ann Arbor.179228.Google Scholar
Hibbard, C.W., (1960). An interpretation of Pliocene and Pleistocene climates in North America. Annual Report of the Michigan Academy of Science, Arts and Letters 62, 530.Google Scholar
Hicks, B.A. (2004). Marmes Rockshelter: a Final Report on 11,000 Years of Cultural Use. Washington State Univ. Press, Pullman.Google Scholar
Huckleberry, G., Fadem, C., (2007). Environmental change recorded in sediments from the Marmes Rockshelter archaeological site, southeastern Washington state, USA. Quaternary Research 67, 2132.Google Scholar
Huckleberry, G., Gustafson, C., Gibson, S., (2004). Stratigraphy and site formation processes. Hicks, B.A. Marmes Rockshelter: a Final Report on 11,000 Years of Cultural Use Washington State Univ. Press, Pullman.77121.Google Scholar
Huntley, B., (1996). Quaternary paleoecology and ecology. Quaternary Science Reviews 15, 591606.Google Scholar
Jans-Langel, C.M., Semken, H.A. Jr.(2003). Paleoecological interpretation of late Pleistocene micromammal faunules from Dulme Cave, eastern Iowa. Schubert, B.W., Mead, J.I., Graham, R.W. Ice Age Cave Faunas of North America Indiana Univ. Press, Bloomington.119148.Google Scholar
Johnson, R.E., Cassidy, K.M., (1997). Terrestrial mammals of Washington State: location data and predicted distributions. Cassidy, K.M., Grue, C.E., Smith, M.R., Dvornich, K.M. Washington State Gap Analysis—Final Report Vol. 3, Washington Cooperative Fish and Wildlife Research Unit, Univ. of Washington, Seattle.Google Scholar
Lundelius, E.L. Jr., Graham, R.W., Anderson, E., Guilday, J., Holman, J.A., Steadman, D.W., Webb, S.D., (1983). Terrestrial vertebrate faunas. Porter, S.C. Late Quaternary Environments of the United States, Vol. 1, : the Late Pleistocene Univ. of Minnesota Press, Minneapolis.311353.Google Scholar
Lyman, R.L., (1986). On the analysis and interpretation of species list data in zooarchaeology. Journal of Ethnobiology 6, 6781.Google Scholar
Lyman, R.L., (1991). The Holocene history of the red fox (Vulpes vulpes) in eastern Washington. Northwest Science 65, 2226.Google Scholar
Lyman, R.L., (1994). Vertebrate Taphonomy. Cambridge Univ. Press, Cambridge.Google Scholar
Lyman, R.L., (2004). Prehistoric biogeography, abundance, and phenotypic plasticity of elk (Cervus elaphus) in Washington state. Lyman, R.L., Cannon, K.P. Zooarchaeology and Conservation Biology Univ. of Utah Press, Salt Lake City.136163.Google Scholar
Lyons, S.K., (2003). A quantitative assessment of the range shifts of Pleistocene mammals. Journal of Mammalogy 84, 385402.Google Scholar
Magurran, A.E., (1988). Ecological Diversity and Its Measurement. Princeton Univ. Press, Princeton.Google Scholar
Martin, P.S., (1958). Pleistocene ecology and biogeography of North America. Hubbs, C.L. Zoogeography American Association for the Advancement of Science Publication 51, Washington, DC.375420.Google Scholar
Rhodes II, R.S. (1984). Paleoecology and regional paleoclimatic implications of the Farmdalian Craigmile and Woodfordian Waubonsie mammalian local faunas, Southwestern Iowa. Illinois State Museum Reports of Investigations No. 40, Springfield.Google Scholar
Roy, K., Valentine, J.W., Jablonski, D., Kidwell, S.M., (1996). Scales of climatic variability and time averaging in Pleistocene biotas: implications for ecology and evolution. Trends in Ecology and Evolution 11, 458463.Google Scholar
Schubert, B.W., (2003). A late Pleistocene and early Holocene mammalian fauna from Little Beaver Cave, central Ozarks, Missouri. Schubert, B.W., Mead, J.I., Graham, R.W. Ice Age Cave Faunas of North America Indiana Univ. Press, Bloomington.149200.Google Scholar
Semken, H.A. Jr.(1966). Stratigraphy and paleontology of the McPherson Equus Beds (Sandahl Local Fauna), McPherson County, Kansas. Contributions from the Museum of Paleontology 20 University of Michigan, Ann Arbor.121178.Google Scholar
Semken, H.A. Jr.(1980). Holocene climatic reconstruction derived from the three micromammal bearing cultural horizons of the Cherokee Sewer Site, northwestern Iowa. Anderson, D.C., Semken, H.A. Jr. The Cherokee Excavations: Holocene Ecology and Human Adaptations in Northwestern Iowa Academic Press, New York.6799.Google Scholar
Semken, H.A. Jr.(1983). Holocene mammalian biogeography and climatic change in the eastern and central United States. Wright, H.E. Jr. Late-Quaternary Environments of the United States, Vol. 2, : the Holocene Univ. of Minnesota Press, Minneapolis.182207.Google Scholar
Semken, H.A. Jr.(1984). Paleoecology of a late Wisconsin/Holocene micromammal sequence in Peccary Cave, northwestern Kansas. Genoways, H.H., Dawson, M.R. Contributions in Quaternary Vertebrate Paleontology: a Volume in Memorial to John E. Guilday Carnegie Museum of Natural History Special Publication No. 8, Pittsburgh, PA.405431.Google Scholar
Semken, H.A. Jr.(1988). Environmental interpretations of the “disharmonius” late Wisconsinan biome of southeastern North America. Laub, R.S., Miller, N.G., Steadman, D.W. Late Pleistocene and Early Holocene Paleoecology and Archeology of the Eastern Great Lakes Region Bulletin of the Buffalo Society of Natural Sciences 33, Buffalo, NY.185194.Google Scholar
Semken, H.A. Jr., and Falk, C.R. (1987). Late Pleistocene/early Holocene mammalian faunas and environmental changes on the northern Plains of the United States. Graham, R.W., Semken, H.A. Jr., Graham, M.A. Late Quaternary Mammalian Biogeography and Environments of the Great Plains and Prairies Illinois State Museum Scientific Papers 22, Springfield., 176313.Google Scholar
Slaughter, B.H., (1967). Animal ranges as a clue to late-Pleistocene extinctions. Martin, P.S., Wright, H.E. Jr. Pleistocene Extinctions: the Search for a Cause Yale Univ. Press, New Haven.155167.Google Scholar
Stafford, T.W. Jr., Semken, H.A. Jr., Graham, R.W., Klippel, W.F., Markova, A., Smirnov, N.G., and Southon, J. (1999). First accelerator mass spectrometry 14C dates documenting contemporaneity of nonanalog species in late Pleistocene mammal communities. Geology 27, 903906.Google Scholar
Visher, S.S., (1954). Climatic Atlas of the United States. Harvard Univ. Press, Cambridge, Mass.Google Scholar
Webb, S.D., Graham, R.W., Barnosky, A.D., Bell, C.J., Franz, R., Hadly, E.A., Lundelius, E.L. Jr., McDonald, H.G., Martin, R.A., Semken, H.A. Jr., Steadman, D.W., (2003). Vertebrate paleontology. Gillespe, A.R., Porter, S., Atwater, B.F. The Quaternary Period in the United States Elsevier, Amsterdam.519538.Google Scholar
Whittaker, R.H., (1970). Communities and Ecosystems. Macmillan, New York.Google Scholar