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The effect of Holocene temperature fluctuations on the evolution and ecology of Neotoma (woodrats) in Idaho and northwestern Utah

Published online by Cambridge University Press:  20 January 2017

Felisa A. Smith
Affiliation:
Department of Biology, University of New Mexico, Albuquerque, NM 87131, USA
Julio L. Betancourt
Affiliation:
U.S. Geological Survey, Desert Laboratory, 1675 West Anklam Road, Tucson, AZ 85745, USA

Abstract

Animals respond to climatic change by adapting or by altering distributional patterns. How an animal responds is influenced by where it is positioned within its geographic range; the probability of extirpation is increased near range boundaries. Here, we examine the impact of Holocene climatic fluctuations on a small mammalian herbivore, the bushy-tailed woodrat (Neotoma cinerea), at five locations within south central Idaho and northwestern Utah. Previous work demonstrated that woodrats adapt to temperature shifts by altering body size. We focus here on the relationship between body mass, temperature, and location within the geographic range. Body mass is estimated by measuring fossil fecal pellets, a technique validated in earlier work. Overall, we find the predicted phenotypic response to climate change: animals were larger during cold periods, and smaller during warmer episodes. However, we also identify several time periods when changes in environmental temperature exceeded the adaptive flexibility of N. cinerea. A smaller-bodied species, the desert woodrat (N. lepida) apparently invaded lower elevation sites during the mid-Holocene, despite being behaviorally and physically subordinate to N. cinerea. Analysis of contemporary patterns of body size and thermal tolerances for both woodrat species suggests this was because of the greater heat tolerance of N. lepida. The robust spatial relationship between contemporary body size and ambient temperature is used as a proxy to reconstruct local climate during the Holocene.

Type
Articles
Copyright
Elsevier Science (USA)

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References

Benson, L., Kashgarian, M., Rye, R., Lund, S., Paillet, F., Smoot, J., Kester, C., Mensing, S., Meko, D., and Lindstrom, S. Holocene multidecadal and mulicentennial droughts affecting Northern California and Nevada. Quaternary Science Reviews 21, (2002). 659 682.CrossRefGoogle Scholar
Bergmann, C. Ueber die Verhältnisse der Wärmeökonomie der Thiere zu ihrer Grösse. Göttinger Studien 1, (1847). 595 708.Google Scholar
Betancourt, J.L. Late Quaternary plant zonation and climate in southeastern Utah. Great Basin Naturalist 44, (1984). 1 35.Google Scholar
Betancourt, J.L. Late Quaternary biogeography of the Colorado Plateau. Betancourt, J.L., Van Devender, T.R., and Martin, P.S. Packrat middens. the last 40,000 years of biotic change. (1990). University of Arizona Press, Tucson. 259 293.Google Scholar
Betancourt, J.L. 1996. Long- and short-term climate influences on southwestern shrublands, in: Barrow, J.R., McArthur, E.D., Sosebbe, R.E., Tausch, R.J. (Eds.), “Proceedings: shrubland ecosystem dynamics in a changing environment,” pp. 5-9. General Technical Report INT-GTR-338, United States Department of Agriculture, Forest Service, Intermountain Research StationGoogle Scholar
Betancourt, J.L., Van Devender, T.R., and Martin, P.S. Packrat middens: the last 40,000 years of biotic change. (1990). University of Arizona Press, Tucson.Google Scholar
Biondi, F., Perkins, D.L., Cayan, D.R., and Berger, W.H. July temperature during the second millennium reconstructed from Idaho tree rings. Geophysical Research Letters 26, (1999). 1445 1448.Google Scholar
Birch, L.C. The role of weather in determining the distribution and abundance of animals. Population studies. animal ecology and demography. Cold Spring Harbor Symposia on Quantitative Biology 22, (1957). 203 218.Google Scholar
Bond, G., and Lotti, R. Iceberg discharges into the North Atlantic on millennial time scales during the last glaciation. Science 267, (1995). 1005 1010.Google Scholar
Brown, J.H. 1968. Adaptation to environmental temperature in two species of woodrats, Neotoma cinerea and N. albigula. Miscellaneous Publications of the Museum of Zoology, University of Michigan 135, 1–48Google Scholar
Brown, J.H., and Lee, A.K. Bergmann’s rule and climatic adaptation in woodrats (Neotoma). Evolution 23, (1969). 329 338.Google Scholar
Calder, W.A. “Size, function and life history.”. (1984). Harvard University Press, Cambridge.Google Scholar
Cameron, G.N. Niche overlap and competition in woodrats. Journal of Mammalogy 52, (1971). 288 296.Google Scholar
Carraway, L.N., and Verts, B.J. Neotoma fuscipes. Mammalian Species 386, (1991). 1 10.Google Scholar
Cronin, T.M., and Schneider, C.E. Climatic influences on species. evidence from the fossil record. Trends in Ecology and Evolution 5, (1990). 275 279.Google Scholar
Dansgaard, W. Evidence for general instability of past climate from a 250 kyr ice-core record. Nature 364, (1993). 218 220.Google Scholar
Dawson, W.R. Physiological responses of animals to higher temperatures. Peters, R.L., and Lovejoy, T.E. Global Warming and Biological Diversity. (1992). Yale University Press, New Haven. 158 170.Google Scholar
Dawson, W.R. Physiological responses of animals to higher temperatures. Peters, R.L., and Lovejoy, T.E. Global warming and biological diversity. (1992). Yale University Press, New Haven. 158 170.Google Scholar
Elias, S.A. Late Pinedale and Holocene seasonal temperatures reconstructed from fossil beetle assemblages in the Rocky Mountains. Quaternary Research 46, (1996). 311 318.Google Scholar
Escherich, P.C. Social biology of the bushy-tailed woodrat, Neotoma cinerea . University of California Publications in Zoology 110, (1981). 1 132.Google Scholar
Field, C.B., Chapin, F.S. III, Matson, P.A., and Mooney, H.A. Responses of terrestrial ecosystems to the changing atmosphere. a resource based approach. Annual Review of Ecology and Systematics 23, (1992). 201 236.Google Scholar
Finley, R.B. 1958. The woodrats of Colorado. University of Kansas Publications, Museum of Natural History 10, 213–552Google Scholar
Graham, R.W. Response of mammalian communities to environmental changes during the late Quaternary. Diamond, J., and Case, T.J. Community ecology. (1986). Harper and Row, New York. 300 313.Google Scholar
Graham, R.W., and Grimm, E.C. Effects of global climate change on the patterns of terrestrial biological communities. Trends in Ecology and Evolution 5, (1990). 289 292.Google Scholar
Grayson, D.K. The desert’s past. a natural prehistory of the Great Basin. (1993). Smithsonian Institution Press, Washington, D.C.Google Scholar
Grayson, D.K. Mammalian responses to Middle Holocene climatic change in the Great Basin of the western United States. Journal of Biogeography 27, (2000). 181 192.CrossRefGoogle Scholar
Grayson, D.K. 2000b. The Homestead cave mammals, in: D.B. Madsen, Ed. Late Quaternary palaeoecology in the Bonneville Basin, Utah Geological Survey Bulletin 130, 1–190, pp. 6789.Google Scholar
Grayson, D.K., and Madsen, D.B. Biogeographic implications of recent low-elevation recolonization by Neotoma cinerea in the Great Basin. Journal of Mammalogy 81, (2000). 1100 1105.Google Scholar
Grayson, D.K., Livingston, S.D., Richart, E., and Shaver, M.W. The biogeographic significance of low elevational records for Neotoma cinerea from the northern Bonneville Basin, Utah. Great Basin Naturalist 56, (1996). 191 196.Google Scholar
Hall, E.R. “The mammals of North America”. (1981). John Wiley and Sons, New York.Google Scholar
Harris, A.H. 1984. Neotoma in the late Pleistocene of New Mexico and Chihuahua, in: H.H. Genoways and M.R. Dawson (Eds.), Contributions to Quaternary vertebrate paleontology: a volume in memorial to John E. Guilday, Special Publications of the Carnegie Museum of Natural History 8, 1–538, pp. 164178.Google Scholar
Harris, A.H. Late Pleistocene vertebrate paleoecology of the west. (1985). University of Texas Press, Austin.Google Scholar
Harris, A.H., (1993). Quaternary vertebrates of New Mexico. in: Lucas, S.G. and Zidek, J. (Eds.), Vertebrate Paleontology in New Mexico, New Mexico Museum of Natural History and Science Bulletin 2, pp. 179197.Google Scholar
Hoffmann, A.A., and Blows, M.W. Evolutionary genetics and climate change. will animals adapt to global warming?. Kareiva, P.M., Kingsolver, J.G., and Huey, R.S. Biotic Interactions and Global Change. (1993). Sinauer Associates, Sunderland. 165 178.Google Scholar
Holt, R.D. The microevolutionary consequences of climate change. Trends in Ecology and Evolution 5, (1990). 311 315.Google Scholar
Hooper, E.T. Geographic variation in bushy-tailed woodrats. University of California Publications in Zoology 42, (1940). 407 424.Google Scholar
Hughes, M.K., and Diaz, H.F. Was there a medieval warm period, and if so, where and when?. Climate Change 26, (1994). 109 142.Google Scholar
Jones, P.D., and Bradley, R.S. Climate fluctuations over the last 500 years,. Bradley, R.S., and Jones, P.D. Climate Change Since AD 1500. (1992). Academic Press, San Diego. 649 665.Google Scholar
Kneller, M., and Peteet, D. Late-glacial to early Holocene climate changes from a central Appalachian pollen and macrofossil record. Quaternary Research 51, (1999). 133 147.Google Scholar
Leamy, L. Genetic and maternal influences on brain and body size in random breed house mice. Evolution 42, (1988). 42 53.Google Scholar
Lee, A.K. The adaptations to arid environments in woodrats of the genus Neotoma. . University of California Publications in Zoology 64, (1963). 57 96.Google Scholar
Madsen, D.B. Late Quaternary palaeoecology in the Bonneville Basin. Utah Geological Survey Bulletin 130, (2000). 1 190.Google Scholar
Meyer, H.W. Lapse rates and other variables applied to estimating paleoaltitudes from fossil floras. Palaeogeography, Palaeoclimatology, Palaeoecology 99, (1992). 71 99.Google Scholar
Mooney, H.A. Biological response to climate change. an agenda for research. Ecological Applications 1, (1991). 112 117.Google Scholar
Nowak, C.L., Nowak, R.S., Tausch, R.J., and Wigand, P.E. Tree and shrub dynamics in northwestern Great Basin woodland and shrub steppe during the late Pleistocene and Holocene. American Journal of Botany 81, (1994). 265 277.Google Scholar
Perkins, D., and Swetnam, T.W. A Dendroecological Assessment of Whitebark Pine (Pinus albicaulis) in the Sawtooth-Salmon River Region of Idaho. Canadian Journal of Forest Research 26, (1996). 2123 2133.Google Scholar
Peters, R.L., and Darling, J.D.S. The greenhouse effect and nature reserves. Bioscience 35, (1985). 707 717.Google Scholar
Peters, R.H. “The ecological implications of body size.”. (1983). Cambridge University Press, Cambridge.Google Scholar
Porter, S.C., (1986). Pattern and forcing of northern hemisphere glacier variations during the last millennium. Quaternary Research, 26, 2748.Google Scholar
Rameax, Sarrus, (1838). Rapport sur un mémoire adressé à l’Académie royale de médecine. Bulletin de l’Académie de Médecine 3, 10941100.Google Scholar
Shugart, H.H., Smith, T.M., and Post, W.M. The potential for application of individual-based simulation models for assessing the effects of global change. Annual Review of Ecology and Systematics 23, (1992). 15 38.Google Scholar
Rutledge, J.J., Eisen, E.J., Legates, J.E. Genetics 75, (1973). 709 715.Google Scholar
Schmidt-Nielsen, K. Scaling. why is animal size so important?. (1984). Cambridge University Press, Cambridge.Google Scholar
Shugart, H.H., Smith, T.M., and Post, W.M. The potential for application of individual-based simulation models for assessing the effects of global change. Annual Review of Ecology and Systematics 23, (1992). 15 38.Google Scholar
Smith, F.A. Den characteristics and survivorship of woodrats (Neotoma lepida) in the eastern Mojave Desert. Southwestern Naturalist 40, (1996). 366 372.Google Scholar
Smith, F.A. Neotoma cinerea. Mammalian Species 564, (1997). 1 8.Google Scholar
Smith, F.A., and Betancourt, J.L. Response of bushy-tailed woodrats (Neotoma cinerea) to late Quaternary climatic change in the Colorado Plateau. Quaternary Research 47, (1998). 1 11.Google Scholar
Smith, F.A., Betancourt, J.L., and Brown, J.H. Evolution of body size in the woodrat over the past 25,000 years of climate change. Science 270, (1995). 2012 2014.Google Scholar
Smith, F.A., Browning, H., and Shepherd, U.L. The influence of climatic change on the body mass of woodrats (Neotoma albigula) in an arid region of New Mexico, USA. Ecography 21, (1998). 140 148.Google Scholar
Smith, F.A., and Charnov, E.L. Fitness tradeoffs select for semelparous (suicidal) reproduction in an extreme environment. Evolutionary Ecology Research 2, (2001). 595 602.Google Scholar
Smith, S.V., and Buddemeir, R.W. Global change and coral reef ecosystems. Annual Review of Ecology and Systematics 23, (1992). 89 118.Google Scholar
Spaulding, W.G., Betancourt, J.L., Croft, L.K., and Cole, K.L. Packrat middens. their composition and methods of analysis. Betancourt, J.L., Van Devender, T.R., and Martin, P.S. Packrat middens. the last 40,000 years of biotic change. (1990). University of Arizona Press, Tucson. 59 84.Google Scholar
Thompson, R.S., Whitlock, C., Bartlein, P.J., Harrison, S.P., and Spaulding, W.G. Climatic changes in the western United States since 18,000 yr B.P. Wright, H.E. Jr., Kutzbach, J.E., Webb, T., Ruddiman, W.F., Street-Perrott, F.A., and Bartlein, P.J. Global Climates Since the Last Glacial Maximum. (1993). University of Minnesota Press, Minneapolis. 468 513.Google Scholar
Tracy, R.C. Ecological responses of animals to climate. Peters, R.L., and Lovejoy, T.E. Global Warming and Biological Diversity. (1992). Yale University Press, New Haven. 171 179.Google Scholar
Webb, T., and Bartlein, P.J. Global changes during the last 3 million years. climatic controls and biotic responses. Annual Review of Ecology and Systematics 23, (1992). 141 173.Google Scholar