Global warming, Bergmann's rule and body mass – are they related? The chukar partridge (Alectoris chukar) case

Yoram Yom-Tov; Yoav Benjamini; Salit Kark

doi:10.1017/S095283690200105X

Abstract

Using museum specimens collected in Israel during the second half of the 20th century, no support was found for the hypothesis that body mass and tarsus length of chukar partridges Alectoris chukar has changed as a result of global warming. Body mass showed fluctuations during the year, reaching a maximum in late winter and spring and a minimum in summer. Bergmann's rule predicts that in warm-blooded animals, races from warm regions will be smaller than races from colder regions, and a wider explanation states that body size is positively related to latitude. Because of its topography and varied climate, Israel provides a unique opportunity to separate partly the effect of latitude from that of ambient temperature, thus testing if Bergmann's rule is related to latitude or to climatic variables. We found that body mass (and marginally also tarsus length) declined significantly with decreasing latitude in accordance with the wider explanation of Bergmann's rule, but ambient temperature explained a much smaller fraction of the variation in body mass than latitude. These results weaken the traditional explanation to Bergmann's rule that a heat conservation mechanism causes the latitudinal size variation.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Kark, Salit Mukerji, Tapan Safriel, Uriel N. Noy‐Meir, Imanuel Nissani, Rachel and Darvasi, Ariel 2002. Peak morphological diversity in an ecotone unveiled in the chukar partridge by a novel Estimator in a Dependent Sample (EDS). Journal of Animal Ecology, Vol. 71, Issue. 6, p. 1015.

Meiri, Shai and Dayan, Tamar 2003. On the validity of Bergmann's rule. Journal of Biogeography, Vol. 30, Issue. 3, p. 331.

MEIRI, SHAI DAYAN, TAMAR and SIMBERLOFF, DANIEL 2004. Carnivores, biases and Bergmann's rule. Biological Journal of the Linnean Society, Vol. 81, Issue. 4, p. 579.

Kaňuščák, Pavel Hromada, Martin Tryjanowski, Piotr and Sparks, Tim 2004. Does climate at different scales influence the phenology and phenotype of the River Warbler Locustella fluviatilis?. Oecologia, Vol. 141, Issue. 1, p. 158.

Litzgus, Jacqueline D. DuRant, Sarah E. and Mousseau, Timothy A. 2004. Clinal variation in body and cell size in a widely distributed vertebrate ectotherm. Oecologia, Vol. 140, Issue. 4, p. 551.

Grenier, J. Letitia and Greenberg, Russell 2005. A BIOGEOGRAPHIC PATTERN IN SPARROW BILL MORPHOLOGY: PARALLEL ADAPTATION TO TIDAL MARSHES. Evolution, Vol. 59, Issue. 7, p. 1588.

Nielsen, Jan Tøttrup and Møller, Anders Pape 2006. Effects of food abundance, density and climate change on reproduction in the sparrowhawk Accipiter nisus. Oecologia, Vol. 149, Issue. 3, p. 505.

Medina, Alonso I. Martí, Dardo A. and Bidau, Claudio J. 2007. Subterranean rodents of the genusCtenomys(Caviomorpha, Ctenomyidae) follow the converse to Bergmann's rule. Journal of Biogeography, Vol. 34, Issue. 8, p. 1439.

Møller, Anders Pape 2008. Climate change and micro-geographic variation in laying date. Oecologia, Vol. 155, Issue. 4, p. 845.

Tomlinson, Sean and Withers, Philip C. 2008. Biogeographical effects on body mass of native Australian and introduced mice, Pseudomys hermannsburgensis and Mus domesticus: an inquiry into Bergmann's Rule. Australian Journal of Zoology, Vol. 56, Issue. 6, p. 423.

Symonds, Matthew R. E. and Tattersall, Glenn J. 2010. Geographical Variation in Bill Size across Bird Species Provides Evidence for Allen’s Rule. The American Naturalist, Vol. 176, Issue. 2, p. 188.

Møller, A. P. Flensted‐Jensen, E. Klarborg, K. Mardal, W. and Nielsen, J. T. 2010. Climate change affects the duration of the reproductive season in birds. Journal of Animal Ecology, Vol. 79, Issue. 4, p. 777.

Watt, Cortney Mitchell, Sean and Salewski, Volker 2010. Bergmann's rule; a concept cluster?. Oikos, Vol. 119, Issue. 1, p. 89.

Gardner, Janet L. Peters, Anne Kearney, Michael R. Joseph, Leo and Heinsohn, Robert 2011. Declining body size: a third universal response to warming?. Trends in Ecology & Evolution, Vol. 26, Issue. 6, p. 285.

Takahashi, Yuma Morita, Satoru Yoshimura, Jin and Watanabe, Mamoru 2011. A geographic cline induced by negative frequency-dependent selection. BMC Evolutionary Biology, Vol. 11, Issue. 1,

Yom-Tov, Yoram and Geffen, Eli 2011. Recent spatial and temporal changes in body size of terrestrial vertebrates: probable causes and pitfalls. Biological Reviews, Vol. 86, Issue. 2, p. 531.

Teplitsky, Celine and Millien, Virginie 2014. Climate warming and Bergmann's rule through time: is there any evidence?. Evolutionary Applications, Vol. 7, Issue. 1, p. 156.

Rypel, Andrew L. 2014. The Cold-Water Connection: Bergmann’s Rule in North American Freshwater Fishes. The American Naturalist, Vol. 183, Issue. 1, p. 147.

Weber, Michael J. Brown, Michael L. Wahl, David H. and Shoup, Daniel E. 2015. Metabolic theory explains latitudinal variation in common carp populations and predicts responses to climate change. Ecosphere, Vol. 6, Issue. 4, p. 1.

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Global warming, Bergmann's rule and body mass – are they related? The chukar partridge (Alectoris chukar) case

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Global warming, Bergmann's rule and body mass – are they related? The chukar partridge (Alectoris chukar) case

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