Latitude, elevation and the tempo of molecular evolution in mammals

Faster rates of microevolution have been recorded for plants and marine foraminifera occupying warmer low latitude environments relative to those occurring at higher latitudes. By contrast, because this rate heterogeneity has been attributed to a relationship between thermal habit and mutagenesis vi...

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Veröffentlicht in:	Proceedings of the Royal Society. B, Biological sciences Biological sciences, 2009-09, Vol.276 (1671), p.3353-3359
Hauptverfasser:	Gillman, Len N., Keeling, D. Jeanette, Ross, Howard A., Wright, Shane D.
Format:	Artikel
Sprache:	eng
Schlagworte:	Amino Acid Substitution Animals Biodiversity Biological taxonomies Climate models Cytochromes Ecosystem Ectotherms Endotherms Energy Metabolism Evolution Evolution, Molecular Genetic mutation Geography Mammals Mammals - genetics Metabolic Rate Metabolism Phylogenetics Population Density Sequence Analysis, Protein Species Species Richness Temperature Time Factors We they distinction
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container_title	Proceedings of the Royal Society. B, Biological sciences
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creator	Gillman, Len N. Keeling, D. Jeanette Ross, Howard A. Wright, Shane D.
description	Faster rates of microevolution have been recorded for plants and marine foraminifera occupying warmer low latitude environments relative to those occurring at higher latitudes. By contrast, because this rate heterogeneity has been attributed to a relationship between thermal habit and mutagenesis via a body temperature linkage, it has been assumed that microevolution in mammals should not also vary systematically with environmental temperature. However, this assumption has not previously been empirically examined. In this study, we tested for a thermally mediated influence on the tempo of microevolution among mammals using a comprehensive global dataset that included 260 mammal species, from 10 orders and 29 families. In contrast to theoretical predictions, we found that substitution rates in the cytochrome b gene have been substantially faster for species living in warmer latitudes and elevations relative to sister species living in cooler habitats. These results could not be attributed to factors otherwise thought to influence rates of microevolution, such as body mass differentials or genetic drift. Instead, the results indicate that the tempo of microevolution among mammals is either responding directly to the thermal environment or indirectly via an ecological mechanism such as the 'Red Queen' effect.
doi_str_mv	10.1098/rspb.2009.0674
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In contrast to theoretical predictions, we found that substitution rates in the cytochrome b gene have been substantially faster for species living in warmer latitudes and elevations relative to sister species living in cooler habitats. These results could not be attributed to factors otherwise thought to influence rates of microevolution, such as body mass differentials or genetic drift. 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subjects	Amino Acid Substitution Animals Biodiversity Biological taxonomies Climate models Cytochromes Ecosystem Ectotherms Endotherms Energy Metabolism Evolution Evolution, Molecular Genetic mutation Geography Mammals Mammals - genetics Metabolic Rate Metabolism Phylogenetics Population Density Sequence Analysis, Protein Species Species Richness Temperature Time Factors We they distinction
title	Latitude, elevation and the tempo of molecular evolution in mammals
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