When Cold is Better: Climate-Driven Elevation Shifts Yield Complex Patterns of Diversification and Demography in an Alpine Specialist (American Pika, Ochotona princeps)

When Cold is Better: Climate-Driven Elevation Shifts Yield Complex Patterns of Diversification and Demography in an Alpine Specialist (American Pika, Ochotona princeps)

The genetic consequences of climate-driven range fluctuation during the Pleistocene have been well studied for temperate species, but cold-adapted (e.g., alpine, arctic) species that may have responded uniquely to past climatic events have received less attention. In particular, we have no a priori...

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Bibliographic Details
Published in:Evolution Vol. 63; no. 11; pp. 2848 - 2863
Main Authors: Galbreath, Kurt E., Hafner, David J., Zamudio, Kelly R.
Format: Journal Article
Language:English
Published: Malden, USA Wiley/Blackwell 01-11-2009
Blackwell Publishing Inc
Wiley Subscription Services
Oxford University Press
Subjects:
Altitude
Animals
Base Sequence
Climate
Climate change
Climate models
Cold
Cold Temperature
Demography
DNA Primers
Ecological niche model
Evolution
Evolution & development
Evolutionary genetics
Genetics
glaciation
Habitats
interglacial
Intermountain West
Lagomorpha - classification
Lagomorpha - genetics
Lagomorpha - physiology
Mammals
Markov Chains
Modeling
Monte Carlo Method
Mountain ranges
Mountains
Ochotona princeps
ORIGINAL ARTICLES
Paleoclimatology
Phylogeny
phylogeography
Population distributions
Population genetics
range fluctuation
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Summary:The genetic consequences of climate-driven range fluctuation during the Pleistocene have been well studied for temperate species, but cold-adapted (e.g., alpine, arctic) species that may have responded uniquely to past climatic events have received less attention. In particular, we have no a priori expectation for long-term evolutionary consequences of elevation shifts into and out of sky islands by species adapted to alpine habitats. Here, we examined the influence of elevation shifts on genetic differentiation and historical demography in an alpine specialist, the American pika (Ochotona princeps). Pika populations are divided into five genetic lineages that evolved in association with separate mountain systems, rather than lineages that reflect individual sky islands. This suggests a role for glacial-period elevation shifts in promoting gene flow among high-elevation populations and maintaining regional cohesion of genetic lineages. We detected a signature of recent demographic decline in all lineages, consistent with the expectation that Holocene climate warming has driven range retraction in southern lineages, but unexpected for northern populations that presumably represent postglacial expansion. An ecological niche model of past and future pika distributions highlights the influence of climate on species range and indicates that the distribution of genetic diversity may change dramatically with continued climate warming.
Bibliography:ark:/67375/WNG-VRWT54GF-V
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ArticleID:EVO803
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
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ISSN:0014-3820
1558-5646
DOI:10.1111/j.1558-5646.2009.00803.x