Effect of altitude on the genetic structure of an Alpine grass, Poa hiemata

doi:10.1093/aob/mcp018

AOBPreview originally published online on February 10, 2009
Annals of Botany 2009 103(6):885-899; doi:10.1093/aob/mcp018

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Effect of altitude on the genetic structure of an Alpine grass, Poa hiemata

Sean G. Byars¹^,*, Yvonne Parsons² and Ary A. Hoffmann¹

¹ Centre for Environmental Stress and Adaptation Research (CESAR), Department of Genetics, Melbourne University, Parkville, Australia
² Department of Genetics, La Trobe University, Australia

^* For correspondence. E-mail s.byars{at}pgrad.unimelb.edu.au

Received: 27 June 2008 Returned for revision: 8 October 2008 Accepted: 5 January 2009 Published electronically: 10 February 2009

Background and Aims: The persistence of plants inhabiting restricted alpine areasunder climate change will depend upon many factors includinglevels of genetic variation in adaptive traits, population structure,and breeding system.

Methods: Using microsatellite markers, the genetic structure of populationsof a relatively common alpine grass, Poa hiemata, is examinedacross three altitudinal gradients within the restricted Australianalpine zone where this species has previously been shown toexhibit local adaptation across a narrow altitudinal gradient.

Key Results: Genetic variation across six microsatellite markers revealedgenetic structuring along altitudinal transects, and a reductionin genetic variation at high and low altitude extremes relativeto sites central within transects. There was less genetic variationamong transect sites compared with altitudinal gradients withintransects, even though distances among transects were relativelylarger. Central sites within transects were less differentiatedthan those at extremes.

Conclusions: These patterns suggest higher rates of gene flow among sitesat similar altitudes than along transects, a process that couldassist altitudinal adaptation. Patterns of spatial autocorrelationand isolation by distance changed with altitude and may reflectaltered patterns of dispersal via pollen and/or seed. Therewas evidence for selfing and clonality in neighbouring plants.Levels of gene flow along transects were insufficient to preventadaptive changes in morphological traits, given previously measuredlevels of selection.

Key words: Poa hiemata, genetic structure, altitudinal gradient, microsatellite, gene flow, climate change

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