Genetic consequences of climate change for northern plants

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Abstract

Climate change will lead to loss of range for many species, and thus to loss of genetic diversity crucial for their long-term persistence. We analysed range-wide genetic diversity (amplified fragment length polymorphisms) in 9581 samples from 1200 populations of 27 northern plant species, to assess genetic consequences of range reduction and potential association with species traits. We used species distribution modelling (SDM, eight techniques, two global circulation models and two emission scenarios) to predict loss of range and genetic diversity by 2080. Loss of genetic diversity varied considerably among species, and this variation could be explained by dispersal adaptation (up to 57%) and by genetic differentiation among populations ( F _ST; up to 61%). Herbs lacking adaptations for long-distance dispersal were estimated to lose genetic diversity at higher rate than dwarf shrubs adapted to long-distance dispersal. The expected range reduction in these 27 northern species was larger than reported for temperate plants, and all were predicted to lose genetic diversity according to at least one scenario. SDM combined with F _ST estimates and/or with species trait information thus allows the prediction of species' vulnerability to climate change, aiding rational prioritization of conservation efforts.

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Most cited references 48

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Ecological and Evolutionary Responses to Recent Climate Change

Camille Parmesan (2006)

Ecological changes in the phenology and distribution of plants and animals are occurring in all well-studied marine, freshwater, and terrestrial groups. These observed changes are heavily biased in the directions predicted from global warming and have been linked to local or regional climate change through correlations between climate and biological variation, field and laboratory experiments, and physiological research. Range-restricted species, particularly polar and mountaintop species, show severe range contractions and have been the first groups in which entire species have gone extinct due to recent climate change. Tropical coral reefs and amphibians have been most negatively affected. Predator-prey and plant-insect interactions have been disrupted when interacting species have responded differently to warming. Evolutionary adaptations to warmer conditions have occurred in the interiors of species' ranges, and resource use and dispersal have evolved rapidly at expanding range margins. Observed genetic shifts modulate local effects of climate change, but there is little evidence that they will mitigate negative effects at the species level.

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Measuring the accuracy of diagnostic systems.

J Swets (1988)

Diagnostic systems of several kinds are used to distinguish between two classes of events, essentially "signals" and "noise". For them, analysis in terms of the "relative operating characteristic" of signal detection theory provides a precise and valid measure of diagnostic accuracy. It is the only measure available that is uninfluenced by decision biases and prior probabilities, and it places the performances of diverse systems on a common, easily interpreted scale. Representative values of this measure are reported here for systems in medical imaging, materials testing, weather forecasting, information retrieval, polygraph lie detection, and aptitude testing. Though the measure itself is sound, the values obtained from tests of diagnostic systems often require qualification because the test data on which they are based are of unsure quality. A common set of problems in testing is faced in all fields. How well these problems are handled, or can be handled in a given field, determines the degree of confidence that can be placed in a measured value of accuracy. Some fields fare much better than others.

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Conserving biodiversity under climate change: the rear edge matters.

Arndt Hampe, Rémy Petit (2005)

Modern climate change is producing poleward range shifts of numerous taxa, communities and ecosystems worldwide. The response of species to changing environments is likely to be determined largely by population responses at range margins. In contrast to the expanding edge, the low-latitude limit (rear edge) of species ranges remains understudied, and the critical importance of rear edge populations as long-term stores of species' genetic diversity and foci of speciation has been little acknowledged. We review recent findings from the fossil record, phylogeography and ecology to illustrate that rear edge populations are often disproportionately important for the survival and evolution of biota. Their ecological features, dynamics and conservation requirements differ from those of populations in other parts of the range, and some commonly recommended conservation practices might therefore be of little use or even counterproductive for rear edge populations.

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Author and article information

Journal

Journal ID (nlm-ta): Proc Biol Sci

Journal ID (iso-abbrev): Proc. Biol. Sci

Journal ID (publisher-id): RSPB

Journal ID (hwp): royprsb

Title: Proceedings of the Royal Society B: Biological Sciences

Publisher: The Royal Society

ISSN (Print): 0962-8452

ISSN (Electronic): 1471-2954

Publication date (Print): 22 May 2012

Publication date (Electronic): 4 January 2012

Publication date PMC-release: 4 January 2012

Volume: 279

Issue: 1735

Pages: 2042-2051

Affiliations

[1 ]simpleTromsø University Museum , 9037 Tromsø, Norway

[2 ]simpleThe University Centre in Svalbard , PO Box 156, 9171 Longyearbyen, Norway

[3 ]National Centre for Biosystematics, Natural History Museum, simpleUniversity of Oslo , PO Box 1172 Blindern, 0318 Oslo, Norway

[4 ]Department of Arctic and Marine Biology, Faculty of Biosciences, Fisheries and Economics, simpleUniversity of Tromsø , 9037 Tromsø, Norway

[5 ]Laboratoire d'Ecologie Alpine, CNRS UMR 5553, simpleUniversité Joseph Fourier , PO Box 53, 38041 Grenoble Cedex 09, France

[6 ]Department of Organismic Biology, simpleUniversity of Salzburg , Hellbrunnerstrasse 34, 5020 Salzburg, Austria

[7 ]Botanical Institute, simpleUniversity of Innsbruck , Innrain 52, 6020 Innsbruck, Austria

Author notes

[* ]Author for correspondence ( inger.g.alsos@ 123456uit.no ).

[†]

Joint senior authors.

Article

Publisher ID: rspb20112363

DOI: 10.1098/rspb.2011.2363

PMC ID: 3311896

PubMed ID: 22217725

SO-VID: d6fb6521-b8c7-4aff-a1cd-2159f167339d

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This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Genetic consequences of climate change for northern plants

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Abstract

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Climate Change: Open Access

Most cited references 48

Ecological and Evolutionary Responses to Recent Climate Change

Measuring the accuracy of diagnostic systems.

Conserving biodiversity under climate change: the rear edge matters.

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