Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming

Species range shifts in response to climate and land use change are commonly forecasted with species distribution models based on species occurrence or abundance data. Although appealing, these models ignore the genetic structure of species, and the fact that different populations might respond in d...

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Main Authors: Jay, Flora, Manel, Stéphanie, Alvarez, Nadir, Durand, Eric Y., Thuiller, Wilfried, Holderegger, Rolf, Taberlet, Pierre, François, Olivier
Format: Other/Unknown Material
Language:unknown
Published: Zenodo 2012
Subjects:
Arabis alpina L
Saxifraga stellaris L
Hedysarum hedysaroides (L.) Schinz & Thell. s.l
Sesleria caerulea (L.) Ard
Androsace obtusifolia All
Gentiana nivalis L
Gypsophila repens L
Cerastium uniflorum Clairv
Loiseleuria procumbens (L.) Desv
Juncus trifidus L
Geum reptans L
Luzula alpinopilosa (Chaix) Breistr
Campanula barbata L
Trifolium alpinum L
Phyteuma hemisphaericum L
Dryas octopetala L
Geum montanum L
Ligusticum mutellinoides (Cr.) Vill
Hypochaeris uniflora Vill
Holocene
Rhododendron ferrugineum L
Dryas octopetala
Online Access:https://doi.org/10.5061/dryad.777jk760
id ftzenodo:oai:zenodo.org:4956195
record_format openpolar
spelling ftzenodo:oai:zenodo.org:4956195 2024-09-15T18:04:04+00:00 Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming Jay, Flora Manel, Stéphanie Alvarez, Nadir Durand, Eric Y. Thuiller, Wilfried Holderegger, Rolf Taberlet, Pierre François, Olivier 2012-02-17 https://doi.org/10.5061/dryad.777jk760 unknown Zenodo https://doi.org/10.1111/j.1365-294X.2012.05541.x https://zenodo.org/communities/dryad https://doi.org/10.5061/dryad.777jk760 oai:zenodo.org:4956195 info:eu-repo/semantics/openAccess Creative Commons Zero v1.0 Universal https://creativecommons.org/publicdomain/zero/1.0/legalcode Arabis alpina L Saxifraga stellaris L Hedysarum hedysaroides (L.) Schinz & Thell. s.l Sesleria caerulea (L.) Ard Androsace obtusifolia All Gentiana nivalis L Gypsophila repens L Cerastium uniflorum Clairv Loiseleuria procumbens (L.) Desv Juncus trifidus L Geum reptans L Luzula alpinopilosa (Chaix) Breistr Campanula barbata L Trifolium alpinum L Phyteuma hemisphaericum L Dryas octopetala L Geum montanum L Ligusticum mutellinoides (Cr.) Vill Hypochaeris uniflora Vill Holocene Rhododendron ferrugineum L info:eu-repo/semantics/other 2012 ftzenodo https://doi.org/10.5061/dryad.777jk76010.1111/j.1365-294X.2012.05541.x 2024-07-26T23:08:20Z Species range shifts in response to climate and land use change are commonly forecasted with species distribution models based on species occurrence or abundance data. Although appealing, these models ignore the genetic structure of species, and the fact that different populations might respond in different ways due to adaptation to their environment. Here, we introduced ancestry distribution models, i.e., statistical models of the spatial distribution of ancestry proportions, for forecasting intra-specific changes based on genetic admixture instead of species occurrence data. Using multi-locus genotypes and extensive geographic coverage of distribution data across the European Alps, we applied this approach to 20 alpine plant species considering a global increase in temperature from 0.25°C to 4°C. We forecasted the magnitudes of displacement of contact zones between plant populations potentially adapted to warmer environments and other populations. While a global trend of movement in a northeast direction was predicted, the magnitude of displacement was species-specific. For a temperature increase of 2°C, contact zones were predicted to move by 92 km on average (minimum of 5 km, maximum of 212 km), and by 188 km for an increase of 4°C (minimum of 11 km, maximum of 393 km). Intra-specific turnover – measuring the extent of change in global population genetic structure – was generally found to be moderate for 2°C of temperature warming. For 4°C of warming, however, the models indicated substantial intra-specific turnover for ten species. These results illustrate that, in spite of unavoidable simplifications, ancestry distribution models open new perspectives to forecast population genetic changes within species, and complement more traditional distribution-based approaches. Data Marker data, geographic, topographic and climatic information for 20 alpine plant species Other/Unknown Material Dryas octopetala Zenodo
institution Open Polar
collection Zenodo
op_collection_id ftzenodo
language unknown
topic Arabis alpina L
Saxifraga stellaris L
Hedysarum hedysaroides (L.) Schinz & Thell. s.l
Sesleria caerulea (L.) Ard
Androsace obtusifolia All
Gentiana nivalis L
Gypsophila repens L
Cerastium uniflorum Clairv
Loiseleuria procumbens (L.) Desv
Juncus trifidus L
Geum reptans L
Luzula alpinopilosa (Chaix) Breistr
Campanula barbata L
Trifolium alpinum L
Phyteuma hemisphaericum L
Dryas octopetala L
Geum montanum L
Ligusticum mutellinoides (Cr.) Vill
Hypochaeris uniflora Vill
Holocene
Rhododendron ferrugineum L
spellingShingle Arabis alpina L
Saxifraga stellaris L
Hedysarum hedysaroides (L.) Schinz & Thell. s.l
Sesleria caerulea (L.) Ard
Androsace obtusifolia All
Gentiana nivalis L
Gypsophila repens L
Cerastium uniflorum Clairv
Loiseleuria procumbens (L.) Desv
Juncus trifidus L
Geum reptans L
Luzula alpinopilosa (Chaix) Breistr
Campanula barbata L
Trifolium alpinum L
Phyteuma hemisphaericum L
Dryas octopetala L
Geum montanum L
Ligusticum mutellinoides (Cr.) Vill
Hypochaeris uniflora Vill
Holocene
Rhododendron ferrugineum L
Jay, Flora
Manel, Stéphanie
Alvarez, Nadir
Durand, Eric Y.
Thuiller, Wilfried
Holderegger, Rolf
Taberlet, Pierre
François, Olivier
Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming
topic_facet Arabis alpina L
Saxifraga stellaris L
Hedysarum hedysaroides (L.) Schinz & Thell. s.l
Sesleria caerulea (L.) Ard
Androsace obtusifolia All
Gentiana nivalis L
Gypsophila repens L
Cerastium uniflorum Clairv
Loiseleuria procumbens (L.) Desv
Juncus trifidus L
Geum reptans L
Luzula alpinopilosa (Chaix) Breistr
Campanula barbata L
Trifolium alpinum L
Phyteuma hemisphaericum L
Dryas octopetala L
Geum montanum L
Ligusticum mutellinoides (Cr.) Vill
Hypochaeris uniflora Vill
Holocene
Rhododendron ferrugineum L
description Species range shifts in response to climate and land use change are commonly forecasted with species distribution models based on species occurrence or abundance data. Although appealing, these models ignore the genetic structure of species, and the fact that different populations might respond in different ways due to adaptation to their environment. Here, we introduced ancestry distribution models, i.e., statistical models of the spatial distribution of ancestry proportions, for forecasting intra-specific changes based on genetic admixture instead of species occurrence data. Using multi-locus genotypes and extensive geographic coverage of distribution data across the European Alps, we applied this approach to 20 alpine plant species considering a global increase in temperature from 0.25°C to 4°C. We forecasted the magnitudes of displacement of contact zones between plant populations potentially adapted to warmer environments and other populations. While a global trend of movement in a northeast direction was predicted, the magnitude of displacement was species-specific. For a temperature increase of 2°C, contact zones were predicted to move by 92 km on average (minimum of 5 km, maximum of 212 km), and by 188 km for an increase of 4°C (minimum of 11 km, maximum of 393 km). Intra-specific turnover – measuring the extent of change in global population genetic structure – was generally found to be moderate for 2°C of temperature warming. For 4°C of warming, however, the models indicated substantial intra-specific turnover for ten species. These results illustrate that, in spite of unavoidable simplifications, ancestry distribution models open new perspectives to forecast population genetic changes within species, and complement more traditional distribution-based approaches. Data Marker data, geographic, topographic and climatic information for 20 alpine plant species
format Other/Unknown Material
author Jay, Flora
Manel, Stéphanie
Alvarez, Nadir
Durand, Eric Y.
Thuiller, Wilfried
Holderegger, Rolf
Taberlet, Pierre
François, Olivier
author_facet Jay, Flora
Manel, Stéphanie
Alvarez, Nadir
Durand, Eric Y.
Thuiller, Wilfried
Holderegger, Rolf
Taberlet, Pierre
François, Olivier
author_sort Jay, Flora
title Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming
title_short Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming
title_full Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming
title_fullStr Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming
title_full_unstemmed Data from: Forecasting changes in population genetic structure of alpine plants in response to global warming
title_sort data from: forecasting changes in population genetic structure of alpine plants in response to global warming
publisher Zenodo
publishDate 2012
url https://doi.org/10.5061/dryad.777jk760
genre Dryas octopetala
genre_facet Dryas octopetala
op_relation https://doi.org/10.1111/j.1365-294X.2012.05541.x
https://zenodo.org/communities/dryad
https://doi.org/10.5061/dryad.777jk760
oai:zenodo.org:4956195
op_rights info:eu-repo/semantics/openAccess
Creative Commons Zero v1.0 Universal
https://creativecommons.org/publicdomain/zero/1.0/legalcode
op_doi https://doi.org/10.5061/dryad.777jk76010.1111/j.1365-294X.2012.05541.x
_version_ 1810441566125293568

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