Potential for evolutionary responses to climate change - evidence from tree populations

Potential for evolutionary responses to climate change - evidence from tree populations

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Evolutionary responses are required for tree populations to be able to track climate change. Results of 250 years of common garden experiments show that most forest trees have evolved local adaptation, as evidenced by the adaptive differentiation of populations in quantitative traits, reflecting environmental conditions of population origins. On the basis of the patterns of quantitative variation for 19 adaptation-related traits studied in 59 tree species (mostly temperate and boreal species from the Northern hemisphere), we found that genetic differentiation between populations and clinal variation along environmental gradients were very common (respectively, 90% and 78% of cases). Thus, responding to climate change will likely require that the quantitative traits of populations again match their environments. We examine what kind of information is needed for evaluating the potential to respond, and what information is already available. We review the genetic models related to selection responses, and what is known currently about the genetic basis of the traits. We address special problems to be found at the range margins, and highlight the need for more modeling to understand specific issues at southern and northern margins. We need new common garden experiments for less known species. For extensively studied species, new experiments are needed outside the current ranges. Improving genomic information will allow better prediction of responses. Competitive and other interactions within species and interactions between species deserve more consideration. Despite the long generation times, the strong background in quantitative genetics and growing genomic resources make forest trees useful species for climate change research. The greatest adaptive response is expected when populations are large, have high genetic variability, selection is strong, and there is ecological opportunity for establishment of better adapted genotypes. © 2013 Blackwell Publishing Ltd.

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Main Authors: Alberto, F. J., Aitken, S. N., Alía Miranda, Ricardo, González-Martínez, S. C., Hänninen, H., Kremer, A., Lefèvre, F., Lenormand, T., Yeaman, S., Whetten, R., Savolainen, O.
Format: artículo de revisión biblioteca
Language:English
Published: John Wiley & Sons 2013
Subjects:Adaptive traits, Conifers, Local adaptation, Natural selection, Phenotypic plasticity, Provenance trials, Quantitative genetics,
Online Access:http://hdl.handle.net/20.500.12792/4834
http://hdl.handle.net/10261/295286
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spelling dig-inia-es-10261-2952862023-02-23T20:12:03Z Potential for evolutionary responses to climate change - evidence from tree populations Alberto, F. J. Aitken, S. N. Alía Miranda, Ricardo González-Martínez, S. C. Hänninen, H. Kremer, A. Lefèvre, F. Lenormand, T. Yeaman, S. Whetten, R. Savolainen, O. Adaptive traits Conifers Local adaptation Natural selection Phenotypic plasticity Provenance trials Quantitative genetics Evolutionary responses are required for tree populations to be able to track climate change. Results of 250 years of common garden experiments show that most forest trees have evolved local adaptation, as evidenced by the adaptive differentiation of populations in quantitative traits, reflecting environmental conditions of population origins. On the basis of the patterns of quantitative variation for 19 adaptation-related traits studied in 59 tree species (mostly temperate and boreal species from the Northern hemisphere), we found that genetic differentiation between populations and clinal variation along environmental gradients were very common (respectively, 90% and 78% of cases). Thus, responding to climate change will likely require that the quantitative traits of populations again match their environments. We examine what kind of information is needed for evaluating the potential to respond, and what information is already available. We review the genetic models related to selection responses, and what is known currently about the genetic basis of the traits. We address special problems to be found at the range margins, and highlight the need for more modeling to understand specific issues at southern and northern margins. We need new common garden experiments for less known species. For extensively studied species, new experiments are needed outside the current ranges. Improving genomic information will allow better prediction of responses. Competitive and other interactions within species and interactions between species deserve more consideration. Despite the long generation times, the strong background in quantitative genetics and growing genomic resources make forest trees useful species for climate change research. The greatest adaptive response is expected when populations are large, have high genetic variability, selection is strong, and there is ecological opportunity for establishment of better adapted genotypes. © 2013 Blackwell Publishing Ltd. 2023-02-20T10:46:39Z 2023-02-20T10:46:39Z 2013 artículo de revisión Global Change Biology 19: 1645-1661 (2013) 1354-1013 http://hdl.handle.net/20.500.12792/4834 http://hdl.handle.net/10261/295286 10.1111/gcb.12181 1365-2486 23505261 en none John Wiley & Sons
institution INIA ES
collection DSpace
country España
countrycode ES
component Bibliográfico
access En linea
databasecode dig-inia-es
tag biblioteca
region Europa del Sur
libraryname Biblioteca del INIA España
language English
topic Adaptive traits
Conifers
Local adaptation
Natural selection
Phenotypic plasticity
Provenance trials
Quantitative genetics
Adaptive traits
Conifers
Local adaptation
Natural selection
Phenotypic plasticity
Provenance trials
Quantitative genetics
spellingShingle Adaptive traits
Conifers
Local adaptation
Natural selection
Phenotypic plasticity
Provenance trials
Quantitative genetics
Adaptive traits
Conifers
Local adaptation
Natural selection
Phenotypic plasticity
Provenance trials
Quantitative genetics
Alberto, F. J.
Aitken, S. N.
Alía Miranda, Ricardo
González-Martínez, S. C.
Hänninen, H.
Kremer, A.
Lefèvre, F.
Lenormand, T.
Yeaman, S.
Whetten, R.
Savolainen, O.
Potential for evolutionary responses to climate change - evidence from tree populations
description Evolutionary responses are required for tree populations to be able to track climate change. Results of 250 years of common garden experiments show that most forest trees have evolved local adaptation, as evidenced by the adaptive differentiation of populations in quantitative traits, reflecting environmental conditions of population origins. On the basis of the patterns of quantitative variation for 19 adaptation-related traits studied in 59 tree species (mostly temperate and boreal species from the Northern hemisphere), we found that genetic differentiation between populations and clinal variation along environmental gradients were very common (respectively, 90% and 78% of cases). Thus, responding to climate change will likely require that the quantitative traits of populations again match their environments. We examine what kind of information is needed for evaluating the potential to respond, and what information is already available. We review the genetic models related to selection responses, and what is known currently about the genetic basis of the traits. We address special problems to be found at the range margins, and highlight the need for more modeling to understand specific issues at southern and northern margins. We need new common garden experiments for less known species. For extensively studied species, new experiments are needed outside the current ranges. Improving genomic information will allow better prediction of responses. Competitive and other interactions within species and interactions between species deserve more consideration. Despite the long generation times, the strong background in quantitative genetics and growing genomic resources make forest trees useful species for climate change research. The greatest adaptive response is expected when populations are large, have high genetic variability, selection is strong, and there is ecological opportunity for establishment of better adapted genotypes. © 2013 Blackwell Publishing Ltd.
format artículo de revisión
topic_facet Adaptive traits
Conifers
Local adaptation
Natural selection
Phenotypic plasticity
Provenance trials
Quantitative genetics
author Alberto, F. J.
Aitken, S. N.
Alía Miranda, Ricardo
González-Martínez, S. C.
Hänninen, H.
Kremer, A.
Lefèvre, F.
Lenormand, T.
Yeaman, S.
Whetten, R.
Savolainen, O.
author_facet Alberto, F. J.
Aitken, S. N.
Alía Miranda, Ricardo
González-Martínez, S. C.
Hänninen, H.
Kremer, A.
Lefèvre, F.
Lenormand, T.
Yeaman, S.
Whetten, R.
Savolainen, O.
author_sort Alberto, F. J.
title Potential for evolutionary responses to climate change - evidence from tree populations
title_short Potential for evolutionary responses to climate change - evidence from tree populations
title_full Potential for evolutionary responses to climate change - evidence from tree populations
title_fullStr Potential for evolutionary responses to climate change - evidence from tree populations
title_full_unstemmed Potential for evolutionary responses to climate change - evidence from tree populations
title_sort potential for evolutionary responses to climate change - evidence from tree populations
publisher John Wiley & Sons
publishDate 2013
url http://hdl.handle.net/20.500.12792/4834
http://hdl.handle.net/10261/295286
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