Jon R. Bridle scite author profile

New biological models are incorporating the realistic processes underlying biological responses to climate change and other human-caused disturbances. However, these more realistic models require detailed information, which is lacking for most species on Earth. Current monitoring efforts mainly document changes in biodiversity, rather than collecting the mechanistic data needed to predict future changes. We describe and prioritize the biological information needed to inform more realistic projections of species' responses to climate change. We also highlight how trait-based approaches and adaptive modeling can leverage sparse data to make broader predictions. We outline a global effort to collect the data necessary to better understand, anticipate, and reduce the damaging effects of climate change on biodiversity.

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Limits to evolution at range margins: when and why does adaptation fail?

Bridle

Vines

2007

Trends in Ecology & Evolution

601

680

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Long‐distance gene flow and adaptation of forest trees to rapid climate change

et al. 2012

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Forest trees are the dominant species in many parts of the world and predicting how they might respond to climate change is a vital global concern. Trees are capable of long-distance gene flow, which can promote adaptive evolution in novel environments by increasing genetic variation for fitness. It is unclear, however, if this can compensate for maladaptive effects of gene flow and for the long-generation times of trees. We critically review data on the extent of long-distance gene flow and summarise theory that allows us to predict evolutionary responses of trees to climate change. Estimates of long-distance gene flow based both on direct observations and on genetic methods provide evidence that genes can move over spatial scales larger than habitat shifts predicted under climate change within one generation. Both theoretical and empirical data suggest that the positive effects of gene flow on adaptation may dominate in many instances. The balance of positive to negative consequences of gene flow may, however, differ for leading edge, core and rear sections of forest distributions. We propose future experimental and theoretical research that would better integrate dispersal biology with evolutionary quantitative genetics and improve predictions of tree responses to climate change.

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Emerging horizons in biodiversity and ecosystem functioning research

Reiss

Bridle

Montoya

et al. 2009

Trends in Ecology & Evolution

515

521

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Jon R. Bridle

Improving the forecast for biodiversity under climate change

Limits to evolution at range margins: when and why does adaptation fail?

Long‐distance gene flow and adaptation of forest trees to rapid climate change

Emerging horizons in biodiversity and ecosystem functioning research

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