2021
DOI: 10.1002/ecy.3381
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Evolution reverses the effect of network structure on metapopulation persistence

Abstract: Global environmental change is challenging species with novel conditions, such that demographic and evolutionary trajectories of populations are often shaped by the exchange of organisms and alleles across landscapes. Current ecological theory predicts that random networks with dispersal shortcuts connecting distant sites can promote persistence when there is no capacity for evolution. Here, we show with an eco‐evolutionary model that dispersal shortcuts across environmental gradients instead hinder persistenc… Show more

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Cited by 18 publications
(25 citation statements)
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References 60 publications
(80 reference statements)
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“…The positive effect of destination strength likely operated through the ecological effects of larval immigration, implying that the demographic benefits of connectivity outweighed the potential negative evolutionary effects of gene swamping (Lenormand, 2002 ). Furthermore, the negative effect of initial SST was likely due to warmer reefs receiving cold‐adapted larvae: as the network warmed, cold‐adapted larvae arriving in relatively warm reefs counteracted evolutionary adaptation (McManus et al, 2021 ; Norberg et al, 2012 ).…”
Section: Discussionmentioning
confidence: 99%
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“…The positive effect of destination strength likely operated through the ecological effects of larval immigration, implying that the demographic benefits of connectivity outweighed the potential negative evolutionary effects of gene swamping (Lenormand, 2002 ). Furthermore, the negative effect of initial SST was likely due to warmer reefs receiving cold‐adapted larvae: as the network warmed, cold‐adapted larvae arriving in relatively warm reefs counteracted evolutionary adaptation (McManus et al, 2021 ; Norberg et al, 2012 ).…”
Section: Discussionmentioning
confidence: 99%
“…Within each region, coral subpopulations exchanged larvae based on previously published biophysical model outputs (Schill et al, 2015 ; Thompson et al, 2018 ; Treml et al, 2008 ) and evolved in response to changing temperatures. To explore the role of ecological versus evolutionary dynamics on regional and local coral populations, we simulated metapopulation dynamics with different levels of standing genetic variation, which sets evolutionary potential (McManus et al, 2021 ; Norberg et al, 2012 ; Walsworth et al, 2019 ). Finally, we constructed general linear models to interpret the influence of patch‐level metrics on the minimum coral cover experienced on a reef.…”
Section: Methodsmentioning
confidence: 99%
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“…The spatial configuration of dispersal networks can impact adaptation by shaping the distribution of adaptive genetic variation among subpopulations [36]. For many marine systems, the scale and degree of dispersal are governed by physical oceanography [58].…”
Section: Gene Flow and Adaptive Potentialmentioning
confidence: 99%