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Local thermal adaptation and limited gene flow constrain future climate responses of a marine ecosystem engineer.
Miller, Adam D; Coleman, Melinda A; Clark, Jennifer; Cook, Rachael; Naga, Zuraya; Doblin, Martina A; Hoffmann, Ary A; Sherman, Craig D H; Bellgrove, Alecia.
Afiliação
  • Miller AD; School of Life and Environmental Sciences Centre for Integrative Ecology Deakin University Geelong Vic. Australia.
  • Coleman MA; Deakin Genomics Centre Deakin University Geelong Vic. Australia.
  • Clark J; NSW Fisheries National Marine Science Centre Coffs Harbour NSW Australia.
  • Cook R; Climate Change Cluster University of Technology Sydney Sydney NSW Australia.
  • Naga Z; Department of Botany University of British Columbia Vancouver BC Canada.
  • Doblin MA; School of Life and Environmental Sciences Centre for Integrative Ecology Deakin University Geelong Vic. Australia.
  • Hoffmann AA; School of Life and Environmental Sciences Centre for Integrative Ecology Deakin University Geelong Vic. Australia.
  • Sherman CDH; Department of Botany University of British Columbia Vancouver BC Canada.
  • Bellgrove A; School of BioSciences Bio21 Institute The University of Melbourne Parkville Vic. Australia.
Evol Appl ; 13(5): 918-934, 2020 May.
Article em En | MEDLINE | ID: mdl-32431743
Rising ocean temperatures and extreme temperature events have precipitated declines and local extinctions in many marine species globally, but patterns of loss are often uneven across species ranges for reasons that are poorly understood. Knowledge of the extent of local adaptation and gene flow may explain such patterns and help predict future trajectories under scenarios of climate change. We test the extent to which local differentiation in thermal tolerance is influenced by gene flow and local adaptation using a widely distributed intertidal seaweed (Hormosira banksii) from temperate Australia. Population surveys across ~2,000 km of the species range revealed strong genetic structuring at regional and local scales (global F ST = 0.243) reflecting extremely limited gene flow, while common garden experiments (14-day exposures to 15, 18, 21°C) revealed strong site differences in early development and mortality in response to elevated temperature. Embryos from many sites spanning a longitudinal thermal gradient showed suppressed development and increased mortality to elevated water temperatures, but populations originating from warmer and more variable thermal environments tended to be less susceptible to warming. Notably, there was significant local-scale variation in the thermal responses of embryos within regions which was corroborated by the finding of small-scale genetic differences. We expect the observed genetic and phenotypic differentiation to lead to uneven responses to warming sea surface temperatures in this important marine foundation species. The study highlights the challenges of predicting species responses to thermal stress and the importance of management strategies that incorporate evolutionary potential for "climate-proofing" marine ecosystems.
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Texto completo: 1 Coleções: 01-internacional Base de dados: MEDLINE Idioma: En Revista: Evol Appl Ano de publicação: 2020 Tipo de documento: Article

Texto completo: 1 Coleções: 01-internacional Base de dados: MEDLINE Idioma: En Revista: Evol Appl Ano de publicação: 2020 Tipo de documento: Article