Climate-linked evolution and genetics in a warming Arctic

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Abstract

The extent to which species might be able to evolutionarily respond to rapid environmental change relies strongly on their genetic diversity. Accurate knowledge of both patterns of evolution and genetic variation across the species range is important for determining appropriate conservation and management strategies. The Arctic is the fastest-warming region on the planet, with the rest of the world expected to reach temperature increases currently experienced in the Arctic by the turn of the century. Here, we review and synthesize research on evolutionary processes in polar bears. Polar bears are perhaps the best-studied species living at the forefront of climate-mediated habitat change, so patterns of evolutionary change in this species should be instructive for understanding the consequences of warming that are expected to occur elsewhere in the near future. Global warming has led to significant sea ice loss that has altered patterns of gene flow across the Arctic and contributed to declines in genetic variation in some, but not all, polar bear populations. Natural selection due to warming may be driving the evolution of smaller body sizes in polar bears. However, evidence of adaptive change remains limited, despite considerable behavioural plasticity in the species in response to changing sea ice conditions. Following our review, we suggest ways that identifying the effects of warming on evolution and genetic variation in polar bears could improve strategies for locally supported conservation and management decisions. Our results point to variable responses to warming that we can expect to occur across different genetically distinct populations in the same species and the general complexity of predicting the consequences of warming for wide-ranging species.
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Abstract

Knowledge of evolutionary patterns and genetic variation across a species’ range is important for determining conservation and management strategies. The Arctic is the fastest-warming ecosystem on Earth and has already reached temperature increases not expected in the rest of the world until the end of the century. Consequently, synthesizing patterns of evolutionary and genetic change in Arctic species will be instructive for understanding future change in other systems. Here, we present a literature review of peer-reviewed published research exploring evolutionary processes in polar bears, a sentinel species for climate action. The wealth of knowledge generated from the long-term monitoring of polar bears has provided data for exploring patterns of evolutionary change associated with climate change. Warming temperatures have led to significant reductions in sea ice coverage and availability, contributing to declines in genetic variation in some, but not all, polar bear subpopulations. Natural selection driven by warming and selective subsistence harvests may be contributing to the evolution of smaller body sizes in polar bears. However, evidence of adaptive change in polar bears remains limited, despite clear behavioural and phenological plasticity in the species in response to changing sea ice conditions. Following our review, we suggest pathways for identifying the effects of climate warming on the evolution and genetic variation in polar bears, which may improve strategies for locally supported conservation and management decisions. Our results highlight the general complexity of predicting the consequences of warming for wide-ranging, genetically structured, and adaptively specialized species such as polar bears, and underscore the importance of developing evolutionarily informed management and conservation priorities for species threatened by climate change. DOI https://doi.org/10.32942/X27K92 Subjects Biology, Life Sciences

Keywords

adaptation, climate change, conservation, genetic diversity, Indigenous knowledge, management, Ursus maritimus Dates Published: 2025-02-27 19:20 Last Updated: 2026-03-05 14:17 Older Versions License No Creative Commons license Additional Metadata Conflict of interest statement: None Data and Code Availability Statement: None Language: English

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