Applying genomics in assisted migration under climate change: Framework, empirical applications, and case studies

Applying genomics in assisted migration under climate change: Framework, empirical applications, and case studies

The rate of global climate change is projected to outpace the ability of many natural populations and species to adapt. Assisted migration (AM), which is defined as the managed movement of climate‐adapted individuals within or outside the species ranges, is a conservation option to improve species&#...

Full description

Saved in:
Bibliographic Details
Published in:Evolutionary applications Vol. 15; no. 1; pp. 3 - 21
Main Authors: Chen, Zhongqi, Grossfurthner, Lukas, Loxterman, Janet L., Masingale, Jonathan, Richardson, Bryce A., Seaborn, Travis, Smith, Brandy, Waits, Lisette P., Narum, Shawn R.
Format: Journal Article
Language:English
Published: England John Wiley & Sons, Inc 01-01-2022
John Wiley and Sons Inc
Wiley
Subjects:
adaptation
Aquatic animals
assisted gene flow
assisted migration
Biodiversity
Climate change
Conservation
Decision making
Endangered & extinct species
Genetic diversity
Genomics
Review
Species
adaptation
genomics
conservation
assisted migration
assisted gene flow
climate change
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The rate of global climate change is projected to outpace the ability of many natural populations and species to adapt. Assisted migration (AM), which is defined as the managed movement of climate‐adapted individuals within or outside the species ranges, is a conservation option to improve species' adaptive capacity and facilitate persistence. Although conservation biologists have long been using genetic tools to increase or maintain diversity of natural populations, genomic techniques could add extra benefit in AM that include selectively neutral and adaptive regions of the genome. In this review, we first propose a framework along with detailed procedures to aid collaboration among scientists, agencies, and local and regional managers during the decision‐making process of genomics‐guided AM. We then summarize the genomic approaches for applying AM, followed by a literature search of existing incorporation of genomics in AM across taxa. Our literature search initially identified 729 publications, but after filtering returned only 50 empirical studies that were either directly applied or considered genomics in AM related to climate change across taxa of plants, terrestrial animals, and aquatic animals; 42 studies were in plants. This demonstrated limited application of genomic methods in AM in organisms other than plants, so we provide further case studies as two examples to demonstrate the negative impact of climate change on non‐model species and how genomics could be applied in AM. With the rapidly developing sequencing technology and accumulating genomic data, we expect to see more successful applications of genomics in AM, and more broadly, in the conservation of biodiversity.
Bibliography:Funding information
This study was supported by the NSF Idaho EPSCoR GEM3 Track 1, award number: OIA‐1757324.
ISSN:1752-4571
1752-4571
DOI:10.1111/eva.13335