Genomic Vulnerability and Socio-economic Threats Under Climate Change in an African Rainforest Bird

Overview

Journal Evol Appl

Specialty Biology

Date 2021 May 24

PMID 34025764

Citations 2

Authors

Thomas B Smith

Trevon L Fuller

Ying Zhen

Virginia Zaunbrecher

Henri A Thomassen

Kevin Njabo

Nicola M Anthony

Mary K Gonder

Wolfgang Buermann

Brenda Larison

Kristen Ruegg

Ryan J Harrigan

Affiliations

Soon will be listed here.

Abstract

Preserving biodiversity under rapidly changing climate conditions is challenging. One approach for estimating impacts and their magnitude is to model current relationships between genomic and environmental data and then to forecast those relationships under future climate scenarios. In this way, understanding future genomic and environmental relationships can help guide management decisions, such as where to establish new protected areas where populations might be buffered from high temperatures or major changes in rainfall. However, climate warming is only one of many anthropogenic threats one must consider in rapidly developing parts of the world. In Central Africa, deforestation, mining, and infrastructure development are accelerating population declines of rainforest species. Here we investigate multiple anthropogenic threats in a Central African rainforest songbird, the little greenbul (). We examine current climate and genomic variation in order to explore the association between genome and environment under future climate conditions. Specifically, we estimate , defined as the mismatch between current and predicted future genomic variation based on genotype-environment relationships modeled across contemporary populations. We do so while considering other anthropogenic impacts. We find that coastal and central Cameroon populations will require the greatest shifts in adaptive genomic variation, because both climate and land use in these areas are predicted to change dramatically. In contrast, in the more northern forest-savanna ecotones, genomic shifts required to keep pace with climate will be more moderate, and other anthropogenic impacts are expected to be comparatively low in magnitude. While an analysis of diverse taxa will be necessary for making comprehensive conservation decisions, the species-specific results presented illustrate how evolutionary genomics and other anthropogenic threats may be mapped and used to inform mitigation efforts. To this end, we present an integrated conceptual model demonstrating how the approach for a single species can be expanded to many taxonomically diverse species.

Citing Articles

Genotype-environment associations across spatial scales reveal the importance of putative adaptive genetic variation in divergence.

Alvarado A, Bossu C, Harrigan R, Bay R, Nelson A, Smith T Evol Appl. 2022; 15(9):1390-1407.

PMID: 36187181 PMC: 9488676. DOI: 10.1111/eva.13444.

Genomic vulnerability and socio-economic threats under climate change in an African rainforest bird.

Smith T, Fuller T, Zhen Y, Zaunbrecher V, Thomassen H, Njabo K Evol Appl. 2021; 14(5):1239-1247.

PMID: 34025764 PMC: 8127712. DOI: 10.1111/eva.13193.

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