Precipitation and Vegetation Shape Patterns of Genomic and Craniometric Variation in the Central African Rodent

Overview

Journal Proc Biol Sci

Specialty Biology

Date 2020 Jul 9

PMID 32635865

Citations 8

Authors

Katy Morgan

Jean-Francois Mboumba

Stephan Ntie

Patrick Mickala

Courtney A Miller

Ying Zhen

Ryan J Harrigan

Vinh Le Underwood

Kristen Ruegg

Eric B Fokam

Geraud C Tasse Taboue

Paul R Sesink Clee

Trevon Fuller

Thomas B Smith

Nicola M Anthony

Affiliations

Soon will be listed here.

Abstract

Predicting species' capacity to respond to climate change is an essential first step in developing effective conservation strategies. However, conservation prioritization schemes rarely take evolutionary potential into account. Ecotones provide important opportunities for diversifying selection and may thus constitute reservoirs of standing variation, increasing the capacity for future adaptation. Here, we map patterns of environmentally associated genomic and craniometric variation in the central African rodent to identify areas with the greatest turnover in genomic composition. We also project patterns of environmentally associated genomic variation under future climate change scenarios to determine where populations may be under the greatest pressure to adapt. While precipitation gradients influence both genomic and craniometric variation, vegetation structure is also an important determinant of craniometric variation. Areas of elevated environmentally associated genomic and craniometric variation overlap with zones of rapid ecological transition underlining their importance as reservoirs of evolutionary potential. We also find that populations in the Sanaga river basin, central Cameroon and coastal Gabon are likely to be under the greatest pressure from climate change. Lastly, we make specific conservation recommendations on how to protect zones of high evolutionary potential and identify areas where populations may be the most susceptible to climate change.

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