Genome‐environment association methods comparison supports omnigenic adaptation to ecological niche in malaria vector mosquitoes

DeRaad, Devon A.; Cobos, Marlon E.; Alkishe, Abdelghafar; Ashraf, Uzma; Ahadji-Dabla, Koffi Mensah; Nuñez‐Penichet, Claudia; Peterson, A. Townsend

doi:10.1111/mec.16094

Cited by 13 publications

(14 citation statements)

References 90 publications

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“…If environmental variables covary with a pattern of isolation by distance, many alleles will exhibit associations with environmental variation and simple GEA analyses may often result in false positives. There are multiple methods that build population structure into GEA analyses (reviewed in Hoban et al 2016), but these can result in false negatives if the true drivers of adaptation have spatial patterns in allele frequency that align with population structure (DeRaad et al 2021). However, under the assumption that most genes in the genome are not contributing to adaptation, the rank-order of GEA summary statistics (e.g.…”

Section: Discussionmentioning

confidence: 99%

Using genome scans to identify genes used repeatedly for adaptation

Booker

Yeaman

Whitlock

2022

Preprint

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Adaptation occurring in similar genes or genomic regions in distinct lineages provides evolutionary biologists with a glimpse at the fundamental opportunities for and constraints to diversification. With the widespread availability of high throughput sequencing technologies and the development of population genetic methods to identify the genetic basis of adaptation, studies have begun to compare the evidence for adaptation at the molecular level among distinct lineages. However, methods to study repeated adaptation are often oriented towards genome-wide testing to identify a set of genes with signatures of repeated use, rather than evaluating the significance at the level of an individual gene. In this study, we propose PicMin, a novel statistical method derived from the theory of order statistics that can test for repeated molecular evolution to estimate significance at the level of an individual gene, using the results of genome scans. This method is generalizable to any number of lineages and indeed, statistical power to detect repeated adaptation increases with the number of lineages that have signals of repeated adaptation of a given gene in multiple lineages. An implementation of the method written for R can be downloaded from https://github.com/TBooker/PicMin.

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Section: Discussionmentioning

confidence: 99%

Using genome scans to identify genes used repeatedly for adaptation

Booker

Yeaman

Whitlock

2022

Preprint

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“…There are a variety of confounding factors that generate a heterogeneous pattern of variation across the genome and thereby create a challenge in the robust identification of genomic regions associated with certain adaptive traits. DeRaad et al (2021) utilized a genome‐environment association (GEA) testing approach to leverage publicly available Anopheles gambiae genomes to differentiate true signals of genome environment adaptation from background variation resulting from alternative evolutionary processes. Colicchio et al (2021) utilized similar GEA approaches using whole‐genome re‐sequencing data from Mimulus guttatus populations to identify candidate genes associated with climatic variables in specialized metabolism, drought resistance, and development.…”

Section: Genetic Basis Of Adaptationmentioning

confidence: 99%

Seeing the whole picture: What molecular ecology is gaining from whole genomes

et al. 2021

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“…The special issue also includes a suite of papers work that use WGS to uncover the genetic basis of adaptive traits including immune response (Batley et al 2021; Moreno Santillán et al, 2021) and environmental heterogeneity (Nunez et al, 2021). Multiple studies take advantage of the comprehensive genomic data to examine polygenic adaptations (Montejo‐Kovacevich et al, 2021; Pereira et al, 2021), while others use WGS to conduct genotype environment association (GEA) analysis, revealing a fine‐scale look at genomic regions involved in adaptation to particular environmental variables (Colicchio et al, 2021; DeRaad et al, 2021). As the editors write in their conclusion, “the contributions presented in this special issue herald a new era in molecular ecology, as we anticipate that a burgeoning and widespread application of WGS will provide unprecedented insights into consequential questions in ecology and evolution,” (Taylor, Jensen, et al, 2021).…”

Section: Highlights Of 2021mentioning

confidence: 99%