Canonical correlations reveal adaptive loci and phenotypic responses to climate in perennial ryegrass

Germplasm from perennial ryegrass (Lolium perenne L.) natural populations is useful for breeding because of its adaptation to a wide range of climates. Climate‐adaptive genes can be detected from associations between genotype, phenotype and climate but an integrated framework for the analysis of the...

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Bibliographic Details
Published in:Molecular ecology resources 2021-04, Vol.21 (3), p.849-870
Main Authors: Blanco‐Pastor, José Luis, Barre, Philippe, Keep, Thomas, Ledauphin, Thomas, Escobar‐Gutiérrez, Abraham, Roschanski, Anna Maria, Willner, Evelyn, Dehmer, Klaus J., Hegarty, Matthew, Muylle, Hilde, Veeckman, Elisabeth, Vandepoele, Klaas, Ruttink, Tom, Roldán‐Ruiz, Isabel, Manel, Stéphanie, Sampoux, Jean‐Paul
Format: Article
Language:English
Subjects:
Adaptation
Agricultural sciences
agriculture
Annotations
Breeding
Climate
Climate adaptation
Climate change
Correlation analysis
ecological genetics
Genes
Genomes
Genotypes
Germplasm
landscape genetics
Life Sciences
Loci
Lolium perenne
Natural populations
Outliers (statistics)
Phenotypes
Plant species
Polygenic inheritance
quantitative genetics
Rainy season
Winter
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Summary:Germplasm from perennial ryegrass (Lolium perenne L.) natural populations is useful for breeding because of its adaptation to a wide range of climates. Climate‐adaptive genes can be detected from associations between genotype, phenotype and climate but an integrated framework for the analysis of these three sources of information is lacking. We used two approaches to identify adaptive loci in perennial ryegrass and their effect on phenotypic traits. First, we combined Genome‐Environment Association (GEA) and GWAS analyses. Then, we implemented a new test based on a Canonical Correlation Analysis (CANCOR) to detect adaptive loci. Furthermore, we improved the previous perennial ryegrass gene set by de novo gene prediction and functional annotation of 39,967 genes. GEA‐GWAS revealed eight outlier loci associated with both environmental variables and phenotypic traits. CANCOR retrieved 633 outlier loci associated with two climatic gradients, characterized by cold‐dry winter versus mild‐wet winter and long rainy season versus long summer, and pointed out traits putatively conferring adaptation at the extremes of these gradients. Our CANCOR test also revealed the presence of both polygenic and oligogenic climatic adaptations. Our gene annotation revealed that 374 of the CANCOR outlier loci were positioned within or close to a gene. Co‐association networks of outlier loci revealed a potential utility of CANCOR for investigating the interaction of genes involved in polygenic adaptations. The CANCOR test provides an integrated framework to analyse adaptive genomic diversity and phenotypic responses to environmental selection pressures that could be used to facilitate the adaptation of plant species to climate change.
ISSN:1755-098X
1755-0998
DOI:10.1111/1755-0998.13289