Strong impact of thermal environment on the quantitative genetic basis of a key stress tolerance trait

Most organisms experience variable and sometimes suboptimal environments in their lifetime. While stressful environmental conditions are normally viewed as a strong selective force, they can also impact directly on the genetic basis of traits such as through environment-dependent gene action. Here,...

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Bibliographic Details
Published in:Heredity 2019-03, Vol.122 (3), p.315-325
Main Authors: Ørsted, Michael, Hoffmann, Ary Anthony, Rohde, Palle Duun, Sørensen, Peter, Kristensen, Torsten Nygaard
Format: Article
Language:English
Subjects:
Adaptation, Biological - genetics
Algorithms
Animals
Cold
Cold Temperature
Cold tolerance
Developmental plasticity
Drosophila melanogaster - genetics
Environment
Environmental conditions
Environmental impact
Evolution, Molecular
Fruit flies
Gene-Environment Interaction
Genetic diversity
Low temperature
Models, Genetic
Phenotype
Quantitative genetics
Quantitative Trait Loci
Quantitative Trait, Heritable
Stress, Physiological
Switches
Temperature
Temperature dependence
Temperature effects
Temperature tolerance
Thermal environments
Thermal resistance
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Summary:Most organisms experience variable and sometimes suboptimal environments in their lifetime. While stressful environmental conditions are normally viewed as a strong selective force, they can also impact directly on the genetic basis of traits such as through environment-dependent gene action. Here, we used the Drosophila melanogaster Genetic Reference Panel to investigate the impact of developmental temperature on variance components and evolutionary potential of cold tolerance. We reared 166 lines at five temperatures and assessed cold tolerance of adult male flies from each line and environment. We show (1) that the expression of genetic variation for cold tolerance is highly dependent on developmental temperature, (2) that the genetic correlation of cold tolerance between environments decreases as developmental temperatures become more distinct, (3) that the correlation between cold tolerance at individual developmental temperatures and plasticity for cold tolerance differs across developmental temperatures, and even switches sign across the thermal developmental gradient, and (4) that evolvability decrease with increasing developmental temperatures. Our results show that the quantitative genetic basis of low temperature tolerance is environment specific. This conclusion is important for the understanding of evolution in variable thermal environments and for designing experiments aimed at pinpointing candidate genes and performing functional analyses of thermal resistance.
ISSN:0018-067X
1365-2540
DOI:10.1038/s41437-018-0117-7