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Publication type: Journal Article
Document type: Full Paper

Year: 2019

Author(s): Barghi, N; Tobler, R; Nolte, V; Jakšić, AM; Mallard, F; Otte, KA; Dolezal, M; Taus, T; Kofler, R; Schlötterer, C

Title: Genetic redundancy fuels polygenic adaptation in Drosophila.

Source: PLoS Biol. 2019; 17(2):e3000128



Authors Vetmeduni Vienna:

Barghi Neda,
Dolezal Marlies,
Jaksic Ana Marija,
Kofler Robert,
Mallard Francois Jean Robert,
Nolte Viola,
Otte Kathrin,
Schlötterer Christian,
Taus Thomas,
Tobler Raymond,

Vetmed Research Units
Institute of Population Genetics,
Platform Bioinformatics and Biostatistics,


Dryad Logo Data are deposited in Dryad | DataLink: https://doi.org/10.5061/dryad.rr137kn


Project(s): ERC ADG: The architecture of adaptation

Population Genetics


Abstract:
The genetic architecture of adaptive traits is of key importance to predict evolutionary responses. Most adaptive traits are polygenic-i.e., result from selection on a large number of genetic loci-but most molecularly characterized traits have a simple genetic basis. This discrepancy is best explained by the difficulty in detecting small allele frequency changes (AFCs) across many contributing loci. To resolve this, we use laboratory natural selection to detect signatures for selective sweeps and polygenic adaptation. We exposed 10 replicates of a Drosophila simulans population to a new temperature regime and uncovered a polygenic architecture of an adaptive trait with high genetic redundancy among beneficial alleles. We observed convergent responses for several phenotypes-e.g., fitness, metabolic rate, and fat content-and a strong polygenic response (99 selected alleles; mean s = 0.059). However, each of these selected alleles increased in frequency only in a subset of the evolving replicates. We discerned different evolutionary paradigms based on the heterogeneous genomic patterns among replicates. Redundancy and quantitative trait (QT) paradigms fitted the experimental data better than simulations assuming independent selective sweeps. Our results show that natural D. simulans populations harbor a vast reservoir of adaptive variation facilitating rapid evolutionary responses using multiple alternative genetic pathways converging at a new phenotypic optimum. This key property of beneficial alleles requires the modification of testing strategies in natural populations beyond the search for convergence on the molecular level.


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