Publication details

Novelty and Convergence in Adaptation to Whole Genome Duplication

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Authors

BOHUTINSKA M. ALSTON M. MONNAHAN P. MALÍK MANDÁKOVÁ Terezie BRAY S. PAAJANEN P. KOLAR F. YANT L.

Year of publication 2021
Type Article in Periodical
Magazine / Source Molecular Biology and Evolution
MU Faculty or unit

Central European Institute of Technology

Citation
Web https://academic.oup.com/mbe/article/38/9/3910/6203814
Doi http://dx.doi.org/10.1093/molbev/msab096
Keywords polyploidy; convergence; genome duplication; adaptation
Description Whole genome duplication (WGD) can promote adaptation but is disruptive to conserved processes, especially meiosis. Studies in Arabidopsis arenosa revealed a coordinated evolutionary response to WGD involving interacting proteins controlling meiotic crossovers, which are minimized in an autotetraploid (within-species polyploid) to avoid missegregation. Here, we test whether this surprising flexibility of a conserved essential process, meiosis, is recapitulated in an independent WGD system, Cardamine amara, 17 My diverged from A. arenosa. We assess meiotic stability and perform population-based scans for positive selection, contrasting the genomic response to WGD in C. amara with that of A. arenosa. We found in C amara the strongest selection signals at genes with predicted functions thought important to adaptation to WGD: meiosis, chromosome remodeling, cell cycle, and ion transport. However, genomic responses to WGD in the two species differ: minimal ortholog-level convergence emerged, with none of the meiosis genes found in A. arenosa exhibiting strong signal in C amara. This is consistent with our observations of lower meiotic stability and occasional clonal spreading in diploid C amara, suggesting that nascent C. amara autotetraploid lineages were pre-adapted by their diploid lifestyle to survive while enduring reduced meiotic fidelity. However, in contrast to a lack of ortholog convergence, we see process-level and network convergence in DNA management, chromosome organization, stress signaling, and ion homeostasis processes. This gives the first insight into the salient adaptations required to meet the challenges of a WGD state and shows that autopolyploids can utilize multiple evolutionary trajectories to adapt to WGD.
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