Male meiotic recombination rate varies with seasonal temperature fluctuations in wild populations of autotetraploid Arabidopsis arenosa

• Published in: Molecular ecology Vol. 30; no. 19; pp. 4630 - 4641
• Main Authors: Weitz, Andrew P., Dukic, Marinela, Zeitler, Leo, Bomblies, Kirsten
• Format: Journal Article
• Language: English
• Published: Oxford Blackwell Publishing Ltd 01.10.2021; John Wiley and Sons Inc
• Subjects: Arabidopsis arenosa; Autotetraploid; Cell division; Correlation; Eukaryotes; evolution; Extreme values; Fertility; Fluctuations; Gametes; Genetics; Genomes; Homologous recombination; Homology; Laboratories; Low temperature; Meiosis; Natural populations; Original; Plastic properties; Plasticity; polyploid; Polyploidy; Population genetics; Population studies; Populations; Questions; recombination; Reproduction (biology); Seasonal variations; Temperature
• ISSN: 0962-1083; 1365-294X
• DOI: 10.1111/mec.16084

Meiosis, the cell division by which eukaryotes produce haploid gametes, is essential for fertility in sexually reproducing species. This process is sensitive to temperature, and can fail outright at temperature extremes. At less extreme values, temperature affects the genome‐wide rate of homologous recombination, which has important implications for evolution and population genetics. Numerous studies in laboratory conditions have shown that recombination rate plasticity is common, perhaps nearly universal, among eukaryotes. These studies have also shown that variation in the length or timing of stresses can strongly affect results, raising the important question whether these findings translate to more variable field conditions. Moreover, lower or higher recombination rate could cause certain kinds of meiotic aberrations, especially in polyploid species—raising the additional question whether temperature fluctuations in field conditions cause problems. Here, we tested whether (1) recombination rate varies across a season in the wild in two natural populations of autotetraploid Arabidopsis arenosa, (2) whether recombination rate correlates with temperature fluctuations in nature, and (3) whether natural temperature fluctuations might cause meiotic aberrations. We found that plants in two genetically distinct populations showed a similar plastic response with recombination rate increases correlated with both high and low temperatures. In addition, increased recombination rate correlated with increased multivalent formation, especially at lower temperature, hinting that polyploids in particular may suffer meiotic problems in conditions they encounter in nature. Our results show that studies of recombination rate plasticity done in laboratory settings inform our understanding of what happens in nature.