Meiosis and the Evolution of Recombination at Low Mutation Rates

Meiosis and the Evolution of Recombination at Low Mutation Rates

Damian D. G. Gessler^a and Shizhong Xu^a
^a Department of Botany and Plant Sciences, University of California, Riverside, California 92521

Corresponding author: Damian D. G. Gessler, National Center for Genome Resources, 2935 Rodeo Park Dr. East, Santa Fe, NM 87505., ddg{at}ncgr.org (E-mail)

Communicating editor: W. STEPHAN

The classical understanding of recombination is that in largeasexual populations with multiplicative fitness, linkage disequilibriumis negligible, and thus there is no selective agent drivingan allele for recombination. This has led researchers to recognizethe importance of synergistic epistatic selection in generatingnegative linkage disequilibrium that thereby renders an advantageto recombination. Yet data on such selection is equivocal, andvarious works have shown that synergistic epistasis per se,when left unquantified in its magnitude or operation, is notsufficient to drive the evolution of recombination. Here weshow that neither it, nor any mechanism generating negativelinkage disequilibrium among fitness-related loci, is necessary.We demonstrate that a neutral gene for recombination can increasein frequency in a large population under a low mutation rateand strict multiplicative fitness. We work in a parameter rangewhere individuals have, on average, less than one mutation each,yet recombination can still evolve. We demonstrate this in twoways: first, by examining the consequences of recombinationcorrelated with misrepaired DNA damage and, second, by increasingthe probability of recombination with declining fitness. Interestingly,the allele spreads without repairing even a single DNA mutation.

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