Abstract
Recombination's omnipresence in nature is one of the most intriguing problems in evolutionary biology. The question of why recombination exhibits certain general features is no less interesting than that of why it exists at all. One such feature is recombination's fitness dependence (FD). The so far developed population genetics models have focused on the evolution of FD recombination mainly in haploids, although the empirical evidence for this phenomenon comes mostly from diploids. Using numerical analysis of modifier models for infinite panmictic populations, we show here that FD recombination can be evolutionarily advantageous in diploids subjected to purifying selection. We ascribe this advantage to the differential rate of disruption of lower‐ versus higher‐fitness genotypes, which can be manifested in selected systems with at least three loci. We also show that if the modifier is linked to such selected system, it can additionally benefit from modifying this linkage in a fitness‐dependent manner. The revealed evolutionary advantage of FD recombination appeared robust to crossover interference within the selected system, either positive or negative. Remarkably, FD recombination was often favored in situations where any constant nonzero recombination was evolutionarily disfavored, implying a relaxation of the rather strict constraints on major parameters (e.g., selection intensity and epistasis) required for the evolutionary advantage of nonzero recombination formulated by classical models.
Highlights
Meiotic recombination is a process of reshuffling the parental genetic material, which takes place when a sexual organism produces its gametes
In the two following subsections, we present the results of competition between fitness dependence (FD) recombination and the corresponding optimal constant recombination rates (RRs), for cases with both zero and intermediate optimal constant RR
(e) The role of FD-induced crossover interference When examining the competition between FD recombination and its equivalent constant RR, we found that under FD-strategy, the population mean RR in the derived interval deviates from that expected under the assumption of independence: rAC rAB 1 rBC rBC 1 rAB
Summary
Meiotic recombination is a process of reshuffling the parental genetic material, which takes place when a sexual organism produces its gametes. Different constant RRs stopped being neutral one to another (in terms of both modifier-allele dynamics and population mean fitness), which allowed estimating the optimal constant RR.
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