Population structure promotes the evolution of costly sex in artificial gene networks

Whitlock, Alexander O. B.; Azevedo, Ricardo B. R.; Burch, Christina L.

doi:10.1111/evo.13733

Cited by 7 publications

(9 citation statements)

References 71 publications

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“…That these early studies of inbreeding and heterosis are relevant to the evolution of sex and recombination is not a new idea [11,20,21], and is subsumed under Lewontin's general proclamation that "every discovery in classical and population genetics has depended on some sort of inbreeding experiment" [20,22,23]. Since these early studies, several more recent studies have shown that different kinds of population structure can create conditions that make recombination across locally-evolving subpopulations favorable [10][11][12][24][25][26][27][28][29]. These studies find that population structure can help to maintain the variation without which recombination would be neither advantageous nor disadvantageous, and they identify conditions under which recombination is advantageous.…”

Section: Introductionmentioning

confidence: 99%

Natural selection promotes the evolution of recombination 1: between the products of natural selection*

Gerrish

Galeota-Sprung

Sniegowski

et al. 2021

Preprint

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Shuffling one's genetic material with another individual seems a risky endeavor more likely to decrease than to increase offspring fitness. This intuitive argument is commonly employed to explain why the ubiquity of sex and recombination in nature is enigmatic. It is predicated on the notion that natural selection assembles selectively well-matched combinations of genes that recombination would break up resulting in low-fitness offspring -- a notion so intuitive that it is often stated in the literature as a self-evident premise. We show, however, that this common premise is only self evident on the surface and that, upon closer examination, it is fundamentally flawed: we find that natural selection in fact has an encompassing tendency to assemble selectively mismatched combinations of alleles; recombination breaks up these selectively mismatched combinations (on average), assembles selectively matched combinations, and should thus be favored. The new perspective our findings offer suggests that sex and recombination are not so enigmatic but are instead natural and unavoidable byproducts of natural selection.

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Section: Introductionmentioning

confidence: 99%

Natural selection promotes the evolution of recombination 1: between the products of natural selection*

Gerrish

Galeota-Sprung

Sniegowski

et al. 2021

Preprint

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show abstract

“…Components X (n) and Y (n) , therefore, while not What we have shown so far is that, if recombination occurs across the products of natural selection, such as fixed genotypes in different populations, subpopulations, demes or competing clones, the resulting offspring should be more fit than their parents, on average. This effect provides novel insight into established observations that population structure can favor recombination [29][30][31][32][33] and may even speak to notions that out-crossing can create hybrid vigour (heterosis).…”

Section: Settingmentioning

confidence: 79%

Natural selection and the advantage of recombination

Gerrish¹,

Galeota-Sprung

Cordero

et al. 2020

Preprint

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Exchanging genetic material with another individual seems risky from an evolutionary standpoint, and yet living things across all scales and phyla do so quite regularly. The pervasiveness of such genetic exchange, or recombination, in nature has defied explanation since the time of Darwin. Conditions that favor recombination, however, are well-understood: recombination is advantageous when the genomes of individuals in a population contain more selectively mismatched combinations of alleles than can be explained by chance alone. Recombination remedies this imbalance by shuffling alleles across individuals. The great difficulty in explaining the ubiquity of recombination in nature lies in identifying a source of this imbalance that is comparably ubiquitous. Intuitively, it would seem that natural selection should reduce the imbalance by favoring selectively matched combinations of high-fitness alleles, thereby opposing the evolution of recombination. We show, however, that this intuition is wrong; to the contrary, we find that natural selection has an encompassing tendency to assemble selectively mismatched combinations of alleles (the products of natural selection), thereby increasing the imbalance and promoting the evolution of recombination. We further show that population dynamics that lead to the fixation of these selectively mismatched genotypes (the process of natural selection) themselves produce an average imbalance that promotes the evolution of recombination. This fact is completely independent of the distribution of allelic fitness effects and is primarily due to the additive component of those effects. Our findings provide a novel vantage point from which the enormous body of established work on the evolution of sex and recombination may be viewed anew. They further suggest that recombination evolved and is maintained more as an unavoidable byproduct of natural selection than as a catalyst.

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“…; Whitlock et al. ) and cooperation (Nowak ; Taylor and Nowak ) in sufficiently structured populations. Similar to its effect on mutators, population subdivision allows costly recombiner alleles to persist in a metapopulation despite indirect selection against the recombination load—the cost of unfavorable combinations of alleles.…”

Section: Resultsmentioning

confidence: 99%

Migration promotes mutator alleles in subdivided populations

2019

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Mutator alleles that elevate the genomic mutation rate may invade nonrecombining populations by hitchhiking with beneficial mutations. Mutators have been repeatedly observed to take over adapting laboratory populations and have been found at high frequencies in both microbial pathogen and cancer populations in nature. Recently, we have shown that mutators are only favored by selection in sufficiently large populations and transition to being disfavored as population size decreases. This population size‐dependent sign inversion in selective effect suggests that population structure may also be an important determinant of mutation rate evolution. Although large populations may favor mutators, subdividing such populations into sufficiently small subpopulations (demes) might effectively inhibit them. On the other hand, migration between small demes that otherwise inhibit hitchhiking may promote mutator fixation in the whole metapopulation. Here, we use stochastic, agent‐based simulations and evolution experiments with the yeast Saccharomyces cerevisiae to show that mutators can, indeed, be favored by selection in subdivided metapopulations composed of small demes connected by sufficient migration. In fact, we show that population structure plays a previously unsuspected role in promoting mutator success in subdivided metapopulations when migration is rare.

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Population structure promotes the evolution of costly sex in artificial gene networks

Cited by 7 publications

References 71 publications

Natural selection promotes the evolution of recombination 1: between the products of natural selection*

Natural selection promotes the evolution of recombination 1: between the products of natural selection*

Natural selection and the advantage of recombination

Migration promotes mutator alleles in subdivided populations

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