The best of both worlds: Combining population genetic and quantitative genetic models

IF 1.2 4区 生物学 Q4 ECOLOGY Theoretical Population Biology Pub Date : 2022-12-01 DOI:10.1016/j.tpb.2022.10.002
L. Dekens , S.P. Otto , V. Calvez
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引用次数: 3

Abstract

Numerous traits under migration–selection balance are shown to exhibit complex patterns of genetic architecture with large variance in effect sizes. However, the conditions under which such genetic architectures are stable have yet to be investigated, because studying the influence of a large number of small allelic effects on the maintenance of spatial polymorphism is mathematically challenging, due to the high complexity of the systems that arise. In particular, in the most simple case of a haploid population in a two-patch environment, while it is known from population genetics that polymorphism at a single major-effect locus is stable in the symmetric case, there exist no analytical predictions on how this polymorphism holds when a polygenic background also contributes to the trait. Here we propose to answer this question by introducing a new eco-evo methodology that allows us to take into account the combined contributions of a major-effect locus and of a quantitative background resulting from small-effect loci, where inheritance is encoded according to an extension to the infinitesimal model. In a regime of small variance contributed by the quantitative loci, we justify that traits are concentrated around the major alleles, according to a normal distribution, using new convex analysis arguments. This allows a reduction in the complexity of the system using a separation of time scales approach. We predict an undocumented phenomenon of loss of polymorphism at the major-effect locus despite strong selection for local adaptation, because the quantitative background slowly disrupts the rapidly established polymorphism at the major-effect locus, which is confirmed by individual-based simulations. Our study highlights how segregation of a quantitative background can greatly impact the dynamics of major-effect loci by provoking migrational meltdowns. We also provide a comprehensive toolbox designed to describe how to apply our method to more complex population genetic models.

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两全其美:结合群体遗传和数量遗传模型
在迁移-选择平衡下,许多性状表现出复杂的遗传结构模式,其效应大小差异很大。然而,这种遗传结构稳定的条件尚未得到研究,因为研究大量小等位基因效应对空间多态性维持的影响在数学上是具有挑战性的,因为所产生的系统非常复杂。特别是,在单倍体群体中最简单的情况下,在两个斑块的环境中,虽然从群体遗传学中我们知道,在对称的情况下,单个主效应位点的多态性是稳定的,但当多基因背景也有助于该性状时,这种多态性是如何保持的,目前还没有分析预测。在这里,我们建议通过引入一种新的生态进化方法来回答这个问题,该方法允许我们考虑到主要影响位点和由小影响位点产生的定量背景的综合贡献,其中遗传是根据对无穷小模型的扩展进行编码的。在由定量位点贡献的小方差制度中,我们证明性状集中在主要等位基因周围,根据正态分布,使用新的凸分析参数。这允许使用时间尺度分离方法降低系统的复杂性。我们预测,尽管有很强的局部适应选择,但主效应位点的多态性丢失现象并未记录,因为定量背景缓慢地破坏了主效应位点快速建立的多态性,这已被基于个体的模拟所证实。我们的研究强调了定量背景的分离如何通过引发迁移熔融而极大地影响主要效应位点的动态。我们还提供了一个全面的工具箱,旨在描述如何将我们的方法应用于更复杂的群体遗传模型。
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来源期刊
Theoretical Population Biology
Theoretical Population Biology 生物-进化生物学
CiteScore
2.50
自引率
14.30%
发文量
43
审稿时长
6-12 weeks
期刊介绍: An interdisciplinary journal, Theoretical Population Biology presents articles on theoretical aspects of the biology of populations, particularly in the areas of demography, ecology, epidemiology, evolution, and genetics. Emphasis is on the development of mathematical theory and models that enhance the understanding of biological phenomena. Articles highlight the motivation and significance of the work for advancing progress in biology, relying on a substantial mathematical effort to obtain biological insight. The journal also presents empirical results and computational and statistical methods directly impinging on theoretical problems in population biology.
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