Polygenic dynamics underlying the response of quantitative traits to directional selection

IF 1.2 4区生物学 Q4 ECOLOGY

Theoretical Population Biology Pub Date : 2024-04-26 DOI:10.1016/j.tpb.2024.04.006

Hannah Götsch , Reinhard Bürger

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引用次数: 0

Abstract

We study the response of a quantitative trait to exponential directional selection in a finite haploid population, both at the genetic and the phenotypic level. We assume an infinite sites model, in which the number of new mutations per generation in the population follows a Poisson distribution (with mean $Θ$ ) and each mutation occurs at a new, previously monomorphic site. Mutation effects are beneficial and drawn from a distribution. Sites are unlinked and contribute additively to the trait. Assuming that selection is stronger than random genetic drift, we model the initial phase of the dynamics by a supercritical Galton–Watson process. This enables us to obtain time-dependent results. We show that the copy-number distribution of the mutant in generation $n$ , conditioned on non-extinction until $n$ , is described accurately by the deterministic increase from an initial distribution with mean 1. This distribution is related to the absolutely continuous part $W^{+}$ of the random variable, typically denoted $W$ , that characterizes the stochasticity accumulating during the mutant’s sweep. A suitable transformation yields the approximate dynamics of the mutant frequency distribution in a Wright–Fisher population of size $N$ . Our expression provides a very accurate approximation except when mutant frequencies are close to 1. On this basis, we derive explicitly the (approximate) time dependence of the expected mean and variance of the trait and of the expected number of segregating sites. Unexpectedly, we obtain highly accurate approximations for all times, even for the quasi-stationary phase when the expected per-generation response and the trait variance have equilibrated. The latter refine classical results. In addition, we find that $Θ$ is the main determinant of the pattern of adaptation at the genetic level, i.e., whether the initial allele-frequency dynamics are best described by sweep-like patterns at few loci or small allele-frequency shifts at many. The number of segregating sites is an appropriate indicator for these patterns. The selection strength determines primarily the rate of adaptation. The accuracy of our results is tested by comprehensive simulations in a Wright–Fisher framework. We argue that our results apply to more complex forms of directional selection.

查看原文本刊更多论文

定量性状对定向选择反应的多基因动态。

我们研究了有限单倍体种群中数量性状在遗传和表型两个层面上对指数定向选择的响应。我们假设了一个无限位点模型，在该模型中，种群中每一代新突变的数量遵循泊松分布（均值为 Θ），每次突变都发生在一个新的、以前是单态的位点上。突变效应是有益的，且来自分布。突变位点是非连锁的，对性状的贡献是相加的。假设选择强于随机遗传漂变，我们用超临界加尔顿-沃森过程来模拟动态的初始阶段。这使我们能够获得随时间变化的结果。我们证明，在第 n 代之前突变体没有灭绝的条件下，突变体在第 n 代的拷贝数分布可以用从均值为 1 的初始分布开始的确定性增长来准确描述。该分布与随机变量的绝对连续部分 W+ 有关，通常用 W 表示，它描述了突变体扫掠过程中累积的随机性。我们的表达式提供了一个非常精确的近似值，除非突变频率接近 1。在此基础上，我们明确推导出性状的预期均值和方差以及预期分离位点数量的（近似）时间依赖性。出乎意料的是，我们在所有时间都得到了高度精确的近似值，甚至在预期每代反应和性状方差达到平衡的准稳态阶段也是如此。后者完善了经典结果。此外，我们还发现，Θ 是决定遗传水平适应模式的主要因素，也就是说，最初等位基因频率动态的最佳描述方式是在少数位点出现类似扫掠的模式，还是在许多位点出现等位基因频率的小幅移动。分离位点的数量是这些模式的适当指标。选择强度主要决定适应速率。我们在赖特-费舍框架下进行了综合模拟，检验了我们结果的准确性。我们认为，我们的结果适用于更复杂的定向选择形式。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Theoretical Population Biology 生物-进化生物学

CiteScore

2.50

自引率

14.30%

发文量

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.