A gene-based model of fitness and its implications for genetic variation

Parul Johri, Brian Charlesworth
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Abstract

A widely used model of the effects of mutations on fitness (the ″sites″ model) assumes that heterozygous recessive or partially recessive deleterious mutations at different sites in a gene complement each other, similarly to mutations in different genes. However, the general lack of complementation between major effect allelic mutations suggests an alternative possibility, the ″gene″ model. This assumes that a pair of heterozygous deleterious mutations in trans behave effectively as homozygotes, so that the fitnesses of trans heterozygotes are lower than those of cis heterozygotes. We examine the properties of the two different models, using both analytical and simulation methods. We show that the gene model results in a slightly lower mutational load, but a much smaller inbreeding load, than the sites model, implying that standard predictions of mutational contributions to inbreeding depression may be overestimates. The gene model also predicts positive linkage disequilibrium (LD) between derived variants within the coding sequence under conditions when the sites model predicts zero or slightly negative LD. We also show that focussing on rare variants when examining patterns of LD, especially with Lewontin′s D′ measure, is likely to produce misleading results with respect to inferences concerning the causes of the sign of LD. Synergistic epistasis between pairs of mutations was also modeled; it is less likely to produce negative LD under the gene model than the sites model. The theoretical results are discussed in relation to data on inbreeding load in Drosophila melanogaster and patterns of LD in natural populations of several species.
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基于基因的适应性模型及其对遗传变异的影响
关于突变对适应性影响的一个广泛使用的模型(″位点″模型)假定,一个基因中不同位点的杂合隐性或部分隐性有害突变是互补的,类似于不同基因中的突变。然而,主要效应等位基因突变之间普遍缺乏互补性,这就提出了另一种可能性,即″基因″模型。该模型假定,一对反式杂合有害突变的行为实际上与同式杂合突变相同,因此反式杂合突变的适合度低于顺式杂合突变的适合度。我们使用分析和模拟方法研究了这两种不同模型的特性。我们发现,基因模型的突变负荷略低于位点模型,但近交负荷却小得多,这意味着对近交抑郁的突变贡献的标准预测可能是高估了。在位点模型预测 LD 为零或略微为负的情况下,基因模型还预测编码序列内衍生变体之间存在正的连锁不平衡(LD)。我们还表明,在研究 LD 模式时,尤其是使用 Lewontin 的 D′ 测量时,如果只关注罕见变异,很可能会在推断 LD 符号的原因方面产生误导性结果。我们还对成对突变之间的协同外显进行了建模;与位点模型相比,在基因模型下产生负 LD 的可能性较小。本文结合黑腹果蝇近交负荷的数据和几个物种自然种群的 LD 模式,对理论结果进行了讨论。
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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