Grieshop Karl, Maurizio Paul L, Arnqvist Göran, Berger David
Animal Ecology, Department of Ecology and Genetics Uppsala University Uppsala SE-75236 Sweden.
Department of Ecology and Evolutionary Biology University of Toronto Toronto ON M5S 3B2 Canada.
Evol Lett. 2021 Jun 26;5(4):328-343. doi: 10.1002/evl3.239. eCollection 2021 Aug.
Theory predicts that the ability of selection and recombination to purge mutation load is enhanced if selection against deleterious genetic variants operates more strongly in males than females. However, direct empirical support for this tenet is limited, in part because traditional quantitative genetic approaches allow dominance and intermediate-frequency polymorphisms to obscure the effects of the many rare and partially recessive deleterious alleles that make up the main part of a population's mutation load. Here, we exposed the partially recessive genetic load of a population of seed beetles via successive generations of inbreeding, and quantified its effects by measuring heterosis-the increase in fitness experienced when masking the effects of deleterious alleles by heterozygosity-in a fully factorial sex-specific diallel cross among 16 inbred strains. Competitive lifetime reproductive success (i.e., fitness) was measured in male and female outcrossed Fs as well as inbred parental "selfs," and we estimated the 4 × 4 male-female inbred-outbred genetic covariance matrix for fitness using Bayesian Markov chain Monte Carlo simulations of a custom-made general linear mixed effects model. We found that heterosis estimated independently in males and females was highly genetically correlated among strains, and that heterosis was strongly negatively genetically correlated to outbred male, but not female, fitness. This suggests that genetic variation for fitness in males, but not in females, reflects the amount of (partially) recessive deleterious alleles segregating at mutation-selection balance in this population. The population's mutation load therefore has greater potential to be purged via selection in males. These findings contribute to our understanding of the prevalence of sexual reproduction in nature and the maintenance of genetic variation in fitness-related traits.
理论预测,如果针对有害遗传变异的选择在雄性中比在雌性中作用更强,那么选择和重组清除突变负荷的能力就会增强。然而,这一原则的直接实证支持有限,部分原因是传统的数量遗传学方法使显性和中频多态性掩盖了构成种群突变负荷主要部分的许多罕见且部分隐性有害等位基因的影响。在这里,我们通过连续几代的近亲繁殖揭示了一群种子甲虫的部分隐性遗传负荷,并通过测量杂种优势——当杂合性掩盖有害等位基因的影响时所经历的适应性增加——在16个近交系之间的全因子性别特异性双列杂交中对其影响进行了量化。在雄性和雌性杂交F1代以及近交亲本“自交”中测量了竞争性终生繁殖成功率(即适应性),并且我们使用定制的广义线性混合效应模型的贝叶斯马尔可夫链蒙特卡罗模拟估计了适应性的4×4雄性 - 雌性近交 - 杂交遗传协方差矩阵。我们发现,在雄性和雌性中独立估计的杂种优势在品系间具有高度的遗传相关性,并且杂种优势与杂交雄性的适应性呈强烈的负遗传相关,但与雌性适应性无关。这表明雄性而非雌性的适应性遗传变异反映了该种群中在突变 - 选择平衡状态下分离的(部分)隐性有害等位基因的数量。因此,该种群的突变负荷通过雄性选择有更大的清除潜力。这些发现有助于我们理解自然界中两性生殖的普遍性以及与适应性相关性状的遗传变异的维持。
