Unckless Robert L, Orr H Allen
Am Nat. 2020 Mar;195(3):561-568. doi: 10.1086/707139. Epub 2020 Jan 15.
Most population genetic theory assumes that populations adapt to an environmental change without a change in population size. However, environmental changes might be so severe that populations decline in size and, without adaptation, become extinct. This "evolutionary rescue" scenario differs from traditional models of adaptation in that rescue involves a race between adaptation and extinction. While most previous work has usually focused on models of evolutionary rescue in haploids, here we consider diploids. In many species, diploidy introduces a novel feature into adaptation: adaptive evolution might occur either on sex chromosomes or on autosomes. Previous studies of nonrescue adaptation revealed that the relative rates of adaptation on the X chromosome versus autosomes depend on the dominance of beneficial mutations, reflecting differences in effective population size and the efficacy of selection. Here, we extend these results to evolutionary rescue and find that, given equal-sized chromosomes, there is greater parameter space in which the X is more likely to contribute to adaptation than the autosomes relative to standard nonrescue models. We also discuss how subtle effects of dominance can increase the chance of evolutionary rescue in diploids when absolute heterozygote fitness is close to 1. These effects do not arise in standard nonrescue models.
大多数群体遗传学理论假定群体在不改变群体大小的情况下适应环境变化。然而,环境变化可能非常剧烈,以至于群体规模减小,若不适应,就会灭绝。这种“进化拯救”情形与传统的适应模型不同,因为拯救涉及适应与灭绝之间的一场竞赛。虽然此前大多数研究通常聚焦于单倍体的进化拯救模型,但在此我们考虑二倍体。在许多物种中,二倍性给适应引入了一个新特征:适应性进化可能发生在性染色体上,也可能发生在常染色体上。先前关于非拯救适应的研究表明,X染色体与常染色体上的相对适应速率取决于有益突变的显性程度,这反映了有效群体大小和选择效率的差异。在此,我们将这些结果扩展到进化拯救,发现给定染色体大小相等的情况下,相对于标准的非拯救模型,存在更大的参数空间,其中X染色体比常染色体更有可能对适应做出贡献。我们还讨论了显性的微妙效应如何在绝对杂合子适合度接近1时增加二倍体进化拯救的机会。这些效应在标准的非拯救模型中不会出现。