Institut de Biologie de l' École Normale Supérieure (IBENS), École Normale Supérieure, CNRS, Inserm, PSL Research University, Paris, France.
Instituto Gulbenkian de Ciência, Oeiras, Portugal.
PLoS Genet. 2018 Nov 1;14(11):e1007731. doi: 10.1371/journal.pgen.1007731. eCollection 2018 Nov.
Evolutionary responses to environmental change depend on the time available for adaptation before environmental degradation leads to extinction. Explicit tests of this relationship are limited to microbes where adaptation usually depends on the sequential fixation of de novo mutations, excluding standing variation for genotype-by-environment fitness interactions that should be key for most natural species. For natural species evolving from standing genetic variation, adaptation at slower rates of environmental change may be impeded since the best genotypes at the most extreme environments can be lost during evolution due to genetic drift or founder effects. To address this hypothesis, we perform experimental evolution with self-fertilizing populations of the nematode Caenorhabditis elegans and develop an inference model to describe natural selection on extant genotypes under environmental change. Under a sudden environmental change, we find that selection rapidly increases the frequency of genotypes with high fitness in the most extreme environment. In contrast, under a gradual environmental change selection first favors genotypes that are worse at the most extreme environment. We demonstrate with a second set of evolution experiments that, as a consequence of slower environmental change and thus longer periods to reach the most extreme environments, genetic drift and founder effects can lead to the loss of the most beneficial genotypes. We further find that maintenance of standing genetic variation can retard the fixation of the best genotypes in the most extreme environment because of interference between them. Taken together, these results show that slower environmental change can hamper adaptation from standing genetic variation and they support theoretical models indicating that standing variation for genotype-by-environment fitness interactions critically alters the pace and outcome of adaptation under environmental change.
进化对环境变化的响应取决于在环境退化导致灭绝之前适应的时间。这种关系的明确测试仅限于微生物,在微生物中,适应通常取决于新突变的连续固定,排除了基因型与环境适应性相互作用的固定变异,而基因型与环境适应性相互作用应该是大多数自然物种的关键。对于从现有遗传变异中进化而来的自然物种,由于在最极端环境下的最佳基因型可能由于遗传漂变或奠基者效应而在进化过程中丢失,因此,在环境变化较慢的情况下,适应可能会受到阻碍。为了解决这个假设,我们对自交的秀丽隐杆线虫种群进行了实验进化,并开发了一个推断模型来描述环境变化下现存基因型的自然选择。在环境突然变化的情况下,我们发现选择迅速增加了在最极端环境中具有高适应性的基因型的频率。相比之下,在环境逐渐变化的情况下,选择首先有利于在最极端环境中表现较差的基因型。我们通过第二组进化实验证明,由于环境变化较慢,到达最极端环境的时间较长,遗传漂变和奠基者效应可能导致最有益的基因型丢失。我们还发现,由于它们之间的干扰,维持现有遗传变异会延迟最极端环境中最佳基因型的固定。总的来说,这些结果表明,环境变化较慢会阻碍从现有遗传变异中进行适应,并且支持理论模型,即基因型与环境适应性相互作用的固定变异会极大地改变环境变化下适应的速度和结果。
