Division of Evolutionary Biology, Faculty of Biology, Ludwig-Maximilians-Universität Munich, Munich, Germany.
Science for Life Laboratory, Uppsala University, Uppsala, Sweden.
Nat Ecol Evol. 2021 Mar;5(3):338-349. doi: 10.1038/s41559-020-01363-2. Epub 2021 Jan 11.
Adaptive divergence is the key evolutionary process generating biodiversity by means of natural selection. Yet, the conditions under which it can arise in the presence of gene flow remain contentious. To address this question, we subjected 132 sexually reproducing fission yeast populations, sourced from two independent genetic backgrounds, to disruptive ecological selection and manipulated the level of migration between environments. Contrary to theoretical expectations, adaptive divergence was most pronounced when migration was either absent (allopatry) or maximal (sympatry), but was much reduced at intermediate rates (parapatry and local mating). This effect was apparent across central life-history components (survival, asexual growth and mating) but differed in magnitude between ancestral genetic backgrounds. The evolution of some fitness components was constrained by pervasive negative correlations (trade-off between asexual growth and mating), while others changed direction under the influence of migration (for example, survival and mating). In allopatry, adaptive divergence was mainly conferred by standing genetic variation and resulted in ecological specialization. In sympatry, divergence was mainly mediated by novel mutations enriched in a subset of genes and was characterized by the repeated emergence of two strategies: an ecological generalist and an asexual growth specialist. Multiple loci showed consistent evidence for antagonistic pleiotropy across migration treatments providing a conceptual link between adaptation and divergence. This evolve-and-resequence experiment shows that rapid ecological differentiation can arise even under high rates of gene flow. It further highlights that adaptive trajectories are governed by complex interactions of gene flow, ancestral variation and genetic correlations.
适应辐射是通过自然选择产生生物多样性的关键进化过程。然而,在存在基因流的情况下,它能够产生的条件仍然存在争议。为了解决这个问题,我们对来自两个独立遗传背景的 132 个有性繁殖的裂殖酵母种群进行了破坏性的生态选择,并操纵了环境之间的迁移水平。与理论预期相反,当迁移要么不存在(异域)要么最大(同域)时,适应性辐射最为明显,但在中间速率(邻域和局部交配)时则大大减少。这种影响在核心生命史成分(生存、无性生长和交配)中都很明显,但在祖先遗传背景之间存在差异。一些适应度成分的进化受到普遍存在的负相关(无性生长和交配之间的权衡)的限制,而其他成分在迁移的影响下改变了方向(例如,生存和交配)。在异域,适应性辐射主要是由现成的遗传变异赋予的,并导致生态特化。在同域,分歧主要是由基因子集富集的新突变介导的,其特征是两种策略的反复出现:生态广适性和无性生长专化性。多个基因座在所有迁移处理中都表现出一致的拮抗多效性证据,为适应和分化之间提供了一个概念上的联系。这个进化和重测序实验表明,即使在高基因流率下,也可以快速产生生态分化。它进一步强调了适应轨迹是由基因流、祖先变异和遗传相关性的复杂相互作用所决定的。
