The Francis Crick Institute, London, United Kingdom.
Division of Infection & Immunity, University College London, London, United Kingdom.
PLoS Comput Biol. 2019 Jul 23;15(7):e1007177. doi: 10.1371/journal.pcbi.1007177. eCollection 2019 Jul.
Developmental system drift is a likely mechanism for the origin of hybrid incompatibilities between closely related species. We examine here the detailed mechanistic basis of hybrid incompatibilities between two allopatric lineages, for a genotype-phenotype map of developmental system drift under stabilising selection, where an organismal phenotype is conserved, but the underlying molecular phenotypes and genotype can drift. This leads to number of emergent phenomenon not obtainable by modelling genotype or phenotype alone. Our results show that: 1) speciation is more rapid at smaller population sizes with a characteristic, Orr-like, power law, but at large population sizes slow, characterised by a sub-diffusive growth law; 2) the molecular phenotypes under weakest selection contribute to the earliest incompatibilities; and 3) pair-wise incompatibilities dominate over higher order, contrary to previous predictions that the latter should dominate. The population size effect we find is consistent with previous results on allopatric divergence of transcription factor-DNA binding, where smaller populations have common ancestors with a larger drift load because genetic drift favours phenotypes which have a larger number of genotypes (higher sequence entropy) over more fit phenotypes which have far fewer genotypes; this means less substitutions are required in either lineage before incompatibilities arise. Overall, our results indicate that biophysics and population size provide a much stronger constraint to speciation than suggested by previous models, and point to a general mechanistic principle of how incompatibilities arise the under stabilising selection for an organismal phenotype.
发育系统漂变是近缘物种间杂种不亲和性起源的一种可能机制。我们在这里研究了两个异地谱系之间杂种不亲和性的详细机制基础,即在稳定选择下发育系统漂变的基因型-表型图谱中,生物体表现型是保守的,但潜在的分子表型和基因型可以漂变。这导致了一些仅通过建模基因型或表型无法获得的新兴现象。我们的结果表明:1)在较小的种群中,物种形成更快,具有特征性的 Orr 样幂律,但在较大的种群中,物种形成较慢,具有亚扩散增长律;2)在最弱选择下的分子表型最先导致不亲和性;3)成对不亲和性支配着更高阶的不亲和性,与之前预测的后者应该占主导地位的观点相反。我们发现的种群大小效应与之前关于转录因子-DNA 结合的异地分歧的结果一致,在较小的种群中,共同的祖先具有更大的漂变负荷,因为遗传漂变有利于具有更多基因型(更高序列熵)的表型,而不是更适合的表型,后者具有更少的基因型;这意味着在不亲和性出现之前,任一线粒体所需的替代次数都更少。总体而言,我们的结果表明,生物物理学和种群大小对物种形成的限制比以前的模型所暗示的要强得多,并指出了在稳定选择下生物体表现型下不亲和性产生的一般机制原则。
