进化与生命中许多粒度的分支相结合

Jordan Douglas, Remco Bouckaert, Simon C Harris, Charles W Carter, Peter R Wills
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引用次数: 0

摘要

在许多不同尺度的生命中,一个品系分裂成两个品系时,进化变化的速度往往会加快。基因复制(新功能化)可以促进新蛋白质功能的出现;形态的快速变化往往伴随着物种的分化(点状平衡);而文化特征的建立则经常受到社会政治分裂(分裂发生)的驱动。在每种情况下,变化都会抵制再同质化;促进分化成不同的品系,这些品系容易受到不同的选择性压力,从而导致迅速分化。传统的渐进进化观点难以发现这一现象。我们设计了一个概率框架,用于构建系统发育、检验假设,并在出现进化突变时改进对分化时间的估计。该模型不仅为系统树的每个分支分配了一个渐进进化的时钟速率,还分配了一个突变的峰值,并独立估算了每个过程的贡献。我们提供了蛋白质(氨基酰-tRNA 合成酶)、动物形态(头足类)和人类语言(印欧语)在分支时突然进化的证据。这三个案例提供了独特的见解:就氨基酸酰-tRNA 合成酶而言,其演化树与渐变模型下的演化树有很大不同;头足类动物的形态几乎完全是通过突变演化而来;印欧语的传播估计始于公元前 6000 年左右,这证实了最近提出的混合解释。这项工作展示了一种检测突变过程的可靠方法,并推进了我们对进化变化与分支事件之间联系的理解。我们的开源代码采用 GPL 许可。
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Evolution is coupled with branching across many granularities of life
Across many different scales of life, the rate of evolutionary change is often accelerated at the time when one lineage splits into two. The emergence of novel protein function can be facilitated by gene duplication (neofunctionalisation); rapid morphological change is often accompanied with speciation (punctuated equilibrium); and the establishment of cultural identity is frequently driven by sociopolitical division (schismogenesis). In each case, the change resists re-homogenisation; promoting assortment into distinct lineages that are susceptible to different selective pressures, leading to rapid divergence. The traditional gradualistic view of evolution struggles to detect this phenomenon. We have devised a probabilistic framework that constructs phylogenies, tests hypotheses, and improves divergence time estimation when evolutionary bursts are present. As well as assigning a clock rate of gradual evolution to each branch of a tree, this model also assigns a spike of abrupt change, and independently estimates the contributions arising from each process. We provide evidence of abrupt evolution at the time of branching for proteins (aminoacyl-tRNA synthetases), animal morphologies (cephalopods), and human languages (Indo-European). These three cases provide unique insights: for aminoacyl-tRNA synthetases, the trees are substantially different from those obtained under gradualist models; Cephalopod morphologies are found to evolve almost exclusively through abrupt shifts; and Indo-European dispersal is estimated to have started around 6000 BCE, corroborating the recently proposed hybrid explanation. This work demonstrates a robust means for detecting burst-like processes, and advances our understanding of the link between evolutionary change and branching events. Our open-source code is available under a GPL license.
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