Exploring the Macroevolutionary Signature of Asymmetric Inheritance at Speciation.

IF 6.1 1区 生物学 Q1 EVOLUTIONARY BIOLOGY
Thèo Gaboriau, Joseph A Tobias, Daniele Silvestro, Nicolas Salamin
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引用次数: 0

Abstract

Popular comparative phylogenetic models such as Brownian Motion, Ornstein-Ulhenbeck, and their extensions, assume that, at speciation, a trait value is inherited identically by two descendant species. This assumption contrasts with models of speciation at a micro-evolutionary scale where descendants' phenotypic distributions are sub-samples of the ancestral distribution. Different speciation mechanisms can lead to a displacement of the ancestral phenotypic mean among descendants and an asymmetric inheritance of the ancestral phenotypic variance. In contrast, even macro-evolutionary models that account for intraspecific variance assume symmetrically conserved inheritance of ancestral phenotypic distribution at speciation. Here we develop an Asymmetric Brownian Motion model (ABM) that relaxes the assumption of symmetric and conserved inheritance of the ancestral distribution at the time of speciation. The ABM jointly models the evolution of both intra- and inter-specific phenotypic variation. It also infers the mode of phenotypic inheritance at speciation, which can range from a symmetric and conserved inheritance, where descendants inherit the ancestral distribution, to an asymmetric and displaced inheritance, where descendants inherit divergent phenotypic means and variances. To demonstrate this model, we analyze the evolution of beak morphology in Darwin finches, finding evidence of displacement at speciation. The ABM model helps to bridge micro- and macro-evolutionary models of trait evolution by providing a more robust framework for testing the effects of ecological speciation, character displacement, and niche partitioning on trait evolution at the macro-evolutionary scale.

探索物种进化过程中不对称遗传的宏观进化特征
流行的比较系统发生学模型,如布朗运动模型、奥恩斯坦-乌伦贝克模型及其扩展模型,都假定在物种分化时,两个后代物种的性状值是完全相同的。这一假设与微进化尺度上的物种演化模型不同,在微进化尺度上,后代的表型分布是祖先分布的子样本。不同的物种演化机制会导致祖先表型的平均值在后代中发生位移,以及祖先表型方差的非对称遗传。与此相反,即使是考虑了种内差异的宏观进化模型,也会假定在物种分化时祖先表型分布的遗传是对称的。在这里,我们建立了一个非对称布朗运动模型(ABM),该模型放宽了在物种形成时对祖先分布的对称和保守遗传的假设。非对称布朗运动模型联合模拟了种内和种间表型变异的演化。它还能推断出物种分化时的表型遗传模式,包括对称和保守遗传(后代继承了祖先的分布)和非对称和移位遗传(后代继承了不同的表型均值和方差)。为了证明这一模型,我们分析了达尔文雀喙形态的进化,发现了物种变异时发生位移的证据。ABM模型提供了一个更稳健的框架,用于在宏观进化尺度上检验生态物种分化、特征位移和生态位分割对特征进化的影响,从而有助于在特征进化的微观和宏观进化模型之间架起一座桥梁。
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来源期刊
Systematic Biology
Systematic Biology 生物-进化生物学
CiteScore
13.00
自引率
7.70%
发文量
70
审稿时长
6-12 weeks
期刊介绍: Systematic Biology is the bimonthly journal of the Society of Systematic Biologists. Papers for the journal are original contributions to the theory, principles, and methods of systematics as well as phylogeny, evolution, morphology, biogeography, paleontology, genetics, and the classification of all living things. A Points of View section offers a forum for discussion, while book reviews and announcements of general interest are also featured.
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