Geogenomic Predictors of Genetree Heterogeneity Explain Phylogeographic and Introgression History: A Case Study in an Amazonian Bird (Thamnophilus aethiops).

IF 6.1 1区 生物学 Q1 EVOLUTIONARY BIOLOGY
Lukas J Musher, Glaucia Del-Rio, Rafael S Marcondes, Robb T Brumfield, Gustavo A Bravo, Gregory Thom
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引用次数: 0

Abstract

Can knowledge about genome architecture inform biogeographic and phylogenetic inference? Selection, drift, recombination, and gene flow interact to produce a genomic landscape of divergence wherein patterns of differentiation and genealogy vary nonrandomly across the genomes of diverging populations. For instance, genealogical patterns that arise due to gene flow should be more likely to occur on smaller chromosomes, which experience high recombination, whereas those tracking histories of geographic isolation (reduced gene flow caused by a barrier) and divergence should be more likely to occur on larger and sex chromosomes. In Amazonia, populations of many bird species diverge and introgress across rivers, resulting in reticulated genomic signals. Herein, we used reduced representation genomic data to disentangle the evolutionary history of 4 populations of an Amazonian antbird, Thamnophilus aethiops, whose biogeographic history was associated with the dynamic evolution of the Madeira River Basin. Specifically, we evaluate whether a large river capture event ca. 200 Ka, gave rise to reticulated genealogies in the genome by making spatially explicit predictions about isolation and gene flow based on knowledge about genomic processes. We first estimated chromosome-level phylogenies and recovered 2 primary topologies across the genome. The first topology (T1) was most consistent with predictions about population divergence and was recovered for the Z-chromosome. The second (T2), was consistent with predictions about gene flow upon secondary contact. To evaluate support for these topologies, we trained a convolutional neural network to classify our data into alternative diversification models and estimate demographic parameters. The best-fit model was concordant with T1 and included gene flow between non-sister taxa. Finally, we modeled levels of divergence and introgression as functions of chromosome length and found that smaller chromosomes experienced higher gene flow. Given that (1) genetrees supporting T2 were more likely to occur on smaller chromosomes and (2) we found lower levels of introgression on larger chromosomes (and especially the Z-chromosome), we argue that T1 represents the history of population divergence across rivers and T2 the history of secondary contact due to barrier loss. Our results suggest that a significant portion of genomic heterogeneity arises due to extrinsic biogeographic processes such as river capture interacting with intrinsic processes associated with genome architecture. Future phylogeographic studies would benefit from accounting for genomic processes, as different parts of the genome reveal contrasting, albeit complementary histories, all of which are relevant for disentangling the intricate geogenomic mechanisms of biotic diversification. [Amazonia; biogeography; demographic modeling; gene flow; gene tree; genome architecture; geogenomics; introgression; linked selection; neural network; phylogenomic; phylogeography; reproductive isolation; speciation; species tree.].

基因树异质性的地理基因组预测因子解释了系统地理学和渐渗史:一项亚马逊鸟类(Thamnophilus aethiops)的案例研究。
关于基因组结构的知识能为生物地理学和系统发育推断提供信息吗?选择、漂移、重组和基因流动相互作用,产生分化的基因组景观,其中分化模式和谱系在分化群体的基因组中非随机变化。例如,由于基因流动而产生的谱系模式应该更有可能发生在经历高度重组的较小染色体上,而那些追踪地理隔离(屏障导致基因流动减少)和分化历史的染色体应该更有可能出现在较大的性染色体上。在亚马逊地区,许多鸟类的种群在河流中分化和渗入,从而产生网状的基因组信号。在此,我们使用减少代表性的基因组数据来理清亚马逊蚁鸟Thamnophilus aethiops四个种群的进化史,其生物地理学历史与马德拉河流域的动态进化有关。具体而言,我们通过基于基因组过程的知识对隔离和基因流动进行空间显式预测,来评估约200 Ka的大型河流捕获事件是否在基因组中产生网状谱系。我们首先估计了染色体水平的系统发育,并恢复了整个基因组的两种主要拓扑结构。第一种拓扑结构(T1)与关于群体分化的预测最为一致,并且在Z染色体上得到了恢复。第二个(T2)与关于二次接触时基因流动的预测一致。为了评估对这些拓扑结构的支持,我们训练了一个卷积神经网络,将我们的数据分类到替代的多样化模型中,并估计人口统计参数。最佳拟合模型与T1一致,包括非姐妹分类群之间的基因流动。最后,我们将分化和渐渗水平建模为染色体长度的函数,发现较小的染色体经历了更高的基因流。考虑到(1)支持T2的基因树更有可能出现在较小的染色体上,以及(2)我们发现较大染色体(尤其是Z染色体)上的渗入水平较低,我们认为T1代表河流间种群分化的历史,T2代表由于屏障丧失而导致的二次接触的历史。我们的研究结果表明,基因组异质性的很大一部分是由于外在的生物地理学过程(如河流捕获)与与基因组结构相关的内在过程相互作用而产生的。未来的系统地理学研究将受益于对基因组过程的解释,因为基因组的不同部分揭示了不同的、尽管互补的历史,所有这些都与解开生物多样化的复杂地理基因组机制有关。
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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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