MAST:利用跨位点和树的混合物进行系统发育推断。

IF 6.1 1区 生物学 Q1 EVOLUTIONARY BIOLOGY Systematic Biology Pub Date : 2024-07-27 DOI:10.1093/sysbio/syae008
Thomas K F Wong, Caitlin Cherryh, Allen G Rodrigo, Matthew W Hahn, Bui Quang Minh, Robert Lanfear
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引用次数: 0

摘要

在现代系统发生组学研究中,通常会用到成百上千个基因位点。树推断的串联方法假定整个数据集存在单一拓扑结构,但不同的基因位点可能由于不完全的品系分类、引种和/或水平基因转移而具有不同的进化历史;甚至单个基因位点也可能由于重组而不是树状的。为了克服这一缺陷,我们引入了一个多树混合模型的实现方法,我们称之为 MAST。该模型扩展了 Boussau 等人(2009 年)的先前实现,允许用户在单个比对中估算一组预先指定的分叉树中每棵树的权重。MAST 模型允许每棵树都有自己的权重、拓扑结构、分支长度、替代模型、核苷酸或氨基酸频率以及跨位点的速率异质性模型。我们在流行的系统发生学软件 IQ-TREE 的最大似然法框架内实现了 MAST 模型。模拟结果表明,我们可以在多种生物现实场景下准确地恢复真实的模型参数,包括给定树拓扑的分支长度和树权重。我们还证明,在多树模型下模拟数据时,我们可以使用标准的统计推断方法来拒绝单树模型(反之亦然)。我们将 MAST 模型应用于多个灵长类动物数据集,发现它可以恢复类人猿不完全的血统分类信号,以及由多个猕猴物种间的引种引起的次要树的不对称性。当应用于一个由四个钝齿类物种组成的数据集时,我们观察到,MAST给予基因树方法也支持的树以最高权重(即最大比例的位点)。这些结果表明,MAST 模型能够使用最大似然法分析连接比对,同时避免了假设只有一棵树所带来的一些偏差。我们将讨论未来如何扩展 MAST 模型。
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MAST: Phylogenetic Inference with Mixtures Across Sites and Trees.

Hundreds or thousands of loci are now routinely used in modern phylogenomic studies. Concatenation approaches to tree inference assume that there is a single topology for the entire dataset, but different loci may have different evolutionary histories due to incomplete lineage sorting (ILS), introgression, and/or horizontal gene transfer; even single loci may not be treelike due to recombination. To overcome this shortcoming, we introduce an implementation of a multi-tree mixture model that we call mixtures across sites and trees (MAST). This model extends a prior implementation by Boussau et al. (2009) by allowing users to estimate the weight of each of a set of pre-specified bifurcating trees in a single alignment. The MAST model allows each tree to have its own weight, topology, branch lengths, substitution model, nucleotide or amino acid frequencies, and model of rate heterogeneity across sites. We implemented the MAST model in a maximum-likelihood framework in the popular phylogenetic software, IQ-TREE. Simulations show that we can accurately recover the true model parameters, including branch lengths and tree weights for a given set of tree topologies, under a wide range of biologically realistic scenarios. We also show that we can use standard statistical inference approaches to reject a single-tree model when data are simulated under multiple trees (and vice versa). We applied the MAST model to multiple primate datasets and found that it can recover the signal of ILS in the Great Apes, as well as the asymmetry in minor trees caused by introgression among several macaque species. When applied to a dataset of 4 Platyrrhine species for which standard concatenated maximum likelihood (ML) and gene tree approaches disagree, we observe that MAST gives the highest weight (i.e., the largest proportion of sites) to the tree also supported by gene tree approaches. These results suggest that the MAST model is able to analyze a concatenated alignment using ML while avoiding some of the biases that come with assuming there is only a single tree. We discuss how the MAST model can be extended in the future.

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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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