MAST: Phylogenetic Inference with Mixtures Across Sites and Trees

Thomas K F Wong; Caitlin Cherryh; Allen G Rodrigo; Matthew W Hahn; Bui Quang Minh; Robert Lanfear

doi:10.1093/sysbio/syae008

MAST: Phylogenetic Inference with Mixtures Across Sites and Trees

Syst Biol. 2024 Feb 29:syae008. doi: 10.1093/sysbio/syae008. Online ahead of print.

Authors

Thomas K F Wong¹, Caitlin Cherryh², Allen G Rodrigo³, Matthew W Hahn⁴, Bui Quang Minh¹, Robert Lanfear²

Affiliations

¹ School of Computing, Australian National University, Canberra, Australian Capital Territory 2601, Australia.
² Research School of Biology, Australian National University, Canberra, ACT 2601, Australia.
³ School of Biological Sciences, University of Auckland, Auckland, New Zealand.
⁴ Department of Biology and Department of Computer Science, Indiana University, Bloomington, Indiana, United States of America.

PMID: 38421146
DOI: 10.1093/sysbio/syae008

Abstract

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, 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 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 incomplete lineage sorting 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 four Platyrrhine species for which standard concatenated maximum likelihood 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 analyse a concatenated alignment using maximum likelihood, 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.

Keywords: Multitree model; incomplete lineage sorting; introgression; mixture model; phylogenetics.