A Bayesian Compound Stochastic Process for Modeling Nonstationary and Nonhomogeneous Sequence Evolution

doi:10.1093/molbev/msl091

MBE Advance Access originally published online on August 24, 2006
Molecular Biology and Evolution 2006 23(11):2058-2071; doi:10.1093/molbev/msl091

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© The Author 2006. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oxfordjournals.org

Research Articles

A Bayesian Compound Stochastic Process for Modeling Nonstationary and Nonhomogeneous Sequence Evolution

Samuel Blanquart and Nicolas Lartillot

Projet Méthodes et Algorithmes pour la Bioinformatique, LIRMM-CNRS, Montpellier, France

E-mail: samuel.blanquart{at}lirmm.fr.

Variations of nucleotidic composition affect phylogenetic inferenceconducted under stationary models of evolution. In particular,they may cause unrelated taxa sharing similar base compositionto be grouped together in the resulting phylogeny. To addressthis problem, we developed a nonstationary and nonhomogeneousmodel accounting for compositional biases. Unlike previous nonstationarymodels, which are branchwise, that is, assume that base compositiononly changes at the nodes of the tree, in our model, the processof compositional drift is totally uncoupled from the speciationevents. In addition, the total number of events of compositionaldrift distributed across the tree is directly inferred fromthe data. We implemented the method in a Bayesian framework,relying on Markov Chain Monte Carlo algorithms, and appliedit to several nucleotidic data sets. In most cases, the stationarityassumption was rejected in favor of our nonstationary model.In addition, we show that our method is able to resolve a well-knownartifact. By Bayes factor evaluation, we compared our modelwith 2 previously developed nonstationary models. We show thatthe coupling between speciations and compositional shifts inherentto branchwise models may lead to an overparameterization, resultingin a lesser fit. In some cases, this leads to incorrect conclusions,concerning the nature of the compositional biases. In contrast,our compound model more flexibly adapts its effective numberof parameters to the data sets under investigation. Altogether,our results show that accounting for nonstationary sequenceevolution may require more elaborate and more flexible modelsthan those currently used.

Key Words: phylogeny • MCMC • nonstationary • nonhomogeneous • compositional bias • compound stochastic process

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