Modeling character change heterogeneity in phylogenetic analyses of morphology through the use of priors

April M. Wright; Graeme T. Lloyd; David M. Hillis

doi:10.1093/sysbio/syv122

Modeling character change heterogeneity in phylogenetic analyses of morphology through the use of priors

April M. Wright, Graeme T. Lloyd, David M. Hillis

Research output: Contribution to journal › Article › peer-review

60 Citations (Scopus)

Abstract

The Mk model was developed for estimating phylogenetic trees from discrete morphological data, whether for living or fossil taxa. Like any model, the Mk model makes a number of assumptions. One assumption is that transitions between character states are symmetric (i.e., the probability of changing from 0 to 1 is the same as 1 to 0). However, some characters in a datamatrix may not satisfy this assumption. Here,we test methods for relaxing this assumption in a Bayesian context. Using empirical data sets, we perform model fitting to illustrate cases in which modeling asymmetric transition rates among characters is preferable to the standard Mk model. We use simulated data sets to demonstrate that choosing the best-fit model of transition-state symmetry can improve model fit and phylogenetic estimation.

Original language	English
Pages (from-to)	602-611
Number of pages	10
Journal	Systematic Biology
Volume	65
Issue number	4
DOIs	https://doi.org/10.1093/sysbio/syv122
Publication status	Published - Jul 2016

Keywords

Bayesian estimation
morphology
paleontology
phylogeny
priors

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10.1093/sysbio/syv122

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abstract = "The Mk model was developed for estimating phylogenetic trees from discrete morphological data, whether for living or fossil taxa. Like any model, the Mk model makes a number of assumptions. One assumption is that transitions between character states are symmetric (i.e., the probability of changing from 0 to 1 is the same as 1 to 0). However, some characters in a datamatrix may not satisfy this assumption. Here,we test methods for relaxing this assumption in a Bayesian context. Using empirical data sets, we perform model fitting to illustrate cases in which modeling asymmetric transition rates among characters is preferable to the standard Mk model. We use simulated data sets to demonstrate that choosing the best-fit model of transition-state symmetry can improve model fit and phylogenetic estimation.",

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AB - The Mk model was developed for estimating phylogenetic trees from discrete morphological data, whether for living or fossil taxa. Like any model, the Mk model makes a number of assumptions. One assumption is that transitions between character states are symmetric (i.e., the probability of changing from 0 to 1 is the same as 1 to 0). However, some characters in a datamatrix may not satisfy this assumption. Here,we test methods for relaxing this assumption in a Bayesian context. Using empirical data sets, we perform model fitting to illustrate cases in which modeling asymmetric transition rates among characters is preferable to the standard Mk model. We use simulated data sets to demonstrate that choosing the best-fit model of transition-state symmetry can improve model fit and phylogenetic estimation.

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KW - paleontology

KW - phylogeny

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JO - Systematic Biology

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Modeling character change heterogeneity in phylogenetic analyses of morphology through the use of priors

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Keywords

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