Calculating Higher-Order Moments of Phylogenetic Stochastic Mapping Summaries in Linear Time

Stochastic mapping is a simulation-based method for probabilistically mapping substitution histories onto phylogenies according to continuous-time Markov models of evolution. This technique can be used to infer properties of the evolutionary process on the phylogeny and, unlike parsimony-based mappi...

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Vydáno v:Journal of computational biology Ročník 24; číslo 5; s. 377
Hlavní autoři: Dhar, Amrit, Minin, Vladimir N
Médium: Journal Article
Jazyk:angličtina
Vydáno: United States 01.05.2017
Témata:
Algorithms
Computational Biology - methods
Computer Simulation
Evolution, Molecular
Markov Chains
Models, Genetic
Phylogeny
dynamic programming
posterior predictive diagnostics
evolutionary conservation
ISSN:1557-8666, 1557-8666
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Shrnutí:Stochastic mapping is a simulation-based method for probabilistically mapping substitution histories onto phylogenies according to continuous-time Markov models of evolution. This technique can be used to infer properties of the evolutionary process on the phylogeny and, unlike parsimony-based mapping, conditions on the observed data to randomly draw substitution mappings that do not necessarily require the minimum number of events on a tree. Most stochastic mapping applications simulate substitution mappings only to estimate the mean and/or variance of two commonly used mapping summaries: the number of particular types of substitutions (labeled substitution counts) and the time spent in a particular group of states (labeled dwelling times) on the tree. Fast, simulation-free algorithms for calculating the mean of stochastic mapping summaries exist. Importantly, these algorithms scale linearly in the number of tips/leaves of the phylogenetic tree. However, to our knowledge, no such algorithm exists for calculating higher-order moments of stochastic mapping summaries. We present one such simulation-free dynamic programming algorithm that calculates prior and posterior mapping variances and scales linearly in the number of phylogeny tips. Our procedure suggests a general framework that can be used to efficiently compute higher-order moments of stochastic mapping summaries without simulations. We demonstrate the usefulness of our algorithm by extending previously developed statistical tests for rate variation across sites and for detecting evolutionarily conserved regions in genomic sequences.
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ISSN:1557-8666
1557-8666
DOI:10.1089/cmb.2016.0172