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Genomic data are increasingly being used to understand infectious disease epidemiology. Isolates from a given outbreak are sequenced, and the patterns of shared variation are used to infer which isolates within the outbreak are most closely related to each other. Unfortunately, the phylogenetic trees typically used to represent this variation are not directly informative about who infected whom-a phylogenetic tree is not a transmission tree. However, a transmission tree can be inferred from a phylogeny while accounting for within-host genetic diversity by coloring the branches of a phylogeny according to which host those branches were in. Here we extend this approach and show that it can be applied to partially sampled and ongoing outbreaks. This requires computing the correct probability of an observed transmission tree and we herein demonstrate how to do this for a large class of epidemiological models. We also demonstrate how the branch coloring approach can incorporate a variable number of unique colors to represent unsampled intermediates in transmission chains. The resulting algorithm is a reversible jump Monte-Carlo Markov Chain, which we apply to both simulated data and real data from an outbreak of tuberculosis. By accounting for unsampled cases and an outbreak which may not have reached its end, our method is uniquely suited to use in a public health environment during real-time outbreak investigations. We implemented this transmission tree inference methodology in an R package called TransPhylo, which is freely available from https://github.com/xavierdidelot/TransPhylo.

Original publication

DOI

10.1093/molbev/msw275

Type

Journal article

Journal

Molecular biology and evolution

Publication Date

04/2017

Volume

34

Pages

997 - 1007

Addresses

Department of Infectious Disease Epidemiology, Imperial College London, Norfolk Place, London, United Kingdom.

Keywords

Humans, Communicable Diseases, Monte Carlo Method, Probability, Markov Chains, Computational Biology, Genomics, Disease Outbreaks, Phylogeny, Algorithms, Models, Genetic, Computer Simulation, Software, Disease Transmission, Infectious