Abstract
For various species, high quality sequences and complete genomes are nowadays available for many individuals. This makes data analysis challenging, as methods need not only to be accurate, but also time efficient given the tremendous amount of data to process. In this article, we introduce an efficient method to infer the evolutionary history of individuals under the multispecies coalescent model in networks (MSNC). Phylogenetic networks are an extension of phylogenetic trees that can contain reticulate nodes, which allow to model complex biological events such as horizontal gene transfer, hybridization and introgression. We present a novel way to compute the likelihood of biallelic markers sampled along genomes whose evolution involved such events. This likelihood computation is at the heart of a Bayesian network inference method called SnappNet, as it extends the Snapp method inferring evolutionary trees under the multispecies coalescent model, to networks. SnappNet is available as a package of the well-known beast 2 software. Recently, the MCMC_BiMarkers method, implemented in PhyloNet, also extended Snapp to networks. Both methods take biallelic markers as input, rely on the same model of evolution and sample networks in a Bayesian framework, though using different methods for computing priors. However, SnappNet relies on algorithms that are exponentially more time-efficient on non-trivial networks. Using simulations, we compare performances of SnappNet and MCMC_BiMarkers. We show that both methods enjoy similar abilities to recover simple networks, but SnappNet is more accurate than MCMC_BiMarkers on more complex network scenarios. Also, on complex networks, SnappNet is found to be extremely faster than MCMC_BiMarkers in terms of time required for the likelihood computation. We finally illustrate SnappNet performances on a rice data set. SnappNet infers a scenario that is consistent with previous results and provides additional understanding of rice evolution.
Highlights
Complete genomes for numerous species in various life domains [1,2,3,4,5], and even for several individuals for some species [6, 7] are nowadays available thanks to generation sequencing
We present a new Bayesian method, called SNAPPNET, dedicated to phylogenetic network inference
The availability of numerous genomes at both the intra and inter species levels has been a fertile ground for studies at the interface of population genetics and phylogenetics [14] that aim to estimate the evolutionary history of closely related species
Summary
Complete genomes for numerous species in various life domains [1,2,3,4,5], and even for several individuals for some species [6, 7] are nowadays available thanks to generation sequencing This flow of data finds applications in various fields such as pathogenecity [8], crop improvement [9], evolutionary genetics [10] or population migration and history [11,12,13]. Phylogenomic studies use as input thousands to millions genomic fragments sampled across different species To process such a large amount of data, methods need to be accurate, and time efficient. It is possible to reconstruct evolutionary histories while accounting for both incomplete lineage sorting (ILS) and sequence evolution [20, 21]
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