%0 Journal Article %1 rasmussen2022espalier %A Rasmussen, David A. %A Guo, Fangfang %D 2022 %I Cold Spring Harbor Laboratory %J bioRxiv %K ARG tree_sequence tree_sequence_inference %R 10.1101/2022.01.17.476639 %T Espalier: Efficient tree reconciliation and ARG reconstruction using maximum agreement forests %U https://www.biorxiv.org/content/early/2022/02/06/2022.01.17.476639 %X In the presence of recombination individuals may inherit different regions of their genome from different ancestors, resulting in a mosaic of phylogenetic histories across their genome. Ancestral recombination graphs (ARGs) can capture how phylogenetic relationships vary across the genome due to recombination, but reconstructing ARGs from genomic sequence data is notoriously difficult. Here we present a method for reconciling discordant phylogenetic trees and reconstructing ARGs using maximum agreement forests (MAFs). Given two discordant trees, a MAF identifies a set of topologically concordant subtrees present in both trees. We show how discordant trees can be reconciled through their MAF in a way that retains discordances strongly supported by sequence data while eliminating conflicts likely attributable to phylogenetic noise. We further show how MAFs and our reconciliation approach can be combined to select a path of local trees across the genome that maximizes the likelihood of the genomic sequence data, minimizes discordance between neighboring local trees, and identifies the recombination events necessary to explain remaining discordances to obtain a fully connected ARG. While heuristic, our ARG reconstruction approach is often as accurate as more exact methods while being much more computationally efficient. Moreover, important demographic parameters such as recombination rates can be accurately estimated from reconstructed ARGs. Finally, we apply our approach to plant infecting RNA viruses in the genus Potyvirus to demonstrate how true recombination events can be disentangled from phylogenetic noise using our ARG reconstruction methods.Competing Interest StatementThe authors have declared no competing interest.

@article{rasmussen2022espalier, abstract = {In the presence of recombination individuals may inherit different regions of their genome from different ancestors, resulting in a mosaic of phylogenetic histories across their genome. Ancestral recombination graphs (ARGs) can capture how phylogenetic relationships vary across the genome due to recombination, but reconstructing ARGs from genomic sequence data is notoriously difficult. Here we present a method for reconciling discordant phylogenetic trees and reconstructing ARGs using maximum agreement forests (MAFs). Given two discordant trees, a MAF identifies a set of topologically concordant subtrees present in both trees. We show how discordant trees can be reconciled through their MAF in a way that retains discordances strongly supported by sequence data while eliminating conflicts likely attributable to phylogenetic noise. We further show how MAFs and our reconciliation approach can be combined to select a path of local trees across the genome that maximizes the likelihood of the genomic sequence data, minimizes discordance between neighboring local trees, and identifies the recombination events necessary to explain remaining discordances to obtain a fully connected ARG. While heuristic, our ARG reconstruction approach is often as accurate as more exact methods while being much more computationally efficient. Moreover, important demographic parameters such as recombination rates can be accurately estimated from reconstructed ARGs. Finally, we apply our approach to plant infecting RNA viruses in the genus Potyvirus to demonstrate how true recombination events can be disentangled from phylogenetic noise using our ARG reconstruction methods.Competing Interest StatementThe authors have declared no competing interest.}, added-at = {2022-03-02T18:34:25.000+0100}, author = {Rasmussen, David A. and Guo, Fangfang}, biburl = {https://www.bibsonomy.org/bibtex/25d71e48e4f4efda3dd8affa7992ba5de/peter.ralph}, doi = {10.1101/2022.01.17.476639}, elocation-id = {2022.01.17.476639}, eprint = {https://www.biorxiv.org/content/early/2022/02/06/2022.01.17.476639.full.pdf}, interhash = {4afe2716db1ecd82621ead15b1d970a5}, intrahash = {5d71e48e4f4efda3dd8affa7992ba5de}, journal = {bioRxiv}, keywords = {ARG tree_sequence tree_sequence_inference}, publisher = {Cold Spring Harbor Laboratory}, timestamp = {2022-03-02T18:34:25.000+0100}, title = {Espalier: Efficient tree reconciliation and {ARG} reconstruction using maximum agreement forests}, url = {https://www.biorxiv.org/content/early/2022/02/06/2022.01.17.476639}, year = 2022 }