Gespeichert in:
Bibliographische Detailangaben
Hauptverfasser: Reshef, Ortal, Glassman, Ofer, Zuk, Or, Aizenbud, Yariv, Nadler, Boaz, Jaffe, Ariel
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2603.10215
Tags: Tag hinzufügen
Keine Tags, Fügen Sie den ersten Tag hinzu!
_version_ 1866914384481091584
author Reshef, Ortal
Glassman, Ofer
Zuk, Or
Aizenbud, Yariv
Nadler, Boaz
Jaffe, Ariel
author_facet Reshef, Ortal
Glassman, Ofer
Zuk, Or
Aizenbud, Yariv
Nadler, Boaz
Jaffe, Ariel
contents Recovering a tree that represents the evolutionary history of a group of species is a key task in phylogenetics. Performing this task using sequence data from multiple genetic markers poses two key challenges. The first is the discordance between the evolutionary history of individual genes and that of the species. The second challenge is computational, as contemporary studies involve thousands of species. Here we present SDSR, a scalable divide-and-conquer approach for species tree reconstruction based on spectral graph theory. The algorithm recursively partitions the species into subsets until their sizes are below a given threshold. The trees of these subsets are reconstructed by a user-chosen species tree algorithm. Finally, these subtrees are merged to form the full tree. On the theoretical front, we derive recovery guarantees for SDSR, under the multispecies coalescent (MSC) model. We also perform a runtime complexity analysis. We show that SDSR, when combined with a species tree reconstruction algorithm as a subroutine, yields substantial runtime savings as compared to applying the same algorithm on the full data. Empirically, we evaluate SDSR on synthetic benchmark datasets with incomplete lineage sorting and horizontal gene transfer. In accordance with our theoretical analysis, the simulations show that combining SDSR with common species tree methods, such as CA-ML or ASTRAL, yields up to 10-fold faster runtimes. In addition, SDSR achieves a comparable tree reconstruction accuracy to that obtained by applying these methods on the full data.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10215
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle SDSR: A Spectral Divide-and-Conquer Approach for Species Tree Reconstruction
Reshef, Ortal
Glassman, Ofer
Zuk, Or
Aizenbud, Yariv
Nadler, Boaz
Jaffe, Ariel
Populations and Evolution
Machine Learning
62H12, 62H30, 05C50, 05C05
Recovering a tree that represents the evolutionary history of a group of species is a key task in phylogenetics. Performing this task using sequence data from multiple genetic markers poses two key challenges. The first is the discordance between the evolutionary history of individual genes and that of the species. The second challenge is computational, as contemporary studies involve thousands of species. Here we present SDSR, a scalable divide-and-conquer approach for species tree reconstruction based on spectral graph theory. The algorithm recursively partitions the species into subsets until their sizes are below a given threshold. The trees of these subsets are reconstructed by a user-chosen species tree algorithm. Finally, these subtrees are merged to form the full tree. On the theoretical front, we derive recovery guarantees for SDSR, under the multispecies coalescent (MSC) model. We also perform a runtime complexity analysis. We show that SDSR, when combined with a species tree reconstruction algorithm as a subroutine, yields substantial runtime savings as compared to applying the same algorithm on the full data. Empirically, we evaluate SDSR on synthetic benchmark datasets with incomplete lineage sorting and horizontal gene transfer. In accordance with our theoretical analysis, the simulations show that combining SDSR with common species tree methods, such as CA-ML or ASTRAL, yields up to 10-fold faster runtimes. In addition, SDSR achieves a comparable tree reconstruction accuracy to that obtained by applying these methods on the full data.
title SDSR: A Spectral Divide-and-Conquer Approach for Species Tree Reconstruction
topic Populations and Evolution
Machine Learning
62H12, 62H30, 05C50, 05C05
url https://arxiv.org/abs/2603.10215