RecGraph: Recombination-aware Alignment of Sequences to Variation Graphs

Overview

Journal Bioinformatics

Publisher Oxford University Press

Specialty Biology

Date 2024 Apr 27

PMID 38676570

Authors

Jorge Avila Cartes

Paola Bonizzoni

Simone Ciccolella

Gianluca Della Vedova

Luca Denti

Xavier Didelot

Davide Cesare Monti

Yuri Pirola

Affiliations

Soon will be listed here.

Abstract

Motivation: Bacterial genomes present more variability than human genomes, which requires important adjustments in computational tools that are developed for human data. In particular, bacteria exhibit a mosaic structure due to homologous recombinations, but this fact is not sufficiently captured by standard read mappers that align against linear reference genomes. The recent introduction of pangenomics provides some insights in that context, as a pangenome graph can represent the variability within a species. However, the concept of sequence-to-graph alignment that captures the presence of recombinations has not been previously investigated.

Results: In this paper, we present the extension of the notion of sequence-to-graph alignment to a variation graph that incorporates a recombination, so that the latter are explicitly represented and evaluated in an alignment. Moreover, we present a dynamic programming approach for the special case where there is at most a recombination-we implement this case as RecGraph. From a modelling point of view, a recombination corresponds to identifying a new path of the variation graph, where the new arc is composed of two halves, each extracted from an original path, possibly joined by a new arc. Our experiments show that RecGraph accurately aligns simulated recombinant bacterial sequences that have at most a recombination, providing evidence for the presence of recombination events.

Availability And Implementation: Our implementation is open source and available at https://github.com/AlgoLab/RecGraph.

Citing Articles

Haplotype-aware sequence alignment to pangenome graphs.

Chandra G, Gibney D, Jain C Genome Res. 2024; 34(9):1265-1275.

PMID: 39013594 PMC: 11529843. DOI: 10.1101/gr.279143.124.

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