InvertypeR: Bayesian Inversion Genotyping with Strand-seq Data

Overview

Journal BMC Genomics

Publisher Biomed Central

Specialty Genetics

Date 2021 Aug 1

PMID 34332539

Citations 2

Authors

Vincent C T Hanlon

Carl-Adam Mattsson

Diana C J Spierings

Victor Guryev

Peter M Lansdorp

Affiliations

Soon will be listed here.

Abstract

Background: Single cell Strand-seq is a unique tool for the discovery and phasing of genomic inversions. Conventional methods to discover inversions with Strand-seq data are blind to known inversion locations, limiting their statistical power for the detection of inversions smaller than 10 Kb. Moreover, the methods rely on manual inspection to separate false and true positives.

Results: Here we describe "InvertypeR", a method based on a Bayesian binomial model that genotypes inversions using fixed genomic coordinates. We validated InvertypeR by re-genotyping inversions reported for three trios by the Human Genome Structural Variation Consortium. Although 6.3% of the family inversion genotypes in the original study showed Mendelian discordance, this was reduced to 0.5% using InvertypeR. By applying InvertypeR to published inversion coordinates and predicted inversion hotspots (n = 3701), as well as coordinates from conventional inversion discovery, we furthermore genotyped 66 inversions not previously reported for the three trios.

Conclusions: InvertypeR discovers, genotypes, and phases inversions without relying on manual inspection. For greater accessibility, results are presented as phased chromosome ideograms with inversions linked to Strand-seq data in the genome browser. InvertypeR increases the power of Strand-seq for studies on the role of inversions in phenotypic variation, genome instability, and human disease.

Citing Articles

Simultaneous de novo calling and phasing of genetic variants at chromosome-scale using NanoStrand-seq.

Bai X, Chen Z, Chen K, Wu Z, Wang R, Liu J Cell Discov. 2024; 10(1):74.

PMID: 38977679 PMC: 11231365. DOI: 10.1038/s41421-024-00694-9.

Parent-of-origin detection and chromosome-scale haplotyping using long-read DNA methylation sequencing and Strand-seq.

Akbari V, Hanlon V, ONeill K, Lefebvre L, Schrader K, Lansdorp P Cell Genom. 2023; 3(1):100233.

PMID: 36777186 PMC: 9903809. DOI: 10.1016/j.xgen.2022.100233.

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