Targeted Long-read Sequencing Enriches Disease-relevant Genomic Regions of Interest to Provide Complete Mendelian Disease Diagnostics

Overview

Journal JCI Insight

Specialties Biomedical Engineering
General Medicine

Date 2024 Sep 12

PMID 39264853

Authors

Kenji Nakamichi

Jennifer Huey

Riccardo Sangermano

Emily M Place

Kinga M Bujakowska

Molly Marra

Lesley A Everett

Paul Yang

Jennifer R Chao

Russell N Van Gelder

Debarshi Mustafi

Affiliations

Soon will be listed here.

Abstract

Despite advances in sequencing technologies, a molecular diagnosis remains elusive in many patients with Mendelian disease. Current short-read clinical sequencing approaches cannot provide chromosomal phase information or epigenetic information without further sample processing, which is not routinely done and can result in an incomplete molecular diagnosis in patients. The ability to provide phased genetic and epigenetic information from a single sequencing run would improve the diagnostic rate of Mendelian conditions. Here, we describe targeted long-read sequencing of Mendelian disease genes (TaLon-SeqMD) using a real-time adaptive sequencing approach. Optimization of bioinformatic targeting enabled selective enrichment of multiple disease-causing regions of the human genome. Haplotype-resolved variant calling and simultaneous resolution of epigenetic base modification could be achieved in a single sequencing run. The TaLon-SeqMD approach was validated in a cohort of 18 individuals with previous genetic testing targeting 373 inherited retinal disease (IRD) genes, yielding the complete molecular diagnosis in each case. This approach was then applied in 2 IRD cases with inconclusive testing, which uncovered noncoding and structural variants that were difficult to characterize by standard short-read sequencing. Overall, these results demonstrate TaLon-SeqMD as an approach to provide rapid phased-variant calling to provide the molecular basis of Mendelian diseases.

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