Targeted long-read sequencing identifies missing pathogenic variants in unsolved Werner syndrome cases

Miller, Danny E.; Lei, Lin; Galey, Miranda; Kandhaya‐Pillai, Renuka; Tischkowitz, Marc; Amalnath, Deepak; Vithlani, Avadh; Yokote, Koutaro; Kato, Hisaya; Maezawa, Yoshiro; Takada-Watanabe, Aki; Takemoto, Minoru; Martin, George M.; Eichler, Evan E.; Hisama, Fuki M.; Oshima, Junko

doi:10.1136/jmedgenet-2022-108485

Cited by 19 publications

(21 citation statements)

References 41 publications

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“…Although additional read depth would be required to confidently assess the parent of origin of the duplicated allele, we have demonstrated that methylated reads can be phased such that parent-of-origin could be determined in samples with sufficient depth. Parent-of-origin for this variant has potential prognostic implications because individuals with 15q11.2-q13 duplications of the paternal allele typically develop less severe autism spectrum disorder than individuals with duplications of the maternal allele [ 25 ]. In the case we presented, we relied on a single nearby SNV to phase reads.…”

Section: Discussionmentioning

confidence: 99%

Implementation of Nanopore sequencing as a pragmatic workflow for copy number variant confirmation in the clinic

et al. 2023

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Background Diagnosis of rare genetic diseases can be a long, expensive and complex process, involving an array of tests in the hope of obtaining an actionable result. Long-read sequencing platforms offer the opportunity to make definitive molecular diagnoses using a single assay capable of detecting variants, characterizing methylation patterns, resolving complex rearrangements, and assigning findings to long-range haplotypes. Here, we demonstrate the clinical utility of Nanopore long-read sequencing by validating a confirmatory test for copy number variants (CNVs) in neurodevelopmental disorders and illustrate the broader applications of this platform to assess genomic features with significant clinical implications. Methods We used adaptive sampling on the Oxford Nanopore platform to sequence 25 genomic DNA samples and 5 blood samples collected from patients with known or false-positive copy number changes originally detected using short-read sequencing. Across the 30 samples (a total of 50 with replicates), we assayed 35 known unique CNVs (a total of 55 with replicates) and one false-positive CNV, ranging in size from 40 kb to 155 Mb, and assessed the presence or absence of suspected CNVs using normalized read depth. Results Across 50 samples (including replicates) sequenced on individual MinION flow cells, we achieved an average on-target mean depth of 9.5X and an average on-target read length of 4805 bp. Using a custom read depth-based analysis, we successfully confirmed the presence of all 55 known CNVs (including replicates) and the absence of one false-positive CNV. Using the same CNV-targeted data, we compared genotypes of single nucleotide variant loci to verify that no sample mix-ups occurred between assays. For one case, we also used methylation detection and phasing to investigate the parental origin of a 15q11.2-q13 duplication with implications for clinical prognosis. Conclusions We present an assay that efficiently targets genomic regions to confirm clinically relevant CNVs with a concordance rate of 100%. Furthermore, we demonstrate how integration of genotype, methylation, and phasing data from the Nanopore sequencing platform can potentially simplify and shorten the diagnostic odyssey.

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Section: Discussionmentioning

confidence: 99%

Implementation of Nanopore sequencing as a pragmatic workflow for copy number variant confirmation in the clinic

et al. 2023

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“…This may be particularly true in the case of genomic disorders, a term first coined by Lupski in 1998 to describe diseases that result from rearrangements of the human genome rather than from DNA sequence base changes 10 . There are indeed a few studies demonstrating the superiority of LRS over SRS in this class of disorders 11,12 . However, whole genome LRS is still prohibitively expensive for routine genetic diagnosis and remains largely inaccessible due to complex workflow and stringent sample requirement for ultrahigh molecular weight DNA.…”

Section: Mainmentioning

confidence: 99%

NanoRanger enables rapid single base-pair resolution of genomic disorders

Zhang,

Bi,

Nadeef

et al. 2023

Preprint

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Rare diseases affect around 350 million individuals globally, yet at least half of those with suspected Mendelian disorders remain without a precise molecular diagnosis despite advanced genetic testing using short read sequencing (SRS). Long-read sequencing (LRS) holds a promise in addressing this diagnostic gap although its clinical application is hampered by its complicated workflow, demanding sample requirements, and exorbitant cost. Genomic disorders represent an opportunity to demonstrate the unique capability of LRS. This study addresses the challenges of identifying missing disease-causing breakpoints in complex genomic disorders by employing multiple LRS strategies, including a novel strategy named nanopore-based rapid acquisition of neighboring genomic regions (NanoRanger). NanoRanger requires neither detailed prior genetic mapping nor large amounts of ultrahigh-molecular-weight DNA, and it stands out for its ease of use and ultra-rapid acquisition of large genomic regions of interest with deep coverage. We describe a cohort of 13 families, each harboring a different homozygous disease-causing genomic rearrangement that defied breakpoint determination by SRS and Optical Genome Mapping (OGM). In each case, NanoRanger identified the breakpoints with a single base-pair resolution. This has enabled the accurate determination of the carrier status of unaffected family members as well as the founder nature of these genomic lesions and their frequency in the local population. It has also enabled an unprecedented analysis of the DNA motifs to discern the mechanism that predisposed to these recessive rearrangements. Our data suggest that NanoRanger can greatly accelerate the clinical adoption of LRS and expand its access for the benefit of patients with rare diseases.

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Section: Long-read Sequencing (Lrs)mentioning

confidence: 99%

“…Research studies over the last several years have highlighted the utility of long reads in diagnosing genetic disorders where the standard of care assays fail to achieve a molecular diagnosis (Amarasinghe et al, 2020; Ardui et al, 2018; Borras et al, 2017; Melas et al, 2022; D. E. Miller et al, 2021, 2022). These studies fall into the two broad categories: (1) identifying pathogenic variants in regions difficult to sequence with short‐reads: repeat expansions, homopolymers, protein‐coding genes with pseudogenes, long insertions (>50 base pairs), and complex structural rearrangements, and (2) resolving unknown or uncertain phase in autosomal recessive conditions where short‐read technology requires additional sequencing of parental samples.…”

Section: Introductionmentioning

confidence: 99%

“…LRS revealed the deletion and the single nucleotide variant in the same experiment with phase resolution in the same experiment. More recently, Miller et al used Oxford Nanopore sequencing in a cohort of nine patients with a clinical diagnosis of Werner Syndrome (WRN; MIM# 277700) (D. E. Miller et al, 2022). Werner syndrome is an autosomal recessive disorder caused by loss of function variants in the gene WRN (MIM# 604611).…”

Section: Introductionmentioning

confidence: 99%

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Long‐read sequencing for molecular diagnostics in constitutional genetic disorders

et al. 2022

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Long-read sequencing (LRS) has been around for more than a decade, but widespread adoption of the technology has been slow due to the perceived high error rates and high sequencing cost. This is changing due to the recent advancements to produce highly accurate sequences and the reducing costs. LRS Chromosomal microarrays (SNP arrays and array CompetitiveGenomic Hybridization [aCGH]) have been considered the gold standard to detect submicroscopic deletions and duplications greater than 50 kb in length for over a decade. Currently, CMA is a first-tier diagnostic test for many congenital disorders, including developmental delay, autism, and multiple congenital anomalies (D. T. Miller et al., 2010). Targeted arrays, often focusing on exonic regions, are also companions for panel-based or targeted gene testing. While

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Targeted long-read sequencing identifies missing pathogenic variants in unsolved Werner syndrome cases

Cited by 19 publications

References 41 publications

Implementation of Nanopore sequencing as a pragmatic workflow for copy number variant confirmation in the clinic

Implementation of Nanopore sequencing as a pragmatic workflow for copy number variant confirmation in the clinic

NanoRanger enables rapid single base-pair resolution of genomic disorders

Long‐read sequencing for molecular diagnostics in constitutional genetic disorders

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