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

Stephanie U Greer; Jacquelin Botello; Donna Hongo; Brynn Levy; Premal Shah; Matthew Rabinowitz; Danny E Miller; Kate Im; Akash Kumar

doi:10.1186/s12967-023-04243-y

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

J Transl Med. 2023 Jun 10;21(1):378. doi: 10.1186/s12967-023-04243-y.

Authors

Stephanie U Greer¹, Jacquelin Botello¹, Donna Hongo¹, Brynn Levy^{1

2}, Premal Shah¹, Matthew Rabinowitz^{1

3}, Danny E Miller⁴, Kate Im¹, Akash Kumar⁵

Affiliations

¹ MyOme Inc., 535 Middlefield Rd Suite 170, Menlo Park, CA, USA.
² Department of Pathology and Cell Biology, Columbia University Irving Medical Center, New York, NY, USA.
³ Natera Inc., San Carlos, CA, USA.
⁴ Department of Pediatrics, Department of Laboratory Medicine and Pathology, University of Washington, WA, Seattle, USA.
⁵ MyOme Inc., 535 Middlefield Rd Suite 170, Menlo Park, CA, USA. akumar@myome.com.

Abstract

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.

Keywords: Adaptive sampling; Clinical testing; Copy number variants; Genome analysis; Long-read sequencing; Neurodevelopmental disorders; Oxford Nanopore Technologies; Targeted sequencing.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

DNA Copy Number Variations / genetics
Genomics
High-Throughput Nucleotide Sequencing
Humans
Nanopore Sequencing*
Sequence Analysis, DNA
Workflow