Your search keyword '"Horike-Pyne M"' showing total 2 results

1. Synchronized long-read genome, methylome, epigenome, and transcriptome for resolving a Mendelian condition.

Author

Vollger MR, Korlach J, Eldred KC, Swanson E, Underwood JG, Cheng YH, Ranchalis J, Mao Y, Blue EE, Schwarze U, Munson KM, Saunders CT, Wenger AM, Allworth A, Chanprasert S, Duerden BL, Glass I, Horike-Pyne M, Kim M, Leppig KA, McLaughlin IJ, Ogawa J, Rosenthal EA, Sheppeard S, Sherman SM, Strohbehn S, Yuen AL, Reh TA, Byers PH, Bamshad MJ, Hisama FM, Jarvik GP, Sancak Y, Dipple KM, and Stergachis AB

Abstract

Resolving the molecular basis of a Mendelian condition (MC) remains challenging owing to the diverse mechanisms by which genetic variants cause disease. To address this, we developed a synchronized long-read genome, methylome, epigenome, and transcriptome sequencing approach, which enables accurate single-nucleotide, insertion-deletion, and structural variant calling and diploid de novo genome assembly, and permits the simultaneous elucidation of haplotype-resolved CpG methylation, chromatin accessibility, and full-length transcript information in a single long-read sequencing run. Application of this approach to an Undiagnosed Diseases Network (UDN) participant with a chromosome X;13 balanced translocation of uncertain significance revealed that this translocation disrupted the functioning of four separate genes ( NBEA , PDK3 , MAB21L1 , and RB1 ) previously associated with single-gene MCs. Notably, the function of each gene was disrupted via a distinct mechanism that required integration of the four 'omes' to resolve. These included nonsense-mediated decay, fusion transcript formation, enhancer adoption, transcriptional readthrough silencing, and inappropriate X chromosome inactivation of autosomal genes. Overall, this highlights the utility of synchronized long-read multi-omic profiling for mechanistically resolving complex phenotypes., Competing Interests: Conflicts J.K., J.G.U., C.T.S., A.M.W., M.K. and I.J.M. are full-time employees at PacBio, a company developing single-molecule sequencing technologies. A.B.S. is a co-inventor on a patent relating to the Fiber-seq method (US17/995,058).

Published

2023

2. Full-length isoform sequencing for resolving the molecular basis of Charcot-Marie-Tooth 2A.

Author

Stergachis AB, Blue EE, Gillentine MA, Wang LK, Schwarze U, Cortés AS, Ranchalis J, Allworth A, Bland AE, Chanprasert S, Chen J, Doherty D, Folta AB, Glass I, Horike-Pyne M, Huang AY, Khan AT, Leppig KA, Miller DE, Mirzaa G, Parhin A, Raskind W, Rosenthal EA, Sheppeard S, Strohbehn S, Sybert VP, Tran TT, Wener M, Byers PH, Nelson SF, Bamshad MJ, Dipple KM, Jarvik GP, Hoppins S, and Hisama FM

Abstract

Objectives: Transcript sequencing of patient derived samples has been shown to improve the diagnostic yield for solving cases of likely Mendelian disorders, yet the added benefit of full-length long-read transcript sequencing is largely unexplored., Methods: We applied short-read and full-length isoform cDNA sequencing and mitochondrial functional studies to a patient-derived fibroblast cell line from an individual with neuropathy that previously lacked a molecular diagnosis., Results: We identified an intronic homozygous MFN2 c.600-31T>G variant that disrupts a branch point critical for intron 6 spicing. Full-length long-read isoform cDNA sequencing after treatment with a nonsense-mediated mRNA decay (NMD) inhibitor revealed that this variant creates five distinct altered splicing transcripts. All five altered splicing transcripts have disrupted open reading frames and are subject to NMD. Furthermore, a patient-derived fibroblast line demonstrated abnormal lipid droplet formation, consistent with MFN2 dysfunction. Although correctly spliced full-length MFN2 transcripts are still produced, this branch point variant results in deficient MFN2 protein levels and autosomal recessive Charcot-Marie-Tooth disease, axonal, type 2A (CMT2A)., Discussion: This case highlights the utility of full-length isoform sequencing for characterizing the molecular mechanism of undiagnosed rare diseases and expands our understanding of the genetic basis for CMT2A.

Published

2023