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01-10-2014 | Original Research

Targeted Sequencing of a Pediatric Metabolic Bone Gene Panel Using a Desktop Semiconductor Next-Generation Sequencer

Authors: Frank Rauch, Liljana Lalic, Francis H. Glorieux, Pierre Moffatt, Peter Roughley

Published in: Calcified Tissue International | Issue 4/2014

Abstract

Metabolic bone disorders in children frequently are heritable, but the expanding number of genes associated with these conditions makes it difficult to perform molecular diagnosis. In the present study, we therefore evaluated a semiconductor (SC)-based sequencing system for this purpose. A total of 65 DNA samples were analyzed comprising 24 samples from patients with 27 known pathogenic mutations, 6 samples from patients with prior negative Sanger sequencing, and 35 consecutive samples from patients with suspected heritable metabolic bone disorders who had not had prior molecular diagnosis. In the samples with known pathogenic mutations, 26 of 27 mutations were identified by SC sequencing. All single nucleotide variants were correctly identified, but a 7-nucleotide duplication in CYP27B1 was not detected. SC sequencing revealed two pathogenic mutations in the six samples where prior Sanger sequencing had failed to identify a mutation. Finally, pathogenic mutations were found in 27 samples of patients with unknown mutation status (15 in COL1A1, 9 in COL1A2, 1 in LEPRE1, 1 in LRP5, 1 in PHEX). Subsequent Sanger sequencing confirmed the mutations in all 27 samples. In conclusion, we found that SC sequencing is suitable for the diagnosis of heritable metabolic bone disorders in children.

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Title: Targeted Sequencing of a Pediatric Metabolic Bone Gene Panel Using a Desktop Semiconductor Next-Generation Sequencer
Authors: Frank Rauch
Liljana Lalic
Francis H. Glorieux
Pierre Moffatt
Peter Roughley
Publication date: 01-10-2014
Publisher: Springer US
Published in: Calcified Tissue International / Issue 4/2014
Print ISSN: 0171-967X
Electronic ISSN: 1432-0827
DOI: https://doi.org/10.1007/s00223-014-9897-9

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