Implementation of a Reliable Next-Generation Sequencing Strategy for Molecular Diagnosis of Dystrophinopathies

International audienceDiagnosis of dystrophinopathies needs to combine several techniques for detecting copy number variations (CNVs; two-thirds of mutations) and single nucleotide variations (SNVs). We participated in the design of an amplicon-based PCR kit (Multiplicom) for sequencing with a GS-Junior instrument (Roche) and later with a MiSeq instrument (Illumina). We compared two different software programs, MiSeq Reporter (Illumina) and SeqNext (JSI Medical Systems) for data analyses. Testing of six patient DNA samples carrying 72 SNVs in the DMD gene showed an experimental sensitivity of 91.7% with MiSeq Reporter, 98.6% with SeqNext, and >99.9% with both, demonstrating the need to use two different software programs. Analytical specificity was >98%. Fifty-eight additional patient DNAs were analyzed, and 25 deleterious mutations were identified, without false-negative results. We also tested the possibility for our protocol to identify CNVs. We performed additional next-generation sequencing experiments on 50 DNAs and identified 28 CNVs, all confirmed by multiple ligation probe amplification. Statistical analyses on amplicons without CNV (n = 3797), amplicons with heterozygous deletions (n = 51) or duplications (n = 191), and with hemizygous duplications (n = 63) showed a sensitivity and specificity of >99.9%. We implemented a strategy to simultaneously detect SNVs and CNVs in the DMD gene with one comprehensive technique, allowing considerable reduction of time and cost burden for diagnosis of dystrophinopathies

Novel dominant distal titinopathy phenotype associated with copy number variation

International audienceThe aim of this study was to analyze patients from two distinct families with a novel distal titinopathy phenotype associated with exactly the same CNV in the TTN gene. We used an integrated strategy combining deep phenotyping and complete molecular analyses in patients. The CNV is the most proximal out-of-frame TTN variant reported and leads to aberrant splicing transcripts leading to a frameshift. In this case, the dominant effect would be due to dominant-negative and/or haploinsufficiency. Few CNV in TTN have been reported to date. Our data represent a novel phenotype-genotype association and provides hypotheses for its dominant effects

The importance of an integrated genotype-phenotype strategy to unravel the molecular bases of titinopathies

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Evaluating next-generation sequencing in neuromuscular diseases with neonatal respiratory distress

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Long-Reads Sequencing Strategy to Localize Variants in TTN Repeated Domains

International audienceTitin protein is responsible for muscle elasticity. The TTN gene, composed of 364 exons, is subjected to extensive alternative splicing and leads to different isoforms expressed in skeletal and cardiac muscle. Variants in TTN are responsible for myopathies with a wide phenotypic spectrum and autosomal dominant or recessive transmission. The I-band coding domain, highly subject to alternative splicing, contains a three-zone block of repeated sequences with 99% homology. Sequencing and localization of variants in these areas are complex when using short-reads sequencing, a second-generation sequencing technique. We have implemented a protocol based on the third-generation sequencing technology (long-reads sequencing). This new method allows us to localize variants in these repeated areas to improve the diagnosis of TTN-related myopathies and offer the analysis of relatives in postnatal or in prenatal screening

A Reliable Targeted Next-Generation Sequencing Strategy for Diagnosis of Myopathies and Muscular Dystrophies, Especially for the Giant Titin and Nebulin Genes

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An Integrated Clinical-Biological Approach to Identify Interindividual Variability and Atypical Phenotype-Genotype Correlations in Myopathies: Experience on A Cohort of 156 Families

International audienceDiagnosis of myopathies is challenged by the high genetic heterogeneity and clinical overlap of the various etiologies. We previously reported a Next-Generation Sequencing strategy to identify genetic etiology in patients with undiagnosed Limb-Girdle Muscular Dystrophies, Congenital Myopathies, Congenital Muscular Dystrophies, Distal Myopathies, Myofibrillar Myopathies, and hyperCKemia or effort intolerance, using a large gene panel including genes classically associated with other entry diagnostic categories. In this study, we report the comprehensive clinical-biological strategy used to interpret NGS data in a cohort of 156 pediatric and adult patients, that included Copy Number Variants search, variants filtering and interpretation according to ACMG guidelines, segregation studies, deep phenotyping of patients and relatives, transcripts and protein studies, and multidisciplinary meetings. Genetic etiology was identified in 74 patients, a diagnostic yield (47.4%) similar to previous studies. We identified 18 patients (10%) with causative variants in different genes (ACTA1, RYR1, NEB, TTN, TRIP4, CACNA1S, FLNC, TNNT1, and PAPBN1) that resulted in milder and/or atypical phenotypes, with high intrafamilial variability in some cases. Mild phenotypes could mostly be explained by a less deleterious effect of variants on the protein. Detection of inter-individual variability and atypical phenotype-genotype associations is essential for precision medicine, patient care, and to progress in the understanding of the molecular mechanisms of myopathies