Virginie Kergourlay scite author profile

Virginie Kergourlay

3Publications

77Citation Statements Received

109Citation Statements Given

How they've been cited

How they cite others

134

Affiliations

Inserm, Aix-Marseille University

Publications

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Identification of Splicing Defects Caused by Mutations in the Dysferlin Gene

et al. 2014

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Missense, iso-semantic, and intronic mutations are challenging for interpretation, in particular for their impact in mRNA. Various tools such as the Human Splicing Finder (HSF) system could be used to predict the impact on splicing; however, no diagnosis result could rely on predictions alone, but requires functional testing. Here, we report an in vitro approach to study the impact of DYSF mutations on splicing. It was evaluated on a series of 45 DYSF mutations, both intronic and exonic. We confirmed splicing alterations for all intronic mutations localized in 5 or 3 splice sites. Then, we showed that DYSF missense mutations could also result in splicing defects: mutations c.463G>A and c.2641A>C abolished ESEs and led to exon skipping; mutations c.565C>G and c.1555G>A disrupted Exonic Splicing Enhancer (ESE), while concomitantly creating new 5 or 3 splice site leading to exonic out of frame deletions. We demonstrated that 20% of DYSF missense mutations have a strong impact on splicing. This minigene strategy is an efficient tool for the detection of splicing defects in dysferlinopathies, which could allow for a better comprehension of splicing defects due to mutations and could improve prediction tools evaluating splicing defects.

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Correction of pseudoexon splicing caused by a novel intronic dysferlin mutation

Dominov

Uyan

McKenna‐Yasek

et al. 2019

Ann Clin Transl Neurol

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Objective Dysferlin is a large transmembrane protein that functions in critical processes of membrane repair and vesicle fusion. Dysferlin‐deficiency due to mutations in the dysferlin gene leads to muscular dystrophy (Miyoshi myopathy ( MM ), limb girdle muscular dystrophy type 2B ( LGMD 2B), distal myopathy with anterior tibial onset ( DMAT )), typically with early adult onset. At least 416 pathogenic dysferlin mutations are known, but for approximately 17% of patients, one or both of their pathogenic variants remain undefined following standard exon sequencing methods that interrogate exons and nearby flanking intronic regions but not the majority of intronic regions. Methods We sequenced RNA from myogenic cells to identify a novel dysferlin pathogenic variant in two affected siblings that previously had only one disease‐causing variant identified. We designed antisense oligonucleotides ( AON s) to bypass the effects of this mutation on RNA splicing. Results We identified a new pathogenic point mutation deep within dysferlin intron 50i. This intronic variant causes aberrant mRNA splicing and inclusion of an additional pseudoexon ( PE , we term PE 50.1) within the mature dysferlin mRNA . PE 50.1 inclusion alters the protein sequence, causing premature translation termination. We identified this mutation in 23 dysferlinopathy patients (seventeen families), revealing it to be one of the more prevalent dysferlin mutations. We used AON ‐mediated exon skipping to correct the aberrant PE 50.1 splicing events in vitro, which increased normal mRNA production and significantly restored dysferlin protein expression. Interpretation Deep intronic mutations can be a common underlying cause of dysferlinopathy, and importantly, could be treatable with AON ‐based exon‐skipping strategies.

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Exon 32 Skipping of Dysferlin Rescues Membrane Repair in Patients’ Cells

Barthélémy

Blouin

Wein

et al. 2015

JND

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Dysferlinopathies are a family of disabling muscular dystrophies with LGMD2B and Miyoshi myopathy as the main phenotypes. They are associated with molecular defects in DYSF, which encodes dysferlin, a key player in sarcolemmal homeostasis. Previous investigations have suggested that exon skipping may be a promising therapy for a subset of patients with dysferlinopathies. Such an approach aims to rescue functional proteins when targeting modular proteins and specific tissues.We sought to evaluate the dysferlin functional recovery following exon 32 skipping in the cells of affected patients. Exon skipping efficacy was characterized at several levels by use of in vitro myotube formation assays and quantitative membrane repair and recovery tests. Data obtained from these assessments confirmed that dysferlin function is rescued by quasi-dysferlin expression in treated patient cells, supporting the case for a therapeutic antisense-based trial in a subset of dysferlin-deficient patients.

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