Mutations in the EMD and LMNA genes, encoding emerin and lamins A and C, are responsible for the X-linked and autosomal dominant and recessive forms of Emery-Dreifuss muscular dystrophy (EDMD). LMNA ...mutations can also lead to several other disorders, collectively termed laminopathies, involving heart, fat, nerve, bone, and skin tissues, and some premature ageing syndromes.
Fourteen members of a single family underwent neurologic, electromyographic, and cardiologic assessment. Gene mutation and protein expression analyses were performed for lamins A/C and emerin.
Clinical investigations showed various phenotypes, including isolated cardiac disease (seven patients), axonal neuropathy (one patient), and a combination of EDMD with axonal neuropathy (two patients), whereas five subjects remained asymptomatic. Genetic analyses identified the coincidence of a previously described homozygous LMNA mutation (c.892C-->T, p. R298C) and a new in-frame EMD deletion (c.110-112delAGA, p. delK37), which segregate independently. Analyses of the contribution of these mutations showed 1) the EMD codon deletion acts in X-linked dominant fashion and was sufficient to induce the cardiac disease, 2) the combination of both the hemizygous EMD and the homozygous LMNA mutations was necessary to induce the EDMD phenotype, 3) emerin was present in reduced amount in EMD-mutated cells, and 4) lamin A/C and emerin expression was most dramatically affected in the doubly mutated fibroblasts.
This highlights the crucial role of lamin A/C-emerin interactions, with evidence for synergistic effects of these mutations that lead to Emery-Dreifuss muscular dystrophy as the worsened result of digenic mechanism in this family.
In the context of future AAV-based clinical trials for Duchenne myopathy, AAV genome fate in dystrophic muscles is of importance considering the viral capsid immunogenicity that prohibits recurring ...treatments. We followed AAV genome copy numbers after AAV-U7 delivery in the mdx dystrophic mouse. We showed that AAV genomes encoding non-therapeutic U7 were lost from mdx muscles within three weeks after intra-muscular injection. In contrast, AAV genomes encoding U7ex23 restoring expression of a slightly shortened dystrophin were maintained endorsing that the arrest of the dystrophic process is crucial for maintaining viral genomes in transduced fibers. Indeed, muscles treated with low doses of AAV-U7ex23, resulting in sub-optimal exon-skipping, displayed much lower titers of viral genomes, showing that sub-optimal dystrophin restoration does not prevent AAV genome loss. We also followed therapeutic viral genomes in severe dystrophic dKO mice over time after systemic treatment with scAAV9-U7ex23. Dystrophin restoration decreased significantly between 3 and 12 months in various skeletal muscles, which was correlated with important viral genome loss, except in the heart. Altogether these data show that the success of future AAV-U7 therapy for Duchenne patients would require optimal doses of AAV-U7 to induce substantial levels of dystrophin to stabilize the treated fibers and maintain the long lasting effect of the treatment.
In the course of a mutation search performed by muscle dystrophin transcript analysis in 72 Duchenne and Becker Muscular Dystrophies (DMD/BMD) patients without gross gene defect, we encountered four ...unrelated cases with additional out-of-frame sequences precisely intercalated between two intact exons of the mature muscle dystrophin mRNA. An in silico search of the whole dystrophin genomic sequence revealed that these inserts correspond to cryptic exons flanked by one strong and one weak consensus splice site and located in the mid-part of large introns (introns 60, 9, 1M, and 62, respectively). In each case we identified an intronic point mutation activating the cryptic donor or acceptor splice site. The patients exhibited a BMD/intermediate phenotype consistent with the presence of reduced amounts of normally spliced transcript and normal dystrophin. The frequency of this new type of mutation is not negligible (6% of our series of 65 patients with ‘small’ mutations). It would be missed if the exploration of the DMD gene is exclusively performed on exons and flanking sequences of genomic DNA.
