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PPMO therapy for dysferlinopathy induces pseudoexon skipping and restoration of functional protein
James E. Gooding, Gyeongsu Park, Atish Wagh, Jonathan K. Watts, Janice A. Dominov, Robert H. Brown
James E. Gooding, Gyeongsu Park, Atish Wagh, Jonathan K. Watts, Janice A. Dominov, Robert H. Brown
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Research In-Press Preview Genetics Muscle biology

PPMO therapy for dysferlinopathy induces pseudoexon skipping and restoration of functional protein

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Abstract

The dysferlinopathies are a spectrum of autosomal recessive muscle diseases caused by mutations in the dysferlin gene (DYSF) gene. Clinical manifestations vary from asymptomatic hyperCKemia to severe muscle pathology and loss of muscle function. These are designated limb-girdle muscular dystrophy type 2R or LGMDR2 (formerly LGMD2B or Miyoshi myopathy). Among other functions, dysferlin is crucial for plasma membrane repair and maintenance of intracellular calcium homeostasis. In previous studies, we identified in two independent point mutations deep within introns that cause aberrant DYSF mRNA splicing and the inclusion of pseudoexons within transcripts that disrupt protein expression. In this study, we generated and characterized a novel mouse model for one of these mutations (within DYSF intron 44). In these mice, a segment of human DYSF DNA containing the mutant intronic sequence flanked by surrounding human exon sequences replaces the normal homologous mouse DNA. These mice exhibit aberrant Dysf pre-mRNA splicing, pseudoexon inclusion, loss of DYSF protein expression, and muscle pathology similar to that observed in patients. Using this new model, we identified antisense oligonucleotides and then a PPMO that blocks the mouse Dysf pre-mRNA splicing complexes from binding the mutant pre-mRNA, thereby restoring nearly normal muscle histology and function.

Authors

James E. Gooding, Gyeongsu Park, Atish Wagh, Jonathan K. Watts, Janice A. Dominov, Robert H. Brown

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