148. Screening and Optimization of Antisense Oligonucleotide for Skipping Human Dystrophin Exon 51 and 53

Abstract

Duchenne muscular dystrophy (DMD) results from dystrophin gene mutations, causing shift of the reading frame and preventing production of a functional protein. Most DMD mutations occur in the parts of the gene that are not critical for its function, therefore restoration of the reading frame by antisense oligonucleotide-mediated exon skipping is a viable approach. The efficacy of antisense therapy has now been proven in animal models and in clinical trials.Therapeutic effect of exon skipping largely depends on the efficiency of individual antisense oligoneotide, which has to be identified by screening. This study aims specifically to search for the most effective morpholino (PMO) oligomer to target the human dystrophin exon 51 and exon 53 for the correction of the relevant DMD mutations. We established the GFP reporter myoblast cell cultures and screened more than 40 PMOs targeting each of exon 51 and exon 53. We also examined the PMOs in normal human myoblast cultures and in humanized DMD (hDMD) mice with local delivery by i.m injection to identify PMOs of maximal skipping potency. Finally we selected 5 oligomers as vivo-PMOs targeting each of the exon 51 and 53 and examined their exon skipping efficiency in the hDMD mice by systemic delivery. We were able to identify PMOs with high exon skipping efficiency in all muscles. The selected PMOs will be further validated in patient-derived fibroblasts and then be applied to clinical trials for DMD treatment.