Gene Correction of a Duchenne Muscular Dystrophy Mutation by Meganuclease-Enhanced Exon Knock-in

Duchenne muscular dystrophy (DMD) is a severe inherited, muscle wasting disorder caused by mutations in the DMD gene. Gene therapy development for DMD has concentrated on vector-based DMD minigene transfer, cell-based gene therapy using genetically modified adult muscle stem cells or healthy wild-type donor cells, and antisense oligonucleotide-induced exon skipping therapy to restore the reading frame of the mutated DMD gene. This study is an investigation into DMD gene targeting-mediated correction of deletions in human patient myoblasts using a target-specific meganuclease (MN) and a homologous recombination repair matrix. The MN was designed to cleave within DMD intron 44, upstream of a deletion hot-spot, and integration-competent lentiviral vectors expressing the nuclease (LVcMN) were generated. MN western blotting and deep gene sequencing for LVcMN-induced non-homologous end joining indels confirmed efficient MN expression and activity in transduced DMD myoblasts. A homologous repair matrix carrying exons 45-52 (RM45-52) was designed and packaged into integration-deficient lentiviral vectors (IDLVs; LVdRM45-52). Following co-transduction of DMD myoblasts harbouring a deletion of exons 45 to 52 with LVcMN and LVdRM45-52 vectors, targeted knock-in of the RM45-52 region in the correct location in DMD intron 44, and expression of full length, correctly spliced wild-type dystrophin mRNA containing exons 45-52 was observed. This work demonstrates that genome surgery of human DMD gene mutations can be achieved by meganuclease-induced locus-specific genome cleavage and homologous recombination knock-in of deleted exons. The feasibility of human DMD gene repair in patient myoblasts has exciting therapeutic potential.