679. Efficient Reconstitution of a 7kb Therapeutic Mini-Dystrophin Gene in Duchenne Muscular Dystrophy Dog Muscle

Abstract

Duchenne muscular dystrophy (DMD) is a devastating muscle wasting disease caused by mutations in the dystrophin gene. Restoring dystrophin expression by adeno-associated virus mediated gene therapy holds great promise as a mutation-independent therapy for all DMD patients. The full-length dystrophin cDNA (≈11 kb) is far beyond the 5 kb packaging capacity of a single AAV vector. Consequently, truncated micro- and mini-dystrophin genes have been used. The micro- and mini-dystrophin genes encode ≈30% and ≈50% of the full-length dystrophin coding sequence, respectively. Mini-dystrophin is expected to provide better protection than micro-dystrophin. We have previously shown that dual AAV vectors can efficiently express a 6 to 8-kb mini-dystrophin in mdx mice. Dual AAV-mediated mini-dystrophin gene therapy significantly ameliorated histopathology and improved muscle function in mdx mice, a mouse model of DMD. To translate this promising therapy to large mammals, here we evaluated the reconstitution of a 7-kb minigene in the canine model of DMD by local injection. We engineered a pair of dual-AAV vectors to express a 7-kb canine codon-optimized ΔH2-R15 mini-dystrophin gene. For easy detection, a flag-tag and a GFP gene were fused to the N-terminal and C-terminal ends, respectively. To determine whether dual AAV vectors can lead to efficient mini-dystrophin expression, we co-delivered both vectors to the extensor carpi ulnaris muscle in the forelimb of DMD dogs at a dose of 2×013 vg particles/vector/muscle. Two months after gene transfer we evaluated transduction efficiency and observed successful expression of mini-dystrophin from the dual-AAV vectors. All flag-tag positive myofibers were also positive for minidystrophin, GFP and dystrophin-associated glycoprotein complex proteins. Importantly, mini-dystrophin gene therapy also reduced muscle force loss under the stress of repeated cycles of eccentric contraction. These results establish the proof-of-concept for mini-dystrophin gene therapy in dystrophic muscles of large mammals.