T.O.4 Development of AAV-gene and protein-based therapies for X-linked myotubular myopathy

MTM1 gene mutations cause X-linked myotubular myopathy (XLMTM), a fatal congenital myopathy characterized by small myofibers with frequent central nuclei. XLMTM patients typically present with severe hypotonia, muscle weakness and respiratory failure. Previous intramuscular (IM) injection studies in Mtm1 KO mice demonstrated potential efficacy of gene therapy to treat the disease. We extended these results to a large animal model by testing IM delivery of an AAV8-canine MTM1 vector into the cranial tibialis muscle of dogs with XLMTM. We observed dramatic improvement in strength of treated limb muscles to levels approaching that of age-matched normal littermates. This response was detectable at 1 week post-injection and improvement continued until a terminal measurement at 6 weeks post-injection. Concomitantly, the AAV-injected XLMTM muscles showed substantial increase in mass and myofiber size, and decreases in pathological features. We also utilized the Mtm1 KO mouse to determine the response to systemic intravenous delivery of an AAV serotype 9 vector expressing myotubularin under the muscle-specific desmin promoter. Myotubularin was rapidly and persistently expressed in muscles scattered throughout the body and this translated into robust improvement of skeletal muscle pathology and contractile force, and normalized motor activity of treated mice. Importantly, the lifespans of treated mice, which normally survive ∼7–8 weeks, were prolonged to >6 months. We then evaluated the effects of a targeted protein-replacement agent (3E10Fv-MTM1) injected into the tibialis anterior muscle of Mtm1 KO mice. Injection of 3E10Fv-MTM1 over 2 weeks increased contractile function (p