C. Shilling

Gentamicin-induced readthrough of stop codons in duchenne muscular dystrophy

The objective of this study was to establish the feasibility of long‐term gentamicin dosing to achieve stop codon readthrough and produce full‐length dystrophin. Mutation suppression of stop codons, successfully achieved in the mdx mouse using gentamicin, represents an important evolving treatment strategy in Duchenne muscular dystrophy (DMD).

Limb-Girdle Muscular Dystrophy in the United States

Limb-girdle muscular dystrophy (LGMD) has been linked to 15 chromosomal loci, 7 autosomal-dominant (LGMD1A to E) and 10 autosomal-recessive (LGMD2A to J). To determine the distribution of subtypes among patients in the United States, 6 medical centers evaluated patients with a referral diagnosis of LGMD. Muscle biopsies provided histopathology and immunodiagnostic testing, and their protein abnormalities along with clinical parameters directed mutation screening. The diagnosis in 23 patients was a disorder other than LGMD. Of the remaining 289 unrelated patients, 266 had muscle biopsies sufficient for complete microscopic evaluation; 121 also underwent Western blotting. From this combined evaluation, the distribution of immunophenotypes is 12% calpainopathy, 18% dysferlinopathy, 15% sarcoglycanopathy, 15% dystroglycanopathy, and 1.5% caveolinopathy. Genotypes distributed among 2 dominant and 7 recessive subtypes have been determined for 83 patients. This study of a large racially and ethnically diverse population of patients with LGMD indicates that establishing a putative subtype is possible more than half the time using available diagnostic testing. An efficient approach to genotypic diagnosis is muscle biopsy immunophenotyping followed by directed mutational analysis. The most common LGMDs in the United States are calpainopathies, dysferlinopathies, sarcoglycanopathies, and dystroglycanopathies.

Follistatin Gene Delivery Enhances Muscle Growth and Strength in Nonhuman Primates

A vector delivered into muscles of monkeys generates a natural regulatory molecule, which increases muscle size and strength and may be useful therapeutically. Beyond Mighty Mouse: Building Muscle Mass Strength in Monkeys Patients with progressive neuromuscular disorders all experience the foreboding of the severe disability that awaits them and from which there is little to no relief. Although this class of disorders has multiple genetic and physiological origins, a therapy that directly addresses the debilitating muscle weakness that is the hallmark of these maladies would enhance the lives of millions. Now, in an extension of their previous work in dystrophic mice, Kota et al. describe such a therapeutic approach in preclinical studies performed in nonhuman primates. This treatment mode is applicable to several progressive neuromuscular disorders whether or not scientists have defined their precise genetic defects. The authors used a gene therapy approach to introduce a version of the human gene encoding follistatin into the muscles of the femurs of healthy cynomolgus macaques. Follistatin is a potent inhibitor of myostatin, a signaling molecule that regulates skeletal muscle mass. Follistatin blocks myostatin signaling and augments muscle size and strength safely in mice but, until now, has not been tested in primates. Kota et al. injected a follistatin-producing gene therapy vector into the leg muscles of the monkeys and measured increases in muscle mass and strength. Sustained follistatin expression caused no aberrations in the structures or functions of a variety of organs. This promising progress comes with some caveats. Because healthy monkeys served as subjects for this therapeutic protocol, these findings are not predictive of the outcome in a clinical setting with patients suffering from muscle disorders. In certain genetic neuromuscular diseases, the muscles undergo a repeated cycle of degeneration and regeneration. The vector used in this study does not integrate into the muscle cell genome and thus can be lost from the cells during the degeneration-regeneration cycles. However, the authors point out that the enhancement of muscle size and strength observed in similarly treated dystrophic mice persisted for more than a year even though there was appreciable muscle turnover. More study is needed before follistatin enters the clinic, such as a molecular assessment of gene and vector sequences in multiple tissues. Nonetheless, the work of Kota et al. constitutes proof of principle for the use of myostatin inhibitors to build muscle in primates. Antagonists of myostatin, a blood-borne negative regulator of muscle growth produced in muscle cells, have shown considerable promise for enhancing muscle mass and strength in rodent studies and could serve as potential therapeutic agents for human muscle diseases. One of the most potent of these agents, follistatin, is both safe and effective in mice, but similar tests have not been performed in nonhuman primates. To assess this important criterion for clinical translation, we tested an alternatively spliced form of human follistatin that affects skeletal muscle but that has only minimal effects on nonmuscle cells. When injected into the quadriceps of cynomolgus macaque monkeys, a follistatin isoform expressed from an adeno-associated virus serotype 1 vector, AAV1-FS344, induced pronounced and durable increases in muscle size and strength. Long-term expression of the transgene did not produce any abnormal changes in the morphology or function of key organs, indicating the safety of gene delivery by intramuscular injection of an AAV1 vector. Our results, together with the findings in mice, suggest that therapy with AAV1-FS344 may improve muscle mass and function in patients with certain degenerative muscle disorders.

C-2. Eteplirsen, a Phosphorodiamidate Morpholino Oligomer (PMO) for the Treatment of Duchenne Muscular Dystrophy (DMD): 168 Week Update on Six-Minute Walk Test (6MWT), Pulmonary Function Testing (PFT), and Safety

DMD is a rare, degenerative, X-linked recessive genetic disease that results in progressive muscle loss and premature death. DMD is caused by mutations in the dystrophin gene that lead to a reading frame shift and premature translation termination. Exon skipping, a promising disease-modifying approach for DMD, can be induced by eteplirsen, a charge neutral PMO that selectively binds to exon 51 of dystrophin pre-mRNA, restoring the open reading frame and enabling production of an internally truncated yet functional dystrophin protein as found in the less severe dystrophinopathy, Becker muscular dystrophy (BMD).

G.O.24

DMD, a rare, degenerative, genetic disease that results in progressive muscle loss and premature death affects 1:5000 male births. It is caused by deletions in the dystrophin gene, which prevents production of the dystrophin protein. There are no approved treatments available, although corticosteroids have shown some benefit. Eteplirsen is an investigational drug designed to enable functional dystrophin production in boys who are amenable to skipping exon 51. Twelve boys aged 7–13years with eligible genotypes were randomized 1:1:1 to eteplirsen 30mg/kg/wk, 50mg/kg/wk, or placebo IV for 24-weeks. All patients transitioned into an ongoing open-label extension with 30 or 50mg/kg eteplirsen. Clinical efficacy endpoints included the 6-min walk test (6MWT) and pulmonary function testing. Safety assessments included adverse event recording, EKG, ECHO, hematology, blood chemistry and urinalysis. After 120weeks of treatment, a significant clinical benefit of 65m was observed ( p =0.006) on the 6MWT for ambulatory-evaluable patients in the combined eteplirsen-treated cohorts ( n =6) versus the placebo/delayed-treatment cohort ( n =4). The eteplirsen-treated cohorts showed a decline of less than 14m in walking ability from baseline, which was not statistically significant. After a substantial decline in the first 36weeks of the study, the placebo/delayed-treatment cohort demonstrated stabilization in walking ability at week 48, i.e., 12weeks after initiation of treatment with eteplirsen when meaningful levels of dystrophin were likely produced, with