AAV.Dysferlin Overlap Vectors Restore Function in Dysferlinopathy Animal Models

The limb-girdle muscular dystrophies are a genetically heterogeneous group of inherited progressive muscle disorders that affect mainly the proximal musculature, with evidence for at least three autosomal dominant and eight autosomal recessive loci. The latter mostly involve mutations in genes encoding components of the dystrophin-associated complex; another form is caused by mutations in the gene for the muscle-specific protease calpain 3. Using a positional cloning approach, we have identified the gene for a form of limb-girdle muscular dystrophy that we previously mapped to chromosome 2p13 (LGMD2B). This gene shows no homology to any known mammalian gene, but its predicted product is related to the C. elegans spermatogenesis factor fer-1. We have identified two homozygous frameshift mutations in this gene, resulting in muscular dystrophy of either proximal or distal onset in nine families. The proposed name 'dysferlin' combines the role of the gene in producing muscular dystrophy with its C. elegans homology.

Attempts to develop gene therapy for Duchenne muscular dystrophy (DMD) have been complicated by the enormous size of the dystrophin gene. We have performed a detailed functional analysis of dystrophin structural domains and show that multiple regions of the protein can be deleted in various combinations to generate highly functional mini- and micro-dystrophins. Studies in transgenic mdx mice, a model for DMD, reveal that a wide variety of functional characteristics of dystrophy are prevented by some of these truncated dystrophins. Muscles expressing the smallest dystrophins are fully protected against damage caused by muscle activity and are not morphologically different from normal muscle. Moreover, injection of adeno-associated viruses carrying micro-dystrophins into dystrophic muscles of immunocompetent mdx mice results in a striking reversal of histopathological features of this disease. These results demonstrate that the dystrophic pathology can be both prevented and reversed by gene therapy using micro-dystrophins.

AAV based vectors can achieve stable gene transfer with minimal vector related toxicities. AAV serotype 2 (AAV2) is the first AAV that was vectored for gene transfer applications. However, the restricted tissue tropism of AAV and its low transduction efficiency have limited its further development as vector. Recent studies using vectors derived from alternative AAV serotypes such as AAV1, 4, 5 and 6 have shown improved potency and broadened tropism of the AAV vector by packaging the same vector genome with different AAV capsids. In an attempt to search for potent AAV vectors with enhanced performance profiles, molecular techniques were employed for the detection and isolation of endogenous AAVs from a variety of human and non-human primate (NHP) tissues. A family of novel primate AAVs consisting of 110 non-redundant species of proviral sequences was discovered and turned to be prevalent in 18-19% of the tissues evaluated. Phylogenetic and functional analyses revealed that primate AAVs are segregated into clades based on phylogenetic relatedness. The members within a clade share functional and serological properties. Initial evaluation in mouse models of vectors based on these novel AAVs for tissue tropism and gene transfer potency led to the identification of some vector with improved gene transfer to different target tissues. Gene therapy treatment of several mouse and canine models with novel AAV vectors achieved long term phenotypic corrections. Vectors based on new primate AAVs could become the next generation of efficient gene transfer vehicles for various gene therapy applications.