In Vivo Assessment of Potential Therapeutic Approaches for USH2A-Associated Diseases

Abstract

Mutations in USH2A gene account for most cases of Usher syndrome type II (USH2), characterized by a combination of congenital hearing loss and progressive vision loss. In particular, approximately 30% of USH2A patients harbor a single base pair deletion, c.2299delG, in exon 13 that creates a frameshift and premature stop codon, leading to a nonfunctional USH2A protein. The USH2A protein, also known as usherin, is an extremely large transmembrane protein (5202 aa), which limits the use of conventional AAV-mediated gene therapy; thus development of alternative approaches is required for the treatment of USH2A patients. As usherin contains multiple repetitive domains, we hypothesize that removal of one or more of those domains encoded by mutant exon(s) in the USH2A gene may reconstitute the reading frame and restore the production of a shortened yet adequately functional protein. In this study, we deleted the exon 12 of mouse Ush2a gene (corresponding to exon 13 of human USH2A) using CRISPR/Cas9-based exon-skipping approach and revealed that a shortened form of Ush2a that lacks exon 12 (Ush2a-∆Ex12) is produced and localized correctly in the cochlea. When the Ush2a-∆Ex12 allele is expressed on an Ush2a null background, the Ush2a-∆Ex12 protein can successfully restore the impaired hair cell structure and the auditory function in the Ush2a−/− mice. These results demonstrate that CRISPR/Cas9-based exon-skipping strategy holds a great therapeutic potential for the treatment of USH2A patients.