Gene Supplementation of MYO7A or activation of Myo7b for treatment of Usher syndrome 1B
Mittas, D. M.; Otify, D. Y.; Gavrilov, Z.; Heigl, T.; Suchomski, J.; Deltuvaite, P.; Hinrichsmeyer, K.; Mercey, O.; Kynast, F.; Motlik, J.; Ellederova, Z.; Ardan, T.; Klingl, A.; Grünert, J.; Mehlfeld, V.; Kolesnikova, A.; Nyshchuk, R.; Juhasova, J.; Juhas, S.; Drutovic, S.; Fischer, M. D.; Veith, M.; Stranak, Z.; Boon, N.; Wijnholds, J.; Wiest, A.; Kielkowski, P.; Gökce, G.; Guichard, P.; Hamel, V.; Ammer, H.; Michalakis, S.; Koch, S.; Biel, M.; Becirovic, E.
Show abstract
Mutations in MYO7A result in the most severe subtype of Usher syndrome, the leading genetic cause of deafblindness. The large size of MYO7A requires dual adeno-associated virus (AAV) vectors for gene transfer or alternative methods to treat retinal defects. Here, we evaluated two treatment approaches: i) Supplementation of the human MYO7A gene via dual mRNA trans-splicing AAVs, and ii) CRISPR/Cas-mediated activation of the related murine Myo7b gene. Upon MYO7A supplementation, the transgenic MYO7A transcript and protein were expressed and correctly localized in retinal pigment epithelial (RPE) and photoreceptors of mice, pigs, and human retinal organoids. In RPE-and photoreceptor-specific Myo7a knockout mice, we could restore MYO7A expression and localization of melanosomes in RPE cells to wild-type levels. Myo7b activation led to partial restoration of melanosome localization, and the localization of MYO7B protein was largely comparable to MYO7A. These findings indicate that both approaches are in principle suitable for the therapy of Usher syndrome.
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