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Cochlear gene therapy restores hearing and auditory processing in an atypical DFNB9 mouse model
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Cochlear gene therapy restores hearing and auditory processing in an atypical DFNB9 mouse model
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Cochlear gene therapy restores hearing and auditory processing in an atypical DFNB9 mouse model
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Journal Article
Cochlear gene therapy restores hearing and auditory processing in an atypical DFNB9 mouse model
2025
Overview
Background
The autosomal recessive deafness 9 (DFNB9) is caused by mutations in the otoferlin gene that accounts for 2–8% of all inherited deafness cases. In a previous study, we demonstrated that Adeno-associated virus (AAV) gene therapy restored hearing in a preclinical mouse model of profound DFNB9 deafness caused by a frameshift mutation leading to a complete loss of otoferlin expression. However, it remains to be demonstrated that it can address the full spectrum of DFNB9 deafness severity, while also restoring central auditory processing essential for speech understanding.
Methods
Using homologous recombination in mouse embryonic stem cells, we created a knock-in mouse model carrying the E1799del otoferlin mutation, which mirrors the human E1804del variant linked to DFNB9 deafness, characterized by moderate-to-profound deafness during febrile episodes in affected individuals. A mixture of male and female mice was used at P2, P8, and P30. Some were followed for up to 4 months for longevity monitoring and behavioral tests.
Results
The mouse model exhibits abnormal otoferlin distribution, failure of synaptic transmission in inner hair cells, and profound hearing loss, all of which is restored to normal through AAV gene therapy. Notably, we conduct objective behavioral testing to provide the first evidence that gene therapy administered to the cochlea, which is part of the peripheral auditory system, can restore frequency discrimination, indicating the recovery of central auditory processing. This is achieved even when treatment is administered late at the end of the critical period.
Conclusions
These findings indicate that gene therapy can address the entire spectrum of DFNB9 hearing loss, and that profound deafness during critical period may not impede the restoration of central auditory processing.
Plain language summary
We investigated gene therapy, a technique that introduces a healthy copy of a gene to restore normal cell function, as a potential treatment for an unusual form of inherited deafness caused by mutations in the
otoferlin
gene. These mutations result in the production of a defective protein, leading to hearing loss during fever episodes. We developed and studied a mouse model with the same genetic alteration observed in affected individuals and discovered that the deafness resulted from the abnormal protein distribution in the inner ear. We use gene therapy to correct this mislocalization and restored normal hearing. Our findings indicate that gene therapy may be an effective approach for treating all forms of otoferlin-related hearing loss.
Benamer et al. develop a knock-in mouse model carrying the E1799del otoferlin mutation to study the atypical DFNB9 variant form of deafness. They show the mouse model exhibits abnormal otoferlin distribution, failure of synaptic transmission in inner hair cells, and profound hearing loss, all of which can be restored with AAV gene therapy.
