Relationship between inner hair cell synaptopathy and outer hair cell loss in two mouse models of accelerated age-related hearing loss.

Hallmarks of sensorineural hearing loss are elevated hearing thresholds and defects in temporal auditory processing, the former being often caused by outer hair cell (OHC) damage, and the latter by the loss of synapses between inner hair cells (IHCs) and spiral ganglion neurons. In the well-studied CBA/CaJ mouse strain, these impairments are disconnected, IHC synaptopathy preceding OHC loss. We have investigated the relationship between IHC synaptopathy and OHC loss in the C57BL/6J (B6) and ICR mouse strains that model accelerated age-related hearing loss. Regression analysis revealed a strong correlation between these variables across the high-to-low frequency axis of the cochlea. Using the fluorescent dye FM1-43 as a proxy for mechanotransduction (MET) in the hair-cell stereocilia bundle, we found that MET malfunction coexisted with synaptopathy in IHCs. Thus, our results suggest that a MET defect drives IHC synaptopathy in the B6 and ICR strains known to carry a missense mutation of Cadherin 23, encoding a stereocilia bundle protein. Previous data have suggested that OHC stereocilia abnormalities could trigger OHC death. Therefore, stereocilia defect could be a trigger of intracellular stress that drives both IHC synaptopathy and OHC loss. To determine whether tauroursodeoxycholic acid (TUDCA), known to target several stress signalling pathways, could influence cochlear pathology, we conducted long-term TUDCA delivery to ICR mice. TUDCA provided partial protection against IHC synaptopathy but did not prevent OHC loss. These results in two mouse models of accelerated cochlear pathology provide novel insights into the mechanisms behind age-related hearing loss.