This is a proposal to determine the functional properties of till-now-mysterious type II afferents of the mammalian cochlea. Although comprising only a small fraction (5-10%) of all cochlear afferents, their unique arborization to outer hair cells, and termination pattern in the auditory brainstem strongly imply a functional role quite distinct from that of the type I afferents. Limited data suggest that type II afferents have a very high acoustic threshold, perhaps signaling only traumatic or painful levels of sound. Further extending an analogy to somatic pain fibers, type II afferents are activated by ATP that can be released during cochlear trauma, as it is in damaged skin. This project will involve giga-ohm-seal intracellular recording from type II afferents in cochlear segments ex vivo to characterize the excitability and synaptic function of type II afferents. Basic membrane properties, action potential threshold and initiation site, and the size and distribution of synaptic inputs will be determined. Quantal analysis will determine outer hair cell synaptic strength. Pre- and postsynaptic structures associated with recorded fibers will be immunolabeled posthoc. These data will be incorporated into an anatomically-correct, compartmental model to obtain an estimate of the acoustic stimulus required to activate the type II afferent. To explore further a possible role in cochlear trauma, type II recordings will be made in cochleae that have been damaged by loud sound and/or exposure to ototoxins. Hearing loss can lead to hyperacusis and the phantom percept of tinnitus. The analogy to peripheral sensitization and 'phantom limb pain' prompts parallels with somatic neuropathy. Delineation of the functional role of type II afferents adds essential, long-missing information on cochlear function that will enhance theories of auditory pathogenesis, and may provide new therapeutic targets.
Hearing loss and the associated pathologies of hyperacusis and tinnitus result from loss of cochlear hair cells, and altered activity in cochlear afferent neurons. This proposal will determine the responsiveness, signaling and pharmacology of type II cochlear afferents that have until recently been entirely mysterious. Auditory pathogenesis may result from an altered balance of activity between small type II, and large type I afferents, by analogy to neuropathic pain in the somatic nervous system, thus providing the type II afferent as a novel therapeutic target.
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