Deflection of the sensory hair cell's hair bundle (mechanotransduction) results in an electrical response from the hair cell that is the primary signal for audition. Disruption of this pathway by noise, ototoxic agents or aging leads to maladies such as threshold shifts (both temporary and permanent), hearing loss, deafness at an extreme and may even underlie some forms of Tinnitus. Understanding the mechanisms involved in the mechanotransduction process should help identify sites for intervention and prevention of hearing loss and may also provide guidelines for development of replacement therapies such as hair cell regeneration. Although a great deal of knowledge regarding mechanotransduction has accrued over the past 25 years, many fundamental questions regarding mechanisms and functions remain to be elucidated. Experiments herein will use state of the art optical and electrical techniques coupled with tissue culture and pharmacological tools to probe several basic questions regarding hair cell mechanotransduction.
Specific Aim (SA) 1 will determine whether the functional mechano electric transduction (MET) channels are located at the tops or along the sides of the stereocilia by taking advantage of the morphological arrangement of inner hair cell bundles. It will determine the number of channels per stereocilia by coupling calcium imaging of individual stereocilia with measurements of MET current. Finally, it will determine the role of membrane tension on channel gating which should give insight into whether the MET channel is directly tethered to the tip-link or cytoskeleton or whether it is activated via membrane stretch. SA2 will investigate the Ca2+ dependence of adaptation and activation by coupling Ca2+ imaging, Ca2+ uncaging and electrophysiological measurements of MET currents. These experiments will attempt to separate calcium-dependent responses from mechanical stimulation and should yield important new kinetic information regarding the calcium regulation of transduction and adaptation. Experiments will also explore the Ca2+ dependence of hair bundle mechanics. SA3 will investigate single channel MET properties to determine the mechanism by which Ca2+ regulates channel conductance and open time. SA4 will test the hypothesis that MET provides mechanical tuning to the hair cell.

National Institute of Health (NIH)
National Institute on Deafness and Other Communication Disorders (NIDCD)
Research Project (R01)
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Special Emphasis Panel (ZRG1-IFCN-B (02))
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Cyr, Janet
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Stanford University
Schools of Medicine
United States
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