The outer hair cell of the organ of Corti possesses a voltage-dependent motile frequency response: evidence for the frequency-dependent compliance of prestin.

The outer hair cell (OHC) of the organ of Corti underlies a mechanically based process that enhances hearing, termed cochlear amplification. The cell possesses a unique motor protein, prestin, which senses voltage and consequently changes conformation to cause large cell length changes, termed electromotility (eM). In OHCs studied in vitro, the prestin voltage sensor generates a capacitance that is both voltage and frequency dependent, peaking in magnitude at a characteristic membrane voltage (Vh), which can be greater than the linear capacitance of the cell. Consequently, the OHC membrane time constant is multifarious depending upon resting potential and frequency of AC evaluation. After precisely correcting for this influence on the whole-cell voltage clamp time constant, we find that OHC eM is low pass in nature, substantially attenuating in magnitude within the frequency bandwidth of human speech. The frequency response is slowest at Vh, with a cut-off near 1.5 kHz, but increases up to six-fold in a U shaped manner as holding voltage deviates from Vh. NLC measures follow this pattern. Viscous drag alone cannot account for such eM behavior; nor can it arise from viscous drag in combination with a sigmoidal voltage-dependent OHC stiffness. However, viscous drag combined with kinetics of prestin, likely corresponding to its bell-shaped conformational gating compliance (Iwasa, 2000), is in line with our observations. How OHC eM influences cochlear amplification at higher frequencies needs reconsideration.