Cholesterol as a tool to probe the role of membrane in cochlear hair cell mechanotransduction.

Abstract

Most mechanically gated channels are sensitive to force translated through the membrane. The lipid bilayer can modulate channel function directly through lipid/protein interactions or indirectly based on membrane mechanical properties. Cholesterol is an important component of the membrane and a major modulator of membrane mechanical properties. While other ion channels and mechanically gated channels can be activated or modulated by changes to the membrane cholesterol, the functional role of membrane cholesterol in regulation of mammalian cochlear mechanotransduction (MET) channels has not been closely investigated. Using whole-cell patch clamping and live-cell fluorescence lifetime imaging (FLIM) of a viscosity-sensitive molecular rotor BODIPY 1c for the first time in the inner ear, we examined the role of membrane cholesterol in modulating the MET response properties of rat cochlear hair cells. Molecular rotors are fluorophores for which the fluorescence lifetime (the average time a fluorophore remains in the excited state) increase with increasing viscosity of their immediate environment. We confirmed extraction of cholesterol, using methyl β cyclodextrin (MβCD), with reduced filipin staining in both inner and outer hair bundles. MβCD results in reversible reduction in fluorescence lifetime in hair bundles, suggesting initial reduction followed by gradual recovery in the stereocilia membrane viscosity. MβCD reversibly increases the channel resting open probability, suggesting that cholesterol depletion increases force transfer to the MET channel. Together this data suggests that the cell membrane is part of the force relay machinery to the MET channel and could possibly interact directly with components of the MET machinery. Further studies are needed to generate causal link between MET channel gating and membrane mechanics.