Transduction channels’ gating can control friction on vibrating hair-cell bundles in the ear

Hearing starts when sound-evoked mechanical vibrations of the hair-cell bundle activate mechanosensitive ion channels, giving birth to an electrical signal. As for any mechanical system, friction impedes movements of the hair bundle and thus constrains the sensitivity and frequency selectivity of au...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2014-05, Vol.111 (20), p.7185-7190
Main Authors: Bormuth, Volker, Barral, Jérémie, Joanny, Jean-François, Jülicher, Frank, Martin, Pascal
Format: Article
Language:English
Subjects:
Animals
Audio frequencies
Biological Sciences
Calcium - chemistry
Cells
Chelating Agents - chemistry
Ear - physiology
ears
Ears & hearing
Fluid mechanics
Fracture mechanics
Friction
Gentamicins - chemistry
Hair
Hair cells
Hair Cells, Auditory - physiology
hearing
Hearing - physiology
Hydrodynamics
hysteresis
Ion Channel Gating - physiology
Ion channels
Ion Channels - chemistry
Iontophoresis
Kinetics
Low speed
Oscillation
Physical Sciences
Rana catesbeiana
Signal Processing, Computer-Assisted
Signal Transduction
Stress, Mechanical
Thermodynamics
Velocity
Vibration
Viscous drag
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Summary:Hearing starts when sound-evoked mechanical vibrations of the hair-cell bundle activate mechanosensitive ion channels, giving birth to an electrical signal. As for any mechanical system, friction impedes movements of the hair bundle and thus constrains the sensitivity and frequency selectivity of auditory transduction. Friction is generally thought to result mainly from viscous drag by the surrounding fluid. We demonstrate here that the opening and closing of the transduction channels produce internal frictional forces that can dominate viscous drag on the micrometer-sized hair bundle. We characterized friction by analyzing hysteresis in the force–displacement relation of single hair-cell bundles in response to periodic triangular stimuli. For bundle velocities high enough to outrun adaptation, we found that frictional forces were maximal within the narrow region of deflections that elicited significant channel gating, plummeted upon application of a channel blocker, and displayed a sublinear growth for increasing bundle velocity. At low velocity, the slope of the relation between the frictional force and velocity was nearly fivefold larger than the hydrodynamic friction coefficient that was measured when the transduction machinery was decoupled from bundle motion by severing tip links. A theoretical analysis reveals that channel friction arises from coupling the dynamics of the conformational change associated with channel gating to tip-link tension. Varying channel properties affects friction, with faster channels producing smaller friction. We propose that this intrinsic source of friction may contribute to the process that sets the hair cell’s characteristic frequency of responsiveness.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1402556111