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Decades-old model of slow adaptation in sensory hair cells is not supported in mammals

Giusy A. Caprara, Andrew A. Mecca, Anthony W. Peng

2020Science Advances36 citationsDOIOpen Access PDF

Abstract

Hair cells detect sound and motion through a mechano-electric transduction (MET) process mediated by tip links connecting shorter stereocilia to adjacent taller stereocilia. Adaptation is a key feature of MET that regulates a cell's dynamic range and frequency selectivity. A decades-old hypothesis proposes that slow adaptation requires myosin motors to modulate the tip-link position on taller stereocilia. This "motor model" depended on data suggesting that the receptor current decay had a time course similar to that of hair-bundle creep (a continued movement in the direction of a step-like force stimulus). Using cochlear and vestibular hair cells of mice, rats, and gerbils, we assessed how modulating adaptation affected hair-bundle creep. Our results are consistent with slow adaptation requiring myosin motors. However, the hair-bundle creep and slow adaptation were uncorrelated, challenging a critical piece of evidence upholding the motor model. Considering these data, we propose a revised model of hair cell adaptation.

Topics & Concepts

Hair cellNeuroscienceStimulus (psychology)BundleSensory systemStereocilia (inner ear)Receptor potentialVestibular systemAdaptation (eye)KinociliumInner earMyosinBiologyBiophysicsAnatomyMaterials scienceReceptorPsychologyComposite materialBiochemistryPsychotherapistHearing, Cochlea, Tinnitus, GeneticsAnimal Vocal Communication and BehaviorVestibular and auditory disorders
Decades-old model of slow adaptation in sensory hair cells is not supported in mammals | Litcius