An allosteric gating model recapitulates the biophysical properties of IK,L expressed in mouse vestibular type I hair cells.

Paolo Spaiardi,Elisa Tavazzani,Veronica Milesi,Walter Marcotti,Ivo Prigioni,Jacopo Magistretti,Sergio Masetto,Giancarlo Russo,Marco Manca

doi:10.1113/jp274202

Paolo Spaiardi, Elisa Tavazzani + Show 7 more

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https://doi.org/10.1113/jp274202

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Abstract

Key points Vestibular type I and type II hair cells and their afferent fibres send information to the brain regarding the position and movement of the head.The characteristic feature of type I hair cells is the expression of a low‐voltage‐activated outward rectifying K+ current, I K,L, whose biophysical properties and molecular identity are still largely unknown. In vitro, the afferent nerve calyx surrounding type I hair cells causes unstable intercellular K+ concentrations, altering the biophysical properties of I K,L.We found that in the absence of the calyx, I K,L in type I hair cells exhibited unique biophysical activation properties, which were faithfully reproduced by an allosteric channel gating scheme.These results form the basis for a molecular and pharmacological identification of I K,L. Type I and type II hair cells are the sensory receptors of the mammalian vestibular epithelia. Type I hair cells are characterized by their basolateral membrane being enveloped in a single large afferent nerve terminal, named the calyx, and by the expression of a low‐voltage‐activated outward rectifying K+ current, I K,L. The biophysical properties and molecular profile of I K,L are still largely unknown. By using the patch‐clamp whole‐cell technique, we examined the voltage‐ and time‐dependent properties of I K,L in type I hair cells of the mouse semicircular canal. We found that the biophysical properties of I K,L were affected by an unstable K+ equilibrium potential (V eqK+). Both the outward and inward K+ currents shifted V eqK+ consistent with K+ accumulation or depletion, respectively, in the extracellular space, which we attributed to a residual calyx attached to the basolateral membrane of the hair cells. We therefore optimized the hair cell dissociation protocol in order to isolate mature type I hair cells without their calyx. In these cells, the uncontaminated I K,L showed a half‐activation at –79.6 mV and a steep voltage dependence (2.8 mV). I K,L also showed complex activation and deactivation kinetics, which we faithfully reproduced by an allosteric channel gating scheme where the channel is able to open from all (five) closed states. The ‘early’ open states substantially contribute to I K,L activation at negative voltages. This study provides the first complete description of the ‘native’ biophysical properties of I K,L in adult mouse vestibular type I hair cells.

Highlights

Vestibular hair cells are responsible for relaying information about head movements to the central nervous system via afferent vestibular nerve fibres
Vestibular peripheral processing employs two distinct sensory cells: type I hair cells, which are innervated by a single afferent nerve calyx enveloping their basolateral membrane, and type II hair cells, which are contacted by 10–20 afferent bouton nerve terminals (Songer & Eatock 2013)
–44 mV, following conditioning potential (Vcond) of 16 mV, was initially inward but it reversed to outward within a few milliseconds (Fig. 2A, inset) and its size increased to a steady level consistent with a more negative VrevK+. These findings suggest that, because of the residual calyx, VrevK+ varies depending on the amount of K+ exiting the hair cell, which precludes the characterization of IK,L voltage-dependent properties

Summary

Introduction

Vestibular hair cells are responsible for relaying information about head movements to the central nervous system via afferent vestibular nerve fibres. The physiological interaction between type I hair cells and the afferent nerve calyx is still unclear, a recent study has provided evidence that this interaction preserves the fidelity of high speed synaptic transmission (Contini et al 2016). One of the most distinctive characteristic of type I hair cells is the expression of the negatively activated outward K+ current IK,L, such that it is almost fully available at the cell’s resting membrane potential (Rennie & Correia 1994; Rusch & Eatock 1996; Rusch et al 1998; Hurley et al 2006). A major problem in defining the biophysical properties of IK,L is that they seem to vary from cell to cell and during postnatal development and within the same type I hair cell over the recording time (Ricci et al 1996; Rusch & Eatock 1996; Hurley et al 2006; Contini et al 2012)

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