Litcius/Paper detail

The potassium channel subunit KV1.8 (Kcna10) is essential for the distinctive outwardly rectifying conductances of type I and II vestibular hair cells

Hannah R Martin, Anna Lysakowski, Ruth Anne Eatock

2024eLife17 citationsDOIOpen Access PDF

Abstract

In amniotes, head motions and tilt are detected by two types of vestibular hair cells (HCs) with strikingly different morphology and physiology. Mature type I HCs express a large and very unusual potassium conductance, g K,L , which activates negative to resting potential, confers very negative resting potentials and low input resistances, and enhances an unusual non-quantal transmission from type I cells onto their calyceal afferent terminals. Following clues pointing to K V 1.8 ( Kcna10 ) in the Shaker K channel family as a candidate g K,L subunit, we compared whole-cell voltage-dependent currents from utricular HCs of K V 1.8-null mice and littermate controls. We found that K V 1.8 is necessary not just for g K,L but also for fast-inactivating and delayed rectifier currents in type II HCs, which activate positive to resting potential. The distinct properties of the three K V 1.8-dependent conductances may reflect different mixing with other K V subunits that are reported to be differentially expressed in type I and II HCs. In K V 1.8-null HCs of both types, residual outwardly rectifying conductances include K V 7 ( Knq ) channels. Current clamp records show that in both HC types, K V 1.8-dependent conductances increase the speed and damping of voltage responses. Features that speed up vestibular receptor potentials and non-quantal afferent transmission may have helped stabilize locomotion as tetrapods moved from water to land.

Topics & Concepts

Vestibular systemPatch clampPotassium channelBiophysicsConductanceProtein subunitChemistryElectrophysiologyIon channelResting potentialHair cellReversal potentialShakerMembrane potentialBiologyAnatomyNeurosciencePhysicsReceptorInner earBiochemistryCondensed matter physicsGeneVibrationQuantum mechanicsHearing, Cochlea, Tinnitus, GeneticsIon channel regulation and functionConnexins and lens biology