The vestibular inner ear supplies information about head motion and position to the brain, driving powerful reflexes that stabilize gaze and posture during head motions, and contributing to our sense of heading and orientation as we move through the world. Although we are not normally aware of these functions, their loss severely affects mobility by destabilizes vision and causes vertigo. Loss of vestibular function often originates in damage to hair cells and their synapses with the afferent vestibular nerve fibers that project to the brain. These hair cells, synapses, and afferent fibers have striking properties that are only partly understood. The longterm goal of this program of research is to build a comprehensive understanding of how vestibular information is generated and encoded in the inner ear. The current proposal focuses on the synaptic transfer of head motion signals from hair cells to primary vestibular neurons (Aim 1) and the subsequent initiation of action potentials (spikes) (Aim 2) in the mouse utricle, a model preparation for genetic, developmental and physiological studies. Principal methods are whole-cell patch clamping of hair cells and afferent neurons; immunolocalization of voltage-gated ion channels, pumps and synaptic markers; and computational modeling of the hair cells, synapses and afferent nerve fibers, incorporating current information on ion channels, pumps, and morphology. Vestibular afferent neurons make conventional bouton synaptic terminals on type II hair cells and unique calyceal contacts on type I hair cells. At both boutons and calyces, hair cells release vesicles of glutamate (?quantal? synaptic transmission) into the synaptic cleft, activating glutamate receptor-channels in the postsynaptic membrane to produce excitatory postsynaptic potentials and initiate spikes. At calyceal contacts, an additional ?non-quantal? transmission mechanism depends not on vesicular release or gap junctions, but rather on flow of ions from the hair cell through ion channels into the synaptic cleft and into the calyx through different ion channels. Postsynaptic responses to controlled stimulation of individual hair bundles show that quantal and non-quantal transmission modes can occur at the same calyceal synapse and that the non-quantal mode provides a fast signal that may be important for high-speed vestibular reflexes. Proposed experiments and modeling will investigate the impact of key hair cell ion channels on non-quantal transmission and delineate how quantal and non-quantal transmission are integrated in individual calyces and afferent nerve fibers. Other experiments will test how specific voltage-gated potassium and sodium channels in calyces and boutons shape the postsynaptic voltage response and spikes in the axonal initial segment. Immunolocalization has revealed remarkable concentrations of ion channels in microdomains of the calyx ending and nearby spike initiation zone. Experiments focus on channels with the potential to shape salient differences in response dynamics and spike timing between afferents of different connectivity (hair cell inputs) and different zones of the sensory epithelium.

Public Health Relevance

The vestibular inner ear provides signals about head motion that are essential to our ability to stabilize vision, posture and orientation as we move about. The vestibular receptor cells and neurons that project to the brain have remarkable capabilities for fast and faithful encoding of head motions that are poorly understood. Proposed experiments target the mechanisms by which head motion information is transferred from sensory receptor cells to neurons and then encoded in patterns of neuronal action potentials.

Agency
National Institute of Health (NIH)
Institute
National Institute on Deafness and Other Communication Disorders (NIDCD)
Type
Research Project (R01)
Project #
2R01DC012347-06A1
Application #
9539798
Study Section
Auditory System Study Section (AUD)
Program Officer
Cyr, Janet
Project Start
2012-02-16
Project End
2023-02-28
Budget Start
2018-03-14
Budget End
2019-02-28
Support Year
6
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of Chicago
Department
Biology
Type
Schools of Medicine
DUNS #
005421136
City
Chicago
State
IL
Country
United States
Zip Code
60637
Eatock, Ruth Anne (2018) Specializations for Fast Signaling in the Amniote Vestibular Inner Ear. Integr Comp Biol 58:341-350
Liu, Xiao-Ping; Wooltorton, Julian R A; Gaboyard-Niay, Sophie et al. (2016) Sodium channel diversity in the vestibular ganglion: NaV1.5, NaV1.8, and tetrodotoxin-sensitive currents. J Neurophysiol 115:2536-55
McLean, Will J; McLean, Dalton T; Eatock, Ruth Anne et al. (2016) Distinct capacity for differentiation to inner ear cell types by progenitor cells of the cochlea and vestibular organs. Development 143:4381-4393
Schuth, Olga; McLean, Will J; Eatock, Ruth Anne et al. (2014) Distribution of Na,K-ATPase ? subunits in rat vestibular sensory epithelia. J Assoc Res Otolaryngol 15:739-54
Songer, Jocelyn E; Eatock, Ruth Anne (2013) Tuning and timing in mammalian type I hair cells and calyceal synapses. J Neurosci 33:3706-24