scholarly journals A Biophysical Model of Nonquantal Transmission at the Vestibular Hair Cell-Calyx Synapse: KLV currents Modulate Fast Electrical and Slow K+ potentials in the Synaptic Cleft

2021 ◽  
Author(s):  
Aravind Chenrayan Govindaraju ◽  
Imran H Quraishi ◽  
Anna Lysakowski ◽  
Ruth Anne Eatock ◽  
Robert M Raphael
Keyword(s):  
Hair Cell ◽  
Hair Cells ◽  
Low Voltage ◽  
Electrical Potential ◽  
Synaptic Cleft ◽  
Biophysical Model ◽  
Afferent Neuron ◽  
Type I ◽  
Significant Finding ◽  
Vestibular Hair Cells

Vestibular hair cells transmit information about head position and motion across synapses to primary afferent neurons. At some of these synapses, the afferent neuron envelopes the hair cell, forming an enlarged synaptic terminal referred to as a calyx. The vestibular hair cell-calyx synapse supports nonquantal transmission (NQT), a neurotransmitter-independent mechanism that is exceptionally fast. The underlying biophysical mechanisms that give rise to NQT are not fully understood. Here we present a computational model of NQT that integrates morphological and electrophysiological data. The model predicts that NQT involves two processes: changes in cleft K+ concentration, as previously recognized, and very fast changes in cleft electrical potential. A significant finding is that changes in cleft electrical potential are faster than changes in [K+] or quantal transmission. The electrical potential mechanism thus provides a basis for the exceptional speed of neurotransmission between type I hair cells and primary neurons and explains experimental observations of fast postsynaptic currents. The [K+] mechanism increases the gain of NQT. Both processes are mediated by current flow through low-voltage-activated K+ (KLV) channels located in both pre-synaptic (hair cell) and post-synaptic (calyx inner face) membranes. The model further demonstrates that the calyx morphology is necessary for NQT; as calyx height is increased, NQT increases in size, speed and efficacy at depolarizing the afferent neuron. We propose that the calyx evolved to enhance NQT and speed up signals that drive vestibular reflexes essential for stabilizing the eyes and neck and maintaining balance during rapid and complex head motions.

Temporal Bone Studies of the Human Peripheral Vestibular System

2000 ◽  
Vol 109 (5_suppl) ◽  
pp. 20-25 ◽  
Author(s):  
Kojiro Tsuji ◽  
Steven D. Rauch ◽  
Conrad Wall ◽  
Luis Velázquez-Villaseñor ◽  
Robert J. Glynn ◽  
...  
Keyword(s):  
Hair Cell ◽  
Hair Cells ◽  
Ganglion Cells ◽  
Significant Loss ◽  
Small Sample ◽  
Type I ◽  
Type Ii ◽  
Vestibular Hair Cells ◽  
Scarpa's Ganglion ◽  
Temporal Bones

Quantitative assessments of vestibular hair cells and Scarpa's ganglion cells were performed on 17 temporal bones from 10 individuals who had well-documented clinical evidence of aminoglycoside ototoxicity (streptomycin, kanamycin, and neomycin). Assessment of vestibular hair cells was performed by Nomarski (differential interference contrast) microscopy. Hair cell counts were expressed as densities (number of cells per 0.01 mm2 surface area of the sensory epithelium). The results were compared with age-matched normal data. Streptomycin caused a significant loss of both type I and type II hair cells in all 5 vestibular sense organs. In comparing the ototoxic effect on type I versus type II hair cells, there was greater type I hair cell loss for all 3 cristae, but not for the maculae. The vestibular ototoxic effects of kanamycin appeared to be similar to those of streptomycin, but the small sample size precluded definitive conclusions from being made. Neomycin did not cause loss of vestibular hair cells. Within the limits of this study (maximum postototoxicity survival time of 12 months), there was no significant loss of Scarpa's ganglion cells for any of the 3 drugs. The findings have implications in several clinical areas, including the correlation of vestibular test results to pathological findings, the rehabilitation of patients with vestibular ototoxicity, the use of aminoglycosides to treat Meniere's disease, and the development of a vestibular prosthesis.

Effects of KCNQ channel blockers on K+ currents in vestibular hair cells

2001 ◽  
Vol 280 (3) ◽  
pp. C473-C480 ◽  
Author(s):  
Katherine J. Rennie ◽  
Tianxiang Weng ◽  
Manning J. Correia
Keyword(s):  
Steady State ◽  
Hair Cells ◽  
Low Voltage ◽  
Dissociation Constants ◽  
Channel Blockers ◽  
Type I ◽  
Type Ii ◽  
Kcnq Channels ◽  
Vestibular Hair Cells ◽  
Inward Currents

Linopirdine and XE991, selective blockers of K+ channels belonging to the KCNQ family, were applied to hair cells isolated from gerbil vestibular system and to hair cells in slices of pigeon crista. In type II hair cells, both compounds inhibited a slowly activating, slowly inactivating component of the macroscopic current recruited at potentials above −60 mV. The dissociation constants for linopirdine and XE991 block were <5 μM. A similar component of the current was also blocked by 50 μM capsaicin in gerbil type II hair cells. All three drugs blocked a current component that showed steady-state inactivation and a biexponential inactivation with time constants of ∼300 ms and 4 s. Linopirdine (10 μM) reduced inward currents through the low-voltage-activated K+ current in type I hair cells, but concentrations up to 200 μM had little effect on steady-state outward K+ current in these cells. These results suggest that KCNQ channels may be present in amniote vestibular hair cells.

Recovery of the Vestibulocolic Reflex After Aminoglycoside Ototoxicity in Domestic Chickens

1999 ◽  
Vol 81 (3) ◽  
pp. 1025-1035 ◽  
Author(s):  
Christopher T. Goode ◽  
John P. Carey ◽  
Albert F. Fuchs ◽  
Edwin W Rubel
Keyword(s):  
Hair Cell ◽  
Hair Cells ◽  
Afferent Input ◽  
Open Loop ◽  
Cell Regeneration ◽  
Type I ◽  
Neural Pathways ◽  
Hair Cell Regeneration ◽  
Vestibular Hair Cells ◽  
Aminoglycoside Ototoxicity

Recovery of the vestibulocolic reflex after aminoglycoside ototoxicity in domestic chickens. Avian auditory and vestibular hair cells regenerate after damage by ototoxic drugs, but until recently there was little evidence that regenerated vestibular hair cells function normally. In an earlier study we showed that the vestibuloocular reflex (VOR) is eliminated with aminoglycoside antibiotic treatment and recovers as hair cells regenerate. The VOR, which stabilizes the eye in the head, is an open-loop system that is thought to depend largely on regularly firing afferents. Recovery of the VOR is highly correlated with the regeneration of type I hair cells. In contrast, the vestibulocolic reflex (VCR), which stabilizes the head in space, is a closed-loop, negative-feedback system that seems to depend more on irregularly firing afferent input and is thought to be subserved by different circuitry than the VOR. We examined whether this different reflex also of vestibular origin would show similar recovery after hair cell regeneration. Lesions of the vestibular hair cells of 10-day-old chicks were created by a 5-day course of streptomycin sulfate. One day after completion of streptomycin treatment there was no measurable VCR gain, and total hair cell density was ∼35% of that in untreated, age-matched controls. At 2 wk postlesion there was significant recovery of the VCR; at this time two subjects showed VCR gains within the range of control chicks. At 3 wk postlesion all subjects showed VCR gains and phase shifts within the normal range. These data show that the VCR recovers before the VOR. Unlike VOR gain, recovering VCR gain correlates equally well with the density of regenerating type I and type II vestibular hair cells, except at high frequencies. Several factors other than hair cell regeneration, such as length of stereocilia, reafferentation of hair cells, and compensation involving central neural pathways, may be involved in behavioral recovery. Our data suggest that one or more of these factors differentially affect the recovery of these two vestibular reflexes.

Architecture of the Mouse Utricle: Macular Organization and Hair Bundle Heights

2008 ◽  
Vol 99 (2) ◽  
pp. 718-733 ◽  
Author(s):  
A. Li ◽  
J. Xue ◽  
E. H. Peterson
Keyword(s):  
Hair Cell ◽  
Hair Cells ◽  
Quantitative Data ◽  
Posterior Margin ◽  
Adult Mouse ◽  
Type I ◽  
Type Ii ◽  
Cell Type ◽  
Vestibular Hair Cells ◽  
Utricular Macula

Hair bundles are critical to mechanotransduction by vestibular hair cells, but quantitative data are lacking on vestibular bundles in mice or other mammals. Here we quantify bundle heights and their variation with macular locus and hair cell type in adult mouse utricular macula. We also determined that macular organization differs from previous reports. The utricle has ∼3,600 hair cells, half on each side of the line of polarity reversal (LPR). A band of low hair cell density corresponds to a band of calretinin-positive calyces, i.e., the striola. The relation between the LPR and the striola differs from previous reports in two ways. First, the LPR lies lateral to the striola instead of bisecting it. Second, the LPR follows the striolar trajectory anteriorly, but posteriorly it veers from the edge of the striola to reach the posterior margin of the macula. Consequently, more utricular bundles are oriented mediolaterally than previously supposed. Three hair cell classes are distinguished in calretinin-stained material: type II hair cells, type ID hair cells contacting calretinin-negative (dimorphic) afferents, and type IC hair cells contacting calretinin-positive (calyceal) afferents. They differ significantly on most bundle measures. Type II bundles have short stereocilia. Type IC bundles have kinocilia and stereocilia of similar heights, i.e., KS ratios (ratio of kinocilium to stereocilia heights) ∼1, unlike other receptor classes. In contrast to these class-specific differences, bundles show little regional variation except that KS ratios are lowest in the striola. These low KS ratios suggest that bundle stiffness is greater in the striola than in the extrastriola.

Evidence for an Na+-K+-Cl−cotransporter in mammalian type I vestibular hair cells

1997 ◽  
Vol 273 (6) ◽  
pp. C1972-C1980 ◽  
Author(s):  
K. J. Rennie ◽  
J. F. Ashmore ◽  
M. J. Correia
Keyword(s):  
Hair Cell ◽  
Hair Cells ◽  
Cell Swelling ◽  
Type I ◽  
Vestibular Hair Cells ◽  
Type I Cells ◽  
High K ◽  
I Cells ◽  
Shape Changes ◽  
External K

In amniotes, there are two types of hair cells, designated I and II, that differ in their morphology, innervation pattern, and ionic membrane properties. Type I cells are unique among hair cells in that their basolateral surfaces are almost completely enclosed by an afferent calyceal nerve terminal. Recently, several lines of evidence have ascribed a motile function to type I hair cells. To investigate this, elevated external K+, which had been used previously to induce hair cell shortening, was used to induce shape changes in dissociated mammalian type I vestibular hair cells. Morphologically identified type I cells shortened and widened when the external K+ concentration was raised isotonically from 2 to 125 mM. The shortening did not require external Ca2+ but was abolished when external Cl− was replaced with gluconate or sulfate and when external Na+ was replaced with N-methyl-d-glucamine. Bumetanide (10–100 μM), a specific blocker of the Na+-K+-Cl− cotransporter, significantly reduced K+-induced shortening. Hyposmotic solution resulted in type I cell shape changes similar to those seen with high K+, i.e., shortening and widening. Type I cells became more spherical in hyposmotic solution, presumably as a result of a volume increase due to water influx. In hypertonic solution, cells became narrower and increased in length. These results suggest that shape changes in type I hair cells induced by high K+ are due, at least in part, to ion and solute entry via an Na+-K+-Cl− cotransporter, which results in cell swelling. A scheme is proposed whereby the type I hair cell depolarizes and K+ leaves the cell via voltage-dependent K+channels and accumulates in the synaptic space between the type I hair cell and calyx. Excess K+ could then be removed from the intercellular space by uptake via the cotransporter.

Effects of Intratympanic Gentamicin on Vestibular Afferents and Hair Cells in the Chinchilla

2005 ◽  
Vol 93 (2) ◽  
pp. 643-655 ◽  
Author(s):  
Timo P. Hirvonen ◽  
Lloyd B. Minor ◽  
Timothy E. Hullar ◽  
John P. Carey
Keyword(s):  
Hair Cell ◽  
Hair Cells ◽  
Synaptic Activity ◽  
Type I ◽  
Vestibular Hair Cells ◽  
Intratympanic Gentamicin ◽  
Vestibular Afferents ◽  
Gentamicin Treatment ◽  
Spike Initiation ◽  
Spontaneous Firing Rate

Gentamicin is toxic to vestibular hair cells, but its effects on vestibular afferents have not been defined. We treated anesthetized chinchillas with one injection of gentamicin (26.7 mg/ml) into the middle ear and made extracellular recordings from afferents after 5–25 (early) or 90–115 days (late). The relative proportions of regular, intermediate, and irregular afferents did not change after treatment. The spontaneous firing rate of regular afferents was lower ( P < 0.001) on the treated side (early: 44.3 ± 16.3; late: 33.9 ± 13.2 spikes·s−1) than on the untreated side (54.9 ± 16.8 spikes·s−1). Spontaneous rates of irregular and intermediate afferents did not change. The majority of treated afferents did not measurably respond to tilt or rotation (82% in the early group, 76% in the late group). Those that did respond had abnormally low sensitivities ( P < 0.001). Treated canal units that responded to rotation had mean sensitivities only 5–7% of the values for untreated canal afferents. Treated otolith afferents had mean sensitivities 23–28% of the values for untreated otolith units. Sensitivity to externally applied galvanic currents was unaffected for all afferents. Intratympanic gentamicin treatment reduced the histological density of all hair cells by 57% ( P = 0.04). The density of hair cells with calyx endings was reduced by 99% ( P = 0.03), although some remaining hair cells had other features suggestive of type I morphology. Type II hair cell density was not significantly reduced. These findings suggest that a single intratympanic gentamicin injection causes partial damage and loss of vestibular hair cells, particularly type I hair cells or their calyceal afferent endings, does not damage the afferent spike initiation zones, and preserves enough hair cell synaptic activity to drive the spontaneous activity of vestibular afferents.

Differences Between Stereocilia Numbers on Type I and Type II Vestibular Hair Cells

2004 ◽  
Vol 92 (5) ◽  
pp. 3153-3160 ◽  
Author(s):  
W. J. Moravec ◽  
E. H. Peterson
Keyword(s):  
Hair Cell ◽  
Hair Cells ◽  
Direct Evidence ◽  
Cell Types ◽  
Type I ◽  
Type Ii ◽  
Functional Roles ◽  
Vestibular Hair Cells ◽  
Mechanoelectric Transduction ◽  
Bundle Structure

A major outstanding goal of vestibular neuroscience is to understand the distinctive functional roles of type I and type II hair cells. One important question is whether these two hair cell types differ in bundle structure. To address this, we have developed methods to characterize stereocilia numbers on identified type I and type II hair cells in the utricle of a turtle, Trachemys scripta. Our data indicate that type I hair cells, which occur only in the striola, average 95.9 ±16.73 (SD) stereocilia per bundle. In contrast, striolar type II hair cells have 59.9 ± 8.98 stereocilia, and type II hair cells in the adjacent extrastriola average 44.8 ± 10.82 stereocilia. Thus type I hair cells have the highest stereocilia counts in the utricle. These results provide the first direct evidence that type I hair cells have significantly more stereocilia than type II hair cells, and they suggest that the two hair cell types may differ in bundle mechanics and peak mechanoelectric transduction currents.

scholarly journals K+ Accumulation and Clearance in the Calyx Synaptic Cleft of Type I Mouse Vestibular Hair Cells

Neuroscience ◽  
2020 ◽  
Vol 426 ◽  
pp. 69-86 ◽  
Author(s):  
P. Spaiardi ◽  
E. Tavazzani ◽  
M. Manca ◽  
G. Russo ◽  
I. Prigioni ◽  
...  
Keyword(s):  
Hair Cells ◽  
Synaptic Cleft ◽  
Type I ◽  
Vestibular Hair Cells

Ionic Currents and Electromotility in Inner Ear Hair Cells From Humans

1998 ◽  
Vol 79 (4) ◽  
pp. 2235-2239 ◽  
Author(s):  
John S. Oghalai ◽  
Jeffrey R. Holt ◽  
Takashi Nakagawa ◽  
Thomas M. Jung ◽  
Newton J. Coker ◽  
...  
Keyword(s):  
Inner Ear ◽  
Hair Cells ◽  
Ionic Currents ◽  
Sensory Epithelium ◽  
Outer Hair Cells ◽  
Sensory Receptor ◽  
Surgical Removal ◽  
Type I ◽  
Vestibular Hair Cells ◽  
Sensory Receptor Cells

Oghalai, John S., Jeffrey R. Holt, Takashi Nakagawa, Thomas M. Jung, Newton J. Coker, Herman A. Jenkins, Ruth Anne Eatock, and William E. Brownell. Ionic currents and electromotility in inner ear hair cells from humans. J. Neurophysiol. 79: 2235–2239, 1998. The upright posture and rich vocalizations of primates place demands on their senses of balance and hearing that differ from those of other animals. There is a wealth of behavioral, psychophysical, and CNS measures characterizing these senses in primates, but no prior recordings from their inner ear sensory receptor cells. We harvested human hair cells from patients undergoing surgical removal of life-threatening brain stem tumors and measured their ionic currents and electromotile responses. The hair cells were either isolated or left in situ in their sensory epithelium and investigated using the tight-seal, whole cell technique. We recorded from both type I and type II vestibular hair cells under voltage clamp and found four voltage-dependent currents, each of which has been reported in hair cells of other animals. Cochlear outer hair cells demonstrated electromotility in response to voltage steps like that seen in rodent animal models. Our results reveal many qualitative similarities to hair cells obtained from other animals and justify continued investigations to explore quantitative differences that may be associated with normal or pathological human sensation.

Molecular characterization of an inward rectifier channel (IKir) found in avian vestibular hair cells: cloning and expression of pKir2.1

2004 ◽  
Vol 19 (2) ◽  
pp. 155-169 ◽  
Author(s):  
Manning J. Correia ◽  
Thomas G. Wood ◽  
Deborah Prusak ◽  
Tianxiang Weng ◽  
Katherine J. Rennie ◽  
...  
Keyword(s):  
Hair Cells ◽  
Cho Cells ◽  
Dwell Time ◽  
Single Channel ◽  
Cloning And Expression ◽  
Single Type ◽  
Type I ◽  
Type Ii ◽  
Vestibular Hair Cells ◽  
Inwardly Rectifying

A fast inwardly rectifying current has been observed in some of the sensory cells (hair cells) of the inner ear of several species. While the current was presumed to be an IKir current, contradictory evidence existed as to whether the cloned channel actually belonged to the Kir2.0 subfamily of potassium inward rectifiers. In this paper, we report for the first time converging evidence from electrophysiological, biochemical, immunohistochemical, and genetic studies that show that the Kir2.1 channel carries the fast inwardly rectifying currents found in pigeon vestibular hair cells. Following cytoplasm extraction from single type II and multiple pigeon vestibular hair cells, mRNA was reverse transcribed, amplified, and sequenced. The open reading frame (ORF), consisting of a 1,284-bp nucleotide sequence, showed 94, 85, and 83% identity with Kir2.1 subunit sequences from chick lens, Kir2 sequences from human heart, and a mouse macrophage cell line, respectively. Phylogenetic analyses revealed that pKir2.1 formed an immediate node with hKir2.1 but not with hKir2.2–2.4. Hair cells (type I and type II) and supporting cells in the sensory epithelium reacted positively with a Kir2.1 antibody. The whole cell current recorded in oocytes and CHO cells, transfected with pigeon hair cell Kir2.1 (pKir2.1), demonstrated blockage by Ba2+ and sensitivity to changing K+ concentration. The mean single-channel linear slope conductance in transfected CHO cells was 29 pS. The open dwell time was long (∼300 ms at −100 mV), and the closed dwell time was short (∼34 ms at −100 mV). Multistates ranging from 3–6 were noted in some single-channel responses. All of the above features have been described for other Kir2.1 channels. Current clamp studies of native pigeon vestibular hair cells illustrated possible physiological roles of the channel and showed that blockage of the channel by Ba2+ depolarized the resting membrane potential by ∼30 mV. Negative currents hyperpolarized the membrane ∼20 mV before block but ∼60 mV following block. RT-PCR studies revealed that the pKir2.1 channels found in pigeon vestibular hair cells were also present in pigeon vestibular nerve, vestibular ganglion, lens, neck muscle, brain (brain stem, cerebellum and optic tectum), liver, and heart.

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