Structural relationship between the putative hair cell mechanotransduction channel TMC1 and TMEM16 proteins

The hair cell mechanotransduction (MET) channel complex is essential for hearing, yet it’s molecular identity and structure remain elusive. The transmembrane channel–like 1 (TMC1) protein localizes to the site of the MET channel, interacts with the tip-link responsible for mechanical gating, and genetic alterations in TMC1 alter MET channel properties and cause deafness, supporting the hypothesis that TMC1 forms the MET channel. We generated a model of TMC1 based on X-ray and cryo-EM structures of TMEM16 proteins, revealing the presence of a large cavity near the protein-lipid interface that also harbors the Beethoven mutation, suggesting that it could function as a permeation pathway. We also find that hair cells are permeable to 3 kDa dextrans, and that dextran permeation requires TMC1/2 proteins and functional MET channels, supporting the presence of a large permeation pathway and the hypothesis that TMC1 is a pore forming subunit of the MET channel complex.

Download Full-text

Structural relationship between the putative hair cell mechanotransduction channel TMC1 and TMEM16 proteins

10.1101/327072 ◽

2018 ◽

Author(s):

Angela Ballesteros ◽

Cristina Fenollar-Ferrer ◽

Kenton J. Swartz

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Genetic Alterations ◽

Structural Relationship ◽

Large Cavity ◽

X Ray ◽

Molecular Identity ◽

Transmembrane Channel ◽

Tip Link ◽

Channel Properties

AbstractThe hair cell mechanotransduction (MET) channel complex is essential for hearing, yet it’s molecular identity and structure remain elusive. The transmembrane channel-like 1 (TMC1) protein localizes to the site of the MET channel, interacts with the tip-link responsible for mechanical gating, and genetic alterations in TMC1 alter MET channel properties and cause deafness, supporting the hypothesis that TMC1 forms the MET channel. We generated a model of TMC1 based on X-ray and cryo-EM structures of TMEM16 proteins, revealing the presence of a large cavity near the protein-lipid interface that also harbors the Beethoven mutation, suggesting that it could function as a permeation pathway. We also find that hair cells are permeable to 3 kDa dextrans, and that dextran permeation requires TMC1/2 proteins and functional MET channels, supporting the presence of a large permeation pathway and the hypothesis that TMC1 is a pore forming subunit of the MET channel complex.

Download Full-text

Permeation properties of the hair cell mechanotransducer channel provide insight into its molecular structure

Journal of Neurophysiology ◽

10.1152/jn.01178.2011 ◽

2012 ◽

Vol 107 (9) ◽

pp. 2408-2420 ◽

Cited By ~ 12

Author(s):

B. Pan ◽

J. Waguespack ◽

M. E. Schnee ◽

C. LeBlanc ◽

A. J. Ricci

Keyword(s):

Hair Cells ◽

Apparent Difference ◽

Channel Conductance ◽

Critical Function ◽

Molecular Identity ◽

Sensory Hair Cells ◽

Molecular Components ◽

Channel Properties ◽

Permeation Properties ◽

Insight Into

Mechanoelectric transducer (MET) channels, located near stereocilia tips, are opened by deflecting the hair bundle of sensory hair cells. Defects in this process result in deafness. Despite this critical function, the molecular identity of MET channels remains a mystery. Inherent channel properties, particularly those associated with permeation, provide the backbone for the molecular identification of ion channels. Here, a novel channel rectification mechanism is identified, resulting in a reduced pore size at positive potentials. The apparent difference in pore dimensions results from Ca2+ binding within the pore, occluding permeation. Driving force for permeation at hyperpolarized potentials is increased because Ca2+ can more easily be removed from binding within the pore due to the presence of an electronegative external vestibule that dehydrates and concentrates permeating ions. Alterations in Ca2+ binding may underlie tonotopic and Ca2+-dependent variations in channel conductance. This Ca2+-dependent rectification provides targets for identifying the molecular components of the MET channel.

Download Full-text

The development of cooperative channels explains the maturation of hair cell’s mechanotransduction

10.1101/654764 ◽

2019 ◽

Author(s):

Francesco Gianoli ◽

Thomas Risler ◽

Andrei S. Kozlov

Keyword(s):

Ion Channels ◽

Hair Cell ◽

Inner Ear ◽

Hair Cells ◽

Hair Bundle ◽

Mechanical Stimuli ◽

Biophysical Properties ◽

Tip Link ◽

Fast Adaptation ◽

Kinetics Of

ABSTRACTHearing relies on the conversion of mechanical stimuli into electrical signals. In vertebrates, this process of mechano-electrical transduction (MET) is performed by specialized receptors of the inner ear, the hair cells. Each hair cell is crowned by a hair bundle, a cluster of microvilli that pivot in response to sound vibrations, causing the opening and closing of mechanosensitive ion channels. Mechanical forces are projected onto the channels by molecular springs called tip links. Each tip link is thought to connect to a small number of MET channels that gate cooperatively and operate as a single transduction unit. Pushing the hair bundle in the excitatory direction opens the channels, after which they rapidly reclose in a process called fast adaptation. It has been experimentally observed that the hair cell’s biophysical properties mature gradually during postnatal development: the maximal transduction current increases, sensitivity sharpens, transduction occurs at smaller hair-bundle displacements, and adaptation becomes faster. Similar observations have been reported during tip-link regeneration after acoustic damage. Moreover, when measured at intermediate developmental stages, the kinetics of fast adaptation varies in a given cell depending on the magnitude of the imposed displacement. The mechanisms underlying these seemingly disparate observations have so far remained elusive. Here, we show that these phenomena can all be explained by the progressive addition of MET channels of constant properties, which populate the hair bundle first as isolated entities, then progressively as clusters of more sensitive, cooperative MET channels. As the proposed mechanism relies on the difference in biophysical properties between isolated and clustered channels, this work highlights the importance of cooperative interactions between mechanosensitive ion channels for hearing.SIGNIFICANCEHair cells are the sensory receptors of the inner ear that convert mechanical stimuli into electrical signals transmitted to the brain. Sensitivity to mechanical stimuli and the kinetics of mechanotransduction currents change during hair-cell development. The same trend, albeit on a shorter timescale, is also observed during hair-cell recovery from acoustic trauma. Furthermore, the current kinetics in a given hair cell depends on the stimulus magnitude, and the degree of that dependence varies with development. These phenomena have so far remained unexplained. Here, we show that they can all be reproduced using a single unifying mechanism: the progressive formation of channel pairs, in which individual channels interact through the lipid bilayer and gate cooperatively.

Download Full-text

Generation of Otic Lineages from Integration-Free Human-Induced Pluripotent Stem Cells Reprogrammed by mRNAs

Stem Cells International ◽

10.1155/2020/3692937 ◽

2020 ◽

Vol 2020 ◽

pp. 1-10 ◽

Cited By ~ 1

Author(s):

Sarah L. Boddy ◽

Ricardo Romero-Guevara ◽

Ae-Ri Ji ◽

Christian Unger ◽

Laura Corns ◽

...

Keyword(s):

Stem Cells ◽

Hair Cell ◽

Induced Pluripotent Stem Cells ◽

Cell Lines ◽

Hair Cells ◽

Pluripotent Stem Cells ◽

Genetic Alterations ◽

Pluripotent Cell ◽

Induced Pluripotent ◽

Ganglion Neurons

Damage to the sensory hair cells and the spiral ganglion neurons of the cochlea leads to deafness. Induced pluripotent stem cells (iPSCs) are a promising tool to regenerate the cells in the inner ear that have been affected by pathology or have been lost. To facilitate the clinical application of iPSCs, the reprogramming process should minimize the risk of introducing undesired genetic alterations while conferring the cells the capacity to differentiate into the desired cell type. Currently, reprogramming induced by synthetic mRNAs is considered to be one of the safest ways of inducing pluripotency, as the transgenes are transiently delivered into the cells without integrating into the genome. In this study, we explore the ability of integration-free human-induced pluripotent cell lines that were reprogrammed by mRNAs, to differentiate into otic progenitors and, subsequently, into hair cell and neuronal lineages. hiPSC lines were induced to differentiate by culturing them in the presence of fibroblast growth factors 3 and 10 (FGF3 and FGF10). Progenitors were identified by quantitative microscopy, based on the coexpression of otic markers PAX8, PAX2, FOXG1, and SOX2. Otic epithelial progenitors (OEPs) and otic neuroprogenitors (ONPs) were purified and allowed to differentiate further into hair cell-like cells and neurons. Lineages were characterised by immunocytochemistry and electrophysiology. Neuronal cells showed inward Na+ (INa) currents and outward (Ik) and inward K+ (IK1) currents while hair cell-like cells had inward IK1 and outward delayed rectifier K+ currents, characteristic of developing hair cells. We conclude that human-induced pluripotent cell lines that have been reprogrammed using nonintegrating mRNAs are capable to differentiate into otic cell types.

Download Full-text

Mechanotransduction in vertebrate hair cells: structure and function of the stereociliary bundle

AJP Cell Physiology ◽

10.1152/ajpcell.1995.268.1.c1 ◽

1995 ◽

Vol 268 (1) ◽

pp. C1-C13 ◽

Cited By ~ 79

Author(s):

C. M. Hackney ◽

D. N. Furness

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Cell Function ◽

Structure And Function ◽

Na Channel ◽

Tip Link ◽

And Function ◽

Epithelial Na Channel ◽

Ultrastructural Findings

The mechanosensitive hair cells of the vertebrate acousticolateralis system have an apical bundle of stereocilia, deflections of which control the opening of mechano-electrical transduction channels and thus generate receptor potentials in the cell below. This review describes current theories of hair cell function in the light of recent immunocytochemical and ultrastructural findings; in particular, the location and operation of the transduction channels are considered. The most widely accepted hypothesis of mechanotransduction by hair cells is that fine extracellular links that run between the tips of shorter stereocilia and the sides of taller ones operate the transduction channels. However, the fact that the transduction channels are amiloride sensitive has led to labeling experiments using antibodies to the amiloride-sensitive epithelial Na+ channel from kidney which suggest that the mechanotransduction channels may not be directly associated with the tip links. Instead, they appear to be located near a junctionlike structure at the point of contact between the shorter and taller stereocilia. The implications of these findings for the tip link hypothesis are discussed.

Download Full-text

The effects of Tmc1 Beethoven mutation on mechanotransducer channel function in cochlear hair cells

The Journal of General Physiology ◽

10.1085/jgp.201511458 ◽

2015 ◽

Vol 146 (3) ◽

pp. 233-243 ◽

Cited By ~ 24

Author(s):

Maryline Beurg ◽

Adam C. Goldring ◽

Robert Fettiplace

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Outer Hair Cells ◽

Wild Type ◽

Cochlear Hair Cells ◽

Transmembrane Channel ◽

Adaptive Shift ◽

Electrical Transducer ◽

Protein Isoform ◽

The Relationship

Sound stimuli are converted into electrical signals via gating of mechano-electrical transducer (MT) channels in the hair cell stereociliary bundle. The molecular composition of the MT channel is still not fully established, although transmembrane channel–like protein isoform 1 (TMC1) may be one component. We found that in outer hair cells of Beethoven mice containing a M412K point mutation in TMC1, MT channels had a similar unitary conductance to that of wild-type channels but a reduced selectivity for Ca2+. The Ca2+-dependent adaptation that adjusts the operating range of the channel was also impaired in Beethoven mutants, with reduced shifts in the relationship between MT current and hair bundle displacement for adapting steps or after lowering extracellular Ca2+; these effects may be attributed to the channel’s reduced Ca2+ permeability. Moreover, the density of stereociliary CaATPase pumps for Ca2+ extrusion was decreased in the mutant. The results suggest that a major component of channel adaptation is regulated by changes in intracellular Ca2+. Consistent with this idea, the adaptive shift in the current–displacement relationship when hair bundles were bathed in endolymph-like Ca2+ saline was usually abolished by raising the intracellular Ca2+ concentration.

Download Full-text

Conductance and block of hair-cell mechanotransducer channels in transmembrane channel–like protein mutants

The Journal of General Physiology ◽

10.1085/jgp.201411173 ◽

2014 ◽

Vol 144 (1) ◽

pp. 55-69 ◽

Cited By ~ 49

Author(s):

Maryline Beurg ◽

Kyunghee X. Kim ◽

Robert Fettiplace

Keyword(s):

Hair Cells ◽

Outer Hair Cells ◽

Incomplete Block ◽

Wild Type ◽

Pharmacological Profile ◽

Cochlear Hair Cells ◽

Transmembrane Channel ◽

Protein Mutants ◽

Tip Link ◽

Peptide Toxin

Transmembrane channel–like (TMC) proteins TMC1 and TMC2 are crucial to the function of the mechanotransducer (MT) channel of inner ear hair cells, but their precise function has been controversial. To provide more insight, we characterized single MT channels in cochlear hair cells from wild-type mice and mice with mutations in Tmc1, Tmc2, or both. Channels were recorded in whole-cell mode after tip link destruction with BAPTA or after attenuating the MT current with GsMTx-4, a peptide toxin we found to block the channels with high affinity. In both cases, the MT channels in outer hair cells (OHCs) of wild-type mice displayed a tonotopic gradient in conductance, with channels from the cochlear base having a conductance (110 pS) nearly twice that of those at the apex (62 pS). This gradient was absent, with channels at both cochlear locations having similar small conductances, with two different Tmc1 mutations. The conductance of MT channels in inner hair cells was invariant with cochlear location but, as in OHCs, was reduced in either Tmc1 mutant. The gradient of OHC conductance also disappeared in Tmc1/Tmc2 double mutants, in which a mechanically sensitive current could be activated by anomalous negative displacements of the hair bundle. This “reversed stimulus–polarity” current was seen with two different Tmc1/Tmc2 double mutants, and with Tmc1/Tmc2/Tmc3 triple mutants, and had a pharmacological sensitivity comparable to that of native MT currents for most antagonists, except dihydrostreptomycin, for which the affinity was less, and for curare, which exhibited incomplete block. The existence in the Tmc1/Tmc2 double mutants of MT channels with most properties resembling those of wild-type channels indicates that proteins other than TMCs must be part of the channel pore. We suggest that an external vestibule of the MT channel may partly account for the channel’s large unitary conductance, high Ca2+ permeability, and pharmacological profile, and that this vestibule is disrupted in Tmc mutants.

Download Full-text

Tmc Reliance Is Biased by the Hair Cell Subtype and Position Within the Ear

Frontiers in Cell and Developmental Biology ◽

10.3389/fcell.2020.570486 ◽

2021 ◽

Vol 8 ◽

Author(s):

Shaoyuan Zhu ◽

Zongwei Chen ◽

Haoming Wang ◽

Brian M. McDermott

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Cell Types ◽

Genetic Mutations ◽

Mechanical Stimuli ◽

Vestibular Organ ◽

Short Hair ◽

Transmembrane Channel ◽

Quantitative Measurements ◽

Cell Position

Hair cells are heterogenous, enabling varied roles in sensory systems. An emerging hypothesis is that the transmembrane channel-like (Tmc) proteins of the hair cell’s mechanotransduction apparatus vary within and between organs to permit encoding of different mechanical stimuli. Five anatomical variables that may coincide with different Tmc use by a hair cell within the ear are the containing organ, cell morphology, cell position within an organ, axis of best sensitivity for the cell, and the hair bundle’s orientation within this axis. Here, we test this hypothesis in the organs of the zebrafish ear using a suite of genetic mutations. Transgenesis and quantitative measurements demonstrate two morphologically distinct hair cell types in the central thickness of a vestibular organ, the lateral crista: short and tall. In contrast to what has been observed, we find that tall hair cells that lack Tmc1 generally have substantial reductions in mechanosensitivity. In short hair cells that lack Tmc2 isoforms, mechanotransduction is largely abated. However, hair cell Tmc dependencies are not absolute, and an exceptional class of short hair cell that depends on Tmc1 is present, termed a short hair cell erratic. To further test anatomical variables that may influence Tmc use, we map Tmc1 function in the saccule of mutant larvae that depend just on this Tmc protein to hear. We demonstrate that hair cells that use Tmc1 are found in the posterior region of the saccule, within a single axis of best sensitivity, and hair bundles with opposite orientations retain function. Overall, we determine that Tmc reliance in the ear is dependent on the organ, subtype of hair cell, position within the ear, and axis of best sensitivity.

Download Full-text

Putative pore-forming subunits of the mechano-electrical transduction channel, Tmc1/2b, require Tmie to localize to the site of mechanotransduction in zebrafish sensory hair cells

10.1101/393330 ◽

2018 ◽

Cited By ~ 1

Author(s):

Itallia V. Pacentine ◽

Teresa Nicolson

Keyword(s):

Hair Cell ◽

Inner Ear ◽

Hair Cells ◽

Transmembrane Domain ◽

Cell Activity ◽

Sensory Hair ◽

Transmembrane Channel ◽

Extracellular Region ◽

Normal Site ◽

Sensory Hair Cells

AbstractMutations in transmembrane inner ear (TMIE) cause deafness in humans; previous studies suggest involvement in the mechano-electrical transduction (MET) complex in sensory hair cells, but TMIE’s precise role is unclear. In tmie zebrafish mutants, we observed that GFP-tagged Tmc1 and Tmc2b, which are putative subunits of the MET channel, fail to target to the hair bundle. In contrast, overexpression of Tmie strongly enhances the targeting of Tmc2b-GFP to stereocilia. To identify the motifs of Tmie underlying the regulation of the Tmcs, we systematically deleted or replaced peptide segments. We then assessed localization and functional rescue of each mutated/chimeric form of Tmie in tmie mutants. We determined that the first putative helix was dispensable and identified a novel critical region of Tmie, the extracellular region and transmembrane domain, which mediates both mechanosensitivity and Tmc2b-GFP expression in bundles. Collectively, our results suggest that Tmie’s role in sensory hair cells is to target and stabilize Tmc subunits to the site of MET.Author summaryHair cells mediate hearing and balance through the activity of a pore-forming channel in the cell membrane. The transmembrane inner ear (TMIE) protein is an essential component of the protein complex that gates this so-called mechanotransduction channel. While it is known that loss of TMIE results in deafness, the function of TMIE within the complex is unclear. Using zebrafish as a deafness model, Pacentine and Nicolson demonstrate that Tmie is required for the localization of other essential complex members, the transmembrane channel-like (Tmc) proteins, Tmc1/2b. They then evaluate twelve unique versions of Tmie, each containing mutations to different domains of Tmie. This analysis reveals that some mutations in Tmie cause dysfunctional gating of the channel as demonstrated through reduced hair cell activity, and that these same dysfunctional versions also display reduced Tmc expression at the normal site of the channel. These findings link hair cell activity with the levels of Tmc in the bundle, reinforcing the currently-debated notion that the Tmcs are the pore-forming subunits of the mechanotransduction channel. The authors conclude that Tmie, through distinct regions, is involved in both trafficking and stabilizing the Tmcs at the site of mechanotransduction.

Download Full-text

TRPV5, TRPV6, TRPM6, and TRPM7 do not contribute to hair-cell mechanotransduction

10.1101/204172 ◽

2017 ◽

Cited By ~ 1

Author(s):

Clive P. Morgan ◽

Hongyu Zhao ◽

Meredith LeMasurier ◽

Wei Xiong ◽

Bifeng Pan ◽

...

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Auditory Function ◽

Cochlear Hair Cells ◽

Cochlear Hair Cell ◽

Cysteine Substitution ◽

Tip Link ◽

Transient Receptor ◽

Receptor Channel

AbstractThe hair-cell mechanotransduction channel remains unidentified. We tested whether four transient receptor channel (TRP) family members, TRPV5, TRPV6, TRPM6, and TRPM7, participated in transduction. Using cysteine-substitution mouse knock-ins and methanethiosulfonate reagents selective for those alleles, we found that inhibition of TRPV5 or TRPV6 had no effect on transduction in mouse cochlear hair cells. TRPM6 and TRPM7 each interacted with the tip-link component PCDH15 in cultured eukaryotic cells, which suggested they could participate in transduction. Cochlear hair cell transduction was insensitive to shRNA knockdown ofTrpm6orTrpm7, however, and was not affected by manipulations of Mg2+, which normally perturbs TRPM6 and TRPM7. To definitively examine the role of these two channels in transduction, we showed that deletion of either or both of their genes selectively in hair cells had no effect on auditory function. We suggest that TRPV5, TRPV6, TRPM6, and TRPM7 are unlikely to be the pore-forming subunit of the hair-cell transduction channel.

Download Full-text