Your search keyword '"TMC1"' showing total 22 results

1. TMC function, dysfunction, and restoration in mouse vestibular organs.

Author

Ratzan, Evan M., Lee, John, Madison, Margot A., Hong Zhu, Wu Zhou, Géléoc, Gwenaëlle S. G., and Holt, Jeffrey R.

Subjects

FLUORESCENCE in situ hybridization, HAIR cells, INNER ear, POLYMERASE chain reaction, EVOKED potentials (Electrophysiology)

Abstract

Tmc1 and Tmc2 are essential pore-forming subunits of mechanosensory transduction channels localized to the tips of stereovilli in auditory and vestibular hair cells of the inner ear. To investigate expression and function of Tmc1 and Tmc2 in vestibular organs, we used quantitative polymerase chain reaction (qPCR), fluorescence in situ hybridization - hairpin chain reaction (FISH-HCR), immunostaining, FM1-43 uptake and we measured vestibular evoked potentials (VsEPs) and vestibular ocular reflexes (VORs). We found that Tmc1 and Tmc2 showed dynamic developmental changes, differences in regional expression patterns, and overall expression levels which differed between the utricle and saccule. These underlying changes contributed to unanticipated phenotypic loss of VsEPs and VORs in Tmc1 KO mice. In contrast, Tmc2 KO mice retained VsEPs despite the loss of the calcium buffering protein calretinin, a characteristic biomarker of mature striolar calyx-only afferents. Lastly, we found that neonatal Tmc1 gene replacement therapy is sufficient to restore VsEP in Tmc1 KO mice for up to six months post-injection. [ABSTRACT FROM AUTHOR]

Published

2024

2. Genetic correction of induced pluripotent stem cells from a DFNA36 patient results in morphologic and functional recovery of derived hair cell-like cells

Author

Yi Luo, Kaiwen Wu, Xiaolong Zhang, Hongyang Wang, and Qiuju Wang

Subjects

Induced pluripotent stem cells, TMC1, Hair cells, Differentiation, Whole-cell patch-clamp, Medicine (General), R5-920, Biochemistry, QD415-436

Abstract

Abstract Background TMC1 is one of the most common deafness genes causing DFNA36. Patient-derived human induced pluripotent stem cells (iPSCs) provide an opportunity to modelling diseases. TMC1 p.M418K mutation in human is orthologous to Beethoven mice. Here, we investigated the differentiation, morphology and electrophysiological properties of hair cell-like cells (HC-like cells) derived from DFNA36 patient. Methods Inner ear HC-like cells were induced from iPSCs derived from DFNA36 (TMC1 p.M418K) patient (M+/−), normal control (M+/+) and genetic corrected iPSCs (M+/C). Immunofluorescence, scanning electron microscopy and whole-cell patch-clamp were used to study the mechanism and influence of TMC1 p.M418K mutation. Results In this study we successfully generated HC-like cells from iPSCs with three different genotypes. HC-like cells from M+/− showed defected morphology of microvilli and physiological properties compared to M+/+. HC-like cells from M+/C showed recovery in morphology of microvilli and physiological properties. Conclusions Our results indicate that TMC1 p.M418K mutation didn’t influence inner ear hair cell differentiation but the morphology of microvilli and electrophysiological properties and gene correction induced recovery. CRISPR/Cas9 gene therapy is feasible in human patient with TMC1 p.M418K mutation.

Published

2024

3. LHFPL5 is a key element in force transmission from the tip link to the hair cell mechanotransducer channel.

Author

Beurg, Maryline, Schwalbach, Evan Travis, and Fettiplace, Robert

Subjects

*HAIR cells, *MEMBRANE proteins, *ION channels, *KNOCKOUT mice, *GENETIC transduction

Abstract

During auditory transduction, sound-evoked vibrations of the hair cell stereociliary bundles open mechanotransducer (MET) ion channels via tip links extending from one stereocilium to its neighbor. How tension in the tip link is delivered to the channel is not fully understood. The MET channel comprises a pore-forming subunit, transmembrane channel-like protein (TMC1 or TMC2), aided by several accessory proteins, including LHFPL5 (lipoma HMGIC fusion partner-like 5). We investigated the role of LHFPL5 in transduction by comparing MET channel activation in outer hair cells of Lhfpl5-/- knockout mice with those in Lhfpl5+/- heterozygotes. The 10 to 90 percent working range of transduction in Tmc1+/+; Lhfpl5+/- was 52 nm, from which the single-channel gating force, Z, was evaluated as 0.34 pN. However, in Tmc1+/+; Lhfpl5-/- mice, the working range increased to 123 nm and Z more than halved to 0.13 pN, indicating reduced sensitivity. Tip link tension is thought to activate the channel via a gating spring, whose stiffness is inferred from the stiffness change on tip link destruction. The gating stiffness was ~40 percent of the total bundle stiffness in wild type but was virtually abolished in Lhfpl5-/-, implicating LHFPL5 as a principal component of the gating spring. The mutation Tmc1 p.D569N reduced the LHFPL5 immunolabeling in the stereocilia and like Lhfpl5-/- doubled the MET working range, but other deafness mutations had no effect on the dynamic range. We conclude that tip-link tension is transmitted to the channel primarily via LHFPL5; residual activation without LHFPL5 may occur by direct interaction between PCDH15 and TMC1. [ABSTRACT FROM AUTHOR]

Published

2024

4. Genetic correction of induced pluripotent stem cells from a DFNA36 patient results in morphologic and functional recovery of derived hair cell-like cells.

Author

Luo, Yi, Wu, Kaiwen, Zhang, Xiaolong, Wang, Hongyang, and Wang, Qiuju

Subjects

*INDUCED pluripotent stem cells, *HAIR cells, *PLURIPOTENT stem cells, *CELL morphology, *INNER ear

Abstract

Background: TMC1 is one of the most common deafness genes causing DFNA36. Patient-derived human induced pluripotent stem cells (iPSCs) provide an opportunity to modelling diseases. TMC1 p.M418K mutation in human is orthologous to Beethoven mice. Here, we investigated the differentiation, morphology and electrophysiological properties of hair cell-like cells (HC-like cells) derived from DFNA36 patient. Methods: Inner ear HC-like cells were induced from iPSCs derived from DFNA36 (TMC1 p.M418K) patient (M+/−), normal control (M+/+) and genetic corrected iPSCs (M+/C). Immunofluorescence, scanning electron microscopy and whole-cell patch-clamp were used to study the mechanism and influence of TMC1 p.M418K mutation. Results: In this study we successfully generated HC-like cells from iPSCs with three different genotypes. HC-like cells from M+/− showed defected morphology of microvilli and physiological properties compared to M+/+. HC-like cells from M+/C showed recovery in morphology of microvilli and physiological properties. Conclusions: Our results indicate that TMC1 p.M418K mutation didn't influence inner ear hair cell differentiation but the morphology of microvilli and electrophysiological properties and gene correction induced recovery. CRISPR/Cas9 gene therapy is feasible in human patient with TMC1 p.M418K mutation. [ABSTRACT FROM AUTHOR]

Published

2024

5. Differential expression of mechanotransduction complex genes in auditory/vestibular hair cells in zebrafish.

Author

Smith, Eliot T., Peng Sun, Shengyang Kevin Yu, Raible, David W., and Nicolson, Teresa

Subjects

HAIR cells, OLFACTORY receptors, MECHANOTRANSDUCTION (Cytology), G protein coupled receptors, SENSORY receptors, INNER ear

Abstract

Ciliated sensory cells such as photo- and olfactory receptors employ multiple types of opsins or hundreds of unique olfactory G-protein coupled receptors to respond to various wavelengths of light or odorants. With respect to hearing and balance, the mechanotransduction machinery involves fewer variants; however, emerging evidence suggests that specialization occurs at the molecular level. To address how the mechanotransduction complex varies in the inner ear, we characterized the expression of paralogous genes that encode components required for mechanotransduction in zebrafish hair cells using RNA-FISH and bioinformatic analysis. Our data indicate striking zonal differences in the expression of two components of the mechanotransduction complex which are known to physically interact, the transmembrane channel-like 1 and 2 (tmc1/2) family members and the calcium and integrin binding 2 and 3 (cib2/3) paralogues. tmc1, tmc2b, and cib3 are largely expressed in peripheral or extrastriolar hair cells, whereas tmc2a and cib2 are enriched in central or striolar hair cells. In addition, a gene implicated in deaf-blindness, ush1c, is highly enriched in a subset of extrastriolar hair cells. These results indicate that specific combinations of these components may optimize responses to mechanical stimuli in subtypes of sensory receptors within the inner ear. [ABSTRACT FROM AUTHOR]

Published

2023

6. The conductance and organization of the TMC1-containing mechanotransducer channel complex in auditory hair cells.

Author

Fettiplace, Robert, Furness, David N., and Beurg, Maryline

Subjects

*HAIR cells, *PERMEABILITY measurement, *KNOCKOUT mice, *MISSENSE mutation, *MEMBRANE proteins

Abstract

Transmembrane channel-like protein 1 (TMC1) is thought to form the ion-conducting pore of the mechanoelectrical transducer (MET) channel in auditory hair cells. Using single-channel analysis and ionic permeability measurements, we characterized six missense mutations in the purported pore region of mouse TMC1. All mutations reduced the Ca2+ permeability of the MET channel, triggering hair cell apoptosis and deafness. In addition, Tmc1 p.E520Q and Tmc1 p.D528N reduced channel conductance, whereas Tmc1 p.W554L and Tmc1 p.D569N lowered channel expression without affecting the conductance. Tmc1 p.M412K and Tmc1 p.T416K reduced only the Ca2+ permeability. The consequences of these mutations endorse TMC1 as the pore of the MET channel. The accessory subunits, LHFPL5 and TMIE, are thought to be involved in targeting TMC1 to the tips of the stereocilia. We found sufficient expression of TMC1 in outer hair cells of Lhfpl5 and Tmie knockout mice to determine the properties of the channels, which could still be gated by hair bundle displacement. Single-channel conductance was unaffected in Lhfpl5−/− but was reduced in Tmie−/−, implying TMIE very likely contributes to the pore. Both the working range and half-saturation point of the residual MET current in Lhfpl5−/− were substantially increased, suggesting that LHFPL5 is part of the mechanical coupling between the tip-link and the MET channel. Based on counts of numbers of stereocilia per bundle, we estimate that each PCDH15 and LHFPL5 monomer may contact two channels irrespective of location. [ABSTRACT FROM AUTHOR]

Published

2022

7. Optimized AAV Vectors for TMC1 Gene Therapy in a Humanized Mouse Model of DFNB7/11.

Author

Marcovich, Irina, Baer, Nicholas K., Shubina-Oleinik, Olga, Eclov, Rachel, Beard, Clayton W., and Holt, Jeffrey R.

Subjects

*HAIR cells, *GENE therapy, *EAR, *INNER ear, *LABORATORY mice, *ANIMAL disease models, *OTOACOUSTIC emissions, *VIRAL DNA

Abstract

Gene therapy for genetic hearing loss is an emerging therapeutic modality for hearing restoration. However, the approach has not yet been translated into clinical application. To further develop inner-ear gene therapy, we engineered a novel mouse model bearing a human mutation in the transmembrane channel-1 gene (Tmc1) and characterized the auditory phenotype of the mice. TMC1 forms the mechanosensory transduction channel in mice and humans and is necessary for auditory function. We found that mice harboring the equivalent of the human p.N199I mutation (p.N193I) had profound congenital hearing loss due to loss of hair cell sensory transduction. Next, we optimized and screened viral payloads packaged into AAV9-PHP.B capsids. The vectors were injected into the inner ears of Tmc1Δ/Δ mice and the new humanized Tmc1-p.N193I mouse model. Auditory brainstem responses (ABRs), distortion product otoacoustic emissions (DPOAEs), cell survival, and biodistribution were evaluated in the injected mice. We found broad-spectrum, durable recovery of auditory function in Tmc1-p.N193I mice injected with AAV9-PHP.B-CB6-hTMC1-WPRE. ABR and DPOAE thresholds were equivalent to those of wild-type mice across the entire frequency range. Biodistribution analysis revealed viral DNA/RNA in the contralateral ear, brain, and liver but no overt toxicity. We conclude that the AAV9-PHP.B-CB6-hTMC1-WPRE construct may be suitable for further development as a gene therapy reagent for treatment of humans with genetic hearing loss due to recessive TMC1 mutations. [ABSTRACT FROM AUTHOR]

Published

2022

8. Putting the Pieces Together: the Hair Cell Transduction Complex.

Author

Holt, Jeffrey R., Tobin, Mélanie, Elferich, Johannes, Gouaux, Eric, Ballesteros, Angela, Yan, Zhiqiang, Ahmed, Zubair M., and Nicolson, Teresa

Subjects

HAIR cells, GENETIC transduction, INNER ear, PROTEIN-protein interactions, SCIENTIFIC discoveries

Abstract

Identification of the components of the mechanosensory transduction complex in hair cells has been a major research interest for many auditory and vestibular scientists and has attracted attention from outside the field. The past two decades have witnessed a number of significant advances with emergence of compelling evidence implicating at least a dozen distinct molecular components of the transduction machinery. Yet, how the pieces of this ensemble fit together and function in harmony to enable the senses of hearing and balance has not been clarified. The goal of this review is to summarize a 2021 symposium presented at the annual mid-winter meeting of the Association for Research in Otolaryngology. The symposium brought together the latest insights from within and beyond the field to examine individual components of the transduction complex and how these elements interact at molecular, structural, and biophysical levels to gate mechanosensitive channels and initiate sensory transduction in the inner ear. The review includes a brief historical background to set the stage for topics to follow that focus on structure, properties, and interactions of proteins such as CDH23, PCDH15, LHFPL5, TMIE, TMC1/2, and CIB2/3. We aim to present the diversity of ideas in this field and highlight emerging theories and concepts. This review will not only provide readers with a deeper appreciation of the components of the transduction apparatus and how they function together, but also bring to light areas of broad agreement, areas of scientific controversy, and opportunities for future scientific discovery. [ABSTRACT FROM AUTHOR]

Published

2021

9. Mechanisms in cochlear hair cell mechano-electrical transduction for acquisition of sound frequency and intensity.

Author

Liu, Shuang, Wang, Shufeng, Zou, Linzhi, and Xiong, Wei

Subjects

*HAIR cells, *AUDIO frequency, *GENETIC transduction, *AUDITORY pathways, *CELL physiology, *COCHLEA physiology, *INNER ear, *COCHLEAR nucleus

Abstract

Sound signals are acquired and digitized in the cochlea by the hair cells that further transmit the coded information to the central auditory pathways. Any defect in hair cell function may induce problems in the auditory system and hearing-based brain function. In the past 2 decades, our understanding of auditory transduction has been substantially deepened because of advances in molecular, structural, and functional studies. Results from these experiments can be perfectly embedded in the previously established profile from anatomical, histological, genetic, and biophysical research. This review aims to summarize the progress on the molecular and cellular mechanisms of the mechano-electrical transduction (MET) channel in the cochlear hair cells, which is involved in the acquisition of sound frequency and intensity—the two major parameters of an acoustic cue. We also discuss recent studies on TMC1, the molecule likely to form the MET channel pore. [ABSTRACT FROM AUTHOR]

Published

2021

10. New Tmc1 Deafness Mutations Impact Mechanotransduction in Auditory Hair Cells.

Author

Beurg, Maryline, Schimmenti, Lisa A., Koleilat, Alaa, Amr, Sami S., Oza, Andrea, Barlow, Amanda J., Ballesteros, Angela, and Fettiplace, Robert

Subjects

*HAIR cells, *AUDITORY neuropathy, *MECHANOTRANSDUCTION (Cytology), *MEMBRANE proteins, *ALPHA rhythm, *MUCOCILIARY system

Abstract

Transmembrane channel-like protein isoform 1 (TMC1) is a major component of the mechano-electrical transducer (MET) channel in cochlear hair cells and is subject to numerous mutations causing deafness. We report a new dominant human deafness mutation, TMC1 p.T422K, and have characterized the homologous mouse mutant, Tmc1 p.T416K, which caused deafness and outer hair cell (OHC) loss by the fourth postnatal week. MET channels showed decreased Ca2+ permeability and resting open probability, but no change in single-channel conductance or expression. Three adjacent deafness mutations are TMC1 p.L416R, p.G417R, and p.M418K, the last homologous to the mouse Beethoven that exhibits similar channel effects. All substitute a positive for a neutral residue, which could produce charge screening in the channel pore or influence binding of an accessory subunit. Channel properties were compared in mice of both sexes between dominant (Tmc1 p.T416K, Tmc1 p.D569N) and recessive (Tmc1 p.W554L, Tmc1 p.D528N) mutations of residues near the putative pore of the channel. Tmc1 p.W554L and p.D569N exhibit reduced maximum current with no effect on single-channel conductance, implying a smaller number of channels transported to the stereociliary tips; this may stem from impaired TMC1 binding to LHFPL5. Tmc1 p.D528N, located in the pore's narrowest region, uniquely caused large reductions in MET channel conductance and block by dihydrostreptomycin (DHS). For Tmc1 p.T416K and Tmc1 p.D528N, transduction loss occurred between P15 and P20. We propose two mechanisms linking channel mutations and deafness: decreased Ca2+ permeability, common to all mutants, and decreased resting open probability in low Ca2+, confined to dominant mutations. [ABSTRACT FROM AUTHOR]

Published

2021

11. The Mechanosensory Transduction Machinery in Inner Ear Hair Cells.

Author

Zheng, Wang and Holt, Jeffrey R.

Abstract

Sound-induced mechanical stimuli are detected by elaborate mechanosensory transduction (MT) machinery in highly specialized hair cells of the inner ear. Genetic studies of inherited deafness in the past decades have uncovered several molecular constituents of the MT complex, and intense debate has surrounded the molecular identity of the pore-forming subunits. How the MT components function in concert in response to physical stimulation is not fully understood. In this review, we summarize and discuss multiple lines of evidence supporting the hypothesis that transmembrane channel-like 1 is a long-sought MT channel subunit. We also review specific roles of other components of the MT complex, including protocadherin 15, cadherin 23, lipoma HMGIC fusion partner-like 5, transmembrane inner ear, calcium and integrin-binding family member 2, and ankyrins. Based on these recent advances, we propose a unifying theory of hair cell MT that may reconcile most of the functional discoveries obtained to date. Finally, we discuss key questions that need to be addressed for a comprehensive understanding of hair cell MT at molecular and atomic levels. [ABSTRACT FROM AUTHOR]

Published

2021

12. Deafness mutation D572N of TMC1 destabilizes TMC1 expression by disrupting LHFPL5 binding.

Author

Xiaojie Yu, Qirui Zhao, Xiaofen Li, Yixuan Chen, Ye Tian, Shuang Liu, Wei Xiong, and Pingbo Huang

Subjects

*HAIR cells, *DEAFNESS, *MEMBRANE proteins

Abstract

Transmembrane channel-like protein 1 (TMC1) and lipoma HMGIC fusion partner-like 5 (LHFPL5) are recognized as two critical components of the mechanotransduction complex in inner-ear hair cells. However, the physical and functional interactions of TMC1 and LHFPL5 remain largely unexplored. We examined the interaction between TMC1 and LHFPL5 by using multiple approaches, including our recently developed ultrasensitive microbead-based single-molecule pulldown (SiMPull) assay. We demonstrate that LHFPL5 physically interacts with and stabilizes TMC1 in both heterologous expression systems and in the soma and hair bundle of hair cells. Moreover, the semidominant deafness mutation D572N in human TMC1 (D569N in mouse TMC1) severely disrupted LHFPL5 binding and destabilized TMC1 expression. Thus, our findings reveal previously unrecognized physical and functional interactions of TMC1 and LHFPL5 and provide insights into the molecular mechanism by which the D572N mutation causes deafness. Notably, these findings identify a missing link in the currently known physical organization of the mechanotransduction macromolecular complex. Furthermore, this study has demonstrated the power of the microbead-based SiMPull assay for biochemical investigation of rare cells such as hair cells. [ABSTRACT FROM AUTHOR]

Published

2020

13. Systemic Fluorescent Gentamicin Enters Neonatal Mouse Hair Cells Predominantly Through Sensory Mechanoelectrical Transduction Channels.

Author

Makabe, Ayane, Kawashima, Yoshiyuki, Sakamaki, Yuriko, Maruyama, Ayako, Fujikawa, Taro, Ito, Taku, Kurima, Kiyoto, Griffith, Andrew J., and Tsutsumi, Takeshi

Subjects

HAIR cells, GENTAMICIN, X chromosome, GENETIC transduction, TRANSMISSION electron microscopy, ANIMAL populations, RESEARCH, HETEROCYCLIC compounds, ANIMAL experimentation, RESEARCH methodology, MEDICAL cooperation, EVALUATION research, CELLULAR signal transduction, COMPARATIVE studies, RESEARCH funding, MEMBRANE proteins, ANTIBIOTICS, MICE

Abstract

Systemically administered aminoglycoside antibiotics can enter inner ear hair cells and trigger apoptosis. However, the in vivo route(s) by which aminoglycoside antibiotics enter hair cells remains controversial. Aminoglycosides can enter mouse hair cells by endocytosis or by permeation through transmembrane ion channels such as sensory mechanoelectrical transduction (MET) channels, transient receptor potential (TRP) channels, P2X channels, Piezo2-containing ion channels, or a combination of these routes. Transmembrane channel-like 1 (TMC1) and TMC2 are essential for sensory MET and appear to be the pore-forming components of sensory MET channels. The present study tested the hypothesis that systemic fluorescent gentamicin enters mouse hair cells predominantly through sensory MET channels. We employed Tmc1Δ, Tmc2Δ, and Tmc1::mCherry mice. In Tmc1::mCherry mice, the transgene was integrated on the X chromosome, resulting in mosaic expression of TMC1-mCherry in the hair cells of female heterozygous mice. After systemic administration of gentamicin-conjugated Texas Red (GTTR) into Tmc1Δ;Tmc2Δ mice and wild-type mice at postnatal day 4 (P4), robust GTTR fluorescence was detected in wild-type hair cells, whereas little or no GTTR fluorescence was detected in Tmc1Δ;Tmc2Δ hair cells. When GTTR was injected into developing mice at P0, P2, P4, or P6, the GTTR fluorescent intensity gradually increased from P0 to P4 in wild-type hair cells, whereas the intensity was stably low from P0 through P6 in Tmc1Δ;Tmc2Δ hair cells. The increase in the GTTR intensity coincided with the spatio-temporal onset of sensory MET in wild-type hair cells. In Tmc1::mCherry cochleae, only hair cells that showed a significant uptake of systemic GTTR took up FM1-43. Transmission electron microscopy could detect no disruption of normal endocytosis at the apical surface of Tmc1Δ;Tmc2Δ hair cells in vitro. These results provide substantial novel evidence that in vivo gentamicin enters neonatal mouse hair cells predominantly through sensory MET channels and not via endocytosis. [ABSTRACT FROM AUTHOR]

Published

2020

14. The lhfpl5 Ohnologs lhfpl5a and lhfpl 5b Are Required for Mechanotransduction in Distinct Populations of Sensory Hair Cells in Zebrafish.

Author

Erickson, Timothy, Pacentine, Itallia V., Venuto, Alexandra, Clemens, Rachel, and Nicolson, Teresa

Subjects

HAIR cells, BRACHYDANIO, MOLECULAR motor proteins, IMMOBILIZED proteins, CELL populations

Abstract

Hair cells sense and transmit auditory, vestibular, and hydrodynamic information by converting mechanical stimuli into electrical signals. This process of mechano-electrical transduction (MET) requires a mechanically gated channel localized in the apical stereocilia of hair cells. In mice, lipoma HMGIC fusion partner-like 5 (LHFPL5) acts as an auxiliary subunit of the MET channel whose primary role is to correctly localize PCDH15 and TMC1 to the mechanotransduction complex. Zebrafish have two lhfpl5 genes (lhfpl5a and lhfpl5b), but their individual contributions to MET channel assembly and function have not been analyzed. Here we show that the zebrafish lhfpl5 genes are expressed in discrete populations of hair cells: lhfpl5a expression is restricted to auditory and vestibular hair cells in the inner ear, while lhfpl5b expression is specific to hair cells of the lateral line organ. Consequently, lhfpl5a mutants exhibit defects in auditory and vestibular function, while disruption of lhfpl5b affects hair cells only in the lateral line neuromasts. In contrast to previous reports in mice, localization of Tmc1 does not depend upon Lhfpl5 function in either the inner ear or lateral line organ. In both lhfpl5a and lhfpl5b mutants, GFP-tagged Tmc1 and Tmc2b proteins still localize to the stereocilia of hair cells. Using a stably integrated GFP-Lhfpl5a transgene, we show that the tip link cadherins Pcdh15a and Cdh23, along with the Myo7aa motor protein, are required for correct Lhfpl5a localization at the tips of stereocilia. Our work corroborates the evolutionarily conserved co-dependence between Lhfpl5 and Pcdh15, but also reveals novel requirements for Cdh23 and Myo7aa to correctly localize Lhfpl5a. In addition, our data suggest that targeting of Tmc1 and Tmc2b proteins to stereocilia in zebrafish hair cells occurs independently of Lhfpl5 proteins. [ABSTRACT FROM AUTHOR]

Published

2020

15. TMC1 is an essential component of a leak channel that modulates tonotopy and excitability of auditory hair cells in mice

Author

Shuang Liu, Shufeng Wang, Linzhi Zou, Jie Li, Chenmeng Song, Jiaofeng Chen, Qun Hu, Lian Liu, Pingbo Huang, and Wei Xiong

Subjects

TMC1, mechanotransduction, leak conductance, membrane channels, tonotopy, hair cells, Medicine, Science, Biology (General), QH301-705.5

Abstract

Hearing sensation relies on the mechano-electrical transducer (MET) channel of cochlear hair cells, in which transmembrane channel-like 1 (TMC1) and transmembrane channel-like 2 (TMC2) have been proposed to be the pore-forming subunits in mammals. TMCs were also found to regulate biological processes other than MET in invertebrates, ranging from sensations to motor function. However, whether TMCs have a non-MET role remains elusive in mammals. Here, we report that in mouse hair cells, TMC1, but not TMC2, provides a background leak conductance, with properties distinct from those of the MET channels. By cysteine substitutions in TMC1, we characterized four amino acids that are required for the leak conductance. The leak conductance is graded in a frequency-dependent manner along the length of the cochlea and is indispensable for action potential firing. Taken together, our results show that TMC1 confers a background leak conductance in cochlear hair cells, which may be critical for the acquisition of sound-frequency and -intensity.

Published

2019

16. Mechanically Gated Ion Channels in Mammalian Hair Cells.

Author

Qiu, Xufeng and Müller, Ulrich

Subjects

HAIR cells, ION channels, INNER ear, SOUND waves, CELLULAR signal transduction, MEMBRANE proteins

Abstract

Hair cells in the inner ear convert mechanical stimuli provided by sound waves and head movements into electrical signal. Several mechanically evoked ionic currents with different properties have been recorded in hair cells. The search for the proteins that form the underlying ion channels is still in progress. The mechanoelectrical transduction (MET) channel near the tips of stereociliary in hair cells, which is responsible for sensory transduction, has been studied most extensively. Several components of the sensory mechanotransduction machinery in stereocilia have been identified, including the multi-transmembrane proteins tetraspan membrane protein in hair cell stereocilia (TMHS)/LHFPL5, transmembrane inner ear (TMIE) and transmembrane channel-like proteins 1 and 2 (TMC1/2). However, there remains considerable uncertainty regarding the molecules that form the channel pore. In addition to the sensory MET channel, hair cells express the mechanically gated ion channel PIEZO2, which is localized near the base of stereocilia and not essential for sensory transduction. The function of PIEZO2 in hair cells is not entirely clear but it might have a role in damage sensing and repair processes. Additional stretch-activated channels of unknown molecular identity and function have been found to localize at the basolateral membrane of hair cells. Here, we review current knowledge regarding the different mechanically gated ion channels in hair cells and discuss open questions concerning their molecular composition and function. [ABSTRACT FROM AUTHOR]

Published

2018

17. Molecular Identity of the Mechanotransduction Channel in Hair Cells: Not Quiet There Yet.

Author

Zizhen Wu and Müller, Ulrich

Subjects

*HAIR cells, *COCHLEA, *MECHANORECEPTORS, *MECHANOTRANSDUCTION (Cytology), *CELLULAR signal transduction

Abstract

Hair cells in the mammalian cochlea are specialized mechanosensory cells that convert sound-induced vibrations into electrochemical signals. The molecular composition of the mechanotransduction channel underlying auditory perception has been difficult to define. The study of genes that are linked to inherited forms of deafness has recently provided tantalizing clues. Current findings indicate that the mechanotransduction channel in hair cells is a complex molecular machine. Four different proteins (TMHS/LHFPL5, TMIE, TMC1, and TMC2) have so far been linked to the transduction channel, but which proteins contribute to the channel pore still needs to be determined. Current evidence also suggests that the channel complex may contain additional, yet to be identified components. [ABSTRACT FROM AUTHOR]

Published

2016

18. The tip-link molecular complex of the auditory mechano-electrical transduction machinery.

Author

Pepermans, Elise and Petit, Christine

Subjects

*AUDITORY pathways, *MECHANOTRANSDUCTION (Cytology), *CADHERINS, *HAIR cells, *CELLULAR signal transduction

Abstract

Sound waves are converted into electrical signals by a process of mechano-electrical transduction (MET), which takes place in the hair bundle of cochlear hair cells. In response to the mechanical stimulus of the hair bundle, the tip-links, key components of the MET machinery, are tensioned and the MET channels open, which results in the generation of the cell receptor potential. Tip-links are composed of cadherin-23 (Cdh23) and protocadherin-15 (Pcdh15), both non-conventional cadherins, that form the upper and the lower part of these links, respectively. Here, we review the various Pcdh15 isoforms present in the organ of Corti, their localization in the auditory hair bundles, their involvement in the molecular complex forming the tip-link, and their interactions with transmembrane molecules that are components of the lower MET machinery. This article is part of a Special Issue entitled < IEB Kyoto > . [ABSTRACT FROM AUTHOR]

Published

2015

19. Mutations of TMC1 cause deafness by disrupting mechanoelectrical transduction.

Author

Nakanishi, Hiroshi, Kurima, Kiyoto, Kawashima, Yoshiyuki, and Griffith, Andrew J.

Subjects

*GENETIC mutation, *BIOLOGICAL membranes, *DEAFNESS, *MAGNETIC transducers, *HAIR cells, *CELLULAR signal transduction, *SENSORY neurons

Abstract

Objective Mutations of transmembrane channel-like 1 gene ( TMC1 ) can cause dominant (DFNA36) or recessive (DFNB7/B11) deafness. In this article, we describe the characteristics of DFNA36 and DFNB7/B11 deafness, the features of the Tmc1 mutant mouse strains, and recent advances in our understanding of TMC1 function. Methods Publications related to TMC1 , DFNA36, or DFNB7/B11 were identified through PubMed. Results All affected DFNA36 subjects showed post-lingual, progressive, sensorineural hearing loss (HL), initially affecting high frequencies. In contrast, almost all affected DFNB7/B11 subjects demonstrated congenital or prelingual severe to profound sensorineural HL. The mouse Tmc1 gene also has dominant and recessive mutant alleles that cause HL in mutant strains, including Beethoven , deafness , and Tmc1 knockout mice. These mutant mice have been instrumental for revealing that Tmc1 and its closely related paralog Tmc2 are expressed in cochlear and vestibular hair cells, and are required for hair cell mechanoelectrical transduction (MET). Recent studies suggest that TMC1 and TMC2 may be components of the long-sought hair cell MET channel. Conclusion TMC1 mutations disrupt hair cell MET. [ABSTRACT FROM AUTHOR]

Published

2014

20. TMC1 is an essential component of a leak channel that modulates tonotopy and excitability of auditory hair cells in mice

Author

Chenmeng Song, Shuang Liu, Jiaofeng Chen, Linzhi Zou, Shufeng Wang, Qun Hu, Lian Liu, Wei Xiong, Pingbo Huang, and Jie Li

Subjects

0301 basic medicine, Leak, hair cells, Mouse, QH301-705.5, Science, leak conductance, Mechanotransduction, Cellular, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Mice, 0302 clinical medicine, Sensation, Hair Cells, Auditory, otorhinolaryngologic diseases, Animals, Cysteine, Biology (General), Mechanotransduction, tonotopy, Cochlea, mechanotransduction, General Immunology and Microbiology, Chemistry, General Neuroscience, Conductance, Membrane Proteins, TMC1, General Medicine, Cell Biology, Transmembrane protein, Cell biology, membrane channels, 030104 developmental biology, Medicine, Membrane channel, Tonotopy, 030217 neurology & neurosurgery, Research Article, Neuroscience

Abstract

Hearing sensation relies on the mechano-electrical transducer (MET) channel of cochlear hair cells, in which transmembrane channel-like 1 (TMC1) and transmembrane channel-like 2 (TMC2) have been proposed to be the pore-forming subunits in mammals. TMCs were also found to regulate biological processes other than MET in invertebrates, ranging from sensations to motor function. However, whether TMCs have a non-MET role remains elusive in mammals. Here, we report that in mouse hair cells, TMC1, but not TMC2, provides a background leak conductance, with properties distinct from those of the MET channels. By cysteine substitutions in TMC1, we characterized four amino acids that are required for the leak conductance. The leak conductance is graded in a frequency-dependent manner along the length of the cochlea and is indispensable for action potential firing. Taken together, our results show that TMC1 confers a background leak conductance in cochlear hair cells, which may be critical for the acquisition of sound-frequency and -intensity.

Published

2019

21. A Mechanosensitive Channel, Mouse Transmembrane Channel-Like Protein 1 (mTMC1) Is Translated from a Splice Variant mTmc1ex1 but Not from the Other Variant mTmc1ex2.

Author

Yamaguchi, Soichiro, Hamamura, Maho, and Otsuguro, Ken-ichi

Subjects

*MEMBRANE proteins, *SITE-specific mutagenesis, *SOUND waves, *HAIR cells, *MICE

Abstract

Mechanical stimuli caused by sound waves are detected by hair cells in the cochlea through the opening of mechanoelectrical transduction (MET) channels. Transmembrane channel-like protein 1 (TMC1) has been revealed to be the pore-forming component of the MET channel. The two splice variants for mouse Tmc1 (mTmc1ex1 and mTmc1ex2) were reported to be expressed in the cochlea of infant mice, though only the sequence of mTmc1ex2 had been deposited in GenBank. However, due to the presence of an upstream open reading frame (uORF) and the absence of a typical Kozak sequence in mTmc1ex2, we questioned whether mTMC1 was translated from mTmc1ex2. Therefore, in this study, we evaluated which splice variant was protein-coding mRNA. Firstly, the results of RT-PCR and cDNA cloning of mTmc1 using mRNA isolated from the cochlea of five-week-old mice suggested that more Tmc1ex1 were expressed than mTmc1ex2. Secondly, mTMC1 was translated from mTmc1ex1 but not from mTmc1ex2 in a heterologous expression system. Finally, analyses using site-directed mutagenesis revealed that the uORF and the weak Kozak sequence in mTmc1ex2 prevented the translation of mTMC1 from mTmc1ex2. These results suggest that mTmc1ex1 plays a main role in the expression of mTMC1 in the mouse cochlea, and therefore, mTmc1ex1 should be the mRNA for mTMC1 hereafter. [ABSTRACT FROM AUTHOR]

Published

2020

22. TMC1 and TMC2 Proteins Are Pore-Forming Subunits of Mechanosensitive Ion Channels.

Author

Jia, Yanyan, Zhao, Yimeng, Kusakizako, Tsukasa, Wang, Yao, Pan, Chengfang, Zhang, Yuwei, Nureki, Osamu, Hattori, Motoyuki, and Yan, Zhiqiang

Subjects

*ION channels, *POLYMERSOMES, *GREEN turtle, *HAIR cells, *PROTEINS

Abstract

Transmembrane channel-like (TMC) 1 and 2 are required for the mechanotransduction of mouse inner ear hair cells and localize to the site of mechanotransduction in mouse hair cell stereocilia. However, it remains unclear whether TMC1 and TMC2 are indeed ion channels and whether they can sense mechanical force directly. Here we express TMC1 from the green sea turtle (CmTMC1) and TMC2 from the budgerigar (MuTMC2) in insect cells, purify and reconstitute the proteins, and show that liposome-reconstituted CmTMC1 and MuTMC2 proteins possess ion channel activity. Furthermore, by applying pressure to proteoliposomes, we demonstrate that both CmTMC1 and MuTMC2 proteins can indeed respond to mechanical stimuli. In addition, CmTMC1 mutants corresponding to human hearing loss mutants exhibit reduced or no ion channel activity. Taken together, our results show that the CmTMC1 and MuTMC2 proteins are pore-forming subunits of mechanosensitive ion channels, supporting TMC1 and TMC2 as hair cell transduction channels. • Purified CmTMC1 and MuTMC2 proteins can incorporate into artificial liposomes • CmTMC1 and MuTMC2 proteins are pore-forming ion channels • CmTMC1 and MuTMC2 ion channels are mechanosensitive • Deafness-related CmTMC1 mutants exhibit reduced or no ion channel activity Jia et al. used protein purification, functional reconstitution, and liposome recording to demonstrate that TMC1 and TMC2 proteins are pore-forming subunits of mechanosensitive ion channels, supporting TMC1 and TMC2 as hair cell transduction channels. [ABSTRACT FROM AUTHOR]

Published

2020