Transgenic Tmc2 expression preserves inner ear hair cells and vestibular function in mice lacking Tmc1

Planar polarity describes the organization and orientation of polarized cells or cellular structures within the plane of an epithelium. The sensory receptor hair cells of the vertebrate inner ear have been recognized as a preeminent vertebrate model system for studying planar polarity and its development. This is principally because planar polarity in the inner ear is structurally and molecularly apparent and therefore easy to visualize. Inner ear planar polarity is also functionally significant because hair cells are mechanosensors stimulated by sound or motion and planar polarity underlies the mechanosensory mechanism, thereby facilitating the auditory and vestibular functions of the ear. Structurally, hair cell planar polarity is evident in the organization of a polarized bundle of actin-based protrusions from the apical surface called stereocilia that is necessary for mechanosensation and when stereociliary bundle is disrupted auditory and vestibular behavioral deficits emerge. Hair cells are distributed between six sensory epithelia within the inner ear that have evolved unique patterns of planar polarity that facilitate auditory or vestibular function. Thus, specialized adaptations of planar polarity have occurred that distinguish auditory and vestibular hair cells and will be described throughout this review. There are also three levels of planar polarity organization that can be visualized within the vertebrate inner ear. These are the intrinsic polarity of individual hair cells, the planar cell polarity or coordinated orientation of cells within the epithelia, and planar bipolarity; an organization unique to a subset of vestibular hair cells in which the stereociliary bundles are oriented in opposite directions but remain aligned along a common polarity axis. The inner ear with its complement of auditory and vestibular sensory epithelia allows these levels, and the inter-relationships between them, to be studied using a single model organism. The purpose of this review is to introduce the functional significance of planar polarity in the auditory and vestibular systems and our contemporary understanding of the developmental mechanisms associated with organizing planar polarity at these three cellular levels.

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The lhfpl5 ohnologs lhfpl5a and lhfpl5b are required for mechanotransduction in distinct populations of sensory hair cells in zebrafish

10.1101/793042 ◽

2019 ◽

Author(s):

Timothy Erickson ◽

Itallia V. Pacentine ◽

Alexandra Venuto ◽

Rachel Clemens ◽

Teresa Nicolson

Keyword(s):

Inner Ear ◽

Lateral Line ◽

Hair Cells ◽

Vestibular Function ◽

Fusion Partner ◽

Primary Role ◽

Mechanical Stimuli ◽

Vestibular Hair Cells ◽

Lateral Line Organ ◽

Line Organ

1AbstractHair 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.

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Endolymphatic Potential Measured From Developing and Adult Mouse Inner Ear

Frontiers in Cellular Neuroscience ◽

10.3389/fncel.2020.584928 ◽

2020 ◽

Vol 14 ◽

Author(s):

Yi Li ◽

Huizhan Liu ◽

Xiaochang Zhao ◽

David Z. He

Keyword(s):

Inner Ear ◽

Hair Cells ◽

Adult Mouse ◽

Vestibular Function ◽

Vestibular Organ ◽

Positive Potential ◽

Adult Mice ◽

High K ◽

Endolymphatic Potential ◽

Vestibular Organs

The mammalian inner ear has two major parts, the cochlea is responsible for hearing and the vestibular organ is responsible for balance. The cochlea and vestibular organs are connected by a series of canals in the temporal bone and two distinct extracellular fluids, endolymph and perilymph, fill different compartments of the inner ear. Stereocilia of mechanosensitive hair cells in the cochlea and vestibular end organs are bathed in the endolymph, which contains high K+ ions and possesses a positive potential termed endolymphatic potential (ELP). Compartmentalization of the fluids provides an electrochemical gradient for hair cell mechanotransduction. In this study, we measured ELP from adult and neonatal C57BL/6J mice to determine how ELP varies and develops in the cochlear and vestibular endolymph. We measured ELP and vestibular microphonic response from saccules of neonatal mice to determine when vestibular function is mature. We show that ELP varies considerably in the cochlear and vestibular endolymph of adult mice, ranging from +95 mV in the basal turn to +87 mV in the apical turn of the cochlea, +9 mV in the saccule and utricle, and +3 mV in the semicircular canal. This suggests that ELP is indeed a local potential, despite the fact that endolymph composition is similar. We further show that vestibular ELP reaches adult-like magnitude around post-natal day 6, ~12 days earlier than maturation of cochlear ELP (i.e., endocochlear potential). Maturation of vestibular ELP coincides with the maturation of vestibular microphonic response recorded from the saccular macula, suggesting that maturation of vestibular function occurs much earlier than maturation of hearing in mice.

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Faculty Opinions recommendation of Mechanotransduction in mouse inner ear hair cells requires transmembrane channel-like genes.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.13372023.14859074 ◽

2012 ◽

Cited By ~ 1

Author(s):

Jaime García-Añoveros

Keyword(s):

Inner Ear ◽

Hair Cells ◽

Transmembrane Channel

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Faculty Opinions recommendation of TMC1 and TMC2 are components of the mechanotransduction channel in hair cells of the mammalian inner ear.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.718040306.793482643 ◽

2013 ◽

Author(s):

Andy Groves

Keyword(s):

Inner Ear ◽

Hair Cells

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Chimera states and frequency clustering in systems of coupled inner-ear hair cells

Chaos An Interdisciplinary Journal of Nonlinear Science ◽

10.1063/5.0056848 ◽

2021 ◽

Vol 31 (7) ◽

pp. 073142

Author(s):

Justin Faber ◽

Dolores Bozovic

Keyword(s):

Inner Ear ◽

Hair Cells ◽

Chimera States

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Inner Ear and Muscle Developmental Defects in Smpx-Deficient Zebrafish Embryos

International Journal of Molecular Sciences ◽

10.3390/ijms22126497 ◽

2021 ◽

Vol 22 (12) ◽

pp. 6497

Author(s):

Anna Ghilardi ◽

Alberto Diana ◽

Renato Bacchetta ◽

Nadia Santo ◽

Miriam Ascagni ◽

...

Keyword(s):

Hearing Loss ◽

Inner Ear ◽

Hair Cells ◽

Muscle Fibers ◽

Underlying Mechanism ◽

Loss Of Function ◽

Zebrafish Model ◽

Developmental Defects ◽

Inner Ear Development ◽

Syndromic Hearing Loss

The last decade has witnessed the identification of several families affected by hereditary non-syndromic hearing loss (NSHL) caused by mutations in the SMPX gene and the loss of function has been suggested as the underlying mechanism. In the attempt to confirm this hypothesis we generated an Smpx-deficient zebrafish model, pointing out its crucial role in proper inner ear development. Indeed, a marked decrease in the number of kinocilia together with structural alterations of the stereocilia and the kinocilium itself in the hair cells of the inner ear were observed. We also report the impairment of the mechanotransduction by the hair cells, making SMPX a potential key player in the construction of the machinery necessary for sound detection. This wealth of evidence provides the first possible explanation for hearing loss in SMPX-mutated patients. Additionally, we observed a clear muscular phenotype consisting of the defective organization and functioning of muscle fibers, strongly suggesting a potential role for the protein in the development of muscle fibers. This piece of evidence highlights the need for more in-depth analyses in search for possible correlations between SMPX mutations and muscular disorders in humans, thus potentially turning this non-syndromic hearing loss-associated gene into the genetic cause of dysfunctions characterized by more than one symptom, making SMPX a novel syndromic gene.

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Identification and characterization of amphibian SLC26A5 using RNA-Seq

BMC Genomics ◽

10.1186/s12864-021-07798-6 ◽

2021 ◽

Vol 22 (1) ◽

Author(s):

Zhongying Wang ◽

Qixuan Wang ◽

Hao Wu ◽

Zhiwu Huang

Keyword(s):

Amino Acid ◽

Inner Ear ◽

Hair Cells ◽

Rana Catesbeiana ◽

Site Directed Mutagenesis ◽

Amino Acid Residues ◽

Rna Seq ◽

American Bullfrog ◽

Frog Species

Abstract Background Prestin (SLC26A5) is responsible for acute sensitivity and frequency selectivity in the vertebrate auditory system. Limited knowledge of prestin is from experiments using site-directed mutagenesis or domain-swapping techniques after the amino acid residues were identified by comparing the sequence of prestin to those of its paralogs and orthologs. Frog prestin is the only representative in amphibian lineage and the studies of it were quite rare with only one species identified. Results Here we report a new coding sequence of SLC26A5 for a frog species, Rana catesbeiana (the American bullfrog). In our study, the SLC26A5 gene of Rana has been mapped, sequenced and cloned successively using RNA-Seq. We measured the nonlinear capacitance (NLC) of prestin both in the hair cells of Rana’s inner ear and HEK293T cells transfected with this new coding gene. HEK293T cells expressing Rana prestin showed electrophysiological features similar to that of hair cells from its inner ear. Comparative studies of zebrafish, chick, Rana and an ancient frog species showed that chick and zebrafish prestin lacked NLC. Ancient frog’s prestin was functionally different from Rana. Conclusions We mapped and sequenced the SLC26A5 of the Rana catesbeiana from its inner ear cDNA using RNA-Seq. The Rana SLC26A5 cDNA was 2292 bp long, encoding a polypeptide of 763 amino acid residues, with 40% identity to mammals. This new coding gene could encode a functionally active protein conferring NLC to both frog HCs and the mammalian cell line. While comparing to its orthologs, the amphibian prestin has been evolutionarily changing its function and becomes more advanced than avian and teleost prestin.

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