Implication of Vestibular Hair Cell Loss of Planar Polarity for the Canal and Otolith-Dependent Vestibulo-Ocular Reflexes in Celsr1–/– Mice

Introduction: Vestibular sensory hair cells are precisely orientated according to planar cell polarity (PCP) and are key to enable mechanic-electrical transduction and normal vestibular function. PCP is found on different scales in the vestibular organs, ranging from correct hair bundle orientation, coordination of hair cell orientation with neighboring hair cells, and orientation around the striola in otolithic organs. Celsr1 is a PCP protein and a Celsr1 KO mouse model showed hair cell disorganization in all vestibular organs, especially in the canalar ampullae. The objective of this work was to assess to what extent the different vestibulo-ocular reflexes were impaired in Celsr1 KO mice.Methods: Vestibular function was analyzed using non-invasive video-oculography. Semicircular canal function was assessed during sinusoidal rotation and during angular velocity steps. Otolithic function (mainly utricular) was assessed during off-vertical axis rotation (OVAR) and during static and dynamic head tilts.Results: The vestibulo-ocular reflex of 10 Celsr1 KO and 10 control littermates was analyzed. All KO mice presented with spontaneous nystagmus or gaze instability in dark. Canalar function was reduced almost by half in KO mice. Compared to control mice, KO mice had reduced angular VOR gain in all tested frequencies (0.2–1.5 Hz), and abnormal phase at 0.2 and 0.5 Hz. Concerning horizontal steps, KO mice had reduced responses. Otolithic function was reduced by about a third in KO mice. Static ocular-counter roll gain and OVAR bias were both significantly reduced. These results demonstrate that canal- and otolith-dependent vestibulo-ocular reflexes are impaired in KO mice.Conclusion: The major ampullar disorganization led to an important reduction but not to a complete loss of angular coding capacities. Mildly disorganized otolithic hair cells were associated with a significant loss of otolith-dependent function. These results suggest that the highly organized polarization of otolithic hair cells is a critical factor for the accurate encoding of the head movement and that the loss of a small fraction of the otolithic hair cells in pathological conditions is likely to have major functional consequences. Altogether, these results shed light on how partial loss of vestibular information encoding, as often encountered in pathological situations, translates into functional deficits.

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Connectomics of the zebrafish's lateral-line neuromast reveals wiring and miswiring in a simple microcircuit

eLife ◽

10.7554/elife.33988 ◽

2018 ◽

Vol 7 ◽

Cited By ~ 11

Author(s):

Eliot Dow ◽

Adrian Jacobo ◽

Sajjad Hossain ◽

Kimberly Siletti ◽

A J Hudspeth

Keyword(s):

Hair Cell ◽

Lateral Line ◽

Hair Cells ◽

Planar Cell Polarity ◽

Developmental Stages ◽

Notch Signaling Pathway ◽

Nerve Fibers ◽

Directional Sensitivity ◽

Efferent Nerve ◽

Polarity Gene

The lateral-line neuromast of the zebrafish displays a restricted, consistent pattern of innervation that facilitates the comparison of microcircuits across individuals, developmental stages, and genotypes. We used serial blockface scanning electron microscopy to determine from multiple specimens the neuromast connectome, a comprehensive set of connections between hair cells and afferent and efferent nerve fibers. This analysis delineated a complex but consistent wiring pattern with three striking characteristics: each nerve terminal is highly specific in receiving innervation from hair cells of a single directional sensitivity; the innervation is redundant; and the terminals manifest a hierarchy of dominance. Mutation of the canonical planar-cell-polarity gene vangl2, which decouples the asymmetric phenotypes of sibling hair-cell pairs, results in randomly positioned, randomly oriented sibling cells that nonetheless retain specific wiring. Because larvae that overexpress Notch exhibit uniformly oriented, uniformly innervating hair-cell siblings, wiring specificity is mediated by the Notch signaling pathway.

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Wnts regulate planar cell polarity via heterotrimeric G protein and PI3K signaling

The Journal of Cell Biology ◽

10.1083/jcb.201912071 ◽

2020 ◽

Vol 219 (10) ◽

Cited By ~ 1

Author(s):

Andre Landin Malt ◽

Arielle K. Hogan ◽

Connor D. Smith ◽

Maxwell S. Madani ◽

Xiaowei Lu

Keyword(s):

Hair Cell ◽

G Protein ◽

Cell Polarity ◽

Planar Cell Polarity ◽

Pi3k Pathway ◽

Sensory Epithelium ◽

Nucleotide Exchange ◽

Cell Orientation ◽

Complex Signals ◽

Heterotrimeric G Protein

In the mammalian cochlea, the planar cell polarity (PCP) pathway aligns hair cell orientation along the plane of the sensory epithelium. Concurrently, multiple cell intrinsic planar polarity (referred to as iPCP) modules mediate planar polarization of the hair cell apical cytoskeleton, including the kinocilium and the V-shaped hair bundle essential for mechanotransduction. How PCP and iPCP are coordinated during development and the roles of Wnt ligands in this process remain unresolved. Here we show that genetic blockade of Wnt secretion in the cochlear epithelium resulted in a shortened cochlear duct and misoriented and misshapen hair bundles. Mechanistically, Wnts stimulate Gi activity by regulating the localization of Daple, a guanine nucleotide exchange factor (GEF) for Gαi. In turn, the Gβγ complex signals through phosphoinositide 3-kinase (PI3K) to regulate kinocilium positioning and asymmetric localizations of a subset of core PCP proteins, thereby coordinating PCP and iPCP. Thus, our results identify a putative Wnt/heterotrimeric G protein/PI3K pathway for PCP regulation.

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On the Legacy of Genetically Altered Mouse Models to Explore Vestibular Function: Distribution of Vestibular Hair Cell Phenotypes in the Otoferlin-Null Mouse

Annals of Otology Rhinology & Laryngology ◽

10.1177/0003489419834596 ◽

2019 ◽

Vol 128 (6_suppl) ◽

pp. 125S-133S ◽

Cited By ~ 1

Author(s):

Terry J. Prins ◽

Johnny J. Saldate ◽

Gerald S. Berke ◽

Larry F. Hoffman

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Vestibular Function ◽

Null Mouse ◽

Type I ◽

Vestibular Hypofunction ◽

Cellular Changes ◽

Sensory Epithelia ◽

Vestibular Sensory Epithelia ◽

Cell Phenotypes

Objectives: Early in his career, David Lim recognized the scientific impact of genetically anomalous mice exhibiting otoconia agenesis as models of drastically compromised vestibular function. While these studies focused on the mutant pallid mouse, contemporary genetic tools have produced other models with engineered functional modifications. Lim and colleagues foresaw the need to analyze vestibular epithelia from pallid mice to verify the absence of downstream consequences that might be secondary to the altered load represented by otoconial agenesis. More generally, however, such comparisons also contribute to an understanding of the susceptibility of labyrinthine sensory epithelia to more widespread cellular changes associated with what may appear as isolated modifications. Methods: Our laboratory utilizes a model of vestibular hypofunction produced through genetic alteration, the otoferlin-null mouse, which has been shown to exhibit severely compromised stimulus-evoked neurotransmitter release in type I hair cells of the utricular striola. The present study, reminiscent of early investigations of Lim and colleagues that explored the utility of a genetically altered mouse to explore its utility as a model of vestibular hypofunction, endeavored to compare the expression of the hair cell marker oncomodulin in vestibular epithelia from wild-type and otoferlin-null mice. Results: We found that levels of oncomodulin expression were much greater in type I than type II hair cells, though were similar across the 3 genotypes examined (ie, including heterozygotes). Conclusion: These findings support the notion that modifications resulting in a specific component of vestibular hypofunction are not accompanied by widespread morphologic and cellular changes in the vestibular sensory epithelia.

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Temporal Bone Studies of the Human Peripheral Vestibular System

Annals of Otology Rhinology & Laryngology ◽

10.1177/00034894001090s504 ◽

2000 ◽

Vol 109 (5_suppl) ◽

pp. 20-25 ◽

Cited By ~ 38

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.

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Structure and Development of Vestibular Hair Cells in the Larval Bullfrog

Annals of Otology Rhinology & Laryngology ◽

10.1177/000348947908800323 ◽

1979 ◽

Vol 88 (3) ◽

pp. 427-437 ◽

Cited By ~ 23

Author(s):

Cheuk W. Li ◽

Edwin R. Lewis

Keyword(s):

Hair Cell ◽

Hair Cells ◽

High Frequency ◽

Low Frequency ◽

Type A ◽

Cell Types ◽

Sensory Organs ◽

Sensory Epithelia ◽

Sensory Structures ◽

Vestibular Organs

Structure and development of hair cells in vestibular sensory organs of the larval bullfrog were examined with scanning electron microscopy. The larval vestibular sensory epithelia resembled those of the adult frog. Based on morphology of the ciliary tufts, seven hair cell types were identified. One of them, the type A hair cell, appears to be the morphogenetic precursor of other hair cell types. The size of the stereocilia of type A hair cells is comparable to the surrounding microvilli. The distribution of immature type A hair cells suggests that the periphery of the sensory epithelia is the principal growth zone and the site of formation of new hair cells. However, a far greater number of type A hair cells were found in high frequency sensitive sensory organs (sacculus, amphibian and basilar papillae) than low frequency sensitive vestibular sensory structures (canal cristae, utriculus and lagena). This phenomenon may suggest that the time period required for the maturation of type A hair cells to their ultimate hair cell types in the low frequency sensitive vestibular organs is shorter than in the high frequency sensory structures. It is also possible that the low frequency sensitive vestibular organs may have completed their morphogenetic development in the early larval stages, while morphogenesis of hair cells in the high frequency sensory structures continues throughout the lifetime of a bullfrog.

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Par3 is essential for the establishment of planar cell polarity of inner ear hair cells

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1816333116 ◽

2019 ◽

Vol 116 (11) ◽

pp. 4999-5008 ◽

Cited By ~ 11

Author(s):

Andre Landin Malt ◽

Zachary Dailey ◽

Julia Holbrook-Rasmussen ◽

Yuqiong Zheng ◽

Arielle Hogan ◽

...

Keyword(s):

Hair Cell ◽

Inner Ear ◽

Cell Polarity ◽

Hair Cells ◽

Planar Cell Polarity ◽

Tissue Level ◽

Hair Bundle ◽

Nucleotide Exchange ◽

Genetic Mosaic ◽

Pcp Signaling

In the inner ear sensory epithelia, stereociliary hair bundles atop sensory hair cells are mechanosensory apparatus with planar polarized structure and orientation. This is established during development by the concerted action of tissue-level, intercellular planar cell polarity (PCP) signaling and a hair cell-intrinsic, microtubule-mediated machinery. However, how various polarity signals are integrated during hair bundle morphogenesis is poorly understood. Here, we show that the conserved cell polarity protein Par3 is essential for planar polarization of hair cells. Par3 deletion in the inner ear disrupted cochlear outgrowth, hair bundle orientation, kinocilium positioning, and basal body planar polarity, accompanied by defects in the organization and cortical attachment of hair cell microtubules. Genetic mosaic analysis revealed that Par3 functions both cell-autonomously and cell-nonautonomously to regulate kinocilium positioning and hair bundle orientation. At the tissue level, intercellular PCP signaling regulates the asymmetric localization of Par3, which in turn maintains the asymmetric localization of the core PCP protein Vangl2. Mechanistically, Par3 interacts with and regulates the localization of Tiam1 and Trio, which are guanine nucleotide exchange factors (GEFs) for Rac, thereby stimulating Rac-Pak signaling. Finally, constitutively active Rac1 rescued the PCP defects in Par3-deficient cochleae. Thus, a Par3–GEF–Rac axis mediates both tissue-level and hair cell-intrinsic PCP signaling.

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Conserved and Divergent Principles of Planar Polarity Revealed by Hair Cell Development and Function

Frontiers in Neuroscience ◽

10.3389/fnins.2021.742391 ◽

2021 ◽

Vol 15 ◽

Author(s):

Michael R. Deans

Keyword(s):

Hair Cell ◽

Inner Ear ◽

Hair Cells ◽

Model Organism ◽

Vestibular Function ◽

Sensory Receptor ◽

Apical Surface ◽

Planar Polarity ◽

Vestibular Hair Cells ◽

Sensory Epithelia

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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EMX2-GPR156-Gαi reverses hair cell orientation in mechanosensory epithelia

Nature Communications ◽

10.1038/s41467-021-22997-1 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Katie S. Kindt ◽

Anil Akturk ◽

Amandine Jarysta ◽

Matthew Day ◽

Alisha Beirl ◽

...

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Mirror Image ◽

Hair Bundle ◽

Otolith Organs ◽

Cell Orientation ◽

Stimulus Detection ◽

Cell Reversal ◽

Image Organization ◽

Orphan Gpcr

AbstractHair cells detect sound, head position or water movements when their mechanosensory hair bundle is deflected. Each hair bundle has an asymmetric architecture that restricts stimulus detection to a single axis. Coordinated hair cell orientations within sensory epithelia further tune stimulus detection at the organ level. Here, we identify GPR156, an orphan GPCR of unknown function, as a critical regulator of hair cell orientation. We demonstrate that the transcription factor EMX2 polarizes GPR156 distribution, enabling it to signal through Gαi and trigger a 180° reversal in hair cell orientation. GPR156-Gαi mediated reversal is essential to establish hair cells with mirror-image orientations in mouse otolith organs in the vestibular system and in zebrafish lateral line. Remarkably, GPR156-Gαi also instructs hair cell reversal in the auditory epithelium, despite a lack of mirror-image organization. Overall, our work demonstrates that conserved GPR156-Gαi signaling is integral to the framework that builds directional responses into mechanosensory epithelia.

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Parallel control of mechanosensory hair cell orientation by the PCP and Wnt pathways

10.1101/527937 ◽

2019 ◽

Cited By ~ 1

Author(s):

Joaquin Navajas Acedo ◽

Matthew G. Voas ◽

Richard Alexander ◽

Thomas Woolley ◽

Jay R. Unruh ◽

...

Keyword(s):

Hair Cell ◽

Cell Polarity ◽

Lateral Line ◽

Hair Cells ◽

Wnt Pathway ◽

Neural Tube Closure ◽

Cell Phenotype ◽

Cell Orientation ◽

Pcp Signaling ◽

Wnt Pathways

ABSTRACTCell polarity plays a crucial role during development of vertebrates and invertebrates. Planar Cell Polarity (PCP) is defined as the coordinated polarity of cells within a tissue axis and is essential for processes such as gastrulation, neural tube closure or hearing. Wnt ligands can be instructive or permissive during PCP-dependent processes, and Wnt pathway mutants are often classified as PCP mutants due to the complexity and the similarities between their phenotypes. Our studies of the zebrafish sensory lateral line reveal that disruptions of the PCP and Wnt pathways have differential effects on hair cell orientations. While mutations in PCP genes cause random orientations of hair cells, mutations in Wnt pathway members induce hair cells to adopt a concentric pattern. We show that PCP signaling is normal in hair cells of Wnt pathway mutants and that the concentric hair cell phenotype is due to altered organization of the surrounding support cells. Thus, the PCP and Wnt pathways work in parallel, as separate pathways to establish proper hair cell orientation. Our data suggest that coordinated support cell organization is established during the formation of lateral line primordia, much earlier than the appearance of hair cells. Together, these finding reveal that hair cell orientation defects are not solely explained by defects in PCP signaling and that some hair cell phenotypes warrant reevaluation.

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Autocorrelation Analysis of Hair Bundle Structure in the Utricle

Journal of Neurophysiology ◽

10.1152/jn.00565.2006 ◽

2006 ◽

Vol 96 (5) ◽

pp. 2653-2669 ◽

Cited By ~ 18

Author(s):

M. H. Rowe ◽

E. H. Peterson

Keyword(s):

Hair Cell ◽

Hair Cells ◽

Cell Types ◽

Head Movements ◽

Type I ◽

Autocorrelation Analysis ◽

Response Dynamics ◽

Hair Bundles ◽

Vestibular Organs ◽

Bundle Structure

The ability of hair bundles to signal head movements and sounds depends significantly on their structure, but a quantitative picture of bundle structure has proved elusive. The problem is acute for vestibular organs because their hair bundles exhibit complex morphologies that vary with endorgan, hair cell type, and epithelial locus. Here we use autocorrelation analysis to quantify stereociliary arrays (the number, spacing, and distribution of stereocilia) on hair cells of the turtle utricle. Our first goal was to characterize zonal variation across the macula, from medial extrastriola, through striola, to lateral extrastriola. This is important because it may help explain zonal variation in response dynamics of utricular hair cells and afferents. We also use known differences in type I and II bundles to estimate array characteristics of these two hair cell types. Our second goal was to quantify variation in array orientation at single macular loci and use this to estimate directional tuning in utricular afferents. Our major findings are that, of the features measured, array width is the most distinctive feature of striolar bundles, and within the striola there are significant, negatively correlated gradients in stereocilia number and spacing that parallel gradients in bundle heights. Together with previous results on stereocilia number and bundle heights, our results support the hypothesis that striolar hair cells are specialized to signal high-frequency/acceleration head movements. Finally, there is substantial variation in bundle orientation at single macular loci that may help explain why utricular afferents respond to stimuli orthogonal to their preferred directions.

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