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

Li, A.; Xue, Jianping; Peterson, E. H.

doi:10.1152/jn.00831.2007

Cited by 119 publications

(160 citation statements)

References 66 publications

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“…In addition to the actin-based stereocilia, vestibular hair bundles and immature cochlear hair bundles have a single kinocilium that is microtubule based and contains acetylated α-tubulin (Li et al, 2008;Ogata and Slepecky, 1995). In our differentiated cells, immunoreactivity to acetylated α3 tubulin was rare: only 4% (9/289) of vestibular hair cell-like cells ( Fig.…”

Section: Hc Proteins In Cells Differentiated From Inner Ear Progenitorsmentioning

confidence: 83%

“…Ten percent (8/83) of myosin VIIA-positive cells derived from vestibular progenitors showed oncomodulin-like immunoreactivity, the same as the percentage of HCs in the mature mouse utricular epithelium that are striolar type I HCs (366/3613; Li et al, 2008). The Ca 2+ -binding protein calretinin (calbindin 2) is strongly expressed in immature HCs as well as in mature type II vestibular HCs and cochlear inner HCs (IHCs) (Dechesne et al, 1994;Desai et al, 2005;Li et al, 2008). The calretinin antibody labeled one-third of Atoh1-nGFP + cells (5/15 cells, one experiment) derived from vestibular tissue ( Fig.…”

Section: Hc Proteins In Cells Differentiated From Inner Ear Progenitorsmentioning

confidence: 93%

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Distinct capacity for differentiation to inner ear cell types by progenitor cells of the cochlea and vestibular organs

McLean

Eatock

et al. 2016

Development

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Disorders of hearing and balance are most commonly associated with damage to cochlear and vestibular hair cells or neurons. Although these cells are not capable of spontaneous regeneration, progenitor cells in the hearing and balance organs of the neonatal mammalian inner ear have the capacity to generate new hair cells after damage. To investigate whether these cells are restricted in their differentiation capacity, we assessed the phenotypes of differentiated progenitor cells isolated from three compartments of the mouse inner ear -the vestibular and cochlear sensory epithelia and the spiral ganglion -by measuring electrophysiological properties and gene expression. Lgr5 + progenitor cells from the sensory epithelia gave rise to hair cell-like cells, but not neurons or glial cells. Newly created hair cell-like cells had hair bundle proteins, synaptic proteins and membrane proteins characteristic of the compartment of origin. PLP1 + glial cells from the spiral ganglion were identified as neural progenitors, which gave rise to neurons, astrocytes and oligodendrocytes, but not hair cells. Thus, distinct progenitor populations from the neonatal inner ear differentiate to cell types associated with their organ of origin.

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Section: Hc Proteins In Cells Differentiated From Inner Ear Progenitorsmentioning

confidence: 83%

Section: Hc Proteins In Cells Differentiated From Inner Ear Progenitorsmentioning

confidence: 93%

Distinct capacity for differentiation to inner ear cell types by progenitor cells of the cochlea and vestibular organs

McLean

Eatock

et al. 2016

Development

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“…1) and many between-zone differences in patterns of hair cells and afferent and efferent innervation are shared across organs (Goldberg, 1991). The central zone of each canal crista resembles in many ways the striola, a swath within each otolith macula that straddles or borders (see Li et al, 2008) a line at which hair bundles reverse orientation. Likewise, the peripheral zones of cristas resemble the extrastriolar zones of maculas (Fig.…”

Section: Firing Regularitymentioning

confidence: 99%

“…1 shows part of the Firing patterns in vestibular afferents vestibular labyrinth of the mouse inner ear; the utricular macula and two canal cristas have been exposed by removal of the extracellular matrices. Each epithelium comprises several thousand hair cells (Desai et al, 2005a;Desai et al, 2005b;Li et al, 2008) and supporting cells. The hair cells synapse onto the specialized terminals of primary vestibular afferents, as illustrated schematically in Fig.…”

Section: Introductionmentioning

confidence: 99%

Ion channels in mammalian vestibular afferents may set regularity of firing

Eatock

Xue

Kalluri

2008

Journal of Experimental Biology

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SummaryRodent vestibular afferent neurons offer several advantages as a model system for investigating the significance and origins of regularity in neuronal firing interval. Their regularity has a bimodal distribution that defines regular and irregular afferent classes. Factors likely to be involved in setting firing regularity include the morphology and physiology of the afferents' contacts with hair cells, which may influence the averaging of synaptic noise and the afferents' intrinsic electrical properties. In vitro patch clamp studies on the cell bodies of primary vestibular afferents reveal a rich diversity of ion channels, with indications of at least two neuronal populations. Here we suggest that firing patterns of isolated vestibular ganglion somata reflect intrinsic ion channel properties, which in vivo combine with hair cell synaptic drive to produce regular and irregular firing.

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“…In mammals, striolar afferents are reported to have higher gains (spikes/s/unit acceleration) than extrastriolar afferents (Lysakowski and Goldberg 2004). If regional differences in the stiffness of turtle utricular hair cells are also present in mammals, as their bundle structures suggest (Li et al 2008), then striolar bundles in mammals may have higher gains (steeper current-displacement curves) than extrastriolar bundles and so may contribute to the higher gains of their postsynaptic afferents. An additional possibility is that stiffer hair bundles in the striola may contribute to the phasic response properties and high-pass filtering of striolar afferents (Eatock and Songer 2011).…”

Section: Functional Significance Of Hair Bundle Stiffnessmentioning

confidence: 99%

Steady-state stiffness of utricular hair cells depends on macular location and hair bundle structure

Spoon

Moravec

Rowe

et al. 2011

Journal of Neurophysiology

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Spoon C, Moravec WJ, Rowe MH, Grant JW, Peterson EH. Steady-state stiffness of utricular hair cells depends on macular location and hair bundle structure. J Neurophysiol 106: 2950-2963. First published September 14, 2011 doi:10.1152/jn.00469.2011.-Spatial and temporal properties of head movement are encoded by vestibular hair cells in the inner ear. One of the most striking features of these receptors is the orderly structural variation in their mechanoreceptive hair bundles, but the functional significance of this diversity is poorly understood. We tested the hypothesis that hair bundle structure is a significant contributor to hair bundle mechanics by comparing structure and steady-state stiffness of 73 hair bundles at varying locations on the utricular macula. Our first major finding is that stiffness of utricular hair bundles varies systematically with macular locus. Stiffness values are highest in the striola, near the line of hair bundle polarity reversal, and decline exponentially toward the medial extrastriola. Striolar bundles are significantly more stiff than those in medial (median: 8.9 N/m) and lateral (2.0 N/m) extrastriolae. Within the striola, bundle stiffness is greatest in zone 2 (106.4 N/m), a band of type II hair cells, and significantly less in zone 3 (30.6 N/m), which contains the only type I hair cells in the macula. Bathing bundles in media that break interciliary links produced changes in bundle stiffness with predictable time course and magnitude, suggesting that links were intact in our standard media and contributed normally to bundle stiffness during measurements. Our second major finding is that bundle structure is a significant predictor of steady-state stiffness: the heights of kinocilia and the tallest stereocilia are the most important determinants of bundle stiffness. Our results suggest 1) a functional interpretation of bundle height variability in vertebrate vestibular organs, 2) a role for the striola in detecting onset of head movement, and 3) the hypothesis that differences in bundle stiffness contribute to diversity in afferent response dynamics.

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

Cited by 119 publications

References 66 publications

Distinct capacity for differentiation to inner ear cell types by progenitor cells of the cochlea and vestibular organs

Distinct capacity for differentiation to inner ear cell types by progenitor cells of the cochlea and vestibular organs

Ion channels in mammalian vestibular afferents may set regularity of firing

Steady-state stiffness of utricular hair cells depends on macular location and hair bundle structure

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