Voltage‐Gated Na<sup>+</sup> Channel Activation Induces Both Action Potentials in Utricular Hair Cells and Brain‐Derived Neurotrophic Factor Release in the Rat Utricle During a Restricted Period of Development

Chabbert, Christian; Méchaly, Ilana; Sieso, Victor; Giraud, Pierre; Brugeaud, Aurore; Lehouelleur, Jacques; Couraud, François; Valmier, Jean; Sans, Alain

doi:10.1113/jphysiol.2003.043034

Cited by 45 publications

(70 citation statements)

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“…This developmental excitability, also observed in the mouse utricle (Geleoc et al, 2004), has also been reported in other sensory organs of the higher vertebrates, such as the cochlea (Evans and Fuchs, 1987;Kros et al, 1998) and the retina (Pan and Hu, 2000;Kawai et al, 2001). Although, in most cases, the physiological relevance of the I Na remains unknown, we first reported that I Na was involved in the activity-dependent secretion of brain-derived neurotrophic factor (BDNF) in the neonate rat utricle (Chabbert et al, 2003). Regarding the major role of BDNF in the establishment and the stabilization of synaptic contacts (Ernfors et al, 1995;Schimmang et al, 1995), we proposed that the transient hair cell excitability may contribute to the synaptogenesis process in the vestibular organs.…”

Section: Introductionsupporting

confidence: 61%

“…We have previously shown that, at birth [postnatal day 0 (P0)], rat utricle hair cells transiently express a neuronal-like tetrodotoxin (TTX)-sensitive voltage-gated Na ϩ current (I Na ), enabling these cells to generate sodium-driven action potentials (APs) (Chabbert et al, 2003). I Na is downregulated during the first postnatal week, decreasing the sodium-based excitability in mature hair cells.…”

Section: Introductionmentioning

confidence: 99%

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Control of Hair Cell Excitability by Vestibular Primary Sensory Neurons

et al. 2007

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In the rat utricle, synaptic contacts between hair cells and the nerve fibers arising from the vestibular primary neurons form during the first week after birth. During that period, the sodium-based excitability that characterizes neonate utricle sensory cells is switched off. To investigate whether the establishment of synaptic contacts was responsible for the modulation of the hair cell excitability, we used an organotypic culture of rat utricle in which the setting of synapses was prevented. Under this condition, the voltage-gated sodium current and the underlying action potentials persisted in a large proportion of nonafferented hair cells. We then studied whether impairment of nerve terminals in the utricle of adult rats may also affect hair cell excitability. We induced selective and transient damages of afferent terminals using glutamate excitotoxicity in vivo. The efficiency of the excitotoxic injury was attested by selective swellings of the terminals and underlying altered vestibular behavior. Under this condition, the sodium-based excitability transiently recovered in hair cells. These results indicate that the modulation of hair cell excitability depends on the state of the afferent terminals. In adult utricle hair cells, this property may be essential to set the conditions required for restoration of the sensory network after damage. This is achieved via re-expression of a biological process that occurs during synaptogenesis.

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Section: Introductionsupporting

confidence: 61%

Section: Introductionmentioning

confidence: 99%

Control of Hair Cell Excitability by Vestibular Primary Sensory Neurons

et al. 2007

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“…We did not see the mixed Ca 2+ -Na + spikes that are typical of mouse IHCs in the first postnatal week (Marcotti et al, 2003b). All Atoh1 + cells lacked the voltage-gated Na + currents of immature HC subtypes (Chabbert et al, 2003;Eckrich et al, 2012;Géléoc et al, 2004;Li et al, 2010;Marcotti et al, 2003b;Oliver et al, 1997;Witt et al, 1994;Wooltorton et al, 2007). Again, these channels either were never expressed or had stopped being expressed by the earliest time point we examined, 12 days of in vitro differentiation.…”

Section: Voltage-gated Currents In Differentiated Hair Cell-like Cellsmentioning

confidence: 72%

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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“…It is therefore likely that ES cell types will have to be cotransplanted with appropriate factors to encourage directed differentiation and integration. It is known that neurotrophic factors are important for hair cell development (Chabbert et al 2003), and a recent report indicates that epidermal growth factor (EGF) may be required to induce formation of new hair cells (Doetzlhofer et al 2004). The formation of new hair cells may also require overexpression of Math1, a transcription factor downstream in the EGF pathway that is essential for hair cell development (Zheng and Gao 2000;Woods et al 2004).…”

Section: Discussionmentioning

confidence: 99%

Survival of Partially Differentiated Mouse Embryonic Stem Cells in the Scala Media of the Guinea Pig Cochlea

Hildebrand

Dahl

Hardman

et al. 2005

JARO

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The low regenerative capacity of the hair cells of the mammalian inner ear is a major obstacle for functional recovery following sensorineural hearing loss. A potential treatment is to replace damaged tissue by transplantation of stem cells. To test this approach, undifferentiated and partially differentiated mouse embryonic stem (ES) cells were delivered into the scala media of the deafened guinea pig cochlea. Transplanted cells survived in the scala media for a postoperative period of at least nine weeks, evidenced by histochemical and direct fluorescent detection of enhanced green fluorescent protein (EGFP). Transplanted cells were discovered near the spiral ligament and stria vascularis in the endolymph fluid of the scala media. In some cases, cells were observed close to the damaged organ of Corti structure. There was no evidence of significant immunological rejection of the implanted ES cells despite the absence of immunosuppression. Our surgical approach allowed efficient delivery of ES cells to the scala media while preserving the delicate structures of the cochlea. This is the first report of the survival of partially differentiated ES cells in the scala media of the mammalian cochlea, and it provides support for the potential of cell-based therapies for sensorineural hearing impairment.

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Voltage‐Gated Na⁺ Channel Activation Induces Both Action Potentials in Utricular Hair Cells and Brain‐Derived Neurotrophic Factor Release in the Rat Utricle During a Restricted Period of Development

Cited by 45 publications

References 43 publications

Control of Hair Cell Excitability by Vestibular Primary Sensory Neurons

Control of Hair Cell Excitability by Vestibular Primary Sensory Neurons

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

Survival of Partially Differentiated Mouse Embryonic Stem Cells in the Scala Media of the Guinea Pig Cochlea

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Voltage‐Gated Na+ Channel Activation Induces Both Action Potentials in Utricular Hair Cells and Brain‐Derived Neurotrophic Factor Release in the Rat Utricle During a Restricted Period of Development

Cited by 45 publications

References 43 publications

Control of Hair Cell Excitability by Vestibular Primary Sensory Neurons

Control of Hair Cell Excitability by Vestibular Primary Sensory Neurons

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

Survival of Partially Differentiated Mouse Embryonic Stem Cells in the Scala Media of the Guinea Pig Cochlea

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Voltage‐Gated Na⁺ Channel Activation Induces Both Action Potentials in Utricular Hair Cells and Brain‐Derived Neurotrophic Factor Release in the Rat Utricle During a Restricted Period of Development