Project description:Several compounds cause auditory and vestibular toxicity by targeting the sensory transducing cells of the inner ear, the hair cells (HC). These compounds, known as ototoxic compounds, may cause vestibular HC apoptosis following high dose acute exposure. However, chronic exposure to low doses has been observed to cause progressive damage. Thus, chronic ototoxic stress first cause detachment and uncoupling of the HC and their post-synaptic neurons, followed by changes in cell shape including stereocilia fusion and ending with extrusion of the HCs from the sensory epithelium towards the luminal spaces of the vestibule. The molecular mechanisms driving these phenomena have not been established. We hypothesized that this response of the vestibular epithelium to chronic ototoxic stress must include specific gene expression responses. The present SubSeries is part of a SuperSeries aimed at identifying these expression responses. Two species, two ototoxic compounds and different times were studied as a strategy to identify the most relevant responses. In the present SubSeries, the expression response of the vestibular epithelium is studied in mice exposed to 3,3'-iminodipropionitrile (IDPN).

Project description:Several compounds cause auditory and vestibular toxicity by targeting the sensory transducing cells of the inner ear, the hair cells (HC). These compounds, known as ototoxic compounds, may cause vestibular HC apoptosis following high dose acute exposure. However, chronic exposure to low doses has been observed to cause progressive damage. Thus, chronic ototoxic stress first cause detachment and uncoupling of the HC and their post-synaptic neurons, followed by changes in cell shape including stereocilia fusion and ending with extrusion of the HCs from the sensory epithelium towards the luminal spaces of the vestibule. The molecular mechanisms driving these phenomena have not been established. We hypothesized that this response of the vestibular epithelium to chronic ototoxic stress must include specific gene expression responses. The present SubSeries is part of a SuperSeries aimed at identifying these expression responses. Two species, two ototoxic compounds and different times were studied as a strategy to identify the most relevant responses. In the present SubSeries, the expression response of the vestibular epithelium is studied in rats exposed to 3,3'-iminodipropionitrile (IDPN) for 4 weeks.

Project description:Several compounds cause auditory and vestibular toxicity by targeting the sensory transducing cells of the inner ear, the hair cells (HC). These compounds, known as ototoxic compounds, may cause vestibular HC apoptosis following high dose acute exposure. However, chronic exposure to low doses has been observed to cause progressive damage. Thus, chronic ototoxic stress first cause detachment and uncoupling of the HC and their post-synaptic neurons, followed by changes in cell shape including stereocilia fusion and ending with extrusion of the HCs from the sensory epithelium towards the luminal spaces of the vestibule. The molecular mechanisms driving these phenomena have not been established. We hypothesized that this response of the vestibular epithelium to chronic ototoxic stress must include specific gene expression responses. The present SubSeries is part of a SuperSeries aimed at identifying these expression responses. Two species, two ototoxic compounds and different times were studied as a strategy to identify the most relevant responses. In the present SubSeries, the expression response of the vestibular epithelium is studied in rats exposed to 3,3'-iminodipropionitrile (IDPN) for 3 or 7 weeks.

Project description:The response of the vestibular ganglion neurons to the stress or loss of their presynaptic hair cells (HC) is not understood. This understanding is necessary because the survival and functional competence of these neurons will determine the outcome of any intervention aiming at repair or regeneration of the HC. One existing observation is that of uncoupling of the synapse between the HCs and ganglion neurons following subchronic ototoxic exposure in rodent models. We here studied the expression response of the vestibular ganglion associated with this synaptic uncoupling.

Project description:The response of the vestibular ganglion neurons to the stress or loss of their presynaptic hair cells (HC) is not understood. This understanding is necessary because the survival and functional competence of these neurons will determine the outcome of any intervention aiming at repair or regeneration of the HC. One existing observation is that of uncoupling of the synapse between the HCs and ganglion neurons following subchronic ototoxic exposure in rodent models. We here studied the expression response of the vestibular ganglion associated with this synaptic uncoupling.

Project description:Effect of subchronic ototoxic exposure on the vestibular epithelium

Project description:Effect of subchronic ototoxic (streptomycin) exposure on the vestibular epithelium of the rat

Project description:Effect of subchronic ototoxic (3,3'-iminodipropionitrile - IDPN) exposure on the vestibular epithelium of the mouse

Project description:The vestibular sensory epithelium may degenerate into a layer of flat cells, known as flat epithelium, after a severe lesion, but the pathogenesis of vestibular flat epithelium remains unclear. We used microarrays to detail the global programme of gene expression in normal utricle and vestibular flat epithelium and identified whether epithelial-mesenchymal transition participite in this process

Project description:The mammalian inner ear subserves auditory and vestibular sensations via highly specialized cells and proteins. We show that sensory hair cells (HCs) employ hundreds of uniquely or highly expressed proteins for processes involved in transducing mechanical inputs, stimulating sensory neurons, and maintaining structure and function of these post-mitotic cells. Our proteomic analysis of purified HCs extends the existing HC transcriptome, revealing undetected gene products and isoform-specific protein expression. Comparison with mouse and human databases of genetic auditory/vestibular impairments confirms the critical role of the HC proteome for normal inner ear function, providing a cell-specific pool of candidates for novel, important HC genes. Several proteins identified exclusively in HCs by proteomics and by immunohistochemistry map to human genetic deafness loci, potentially representing new deafness genes.