Project description:Much of human hearing loss is caused by loss of auditory hair cell (HC) function. Mammals cannot regenerate these essential mechanoelectrical transducers of sound. However, birds have retained the ability to regenerate HCs from surrounding supporting cells. To better understand hair cell regeneration, we have expression profiled the sensory epithelia from chicken cochleae and utricles. Pure sensory epithelia, consisting of HCs plus supporting cells, were damaged with either neomycin or laser treatment. Changes in gene expression at various points during regeneration were compared to undamaged control cultures on a custom microarray that interrogates the vast majority of transcription factor (TF) genes. These experiments involved multiple biological samples and hundreds of microarray comparisons. Keywords: timecourse

Project description:Much of human hearing loss is caused by loss of auditory hair cell (HC) function. Mammals cannot regenerate these essential mechanoelectrical transducers of sound. However, birds have retained the ability to regenerate HCs from surrounding supporting cells. To better understand hair cell regeneration, we have expression profiled the sensory epithelia from chicken cochleae and utricles. Pure sensory epithelia, consisting of HCs plus supporting cells, were damaged with either neomycin or laser treatment. Changes in gene expression at various points during regeneration were compared to undamaged control cultures on a custom microarray that interrogates the vast majority of transcription factor (TF) genes. These experiments involved multiple biological samples and hundreds of microarray comparisons. Keywords: timecourse

Project description:Much of human hearing loss is caused by loss of auditory hair cell (HC) function. Mammals cannot regenerate these essential mechanoelectrical transducers of sound. However, birds have retained the ability to regenerate HCs from surrounding supporting cells. To better understand hair cell regeneration, we have expression profiled the sensory epithelia from chicken cochleae and utricles. Pure sensory epithelia, consisting of HCs plus supporting cells, were damaged with either neomycin or laser treatment. Changes in gene expression at various points during regeneration were compared to undamaged control cultures on a custom microarray that interrogates the vast majority of transcription factor (TF) genes. These experiments involved multiple biological samples and hundreds of microarray comparisons. Keywords: timecourse

Project description:Much of human hearing loss is caused by loss of auditory hair cell (HC) function. Mammals cannot regenerate these essential mechanoelectrical transducers of sound. However, birds have retained the ability to regenerate HCs from surrounding supporting cells. To better understand hair cell regeneration, we have expression profiled the sensory epithelia from chicken cochleae and utricles. Pure sensory epithelia, consisting of HCs plus supporting cells, were damaged with either neomycin or laser treatment. Changes in gene expression at various points during regeneration were compared to undamaged control cultures on a custom microarray that interrogates the vast majority of transcription factor (TF) genes. These experiments involved multiple biological samples and hundreds of microarray comparisons. Keywords: timecourse

Project description:Mechanosensory hair cells of the mature mammalian organ of Corti do not regenerate, and loss of hair cells leads to permanent hearing loss. Although non-mammalian vertebrates are able to regenerate hair cells by the division and transdifferentiation of adjacent supporting cells, many humans with severe hearing loss completely lack hair cells and supporting cells, with the organ of Corti being replaced by a flat epithelium of non-sensory cells To determine if mature non-sensory cells can produce hair cells in vivo, we reprogrammed non-sensory cells of the mature cochlea with three hair cell transcription factors, Gfi1, Atoh1, and Pou4f3. We were able to generate significant numbers of hair cell-like cells in the non-sensory inner and outer sulci of the cochlea after 2 weeks of reprogramming. New hair cells continued to be added to the non-sensory regions of the cochlea over the next seven weeks, and expressed hair cell proteins such as Myosin VIIa, parvalbumin, and prestin and formed stereociliary hair bundles. We confirmed the identity of these cells by high depth single cell RNA-seq. Significantly, cells adjacent to converted hair cells expressed markers of supporting cells, suggesting that transcription factor reprogramming of non-sensory tissue in the adult animal can generate mosaics of sensory cells similar to those seen in the organ of Corti. Generating such sensory mosaics by reprogramming may represent a potential strategy for hearing restoration in humans.

Project description:Alzheimer's disease (AD) is the most common type of dementia and is characterized by cognitive and behavioral impairment that significantly interferes with social functioning. Over the last decade, there has been an increased interest in whether sensory deficiency may be associated with the development of AD. Notably, the relationship between hearing impairment and AD is of great relevance, but still poorly understood. In this study, we found an early-onset hearing loss in 3xTgAD and 3xTgAD/Polβ+/− mouse models. The hearing assessment was measured by auditory brainstem response (ABR) and distortion product otoacoustic emission (DPOAE) recordings. Herein, we report that both 3xTgAD and 3xTgAD/Polβ+/− mice showed increased ABR thresholds between at 16 and 32 kHz at 4 weeks of age, much earlier than any AD behavioral changes. The ABR thresholds were significantly higher in 3xTgAD/Polβ+/− mice than in 3xTgAD mice at 16 kHz, and DPOAE signals were also reduced, indicating that DNA damage may affect hearing impairment in AD. Poly ADP-ribosylation levels and protein expression of DNA damage markers increased significantly and NAD+ levels were reduced in the cochlea of 3xTgAD and 3xTgAD/Polβ+/− mice. Remarkably, we observed the downregulation of phosphoglycerate mutase 2 (PGAM2) in cochlea and a decrease in the number of synaptic ribbons in the presynaptic zones of inner hair cells in 3xTgAD/Polβ+/− mice. We also find that the activity of sirtuin 3 (SIRT3) is downregulated in cochlea, indicative of impaired mitochondrial function. Taken together, hearing impairment may be a potential early marker of AD. In addition, these findings provide new insights into the mechanism of the relationship between hearing dysfunction and AD and suggest that DNA damage in the cochlea can contributes to the development of early hearing loss of AD. The hearing assessment was measured by auditory brainstem response (ABR) and distortion product otoacoustic emission (DPOAE) at 4 weeks of age, thereafter whole cochlea and auditory cortex tissue were collected from each mouse (WT, Polβ+/−, 3xTgAD, and 3xTgAD/Polβ+/−) and subjected to total RNA isolation to understand what metabolism-related gene expression changes in cochlea and auditory cortex.

Project description:Our work describes the application of mass spectrometry-based label-free quantitative proteomics for the identification of differentially expressed proteins between different-aged cochlea. We report proteins exclusively present as well as up- and downregulated in the cochlear sensory epithelium at significant developmental stages. Additionally, we report proteins exclusively present on P3 that were recently identified in the cochlea for the first time. We use bioinformatics to provide insight on biological functions and potential primary and secondary partners of the differentially expressed proteins. This study provides the first differentially expressed proteome in the mammalian cochlea at significant developmental stages; before hearing, during the onset of hearing, and when hearing is fully developed. We believe that these results will provide insights into the function of proteins that change during development and identify potential protein biomarkers related to hearing impairments.

Project description:The homeobox transcription factor Prox1 is critical for organogenesis including brain, retina, liver and pancreas and lymphatic system. Prox1 is transiently expressed in mouse cochlear hair cells (HCs) and supporting cells (SCs), however, it remains elusive about its in vivo DNA binding site and roles during cochlear development. Here, by using fresh cochlear tissues and Prox1 antibody, we firstly mapped out the genome-wide binding sites of Prox1 via Cleavage Under Targets and Release Using Nuclease (CUT&RUN). Gene function enrichment analysis suggests several potential functions of Prox1, one of which is regulating cell cycle progression. Secondly, to validate our CUT&RUN data, we further performed in vivo prox1 gain-of-function studies through genetic approaches. Onset of ectopic Prox1 at early embryonic otocyst leads to shorter cochlea with density of HCs and SCs distribution, suggesting a precocious cell cycle exit of cochlear sensory progenitor cells. These findings highlight the power of CUT&RUN in mapping DNA binding sites even in tissues (i.e. cochlea) with rare cells, as well as providing the first genetic evidence to support roles of Prox1 in regulating progenitor pools of cochlear progenitors.

Project description:Precise frequency discrimination is a hallmark of auditory function in birds and mammals. In the cochlea, tuning and spectral separation result from longitudinal differences in basilar membrane stiffness and numerous individual gradiations in sensory hair cell phenotypes, but it is unknown what patterns those phenotypes. Hypothesizing that morphogen levels might differ along the longitudinal axis of the developing cochlea, we sequenced the transcriptomes of the proximal, middle, and distal thirds of the chicken cochlea at E6.5, when postmitotic hair cells first form. Embryonic day 6.5 chicken cochlea were dissected. Three samples were collected from each cochlear duct by cutting the duct into three approximately equal sized pieces to produce proximal, middle, and distal pieces. Each sample contained a portion of the future tegmentum vasculosum and the basilar papilla sensory epithelium. The distal piece also contained the region fo the future lagena.

Project description:Ectopic expression of Atoh1 in non-sensory supporting cells (SCs) in mouse cochleae induces their conversion to hair cells (HCs) in vivo. cHCs in multiple intermediate states of the conversion process that most closely resembled neonatal differentiating HCs, but differed from the progenitors. We further identified 52 transcription factors that are differentially expressed in cHCs, SCs, and mature HCs and confirmed that Isl1 synergistically enhanced the efficiency of Atoh1-mediated HC conversion in cochlear explants. Our results demonstrate that direct HC conversion from SCs in vivo follows a different path from normal development and requires multiple factors for maximum efficiency and completion.