Project description:The microRNA miR-96 is important for hearing; mutations in the seed region result in dominant progressive hearing loss in mice and humans. Mir96 is expressed in the sensory hair cells of the organ of Corti along with Mir182 and Mir183. miR-96 is a master regulator of hair cell development, controlling many genes in the organ of Corti, but the role of miR-182 and miR-183 in the hair cells is unknown. We carried out RNA-seq on mice carrying a knockout allele of Mir182, and mice carrying a double knockout allele of Mir183 and Mir96 (Mir183/96). RNA was extracted from the organ of Corti from P4 homozygotes and sex-matched wildtype littermates. Strand-specific libraries were prepared using the NuGEN Ovation Mouse RNA-Seq System 1-16 kit and sequenced on an Illumina HiSeq 2500 machine as paired-end 125bp reads.

Project description:Latent transdifferentiation potential exists in supporting cells at neonatal stage in the organ of Corti in mouse, but this plasticity is lost rapidly during the first week of postnatal maturation, leading to the failure of sensory hair cell regeneration. To investigate the molecular mechanism underlying the loss of transdifferentiation potential, we compared epigenetic changes in E17.5, P1 and P6 supporting cells. In E17.5 and P1 supporting cells, hair cell gene enhancers are kept in a primed state (H3K4me1+ H3K27ac-) which can be readily activated during transdifferentiation induced by Notch blocking. As supporting cells mature, a substantial amount of hair cell gene enhancers are decommissioned by H3K4me1, leading to the loss of transdifferentiation potential. In contrast, hair cell gene enhancers retain their commissioned epigenetic status in mature utricular supporting cells, sustaining the transidifferentiation potential in utricular supporting cells in mature animals. Our findings reveal the epigenetic mechanisms underlying the failure of sensory hair cell regeneration in mammalian cochlea.

Project description:Auditory hair cells transduce sound to the brain and in mammals these cells reside together with supporting cells in the sensory epithelium of the cochlea, called the organ of Corti. To establish the organ’s delicate function during development and differentiation, spatiotemporal gene expression is strictly controlled by chromatin accessibility and cell type specific transcription factors, jointly representing the regulatory landscape. Bulk-sequencing technology and cellular heterogeneity obscured investigations on the interplay between transcription factors and chromatin accessibility in inner ear development. To study the formation of the regulatory landscape in hair cells, we collected single-cell chromatin accessibility profiles accompanied by single-cell RNA data from genetically labeled murine hair cells and supporting cells after birth.

Project description:Following up on our previous observation that early B cell factor (EBF) sites are enriched in open chromatin of the developing sensory epithelium of the mouse cochlea, we investigated the effect of deletion of Ebf1 on inner ear development. We used a Cre driver to delete Ebf1 at the otocyst stage prior to development of the cochlea. These animals survived and were fertile. We examined the cochlea at postnatal day (P) 1 and found that the sensory epithelium had doubled in size but the length of the cochlear duct was unaffected. We also found that deletion of Ebf1 led to ectopic sensory patches in the Kölliker’s organ. Innervation of the developing organ of Corti was disrupted with no obvious spiral bundles. The ectopic patches were also innervated. All the extra hair cells (HCs) within the sensory epithelium and Kölliker’s organ contained mechanoelectrical transduction channels as indicated by rapid uptake of FM1-43. The excessive numbers of HCs were still present in the adult Ebf1 conditional knockout (cKO) animal. The animals had no detectable auditory brainstem response (ABR) suggesting that this gene is essential for hearing development.

Project description:Purpose and Methods: Cochlear sensory hair cells (HCs) are essential for our sense of hearing. They are embedded in the organ of Corti that lacks regenerative capacity, which is a major cause of hearing loss. However, some neonatal non-sensory cells in the organ of Corti display a limited regenerative ability. We used fluorescence-activated cell sorting (FACS) to isolate different cochlear cell types from postnatal day 2 (P2) mice to assess the individual cell groups’ potential to grow organoids and to generate new HCs. Single-cell RNAseq validated the composition of the cell types in the sorted cell groups. Results and Conclusions: The greater epithelial ridge (GER), a transient tissue that only exists in the neonatal inner ear, harbored the most potent organoid-forming cells. GER-derived organoids expanded into large colonies when cultured adherently and gave rise to new hair cell marker-expressing cells in a sensory epithelia-resembling organization. The organoid forming ability of GER cells was synergistically enhanced when they were cultured at increasing density. The synergistic effect relied on direct cell-to-cell contact rather than released soluble factors.

Project description:Sensorineural hearing loss is included in the most common disabilities, and often caused by loss of sensory hair cells in the cochlea. Hair cell regeneration has long been a main target for developing novel therapeutics for sensorineural hearing loss. In the mammalian cochlea, hair cell regeneration occurs in very limited situations, while auditory epithelia of non-mammalians retain the capacity for hair cell regeneration. In the avian basilar papilla, an auditory sensory epithelium, supporting cells, which are sources for regenerated hair cells, are usually quiescent, while hair cell loss induces both direct transdifferentiation of supporting cells and mitotic division of supporting cells. In the present study, we aimed to establish an explant culture model for hair cell regeneration in chick basilar papillae, and validated usefulness of our model to investigate the initial phase of hair cell regeneration. Histological assessments demonstrated that hair cell regeneration via direct transdifferentiation of supporting cells occurred in our model. Labeling assay using 5-ethynyl-2'-deoxyuridine (EdU) revealed the occurrence of mitotic division of supporting cells in the specific location in basilar papillae, while no EdU labeling was identified in newly generated HCs. RNA sequencing indicated alterations in known signaling pathways associated with hair cell regeneration, which is consistent with previous findings. In addition, unbiased analyses of RNA sequencing data indicated novel genes and signaling pathways that could be related to the ignition of supporting cell activation in chick basilar papillae. These results indicate the advantages of our model using explant cultures of chick basilar papillae for exploring molecular mechanisms for hair cell regeneration. Further studies such as single-cell RNA sequencing will allow us to capture the spatiotemporal information by using our explant culture model.

Project description:Age-related hearing impairment (ARHI), one of the most common medical conditions, is strongly heritable, yet its genetic causes remain largely unknown. We conducted a meta-analysis of GWAS summary statistics from multiple hearing-related traits in the UK Biobank (n = up to 323,978) and identified 31 genome-wide significant risk loci for self-reported hearing difficulty (p < 5e-8), of which 30 have not been reported previously at genome-wide significance. We interpreted these loci in the context of newly generated ATAC-seq and single-cell RNA-seq from cells in the mouse cochlea. Risk-associated genes were enriched for expression in cochlear epithelial and non-epithelial cells, as well as for genes related to sensory perception and known Mendelian deafness genes, supporting their relevance to auditory function. Regions of the human genome homologous to open chromatin in sensory epithelial cells from the mouse were strongly enriched for heritable risk for hearing difficulty, even after adjusting for baseline effects of evolutionary conservation and cell-type non-specific regulatory regions. Epigenomic and statistical fine-mapping most strongly supported 50 putative risk genes. Of these, at least 45 were expressed in mouse cochlea and 15 were enriched specifically in sensory hair cells. These results reveal new risk loci and risk genes for hearing difficulty and suggest an important role for altered gene regulation in the cochlear sensory epithelium.

Project description:This study demonstrates the baseline data of gradient gene expression in the cochlea. Especially for genes whose mutations cause autosomal dominant non syndromic hearing loss (Pou4f3, Slc17a8, Tmc1, and Crym) as well as genes important for cochlear function (Emilin-2 and Tectb), gradual expression changes help to explain the various pathological conditions. Four C57BL/6 mice aged 6 weeks cochlea samples including the lateral wall, stria vascularis, spiral ligament, spiral prominence, and the organ of corti were dissected and separated into the apical, middle and basal turns to compare gene expression profiles of each cochlea turn.

Project description:Sensory hair cells cannot be regenerated through transdifferentiation of neighboring supporting cells in the organ of Corti in mature mammalian animals, but limited regeneration capacity exists in supporting cells at neonatal stage in mouse and this transdifferentiation potential is rapidly lost during the first week of postnatal maturtion. We hypothesized that epigenetic decommissioning of hair cell gene enhancers in supporting cells during postnatal maturation leads the permanent silencing of hair cell genes and the loss of transdifferentiation potential. To test this hypothesis, we FACS purified hair cells and supporting cells from cochleae at different developmental stages for transcritomic analysis (RNAseq), chromatin accessibility assay (ATACseq) and histone modification profiling (ChIPseq or CUT&RUN). We first defined hair cell genes and predicted their potential active enhancers. We found that hair cell gene promoters and enhancers were kept in a primed-but-silenced status (H3K4me1/3+, low H3K27ac but high H3K27me3) in supporting cells at neonatal stage. During postnatal maturation, hair cell gene enhancers are decommissioned through H3K4me1 removal, leading to the permanent silencing of hair cells genes. We also found that hair cell gene enhancer decommissioning process correlated with the base-to-apex wave of transdifferentiation potential loss. In addition, hair cell gene enhancer commissioning status is preserved in mature utricular supporting cells, which can regenerate hair cells through transdifferentiation even at adult stage. Those data together suggest that decommissioning of hair cell gene enhancers in supporting cells during postnatal maturation is the epigenetic mechanism underlying the loss of regeneration capacity in the organ of Corti.

Project description:The mammalian cochlea loses its ability to regenerate new hair cells prior to the onset of hearing. In contrast, the adult vestibular system can produce new hair cells in response to damage, or by reprogramming of supporting cells with the hair cell transcription factor Atoh1. We used RNA-seq and ATAC-seq to probe the transcriptional and epigenetic responses of utricle supporting cells to damage and Atoh1 transduction. We show that the improved regenerative response of the utricle correlates with a more accessible chromatin structure in utricle supporting cells compared to their cochlear counterparts. We also provide evidence that Atoh1 transduction of supporting cells is able to promote increased transcriptional accessibility of some hair cell genes. Our study offers a possible explanation for regenerative differences between sensory organs of the inner ear, but shows that additional factors to Atoh1 may be required for optimal reprogramming of hair cell fate.