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:Evaluation of transcriptional changes in the E14.5 cochlear duct epithelium upon tamoxifen-induced loss of Tbx2 in prosensory cells.

Project description:The mouse cochlear sensory epithelium proteome has been characterized using FASP combined with GELFrEE and off-line SCX- and WAX-based methods follwed by nano LC-MS/MS. In addition, we utilzed single digestion and double digestion approaches using LysC and trypsin endoproteases. MS data files were processed with MaxQuant (Version 1.2.2.5, Max Planck Institute) and peak list files were searched by MASCOT search engine against the UniProt mouse database containing both forward and reversed protein sequences and common contaminants such as keratin. The initial parent and fragment ion maximum precursors were set to 6 ppm and 0.5 Da, respectively. The search included a fixed modification of carbamidomethyl of cysteine and variable modifications of oxidation of methionine and protein N-terminal acetylation. The minimum peptide length to be considered for identification was 6 amino acids.

Project description:In the inner ear, cochlear and vestibular sensory epithelia utilize grossly similar cell types to transduce different stimuli: sound and acceleration.  Each individual sensory epithelium is composed of highly heterogeneous populations of cells based on physiological and anatomical criteria. However, limited numbers of each cell type have impeded transcriptional characterization. Here we generated transcriptomes for 301 single cells from the utricular and cochlear sensory epithelia of newborn mice to circumvent this challenge. Cluster analysis indicates distinct profiles for each of the major sensory epithelial cell types, as well as less distinct subpopulations. Asynchrony within utricles allows reconstruction of the temporal progression of cell-type specific differentiation and suggests possible plasticity among cells at the sensory-nonsensory boundary. Comparisons of cell types from utricles and cochleae demonstrate divergence between auditory and vestibular cells despite a common origin. These results provide significant insights into the developmental processes that form unique inner ear cell types.

Project description:We sequenced the total RNA of cells from inner ear organoids generated by EFI,EFI-4C and EFI-CL expansion strategies. Transcriptional profiles revealed that CHIR and LPA significantly increased proliferative potency and contributed to the stemness maintenance. We further compared the gene expression profiles among the sorted Lgr5+ CPCs, the primary organoids of passage (P)0, the P4 organoids, and the sorted E-cadherin+ sensory epithelial cells. Inner ear organoids recapitulated genetic characteristics of auditory epithelium rather than Lgr5+ progenitors alone. Differential gene analysis of cells from primary organoids and organoids at fourth passage indicated stable transcriptional profiles among passages, which confirmed the reliability and authenticity of cochlear organoids for modeling the properties of the cochlea.

Project description:EBF1 regulates sensory establishment in the cochlea by positioning the medial boundary of the prosensory domain and restricting proliferation of the sensory progenitor population

Project description:To understand the molecular control of development and regeneration in the mammalian cochlear sensory epithelia, we performed a comparative study of gene expression patterns between postnatal day-3 (P3) and adult stages using a microarrays approach. Two inner ear development stages were used in this study, Post-natal day three and eight-week-old adult. A total number of sixty Swiss mice were exploited for each stage. The cochlear sensory epithelia (CSE) were collected from the inner ears and immediately placed in RNA later solution. A total of six independent dissection experiments were carried out separately in order to obtain three biological replicates for each stage. In each experiment, the CSE from 20 mice were pooled. Total RNA was purified from each biological sample separately using RNAeasy Mini Kit and the RNA integrity was assessed by the Nanodrop 2000

Project description:Utilizing conditional Trim71 knockout mice, we find that Trim71 deletion during early otic development causes hearing loss and induces premature cell cycle exit and differentiation of hair cell progenitors. Transcriptomic and genetic experiments reveal that TRIM71 maintains hair cell-progenitors proliferative and undifferentiated through repressing TGF-β-type signaling.

Project description:The chromatin remodeler Brg1 is essential for cochlear sensory epithelium differentiation and patterning

Project description:Hearing loss is often due to the absence or the degeneration of hair cells in the cochlea. Understanding the mechanisms regulating the generation of hair cells may therefore lead to better treatments for hearing disorders. To elucidate the transcriptional control mechanisms specifying the progenitor cells (i.e. prosensory cells) that generate the hair cells and support cells critical for hearing function, we compared chromatin accessibility using ATAC-seq in sorted prosensory cells (Sox2-EGFP+) and surrounding cells (Sox2-EGFP-) from E12, E14.5 and E16 cochlear ducts. In Sox2-EGFP+, we find greater accessibility in and near genes restricted in expression to the prosensory region of the cochlear duct including Sox2, Isl1, Eya1 and Pou4f3. Furthermore, we find significant enrichment for the consensus binding sites of Sox2, Six1 and Gata3—transcription factors required for prosensory development—in the open chromatin regions. Over 2,200 regions displayed differential accessibility with developmental time in Sox2-EGFP+ cells, with most changes in the E12-14.5 window. Open chromatin regions detected in Sox2-EGFP+ cells map to over 48,000 orthologous regions in the human genome that include regions in genes linked to deafness. Our results reveal a dynamic landscape of open chromatin in prosensory cells with potential implications for cochlear development and disease.