Project description:Efferent inhibition of cochlear outer hair cells is mediated by nicotinic cholinergic receptors containing alpha9 (a9) and alpha10 subunits. Mice lacking a9 nicotinic subunits fail to exhibit classic olivocochlear responses and are characterized by abnormal synaptic morphology at the base of outer hair cells. To detail molecular changes induced upon the loss of a9 subunit, we sampled cochlear RNA from wild type and a9 null mice at postnatal (P) days spanning periods of synapse formation and maturation (P3, P7, P13 and P60). Our findings point to a delay in cochlear maturation starting at the onset of hearing (P13), as well as an up-regulation of various GABA receptor subunits in adult mice lacking the a9 nicotinic subunit. Cochleae were removed at postnatal ages P3, P7, P13 and P60. Cochlear tissues from 3-5 mice were pooled per replicate; biological triplicates were performed for each age and genotype.

Project description:The aim of this study is to identify the gene targets of Chd7 (by RNA-seq) in spiral ganglia neurons and cochlear hair cells. mRNA profiles of FACS-sorted spiral ganglia neurons from 4-day old mice and cochlear hair cells from embryos af 16.5 days in controls, Chd7 heterozygous and Chd7 homozygous mutant animals were generated by paired-end sequencing, in triplicate, using Illumina HiSeq 4000. The sequence reads that passed quality filters were reads were aligned to mouse MM10 genome assembly using HiSAT2 (version 2.1.0) with the default parameters in Galaxy (version 2.1.0). To facilitate quantitative gene expression analysis, aligned reads for each sample were counted using featureCounts (version1.6.4). Differential gene expression analysis was performed using DESeq2 (version 2.11.40.6), applying parametric fit. qRT–PCR validation was performed using SYBR Green and gene specific primers. To identify differentially expressed genes, RPKM values of genes that are not normally expressed in E16.5 hair cells or P4 spiral ganglia neurons were removed from analysis. This resulted in 6910 transcripts for genes expressed in hair cells and 11293 genes expressed in neurons. A pairwise comparison between controls and homozygotes and controls and heterozygotes was performed. Significant thresholds were considered for transcripts with an adjusted p-value (FDR) of ≤0.05 and linear fold change of >2 in either direction. Altered expression of selected genes was confirmed with qRT–PCR as well as the encoded proteins by immunohistochemistry. Analysis of differentially expressed genes uncovered novel targets and potential mechanisms by which Chd7 controls the survival of these cells during normal hearing.

Project description:Transcriptomes of control and Chd7-deficient spiral ganglia neurons and cochlear hair cells

Project description:In order to determine the regulators of outer hair cell postnatal maturation, we utilized the RiboTag mouse model to perform a detailed transcriptomic analysis of outer hair cells at five postnatal developmental time points: P8, P14, P28, 6 weeks (6wk) and 10 weeks (10wk). This analysis resulted in consistent enrichment of outer hair cell expressed genes in the immunoprecipitated RNA compared to whole cochlear input RNA from each time point. Using transcription factor binding motif prediction on a set of defined outer hair cell enriched genes, we further use this dataset to identify the helios transcription factor as a regulator of the postnatal outer hair cell transcriptome.

Project description:The hair cells of the cochlea play a decisive role in the process of hearing damage and recovery, yet knowledge of their regeneration process is still limited. Greater epithelial ridge (GER) cells, a type of cell present during cochlear development that has the characteristics of a precursor sensory cell, disappear at the time of maturation of hearing development. Its development and evolution remain mysterious for many years. Here, we performed single-cell RNA sequencing to profile the gene expression landscapes of rats' cochlear duct from P1, P7, and P14 and identified eight major subtypes of GER cells. Furthermore, single-cell trajectory analysis for GER cells and hair cells indicated that among the different subtypes of GER, four subtypes had transient cell proliferation after birth and could transdifferentiate into inner and outer hair cells, and two of them mainly transdifferentiated into inner hair cells. The other two subtypes eventually transdifferentiate into outer hair cells. Our study lays the groundwork for elucidating the mechanisms of the key regulatory genes and signaling pathways in the trans-differentiation of GER cell subtypes into hair cells and provides potential clues to understand hair cell regeneration.

Project description:Presbycusis is characterized by an age-related progressive decline of auditory function, and arises mainly from the degeneration of hair cells or spiral ganglion (SG) cells in the cochlea. Here we show that caloric restriction suppresses apoptotic cell death in the mouse cochlea and prevents late onset of presbycusis. Caloric restricted mice, which maintained body weight at the same level as that of young control (YC) mice, retained normal hearing and showed no cochlear degeneration. CR mice also showed significantly fewer TUNEL-positive staining cells and fewer cleaved caspase-3-positive staining cells relative to middle-age control (MC) mice. Microarray analysis revealed that CR down-regulated the expression of 28 proapoptotic genes, including Bak and Bim. Taken together, our findings suggest that loss of critical cells through apoptosis is an important mechanism of presbycusis in mammals, and that CR or staying lean can retard this process by suppressing apoptosis in the inner ear tissue. Experiment Overall Design: To examine the effects of aging, a comparison of cochlea tissues from YC (3 samples) and MC (3 samples) mice was conducted. To examine the effects of calorie restriction (CR), a comparison of cochleae from MC (3 samples) and CR (3 samples) mice was conducted. We examined age-related changes in gene expression in the cochlea and calorie restriction-induced changes in gene expression in the cochlea. We pooled four cochleae from two mice for one sample and used three samples per group (n = 3). Quality control measures were not used. No replicates were done. Dye swap was not used.

Project description:Different mutations in the gene encoding humans IGF-I cause intrauterine growth retardation, postnatal growth failure, microcephaly, mental retardation, bilateral sensorineural deafness and multiple dysmorphic features. Insight into the role of IGFs in inner ear cochlear ganglion neurogenesis has come from the study of genetically modified mice. Postnatal cochlear development is severely impaired in mice Igf1-/-, which develop smaller cochlea and cochlear ganglia, an immature tectorial membrane and they display a significant decrease in the number and size of auditory neurons. We used microarrays to define the genetic signatures of Igf-1 +/+ and Igf-1-/- mouse cochea and identify the differentially expressed genes. Experiment Overall Design: Cochleae from two E18.5 were isolated from both Igf-1+/+ wild type and Igf-1-/- null mice and pooled to obtain RNA. Heterozygous male and female with a genetic background C57BL/6J were mated to obtain embryos 18.5 days post coitus (E18.5). Three independent pools were used. Cochlear tissues included the otic capsule but not vestibular tissues.

Project description:Different mutations in the gene encoding humans IGF-I cause intrauterine growth retardation, postnatal growth failure, microcephaly, mental retardation, bilateral sensorineural deafness and multiple dysmorphic features. Insight into the role of IGFs in inner ear cochlear ganglion neurogenesis has come from the study of genetically modified mice. Postnatal cochlear development is severely impaired in mice Igf1-/-, which develop smaller cochlea and cochlear ganglia, an immature tectorial membrane and they display a significant decrease in the number and size of auditory neurons. We used microarrays to define the genetic signatures of Igf-1 +/+ and Igf-1-/- mouse cochea and identify the differentially expressed genes. Experiment Overall Design: Cochleae from two E18.5 were isolated from both Igf-1+/+ wild type and Igf-1-/- null mice and pooled to obtain RNA. Heterozygous male and female with a genetic background C57BL/6J were mated to obtain embryos 18.5 days post coitus (E18.5). Three independent pools were used. Cochlear tissues included the otic capsule but not vestibular tissues.

Project description:Although mammalian hair cells are essentially unable to regenerate after damage, nonmammalian hair cells have a robust capacity for hair cell regeneration. To obtain insights into the mechanism of this difference, we analyzed the transcriptomic changes in the mouse cochleae after gentamicin damage and compared them with those in the chick cochleae collected at the corresponding damage time. The results indicated that 2,243 genes had significantly differential expression between the gentamicin- and saline-treated cochleae.

Project description:Spiral ganglion neurons (SGNs) and the associated components of the auditory nerve are primary carriers of auditory information from hair cells to the brain. Loss of SGNs occurs with many pathological conditions, resulting in permanent sensorineural hearing loss. Neural stem/progenitors (NSPs) have been well-characterized in several locations of adult brain and retina. However, it is unclear whether NSPs are present in the adult auditory nerve. Here we examined the self-renewal potential of the adult auditory nerve using ouabain application as a well-established mouse model of acute SGN injury. The observed increase in cell proliferation, alteration in enchromatin/heterochromatin ratio and down-regulation of histone deacetylase expression in glial cells suggest that the quiescent glial cells convert to an activated state after SGN degeneration. This was further confirmed by global gene expression analysis of injured auditory nerves, which showed up-regulation of numerous neurogenesis- and/or development-associated genes shortly after ouabain exposure. These genes include molecular markers commonly used for the identification of NSPs. Under a strict culture regimen, auditory nerve-derived cells of adult mouse ears gave rise to neurospheres, suggesting that multipotent NSPs are present in adult cochlear nerve. Neurosphere assays on Sox2 transgenic mice revealed that Sox2+ glial cells are the source for NSPs. Our data also showed that acute injury or hypoxia enhances neurosphere formation. Taken together, our study revealed that glial cells of adult cochlea exhibit several NSP characteristics, and hence these mature non-neuronal cells may be important targets for promoting self-repair of degenerative auditory nerves. Analysis was conducted on auditory nerve samples from stages encompassing maturation and onset of hearing. Cochleas were collected from euthanized mice (CBA/CaJ) at perinatal (P) stages P0, P3, P7, P10, P14 and P21. Cochleas underwent microdissection to remove the outer bony cochlear shell and cochlear lateral wall, thus preserving the modiolus portion of cochlea which contains mainly the auditory nerve. Paired cochleas (i.e., from left and right ears) from each mouse were pooled to make individual samples. All sample types were done in experimental duplicate (n=2).