Project description:In order to elucidate molecular mechanisms of noise-induced hearing loss in the cochlea (inner ear), transcriptome of the cochlear sample was analyzed after induction of hearing loss by exposure to intense noise in mice. Cochlear transcriptome was analyzed at 3 hours following the noise exposure.

Project description:In order to elucidate molecular mechanisms of noise-induced hearing loss and dexamethasone therapy in the cochlea (inner ear), transcriptome of cochlear samples was analyzed after induction of hearing loss by exposure to intense noise in mice. Dexamethasone was intraperitoneally injected immediately following the noise trauma. Cochlear transcriptome was analyzed at 12h and 24h following the noise trauma and dexamethasone administration.

Project description:Alternative splicing contributes to gene expression dynamics in many tissues, yet its role in auditory development remains unclear. We performed whole exome sequencing in individuals with sensorineural hearing loss (SNHL) and identified pathogenic mutations in Epithelial Splicing Regulatory Protein 1 (ESRP1). Patient derived induced pluripotent stem cells showed alternative splicing defects consistent with impaired ESRP1 function. To determine how mutations in ESRP1 cause hearing loss we evaluated Esrp1-/- mouse embryos and uncovered alterations in cochlear morphogenesis, auditory hair cell differentiation and cell fate specification. Transcriptome analysis revealed impaired expression and splicing of genes with essential roles in inner ear development and auditory function. In particular, aberrant splicing of Fgfr2 blocked stria vascularis formation due to erroneous ligand usage, which was corrected by reducing Fgf9 gene dosage. These findings implicate mutations in ESRP1 as a novel cause of SNHL and demonstrate the complex interplay between alternative splicing, inner ear development, and auditory function.

Project description:Age-related hearing (ARHL) loss affects a large part of the human population with a major impact on our aging societies. Yet, underlying mechanisms are not understood, and no validated therapy or prevention exists. NADPH oxidases (NOX), are important sources of reactive oxygen species (ROS) in the cochlea and might therefore be involved in the pathogenesis of ARHL. Here we investigate ARHL in a mouse model. Wild type mice showed early loss of hearing and cochlear integrity, while animals deficient in the NOX subunit p22phox remained unaffected up to six months. Genes of the excitatory pathway were down-regulated in p22phox-deficient auditory neurons. Our results demonstrate that NOX activity leads to upregulation of genes of the excitatory pathway, to excitotoxic cochlear damage, and ultimately to ARHL. In the absence of functional NOXs, aging mice conserve hearing and cochlear morphology. Our study offers new insights into pathomechanisms and future therapeutic targets of ARHL.

Project description:We sought to directly measure the molecular response in the cochlear immune cells following noise exposure.

Project description:Sensorineural hearing loss (SNHL) is referred to as the most common type of hearing loss and typically occurs when the inner ear or the auditory nerve is damaged. Aging, noise exposure, and ototoxic drugs represent three main causes of SNHL, leading to substantial similarities in pathophysiological characteristics of cochlear degeneration. Although the common molecular mechanisms are widely assumed to underlie these similarities, its validity lacks systematic examination. To address this question, we generated three SNHL mouse models from aging, noise exposure, and cisplatin ototoxicity, respectively. Through constructing gene co-expression networks for the cochlear transcriptome data across different hearing-damaged stages, the three models are found to significantly correlate with each other in multiple gene co-expression modules that implicate distinct biological functions, including apoptosis, immune, inflammation, and ion transport. Bioinformatics analyses reveal several potential hub regulators, such as IL1B and CCL2, both of which are verified to contribute to apoptosis accompanied by the increase of (ROS) in in vitro model system. Our findings disentangle the shared molecular circuits across different types of SNHL, providing potential targets for the broad effective therapeutic agents in SNHL.

Project description:We investigate how noise insults affect the cochlea with proteomics and functional assays. Quantitative proteomics reveals that exposure to loud noise causes proteotoxicity. We identify and confirm hundreds of proteins that accumulate, including cytoskeletal proteins, and several nodes of the proteostasis network. Transcriptomic analysis reveals that a subset of the genes encoding these proteins also increase acutely after noise exposure, including numerous proteasome subunits.

Project description:Cochlear single-cell gene expression profiles in mice with noise-induced hidden hearing loss and noise-induced hearing loss.

Project description:Noise-induced hidden hearing loss (HHL) is a new type of hearing loss that has been identified in recent years and leads to insidious damage to the cochlea, unlike the well-known noise-induced hearing loss (NIHL). However, the cellular and molecular basis for it remains to be elucidated. Here, we established a single-cell transcriptome profile of the C57BL/6J mouse cochlea, in which we describe the transcriptome changes of individual cell types within the cochlea with HHL and NIHL. Mice in the HHL group were exposed to 110 dB of noise for 2 hours, and those in the NIHL group were exposed to 115 dB of noise for 4 hours for 3 days. The cochlea was taken 6 hours after the last noise exposure. The control group was not exposed to noise, with other conditions being the same as those in the noise-exposed group. The results of sequencing at the single-cell level help us gain a deeper understanding of the mechanisms of the development of HHL and NIHL.

Project description:Six month-old wild type and Igf1 heterozygous mice were exposed to a violet swept sine noise (frequency range 2–20 kHz) at 110 dB SPL for 30 minutes. Cochlear samples were taken at 2 and 24 hours post-noise exposure to study the evolution of the expression of inflammation genes by using PCR arrays and RT-qPCR. Six month-old wild type and Igf1 heterozygous mice not exposed to noise were used as control.