Project description:We have employed a novel approach for the identification of functionally important microRNA (miRNA)-target interactions using integrated miRNA, transcriptome and proteome profiles with advanced in silico analysis. By looking at both the transcript and protein levels of expression, a thorough coverage of miRNA regulation was obtained. Microdissected auditory and vestibular sensory epithelia were used as the model system, thus being the first time such a comparison was carried out in a neuroepithelial system. Moreover, this is one of only a few studies employing proteome screening for the identification of miRNA targets. Notably, this approach can be employed for the study of other tissues and organs. We detected the expression of 157 miRNAs in the inner ear sensory epithelia, with 53 miRNAs differentially expressed between the cochlea and vestibule. By searching for enrichment and depletion of miRNA targets in the transcript and protein datasets with a reciprocal or similar expression, respectively, as the regulatory miRNA, we identified functionally important miRNAs. Finally, the interaction between miR-135b and PSIP1-P75, a transcriptional coacitvator previously unknown in the inner ear, was identified and validated experimentally. We suggest that miR-135b may serve as a cellular effector, involved in regulating some of the differences between the cochlear and vestibular hair cells. We investigated the mRNA expression profile of the cochlear and vestibular sensory epithelia from inner ears of postnatal day 2 mice using the Affymetrix GeneChip® 430 2Mouse Genome array. Cochlear and vestibular sensory epithelia were dissected from wild type C3H mice and collected separately. The vestibular epithelia consisted of the saccule, utricle and the lateral and anterior cristae. Both the cochlear and vestibular sensory epithelia were dissected with their underlying mesenchyma. Altogether three pools, three biological replicates, of each tissue type were collected consisting of cochlear or vestibular sensory epithelia dissected from 10 to 12 inner ears.

Project description:Transcripts for GH, MHC Class I and II genes, and heavy- and light-chain myosins, as well as many others genes, were differentially regulated in the zebrafish inner ear following overexposure to sound. Following acoustic trauma in the zebrafish inner ear, we used microarray analysis to identify genes involved in inner ear repair following acoustic exposure by comparing the gene expression levels of 2 days and 4 days post-sound exposure (NE-ZF-2d and NE-ZF-4d, respectively) to controls without sound exposure (C-ZF).

Project description:<h4><strong>INTRODUCTION:</strong> Noise-induced hearing loss (NIHL) is an increasing problem in society and accounts for a third of all cases of acquired hearing loss. NIHL is caused by formation of reactive oxygen species (ROS) in the cochlea causing oxidative stress. Hydrogen gas (H₂) can alleviate the damage caused by oxidative stress and can be easily administered through inhalation.</h4><h4><strong>OBJECTIVES:</strong> To present a protocol for untargeted metabolomics of guinea pig perilymph and investigate the effect of H₂ administration on the perilymph metabolome of noise exposed guinea pigs.</h4><h4><strong>METHODS:</strong> The left ear of guinea pigs were exposed to hazardous impulse noise only (Noise, n = 10), noise and H₂ (Noise + H2, n = 10), only H₂ (H2, n = 4), or untreated (Control, n = 2). Scala tympani perilymph was sampled from the cochlea of both ears. The polar component of the perilymph metabolome was analyzed using a HILIC-UHPLC-Q-TOF-MS-based untargeted metabolomics protocol. Multivariate data analysis (MVDA) was performed separately for the exposed- and unexposed ear.</h4><h4><strong>RESULTS:</strong> MVDA allowed separation of groups Noise and Noise + H2 in both the exposed and unexposed ear and yielded 15 metabolites with differentiating relative abundances. Seven were found in both exposed and unexposed ear data and included two osmoprotectants. Eight metabolites were unique to the unexposed ear and included a number of short-chain acylcarnitines.</h4><h4><strong>CONCLUSIONS:</strong> A HILIC-UHPLC-Q-TOF-MS-based protocol for untargeted metabolomics of perilymph is presented and shown to be fit-for-purpose. We found a clear difference in the perilymph metabolome of noise exposed guinea pigs with and without H₂ treatment.</h4>

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:SOX10 (SRY-box 10) mutation may lead to inner ear deformities. However, its molecular mechanisms on inner ear development are not clear. In this work. The inner ear morphology was investigated at different embryonic stages of the SOX10 mutation miniature porcine model with sensorineural hearing loss, and high-throughput RNA-seq and bioinformatics analyses were applied. Our results indicated that the SOX10 mutation in the miniature pigs led to an incomplete partition of the cochlea, a cystic apex caused by fusion from middle and apical turns, cochlear modiolar defects and a shortened cochlear duct. The model demonstrated 173 DEGs and 185 lncRNAs. The down-regulated DEGs most significantly enriched the inflammatory mediator regulation of the TRP channels, arachidonic acid metabolism, and the salivary secretion pathways, while the up-regulated DEGs most significantly enriched the systemic lupus erythematosus and alcoholism pathways. Based on gene cluster analysis, we selected four gene groups: WNT1, KCNQ4, STRC and PAX6.

Project description:We implemented a functional genomics approach as a means to undertake a large-scale analysis of the Xenopus laevis inner ear transcriptome through microarray analysis. Microarray analysis uncovered genes within the X. laevis inner ear transcriptome associated with inner ear function and impairment in other organisms, thereby supporting the inclusion of Xenopus in cross-species genetic studies of the inner ear. Gene expression analysis of Xenopus laevis juvenile inner ear tissue. Inner ear RNA isolated from three groups of 5-10 juvenile X. laevis. Each biological replicate represents pooled inner ear RNA from 10-19 inner ears.

Project description:Meis genes have been shown to control essential processes during development of the central and peripheral nervous system. Here we have defined the roles of the Meis2 gene during vertebrate inner ear induction and the formation of the cochlea. Meis2 is expressed in several tissues required for inner ear induction and in non-sensory tissue of the cochlear duct. Global inactivation of Meis2 in the mouse leads to a severely reduced size of the otic vesicle. Tissue-specific knock outs of Meis2 reveal that its expression in the hindbrain is essential for inner ear induction. Inactivation of Meis2 in the inner ear itself leads to an aberrant coiling of the cochlear duct. By analyzing transcriptomes obtained from Meis2 mutants and ChIPseq analysis of an otic cell line we define candidate target genes for Meis2 which may be directly or indirectly involved in cochlear morphogenesis. Taken together, these data show that Meis2 is essential for inner ear formation and provide an entry point to unveil the network underlying proper coiling of the cochlear duct.

Project description:The inner ear in mammals is derived from a simple ectodermal thickening called the otic placode. Through a series of complex morphological changes, the placode forms the mature inner ear comprising of the auditory organ (cochlea) and the vestibular/balance organs (utricle, saccule, and three semi-circular canals). The vast majority of genes known to be involved during inner ear development have been found through mutational screens or by chance. To identify genes that can serve as novel candidates required for inner ear development, and also candidate genes for uncloned human deafnesses, inner ear tissues from mouse embryos from E9 to E15 were microdissected and expression-profiled at half-day intervals. Also profiled was the non-inner ear mesenchymal tissue surrounding the inner ear tissue. Various patterns of gene expression were identified, and significant biological pathways that these genes represented were identified. Also identified were mouse genes whose human orthologs are located within uncloned non-syndromic deafness intervals, thus serving as candidates for sequence analysis. Experiment Overall Design: Inner ear tissues from E9 to E15 were microdissected at half-day intervals. E9 is the earliest stage when the otic placode is clearly visible and able to be microdissected cleanly. E15 is the stage when all the organs of the inner ear have become established, as have the sensory hair and non-sensory support cells within those organs. For each of the stages from E9 to E10, whole inner ears were profiled. For each of the stages from E10.5 to E12, the primordial cochlear and vestibular organs were profiled separately. For each of the stages from E12.5 to E15, the cochlea and the saccule were profiled separately, whereas the utricle and the three ampullae were combined and profiled together. Any given tissue from any given stage was a collection of anywhere between 4 to 17 identical tissues, and was obtained in duplicate (i.e. from different litters). Hence, a total of 58 inner ear samples were obtained. Moreover, non-inner ear tissue found in the immediate vicinity of inner ear tissue was also obtained and profiled. Specifically, all non-inner ear tissue from E9 was profiled in duplicate. Non-inner ear tissue from E9.5 to E10.5 was pooled and profiled together (in duplicate), whereas that from E11 to E15 was pooled and profiled together (also in duplicate). Therefore, a total of 6 non-inner samples were obtained.

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:Human inner ear perilymph was sampled during cochlear implantation or stapes surgery