Project description:Activating transcription factor 6 (Atf6) is a key regulator of the unfolded protein response (UPR) and is important for endoplasmic reticulum (ER) function and protein homeostasis in metazoan cells. Patients carrying loss-of-function ATF6 disease alleles develop the cone dysfunction disorder, achromatopsia. The impact of loss of ATF6 function on other cell types, organs, and diseases in people remains unclear. Here, we reported that progressive sensorineural hearing loss was a notable complaint in some patients carrying ATF6 disease alleles and that Atf6-/- mice also showed progressive auditory deficits affecting both genders. In mice with hearing deficits, we found disorganized stereocilia on hair cells and focal loss of outer hair cells. Transcriptomic analysis of Atf6-/- cochleae revealed marked induction of UPR, especially through the PERK arm. These findings identify ATF6 as an essential regulator of cochlear health and function. Furthermore, they supported that ATF6 inactivation in people causes progressive sensorineural hearing loss as part of a blindness-deafness genetic syndrome targeting hair cells and cone photoreceptors. Lastly, our genetic findings support ER stress as an important pathomechanism underlying cochlear damage and hearing loss with clinical implications for patient lifestyle modifications that minimize environmental/physiologic sources of ER stress to the ear.

Project description:This study investigates how lead exposure triggers cochlear synaptopathy and hearing loss in mice. Young-adult CBA/J mice were given lead acetate in drinking water for 28 days. We assessed hearing thresholds, outer hair cell activity, and synaptic changes in the cochlea. Lead exposure raises hearing thresholds, indicating cochlear synaptopathy. Notably affects synapses in the basal turn without impacting outer hair cells. In addition to this, lead altered the abundance of 352 synaptic proteins, with the synaptic vesicle cycle pathway prominently affected. Lead-induced cochlear synaptopathy targets basal cochlear regions, implicating synaptic vesicle cycle signaling in hearing loss. Revealing specific mechanisms behind lead-induced hearing deficits enhances targeted interventions and preventive strategies, advancing our understanding of lead induced hearing loss.

Project description:Mutations in the gene for Norrie disease protein (Ndp) cause syndromic deafness and blindness. We show that cochlear function in an Ndp knockout (KO) mouse deteriorated with age: at P3-P4, hair cells (HCs) showed progressive loss of Pou4f3 and Gfi1, key transcription factors for HC maturation, and Myo7a, a specialized myosin required for normal function of HC stereocilia. Loss of expression of these genes correlated to increasing HC loss and profound hearing loss by 2 months of age. We show that overexpression of the Ndp gene in neonatal supporting cells or, remarkably, upregulation of canonical Wnt signaling in HCs rescued HCs and cochlear function. We conclude that Ndp secreted from supporting cells orchestrates a transcription factor network for the maintenance and survival of HCs and that increasing the level of b-catenin, the intracellular effector of Wnt signaling, is sufficient to replace the functional requirement for Ndp in the cochlea.

Project description:Outer and inner hair cells in the cochlea are essential for hearing, but are vulnerable to damage by genetic mutations and environmental insults, resulting in irreversible sensorineural hearing loss. Investigating these processes requires access to large numbers of human cochlear hair cells and the ability to precisely control genetic, biochemical, and environmental conditions. We recently established a new organoid system that recapitulates human cochlear differentiation. However, maturation of cochlear organoid cultures is inefficient, requiring several months to express the mature outer hair cell marker Prestin. To efficiently obtain fully functional outer hair cells, we tested the effects of the thyroid hormone thyroxine on hair cell maturation in human cochlear organoids. Thyroxine supplementation significantly increased the percentages of Prestin-positive hair cells in an age-dependent manner. Additionally, transcriptomic analyses revealed upregulation of mature outer hair cell genes and downregulation of immature hair cell genes in thyroxine-treated hair cells. Furthermore, some of the treated hair cells exhibited electromotility, a functional hallmark of mature outer hair cells. These results suggest that thyroid hormones accelerate the maturation of hair cells in human cochlear organoids, thereby useful for establishing an improved in vitro model for pre-clinical investigation on sensorineural hearing loss.

Project description:Age-related hearing loss (ARHL) is the most common sensory degenerative disease and can significantly impact the quality of life in elderly people. A previous study using GeneChip miRNA microarray assays showed that the expression of miR-29a changes with age, however, its role in hearing loss is still unclear. In this study, we characterized the cochlear phenotype of miR-29a knockout (miR-29a-/-) mice and found that miR-29a-deficient mice had a rapid progressive elevation of the hearing threshold from 2 to 5 months of age compared with littermate controls as measured by the auditory brainstem response. Stereocilia degeneration, hair cell loss and abnormal stria vascularis were observed in miR-29a-/- mice at 4 months of age. Transcriptome sequencing results showed elevated extracellular matrix (ECM) gene expression in miR-29a-/- mice. Both GO annotation and KEGG pathway enrichment analysis revealed that the key differences were closely related to ECM. Further examination with a transmission electron microscope showed thickening of the basilar membrane in the cochlea of miR-29a-/- mice. Five Col4a genes (Col4a1-a5) and two laminin genes (Lamb2 and Lamc1) were validated as miR-29a direct targets by dual luciferase assays and miR-29a inhibition assays with a miR-29a inhibitor. Consistent with the target gene validation results, the expression of these genes was significantly increased in the cochlea of miR-29a-/- mice, as shown by RT-PCR and Western blot. These findings suggest that miR-29a plays an important role in maintaining cochlear structure and function by regulating the expression of collagen and laminin and that the disturbance of its expression could be a cause of progressive hearing loss.

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:Age-related hearing loss (ARHL) is a progressive sensorineural hearing loss that occurs as people get older. As many as 35% to 50% of the population aged between 65 and 75 have ARHL. Although age-related changes in the central auditory system can contribute to hearing impairment, degeneration of the mechanosensitive hair cells in the cochlea is the prevalent cause of ARHL. The molecular mechanisms of hair cell aging are largely unknown. To provide a comprehensive dataset of age-related genes and pathways in hair cells, we individually collected inner and outer hair cells, the two types of sensory receptor cells in the cochlea, from 9- and 26-month-old CBA/J mice and performed cell type-specific transcriptomic analysis. Our analysis showed a significant reduction of the expression of genes related to hair cell structure and function such as Tmc1, Kcnq4, Kcnj13, Slc7a14, Slc17a8, Chrna9/Chrna10, and Slc26a5. Our hair cell-specific transcriptome analysis provides a rich resource for mechanistic studies of biological aging of cochlear hair cells.

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.

Project description:Characterizing adult cochlear supporting cell transcriptional diversity using scRNA-Seq Hearing loss is a significant disability that impacts 432 million people worldwide. A significant proportion of these individuals are dissatisfied with or do not have access to available treatment options which include hearing aids and cochlear implants. An alternative approach to restore hearing would be to regenerate lost cells, including hair cells in the adult cochlea. Such therapy would require restoration of the organ of Corti’s complex architecture, necessitating regeneration of both mature hair cells and supporting cells. We characterize the first single-cell adult cochlear supporting cell transcriptomes with the goals of: (1) demonstrating their transcriptional distinctiveness from perinatal cochlear supporting cells, (2) providing a metric for future attempts at regenerating mature cochlear supporting cells by identifying both cell type-specific and regional-specific expression, and (3) identify cell cycle gene expression present in adult supporting cells at the single cell level which may establish a basis for targeting cell cycle regulation pathways to force these cells out of quiescence.

Project description:The Gfi1-Cre mouse is commonly used for conditional hair cell-specific gene deletion/activation in the inner ear. However, we have shown that these mice produce a pattern of recombination that is not strictly limited to hair cells, and that Gfi1cre/+ mice exhibit an early onset progressive hearing loss as compared with their wildtype littermates. Here we performed a transcriptome analysis of Gfi1cre/+ and Gfi1+/+ cochlea to detect potential changes in gene expression that could contribute to their hearing loss phenotype, or that could potentially confound downstream analysis of conditional gene deletion using these mice.