Project description:Inner ear cochlear supporting cells (SCs) are highly specialized glia-like cells that structurally and functionally support neighboring mechano-sensory hair cells. Despite their importance for proper auditory function, little is known about the molecular mechanisms that control their development. In this study we investigated the function of the Notch ligand Jagged1 (Jag1) in cochlear SC differentiation and maintenance. To address the function of Jag1 in the differentiation of SCs, we conditionally deleted Jag1 in stage E14.5 SC precursors using the recently established Sox2-CreER/+ and Jag1 fx/fx mouse lines. Analysis of stage P0 Jag1 mutant and control animals revealed that Hensen cells, a highly specialized SC-subtype located at the lateral edge of the auditory sensory epithelium, failed to form in the absence of Jag1. Other SC-subtypes did form in the absence of Jag1, however, their morphology and cellular arrangement was abnormal and SC-subtype specific genes and genes associated with mitochondrial function and protein synthesis were significantly reduced, indicating global defects in SC differentiation and SC homeostasis.

Project description:Ectopic expression of Atoh1 in non-sensory supporting cells (SCs) in mouse cochleae induces their conversion to hair cells (HCs) in vivo. cHCs in multiple intermediate states of the conversion process that most closely resembled neonatal differentiating HCs, but differed from the progenitors. We further identified 52 transcription factors that are differentially expressed in cHCs, SCs, and mature HCs and confirmed that Isl1 synergistically enhanced the efficiency of Atoh1-mediated HC conversion in cochlear explants. Our results demonstrate that direct HC conversion from SCs in vivo follows a different path from normal development and requires multiple factors for maximum efficiency and completion.

Project description:Strategies to overcome irreversible cochlear hair cell (HC) damage and loss are of vital importance to develop a treatment for hearing loss. HC regeneration in adult cochlea relies on a two-phase process: 1) Reprogramming mature cochlear (SCs) to regain the properties of their younger selves; 2) Activating Atoh1, a gene responsible for HC fate-determining, in the reprogrammed adult SCs for HC regeneration. We have shown that, by transient co-activation of Myc and NICD (Notch1 intracellular domain), the adult mouse cochlea can be successfully reprogrammed to a relatively younger stage and regain progenitor capacity, with the regeneration of HCs following Atoh1 overexpression in vitro and in vivo. To identify molecules to reprogram mature cochlear SCs, we utilized single-cell RNA sequencing and uncovered the pathways and their target genes underlying MYC/NICD-mediated reprogramming. We used an in-house adult cochlea explant culture system and carried out single-cell RNA sequencing to examine the gene expression profiles of cochlear explants from a transgenic mouse model, rtTa/tet-Myc/-tet-NICD, in response to Dox-induced MYC/NICD co-activation. We have shown that a 4-day treatment by Dox in cultured adult rtTa/tetMyc/-tet-NICD cochleae was sufficient to reprogram adult SCs for HC regeneration.

Project description:Strategies to overcome irreversible cochlear hair cell (HC) damage and loss are of vital importance to develop a treatment for hearing loss. HC regeneration in adult cochlea relies on a two-phase process: 1) Reprogramming mature cochlear (SCs) to regain the properties of their younger selves; 2) Activating Atoh1, a gene responsible for HC fate-determining, in the reprogrammed adult SCs for HC regeneration. We have shown that, by transient co-activation of Myc and NICD (Notch1 intracellular domain), the adult mouse cochlea can be successfully reprogrammed to a relatively younger stage and regain progenitor capacity, with the regeneration of HCs following Atoh1 overexpression in vitro and in vivo. To identify molecules to reprogram mature cochlear SCs and HC regeneration, we utilized single-cell RNA sequencing and uncovered the pathways and their target genes underlying MYC/NICD-mediated reprogramming. We used an in-house adult cochlea explant culture system and carried out single-cell RNA sequencing to examine the gene expression profiles of cochlear explants from a transgenic mouse model, rtTa/tet-Myc/-tet-NICD, in response to Dox-induced MYC/NICD co-activation. We compared gene expression profiles between Atoh1 activation vs. MYC/NICD/Atoh1 co-activation.

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:Strategies to overcome irreversible cochlear hair cell (HC) damage and loss are of vital importance to develop a treatment for hearing loss. HC regeneration in adult cochlea relies on a two-phase process: 1) Reprogramming mature cochlear (SCs) to regain the properties of their younger selves; 2) Activating Atoh1, a gene responsible for HC fate-determining, in the reprogrammed adult SCs for HC regeneration. We have shown that, by transient co-activation of Myc and NICD (Notch1 intracellular domain), the adult mouse cochlea can be successfully reprogrammed to a relatively younger stage and regain progenitor capacity, with the regeneration of HCs following Atoh1 overexpression in vitro and in vivo. We identified a combination (the cocktail) of drug-like molecules composing of small molecules and siRNAs to activate the pathways of Myc, Notch1, Wnt and cAMP. To identify molecules to reprogram mature cochlear SCs and HC regeneration, we utilized single-cell RNA sequencing and uncovered the pathways and their target genes underlying chemical-mediated reprogramming. We used an in-house adult cochlea explant culture system and carried out single-cell RNA sequencing to examine the gene expression profiles of cochlear explants, in response to chemical-induced reprogramming. We compared gene expression profiles between Vehicle/ad.Atoh1 activation vs. Cocktail (chemical reprogramming)/ad.Atoh1 activation.

Project description:The mammalian cochlea loses the ability for hair cell (HC) regeneration after birth, while in the avian auditory epithelium, namely the basilar papilla (BP), supporting cells (SCs) retain the capability for HC regeneration throughout life. Our previous study using single-cell RNA sequencing indicated stepwise fate conversion of SCs to HCs via the precursor state, in which EDNRB2 exhibited specifically high expression, in the process of HC regeneration in chick BP. The present study aimed to reveal a distinct role of EDNRB2 in HC regeneration in chick BP. During HC regeneration in chick BP explant cultures, EDNRB2 expression emerged in a part of ATOH1-expressing SCs immediately after HC loss and decreased according to the progress of HC regeneration process. In embryonic chick BP, EDNRB2 expression was specifically identified in the precursor cell state, which confirmed that mature SCs were reprogrammed to the precursor state in response to HC loss. Pharmacological inhibition of endothelin receptor type B (EDNRB) signaling decreased regenerated HCs in chick BP explant cultures. RNA sequencing revealed that inhibition of EDNRB signaling downregulated genes for HC differentiation and maturation together with genes for cell migration. Histological assessments clarified the deterioration of migration of HC precursors and the delay of HC regeneration processes by inhibition of EDNRB signaling. These results indicate that the expression of EDNRB2 contributes to the fate determination of HCs and that EDNRB signaling regulates the migration and maturation of HC precursors during chick HC regeneration.

Project description:One potential approach to restore hearing is to enforce regeneration of hair cells (HCs) through induction of cellular signaling pathways in supporting cells (SCs) that promote dedifferentiation and proliferation. We previously showed that the constitutive activation of ERBB2 signaling in cochlear SCs indirectly promoted SC differentiation to HCs, both in vivo and in vitro. In the current study, we aimed at identifying mechanisms and molecular pathways activated in SCs with constitutive ERBB2 signaling. To this end, we used single cell RNA sequencing (scRNA-seq) to characterize the transcriptomes of individual neonatal mouse cochlear SCs that were induced to express ERBB2. We found that induction of ERBB2 in vivo resulted in generation of a new distinct cluster of cells with unique transcriptome. This population has de novo expression of two members of the small integrin-binding ligand n-linked glycoproteins (SIBLING) family and their regulators. We confirm expression of the SIBLING Secreted phosphoprotein 1 (SPP1) as one of the most up-regulated genes in response to ERBB2 activation. SPP1 mediates signaling through the CD44 receptor, promoting survival, proliferation, and differentiation of osteoblast lineage cells. Histological analyses of cochlear samples collected from young adult mice confirmed that induction of ERBB2 after noise exposure resulted in up-regulation of both SPP1 and its receptor CD44, and the formation of mitotic sensory stem-like cell aggregates in the organ of Corti. Our results suggest that ectopic activation of ERBB2-signaling in young adult mice secondarily promotes SPP1/CD44 signaling, possibly altering the microenvironment of the organ of Corti.

Project description:During tissue regeneration, lineage-related cells can switch their fate to replace missing cells. This cell plasticity is particularly prominent in more regenerative vertebrates such as zebrafish, yet the molecular basis by which cells transdifferentiate into another cell type upon injury remains unclear. Here we investigate the epigenetic basis of regenerative transdifferentiation in the inner ear, where supporting cells (SCs) generate mechanosensory hair cells (HCs) upon damage. By comparing the chromatin landscapes in regenerative zebrafish and green anole lizards versus non-regenerative mice, we identified a class of enhancers that function in progenitors to generate HCs and then are selectively maintained in SCs of regenerative vertebrates to regenerate HCs. In particular, we uncovered a syntenic class of long-range enhancers for Atoh1, a master transcription factor for HC differentiation. In the absence of injury, these enhancers maintain accessibility in SCs through adulthood but are prevented from driving zebrafish atoh1a expression through Notch repression. Deletion of these enhancers not only impaired atoh1a expression and HC formation during development but also blocked the ability of SCs to transdifferentiate into HCs during regeneration. Moreover, defects were specific to the inner ear versus the lateral line, revealing distinct mechanisms of regeneration in these mechanosensory organs. These findings reveal a class of regenerative enhancer that maintains competency of inner ear SCs to upregulate atoh1a and transdifferentiate into HCs upon damage. We propose that the continued accessibility of developmental enhancers for one cell fate in lineage-related cells may be a common theme underlying adult cell plasticity in regenerative vertebrates.

Project description:Neonatal cochlear Lgr5+ progenitors can regenerate hair cells (HCs), and this process is regulated by several genes and signaling pathways. However, this regeneration ability is limited, and whether additional genes are involved in this process remains unknown. Serpine2 was shown to participate in regulating proliferation and differentiation of cochlear Lgr5+ progenitors in our previous in vitro study. Here, we explored the expression pattern and in vivo roles of Serpine2 in HC regeneration by constructing transgenic mice in which Serpine2 is conditionally overexpressed in cochlear Lgr5+ progenitors. We found that Serpine2 is expressed in the mouse cochlea after birth with a downward trend as the mice aged. In addition, Serpine2 conditional overexpression in vivo in Lgr5+ progenitors of neonatal mice cochlea resulted in an increase number of ectopic HCs in a dose-dependent manner. And Serpine2 knockdown ex vivo and in vivo can inhibit HC regeneration. EdU assay and lineage tracing assay demonstrated that these ectopic HCs likely originated from Lgr5+ progenitors through direct trans-differentiation rather than through mitotic regeneration. Moreover, snRNA-seq analysis and RT-qPCR results revealed that Serpine2 cOE likely induces HC regeneration via inhibiting sonic hedgehog (SHH) signal pathway and inducing Atoh1 and Pou4f3 transcription factor. In brief, our data indicate that Serpine2 plays a pivotal role in HC regeneration from Lgr5+ progenitors in the neonatal mouse cochlea, and this suggests a new avenue for future research into HC regeneration.