Project description:Sensory hair cells cannot be regenerated through transdifferentiation of neighboring supporting cells in the organ of Corti in mature mammalian animals, but limited regeneration capacity exists in supporting cells at neonatal stage in mouse and this transdifferentiation potential is rapidly lost during the first week of postnatal maturtion. We hypothesized that epigenetic decommissioning of hair cell gene enhancers in supporting cells during postnatal maturation leads the permanent silencing of hair cell genes and the loss of transdifferentiation potential. To test this hypothesis, we FACS purified hair cells and supporting cells from cochleae at different developmental stages for transcritomic analysis (RNAseq), chromatin accessibility assay (ATACseq) and histone modification profiling (ChIPseq or CUT&RUN). We first defined hair cell genes and predicted their potential active enhancers. We found that hair cell gene promoters and enhancers were kept in a primed-but-silenced status (H3K4me1/3+, low H3K27ac but high H3K27me3) in supporting cells at neonatal stage. During postnatal maturation, hair cell gene enhancers are decommissioned through H3K4me1 removal, leading to the permanent silencing of hair cells genes. We also found that hair cell gene enhancer decommissioning process correlated with the base-to-apex wave of transdifferentiation potential loss. In addition, hair cell gene enhancer commissioning status is preserved in mature utricular supporting cells, which can regenerate hair cells through transdifferentiation even at adult stage. Those data together suggest that decommissioning of hair cell gene enhancers in supporting cells during postnatal maturation is the epigenetic mechanism underlying the loss of regeneration capacity in the organ of Corti.

Project description:Purpose - To profile epigenetic changes in cochlear progenitor cells, hair cells, and supporting cells across postnatal development. Methods- Cochlear cell types were obtained from fluorescently labeled transgenic mice. E13.5 cochlear prosensory progenitor cells (E13.5_PG, p27Kip1-GFP+), P1 hair cells (P1_HC, Atoh1-GFP+), P1 supporting cells (P1_SC, Lfng-GFP+), and P6, P8, P21 supporting cells (P6_SC, P8_SC, P21_SC, Lfng-creER, NuTRAP lineage-traced) were FACS purified for epigenetic profiling using WGBS (DNA methylation), CUT&Tag (H3K4me1, H3K4me3, H3K27me3, CUTAC H3K4me2). DNA demethylation of hair cell-specific promoters was interrogated by comparing % mCpG profiles of transdifferentiating supporting cells (P1_SC_tdt_gfp, Lfng-creER/TdTomato+, Atoh1-GFP+) against non-transdifferentiating supporting cells (P1_SC_tdt, P6_SC_tdt, Lfng-creER/TdTomato+) purified via FACS. P1 and P8 wildtype cochleas were enzymatically dissociated and used directly for scMultiome simultaneous profiling of RNA and ATAC at the single cell level (P1_scMultiome, P8_scMultiome, 10x Genomics). For scMultiome of P70 wildtype (P70_wt_scMultiome, Lfng-CreERT2, NuTRAP) and P70 deafened (P70_deaf_scMultiome, Lfng-CreERT2, NuTRAP, Pou4f3DTR) supporting cells, mice received 100 mg/kg tamoxifen (Sigma-Aldrich T5648) at P21, 0.01 mg/kg Diptheria toxin (Sigma-Aldrich D0564) at P28, and allowed to mature to P70, at which point cochlear tissues were harvested, FACS purified for NuTRAP+ supporting cells, and inputted into a scMultiome reaction. Results- WGBS highlighted differentially methylated regions (DMR) across E13.5_PG, P1_HC, P1_SC, P6_SC, and P21_SC. Pre-established DMRs become hypermethylated in supporting cells between P1 and P21. This corresponds with increasing heterochromatin characteristics, such as loss of accessibility (CUTAC), loss of H3K4me1, and switch between H3K27me3-mediated repression to DNA methylation-mediated silencing. WGBS of P1_SC_tdt_gfp compared to P1_SC_tdt and P6_SC_tdt showed DNA demethylation of hair cell-specific DMRs, suggesting that DNA demethylation is required for transdifferentiation of supporting cells into hair cells. P1_scMultiome, P8_scMultiome, P70_wt_scMultiome, and P70_deaf_scMultiome revealed changes in chromatin accessibility associated with age, as well as from long-term deafening at the single cell level. scMultiome datasets also highlight cell type-specific enhancers active during different stages of postnatal development.

Project description:Latent transdifferentiation potential exists in supporting cells at neonatal stage in the organ of Corti in mouse, but this plasticity is lost rapidly during the first week of postnatal maturation, leading to the failure of sensory hair cell regeneration. To investigate the molecular mechanism underlying the loss of transdifferentiation potential, we compared epigenetic changes in E17.5, P1 and P6 supporting cells. In E17.5 and P1 supporting cells, hair cell gene enhancers are kept in a primed state (H3K4me1+ H3K27ac-) which can be readily activated during transdifferentiation induced by Notch blocking. As supporting cells mature, a substantial amount of hair cell gene enhancers are decommissioned by H3K4me1, leading to the loss of transdifferentiation potential. In contrast, hair cell gene enhancers retain their commissioned epigenetic status in mature utricular supporting cells, sustaining the transidifferentiation potential in utricular supporting cells in mature animals. Our findings reveal the epigenetic mechanisms underlying the failure of sensory hair cell regeneration in mammalian cochlea.

Project description:This study examined transcripts that are enriched in neonatal mouse cochlear supporting cells at postnatal day 1 and postnatal day 6. Supporting cells were purified by FACS sorting for GFP fluorescence from the cochleas of transgenic mice in which a BAC including the LFng locus drives the expression of GFP. Two replicates of GFP+ supporting cells were compared with all other cochlear cell types that were GFP-. We performed this experiment at two different ages, postnatal day 1 and postnatal day 6. mRNA profiles of supporting cells (GFP+) and all other cochlear cell types (GFP-), two replicates each, at P1 and P6 mice were generated by deep sequencing using Illumna TruSeq.

Project description:This study examined transcripts that are enriched in neonatal mouse cochlear supporting cells at postnatal day 1 and postnatal day 6. Supporting cells were purified by FACS sorting for GFP fluorescence from the cochleas of transgenic mice in which a BAC including the LFng locus drives the expression of GFP. Two replicates of GFP+ supporting cells were compared with all other cochlear cell types that were GFP-. We performed this experiment at two different ages, postnatal day 1 and postnatal day 6.

Project description:Latent regeneration potential has been found in neonatal supporting cells in the organ of Corti in mouse. Upon Notch inhibition by DAPT, postnatal day 1 (P1) supporting cells transdifferentiate into hair cells. To profile the transcriptomic and epigenetic changes in supporting cells during transdifferentiation, we FACS purified supporting cells from DAPT treated cochleae for RNAseq, ATACseq and H3K27ac CUT&RUN. We found that hair cell genes were up-regulated in supporting cells after DAPT treatment and that hair cell gene induction was accompanied by epigentic activation of hair cell gene cis-regulatory elements through chromatin accessibility increase and H3K27ac accumulation, suggesting the regulatory roles of epigenetic activation of hair cell gene elements for hair cell gene expression induction.

Project description:This study examined transcripts that are enriched in neonatal mouse cochlear supporting cells at postnatal day 1 and postnatal day 6 after inhibition of the Notch signaling pathway. Cochleas from postnatal day 0 and postnatal day 5 were cultured for 24 hours in the gamma secretase inhibitor DAPT or DMSO as a vehicle control. Supporting cells were purified by FACS sorting for GFP fluorescence from the cochleas of transgenic mice in which a BAC including the LFng locus drives the expression of GFP. Two replicates of GFP+ supporting cells were compared with all other cochlear cell types that were GFP-. We performed this experiment at two different ages, postnatal day 0+24 hours culture and postnatal day 5 + 24 hours culture. (corresponding to P1 and P6). mRNA profiles of P0 and P5 supporting cells (GFP+) and all other cochlear cell types (GFP-) treated with DAPT or DMSO, two replicates each, were generated by deep sequencing using Illumna TruSeq.

Project description:This study examined transcripts that are enriched in neonatal mouse cochlear supporting cells at postnatal day 1 and postnatal day 6 after inhibition of the Notch signaling pathway. Cochleas from postnatal day 0 and postnatal day 5 were cultured for 24 hours in the gamma secretase inhibitor DAPT or DMSO as a vehicle control. Supporting cells were purified by FACS sorting for GFP fluorescence from the cochleas of transgenic mice in which a BAC including the LFng locus drives the expression of GFP. Two replicates of GFP+ supporting cells were compared with all other cochlear cell types that were GFP-. We performed this experiment at two different ages, postnatal day 0+24 hours culture and postnatal day 5 + 24 hours culture. (corresponding to P1 and P6).

Project description:T cell development is accompanied by epigenetic changes that ensure the silencing of stem cell-related, and the activation of lymphocyte-specific programs. How transcription factors influence these changes remains unclear. We show that the Ikaros transcription factor interacts with the Polycomb Repressive Complex 2 (PRC2) in CD4-CD8- thymocytes, and allows its binding to >200 developmentally-regulated genes, many of which are expressed in hematopoietic stem cells. Loss of Ikaros in CD4-CD8- cells leads to diminished histone H3 Lys27 (H3K27) trimethylation and ectopic expression of these genes. Ikaros binding triggers PRC2 recruitment and H3K27 trimethylation. Furthermore, Ikaros interacts with PRC2 independently of the Nucleosome Remodeling and Deacetylation complex. Our results identify Ikaros as a fundamental regulator of PRC2 function in developing T cells.

Project description:H3K27 trimethylation in mouse peripheral nerve