Project description:The Ten-eleven translocation (TET) DNA demethylases play a well-known role in epigenetic regulation and mouse development. However, their function in cellular differentiation and tissue homeostasis remains poorly understood . Since previous results have implied Tet2/3 in mouse intestinal inflammation, we ablated both enzymes in intestinal epithelial cells (IECs). Our results show that the corresponding mice developed a novel phenotype displaying a severe homeostasis imbalance and a blockage in differentiation trajectories. Transcriptomic, single-cell RNA sequencing (scRNA-seq), single-molecule fluorescence in situ hybridization (sm-FISH), and immunohistochemical analyses revealed that the Tet2/3-deleted mice show a massive loss of mature Paneth cells concomitant with fewer Tuft and more enteroendocrine cells. Further results showed major changes in DNA methylation at putative enhancers, which were associated with cell fate-determining transcription factors and functional effector genes. Notably, pharmacological inhibition of DNA methylation partially rescued the methylation and cellular phenotypes. Moreover, the loss of Tet2/3 results in an altered microbiome, presumably increasing gut susceptibility to inflammatory signals (Ansari et al., 2020). Together, our results uncovered previously unrecognized critical roles for DNA demethylation in intestinal development and function, culminating in the establishment of normal intestinal crypts in mice.

Project description:The Ten-eleven translocation (TET) DNA demethylases play a well-known role in epigenetic regulation and mouse development. However, their function in cellular differentiation and tissue homeostasis remains poorly understood . Since previous results have implied Tet2/3 in mouse intestinal inflammation, we ablated both enzymes in intestinal epithelial cells (IECs). Our results show that the corresponding mice developed a novel phenotype displaying a severe homeostasis imbalance and a blockage in differentiation trajectories. Transcriptomic, single-cell RNA sequencing (scRNA-seq), single-molecule fluorescence in situ hybridization (sm-FISH), and immunohistochemical analyses revealed that the Tet2/3-deleted mice show a massive loss of mature Paneth cells concomitant with fewer Tuft and more enteroendocrine cells. Further results showed major changes in DNA methylation at putative enhancers, which were associated with cell fate-determining transcription factors and functional effector genes. Notably, pharmacological inhibition of DNA methylation partially rescued the methylation and cellular phenotypes. Moreover, the loss of Tet2/3 results in an altered microbiome, presumably increasing gut susceptibility to inflammatory signals (Ansari et al., 2020). Together, our results uncovered previously unrecognized critical roles for DNA demethylation in intestinal development and function, culminating in the establishment of normal intestinal crypts in mice.

Project description:Intestinal homeostasis is dynamically coordinated by various types of epithelial cells fulfilling their specific functions. Tuft cells as chemosensory cells have emerged as key players of the host response, such as innate immunity. Tuft cells are also critical for the restoration of intestinal architecture upon damage, thereby contributing to inflammatory bowel diseases (IBDs) characterized by defective intestinal barrier integrity. However, the molecular mechanism of how tuft cell homeostasis is controlled remains obscure. Recent studies have identified single-nucleotide polymorphisms in the inositol polyphosphate multikinase (IPMK) gene associated with IBD predisposition. IPMK, an essential enzyme for inositol phosphate metabolism, has been known to mediate major biological events such as growth. To investigate the functional significance of IPMK in gut epithelium, we generated intestinal epithelial cell (IEC)-specific Ipmk knockout (IPMKΔIEC) mice. Whereas IPMKΔIEC mice developed normally and showed no intestinal abnormalities during homeostasis, Ipmk deletion aggravated dextran sulfate sodium (DSS)-induced colitis, with higher clinical colitis scores, and elevated epithelial barrier permeability. Surprisingly, no apparent defects in epithelial growth signaling pathway and inflammation were found in DSS-challenged, IPMK-deficient colons. Rather, Ipmk deletion led to a significant decrease in the number of tuft cells without influencing other intestinal epithelial cells. Ipmk deletion in the gut epithelium was found to reduce choline acetyltransferase but not cytokines (e.g., IL-25), suggesting selective loss of cholinergic signaling. Single-cell RNA-sequencing of mouse colonic tuft cells (EpCAM+/Siglec F+) and immunohistochemistry revealed three populations of tuft cells and further showed that, in IPMKΔIEC mice, a transcriptionally inactive tuft club cell population was markedly expanded, and neuronal-related tuft cells were relatively decreased, supporting the abnormal development of tuft cells without IPMK functions. Thus, IPMK acts as a physiological determinant of colonic tuft cell homeostasis, thereby mediating tissue regeneration upon injury.

Project description:Although much research has been done on the diversity of the gut microbiome, little is known about how it influences intestinal homeostasis under normal and pathogenic conditions. Epigenetic mechanisms have recently been suggested to operate at the interface between the microbiota and the intestinal epithelium. We performed whole-genome bisulfite sequencing on conventionally raised and germ-free mice, and discovered that exposure to commensal microbiota induced localized DNA methylation changes at regulatory elements, which are TET2/3-dependent. This culminated in the activation of a set of ‘early sentinel’ response genes to maintain intestinal homeostasis. Furthermore, we demonstrated that exposure to the microbiota in dextran sodium sulfate-induced acute inflammation results in profound DNA methylation and chromatin accessibility changes at regulatory elements, leading to alterations in gene expression programs enriched in colitis- and colon-cancer-associated functions. Finally, by employing genetic interventions, we show that microbiota-induced epigenetic programming is necessary for proper intestinal homeostasis in vivo.

Project description:Aim: The mammalian gut is the largest endocrine organ. Dozens of hormones secreted by enteroendocrine cells regulate a variety of physiological functions of the gut but also of the pancreas and brain. Here, we examined the role of the helix-loop-helix transcription factor ID2 during the differentiation of intestinal stem cells along the enteroendocrine lineage. Methods: To assess the functions of ID2 in the adult mouse small intestine, we used single-cell RNA sequencing, genetically modified mice, and organoid assays. Results: We found that in the adult intestinal epithelium Id2 is predominantly expressed in enterochromaffin and peptidergic enteroendocrine cells. Consistently, the loss of Id2 leads to the reduction of Chromogranin A-positive enteroendocrine cells. In contrast, the numbers of tuft cells are increased in Id2 mutant small intestine. Moreover, ablation of Id2 elevates the numbers of Serotonin+ enterochromaffin cells and Ghrelin+ X-cells in the posterior part of the small intestine. Finally, Id2 acts downstream of BMP signalling during the differentiation of Glucagon Like Peptide-1+ L-cells and Cholecystokinin+ I-cells towards Neurotensin+PYY+ N-cells. Conclusion: Id2 plays an important role in cell fate decisions in the adult small intestine. Firstly, ID2 suppresses the differentiation of secretory intestinal epithelial progenitors towards tuft cell lineage and thus controls host immune response on commensal and parasitic microbiota. Next, ID2 is essential for establishing a differentiation gradient for enterochromaffin and X-cells along the anterior-posterior axis of the gut. Finally, ID2 is necessary for the differentiation of N-cells thus ensuring a differentiation gradient along the crypt-villi axis.

Project description:Tuft cells are an epithelial cell subset critical for initiating type 2 immune responses to parasites and protozoa in the small intestine. To respond to these stimuli, intestinal tuft cells use taste chemosensory signaling pathways, but the role of taste receptors in type 2 immunity is poorly understood. Here, we show that the taste receptor TAS1R3, which detects sweet and umami in the tongue, also regulates tuft cell responses in the distal small intestine. BALB/c mice, which have an inactive form of TAS1R3, as well as Tas1r3-deficient C57BL6/J mice both have severely impaired responses to tuft cell-inducing signals in the ileum including the protozoa Tritrichomonas muris and succinate. In contrast, TAS1R3 is not required to mount an immune response to the helminth Heligmosomoides polygyrus, which infects the proximal small intestine. Examination of uninfected Tas1r3-/- mice revealed a modest reduction in the number of tuft cells in the proximal small intestine but a severe decrease in the distal small intestine at homeostasis. Together, these results suggest that TAS1R3 influences intestinal immunity by shaping the epithelial cell landscape at steady state.

Project description:Nephron endowment is a key determinant of later life hypertension and kidney disease. Here we studied whether epigenetic changes, specifically the ten–eleven translocation (Tet) DNA demethylase family, Tet1, Tet2, and Tet3-mediated active DNA hydroxymethylation is necessary for gene expression regulation and kidney differentiation. We generated mice with deletion of Tet1, Tet2 or Tet3 in Six2 positive nephron progenitors (NP). We did not observe changes in development or kidney function in mice with nephron progenitor-specific deletion of Tet1, Tet2, Tet3 or Tet1/Tet2 or Tet1/Tet3. On the other hand, mice with combined Tet2 and Tet3 loss in Six2-positive NPCs failed to form nephrons leading to kidney failure and perinatal death. Tet2 and Tet3 loss in Six2-positive NPs resulted in defect in mesenchymal to epithelial transition and renal vesicle differentiation. Whole genome bisulfite sequencing, single cell RNA sequencing, and gene and protein expression assay identified a defect in expression in genes in the WNT-β-catenin signaling pathway in absence of Tet2 and Tet3 due to a failure in demethylation of these loci. Our results indicate the key role of Tet2 and Tet3-mediated active cytosine hydroxymethylation in NPs in kidney development and nephron endowment.

Project description:TET proteins convert 5-methylcytosine to 5-hydroxymethylcytosine, an emerging dynamic epigenetic state of DNA that can influence transcription. Evidence has linked TET1 function to epigenetic repression complexes, yet mechanistic information, especially for the TET2 and TET3 proteins, remains limited. Here, we show a direct interaction of TET2 and TET3 with O-GlcNAc transferase (OGT). OGT does not appear to influence hmC activity, rather TET2 and TET3 promote OGT activity. TET2/3-OGT co-localize on chromatin at active promoters enriched for H3K4me3 and reduction of either TET2/3 or OGT activity results in a direct decrease in H3K4me3 and concomitant decreased transcription. Further, we show that Host Cell Factor 1 (HCF1), a component of the H3K4 methyltransferase SET1/COMPASS complex, is a specific GlcNAcylation target of TET2/3-OGT, and modification of HCF1 is important for the integrity of SET1/COMPASS. Additionally, we find both TET proteins and OGT activity promote binding of the SET1/COMPASS H3K4 methyltransferase, SETD1A, to chromatin. Finally, studies in Tet2 knockout mouse bone marrow tissue extend and support the data as decreases are observed of global GlcNAcylation and also of H3K4me3, notably at several key regulators of haematopoiesis. Together, our results unveil a step-wise model, involving TET-OGT interactions, promotion of GlcNAcylation, and influence on H3K4me3 via SET1/COMPASS, highlighting a novel means by which TETs may induce transcriptional activation. ChIP-Seq experiments were performed on Illumina HiScanSQ sequencer in wild-type HEK293T cells for H3K4me3 histone marks, O-GlcNAc and HCF1, for HT-TET2, HT-TET3 and HT-OGT in HEK293T cells overexpressing those three fusion proteins and in TET2 Kd HEK293T cells for H3K4me3 histone marks. ChIP-Seqs were also performed in mouse bone marrow tissues for H3K4me3 histone marks, O-GlcNAc, endogenous Tet2 and in Tet2 Ko bone marrow tissues for H3K4me3 histone marks.

Project description:Purpose: To examine the temporal changes in intestinal tuft cell number and activity in response to intake of a high fat diet and investigate the relation to whole-body energy metabolism and the immune phenotype of the small intestine and epididymal white adipose tissue (eWAT). Methods: C57BL/6J mice were fed either a low fat reference diet (RFD, 10 % kcal fat) or a high fat diet (HFD, 60% kcal fat) for 9 or 22 weeks, followed by characterization of whole-body metabolic parameters, transcription profiles of sorted intestinal tuft cells, and immune phenotypes of tissues. Results: HFD feeding was associated with reductions in the overall number of small intestinal epithelial cells and tuft cells and reduced expression of the intestinal type 2 tuft cell markers Il25 and Tslp. Amongst >1,700 diet-regulated genes in tuft cells identified by RNA-seq, we observed an early association between body mass expansion and increased expression of Serpini1, which encodes the serine protease inhibitor neuroserpin. By contrast, tuft cell expression of genes encoding the GABA-receptors linked to reduced body mass gain. Although we observed a HFD-induced change in the eWAT inflammatory profile, the small intestinal lamina propria displayed a consistent non-inflammatory phenotype, and small intestinal tuft cell-derived transcripts were found to correlate with whole body metabolic features independently of intestinal immune cell involvement. Conclusion: Our These findings point to a role for small intestinal tuft cells in systems-wide metabolic regulation.

Project description:We report the global DNA methylation status in B cells. We found that DNA demethylation occurred around gene promoters and Tet-dependent demethylation sites at the genome-wide manner. This study provides a basis for the comprehensive understanding of role of Tet2 and Tet3 in DNA demethylation-dependent regulation of transcription in B cells.