Project description:The intestine has a remarkable capacity to regenerate during homeostasis by the vigorous intestinal stem cells (ISCs) that reside in the base of the crypts. ISCs are easily impaired by DNA damage due to their active cell cycle. Intriguingly, certain cell populations possess the dedifferentiating ability to restore ISCs after ablation, although the molecular mechanisms by which these cells dedifferentiate into ISCs are largely unknown. Here, we performed single-cell RNA-seq using wild type and Phf16 knockout mice from normal or after irradiation to elucidate molecular mechanisms of Phf16 in intestinal regeneration. Our work characterizes that Phf16 is crucial for downregulating stemness in revival stem cells.

Project description:Chromatin Remodelling in Damaged Intestinal Crypts Orchestrates Redundant TGFβ and Hippo Signalling to Drive Regeneration

Project description:Intestinal polyposis, a precancerous neoplasia, results primarily from an abnormal increase in the number of crypts. Crypts contain intestinal stem cells (ISCs). Thus intestinal polyposis provides an ideal condition for studying stem cell involvement in polyp/tumor formation. Using a conditional knock-out mouse model, we found that the tumor suppressor Phosphatase of Tension homolog (PTEN) governs the proliferation rate and number of ISCs and loss of PTEN results in an excess of ISCs. In PTEN mutants, excess ISCs initiate de-novo crypt formation and crypt fission, recapitulating crypt production in fetal/neonatal intestine. Microarray studies were used to profile the changes in gene expression that occurred when PTEN was knocked out in the intestine. Keywords: Disease state analysis, genetic modification, Intestinal polyposis, PTEN mutant, Cowden disease mouse model

Project description:The currently accepted intestinal epithelial cell organization model equates crypt base columnar (CBC) cells, marked by high levels of Lgr5 expression, with the intestinal stem cell (ISC). However, recent intestinal regeneration studies have uncovered limitations of the ‘Lgr5-CBC’ model, leading to two major views: one favoring the presence of a quiescent reserve stem cell population, the other calling for differentiated cell plasticity. To test if an alternative model may help reconcile these perspectives, we studied the hierarchical organization of crypt epithelial cells in an unbiased fashion, by combining high-resolution, single-cell profiling and lineage tracing in multiple transgenic mouse models. These show that Lgr5 is not a specific ISC marker; rather, cells located in the crypt isthmus, which include Lgr5low cells, comprise the ISCs that sustain tissue homeostasis. Following irradiation or intestinal injury, surviving ISCs and progenitors, but not differentiated cells, participate in intestinal regeneration, suggesting that neither de-differentiation nor reserve stem cell populations are drivers of intestinal regeneration. Our results provide a novel viewpoint for the intestinal crypt epithelium, in which ISCs localize to the crypt isthmus, and ISC potential is restricted to stem and progenitor cells.

Project description:The weekly turnover of the intestinal epithelium is driven by multipotent, Lgr5+, crypt base columnar cells (CBCs). In response to injury, however, Lgr5+ cells are lost but then re-emerge and are required for successful recovery. How these resurgent Lgr5+ stem cells arise is unclear. We transcriptionally profiled single cells from regenerating intestinal epithelia and identified a unique cell type we term the revival stem cell (rSC). rSCs are mutually exclusive to CBCs and are distinguished by elevated expression of cell survival and DNA repair genes. In homeostasis, rSCs are extremely rare, but nevertheless give rise to all the major cell types of the intestine including crypt-villus axes. After damage rSCs display a 20-fold, Yap-dependent, transient expansion, reconstitute the Lgr5+ CBC compartment and are required to regenerate a functional intestine. These studies define a unique stem cell phenotype that is mobilized by damage to reconstitute the intestinal epithelium.

Project description:The weekly turnover of the intestinal epithelium is driven by multipotent, Lgr5+, crypt base columnar cells (CBCs). In response to injury, however, Lgr5+ cells are lost but then re-emerge and are required for successful recovery. How these resurgent Lgr5+ stem cells arise is unclear. We transcriptionally profiled single cells from regenerating intestinal epithelia and identified a unique cell type we term the revival stem cell (rSC). rSCs are mutually exclusive to CBCs and are distinguished by elevated expression of cell survival and DNA repair genes. In homeostasis, rSCs are extremely rare, but nevertheless give rise to all the major cell types of the intestine including crypt-villus axes. After damage rSCs display a 20-fold, Yap-dependent, transient expansion, reconstitute the Lgr5+ CBC compartment and are required to regenerate a functional intestine. These studies define a unique stem cell phenotype that is mobilized by damage to reconstitute the intestinal epithelium.

Project description:The intestinal epithelium undergoes DNA damage response, regenerative response and homeostasis after suffering irradiation. To understand the dynamic change of intestinal epithelium during the irrradiation recovery, we performed single cell RNA sequencing on irradiation-resistant +4 cells in homeostasis and its lineages at different time points after radiation.

Project description:The Lgr5+ intestinal stem cell, Paneth and transit-amplifying cell compartment constitute the intestinal crypt which is the constant source of differentiated epithelial cells that replenish the intestinal villi ensuring organ maintenance and regeneration. The Lgr5+ crypt-based columnar (CBC) cells have been identified as the intestinal stem cells (ISCs) and, importantly, as cells-of-origin of intestinal cancer. We used microarrays to detail the global program of gene expression in normal ISCs describing a mild downregulation of the sumoylation (post-translational modification (PTM) of proteins by SUMO) imposed by the loss of one allele of the unique E2-conjugating enzyme (Ubc9) of the pathway.

Project description:Lgr5+ crypt base columnar cells, the operational intestinal stem cells (ISCs), are thought to be dispensable for small intestinal (SI) homeostasis. Using a novel Lgr5-2A-DTR (Diphtheria Toxin Receptor) model which ablates Lgr5+ cells with near-complete efficiency and retains endogenous levels of Lgr5 expression, we show that persistent depletion of Lgr5+ ISCs in fact compromises SI epithelial integrity and reduces epithelial turnover in vivo. In vitro, Lgr5-2A-DTR SI organoids are unable to establish or survive when Lgr5+ ISCs are continuously eliminated when DT is in the media. However, transient exposure to DT at the start of culture allows organoids to form, and the rate of outgrowth reduces with increasing length of DT presence. Our results indicate that intestinal homeostasis requires a constant pool of Lgr5+ ISCs, which is supplied by rapidly reprogrammed non-Lgr5+ crypt populations when pre-existing Lgr5+ ISCs are ablated.

Project description:The rapid regeneration of the small intestinal epithelium is sustained by crypt intestinal stem cells (ISCs). Wnt/b-catenin signaling is essential for intestinal crypt homeostasis and maintenance of Lgr5+ ISC, and yet no single or combinatorial knockout of Frizzled (FZD) genes, representing Wnt receptors, has phenocopied the severe intestinal epithelial effects of Wnt signaling blockade. The elusive identification of specific Frizzled (Fzd) receptor(s) underlying homeostatic proliferation and ISC function would greatly inform therapeutic mucosal repair strategies. In prior pharmacologic studies, bioengineered antagonists that block Wnt binding to both FZD5 and FZD8 receptors induced lethal crypt and villus loss, implicating FZD5 and/or FZD8 as essential for ISCs maintenance. Here, the potential function of Fzd5 in during intestinal homeostasis was examined by epithelial-specific Fzd5 ko, which rapidly elicited lethal pan-intestinal crypt and villus loss, and by Lgr5-specific Fzd5 cKO, which strongly reduced Lgr5+ ISC while inducing their premature differentiation. In parallel, Fzd5 cKO potently repressed Wnt target gene expression, with phenotypic rescue by constitutive activation of b-catenin in vivo and confirmation upon in vitro organoid culture. Fzd5 cKO but not Fzd8 cKO in organoids ablated responsiveness to dual specificity bioengineered FZD5/FZD8-selective Wnt surrogate agonists, which reversed DSS-induced colitis phenotypes in both wild-type and Fzd8 cKO mice. Overall, our results implicate the FZD5 receptor as an essential regulator of crypt homeostasis, Lgr5+ ISCs and intestinal response to bioengineered Wnt surrogate agonists.