Project description:Crypt cells (mainly stem and transit amplifying (TA) cells) in Adipfl/flpVilli-CreT (gut epithelial cell adiponectin conditioned knockout) mice exhibited stronger ability of renewal and differentiation. ScRNA-seq found that there had much more enrichment intestinal stem and TA cells in Adipfl/flpVilli-CreT mice. The renewal and development of gut epithelial cells in irradiated or DSS (dextran sulfate sodium) treated Adipfl/flpVilli-CreT mice was faster than control Adipfl/flp mice. In vitro culture gut organoid of Adipfl/flpVilli-CreT mice exhibited faster growth than those from Adipfl/flp mice.

Project description:Adiponectin regulated by IAA in Paneth cells controls renewal and differentiation of gut stem cells to maintain homeostasis of epithelial cells

Project description:Adiponectin regulated by IAA in Paneth cells controls renewal and differentiation of gut stem cells to maintain homeostasis of epithelial cells (small intestinal epithelium)

Project description:Dietary patterns and psychosocial factors, ubiquitous part of modern lifestyle, critically shape the gut microbiota and human health. However, it remains obscure how dietary and psychosocial inputs coordinately modulate the gut microbiota and host impact. Here, we show that dietary raffinose metabolism to fructose couples stress-induced gut microbial remodeling to intestinal stem cells (ISC) renewal and epithelial homeostasis. Chow diet (CD) and purified diet (PD) confer distinct vulnerability to gut epithelial injury, microbial alternation and ISC dysfunction in chronically restrained mice. CD preferably enriches Lactobacillus reuteri, and its colonization is sufficient to rescue stress-triggered epithelial injury.

Project description:Using single-cell RNA-seq of intestinal epithelial cells we identify surprising expression of MHC class II, which participates in a novel interaction between gut-resident CD4+ T cells and epithelial stem cells, governing the balance between stem cell differentiation and renewal.

Project description:Tick gut and salivary gland global gene expression change after feeding on adiponectin wildtype and knockout mice

Project description:At birth, newborns are exposed to gut microbiota, which plays a critical role in host physiology. A reduced level of microbial diversity has been associated with necrotizing enterocolitis (NEC), one of the most deadly diseases in premature infants, but the underlying disease mechanisms are still poorly understood. Although the epithelial turnover of germ free mice is significantly delayed compared to conventionally raised mice, it remains unclear how gut microbiota exposure in the early postnatal period promotes stem cell renewal and differentiation. By analyzing genetic and experimental mouse models and performing single cell analysis, we demonstrate that gut microbiota promotes stem cell differentiation through the activation of critical stromal niche components. Our single cell analysis reveals that gut microbiota controls the size and heterogeneity of macrophage populations that secrete Wnt ligands, thereby maintaining the proliferation of intestinal telocytes, a recently identified gut mesenchymal stem cell niche. We show that stem cell differentiation, when impaired by antibiotic treatment promotes NEC, while treatment with Lactobacillus, which in NEC is dramatically less abundant, rescues NEC-like pathology through the activation of macrophage and telocyte niches. Our work highlights the mechanisms of how gut microbiota-facilitate mesenchymal niche proliferation which supports stem cell differentiation in early postnatal development.

Project description:Disruptions of microbiota composition by factors such as genetics have been suggested to be critical contributing factors to the growth of the worldwide epidemics of chronic illness such as metabolic diseases. IL-35-producing regulatory B and T regulatory cells are critical regulators to these illnesses. Whether microbiota-derived metabolites can regulate these IL-35+ cells maintain elusive. Here, we found gut genetic factor Reg4 associated lactobacillus could promote the generation of IL-35+ B cells through producing 3-idoleacetic acid (IAA). HuREG4IEC tg mice had markedly accumulation of IL-35+ not only in adipose tissues but also in colon tissues; whereas significantly decreased IL-35+ cells in adipose tissues and colon tissues could be detected in Reg4 KO mice. On the mechanism, IAA-mediated IL35+ B cells was through PXR), RXR and CAR in the presence of LPS. PXR KO, CAR KO and NF-B KO mice impaired the generation of IAA- IL-35+B cells. Interestingly, lower levels of IAA and IL-35 were also detected in the peripheral blood of individuals with obesity. Thus, IAA is a factor to promote the generation of IL-35+B cells to impede the development of obesity.

Project description:Background & Aims: Hierarchical organization of intestine relies on their stem cells by self-renew and producing committed progenitors. Although signals like Wnt are known to animate the continued renewal by maintaining intestinal stem cells (ISCs) activity, molecular mechanisms especially E3 ubiquitin ligases that modulate ISCs ‘stemness’ and supportive niche have not been well understood. Here, we investigated the role of Cullin 4B (Cul4b) in regulating ISC functions. Methods: We generated mice with intestinal epithelial-specific disruption of Cul4b (pVillin-cre; Cul4bfn/Y), inducible disruption of Cul4b (Lgr5-creERT2; Cul4bfn/Y, CAG-creERT2; Cul4bfn/Y) and their control (Cul4bfn/Y). Intestinal tissues were analyzed by histology, immunofluorescence, RNA sequencing and mass spectrum. Intestinal organoids deprived from mice with pVillin-Cre; Cul4bfn/Y, Lgr5-Cre; Cul4bfn/Y, Tg-Cul4b and their controls were used in assays to measure intestinal self-renewal, proliferation and differentiation. Wnt signaling and intestinal markers were analyzed by immunofluorescence and immunoblot assays. Differential proteins upon Cul4b ablation or Cul4b-interacting proteins were identified by mass spectrometry. Results: Cul4b specifically located at ISCs zone. Block of Cul4b impaired intestinal homeostasis maintenance by reduced self-renewal and proliferation. Transcriptome analysis revealed that Cul4b-null intestine lose ISC characterization and showed disturbed ISC niche. Mechanistically, reactivated Wnt pathway could recover intestinal dysfunction of Cul4b knockout mice. Analysis of differential total and ubiquitylated proteins uncovered the novel targeting substrate of Cullin-Ring ubiquitin ligase 4b (CRL4b), immunity-related GTPase family M member 1 (Irgm1) in intestine. Decreased Irgm1 rescued abnormally interferon signaling, overemphasized autophagy and downstream phosphate proteins in Cul4b knockout mice. Conclusion: We conclude that Cul4b is essential for ISC self-renewal and Paneth cell function by targeting Irgm1 and modulating Wnt signaling. Our results demonstrate that Cul4b is a novel ISC stemness and niche regulator.

Project description:Self-renewal circuitry in embryonic stem (ES) cells is increasingly defined. How the robust pluripotency programme is dissolved to enable fate transition is less appreciated. We developed a forward genetic approach using haploid ES cells. We created libraries of transposon integrations and screened for persistent self-renewal in differentiation permissive culture. This yielded multiple mutants in the FGF/Erk and GSK3/Tcf3 modules known to drive differentiation, and in epigenetic modifiers implicated in lineage commitment. We also identified and validated factors not previously considered. These include the conserved small zinc finger protein Zfp706. Loss of Zfp706 function severely delays the exit from self-renewal. To asses a potential function of Zfp706 in regulation of gene expression we compared transcription profiles between Zfp706 gene trap mutant ES cells and genetic revertants. Assessment of differentially expressed genes in Zfp706 gene trap mutants obtained in a haploid ES cell screen for effectors of ES cell differentiation vs. genetic revertants generated by Flp-e mediated excision of the gene trap cassette