Project description:The epithelium that lines small intestinal villi is critically important for nutrient absorption, defense against pathogens, and mucosal homeostasis. Atrophy or blunting of the villi as a result of epithelial damage is commonly observed in celiac disease, viral gastroenteritis, and various other pathologies. Whereas adaptive responses during epithelial stem cell injury are increasingly well understood, how epithelial tissues, and particularly the intestine, cope with drastic loss of differentiated cells remains unclear. Using an acute model of viral gastroenteritis induced by poly(I:C), we aimed to dissect the cellular adaptations that follow severe intestinal villus injury.

Project description:The epithelium that lines small intestinal villi is critically important for nutrient absorption, defense against pathogens, and mucosal homeostasis. Atrophy or blunting of the villi as a result of epithelial damage is commonly observed in celiac disease, viral gastroenteritis, and various other pathologies. Whereas adaptive responses during epithelial stem cell injury are increasingly well understood, how epithelial tissues, and particularly the intestine, cope with drastic loss of differentiated cells remains unclear. Using an acute model of viral gastroenteritis induced by poly(I:C), we aimed to dissect the cellular adaptations that follow severe intestinal villus injury.

Project description:To assess the role of LSD1 in mouse small intestinal epithelium, we isolated small intestinal crypts and villus from wild type (WT) (Villin-Cre -; Lsd1f/f) and intestinal-epithelial-specific knock-out (cKO) (Villin-Cre+; Lsd1f/f) mice. This experiment uses a new Cre strain with 100% deletion efficiency. RNA was directly isolated from intestinal crypt and villus, and this was used for RNAseq. Gene expression analysis of cKO derived crypt and villus provides a spatially restricted outlook on the maturation status of the intestinal epithelium in the villi and the absence of Paneth cells in the crypt.

Project description:To assess the role of LSD1 in mouse small intestinal epithelium, we isolated small intestinal crypts and villus from wild type (WT) (Villin-Cre -; Lsd1f/f) and intestinal-epithelial-specific knock-out (cKO) (Villin-Cre+; Lsd1f/f) mice. This experiment uses a new Cre strain with 100% recombination efficiency. RNA was directly isolated from the crypt and villus, and this was used for RNAseq. Gene expression analysis of cKO derived crypt and villus provides a spatially restricted outlook on the maturation status of the intestinal epithelium in the villi and the absence of Paneth cells in the crypt. Additionally, these mice were treated with antibiotics to study epithelium intrinsic changes related to LSD1 deletion but independent of the bacterial microbiome.

Project description:We conditionally inactivated mouse Cdx2, a dominant regulator of intestinal development, and mapped its genome occupancy in adult intestinal villi. Although homeotic transformation, observed in Cdx2-null embryos, was absent in mutant adults, gene expression and cell morphology were vitally compromised. Lethality was accelerated in mice lacking both Cdx2 and its homolog Cdx1, with exaggeration of defects in crypt cell replication and enterocyte differentiation. Cdx2 occupancy correlated with hundreds of transcripts that fell but not with equal numbers that rose with Cdx loss, indicating a predominantly activating role at intestinal cis-regulatory regions. Integrated consideration of a mutant phenotype and cistrome hence reveals the continued and distinct requirement in adults of a master developmental regulator that activates tissue-specific genes. Cdx2 ChIP-seq in mouse villus, and gene expression data from Cdx1, Cdx2 and compound knockout mouse intestine

Project description:Genes encoding transcription factors function as hubs in gene regulatory networks because they encode DNA-binding proteins, which bind to promoters that carry their binding sites. In the present work we have studied gene regulatory networks defined by genes with transcripts belonging to different mRNA abundance classes in the small intestinal epithelial cell. The focus is the rewiring that occurs in transcription factor hubs in these networks during the differentiation of the small intestinal epithelial cell while it migrates along the crypt-villus axis and during its development from a fetal endodermal cell to a mature adult villus epithelial cell. We have generated transcriptome data for mouse small intestinal villus, crypt and fetal intestinal epithelial cells. In addition we have generated metabolome data from crypt and villus cells. Our results show that the intestinal crypt transcription factor hubs that are rewired during differentiation are involved in the cell cycle process (E2F, NF-Y) and stem cell maintenance (c-Myc). In contrast the villi are dominated by a HNF-4 villus hub, which is rewired during differentiation by the addition of network genes with relevance for lipoprotein synthesis and lipid absorption. Moreover, we have identified a villus NF-kB hub, which was revealed by comparison of the villus and endoderm transcriptomes. The rewiring of the NF-kB villus hub during intestinal development reflects transcriptional activity established by host and microflora interactions. To aid in the mining of our results we have developed a web portal (http://gastro.imbg.ku.dk/mousecv/) allowing easy linkage between the transcriptomic data, biological processes and functions. Experiment Overall Design: Four different sample categories were analyzed. Experiment Overall Design: 1) Small intestinal crypts isolated form 12-weeks old C57BL/6 mice. These samples are in triplicates. Experiment Overall Design: 2) Small intestinal villi isolated form 12-weeks old C57BL/6 mice. These samples are in triplicates. Experiment Overall Design: 3) Embryonic day 12 mesenchyme. These samples are in quadruplicate. each sample is derived from a pool of mesenchymes (10-40) Experiment Overall Design: 4) Embryonic day 12 endoderm. These samples are in quadruplicate. each sample is derived from a pool of endoderms (10-40)

Project description:Small intestinal villi are highly specialized structural and functional units uniquely adapted to the absorption of nutrients in higher vertebrates. Intestinal villus enterocytes are organized in spatially resolved “zones” dedicated to specialized tasks, such as anti-bacterial protection, and absorption of amino-acids, carbohydrates and lipids. However, the molecular mechanisms for the establishment and maintenance of villus intestinal epithelial zonation are incompletely understood. Here, we show that transcription factor C-Maf is highly expressed in mature lower and mid-villus small intestinal enterocytes, where it is induced in response to BMP signaling. In vivo depletion of C-Maf in the adult enterocytes perturbed the villus epithelial zonation transcriptional program and enhanced the expression of genes involved in carbohydrate metabolism and bile acid regulation and transport, while suppressing genes related to amino acid transport and lipid metabolism. Loss of C-Maf under homeostatic conditions had no effect on body weight due to compensatory small intestinal remodeling, accompanied by increased generation of tuft cells and goblet cell hyperplasia. However, upon challenge with anti-metabolite therapy, C-Maf inactivation impaired body weight recovery, resulting in reduced survival, due to delayed enterocyte maturation. Our results identify a novel role for C-Maf in maintaining the zonation program of differentiated intestinal epithelium, by balancing absorptive versus secretory cell differentiation in the small intestine, while highlighting the importance of coordination between stem/progenitor cell and enterocyte differentiation programs for intestinal regeneration.

Project description:Krüppel-like factor 9 (Klf9), a zinc-finger transcription factor, is implicated in the control of cell proliferation, cell differentiation and cell fate in brain and uterus. Using Klf9 null mutant mice, we have investigated the involvement of Klf9 in small intestine crypt-villus cell renewal and lineage determination. We report the predominant expression of Klf9 gene in small intestine smooth muscle (muscularis externa). Jejunums null for Klf9 have shorter villi, reduced crypt stem/transit cell proliferation, and altered lineage determination as indicated by decreased and increased numbers of Goblet and Paneth cells, respectively. A stimulatory role for Klf9 in villus cell migration was demonstrated by BrdU labeling. Results suggest that Klf9 controls the elaboration, from small intestine smooth muscle, of molecular mediator(s) of crypt cell proliferation and lineage determination, and of villus cell migration. Keywords: Genetic modification

Project description:Differentiation and specialisation of epithelial cells in the small intestine is regulated in two ways. First, there is differentiation along the crypt-villus axis of the intestinal stem cells into absorptive enterocytes, Paneth, goblet, tuft, enteroendocrine or M-cells, which is mainly regulated by WNT. Second, there is specialization along the cephalocaudal axis with different absorptive and digestive functions in duodenum, jejunum and ileum that is controlled by several transcription factors such as GATA4. However, so far it is unknown whether location-specific functional properties are intrinsically programmed within stem cells or if continuous signalling from mesenchymal cells is necessary to maintain the location-specific identity of the small intestine. By using the pure epithelial organoid technique, we show that region-specific gene expression profiles are conserved throughout long-term cultures of both mouse and human intestinal stem cells and correlated with differential Gata4 expression. Furthermore, the human organoid culture system demonstrates that Gata4-regulated gene expression is only allowed in absence of WNT signalling. These data show that location-specific function is intrinsically programmed in the adult stem cells of the small intestine and that their differentiation fate is independent of location-specific extracellular signals. In light of the potential future clinical application of small intestine-derived organoids, our data imply that it is important to generate GATA4-positive and GATA4-negative cultures to regenerate all essential functions of the small intestine. RNA sequencing of intestinal crypts, villi and cultured organoids derived from mouse duodenum, jejunum and ileum

Project description:Expression profiles obtained from the villus and crypt layers of murine large intestine can elucidate the process of differentiation undergone by epithelial cells as they migrate from the undifferentiated bottom of the crypt to the villus tip before being shed into the intestinal lumen. This series includes profiles from wild type mice, as well as mice harboring mutations in genes (APC and p21) which play key roles in the differentiation process. We used microarrays to characterize gene expression profiles at the base of the crypt and at the villus tip of the lumenal layer of the large intestine in order to better understand the process of differentiation and eventual shedding undergone by cells of the large intestinal epithelium. Four wild type, four APC1638+/- and four p21-/- mice were sacrified and the large intestines dissected out. Cells from the villus tip and from the bottom of the crypt were isolated from the lumenal face of the each large intestine using the Weiser method of sequential elution. RNA was extracted from each eluted sample and used to hybridize to Affymetrix 3' expression arrays.