Project description:The small intestinal epithelium is composed of several defined epithelial cell lineages, which in turn exhibit marked transcriptional and functional diversity along the crypt-villus and proximal-to-distal length of the intestinal tract. While epithelial cell type and functional heterogeneity have been characterized in the adult intestinal epithelium, the temporal and spatial changes during the postanatal period, which accompany the transition from placental energy supply to enteral feeding and facilitate the establishment of the enteric microbiota and postnatal immune maturation, have not been systematically investigated. Here, we analyzed the small intestinal epithelium of 1-, 5-, 10- and 25-day-old SPF mice by single cell RNA-Seq and used differential gene expression and pathway analysis to identify age-specific expression patterns. In addition, the influence of enteric infection on the neonatal epithelium was investigated. We identify gene clusters temporally expressed in the neonatal intestine and correlate their expression with the functional changes during postnatal tissue maturation and the neonate to adult transition.

Project description:The small intestinal epithelium is composed of several defined epithelial cell lineages, which in turn exhibit marked transcriptional and functional diversity along the crypt-villus and proximal-to-distal length of the intestinal tract. While epithelial cell type and functional heterogeneity have been characterized in the adult intestinal epithelium, the temporal and spatial changes during the postanatal period, which accompany the transition from placental energy supply to enteral feeding and facilitate the establishment of the enteric microbiota and postnatal immune maturation, have not been systematically investigated. Here, we analyzed the proximal, medial and distal parts of the small intestinal epithelium of 1-, 5-, 10- and 25-day-old SPF mice by bulk RNA-Seq and used differential gene expression and pathway analysis to identify age-specific expression patterns. We identify gene clusters temporally expressed in the neonatal intestine and correlate their expression with the functional changes during postnatal tissue maturation and the neonate to adult transition.

Project description:The small intestinal epithelium is composed of several defined epithelial cell lineages, which in turn exhibit marked transcriptional and functional diversity along the crypt-villus and proximal-to-distal length of the intestinal tract. While epithelial cell type and functional heterogeneity have been characterized in the adult intestinal epithelium, the temporal and spatial changes during the postnatal period, which accompany the transition from placental energy supply to enteral feeding and facilitate the establishment of the enteric microbiota and postanatal immune maturation, have not been systematically investigated. Here, we analyzed microdissected crypt and villus structures of 1-, 5-, 10-, and 25-day-old SPF mice by 3'mRNA-Seq and used differential gene expression and pathway analysis to identify age-specific expression patterns. We identify gene clusters temporally expressed in the neonatal intestine and correlate their expression with the functional changes during postnatal tissue maturation and the neonate to adult transition.

Project description:Postnatal establishment of enteric metabolic, host-microbial and immune homeostasis is the result of precisely timed and tightly regulated developmental and adaptive processes. Here, we show that infection with the invasive enteropathogen Salmonella Typhimurium results in a Myd88-dependent accelerated maturation of the neonatal epithelium with premature appearance of antimicrobial, metabolic, developmental, and regenerative features of the adult tissue.

Project description:Ischemic damage to the intestinal epithelial barrier, such as in necrotizing enterocolitis or small intestinal volvulus, is associated with higher mortality rates in younger patients. We have recently reported a powerful pig model to investigate these age-dependent outcomes in which mucosal barrier restitution is strikingly absent in neonates but can be rescued by direct application of homogenized mucosa from older, juvenile pigs by a yet-undefined mechanism. Within the mucosa, a postnatally developing network of enteric glial cells (EGC) is gaining recognition as a key regulator of the mucosal barrier. Therefore, we hypothesized that the developing EGC network may play an important role in coordinating intestinal barrier repair in neonates. Neonatal and juvenile jejunal mucosa recovering from surgically induced intestinal ischemia was visualized by scanning electron microscopy and the transcriptomic phenotypes were assessed by bulk RNA sequencing. EGC network development was examined by gene set enrichment analysis, three-dimensional volume imaging and western blot and its function in regulating epithelial restitution assessed ex vivo in Ussing chamber using the glia-specific inhibitor fluoroacetate, and in vivo in co-culture assays. Here we refine and elaborate our translational model, confirming a neonatal phenotype characterized by a complete lack of coordinated reparative signaling in the mucosal microenvironment. Further, we report important evidence that the subepithelial EGC network changes significantly over the early postnatal period and demonstrate that EGC function in close proximity to wounded intestinal epithelium is critical to intestinal barrier restitution following ischemic injury. 

Project description:The intestinal epithelium is the first line of defence against invasive enteric pathogens. Removal of infected cells by exfoliation prevents mucosal translocation and systemic infection in the adult host, but is less commonly observed in the neonatal small intestine. Instead, here we describe non-professional efferocytosis of Salmonella-infected enterocytes by neighbouring intestinal epithelial cells in the neonatal intestine. Intestinal epithelial stem cell organoid co-cultures of neonatal and adult cell monolayers with damaged enterocytes replicated this observation, confirmed the age-dependent ability of intestinal epithelial cells for efferocytosis and identified the critical involvement of the 'eat-me' signals and adaptors phosphatidylserine and C1q as well as the 'eat-me' receptors integrin-v (CD51) and CD36 in cellular uptake. Consistent with this, massive epithelial cell membrane protrusions and CD36 accumulation at the contact site with apoptotic cells were observed in the infected neonatal host in vivo. Efferocytosis of infected small intestinal enterocytes by neighbouring epithelial cells may represent a previously unrecognised mechanism of neonatal antimicrobial host defense to maintain barrier integrity.

Project description:Villin-Cre+ Lsd1fl/fl (cKO) mice display an immature intestinal epithelium characterized by an incomplete differentiation of enterocytes and secretory lineages, reduced number of goblet cells and a complete loss of Paneth cells. This experiment aims to elucidate the differences in stool microbial composition derived from WT (Villin-Cre- Lsd1fl/fl) and cKO mice both in adult (2-month-old) and neonatal (14 days postpartum P14) stages. Different timepoints are crucial to understand the role of intestinal maturation in microbiome composition since said maturation is dependent on time-dependent external cues happening at P14-21 (weaning and transition from milk to solid foods).

Project description:Background: The neonatal (D14-17) murine small intestinal epithelium is enriched for Vγ7+ IEL displaying an ‘immature’ CD122LO cell surface phenotype. We believe these cells are precursors for signature CD122HI Vγ7+ IEL that predominate among small intestinal IEL from postnatal D21. Method: To further characterise this potential precursor-product relationship, CD122hi Vg7+ and CD122lo Vg7+ IEL were purified from individual D14-D17 mice on four independent occasions and compared by total RNAseq. Conclusion: ~3000 genes are differentially expressed between CD122HI and CD122LO murine Vg7+ neonatal IEL

Project description:In many mammalian species, the intestinal epithelium is immature at birth. During the suckling to weaning transition, the intestine matures. This developmental transition is the result of a genetic program that is intrinsic to the gut and independent of luminal content, but its regulators have not been identified. We investigated the function of the transcriptional repressor Blimp-1 using mice with intestine-specific ablation of Blimp-1. Deletion of Blimp-1 results in growth retardation and excess neonatal mortality. Mutant mice lack all typical epithelial features of the suckling period and are born with features of adult-like intestine. To assess the function of the gene Prdm1 (Blimp) on postnatal day 7 intestinal epithelium, VillinCre-Blimpflox and control (VillinCre-Blimpwt or Cre-Blimpflox) mice were generated. Mice were sacrificed at day 7 postnatal, and pieces of whole mid-intestine were taken for analysis.

Project description:Background: Recently have found that Btnl1 expressed by murine enterocytes shapes the local TCR-Vγ7+ compartment by driving their clonotypic expansion and phenotypic maturation from CD122LO to CD122HI Vγ7+ cells. The neonatal (D14-17) murine small intestinal epithelium is enriched for Vγ7+ IEL displaying an â??immatureâ?? CD122LO cell surface phenotype. We believe these cells are precursors for CD122HI Vγ7+ IEL. Method: To further characterise this putative product-progenitor relationship, CD122hi Vg7+ and CD122lo Vg7+ IEL were purified from individual D14-D17 mice on four independent occasions and compared by total RNAseq. Conclusion: >3000 genes are differentially expressed between CD122HI and CD122LO murine Vg7+ neonatal IEL 4 independent Paired samples of CD122hi Vg7+ and CD122lo Vg7+ IEL were purified from the small intestinal epithelium of pooled 14-17 day old mice. RNA was isolated from sorted samples. Gene expression analysis was performed by total RNAseq.