Project description:Preterm infants born <32 weeks gestation have abnormal microbial colonisation and dysregulated inflammation within the gut. Preterm infant-derived intestinal organoids (PIOs) represent a valuable model for investigating gut microbiome-host interactions and inflammatory responses. We optimised an inflammation model in PIO monolayers incubated within an anaerobic co-culture system that recreates the physiological oxygen gradient of the intestinal epithelium. We trialled multiple stimuli, including live and heat-killed pathobiont consortia, lipopolysaccharide (LPS) and flagellin. We found that a combination of apical LPS and basolateral flagellin, incubated for 3 hours, elicited the most robust response. This was characterised by enhanced pro-inflammatory cytokine secretion, the potential for chemokine-driven immune recruitment, TNFα and IL17C pathway signalling, shifts from NF-κB to AP-1-mediated responses, and signs of tissue remodelling. This provides a framework for appropriate study design to disentangle the impacts of microbiome-host interactions in health and disease using intestinal organoids.

Project description:To determine if intestinal derived organoids are different between preterm infants and adults

Project description:Impact of small molecules from different microbial gut community types on gene expression from preterm intestinal derived organoids

Project description:RNA-sequencing from flagellin-stimulated intestinal organoids

Project description:Chorioamnionitis (CA), resulting from intra-amniotic inflammation, is a frequent cause of preterm birth and exposes the immature intestine to bacterial toxins and/or inflammatory mediators before birth via fetal swallowing. This may affect intestinal immune development, interacting with the effects of enteral feeding and gut microbiota colonization just after birth. Using preterm pigs as model for preterm infants, we hypothesized that prenatal exposure to gram-negative endotoxin influences postnatal bacterial colonization and gut immune development. Pig fetuses were given intra-amniotic lipopolysaccharide (LPS) 3 d before preterm delivery by cesarean section, and were compared with litter-mate controls (CON) at birth and after 5 d of formula feeding and spontaneous bacterial colonization. Amniotic fluid was collected for analysis of leukocyte counts and cytokines, and the distal small intestine was analyzed for endotoxin level, morphology and immune cell counts. Intestinal gene expression and microbiota were analyzed by transcriptomics and metagenomics, respectively. At birth, LPS-exposed pigs showed higher intestinal endotoxin, neutrophil/macrophage density and shorter villi. About 1.0% of intestinal genes were affected at birth and DMBT1, a regulator of mucosal immune defense, was identified as the hub gene in the co-expression network. Genes related to innate immune response (TLR2, LBP, CD14, C3, SFTPD), neutrophil chemotaxis (C5AR1, CSF3R, CCL5) and antigen processing (MHC II, CD4) were also affected and expression levels correlated with intestinal neutrophil/macrophage density and amniotic fluid cytokine levels. On day 5, LPS and CON pigs showed similar necrotizing enterocolitis (NEC) lesions, endotoxin levels, morphology, immune cell counts, gene expressions and microbiota (except for difference in some low-abundant species). Our results show that CA markedly affects intestinal genes at preterm birth, including genes related to immune cell infiltration. However, a few days later, following the physiological adaptations to preterm birth, CA had limited effects on intestinal structure, function, gene expression, bacterial colonization and NEC sensitivity. We conclude that short-term, prenatal intra-amniotic inflammation is unlikely to exert marked effects on intestinal immune development in preterm neonates beyond the immediate neonatal period.

Project description:Intestinal microbiota colonization is important for intestinal development and health of preterm infants, especially those with extremely low birth weight. Recent studies indicated for a dynamic crosstalk between that gut microbiota and DNA methylome of host intestinal cells. Thereby, we sought to determine the epigenomic and metagenomic consequences of suppression of microbiota colonization in the intestine of preterm neonates to gain insights into biological pathways that shape the interface between the gut microbiota and the preterm intestinal cells. We examined 14 preterm piglets by comparing the conventional preterm neonates with those ones treated with oral antibiotics for genome wide DNA methylation and 16S rDNA microbiome. Our results demonstrated an extensive genome-wide DNA methylation changes in response to the suppression of intestinal microbe colonization, especially genes involved in neonatal immune response signaling and glycol-metabolism pathways were identified. Our study highlights several key genes that might predispose preterm neonates to NEC risk due to their key roles involved in the immune-metabolic networks. Our study not only provided rich omic-data to interpret molecular program in relation with microbiota-associated methylome-proteome network changes, but also confer clinical usage of key gene markers for potential early diagnostics of NEC of preterm neonates.

Project description:This dataset consists of RNA-sequencing of intestinal organoids at rest and after stimulation with the TLR5 ligand flagellin for 4 hours. The goal of this study was to understand the differential patterns of gene expression induced upon stimulation with a TLR ligand in small intestine organoids, colon organoids, and organoids that had been skewed to generate a higher proportion of Paneth cells.

Project description:The intestinal epithelium is constantly exposed to the intestinal microbiome. Here we used single cell RNA sequencing to reveal how murine small intestinal organoids and specific cell types react to stimulation with the bacterial metabolites Desaminotyrosin (DAT) and indole-3-carboxaldehyde (ICA)

Project description:Preterm birth disrupts the critical maturation of the intestinal epithelium, leading to compromised digestive and absorptive functions. This study explores the potential of mesenchymal stem cell (MSC)-derived extracellular vesicles (EVs) to promote the maturation of human preterm intestinal epithelial cells. By establishing human preterm intestinal organoids derived from the ileal tissue of a neonate born at 27 weeks gestational age, we demonstrate that treatment with EVs, particularly the EV39 line, significantly enhances the expression of adult-type enterocyte markers, including genes involved in lipid and nutrient transport, digestive enzymes, and epithelial barrier integrity. These maturation signatures were identified through reanalysis of multiple single-cell RNA sequencing (scRNA-seq) datasets, revealing distinct enterocyte differentiation trajectories and key maturation-specific gene expression profiles. Notably, these maturation effects were dependent on cystic fibrosis transmembrane conductance regulator (CFTR) activity, as CFTR inhibition reversed the observed benefits. Proteomic analysis identified FGF2 and TGFβ1 as key ligands mediating the effects of EV39. Co-treatment with FGF2 and TGFβ1 further enhanced epithelial barrier integrity and fatty acid uptake, highlighting the translational potential of EV39 or its ligands in promoting intestinal functional maturation in preterm infants.

Project description:We performed RNA sequencing to identify the role of fibroblast in the effects of tryptphan metabolites on LPS-stimulated mouse neonatal intestinal organoids.