Project description:Necrotizing enterocolitis (NEC) is the most frequent life-threatening gastrointestinal disease experienced by premature infant occuring in neonatal intensive care units. NEC is associated with severe intestinal inflammation, intestinal perforation leading to mortality. The challenge for neonatologists is to detect early clinical manifestations of NEC. Therefore, one of the strategies to prevent or treat NEC would be to develop an early diagnostic tool allowing identification of preterm infants either at risk of developing NEC or at the onset of the disease. Illumina’s deep sequencing technology (RNA-seq) was used to establish the gene expression profile between resected ileal healthy preterm (control, n=5) and NEC diagnosed preterm infant (NEC, n=9) and analyzed by IPA Core analysis system. IPA analysis indicated that the most significant functional pathways overrepresented in NEC neonates were associated with innate immune functions, such as altered T and B cell signaling, B cell development, and the role of pattern recognition receptors in recognition of bacteria and viruses. Among genes that were strongly modulated in NEC neonates, we observed a high degree of similarity with those linked to the development of IBD. By comparing gene expression patterns between NEC and Crohn’s disease, we identified several new potential protein targets for helping to predict and/or diagnose NEC in preterm infant. Gene expression profile revealed an uncontrolled innate immune response in the intestine of NEC neonates. Moreover, comparative analysis between NEC and Crohn’s disease evidenced high degree of similarity between these two inflammatory diseases and allowed us to identify several new potential NEC biomarkers.

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:Necrotizing enterocolitis (NEC) is an acute gut inflammatory disorder that mainly affects preterm neonates. A large proportion of NEC survivors develop neuronal deficits later in life, however the effect of early stages of NEC on the developing brain is unknown. Using preterm pigs as a NEC-sensitive animal model, we profiled the hippocampal gene expression in response to severe NEC lesions. The NEC-induced differentially expressed genes (DEGs) in the hippocampus segregated the piglets suffering from small intestinal NEC (Si-NEC) from those showing NEC lesions only in the colon (Co-NEC). Only when NEC lesions were observed in the small intestine, did piglets show reduced physical activity together with up-regulation of hippocampal genes related to inflammation and hypoxia, which was further verified by qPCR. Cluster analyses revealed key hippocampal NEC–related DEGs for Si-NEC (23 genes, including S100A8, PDK4, EDN1, IER3, Opalin, TXNIP) and Co-NEC (3 genes: GSTM3, TF, and S100A1). Both NEC phenotypes showed only two down-regulated DEGs (TMEM 167, HBB) and were devoid of any histological signs of microglia activation. Cerebrospinal fluid (CSF) from NEC-positive pigs contained elevated levels of several inflammatory proteins and in vitro exposure of immature hippocampal neurons to NEC-related CSF promoted neuritogenesis. Further in vitro experiments with neurite outgrowth indicated that VEGF, CINC-3, S100A9 and S100A8/S100A9 may play a role in NEC effects on hippocampal development. In conclusion, NEC lesions, especially when involving the small intestine, alter hippocampal gene expression with potential neuroinflammation and effects on neural circuit formation. Our results demonstrated that gut lesions affect the immature brain at early stages of disease progression. Thus, supportive care is important for preterm infants experienced with NEC to lessen possible later neurological dysfunctions.

Project description:Preterm neonates are susceptible to gastrointestinal (GI) disorders such as necrotizing enterocolitis (NEC). Maternal milk, and especially colostrum, protects against NEC via growth promoting, immunomodulatory and antimicrobial factors. The fetal enteral diet, amniotic fluid (AF), contains similar bioactive components and we hypothesized that postnatal AF administration would reduce inflammatory responses and NEC in preterm neonates. Thirty preterm pigs (92% gestation) were delivered by caesarean section and fed total parental nutrition (TPN) for 48 h followed by enteral porcine colostrum (COLOS, n=7), infant formula (FORM, n=13) or formula + porcine AF (AF, n=10). Using a previously validated model of NEC in preterm pigs, we determined the structural, functional, microbiological and immunological responses to AF when administered prior to and after introduction of a suboptimal enteral formula diet. Keywords: Healthy versus inflammed tissues in relation to necrotizing enterocolitis Pigs from each treatment group (COLOS, n=4; FORM, n=6; and AF, n=7) were randomly selected for microarray analysis of frozen distal small intestine samples. The FORM group was further divided into formula-fed healthy pigs (F-HEA, n=3) and formula-fed NEC pigs (F-NEC, n=3) in order to compare sick versus healthy formula fed pigs. Equal amounts of total distal small intestinal RNA from all pigs were pooled to make the reference sample. Samples and reference pool were labelled with Oyster 550 and 650, respectively. The in-house spotted porcine oligonucleotide microarray version 4 (POM4) is a low density microarray consisting of 384 different oligonucleotide probes representing more than 200 different immune related genes.

Project description:Necrotizing enterocolitis (NEC) is the most common and lethal gastrointestinal disease affecting preterm infants. NEC develops suddenly and is characterized by gut barrier destruction, an inflammatory response, intestinal necrosis and multi-system organ failure. There is currently no method for early NEC detection, and the pathogenesis of NEC remains unclear.

Project description:Most hospitalized preterm infants receive antibiotics (AB) in the first days of life to treat or prevent systemic infections. Short-term, early AB treatment may also prevent against the microbiota-dependent serious gut disorder, necrotising enterocolitis (NEC). However, it remains a challenge to predict or early detection of NEC in the first weeks of life and few diagnostic markers exist. Using preterm piglets as models for infants, we hypothesised that proteomic profiling could be used to identify new early plasma biomarkers of NEC with or without prior AB treatment. Preterm newborn pigs were treated with saline (CON) or antibiotics (ampicillin, gentamicin, and metronidazole), given enterally (ENT) or parenterally (PAR), and fed formula for four days to induce NEC. The gut was collected for scoring of NEC lesions and blood was collected for haematology and plasma proteomics

Project description:Necrotizing enterocolitis (NEC) is an acute and life-threatening gastrointestinal disorder afflicting preterm infants, which is currently unpreventable. Fecal microbiota transplantation (FMT) is a promising preventative therapy, but potential bacterial infection raise concern. Removal of bacteria from donor feces may reduce this risk while maintaining the NEC-preventive effects. We aimed to assess preclinical efficacy and safety of bacteria-free fecal filtrate transfer (FFT). Using fecal material from healthy suckling piglets, we administered FMT rectally, or cognate FFT either rectally or oro-gastrically to formula-fed preterm, cesarean-delivered piglets as a model for preterm infants, We compared gut pathology and related safety parameters with saline controls, and analyzed ileal mucosal transcriptome to gauge the host e response to FMT and FFT treatments relative to control. Results showed that oro-gastric FFT prevented NEC, whereas FMT did not perform better than control. Moreover, FFT but not FMT reduced intestinal permeability, whereas FMT animals had reduced body weight increase and intestinal growth. Global gene expression of host mucosa responded to FMT but not FFT with increased and decreased bacterial and viral defense mechanisms, respectively. In conclusion, as preterm infants are extremely vulnerable to enteric bacterial infections, rational NEC-preventive strategies need incontestable safety profiles. Here we show in a clinically relevant animal model that FFT, as opposed to FMT, efficiently prevents NEC without any recognizable side effects. If translatable to preterm infants, this could lead to a change of practice and in turn a reduction in NEC burden.

Project description:We hypothesized that the immature pig intestine would be highly sensitive to gene methylation changes in the immediate prenatal and neonatal periods. We performed a Reduced Representation Bisulfite Sequencing (RRBS) to assess the DNA methylation differences occurring during the last 10 days prenatally (PN, 0d-term vs. 0d-preterm), neonatally after 4 days (NN, 4d-preterm vs. 0d-preterm) and after NEC development (4d-preterm-NEC vs. 4d-preterm) in pigs (each group n=2-3). Differentially methylated gene regions (DMRs) between the groups were identified, subjected to KEGG (Kyoto Encyclopedia of Genes and Genomes) pathway analysis and selected genes were chosen for further validation of gene expression levels by RT-PCR (n= 6 for each group). Consistent with the need to increase expression of many intestinal genes in the perinatal period, methylation levels of most genes decreased during the prenatal and neonatal periods. We identified four intestinal genes (CYP2W1, GPR146, TOP1MT, CEND1), related to intestinal metabolism, that were significantly hyper-methylated in their promoter CGIs, and transcriptionally down-regulated in the 4 d-old preterm pigs. This down-regulation of intestinal metabolism may predispose to intestinal dysfunction and NEC. The first enteral feeds and bacterial colonization are critical factors for NEC sensitivity and it remains to be investigated whether these factors affect intestinal gene methylation and thereby predispose to, or prevent from, disease more long term.

Project description:Preterm neonates are susceptible to gastrointestinal (GI) disorders such as necrotizing enterocolitis (NEC). Maternal milk, and especially colostrum, protects against NEC via growth promoting, immunomodulatory and antimicrobial factors. The fetal enteral diet, amniotic fluid (AF), contains similar bioactive components and we hypothesized that postnatal AF administration would reduce inflammatory responses and NEC in preterm neonates. Thirty preterm pigs (92% gestation) were delivered by caesarean section and fed total parental nutrition (TPN) for 48 h followed by enteral porcine colostrum (COLOS, n=7), infant formula (FORM, n=13) or formula + porcine AF (AF, n=10). Using a previously validated model of NEC in preterm pigs, we determined the structural, functional, microbiological and immunological responses to AF when administered prior to and after introduction of a suboptimal enteral formula diet. Keywords: Healthy versus inflammed tissues in relation to necrotizing enterocolitis

Project description:Necrotizing enterocolitis (NEC) is a devastating intestinal inflammatory disorder that primarily affects premature infants. Despite decades of research, this disease remains a significant cause of death in the absence of efficient therapeutics. Interleukin (IL)-22 has been shown to play a critical role in maintaining the gut barrier, promoting epithelial regeneration, and controlling intestinal inflammation in adult animal models with an established microbiome. However, the importance of IL-22 signaling in the regulation of gut homeostasis and protection in neonates that lack an established microbiome remains unknown. Therefore, the aim of the current study is to investigate the role of IL-22 in the neonatal intestinal epithelium under homeostatic and inflammatory conditions by using a mouse model of NEC. Our data reveal that Il22 expression in neonatal murine intestine is negligible until weaning. In addition, both human and murine neonates lack IL-22 production during NEC. Mice deficient in IL-22 or mice lacking the expression of IL-22 receptor in intestinal epithelial cells, display a similar susceptibility of neonates to NEC consistent with the lack of endogenous IL-22 at this critical stage of intestinal development. Conversely, treatment with recombinant IL-22 during NEC substantially reduces disease severity. This IL-22-mediated protection is associated with enhanced epithelial regeneration and increased expression of several antimicrobial genes. Strikingly, despite an IL-22-mediated induction of an antimicrobial transcriptional program, the composition of the intestinal microbial communities remains unchanged. Taken together, this study demonstrates that an IL-22 signaling axis promotes protection against neonatal NEC through the induction of epithelial cell regeneration.