Project description:Enteric helminths form intimate physical connections with the intestinal epithelium, yet their ability to directly alter epithelial stem cell fate has not been resolved. Here we demonstrate that infection of mice with the symbiotic parasite Heligmosomoides polygyrus bakeri (Hpb), reprograms the intestinal epithelium into a fetal-like state marked by the emergence of Clusterin-expressing revival stem cells (revSCs). Organoid-based studies using parasite-derived excretory/secretory products reveal that Hpb-mediated revSC generation occurs independent of host-derived immune signals and inhibits type 2 cytokine-driven differentiation of secretory epithelial lineages that promote their expulsion. Reciprocally, type 2 cytokine signals limit revSC differentiation and, consequently, Hpb fitness indicating that helminths compete with their host for control of the intestinal stem cell niche to promote continuation of their life cycle.

Project description:Enteric helminths form intimate physical connections with the intestinal epithelium, yet their ability to directly alter epithelial stem cell fate has not been resolved. Here we demonstrate that infection of mice with the symbiotic parasite Heligmosomoides polygyrus bakeri (Hpb), reprograms the intestinal epithelium into a fetal-like state marked by the emergence of Clusterin-expressing revival stem cells (revSCs). Organoid-based studies using parasite-derived excretory/secretory products reveal that Hpb-mediated revSC generation occurs independent of host-derived immune signals and inhibits type 2 cytokine-driven differentiation of secretory epithelial lineages that promote their expulsion. Reciprocally, type 2 cytokine signals limit revSC differentiation and, consequently, Hpb fitness indicating that helminths compete with their host for control of the intestinal stem cell niche to promote continuation of their life cycle.

Project description:Gene expression profile of dendritic cells (DC) of mesenteric lymph node (mLN) and lamina propria of small intestine (SI-LP) of control mice and mice lacking RelB expression in DCs at steady state, four days and 14 days after infection with Heligmosomoides polygyrus bakeri (Hpb) Dendritic cells (DCs) are crucial for initiating protective immune responses and have also been implicated in the generation and regulation of Foxp3+ regulatory T cells (Tregs). Specific DC subsets or DC-intrinsic pathways regulate immunity against pathogens but also tolerance to harmless antigens derived from food or microbiota at barrier sites, but underlying mechanisms in the intestinal tract remain poorly defined. Here, we provide evidence that the alternative NF-B family member RelB controls a defined transcriptional program in migratory DC subsets of mesenteric lymph nodes and the small intestinal lamina propria. Functionally, ablation of RelB in dendritic cells result in increased Foxp3+ Treg cell numbers but decreased RORt peripheral Treg cell numbers maintained even under inflammatory conditions. Single-cell RNA-sequencing revealed a complete RelB dependency for the differentiation of cryptopatches and isolated lymphoid follicles-associated DCs (CIA-DCs) in the lamina propria of the small intestine. In addition, we show a RelB-dependent signature of migratory DCs in mesenteric lymph nodes favoring DC-Treg cell interaction by affecting the expression of chemokines (Ccl22, Ccl17), migration behavior (Cd63), co-stimulatory molecule (Cd80, Cd40, Cd200, Tnfsf4), and tolerance-related integrin (Itgb5, Itgb8) expression. Functionally, increased Treg cell numbers in DC-specific RelB knockout animals did not show any risk of increased reactions in a model of food allergy but instead prevented protective Th2 immune responses in the intestines after infection with Heligmosomoides polygyrus bakeri despite their slight steady-state type 2 immune bias. This protection was dependent on elevated Treg cell frequencies during primary infection as a result of bystander immune tolerance. Thus, RelB expression in conventional DCs acts as a rheostat to establish a tolerogenic set point that is maintained even during infection and strong type 2 immune conditions and thereby is a key regulator of intestinal homeostasis.

Project description:Transcriptome analysis of Intestinal epithelial cells after Heligmosomoides polygyrus bakeri (Hpb) infection

Project description:Vitamin D is widely reported to inhibit innate immune signalling and dendritic cell (DC) maturation, leading to attenuation of DC mediated T cell activation as a potential immunoregulatory mechanism to guard against autoimmunity and immmunopathology. It is not known whether vitamin D has global or gene specific effects on transcriptional responses downstream of innate immune stimulation. In order to address this question, we used genome-wide transcriptional profiling of monocyte derived DC differentiated in the presence and absence of vitamin D, and then stimulated with and without lipopolysaccharide for four hours.

Project description:RNAseq on intestinal epithelial cells 24hrs after Hpb inoculation in WT- villinCre and VillinCre-A2BARfl/fl mice

Project description:Here, using single-cell sequencing we identified an MK derived immunoregulatory cell population, which plays an important role in host-protective responses against bacteria. In contrast to platelet-generating MKs, MK derived immunoregulatory cells highly express immune response genes and chemokines.

Project description:Francisella tularensis is a highly infective Gram-negative bacterium, also known as the causative agent of tularemia. The disease is characterized by the delayed onset of the adaptive immune response which provides time for the bacterial replication. As an intracellular pathogen, Francisella proliferates mainly in the cytosol of host phagocytes, which are linkers between the innate and the adaptive immunity. In particular, dendritic cells (DCs) are known to be the most effective antigen-presenting cells and thus they are crucial for the induction of the adaptive response. However, Francisella is able to invade and to proliferate inside DCs while avoiding their effective activation and maturation. The goal of this study was to map phosphoproteome changes in DCs infected by Francisella in order to reveal host signaling pathways involved in Francisella-DC interaction. The focus was laid on early intervals (<1 h p.i.) because of the ability of Francisella to escape in this time period from the phagosome to the cytosol where it establishes its replicative niche. For comparison, attenuated and in vivo-protective Francisella strain was used in parallel in experiments. DC phosphoproteome was analyzed by the means of shotgun LC-MS-based proteomics and relative changes were quantified by the stable isotope labeling method specially developed for primary bone marrow-derived DCs.

Project description:Th2 cells must sense and adapt to the tissue milieu in order to provide protective host immunity and tissue repair. Here, we examined the mechanisms promoting Th2 cell differentiation and function within the small intestinal lamina propria. Single cell RNA-seq analyses of CD4+ T cells from the small intestinal lamina propria of helminth infected mice revealed high expression of the gene Epas1, encoding the transcription factor hypoxia-inducible factor 2a (HIF2α). In vitro, exposure to hypoxia or genetic HIF2α activation promoted Th2 cell differentiation, even under non-polarizing conditions. In mice, HIF2α activation in CD4+ T cells promoted intestinal Th2 cell accumulation in the absence of infection, and HIF2α-deficiency impaired CD4+ T cell-mediated host immunity to intestinal helminth infection. Our findings identified hypoxia, and the oxygen-regulated transcription factor Hypoxia-Inducible Factor 2α (HIF2α), as key regulators of Th2 cell differentiation and function within the small intestine.

Project description:Protein deficiency and intestinal parasite infection during pregnancy impair fetal growth through passage of signals from the maternal environment which signal impairment of fetal growth. The placenta is an important regulator of the transfer of these signals through differential expression of key placental genes. We used microarrays to examine placental gene expression responses to maternal protein deficiency (6% vs. 24% protein) and Heligmosomoides bakeri infection. 2x2 factorial.