Project description:Previous studies have implicated a causal role for the gut bacterium Akkermansia muciniphila in counteracting diet-induced obesity and metabolic dysfunctions. However, a systems level understanding of the molecular mechanisms underlying the anti-obesogenic effect of A. muciniphila is lacking. Using fructose-induced obese mice as a model, we carried out multiomics studies to investigate the molecular cascades mediating the effect of A. muciniphila. We found that A. muciniphila colonization in fructose-induced obese mice triggered significant shifts in gut microbiota composition as well as alterations in numerous gut and plasma metabolites and gene expression in the hypothalamus. Among these, we found that the metabolite oleoyl-ethanolamide in the gut and circulation and hypothalamic oxytocin are the key regulators of gut-brain interactions that underlie the A. muciniphila anti-obesity effect. Our multiomics investigation elucidates the molecular regulators and pathways involved in the communication between A. muciniphila in the gut and hypothalamic neurons that counter fructose-induced obesity .

Project description:Immunoglobulin A (IgA) is the most abundant antibody in the intestinal tract. Recent studies show that discrete subsets of gut human plasma cells (PCs) release IgA, which contributes to the maintenance of gut homeostasis. To better characterize the properties of these PC subsets, we performed global transcriptome analysis in naïve B cells as well as immature CD19+IgA+CD138- PCs, mature CD19+IgA+CD138+ PCs and late CD19-IgA+CD138+ PCs after their purification from human colon samples.

Project description:The impacts of individual commensal microbes on immunity and disease can differ dramatically depending on the surrounding microbial context, yet the specific bacterial combinations that dictate divergent immunological outcomes in humans remain largely undefined. We isolated a novel Allobaculum strain from an inflammatory bowel disease (IBD) patient that elicited antigen-specific mucosal and systemic antibody responses at homeostasis and exacerbated colitis in gnotobiotic mice. Using human microbiota-associated mouse models, we uncovered an inverse correlation between Allobaculum and the taxonomically-divergent immunostimulatory species Akkermansia muciniphila, which was also reflected in human cohorts. Co-colonization with Allobaculum and A. muciniphila reprogrammed the immune responses evoked by each microbe on its own, ameliorated Allobaculum-induced colitis, and blunted A. muciniphila-induced T and B cell responses. These studies thus identify a reciprocal ‘epistatic’ interaction between unique immunostimulatory human gut bacteria and establish a generalizable framework to dissect the role of microbial context in strain-specific microbial effects on human disease.

Project description:The anaerobic gut microbe Akkermansia muciniphila ATCC BAA-835 lives in the mucus layer where it is exposed to oxygen. To investigate how it survives the changing oxygen concentrations, we exposed a exponentially growing culture to oxygen. The experiment was performed in parallel fermentor systems. To one system we added 0.2l/h oxygen after the culture reached an OD of 0.1, while the other remained anaerobic. Samples were taken just before addition of oxygen, about 1h after and when the cell reached stationary phase.

Project description:Akkermansia muciniphila, a common member of the human gut microbiota, is considered to be a beneficial resident of the intestinal mucus layer. Surface-exposed molecules produced by this organism likely play important roles in colonization and communication with other microbes and the host, but the protein composition of the outer membrane has not been characterized thus far. Herein we identify A. muciniphila proteins after enrichment and fractionation of the outer membrane proteome of A. muciniphila.

Project description:Akkermansia muciniphila, a mucin-degrading microbe found in the human gut, is often associated with positive health outcomes. The abundance of Akkermansia muciniphila is modulated by the presence and accessibility of nutrients, which can be derived from diet or host glycoproteins. In particular, the ability to degrade host mucins, a class of proteins carrying densely O-glycosylated domains, provides a competitive advantage in the sustained colonization of niche mucosal environments. Although Akkermansia muciniphila is known to rely on mucins as a carbon and nitrogen source, the enzymatic machinery used by this microbe to process mucins in the gut is not yet fully characterized. Here, we focus on the mucin-selective metalloprotease, Amuc_0627 (AM0627), which is known to cleave between adjacent residues carrying truncated core 1 O-glycans. We showed that this enzyme is capable of degrading purified mucin 2 (MUC2), the major protein component of mucus in the gut. An X-ray crystal structure of AM0627 (1.9 Å resolution) revealed O-glycan binding residues that are conserved between structurally characterized enzymes from the same family. We further rationalized the substrate cleavage motif using molecular modeling to identify nonconserved glycan-interacting residues. Mutagenesis of these residues resulted in altered substrate preferences down to the glycan level, providing insight into the structural determinants of O-glycan recognition.

Project description:In this study we performed MeRIP-Seq to study N6-methyl adenosine (m6A) and and N6,2′ -O-dimethyladenosine (m6Am) modification of mRNA. We investigated the effect of the microbiota on the transcriptome and epitranscriptomic modifications in murine liver and cecum. We compared m6A/m modification profiles in cecum of conventionally raised (CONV) and germ-free (GF) mice. We additionally included GF mice colonised with the flora of CONV mice for four weeks (ex-GF), for which show that they exhibit similar patterns of the most abundant genera of gut bacteria as CONV mice. We added mice treated with several antibiotics to deplete the gut flora (abx)and vancomycin treated mice in which the genera Akkermansia, Escherichia/Shigella and Lactobacillus were enriched. Furthermore, we included GF mice colonised with the commensal bacterium Akkermansia muciniphila (Am), Lactobacillus plantarum (Lp) and Escherichia coli Nissle (Ec) and analysed their m6A/m modification profiles. In addition, we analysed changes in m6A/m- modified liver RNA for CONV, GF, and Am, Lp and Ec mice.

Project description:Akkermansia muciniphila, a mucin-degrading microbe found in the human gut, is often associated with positive health outcomes. The abundance of Akkermansia muciniphila is modulated by the presence and accessibility of nutrients, which can be derived from diet or host glycoproteins. In particular, the ability to degrade host mucins, a class of proteins carrying densely O-glycosylated domains, provides a competitive advantage in the sustained colonization of niche mucosal environments. Although Akkermansia muciniphila is known to rely on mucins as a carbon and nitrogen source, the enzymatic machinery used by this microbe to process mucins in the gut is not yet fully characterized. Here, we focus on the mucin-selective metalloprotease, Amuc_0627 (AM0627), which is known to cleave between adjacent residues carrying truncated core 1 O-glycans. We showed that this enzyme is capable of degrading purified mucin 2 (MUC2), the major protein component of mucus in the gut. An X-ray crystal structure of AM0627 at 1.9 Å resolution revealed O-glycan binding residues that are conserved between structurally characterized enzymes from the same family. We further rationalized the substrate cleavage motif using molecular modeling to identify nonconserved glycan-interacting residues. Mutagenesis of these residues resulted in altered substrate preferences down to the glycan level, providing insight into the structural determinants of O-glycan recognition.

Project description:We implemented transcriptomic analyses of blood and hippocampus of old mice treated with Akkermansia muciniphila Membrane Protein for 8 weeks.

Project description:Total RNA from ileum of three groups of mice are sequenced. The three groups are 1. wild type mice. 2. mice with IFNg gene knockout. 3. IFNg gene knockout mice after colonization of Akkermansia muciniphila