ABSTRACT
An imbalance in the microbiota may contribute to many human illnesses, which has prompted efforts to rebalance it by targeting the microbes themselves. However, by supplying the habitat, the host wields a prominent influence over microbial growth at body surfaces, raising the possibility that rebalancing the microbiota by targeting our immune system would be a viable alternative. Host control mechanisms that sculpt the microbial habitat form a functional unit with the microbiota, termed microbiota-nourishing immunity, that confers colonization resistance against pathogens. The host components of microbiota-nourishing immunity can be viewed as habitat filters that select for microbial traits licensing growth and survival in host habitat patches. Here we review current knowledge of how host-derived habitat filters shape the size, species composition, and spatial heterogeneity of the microbiota and discuss whether these host control mechanisms could be harnessed for developing approaches to rebalance microbial communities during dysbiosis.
Subject(s)
Dysbiosis , Microbiota , Animals , HumansABSTRACT
Carbohydrate intolerance, commonly linked to the consumption of lactose, fructose, or sorbitol, affects up to 30% of the population in high-income countries. Although sorbitol intolerance is attributed to malabsorption, the underlying mechanism remains unresolved. Here, we show that a history of antibiotic exposure combined with high fat intake triggered long-lasting sorbitol intolerance in mice by reducing Clostridia abundance, which impaired microbial sorbitol catabolism. The restoration of sorbitol catabolism by inoculation with probiotic Escherichia coli protected mice against sorbitol intolerance but did not restore Clostridia abundance. Inoculation with the butyrate producer Anaerostipes caccae restored a normal Clostridia abundance, which protected mice against sorbitol-induced diarrhea even when the probiotic was cleared. Butyrate restored Clostridia abundance by stimulating epithelial peroxisome proliferator-activated receptor-gamma (PPAR-γ) signaling to restore epithelial hypoxia in the colon. Collectively, these mechanistic insights identify microbial sorbitol catabolism as a potential target for approaches for the diagnosis, treatment, and prevention of sorbitol intolerance.
Subject(s)
Carbohydrate Metabolism, Inborn Errors , Gastrointestinal Microbiome , Sorbitol , Animals , Mice , Anti-Bacterial Agents/pharmacology , Butyrates , Clostridium , Escherichia coli , Sorbitol/metabolismABSTRACT
In ecological terms, the microbiome is defined as the microbiota and its environment, a definition that encompasses the human host. The size, species composition, and biogeography of microbial communities is shaped by host interactions, and, in turn, the microbiota influences many aspects of human health. Here we discuss the concept of microbiota-nourishing immunity, a host-microbe chimera composed of the microbiota and host factors that shape the microbial ecosystem, which functions in conferring colonization resistance against pathogens. We propose that dysbiosis is a biomarker of a weakening in microbiota-nourishing immunity and that homeostasis can be defined as a state of immune competence. Microbiota-nourishing immunity thus provides a conceptual framework to further examine the mechanisms that preserve a healthy microbiome and the drivers and consequences of dysbiosis.
Subject(s)
Dysbiosis/immunology , Host-Pathogen Interactions , Microbiota/immunology , Animals , Autoantigens/immunology , Homeostasis , Humans , Immunity , Immunocompetence , Self ToleranceABSTRACT
Humans are uniquely susceptible to typhoid fever caused by infection with Salmonella enterica serovar Typhi. Mathur et al. now report that mice lacking Toll-like receptor 11, which is absent in humans, can be lethally infected with S. Typhi, a breakthrough that promises to speed the development of better vaccines.
ABSTRACT
The gut microbiota plays a role in many human diseases, but high-throughput sequence analysis does not provide a straightforward path for defining healthy microbial communities. Therefore, understanding mechanisms that drive compositional changes during disease (gut dysbiosis) continues to be a central goal in microbiome research. Insights from the microbial pathogenesis field show that an ecological cause for gut dysbiosis is an increased availability of host-derived respiratory electron acceptors, which are dominant drivers of microbial community composition. Similar changes in the host environment also drive gut dysbiosis in several chronic human illnesses, and a better understanding of the underlying mechanisms informs approaches to causatively link compositional changes in the gut microbiota to an exacerbation of symptoms. The emerging picture suggests that homeostasis is maintained by host functions that control the availability of resources governing microbial growth. Defining dysbiosis as a weakening of these host functions directs attention to the underlying cause and identifies potential targets for therapeutic intervention.
Subject(s)
Gastrointestinal Microbiome , Microbiota , Humans , DysbiosisABSTRACT
The gut microbiome, composed of the colonic microbiota and their host environment, is important for many aspects of human health. A gut microbiome imbalance (gut dysbiosis) is associated with major causes of human morbidity and mortality. Despite the central part our gut microbiome plays in health and disease, mechanisms that maintain homeostasis and properties that demarcate dysbiosis remain largely undefined. Here we discuss that sorting taxa into meaningful ecological units reveals that the availability of respiratory electron acceptors, such as oxygen, in the host environment has a dominant influence on gut microbiome health. During homeostasis, host functions that limit the diffusion of oxygen into the colonic lumen shelter a microbial community dominated by primary fermenters from atmospheric oxygen. In turn, primary fermenters break down unabsorbed nutrients into fermentation products that support host nutrition. This symbiotic relationship is disrupted when host functions that limit the luminal availability of host-derived electron acceptors become weakened. The resulting changes in the host environment drive alterations in the microbiota composition, which feature an elevated abundance of facultatively anaerobic microbes. Thus, the part of the gut microbiome that becomes imbalanced during dysbiosis is the host environment, whereas changes in the microbiota composition are secondary to this underlying cause. This shift in our understanding of dysbiosis provides a novel starting point for therapeutic strategies to restore microbiome health. Such strategies can either target the microbes through metabolism-based editing or strengthen the host functions that control their environment.
ABSTRACT
Inflammatory diseases of the gastrointestinal tract are frequently associated with dysbiosis, characterized by changes in gut microbial communities that include an expansion of facultative anaerobic bacteria of the Enterobacteriaceae family (phylum Proteobacteria). Here we show that a dysbiotic expansion of Enterobacteriaceae during gut inflammation could be prevented by tungstate treatment, which selectively inhibited molybdenum-cofactor-dependent microbial respiratory pathways that are operational only during episodes of inflammation. By contrast, we found that tungstate treatment caused minimal changes in the microbiota composition under homeostatic conditions. Notably, tungstate-mediated microbiota editing reduced the severity of intestinal inflammation in mouse models of colitis. We conclude that precision editing of the microbiota composition by tungstate treatment ameliorates the adverse effects of dysbiosis in the inflamed gut.
Subject(s)
Colitis/drug therapy , Colitis/microbiology , Gastrointestinal Microbiome/drug effects , Intestines/drug effects , Intestines/microbiology , Anaerobiosis/drug effects , Animals , Cell Respiration/drug effects , Dysbiosis/drug therapy , Dysbiosis/microbiology , Enterobacteriaceae/drug effects , Enterobacteriaceae/growth & development , Enterobacteriaceae/metabolism , Female , Inflammation/drug therapy , Inflammation/microbiology , Inflammation/pathology , Intestinal Mucosa/drug effects , Intestinal Mucosa/microbiology , Intestinal Mucosa/pathology , Intestines/pathology , Male , Mice , Mice, Inbred C57BL , Molybdenum/metabolism , Tungsten Compounds/pharmacology , Tungsten Compounds/therapeutic useABSTRACT
T cell effector functions can be elicited by noncognate stimuli, but the mechanism and contribution of this pathway to the resolution of intracellular macrophage infections have not been defined. Here, we show that CD4(+) T helper 1 (Th1) cells could be rapidly stimulated by microbe-associated molecular patterns during active infection with Salmonella or Chlamydia. Further, maximal stimulation of Th1 cells by lipopolysaccharide (LPS) did not require T-cell-intrinsic expression of toll-like receptor 4 (TLR4), interleukin-1 receptor (IL-1R), or interferon-γ receptor (IFN-γR) but instead required IL-18R, IL-33R, and adaptor protein MyD88. Innate stimulation of Th1 cells also required host expression of TLR4 and inflammasome components that together increased serum concentrations of IL-18. Finally, the elimination of noncognate Th1 cell stimulation hindered the resolution of primary Salmonella infection. Thus, the in vivo bactericidal capacity of Th1 cells is regulated by the response to noncognate stimuli elicited by multiple innate immune receptors.
Subject(s)
Immunity, Innate/immunology , Inflammasomes/metabolism , Signal Transduction , Th1 Cells/immunology , Toll-Like Receptors/metabolism , Animals , Bacterial Load/immunology , CD4 Antigens/immunology , Chlamydia/physiology , Flow Cytometry , Interleukin-18/metabolism , Mice , Mice, Inbred C57BL , Real-Time Polymerase Chain Reaction , Salmonella/physiology , Toll-Like Receptor 4/metabolismABSTRACT
The microbiome has an important role in human health. Changes in the microbiota can confer resistance to or promote infection by pathogenic bacteria. Antibiotics have a profound impact on the microbiota that alters the nutritional landscape of the gut and can lead to the expansion of pathogenic populations. Pathogenic bacteria exploit microbiota-derived sources of carbon and nitrogen as nutrients and regulatory signals to promote their own growth and virulence. By eliciting inflammation, these bacteria alter the intestinal environment and use unique systems for respiration and metal acquisition to drive their expansion. Unravelling the interactions between the microbiota, the host and pathogenic bacteria will produce strategies for manipulating the microbiota against infectious diseases.
Subject(s)
Bacteria/pathogenicity , Gastrointestinal Microbiome , Intestines/microbiology , Microbial Interactions , Animals , Anti-Bacterial Agents/pharmacology , Bacteria/drug effects , Bacteria/growth & development , Bacteria/metabolism , Bacterial Infections/metabolism , Bacterial Infections/microbiology , Bacterial Infections/therapy , Carbon/metabolism , Disease Resistance , Gastrointestinal Microbiome/drug effects , Humans , Inflammation/metabolism , Inflammation/microbiology , Intestinal Mucosa/metabolism , Intestines/drug effects , Microbial Interactions/drug effects , Nitrogen/metabolism , Signal Transduction , Virulence/physiologyABSTRACT
Changes in the gut microbiota may underpin many human diseases, but the mechanisms that are responsible for altering microbial communities remain poorly understood. Antibiotic usage elevates the risk of contracting gastroenteritis caused by Salmonella enterica serovars, increases the duration for which patients shed the pathogen in their faeces, and may on occasion produce a bacteriologic and symptomatic relapse. These antibiotic-induced changes in the gut microbiota can be studied in mice, in which the disruption of a balanced microbial community by treatment with the antibiotic streptomycin leads to an expansion of S. enterica serovars in the large bowel. However, the mechanisms by which streptomycin treatment drives an expansion of S. enterica serovars are not fully resolved. Here we show that host-mediated oxidation of galactose and glucose promotes post-antibiotic expansion of S. enterica serovar Typhimurium (S. Typhimurium). By elevating expression of the gene encoding inducible nitric oxide synthase (iNOS) in the caecal mucosa, streptomycin treatment increased post-antibiotic availability of the oxidation products galactarate and glucarate in the murine caecum. S. Typhimurium used galactarate and glucarate within the gut lumen of streptomycin pre-treated mice, and genetic ablation of the respective catabolic pathways reduced S. Typhimurium competitiveness. Our results identify host-mediated oxidation of carbohydrates in the gut as a mechanism for post-antibiotic pathogen expansion.
Subject(s)
Anti-Bacterial Agents/pharmacology , Carbohydrate Metabolism , Host-Pathogen Interactions/drug effects , Intestinal Mucosa/drug effects , Salmonella typhimurium/drug effects , Salmonella typhimurium/growth & development , Streptomycin/pharmacology , Animals , Carbohydrate Metabolism/drug effects , Carbohydrate Metabolism/genetics , Cecum/drug effects , Cecum/enzymology , Cecum/microbiology , Female , Galactose/metabolism , Gastroenteritis/microbiology , Glucaric Acid/metabolism , Glucose/metabolism , Intestinal Mucosa/enzymology , Intestinal Mucosa/metabolism , Intestinal Mucosa/microbiology , Male , Mice , Nitric Oxide Synthase Type II/genetics , Nitric Oxide Synthase Type II/metabolism , Operon/genetics , Oxidation-Reduction/drug effects , Reactive Nitrogen Species/metabolism , Salmonella typhimurium/metabolism , Salmonella typhimurium/pathogenicity , Sugar Acids/metabolismABSTRACT
Endoplasmic reticulum (ER) stress is a major contributor to inflammatory diseases, such as Crohn disease and type 2 diabetes. ER stress induces the unfolded protein response, which involves activation of three transmembrane receptors, ATF6, PERK and IRE1α. Once activated, IRE1α recruits TRAF2 to the ER membrane to initiate inflammatory responses via the NF-κB pathway. Inflammation is commonly triggered when pattern recognition receptors (PRRs), such as Toll-like receptors or nucleotide-binding oligomerization domain (NOD)-like receptors, detect tissue damage or microbial infection. However, it is not clear which PRRs have a major role in inducing inflammation during ER stress. Here we show that NOD1 and NOD2, two members of the NOD-like receptor family of PRRs, are important mediators of ER-stress-induced inflammation in mouse and human cells. The ER stress inducers thapsigargin and dithiothreitol trigger production of the pro-inflammatory cytokine IL-6 in a NOD1/2-dependent fashion. Inflammation and IL-6 production triggered by infection with Brucella abortus, which induces ER stress by injecting the type IV secretion system effector protein VceC into host cells, is TRAF2, NOD1/2 and RIP2-dependent and can be reduced by treatment with the ER stress inhibitor tauroursodeoxycholate or an IRE1α kinase inhibitor. The association of NOD1 and NOD2 with pro-inflammatory responses induced by the IRE1α/TRAF2 signalling pathway provides a novel link between innate immunity and ER-stress-induced inflammation.
Subject(s)
Endoplasmic Reticulum Stress , Inflammation/metabolism , Nod1 Signaling Adaptor Protein/metabolism , Nod2 Signaling Adaptor Protein/metabolism , Signal Transduction , Animals , Bacterial Outer Membrane Proteins/metabolism , Brucella abortus/immunology , Brucella abortus/pathogenicity , Cell Line , Dithiothreitol/pharmacology , Endoplasmic Reticulum/drug effects , Endoplasmic Reticulum/pathology , Endoplasmic Reticulum Stress/drug effects , Endoribonucleases/antagonists & inhibitors , Female , Humans , Immunity, Innate , Inflammation/chemically induced , Interleukin-6/biosynthesis , Male , Mice , Mice, Inbred C57BL , NF-kappa B/metabolism , Nod1 Signaling Adaptor Protein/immunology , Nod2 Signaling Adaptor Protein/immunology , Protein Serine-Threonine Kinases/antagonists & inhibitors , Receptors, Pattern Recognition/metabolism , Signal Transduction/drug effects , TNF Receptor-Associated Factor 2/metabolism , Taurochenodeoxycholic Acid/pharmacology , Thapsigargin/pharmacology , Unfolded Protein Response/drug effectsABSTRACT
Inflammatory bowel disease (IBD) is typically diagnosed by exclusion years after its onset. Current diagnostic methods are indirect, destructive, or target overt disease. Screening strategies that can detect low-grade inflammation in the colon would improve patient prognosis and alleviate associated healthcare costs. Here, we test the feasibility of fluorescence lifetime imaging (FLIm) to detect inflammation from thick tissue in a non-destructive and label-free approach based on tissue autofluorescence. A pulse sampling FLIm instrument with 355 nm excitation was coupled to a rotating side-viewing endoscopic probe for high speed (10 mm/s) intraluminal imaging of the entire mucosal surface (50-80 mm) of freshly excised mice colons. Current results demonstrate that tissue autofluorescence lifetime was sensitive to the colon anatomy and the colonocyte layer. Moreover, mice under DSS-induced colitis and 5-ASA treatments showed changes in lifetime values that were qualitatively related to inflammatory markers consistent with alterations in epithelial bioenergetics (switch between ß-oxidation and aerobic glycolysis) and physical structure (colon length). This study demonstrates the ability of intraluminal FLIm to image mucosal lifetime changes in response to inflammatory treatments and supports the development of FLIm as an in vivo imaging technique for monitoring the onset, progression, and treatment of inflammatory diseases.
Subject(s)
Colitis/diagnostic imaging , Colitis/pathology , Optical Imaging/methods , Animals , Colitis/etiology , Disease Management , Disease Models, Animal , Disease Susceptibility , Female , Immunohistochemistry , Inflammatory Bowel Diseases/diagnostic imaging , Inflammatory Bowel Diseases/etiology , Inflammatory Bowel Diseases/pathology , Mice , Microscopy, Fluorescence , Molecular Imaging/methodsABSTRACT
Salmonella enterica is a foodborne pathogen often leading to gastroenteritis and is commonly acquired by consumption of contaminated food of animal origin. However, frequency of outbreaks linked to the consumption of fresh or minimally processed food of nonanimal origin is increasing. New infection routes of S. enterica by vegetables, fruits, nuts, and herbs have to be considered. This leads to special interest in S. enterica interactions with leafy products, e.g., salads, that are mainly consumed in a minimally processed form. The attachment of S. enterica to salad is a crucial step in contamination, but little is known about the bacterial factors required and mechanisms of adhesion. S. enterica possesses a complex set of adhesive structures whose functions are only partly understood. Potentially, S. enterica may deploy multiple adhesive strategies for adhering to various salad species and other vegetables. In this study, we systematically analyzed the contributions of the complete adhesiome, of lipopolysaccharide (LPS), and of flagellum-mediated motility of S. enterica serovar Typhimurium (STM) in adhesion to Valerianella locusta (corn salad). We deployed a reductionist, synthetic approach to identify factors involved in the surface binding of STM to leaves of corn salad, with particular regard to the expression of all known adhesive structures, using the Tet-on system. This work reveals the contribution of Saf fimbriae, type 1 secretion system-secreted BapA, an intact LPS, and flagellum-mediated motility of STM in adhesion to corn salad leaves.IMPORTANCE Transmission of gastrointestinal pathogens by contaminated fresh produce is of increasing relevance to human health. However, the mechanisms of contamination of, persistence on, and transmission by fresh produce are poorly understood. We investigated the contributions of the various adhesive structures of STM to the initial event in transmission, i.e., binding to the plant surface. A reductionist system was used that allowed experimentally controlled surface expression of individual adhesive structures and analyses of the contribution to binding to leave surfaces of corn salad under laboratory conditions. The model system allowed the determination of the relative contributions of fimbrial and nonfimbrial adhesins, the type 3 secretion systems, the O antigen of lipopolysaccharide, the flagella, and chemotaxis of STM to binding to corn salad leaves. Based on these data, future work could reveal the mechanism of binding and the relevance of interaction under agricultural conditions.
Subject(s)
Bacterial Adhesion , Food Microbiology , Salmonella typhimurium/physiology , Valerianella/microbiology , Lipopolysaccharides/metabolismABSTRACT
A metabolically diverse microbial community occupies all available nutrient-niches in the lumen of the mammalian intestine, making it difficult for pathogens to establish themselves in this highly competitive environment. Salmonella serovars sidestep the competition by using their virulence factors to coerce the host into creating a novel nutrient-niche. Inflammation-derived nutrients available in this new niche support a bloom of Salmonella serovars, thereby ensuring transmission of the pathogen to the next susceptible host by the fecal-oral route. Here we review the anaerobic food chain that characterizes resident gut-associated microbial communities along with the winning metabolic strategy Salmonella serovars use to edge out competing microbes in the inflamed intestine.
Subject(s)
Intestines/microbiology , Salmonella typhimurium/growth & development , Salmonella typhimurium/metabolism , Anaerobiosis , Animals , Humans , Microbial Interactions , Salmonella Infections/microbiology , Salmonella Infections/pathology , Salmonella typhimurium/pathogenicity , Virulence Factors/metabolismABSTRACT
KEY POINTS: â¢Nucleotide binding oligomerization domain (Nod)-like receptors regulate cognition, anxiety and hypothalamic-pituitary-adrenal axis activation. â¢Nod-like receptors regulate central and peripheral serotonergic biology. â¢Nod-like receptors are important for maintenance of gastrointestinal physiology. â¢Intestinal epithelial cell expression of Nod1 receptors regulate behaviour. ABSTRACT: Gut-brain axis signalling is critical for maintaining health and homeostasis. Stressful life events can impact gut-brain signalling, leading to altered mood, cognition and intestinal dysfunction. In the present study, we identified nucleotide binding oligomerization domain (Nod)-like receptors (NLR), Nod1 and Nod2, as novel regulators for gut-brain signalling. NLR are innate immune pattern recognition receptors expressed in the gut and brain, and are important in the regulation of gastrointestinal physiology. We found that mice deficient in both Nod1 and Nod2 (NodDKO) demonstrate signs of stress-induced anxiety, cognitive impairment and depression in the context of a hyperactive hypothalamic-pituitary-adrenal axis. These deficits were coupled with impairments in the serotonergic pathway in the brain, decreased hippocampal cell proliferation and immature neurons, as well as reduced neural activation. In addition, NodDKO mice had increased gastrointestinal permeability and altered serotonin signalling in the gut following exposure to acute stress. Administration of the selective serotonin reuptake inhibitor, fluoxetine, abrogated behavioural impairments and restored serotonin signalling. We also identified that intestinal epithelial cell-specific deletion of Nod1 (VilCre+ Nod1f/f ), but not Nod2, increased susceptibility to stress-induced anxiety-like behaviour and cognitive impairment following exposure to stress. Together, these data suggest that intestinal epithelial NLR are novel modulators of gut-brain communication and may serve as potential novel therapeutic targets for the treatment of gut-brain disorders.
Subject(s)
Brain/metabolism , Intestinal Mucosa/metabolism , Nod1 Signaling Adaptor Protein/metabolism , Nod2 Signaling Adaptor Protein/metabolism , Serotonin/metabolism , Synaptic Transmission , Animals , Anxiety/etiology , Anxiety/metabolism , Brain/physiology , Cells, Cultured , Cognition , Female , Hypothalamo-Hypophyseal System/metabolism , Hypothalamo-Hypophyseal System/physiology , Intestinal Absorption , Intestinal Mucosa/physiology , Male , Mice , Mice, Inbred C57BL , Neurogenesis , Nod1 Signaling Adaptor Protein/genetics , Nod2 Signaling Adaptor Protein/genetics , Stress, Psychological/etiology , Stress, Psychological/metabolismABSTRACT
Advances in data collection technologies reveal that an imbalance (dysbiosis) in the composition of host-associated microbial communities (microbiota) is linked to many human illnesses. This association makes dysbiosis a central concept for understanding how the human microbiota contributes to health and disease. However, it remains problematic to define the term dysbiosis by cataloguing microbial species names. Here, we discuss how incorporating the germ-organ concept, ecological assumptions, and immunological principles into a theoretical framework for microbiota research provides a functional definition for dysbiosis. The generation of such a framework suggests that the next logical step in microbiota research will be to illuminate the mechanistic underpinnings of dysbiosis, which often involves a weakening of immune mechanisms that balance our microbial communities.
Subject(s)
Dysbiosis/microbiology , Gastrointestinal Microbiome , Animals , Dysbiosis/etiology , Humans , MetagenomeABSTRACT
Intestinal inflammation caused by Salmonella enterica serovar Typhimurium increases the availability of electron acceptors that fuel a respiratory growth of the pathogen in the intestinal lumen. Here we show that one of the carbon sources driving this respiratory expansion in the mouse model is 1,2-propanediol, a microbial fermentation product. 1,2-propanediol utilization required intestinal inflammation induced by virulence factors of the pathogen. S. Typhimurium used both aerobic and anaerobic respiration to consume 1,2-propanediol and expand in the murine large intestine. 1,2-propanediol-utilization did not confer a benefit in germ-free mice, but the pdu genes conferred a fitness advantage upon S. Typhimurium in mice mono-associated with Bacteroides fragilis or Bacteroides thetaiotaomicron. Collectively, our data suggest that intestinal inflammation enables S. Typhimurium to sidestep nutritional competition by respiring a microbiota-derived fermentation product.
Subject(s)
Colitis/microbiology , Host-Pathogen Interactions/physiology , Propylene Glycol/metabolism , Salmonella Infections, Animal/metabolism , Salmonella typhimurium/pathogenicity , Animals , Cell Respiration/physiology , Disease Models, Animal , Mice , Mice, Inbred C57BL , Polymerase Chain Reaction , Salmonella typhimurium/growth & development , Virulence Factors/metabolismABSTRACT
Dysregulated bile acid (BA) synthesis is accompanied by dysbiosis, leading to compromised metabolism. This study analyzes the effect of epigallocatechin-3-gallate (EGCG) on diet-induced obesity through regulation of BA signaling and gut microbiota. The data revealed that EGCG effectively reduced diet-increased obesity, visceral fat, and insulin resistance. Gene profiling data showed that EGCG had a significant impact on regulating genes implicated in fatty acid uptake, adipogenesis, and metabolism in the adipose tissue. In addition, metabolomics analysis revealed that EGCG altered the lipid and sugar metabolic pathways. In the intestine, EGCG reduced the FXR agonist chenodeoxycholic acid, as well as the FXR-regulated pathway, suggesting intestinal FXR deactivation. However, in the liver, EGCG increased the concentration of FXR and TGR-5 agonists and their regulated signaling. Furthermore, our data suggested that EGCG activated Takeda G protein receptor (TGR)-5 based on increased GLP-1 release and elevated serum PYY level. EGCG and antibiotics had distinct antibacterial effects. They also differentially altered body weight and BA composition. EGCG, but not antibiotics, increased Verrucomicrobiaceae, under which EGCG promoted intestinal bloom of Akkermansia muciniphila. Excitingly, A. muciniphila was as effective as EGCG in treating diet-induced obesity. Together, EGCG shifts gut microbiota and regulates BA signaling thereby having a metabolic beneficial effect.-Sheng, L., Jena, P. K., Liu, H.-X., Hu, Y., Nagar, N., Bronner, D. N., Settles, M. L., Bäumler, A. J. Wan, Y.-J. Y. Obesity treatment by epigallocatechin-3-gallate-regulated bile acid signaling and its enriched Akkermansia muciniphila.
ABSTRACT
Our innate immune system distinguishes microbes from self by detecting conserved pathogen-associated molecular patterns. However, these are produced by all microbes, regardless of their pathogenic potential. To distinguish virulent microbes from those with lower disease-causing potential the innate immune system detects conserved pathogen-induced processes, such as the presence of microbial products in the host cytosol, by mechanisms that are not fully resolved. Here we show that NOD1 senses cytosolic microbial products by monitoring the activation state of small Rho GTPases. Activation of RAC1 and CDC42 by bacterial delivery or ectopic expression of SopE, a virulence factor of the enteric pathogen Salmonella, triggered the NOD1 signalling pathway, with consequent RIP2 (also known as RIPK2)-mediated induction of NF-κB-dependent inflammatory responses. Similarly, activation of the NOD1 signalling pathway by peptidoglycan required RAC1 activity. Furthermore, constitutively active forms of RAC1, CDC42 and RHOA activated the NOD1 signalling pathway. Our data identify the activation of small Rho GTPases as a pathogen-induced process sensed through the NOD1 signalling pathway.