Project description:Fecal samples were collected from patients with recurrent Clostridium difficile infection before and after treatment with fecal microbiota transplantation. Fecal samples were frozen immediately after collections, and later put into ~50mg aliquots for later analysis (at -80 C).

Project description:Leber2015 - Mucosal immunity and gut microbiome interaction during C. difficile infection This model is described in the article: Systems Modeling of Interactions between Mucosal Immunity and the Gut Microbiome during Clostridium difficile Infection. Leber A, Viladomiu M, Hontecillas R, Abedi V, Philipson C, Hoops S, Howard B, Bassaganya-Riera J. PLoS ONE 2015; 10(7): e0134849 Abstract: Clostridium difficile infections are associated with the use of broad-spectrum antibiotics and result in an exuberant inflammatory response, leading to nosocomial diarrhea, colitis and even death. To better understand the dynamics of mucosal immunity during C. difficile infection from initiation through expansion to resolution, we built a computational model of the mucosal immune response to the bacterium. The model was calibrated using data from a mouse model of C. difficile infection. The model demonstrates a crucial role of T helper 17 (Th17) effector responses in the colonic lamina propria and luminal commensal bacteria populations in the clearance of C. difficile and colonic pathology, whereas regulatory T (Treg) cells responses are associated with the recovery phase. In addition, the production of anti-microbial peptides by inflamed epithelial cells and activated neutrophils in response to C. difficile infection inhibit the re-growth of beneficial commensal bacterial species. Computational simulations suggest that the removal of neutrophil and epithelial cell derived anti-microbial inhibitions, separately and together, on commensal bacterial regrowth promote recovery and minimize colonic inflammatory pathology. Simulation results predict a decrease in colonic inflammatory markers, such as neutrophilic influx and Th17 cells in the colonic lamina propria, and length of infection with accelerated commensal bacteria re-growth through altered anti-microbial inhibition. Computational modeling provides novel insights on the therapeutic value of repopulating the colonic microbiome and inducing regulatory mucosal immune responses during C. difficile infection. Thus, modeling mucosal immunity-gut microbiota interactions has the potential to guide the development of targeted fecal transplantation therapies in the context of precision medicine interventions. This model is hosted on BioModels Database and identified by: BIOMD0000000583. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Morphine causes microbial dysbiosis. In this study we focused on restoration of native microbiota in morphine treated mice and looked at the extent of restoration and immunological consequences of this restoration. Fecal transplant has been successfully used clinically, especially for treating C. difficile infection2528. With our expanding knowledge of the central role of microbiome in maintenance of host immune homeostasis17, fecal transplant is gaining importance as a therapy for indications resulting from microbial dysbiosis. There is a major difference between fecal transplant being used for the treatment of C. difficile infection and the conditions described in our studies. The former strategy is based on the argument that microbial dysbiosis caused by disproportionate overgrowth of a pathobiont can be out-competed by re-introducing the missing flora by way of a normal microbiome transplant. This strategy is independent of host factors and systemic effects on the microbial composition. Here, we show that microbial dysbiosis caused due to morphine can be reversed by transplantation of microbiota from the placebo-treated animals.

Project description:Improved understanding of the interplay between host and microbes stands to illuminate new avenues for disease diagnosis, treatment and prevention. Here, we provide a high-resolution view of the dynamics between host and gut microbiota during antibiotic induced intestinal microbiota depletion, opportunistic Salmonella typhimurium and Clostridium difficile pathogenesis, and recovery from these perturbed states in a mouse model. Host-centric proteome and microbial community profiles provide an unprecedented longitudinal view revealing the interdependence between host and microbiota in evolving dysbioses. Time- and condition-specific molecular and microbial signatures are evident and clearly distinguished from pathogen-independent inflammatory fingerprints. Our data reveal that mice recovering from antibiotic treatment or C. difficile infection retain lingering signatures of inflammation despite compositional normalization of the microbiota, and host responses could be rapidly and durably relieved through fecal transplant. These experiments define a novel platform for combining orthogonal, untargeted approaches to shed new light on the gastrointestinal ecosystem.

Project description:Improved understanding of the interplay between host and microbes stands to illuminate new avenues for disease diagnosis, treatment and prevention. Here, we provide a high-resolution view of the dynamics between host and gut microbiota during antibiotic induced intestinal microbiota depletion, opportunistic Salmonella typhimurium and Clostridium difficile pathogenesis, and recovery from these perturbed states in a mouse model. Host-centric proteome and microbial community profiles provide an unprecedented longitudinal view revealing the interdependence between host and microbiota in evolving dysbioses. Time- and condition-specific molecular and microbial signatures are evident and clearly distinguished from pathogen-independent inflammatory fingerprints. Our data reveal that mice recovering from antibiotic treatment or C. difficile infection retain lingering signatures of inflammation despite compositional normalization of the microbiota, and host responses could be rapidly and durably relieved through fecal transplant. These experiments define a novel platform for combining orthogonal, untargeted approaches to shed new light on the gastrointestinal ecosystem.

Project description:Improved understanding of the interplay between host and microbes stands to illuminate new avenues for disease diagnosis, treatment and prevention. Here, we provide a high-resolution view of the dynamics between host and gut microbiota during antibiotic induced intestinal microbiota depletion, opportunistic Salmonella typhimurium and Clostridium difficile pathogenesis, and recovery from these perturbed states in a mouse model. Host-centric proteome and microbial community profiles provide an unprecedented longitudinal view revealing the interdependence between host and microbiota in evolving dysbioses. Time- and condition-specific molecular and microbial signatures are evident and clearly distinguished from pathogen-independent inflammatory fingerprints. Our data reveal that mice recovering from antibiotic treatment or C. difficile infection retain lingering signatures of inflammation despite compositional normalization of the microbiota, and host responses could be rapidly and durably relieved through fecal transplant. These experiments define a novel platform for combining orthogonal, untargeted approaches to shed new light on the gastrointestinal ecosystem.

Project description:Improved understanding of the interplay between host and microbes stands to illuminate new avenues for disease diagnosis, treatment and prevention. Here, we provide a high-resolution view of the dynamics between host and gut microbiota during antibiotic induced intestinal microbiota depletion, opportunistic Salmonella typhimurium and Clostridium difficile pathogenesis, and recovery from these perturbed states in a mouse model. Host-centric proteome and microbial community profiles provide an unprecedented longitudinal view revealing the interdependence between host and microbiota in evolving dysbioses. Time- and condition-specific molecular and microbial signatures are evident and clearly distinguished from pathogen-independent inflammatory fingerprints. Our data reveal that mice recovering from antibiotic treatment or C. difficile infection retain lingering signatures of inflammation despite compositional normalization of the microbiota, and host responses could be rapidly and durably relieved through fecal transplant. These experiments define a novel platform for combining orthogonal, untargeted approaches to shed new light on the gastrointestinal ecosystem.

Project description:Improved understanding of the interplay between host and microbes stands to illuminate new avenues for disease diagnosis, treatment and prevention. Here, we provide a high-resolution view of the dynamics between host and gut microbiota during antibiotic induced intestinal microbiota depletion, opportunistic Salmonella typhimurium and Clostridium difficile pathogenesis, and recovery from these perturbed states in a mouse model. Host-centric proteome and microbial community profiles provide an unprecedented longitudinal view revealing the interdependence between host and microbiota in evolving dysbioses. Time- and condition-specific molecular and microbial signatures are evident and clearly distinguished from pathogen-independent inflammatory fingerprints. Our data reveal that mice recovering from antibiotic treatment or C. difficile infection retain lingering signatures of inflammation despite compositional normalization of the microbiota, and host responses could be rapidly and durably relieved through fecal transplant. These experiments define a novel platform for combining orthogonal, untargeted approaches to shed new light on the gastrointestinal ecosystem.

Project description:Improved understanding of the interplay between host and microbes stands to illuminate new avenues for disease diagnosis, treatment and prevention. Here, we provide a high-resolution view of the dynamics between host and gut microbiota during antibiotic induced intestinal microbiota depletion, opportunistic Salmonella typhimurium and Clostridium difficile pathogenesis, and recovery from these perturbed states in a mouse model. Host-centric proteome and microbial community profiles provide an unprecedented longitudinal view revealing the interdependence between host and microbiota in evolving dysbioses. Time- and condition-specific molecular and microbial signatures are evident and clearly distinguished from pathogen-independent inflammatory fingerprints. Our data reveal that mice recovering from antibiotic treatment or C. difficile infection retain lingering signatures of inflammation despite compositional normalization of the microbiota, and host responses could be rapidly and durably relieved through fecal transplant. These experiments define a novel platform for combining orthogonal, untargeted approaches to shed new light on the gastrointestinal ecosystem.

Project description:Hypervirulent epidemic strains of Clostridium difficile (C. difficile), referred to as NAPI/027, express an additional virulence factor, binary toxin (CDT), and are associated with more severe disease. Emerging evidence indicates gut immunity to C. difficile is a delicate balance between protection and pathology. To identify potential therapeutic host immune targets, we conducted a transcriptome analysis of host genes altered by NAPI/027 infection and identified interleukin-33 (IL-33) as a candidate immune target. Using a murine model, we show that both endogenous IL-33 and exogenous IL-33 treatment protect from the enhanced mortality, weight-loss and tissue pathology which is characteristic of hypervirulent C. difficile. IL-33 mediated protection was elicited through type-2 innate lymphoid cells (ILC2s) and adoptive transfer of purified ILC2s was sufficient to mitigate CDI- associated mortality and weight-loss. Furthermore, dysregulated IL-33 signaling via the soluble IL-33 decoy receptor (sST2) predicted disease severity and mortality in human patients. Lastly, colonic IL-33 expression appears to be regulated by the microbiota as antibiotic- depletion of IL-33 was rescued with mouse fecal microbiota transplant (FMT) and a human fecal spore preparation (HSP). Thus, IL-33 signaling is a novel therapeutic pathway for severe CDI which can potentially be targeted with rationally designed microbial therapies.