Project Details
Description
PROJECT SUMMARY/ABSTRACT
Obesity affects approximately 35% of adults and 17% of children in the United States increasing the risks of
heart disease, stroke and type 2 diabetes. The human gut microbiota, the trillions of microbes that inhabit the
gastrointestinal tract, have been implicated as an environmental factor linked to obesity and energy balance;
however, the mechanisms are not fully understood. Diet remains the first line intervention to induce weight
loss, but its impact on the microbiota, and how this may affect weight loss and regain remain unclear. My
preliminary results from a very-low calorie diet intervention in human subjects reveal that caloric restriction
induces antibiotic-like disturbances in microbiota composition and function. Fecal transplant from post-diet
humans to germ-free mice induces weight loss. Analysis of both human and mouse microbiotas revealed that
the diet-induced reconfiguration of the microbiota allowed for expansion of Clostridioides [Clostridium] difficile,
best known as a major cause of antibiotic-associated diarrhea and its severe complications. In a colonization
model, C. difficile was sufficient to drive weight loss, reduce body fat, and increase glucose tolerance without
causing acute disease. These observations have led to the hypothesis that diet interactions with the gut
microbiota and C. difficile disrupt nutrient uptake contributing to energy imbalance. The first aim of these
studies will focus on the ability of C. difficile to affect host energy balance while characterizing the mechanisms
through which it occurs. Preliminary data strongly implicates the C. difficile toxins TcdA and/or TcdB. Using
combinatorial and individual knockouts, the causative toxin will be identified and its effects on host energy
balance will be extensively characterized. To define the mechanisms through which C. difficile acts at the level
of the intestinal epithelium, the effect of sub-toxic purified toxin(s) on nutrient absorption and cell physiology will
be examined in organoid models of both the human and mouse intestine. Finally, the ability of asymptomatic
colonization to counter diet-induced obesity will be examined. The second aim of this work will examine the
mechanism through which caloric restriction affects C. difficile permissibility. Specifically, this aim will test the
hypothesis that caloric restriction depletes microbes that produce C. difficile-inhibitory secondary bile acids.
Through a humanized mouse model of caloric restriction, and sequence-guided isolation and metabolic
characterization, synthetic communities will be designed replicating diet-responsive microbes to specifically
test the role of secondary bile acid biosynthesis, and potentially identify new antagonistic interactions which are
of great relevance to C. difficile treatment and prevention. The proposed experiments in these aims will
leverage my expertise in the microbiome field with new training in obesity and metabolic disease research. An
expert interdisciplinary advisory committee, and an institutional focus on microbiome and metabolism research,
will provide the ideal environment for the proposed scientific and professional development leading to the
creation of an independent research program.
Status | Finished |
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Effective start/end date | 9/1/21 → 8/31/23 |
Funding
- National Institute of Allergy and Infectious Diseases: $248,665.00
- National Institute of Allergy and Infectious Diseases: $249,000.00
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