Patients with Inflammatory Bowel Disease (IBD) experience relapsing and remitting periods of inflammation in their gastrointestinal tract. During periods of inflammation, many patients exhibit an alteration in colonic microbial communities resulting in an increase in facultative anaerobes (primarily members of the Enterobacteriaceae family, such as E. coli). Similar changes in the gut microbiota composition are observed in murine models of colitis. Previous work from our laboratory indicates that the expansion of the Enterobacteriaceae population can be abrogated in part, by inhibiting two of the metabolic pathways utilized by these bacteria to outgrow during inflammation. Inhibition of this Enterobacteriaceae bloom reduced gut inflammation. This finding suggests that microbial dysbiosis aggravates inflammation leading to poorer host outcomes and supports the approach of specifically targeting the microbiota as a means of ameliorating disease. The objective of this study is to further elucidate the metabolic pathways utilized by facultative anaerobes to outgrow during inflammatory conditions. My preliminary data suggest a counterintuitively positive relationship between host-derived reactive oxygen species and the outgrowth of Enterobacteriaceae. I hypothesize that reactive oxygen species allow facultative anaerobic Enterobacteriaceae to respire in the inflamed gut lumen.
The specific aims of this proposal are to (1) determine the contribution of host-derived reactive oxygen species in the outgrowth of E. coli in murine models of colitis and (2) determine the mechanistic relationship between cytochrome bd-II oxidase (AppBC) and reactive oxygen species in vitro. To test my hypotheses, I will use a strategic combination of host and bacterial genetics in both chemically-induced and genetic models of colitis. Changes in oxygen metabolism will be characterized using immunohistochemical staining, bacterial reporter strains, microelectrode-based technology, and metagenomics. The potential impact of my research will be to understand how oxygen availability influences Enterobacteriaceae outgrowth during inflammation and explore the role reactive oxygen species play in this process. A positive outcome may lay the foundation for novel treatment strategies for IBD patients. Additionally, the training plan I have laid out will help me achieve my goal of becoming an academic researcher at a major university or hospital system. I will be mentored by my Spnosor Sebastian Winter, Ph.D., an expert in host-microbe interactions during inflammation, and by my Co-Sponsor Vanessa Sperandio, Ph.D., an expert in bacterial pathogenesis and gene regulation. Along with support from the Graduate School and Career Development Office, Dr. Winter and Dr. Sperandio will help me attain and strengthen skills necessary for success in academic research, including responsible conduct, technical expertise, and scientific communication skills.
The mechanisms driving Inflammatory Bowel Disease (IBD) associated-microbial dysbiosis are not completely understood. This proposal aims to explore the relationship between the production of host-derived reactive oxygen species and the outgrowth of Enterobacteriaceae during inflammation. Results from this proposal will aid in the development of new IBD therapeutics that specifically target the microbial metabolic pathways driving dysbiosis.