The gut microbiome has a tremendous impact on health and disease, actively contributing to obesity, diabetes, inflammatory bowel disease, cardiovascular diseases, and several poorly understood neurological disorders. We do not yet have the necessary tools to precisely probe these microbial communities, though such tools could unlock extensive benefits to human health. Elucidating the contributions of individual species or consortia of bacteria would provide a rational basis for understanding microbiota-controlled disease and lead to novel therapies. To carry out the fundamental research planned in this proposal, we will tackle three major problems: First, we will build the first set of molecular tools that effectively and precisely modulate the microbiome bacteria; second, we will analyze the multiscale dynamics of microbial communities; and third, we will construct an ingestible biosensor for real-time monitoring of microbiome populations. Although antibiotics and fecal transplants can reconfigure microbial consortia, they do not precisely target individual bacteria. Conversely, antimicrobial peptides (AMPs) have evolved to selectively attack pathogenic bacteria but do not target microbiome bacteria, constituting desirable scaffolds for molecular engineering and potential sources of microbiome-targeting agents. We will develop a new computational peptide design methodology, based on classical and hybrid-quantum mechanical molecular dynamics (MD) simulations, to create a groundbreaking assessment of the dynamical and emergent properties of AMPs. Chemical synthesis and large-scale screening will confirm predicted selectivity against microbiome species, and a machine learning workflow will connect sequences of individual peptides to their dynamics and activity. We will then apply the synthetic AMPs to interrogate the human microbiome by selectively removing species during bacterial consortia experiments, to be carried out in bioreactors, under regular or anaerobic conditions. We will pair our experiments with whole-cell metabolic network models, providing a systems biology perspective to the analysis of inter-species interactions. An integrated ingestible biosensing device will be developed to monitor the microbiome by electrochemically sensing unique biomarkers from gut microbes. This will provide the first real-time measurements of microbiome composition and will be integrated to our bioreactors for testing, to ultimately be used for in vivo tests. This work will build the first set of molecular and computational tools for microbiome engineering and will lay the foundation to address critical gaps in our understanding of the gut micro-environment, and of the contributions of gut bacteria to the etiology of disease. Grounded in our demonstrated expertise in synthetic biology, computer science, microbiology, and electrical engineering, this project will provide a computational- experimental framework for developing a peptide encyclopedia for the gut microbiome, in line with NIH's public health mission and goals.
The gut microbiome plays roles in nutrition, immunity, metabolism, and several poorly understood neurological disorders. Suitable tools, however, do not yet exist for engineering the microbial communities that constitute the human microbiome. The proposed research introduces the first molecular tools to precisely understand the functions of microbiome communities in our health and disease in order to then delineate therapeutic interventions for diseases mediated by the gut microbiota, thereby addressing NIH's public health mission.
