PROJECT SUMMARY The human microbiome is an underappreciated contributor to drug disposition and treatment outcomes, supported by associations in human cohorts, controlled studies in preclinical models, and high-throughput in vitro screens. However, despite considerable recent progress in this emerging area of study there are still major gaps in knowledge regarding the fundamental mechanisms through which human gut microbes impact pharmacology. Research in the Turnbaugh lab over the past 5 years (supported by 1R01HL122593-01A1) was focused on understanding the role of the prevalent human gut Actinobacterium Eggerthella lenta in drug metabolism and disposition. While we began by focusing on the gut bacterial inactivation of the cardiac drug digoxin, used to treat heart failure and cardiac arrythmias, our results together with the broader scientific literature have further implicated E. lenta as a key bacterial species for the metabolism of diverse drugs, dietary small molecules, and host metabolites. We established a robust comparative genomics toolkit for studying E. lenta that could be readily extended to other genetically intractable gut bacterial species. In the coming years we will continue to leverage E. lenta as a test case, with a focus on two general challenges at the interface of microbiome research and pharmacology. In Aim 1, we will study the endogenous substrates for gut bacterial enzymes involved in drug metabolism, building on the surprising observation that the same enzyme responsible for digoxin metabolism is also necessary and sufficient to activate pro-inflammatory Th17 cells in the murine gut, exacerbating mouse models of colitis. Then, in Aim 2, we will determine the mechanism through which E. lenta inhibits the activity of the key intestinal drug efflux transporter P-glycoprotein, providing the first step towards a more comprehensive view of the role of the microbiome in drug disposition that accounts for microbiome-dependent changes in absorption, distribution, metabolism, and elimination. Together, these studies emphasize the utility and feasibility of hypothesis-driven mechanistic studies, meant to complement the wealth of data from large-scale clinical cohort studies and high-throughput screens. Our results have already provided multiple insights that both inform and complicate our model of how the microbiome impacts drugs, emphasizing the numerous challenges that lie ahead prior to translating this work to achieve our long-term goal of microbiome-based precision medicine.