Abstract
Engineering native gut bacteria offers a route to persistent, programmable therapeutics, yet many dominant taxa remain genetically intractable. Lachnospiraceae are a prevalent and abundant family in the human gut microbiome, possessing metabolic functions generally associated with health (1) . Despite their promise as engineered live biotherapeutics, genetic manipulation of Lachnospiraceae remains challenging. Here, we develop a modular toolkit for Lachnospiraceae engineering, including constitutive and inducible expression and chromosomal integration systems. Applying this toolkit to the native commensal Coprococcus comes , we program secretion of the mammalian cytokine interleukin-22 (IL-22) in the mouse intestinal tract where it elicits ileal transcriptional responses consistent with cytokine signaling. In a mouse model of metabolic associated steatotic liver disease, IL-22-secreting C. comes improves glucose homeostasis and attenuates hepatic steatosis. This work demonstrates that a native Lachnospiraceae chassis can be genetically programmed to modulate host metabolic and immune physiology. The toolkit provides a generalizable foundation for Lachnospiraceae-derived microbiome therapeutics and for probing causal links between Lachnospiraceae gene programs and host phenotypes.