Abstract
Study of gut microbiota control of anti-tumor immunity (ATI) identifies Bacteroides rodentium and the human-related Bacteroides uniformis species to be capable of inducing ATI and limiting melanoma development in germ-free (GF), complex microbiome, or wild-type (WT) mice. Enhanced CD8+ T cell infiltration within tumors of mice harboring B. rodentium coincides with increased expression of immune-stimulating pathways. Metabolomic analyses identify lower tryptophan levels in the cecal samples of GF mice harboring B. rodentium. In silico genomic reconstruction reveals that B. rodentium and B. uniformis harbor tryptophanase A (TnaA) and aromatic aminotransferase genes, which degrade tryptophan to indoles. Administration of B. uniformis harboring TnaA mutant fails to inhibit melanoma growth. Notably, administration of indoles effectively induces ATI and inhibits melanoma development. Correspondingly, the levels of bacterially encoded tryptophan-degrading enzymes are higher in cohorts of patients with melanoma responding to immunotherapy. These findings identify indoles as tryptophan breakdown products capable of inducing ATI resulting in melanoma inhibition.