ABSTRACT: Peripheral immune tolerance is a key physiological mechanism sustained by the activity of regulatory cells that impedes immune reaction to self and non-dangerous antigens. Interleukin 10 (IL-10) plays a key immunosuppressive role in this system by inhibiting effector cells and instructing regulatory cells. While the molecular mechanisms and gene expression patterns defining identity and function of T regulatory cells have been deeply studied, the molecular pattern driving tolerogenicity in myeloid antigen presenting cells remain less defined. We have investigated the molecular mechanisms underlying IL-10 tolerogenic activity in human myeloid cells. By performing chromatin and transcriptomic studies in IL-10-induced monocyte-derived DC, we have found that IL-10 imprinted a pattern of accessible enhancers, which were exploited by Aryl Hydrocarbon Receptor (AHR) to promote the expression of a set of core genes. Functional studies demonstrated that AHR activation and core gene expression were necessary for IL-10-mediated induction of tolerogenic functions in in vitro differentiated DC. AHR exerted its role down-stream to IL-10 inducing tolerogenic and repressing inflammatory genes. Analyses of naturally occurring tolerogenic DC from peripheral blood showed that the IL-10-induced AHR module was active also in vivo in healthy conditions. In multiple sclerosis patients, instead, we observed significant alterations in the IL-10-induced AHR module that correlated with functional defects and reduced frequencies of in vitro differentiated and in vivo occurring IL-10-induced tolerogenic DC, respectively. This study unveiled a previously undescribed IL-10-induced molecular mechanism required for establishing tolerogenic functions in human myeloid cells.