IntroductionRegulatory T cells (Tregs) represent a critical barrier to immunotherapy of tumors. Established tumors suppress immune responses against their own antigens, and Tregs are emerging as a key mechanism contributing to this state of functional unresponsiveness. 1 In murine models, host Tregs become activated within days of tumor implantation. 2 Once activated, Tregs are difficult to eliminate and serve to potently and dominantly inhibit otherwise effective immune responses against the tumor. 3 We have shown that Foxp3 ϩ Tregs in the draining lymph nodes of mouse tumors become highly activated by exposure to the immunoregulatory enzyme indoleamine 2,3-dioxygenase (IDO). 4,5 In tumor-draining lymph nodes (TDLNs), IDO is expressed by a specific subset of IDO-competent plasmacytoid dendritic cells (DCs). 6 The combination of these IDO-expressing pDCs and IDO-activated Tregs renders the local milieu in the TDLNs profoundly inhibitory for T-cell activation. 7 Tregs can be suppressive, but this is not a fixed and immutable attribute. Resting Tregs are not spontaneously suppressive, and require an activation step before they become functionally inhibitory. 8 Conversely, the suppressive phenotype of Tregs is plastic. When Foxp3 is artificially ablated in mature Tregs, the suppressor phenotype is converted to a proinflammatory, T helper-like phenotype that can participate in autoimmunity. 9 Likewise, Tregs exposed to certain inflammatory signals (eg, from activated DCs or TLR ligands) can lose their suppressor activity 10 and may alter their phenotype (be "reprogrammed") to resemble proinflammatory effector cells. [11][12][13] Thus, at least in these experimental models, Tregs show a significant degree of phenotypic plasticity and are susceptible to both activation and deactivation (reprogramming) by signals from their local microenvironment.However, it is not known whether this apparent plasticity of Tregs is of biologic relevance for tumor immunology. In the current study, we test the hypothesis that, under conditions of antigendriven T-cell response to tumors, IDO functions as a critical molecular "switch" in TDLNs, regulating the phenotype and functional activity of Tregs. We show that, when IDO is active, Tregs are maintained in their normal potently suppressive state; but when IDO is blocked, Tregs undergo an inflammation-induced, interleukin-6 (IL-6)-dependent conversion into a nonsuppressive, proinflammatory phenotype similar to T-helper-17 (TH17) cells. These findings position IDO as a previously unsuspected key molecular regulator of Treg phenotype and function in TDLNs.
Methods
Reagents, cell lines, and mouse strainsA complete list of reagents, 1-methyl-D-tryptophan (1MT) preparation, tumor cell lines, and all transgenic and knockout mouse strains is given in supplemental materials (available on the Blood website; see the Supplemental Materials link at the top of the online article). Animal studies were approved by the Institutional Animal Care and Use Committee of the Medical College of Georgia. Detail...
