Presentation of exogenous antigen
by both non-classical MHC class I molecules and classical MHC class II molecules requires antigen entry into Kinase Inhibitor Library cell assay the endosomal pathway 39, 40. In agreement with this, we demonstrated that an endosomal pathway operates in the presentation of TCR-peptides associated with I-Au and Qa-1 molecules to CD4+ and CD8αα+TCRαβ+ Treg, respectively (Fig. 3 and 24). We have yet to determine whether CD4+ and CD8αα+TCRαβ+ Treg are primed by the same DC. We do, however, think this is the case due to the shared endosomal pathway and for the following reasons: (i) DC engulf Vβ8.2+ apoptotic T cells containing both the cognate CD4+ and CD8αα+TCRαβ+ Treg antigenic determinants; (ii) DC are adept at presenting antigen in the context of both MHC class II and non-classical class I molecules; (iii) CD4+ T cells can license selleck kinase inhibitor DC, e.g. by CD40L-CD40 interactions, to stimulate a CD8+ T-cell response 41 and (iv) CD4+ T cells may provide help through the secretion of cytokines that act directly on proximal CD8+ T cells 42. We have shown that injection of DC pulsed with Vβ8.2+ apoptotic T cells or TCR peptide B5 prime CD4+ Treg in vivo (Fig. 4) and that DC loaded with B5 can protect from EAE disease (Fig. 5). Data presented here and in
other studies demonstrate that DC are the most efficacious APC for inducing optimal T-cell responses 43. DC can migrate to lymphoid organs, process and present antigens from multiple sources by both MHC class I and class II pathways, cross-present non-replicating antigens and be manipulated to induce immunogenic or tolerogenic responses. However, to date immunotherapeutic studies that have attempted to harness the immuno-modulating ability of the DC, either by targeting antigens to the DC in vivo or by adoptive transfer
of antigen-loaded DC, have demonstrated minimal clinical efficacy 44. One major hindrance has been the lack of knowledge of the specific antigen targets. Here we have delineated the mechanism by which defined antigens are presented to a characterized CD4+ Treg population. Our data clearly show that disease-causing CD4+ T cells can be used to pulse DC’s for efficient in vivo priming of appropriate CD4+ as well as CD8+ Treg populations Tryptophan synthase and subsequent regulation of autoimmune disease. Thus, in this defined system we have an excellent opportunity to study the optimal way to manipulate DC therapy to induce optimal priming of the T cells involved in regulation of an autoimmune disease. In addition, our data suggest a DC-based immune intervention strategy for the induction of negative feedback regulation of T-cell-mediated inflammatory autoimmune disease. B10.PL and PL/J H-2u mice were purchased from Jackson Laboratory (Bar Harbor, ME). CD8−/− PL/J mice were kindly provided by Dr. Tak Mak 45.