[摘要] An elusive objective for tumor immunologists has been the development of an effective tumor vaccine capable of inducing potent immune responses to eliminate established tumors and induce long-term protective antitumor immunity. Dendritic cells (DCs) are potent inducers of immunity and represent a promising tool for the purpose of immune-based tumor therapies. However, DC-based vaccines have enjoyed only limited success in clinical trials, probably due to the use of immature/intermediate mature DCs that maintain tolerance during the steady state, or to the use of non-polarized DCs which lack the proper cytokine production that favors cellular immune responses needed to eliminate established tumors. The failure of past tumor vaccines demonstrates a need to examine and enhance immunization strategies on multiple levels. The underlying hypothesis for these studies was that combining a DC1 polarization signal with an effective antigen-loading strategy will result in enhanced tumor immunotherapy. Our first aim was to compare cytosolic and membrane-bound antigen presentation of tumor-derived proteins by DCs following three different antigen-loading strategies; coculture of DCs and tumor cells, feeding DCs with tumor lysate, and fusion of DCs and tumor cells. We demonstrated that both DC-tumor coculture and fusion result in a higher level of tumor-derived peptide presentation compared to feeding DCs with tumor lysate. Our second aim was to develop a murine DC1 polarization model to evaluate DC1-based tumor immunotherapy. Herein, we described the synergistic affect of TLR3 and TLR9 ligation on IL-12p70 production by murine DCs, characterizing the timing and exhaustion of IL-12p70 production. Furthermore, we examined the ability of polarized DCs to stimulate T cell proliferation and cytokine secretion in response to a model antigen in vitro. For our third aim we examined the capacity of DC1s to stimulate immune responses to a model antigen as well as native tumor antigens in vivo and tested the therapeutic effect of tumor-loaded DC1 vaccines. These studies demonstrate the ability of antigen-loaded polarized DCs to induce strong Th1-mediated anti-tumor immunity characterized by tumor infiltrating CD4+ T cells and macrophages, but not CD8+ T cells, resulting in tumor growth inhibition.