Octamer 4 (Oct4), a member of the POU family of transcription factors, plays a key role in the maintenance of pluripotency and proliferation potential of embryonic stem cells. Cancer stem cell-like cells (CSCLC) are reported to be a minor population in tumors or even in tumor cell lines which also express Oct4. The role of Oct4 in CSCLCs still remains to be defined. In our study, we show that, in vitro, almost all murine Lewis lung carcinoma 3LL cells and human breast cancer MCF7 cells express Oct4 at high levels. This expression of Oct4 is successfully reduced by small interfering RNA, which eventually results in cell apoptosis. The signal pathway Oct4/ Tcl1/Akt1 has been observed to be involved in this event. The repression of Oct4 reduces Tcl1 expression and further downregulates the level of p-Ser.473-Akt1. In vivo, only f5% of tumor cells were detected to express Oct4 in established 3LL and MCF7 tumor models, respectively. Small interfering RNA against Oct4 successfully decreases the CSCLCs and markedly inhibits tumor growth. In summary, we show that Oct4 might maintain the survival of CSCLCs partly through Oct4/Tcl1/ Akt1 by inhibiting apoptosis, which strongly indicates that targeting Oct4 may have important clinical applications in cancer therapy. [Cancer Res 2008;68(16):6533-40]
Thus far, immunotherapies based on one or a few immunostimulatory molecules have shown limited antitumor efficacy. This highlights the need to use multiple immunostimulatory molecules, to target different immune cells, including immunosuppressive cells, simultaneously. Consequently, in this study, we delivered intratumorally via protein transfer four molecules, including the chemotactic molecules secondary lymphoid tissue chemokine and Fas ligand and the costimulatory molecules 4-1BBL and TNF-related activation-induced cytokine. Secondary lymphoid tissue chemokine and Fas ligand together can attract an array of immune cells and induce apoptosis in CD4+CD25+ regulatory T cells (Treg), whereas 4-1BBL and TRANCE together can stimulate T cells and dendritic cells (DCs). We show that the transfer of all four molecules increases tumor-infiltrating neutrophils, DCs, and CD4+ and CD8+ T cells and decreases intratumoral Treg. We show that the treatment favors the generation of a Th1 cytokine milieu at the tumor site, which is attributed not only to an increase in IL-12-producting DCs and IFN-γ-producing CD8+ T cells, but also to a decrease in IL-10-producing Treg. Importantly, in the L5178Y lymphoma model, we show that compared with transfer of the chemotactic molecules alone or the costimulatory molecules alone, transfer of all four molecules demonstrates stronger antitumor responses against established tumors. Furthermore, we show that the antitumor responses elicited by transfer of all four molecules are mediated by long-term, systemic antitumor immunity. Hence, this study demonstrates for the first time that combinatorial use of chemotactic and costimulatory molecules provides a useful strategy for enhancing antitumor responses.
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