Various combination treatments have been considered to attain the effective therapy threshold by combining independent antitumor mechanisms against the heterogeneous characteristics of tumor cells in malignant brain tumors. In this study, the natural killer (NK) cells associated with bevacizumab (Bev) plus irinotecan (Iri) against glioblastoma multiforme (GBM) were investigated. For the experimental design, NK cells were expanded and activated by K562 cells expressing the OX40 ligand and membrane-bound IL-18 and IL-21. The effects of Bev and Iri on the proliferation and NK ligand expression of GBM cells were evaluated through MTT assay and flow cytometry. The cytotoxic effects of NK cells against Bev plus Iri-treated GBM cells were also predicted via the LDH assay in vitro. The therapeutic effect of different injected NK cell routes and numbers combined with the different doses of Bev and Iri was confirmed according to tumor size and survival in the subcutaneous (s.c) and intracranial (i.c) U87 xenograft NOD/SCID IL-12Rγnull mouse model. The presence of injected-NK cells in tumors was detected using flow cytometry and immunohistochemistry ex vivo. As a result, Iri was found to affect the proliferation and NK ligand expression of GBM cells, while Bev did not cause differences in these cellular processes. However, the administration of Bev modulated Iri efficacy in the i.c U87 mouse model. NK cells significantly enhanced the cytotoxic effects against Bev plus Iri-treated GBM cells in vitro. Although the intravenous (IV) injection of NK cells in combination with Bev plus Iri significantly reduced the tumor volume in the s.c U87 mouse model, only the direct intratumorally (IT) injection of NK cells in combination with Bev plus Iri elicited delayed tumor growth in the i.c U87 mouse model. Tumor-infiltrating NK cells were detected after IV injection of NK cells in both s.c and i.c U87 mouse models. In conclusion, the potential therapeutic effect of NK cells combined with Bev plus Iri against GBM cells was limited in this study. Accordingly, further research is required to improve the accessibility and strength of NK cell function in this combination treatment.
Background
Recent clinical trials utilizing antigen-pulsed dendritic cells have demonstrated increased survival of the vaccinated cancer patients. Besides, the cytoplasmic transduction peptide has not only excellent transcellular efficiency but also a strong tendency to remain in the cytoplasm after transduction without migrating into the nucleus. In this study, we investigated the effectiveness of immunotherapy against malignant gliomas using DCs pulsed with cytoplasmic transduction peptide (CTP)-fused recombinant protein combined with programmed cell death protein 1 blockade.
Methods
The expression of tumor associated antigen (WT1 and BIRC5) on glioblastoma target cells was confirmed by western blot. The effect of CTP-rhWT1 and/or CTP-rhBIRC5 on DCs was determined. The immunophenotypes of VaxDCs pulsed with CTP-rhWT1 and/or CTP-rhSBIRC5 was confirmed by flow cytometry and the cytokine production levels of T helper polarization were measured by enzyme-linked immunosorbent assay. The IFN-γ-enzyme linked immunospot assay and lactate dehydrogenase release assay were done to estimate the cytotoxic activity of CTLs stimulated by CTP-fused recombinant protein pulsed VaxDCs along with PD1 blockade against malignant glioma cells expressing WT1 and BIRC5.
Results
The CTP-rhWT1 and CTP-rhBIRC5 enhanced activating markers of DCs. Besides, the CTP-rhWT1 and CTP-rhBIRC5 combination resulted in Th1 cytokine polarization. The increase in number of IFN-γ-secreting cells paralleled with enhanced cytotoxicity of CTLs-stimulated by CTP-fused recombinant protein pulsed VaxDCs against glioblastoma target cells.
Conclusions
Our study suggested that treatment of CTP-fused recombinant protein along with PD1 blockade, which enhances cytotoxicity of DCs, could be an effective immunotherapy strategy for glioblastoma.
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