Abstract
C57BL/6 mice implanted in the flank with murine Lewis lung carcinoma cells were randomized into control, anti-angiogenic, anti-PD-L1, radiotherapy (RT), RT + anti-angiogenic, RT + anti-PD-L1, and RT + anti-PD-L1 + anti-angiogenic therapy groups. Immune response and immunophenotyping were determined by flow cytometry. Vasculature analysis after RT and anti-angiogenic therapy was assessed by quantified power Doppler sonography. Antitumor response, survival, and rechallenged tumor growth were evaluated. RT increased PD-L1 expression on CD8+ T, CD4+ T, dendritic, myeloid-derived suppressor cells (MDSCs), and tumor cells and increased PD-1 expression on CD8+ and CD4+ T cells. Anti-angiogenic therapy insignificantly decreased the RT-induced PD-1 expression on CD8+ and CD4+ T cells, implying a weak reversal of the immune-suppressive environment. Transient vessel collapse was observed within days after RT, and blood flow recovered at 1 week after RT. RT + anti-PD-L1 suppressed the tumor growth, improved survival, and prolonged immune memory capable of protecting against tumor recurrence, evidenced by local accumulation of CD8+ T cells and reduction in MDSCs in microenvironment. Similar and more prominent effects were observed when anti-VEGF was added to RT + anti-PDL1 therapies, implying an additive, rather than synergistic, antitumor immunity. Phenotypic analyses revealed that anti-cancer treatments increased the proportion of effector memory T cells in TILs and splenocytes, and RT, alone or in combination with other treatments, further increased the proportion of central memory T cells in splenocytes. These results provide evidence on operating the immunosuppressive tumor environment and offer insights into the design of the new combination treatment.