Department of Radiation Oncology, University of Pennsylvania, Philadelphia, PA, USA.
Department of Radiation Oncology, McGuire VA Medical Center, Richmond, VA, USA.
Oncogene. 2020 May;39(22):4344-4357. doi: 10.1038/s41388-020-1300-x. Epub 2020 Apr 25.
We explore a novel strategy of activating immune signaling through increased micronuclei formation utilizing a cell cycle checkpoint inhibitor to drive cell cycle progression following ionizing radiation. The Chk1/2 inhibitor AZD7762 is used to abrogate radiation therapy (RT)-induced G2/M cell cycle arrest in multiple cell lines and, we find that this therapeutic combination promotes increased micronuclei formation in vitro and subsequently drives increased type I interferon signaling and cytotoxic T-cell activation. In vivo studies using B16-F10 melanoma cancer cells implanted in C57/BL6 mice demonstrate improved rates of tumor control at the abscopal (unirradiated) site, located outside of the radiation field, only in the AZD7762 + RT group, with a corresponding reduction in mean tumor volume, increase in the CD8 T-cell population, and immune activated gene signaling. Our results demonstrate that targeted inhibition of cell cycle checkpoint activation following ionizing radiation drives increased production of immunogenic micronuclei, leading to systemic tumor response with potential future clinical benefit.
我们探索了一种通过增加微核形成来激活免疫信号的新策略,利用细胞周期检查点抑制剂在电离辐射后驱动细胞周期进程。使用 Chk1/2 抑制剂 AZD7762 来消除多种细胞系中放射治疗 (RT) 诱导的 G2/M 细胞周期阻滞,我们发现这种治疗组合促进了体外微核形成的增加,随后驱动了 I 型干扰素信号和细胞毒性 T 细胞的激活。使用在 C57/BL6 小鼠中植入的 B16-F10 黑色素瘤癌细胞进行的体内研究表明,仅在 AZD7762+RT 组中,在远离放射野的远处(未照射)部位的肿瘤控制率得到了改善,相应地,平均肿瘤体积减小,CD8 T 细胞群体增加,以及免疫激活基因信号。我们的结果表明,电离辐射后靶向抑制细胞周期检查点的激活会导致免疫原性微核的产生增加,从而导致全身肿瘤反应,具有潜在的临床获益。
