Li Lijun, Chen Renxiang, Lin Yun-Tien, Humayun Arslon, Fornace Albert J, Li Heng-Hong
Department of Oncology, Georgetown University Medical Center, Washington, DC.
Georgetown College, Georgetown University, Washington, DC.
Adv Radiat Oncol. 2020 Oct 24;6(1):100601. doi: 10.1016/j.adro.2020.10.014. eCollection 2021 Jan-Feb.
Preclinical and clinical data indicate that radiation therapy acts as an immune modifier, having both immune-stimulatory and immunosuppressive effects on the tumor-immune microenvironment (TIME). 3.3'-diindolylmethane (DIM) sensitizes tumor cells to radiation and protects mice from lethal doses of total body irradiation. We hypothesize that protecting nontumoral cells from the adverse effects of radiation treatment (RT) may help to correct immunosuppression resulting from radiation.
We generated tumor graft models using immune-competent and immune-deficient mouse strains. Narrow-beamed radiation was targeted to tumor sites using shielding. Tumor regression was monitored after DIM and RT versus RT alone. The effects of DIM on the efficacy of RT were assessed using immunohistochemistry staining and gene expression profiling. Complete blood counts, clonogenic cell survival assays, and global gene expression profiling of cultured cells were performed to study DIM's radioprotective effects on normal cells.
DIM enhanced tumor regression after RT in immune-competent but not immune-deficient mice. Data indicated that DIM increased intratumoral immune cells after RT, contributing to enhanced immunologic responses such as adhesion and antigen processing. DIM protected normal cells from radiation-induced immediate injuries in vitro and in vivo Transcriptomic profiling of cultured cells showed that DIM treatment mildly increased expression of some genes that are normally induced after radiation, such as genes involved in cell cycle arrest and apoptosis.
In this study, using cultured cells and preclinical breast cancer models, we show that DIM protects normal cells from radiation-induced immediate cellular injury and combination treatment of DIM and radiation potentiates antitumor immune responses and enhances the efficacy of RT.
临床前和临床数据表明,放射治疗可作为一种免疫调节剂,对肿瘤免疫微环境(TIME)具有免疫刺激和免疫抑制作用。3,3'-二吲哚甲烷(DIM)可使肿瘤细胞对辐射敏感,并保护小鼠免受致死剂量的全身照射。我们假设保护非肿瘤细胞免受放射治疗(RT)的不良反应可能有助于纠正放疗引起的免疫抑制。
我们使用具有免疫活性和免疫缺陷的小鼠品系建立了肿瘤移植模型。使用屏蔽装置将窄束辐射靶向肿瘤部位。监测DIM和RT联合治疗与单独RT治疗后的肿瘤消退情况。使用免疫组织化学染色和基因表达谱分析评估DIM对RT疗效的影响。进行全血细胞计数、克隆形成细胞存活测定以及培养细胞的全基因组表达谱分析,以研究DIM对正常细胞的辐射防护作用。
在具有免疫活性的小鼠中,DIM增强了RT后的肿瘤消退,但在免疫缺陷小鼠中未观察到这种现象。数据表明,DIM增加了RT后肿瘤内的免疫细胞,有助于增强免疫反应,如黏附和抗原处理。DIM在体外和体内保护正常细胞免受辐射诱导的即时损伤。培养细胞的转录组分析表明,DIM处理轻度增加了一些通常在辐射后诱导表达的基因的表达,例如参与细胞周期停滞和凋亡的基因。
在本研究中,我们使用培养细胞和临床前乳腺癌模型表明,DIM保护正常细胞免受辐射诱导的即时细胞损伤,DIM与放疗联合治疗可增强抗肿瘤免疫反应并提高RT的疗效。
