Department of Radiation Oncology, VU University Medical Center, Amsterdam, the Netherlands.
Department of Neurosurgery, Neuro-oncology Research Group, VU University Medical Center, Amsterdam, the Netherlands.
Mol Cancer Ther. 2018 Feb;17(2):347-354. doi: 10.1158/1535-7163.MCT-17-0480. Epub 2017 Sep 27.
Glioblastoma (GBM) is a highly aggressive and lethal brain cancer type. PI3K and MAPK inhibitors have been studied preclinically in GBM as monotherapy, but not in combination with radiotherapy, which is a key component of the current standard treatment of GBM. In our study, GBM cell lines and patient representative primary cultures were grown as multicellular spheroids. Spheroids were treated with a panel of small-molecule drugs including MK2206, RAD001, BEZ235, MLN0128, and MEK162, alone and in combination with irradiation. Following treatment, spheroid growth parameters (growth rate, volume reduction, and time to regrow), cell-cycle distribution and expression of key target proteins were evaluated. , the effect of irradiation (3 × 2 Gy) without or with MEK162 (50 mg/kg) was studied in orthotopic GBM8 brain tumor xenografts with endpoints tumor growth and animal survival. The MAPK-targeting agent MEK162 was found to enhance the effect of irradiation as demonstrated by growth inhibition of spheroids. MEK162 downregulated and dephosphorylated the cell-cycle checkpoint proteins CDK1/CDK2/WEE1 and DNA damage response proteins p-ATM/p-CHK2. When combined with radiation, this led to a prolonged DNA damage signal. data on tumor-bearing animals demonstrated a significantly reduced growth rate, increased growth delay, and prolonged survival time. In addition, RNA expression of responsive cell cultures correlated to mesenchymal stratification of patient expression data. In conclusion, the MAPK inhibitor MEK162 was identified as a radiosensitizer in GBM spheroids and in orthotopic GBM xenografts The data are supportive for implementation of this targeted agent in an early-phase clinical study in GBM patients.
胶质母细胞瘤(GBM)是一种高度侵袭性和致命性的脑癌类型。PI3K 和 MAPK 抑制剂已在 GBM 中作为单药进行了临床前研究,但尚未与放疗联合使用,放疗是目前 GBM 标准治疗的关键组成部分。在我们的研究中,GBM 细胞系和患者代表性原代培养物被培养为多细胞球体。球体用一组小分子药物进行处理,包括 MK2206、RAD001、BEZ235、MLN0128 和 MEK162,单独使用和联合使用放疗。治疗后,评估球体生长参数(生长速度、体积减少和重新生长时间)、细胞周期分布和关键靶蛋白的表达。还研究了没有或有 MEK162(50mg/kg)的 3×2Gy 照射对原位 GBM8 脑肿瘤异种移植的影响,终点为肿瘤生长和动物存活。MAPK 靶向药物 MEK162 被发现增强了照射的效果,表现为球体生长抑制。MEK162 下调并去磷酸化细胞周期检查点蛋白 CDK1/CDK2/WEE1 和 DNA 损伤反应蛋白 p-ATM/p-CHK2。与辐射联合使用时,这会导致 DNA 损伤信号延长。关于荷瘤动物的数据表明,肿瘤生长速度显著降低,生长延迟增加,存活时间延长。此外,对有反应的细胞培养物的 RNA 表达与患者表达数据的间质分层相关。总之,MAPK 抑制剂 MEK162 被鉴定为 GBM 球体和原位 GBM 异种移植中的放射增敏剂。这些数据支持在 GBM 患者的早期临床研究中实施这种靶向药物。
