Translational Radiation Biology, Institute of Cancer Sciences, Wolfson Wohl Cancer Research Centre, University of Glasgow, Glasgow, United Kingdom.
Department of Clinical Neurosciences, Division of Neurosurgery, ED Adrian Building, Forvie Site, Robinson Way, Cambridge University, Cambridge, United Kingdom.
Cancer Res. 2015 Oct 15;75(20):4416-28. doi: 10.1158/0008-5472.CAN-14-3790. Epub 2015 Aug 17.
Glioblastoma is the most common form of primary brain tumor in adults and is essentially incurable. Despite aggressive treatment regimens centered on radiotherapy, tumor recurrence is inevitable and is thought to be driven by glioblastoma stem-like cells (GSC) that are highly radioresistant. DNA damage response pathways are key determinants of radiosensitivity but the extent to which these overlapping and parallel signaling components contribute to GSC radioresistance is unclear. Using a panel of primary patient-derived glioblastoma cell lines, we confirmed by clonogenic survival assays that GSCs were significantly more radioresistant than paired tumor bulk populations. DNA damage response targets ATM, ATR, CHK1, and PARP1 were upregulated in GSCs, and CHK1 was preferentially activated following irradiation. Consequently, GSCs exhibit rapid G2-M cell-cycle checkpoint activation and enhanced DNA repair. Inhibition of CHK1 or ATR successfully abrogated G2-M checkpoint function, leading to increased mitotic catastrophe and a modest increase in radiation sensitivity. Inhibition of ATM had dual effects on cell-cycle checkpoint regulation and DNA repair that were associated with greater radiosensitizing effects on GSCs than inhibition of CHK1, ATR, or PARP alone. Combined inhibition of PARP and ATR resulted in a profound radiosensitization of GSCs, which was of greater magnitude than in bulk populations and also exceeded the effect of ATM inhibition. These data demonstrate that multiple, parallel DNA damage signaling pathways contribute to GSC radioresistance and that combined inhibition of cell-cycle checkpoint and DNA repair targets provides the most effective means to overcome radioresistance of GSC.
胶质母细胞瘤是成人中最常见的原发性脑肿瘤,基本上无法治愈。尽管以放疗为中心的积极治疗方案,但肿瘤复发是不可避免的,据认为这是由高度耐辐射的胶质母细胞瘤干细胞(GSC)驱动的。DNA 损伤反应途径是放射敏感性的关键决定因素,但这些重叠和并行信号成分在多大程度上有助于 GSC 耐辐射尚不清楚。使用一组原发性患者来源的胶质母细胞瘤细胞系,我们通过克隆存活测定证实,GSC 比配对的肿瘤体群具有显著更高的耐辐射性。GSC 中上调了 DNA 损伤反应靶标 ATM、ATR、CHK1 和 PARP1,并且在照射后 CHK1 被优先激活。因此,GSC 表现出快速的 G2-M 细胞周期检查点激活和增强的 DNA 修复。抑制 CHK1 或 ATR 成功地消除了 G2-M 检查点功能,导致有丝分裂灾难增加和放射敏感性适度增加。ATM 的抑制对细胞周期检查点调节和 DNA 修复具有双重影响,与单独抑制 CHK1、ATR 或 PARP 相比,与 GSC 的放射增敏作用相关。PARP 和 ATR 的联合抑制导致 GSC 的显著放射增敏,其程度大于体群,并且超过 ATM 抑制的作用。这些数据表明,多个平行的 DNA 损伤信号途径有助于 GSC 耐辐射,并且联合抑制细胞周期检查点和 DNA 修复靶标是克服 GSC 耐辐射性的最有效手段。
