Jake Atkinson, Joshua Chopin, Eva Bezak, Hien Le, Ivan Kempson
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引用次数: 0
摘要
金属纳米粒子可使癌症对放射治疗敏感,但其作用机制十分复杂。概念灵感来自物理剂量沉积理论,但也发现了各种化学和生物因素。与 DNA 损伤修复因子相比,测量真正的 DNA 损伤所面临的挑战限制了对数据的解读。在这里,我们首次应用了一种新的检测方法 STRIDE 来测量暴露于金纳米粒子和辐射的三阴性乳腺癌模型 4T1 细胞中的 DNA 双链断裂(DSB),并将其与常见的 DSB 修复 γH2AX 检测方法进行了比较。STRIDE检测显示,与不含纳米粒子的细胞相比,含纳米粒子的细胞在照射15分钟后的DSB检测没有增加。金纳米粒子延长了辐照后DSB的检测时间,并延迟了DSB的修复。数据显示,没有证据表明纳米粒子增加了辐射剂量沉积,而是纳米粒子增强了辐射生物学效应,包括扰乱了基本 DDR 机制的招募,从而损害了 DNA 修复过程。
Gold Nanoparticles Cause Radiosensitization in 4T1 Cells by Inhibiting DNA Double Strand Break Repair: Single Cell Comparisons of DSB Formation and γH2AX Expression.
Metal nanoparticles sensitize cancers to radiotherapy however their mechanisms of action are complex. The conceptual inspiration arose from theories of physical dose deposition however various chemical and biological factors have also been identified. Interpretation of data has been limited by challenges in measuring true DNA damage compared to DNA damage repair factors. Here, we applied a new assay, STRIDE, for the first time to measure DNA double strand breaks (DSBs) in 4T1 cells as a model of triple negative breast cancer exposed to gold nanoparticles and radiation, and compared this to the common γH2AX assay for DSB repair. The STRIDE assay showed no increase in DSB detection 15 mins after irradiation for cells containing nanoparticles compared to cells without. Gold nanoparticles led to prolonged detection of DSBs after irradiation and delayed the DSB repair. The data show no evidence of increased radiation dose deposition with nanoparticles, but rather enhanced radiobiological effects resulting from nanoparticles which includes disruption of the recruitment of essential DDR machinery, thereby impairing DNA repair processes.
期刊介绍:
ChemPhysChem is one of the leading chemistry/physics interdisciplinary journals (ISI Impact Factor 2018: 3.077) for physical chemistry and chemical physics. It is published on behalf of Chemistry Europe, an association of 16 European chemical societies.
ChemPhysChem is an international source for important primary and critical secondary information across the whole field of physical chemistry and chemical physics. It integrates this wide and flourishing field ranging from Solid State and Soft-Matter Research, Electro- and Photochemistry, Femtochemistry and Nanotechnology, Complex Systems, Single-Molecule Research, Clusters and Colloids, Catalysis and Surface Science, Biophysics and Physical Biochemistry, Atmospheric and Environmental Chemistry, and many more topics. ChemPhysChem is peer-reviewed.