Physics Department, School of Applied Mathematical and Physical Sciences, National Technical University of Athens (NTUA), Zografou, 15780 Athens, Greece.
Department of Radiation Oncology, St. Jude Children's Research Hospital, Memphis, TN, USA.
Semin Cancer Biol. 2016 Jun;37-38:77-95. doi: 10.1016/j.semcancer.2016.02.002. Epub 2016 Feb 9.
Exposure of cells to any form of ionizing radiation (IR) is expected to induce a variety of DNA lesions, including double strand breaks (DSBs), single strand breaks (SSBs) and oxidized bases, as well as loss of bases, i.e., abasic sites. The damaging potential of IR is primarily related to the generation of electrons, which through their interaction with water produce free radicals. In their turn, free radicals attack DNA, proteins and lipids. Damage is induced also through direct deposition of energy. These types of IR interactions with biological materials are collectively called 'targeted effects', since they refer only to the irradiated cells. Earlier and sometimes 'anecdotal' findings were pointing to the possibility of IR actions unrelated to the irradiated cells or area, i.e., a type of systemic response with unknown mechanistic basis. Over the last years, significant experimental evidence has accumulated, showing a variety of radiation effects for 'out-of-field' areas (non-targeted effects-NTE). The NTE involve the release of chemical and biological mediators from the 'in-field' area and thus the communication of the radiation insult via the so called 'danger' signals. The NTE can be separated in two major groups: bystander and distant (systemic). In this review, we have collected a detailed list of proteins implicated in either bystander or systemic effects, including the clinically relevant abscopal phenomenon, using improved text-mining and bioinformatics tools from the literature. We have identified which of these genes belong to the DNA damage response and repair pathway (DDR/R) and made protein-protein interaction (PPi) networks. Our analysis supports that the apoptosis, TLR-like and NOD-like receptor signaling pathways are the main pathways participating in NTE. Based on this analysis, we formulate a biophysical hypothesis for the regulation of NTE, based on DNA damage and apoptosis gradients between the irradiation point and various distances corresponding to bystander (5mm) or distant effects (5cm). Last but not least, in order to provide a more realistic support for our model, we calculate the expected DSB and non-DSB clusters along the central axis of a representative 200.6MeV pencil beam calculated using Monte Carlo DNA damage simulation software (MCDS) based on the actual beam energy-to-depth curves used in therapy.
细胞暴露于任何形式的电离辐射(IR)预计会引起多种 DNA 损伤,包括双链断裂(DSBs)、单链断裂(SSBs)和氧化碱基,以及碱基丢失,即碱基缺失。IR 的损伤潜力主要与电子的产生有关,电子通过与水的相互作用产生自由基。自由基反过来攻击 DNA、蛋白质和脂质。通过直接沉积能量也会引起损伤。这些类型的 IR 与生物材料的相互作用统称为“靶向效应”,因为它们仅指受照射的细胞。早期的、有时是“轶事”的发现指出了与受照射细胞或区域无关的 IR 作用的可能性,即一种具有未知机制基础的全身反应类型。在过去的几年中,大量的实验证据已经积累起来,显示了“场外”区域的各种辐射效应(非靶向效应-NTE)。这些非靶向效应包括从“场内”区域释放化学和生物介质,从而通过所谓的“危险”信号传递辐射损伤。NTE 可以分为两大类:旁观者和远处(全身)。在这篇综述中,我们使用文献中的改进文本挖掘和生物信息学工具,收集了详细的涉及旁观者或全身效应的蛋白质列表,包括临床上相关的远隔效应,我们确定了这些基因中有哪些属于 DNA 损伤反应和修复途径(DDR/R),并制作了蛋白质-蛋白质相互作用(PPi)网络。我们的分析表明,细胞凋亡、TLR 样和 NOD 样受体信号通路是参与 NTE 的主要通路。基于这一分析,我们根据照射点与旁观者(5mm)或远处效应(5cm)的各种距离之间的 DNA 损伤和细胞凋亡梯度,提出了 NTE 调控的生物物理假设。最后但同样重要的是,为了为我们的模型提供更现实的支持,我们根据实际治疗中使用的束能-深度曲线,使用基于蒙特卡罗的 DNA 损伤模拟软件(MCDS)计算了代表 200.6MeV 铅笔束的中央轴上的预期 DSB 和非 DSB 簇。
