Gunma University Initiative for Advanced Research, GIAR, Gunma University, Maebashi, Japan.
Enzymes. 2022;51:117-130. doi: 10.1016/bs.enz.2022.08.008. Epub 2022 Sep 27.
A carbon ion categorized as a heavy ion particle has been used for cancer radiotherapy. High linear energy transfer (LET) carbon ion irradiation deposits energy at a high density along a particle track, generating multiple types of DNA damage. Complex DNA lesions, comprising DNA double-strand breaks (DSBs), single-strand breaks, and base damage within 1-2 helical turns (<3-4nm), are thought to be difficult to repair and critically influence cell viability. In addition to the effect of lesion complexity, the most recent studies have demonstrated another characteristic of high LET particle radiation-induced DNA damage, clustered DSBs. Clustered DSBs are defined as the formation of multiple DSBs in close proximity where the scale of clustering is approximately 1-2μm, i.e., the scale of the event is estimated to be > ∼1Mbp. This chapter reviews the hallmarks of clustered DSBs and how such DNA damage influences genome instability and cell viability in the context of high LET carbon ion radiotherapy.
一种被归类为重离子粒子的碳离子已被用于癌症放射治疗。高传能线密度(LET)碳离子辐照沿着粒子轨迹以高密度沉积能量,产生多种类型的 DNA 损伤。复杂的 DNA 损伤包括 DNA 双链断裂(DSB)、单链断裂和 1-2 个螺旋(<3-4nm)内的碱基损伤,被认为难以修复,并严重影响细胞活力。除了损伤复杂性的影响外,最近的研究还表明了高 LET 粒子辐射诱导的 DNA 损伤的另一个特征,即簇状 DSB。簇状 DSB 被定义为多个 DSB 在近距离形成,其中簇集的规模约为 1-2μm,即簇集的规模估计> ∼1Mbp。本章综述了簇状 DSB 的特征以及这种 DNA 损伤如何影响高 LET 碳离子放射治疗中基因组不稳定性和细胞活力。
