Effect of Radiation Quality on Lesion Complexity in Cellular DNA

Abstract

Understanding the critical lesions induced by ionizing radiation in DNA and their relationship to cellular effects is an important challenge in radiation biology. Much evidence has suggested that DNA double-strand breaks (dsb) are important lesions. Establishing a cause and effect relationship between initial levels of DNA dsb, their repair rate or the level of residual unrepaired breaks, and cellular effects has proved difficult in mammalian cells. Several studies have measured yields of DNA dsb after irradiation with radiations of differing linear energy transfer (LET). In general the RBEs for dsb induction (20–100 keV/µm) have been lower than the RBEs measured for cell survival and in many cases are around 1·0. Several studies have shown differences in the rejoining of dsb with less dsb rejoined after high-LET irradiation in comparison with low-LET radiation. These results suggest that there may be differences in the types of lesions induced by different radiations and scored as DNA dsb using current techniques. Track structure modelling studies have suggested that some lesions induced will be clustered at the sites of energy depositions and that uniquely large energy deposition events are produced by high-LET radiations. Assays need to be developed to measure complex lesions in both model DNA and cellular systems. Different levels of complexity need to be considered such as clustering of radicals close to DNA, localized areas of DNA damage (1–20 bp) and lesions which may be induced over larger distances. Studies using new and existing assays of DNA damage, coupled with irradiation at various LETs, are directed at understanding the role of lesion complexity in relation to cellular effects.