Abstract
DNA double-strand break (DSB) induction is one of the phenotypes of cellular damage from radiation exposure and is commonly quantified by γ-H2AX assay with the number of excess fluorescent foci per cell as the main component. However, the number of foci alone may not fully characterize the state of DNA damage following exposures to different radiation qualities. This study investigated the feasibility of utilizing the focus size distribution and dephosphorylation rate of γ-H2AX to identify the type of causative radiation and dose. Human lung epithelial cells and mouse vascular endothelial cells were used to observe the expression changes of γ-H2AX foci due to alpha particle and X-ray exposures. Results showed that the average number of excess foci per cell linearly increased with the dose. The focus size distribution showed a consistent pattern depending on the causative radiation type. Three criteria for the identification of causative radiation type were derived from experimental focus size distributions and were validated in blind testing with correct identification of 27 out of 32 samples. The dose could be estimated based on the proportionality constant specific to the identified radiation type with a difference of less than 15% from the actual value. The different dephosphorylation rates of γ-H2AX produced from alpha particle and X-ray exposures were effectively utilized to determine the individual dose contributions of alpha particles and X-rays under mixed beam exposure. Individual doses were estimated to have differences of less than ~ 12% from actual values.
Highlights
DNA double-strand break (DSB) induction is one of the phenotypes of cellular damage from radiation exposure and is commonly quantified by γ-H2AX assay with the number of excess fluorescent foci per cell as the main component
The γ-H2AX signals expressed as bright spots through fluorescence microscopy indicate DNA DSB production, and each γ-H2AX focus corresponds to a single DNA DSB production site at low linear energy transfer (LET) radiation exposure
Conclusion γ-H2AX assay was adopted to measure DNA DSBs induced by X-ray and alpha particle exposures
Summary
DNA double-strand break (DSB) induction is one of the phenotypes of cellular damage from radiation exposure and is commonly quantified by γ-H2AX assay with the number of excess fluorescent foci per cell as the main component. This study investigated the feasibility of utilizing the focus size distribution and dephosphorylation rate of γ-H2AX to identify the type of causative radiation and dose. The γ-H2AX signals expressed as bright spots (foci) through fluorescence microscopy indicate DNA DSB production, and each γ-H2AX focus corresponds to a single DNA DSB production site at low linear energy transfer (LET) radiation exposure. The number of those spots (γ-H2AX foci) reflects DNA DSB q uantity[1] and linearly increases with the radiation dose[2,3]. This study aims to investigate the feasibility of judging the causative radiation type and estimating the dose based on the pattern of γ-H2AX foci formation and dephosphorylation. The size distribution and dephosphorylation rate of γ-H2AX foci were chosen as the key parameters
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