Abstract
Six human cervical cancer cell lines [five human papillomavirus (HPV) positive, one HPV negative] for induction and rejoining of DNA strand breaks and for kinetics of formation and loss of serine 139 phosphorylated histone H2AX (gammaH2AX). X-rays induced the same level of DNA breakage for all cell lines. By 8 hours after 20 Gy, <2% of the initial single-strand breaks remained and no double-strand breaks could be detected. In contrast, 24 hours after irradiation, gammaH2AX representing up to 30% of the initial signal still present. SW756 cells showed almost four times higher background levels of gammaH2AX and no residual gammaH2AX compared with the most radiosensitive HPV-negative C33A cells that showed the lowest background and retained 30% of the maximum level of gammaH2AX. Radiation sensitivity, measured as clonogenic-surviving fraction after 2 Gy, was correlated with the fraction of gammaH2AX remaining 24 hours after irradiation. A substantial correlation with gammaH2AX loss half-time measured over the first 4 hours was seen only when cervical cell lines were included in a larger series of p53-deficient cell lines. Interestingly, p53 wild-type cell lines consistently showed faster gammaH2AX loss half-times than p53-deficient cell lines. We conclude that cell line-dependent differences in loss of gammaH2AX after irradiation are related in part to intrinsic radiosensitivity. The possibility that the presence of gammaH2AX foci may not always signify the presence of a physical break, notably in some tumor cell lines, is also supported by these results.
Highlights
Phosphorylation of histone H2AX occurs in response to DNA double-strand breaks produced by ionizing radiation and a variety of genotoxic drugs [1, 2]
A primary aim of this study was to determine whether either of two methods that detect DNA damage and repair after irradiation might be useful in detecting differences in the radiosensitivity of a series of human cancer cell lines of the same type
In previous experiments in which the comet assay was used, we were unable to identify differences in induction or short-term rejoining of strand breaks that could stratify cell lines according to their radiosensitivity [17]
Summary
Phosphorylation of histone H2AX occurs in response to DNA double-strand breaks produced by ionizing radiation and a variety of genotoxic drugs [1, 2]. Histone phosphorylation is rapid and extensive, covering large regions of the chromosome adjacent to each break and producing foci that can be visualized microscopically after antibody labeling [3, 4]. Phosphorylation of H2AX is proposed to concentrate repair factors at sites of DNA damage [8]. The ability to use serine-139 phosphorylated histone H2AX (␥H2AX) foci to locate one double-strand break per nucleus has introduced new possibilities for low-level DNA damage detection, analysis of repair enzyme recruitment, and development of predictive assays for tumor response
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