Redox regulation of human OGG1 activity in response to cellular oxidative stress.

8-Oxoguanine (8-oxoG), a common and mutagenic form of oxidized guanine in DNA, is eliminated mainly through base excision repair. In human cells its repair is initiated by human OGG1 (hOGG1), an 8-oxoG DNA glycosylase. We investigated the effects of an acute cadmium exposure of human lymphoblastoid cells on the activity of hOGG1. We show that coinciding with alteration of the redox cellular status, the 8-oxoG DNA glycosylase activity of hOGG1 was nearly completely inhibited. However, the hOGG1 activity returned to normal levels once the redox cellular status was normalized. In vitro, the activity of purified hOGG1 was abolished by cadmium and could not be recovered by EDTA. In cells, however, the reversible inactivation of OGG1 activity by cadmium was strictly associated with reversible oxidation of the protein. Moreover, the 8-oxoG DNA glycosylase activity of purified OGG1 and that from crude extracts were modulated by cysteine-modifying agents. Oxidation of OGG1 by the thiol oxidant diamide led to inhibition of the activity and a protein migration pattern similar to that seen in cadmium-treated cells. These results suggest that cadmium inhibits hOGG1 activity mainly by indirect oxidation of critical cysteine residues and that excretion of the metal from the cells leads to normalization of the redox cell status and restoration of an active hOGG1. The results presented here unveil a novel redox-dependent mechanism for the regulation of OGG1 activity.

Persistent oxidative stress after ionizing radiation is involved in inherited radiosensitivity.

The SW620IR1 cell line was derived from SW620 human colon cells surviving to ionizing radiations. It shows an increased radiosensitivity and a higher yield of spontaneous chromosomal aberrations. In order to check whether altered reactive oxygen intermediates (ROI) metabolism is involved in this inherited phenotype, we compared the two cell lines for their radiation-induced modifications at the level of ROI production, antioxidant activities, and chromosomal aberrations. Compared to SW620, SW620IR1 cells exhibit a higher and more persistent ROI induction after various doses of ionizing radiations and a higher yield of dicentric chromosomes. They are also characterized by lower basal activities of glutathione peroxidase and manganese-containing superoxide dismutase, and lower ability to induce these antioxidant defenses after irradiation. Resumption of cell growth after irradiation coincides with maximal induction of antioxidant activities and normalization of ROI concentration. However, at that time radiation-induced chromosomal aberrations are not completely eliminated, leading to the proliferation of genetically unstable cells. These results indicate that the inherited sensitivity of SW620IR1 cells is associated with altered antioxidant activities resulting in higher and more prolonged oxidative stress after radiation exposure. They also suggest that the normalization of ROI levels allows these p53 mutant cells to resume proliferation although high levels of DNA damages are still persisting, thereby explaining the chromosomal instability observed as a delayed effect of radiation exposure.