Arsenite is a human carcinogen reported to inhibit DNA repair. The binding of arsenite to functional thiol groups of DNA repair enzymes has in the past been suggested as a possible mechanism for the effect of arsenite on DNA repair. However, recent studies indicate that reactive oxygen species and nitric oxide are involved in arsenite toxicity. This research aims to elucidate the role of these possible mechanisms in the inhibition of UV-induced DNA repair by arsenite. As arsenite inhibits UV-DNA repair in Chinese hamster ovary cells, and this is a commonly used cell line for UV repair experiments, we used these cells to examine the effect of arsenite on the expression of UV-irradiated reporter genes. The T4 UV endonuclease V-incorporated comet assay was used to examine specifically the effect of arsenite on pyrimidine dimer excision. We showed that inhibition of UV-DNA repair by arsenite was suppressed by nitric oxide synthase inhibitors. Arsenite increased nitric oxide production and nitric oxide generators inhibited UV-DNA repair. The involvement of nitric oxide in the inhibition of pyrimidine dimer excision by arsenite was also confirmed in human fibroblasts. Investigation into the effect of oxidant modulators did not give a clear indication that reactive oxygen species are involved in arsenite inhibition of UV-DNA repair. Phenylarsine oxide, a strong thiol-reacting agent, did not inhibit pyrimidine dimer excision and also did not increase nitric oxide production. Our results show conclusively that nitric oxide is involved in the inhibition of pyrimidine dimer excision by arsenite. Reactive oxygen species and the binding of arsenite to functional thiol groups of DNA repair enzymes do not appear to be involved.
Arsenic has been shown to inhibit methyl methane-sulphonate (MMS)-induced DNA repair but the exact mechanism remains controversial. The purpose of this investigation is to examine which step of DNA repair is most sensitive to arsenite (As) and how As inhibits it. The results from single-cell alkaline electrophoresis, showing post-treatment with As increased DNA strand breaks in MMS-treated cells, suggest that that the excision step seems to be less sensitive to As than later steps. To test this hypothesis, hydroxyurea (Hu) plus cytosine-beta-D-arabinofuranoside (AraC) were used to block DNA polymerization, allowing the DNA strand breaks to accumulate. These experiments indicated that As had weak inhibitory effects on DNA strand break accumulation. However, As inhibited the rejoining of those DNA strand breaks which could be rejoined within 4 h after release from blockage by Hu plus AraC. To further elucidate this mechanism, a cell extract was used to compare the relative sensitivity of the various steps in DNA repair to As. The potency of the As inhibitory effect as deduced from concentration-response curves were: ligation of poly(rA).oligo(dT) > ligation of poly(dA).oligo(dT) approximately DNA polymerization > or = DNA repair synthesis > excision. As is known to inhibit the activity of pyruvate dehydrogenase by interacting with vicinal dithiol groups. Dithiothreitol could effectively remove As inhibition of both the ligation of poly(rA).oligo(dT) and the activity of pyruvate dehydrogenase but had no obvious effect on As inhibition of poly(dA).oligo(dT) ligation. Since DNA ligase III contains vicinal dithiol groups, we postulate that As may inhibit DNA break rejoining by interacting with the vicinal dithiols to inactivate DNA ligation in MMS-treated cells.
Recently, arsenic trioxide (As2O3) was reported to induce clinical remission in patients with acute promyelocytic leukemia. Modulation of protein phosphorylation by binding to the vicinal thiols has been suggested as a possible mechanism. We found that phenylarsine oxide, a strong vicinal thiol-binding agent, neither induced nuclear fragmentation or DNA laddering nor increased caspase activity in NB4 cells; however, As2O3 and a weak thiol-binding agent, dimethylarsinic acid, did increase activity. Dithiothreitol (DTT) effectively suppressed the phenylarsine oxide-inhibited cellular reductive capacity, but unexpectedly, enhanced As2O3-induced apoptosis in NB4 cells. As2O3-induced and As2O3-plus-DTT-induced apoptosis in NB4 cells was modulated by oxidant modifiers, but not by nitric oxide synthase inhibitors. These results demonstrate that DTT, a dithiol agent and known antidote for trivalent inorganic arsenic, enhances the toxicity of As2O3, thereby opening a new research direction for the mechanisms of arsenic toxicity and perhaps also helping in the development of new therapeutic strategies for treating leukemias.
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