Role of the alkali labile sites, reactive oxygen species and antioxidants in DNA damage induced by methylated trivalent metabolites of inorganic arsenic.

In the last decade arsenic metabolism has become an important matter of discussion. Methylation of inorganic arsenic (iAs) to monomethylarsonic acid (MMA(V)) and dimethylarsinic acid (DMA(V)) is considered to decrease arsenic toxicity. However, in addition to these pentavalent metabolites, the trivalent metabolites monomethylarsonous (MMA(III)) and dimethylarsinous acid (DMA(III)) have been identified recently as intermediates in the metabolic pathway of arsenic in cultured human cells. To examine the role of oxidative damage in the generation of DNA strand breaks by methylated trivalent arsenic metabolites, we treated human lymphocytes with both metabolites at non-cytotoxic concentrations. We further tested whether these effects are sensitive to modulation by the antioxidants ascorbate (Vitamin C) and selenomethionine (Se-Met). Both trivalent metabolites produced oxidative stress related DNA damage, consisting of single strand breaks and alkali-labile sites, with MMA(III) being more potent at low concentrations than DMA(III). Neither MMA(III) nor DMA(III) induced DNA-double strand breaks. The oxidative stress response profiles of the metabolites were parallel as determined by lipid peroxidation induction. MMA(III) induced peroxidation from the lowest concentration tested, while effects of DMA(III) were apparent only at concentrations above 10 muM. The antioxidant Se-Met exhibited a more pronounced inhibition of trivalent arsenic metabolite-induced oxidative-DNA damage than did vitamin C. The present findings suggest that DNA damage by methylated trivalent metabolites at non-cytotoxic concentrations may be mediated by a mix of reactive oxygen and nitrogen oxidized species.

Metallothionein (I/II) suppresses genotoxicity caused by dimethylarsinic acid.

Arsenic is an environmental chemical of considerable concern due to its association with an increased risk of human cancer. Dimethylarsinic acid (DMAA) is one of the major methylated metabolites of ingested arsenicals in most mammals. To better clarify the role of metallothionein (MT) in modifying DMAA genotoxicity, MT-I/II null mice, and the corresponding wild-type mice, were exposed to DMAA (0, 188, 375 or 750 mg/kg body weight) via a single oral dose. Twenty-four hours after the DMAA injection, there was increased formation of 8-hydroxy-2'-deoxyguanosine (8-OHdG) in serum and urine and a higher number of DNA strand breaks in peripheral blood cells. These increased levels were concomitant with increasing dose concentrations of DMAA in both strains of mice and they were significantly higher in MT-I/II null mice than in wild-type mice. Furthermore, the induction of apoptotic cells in the urinary bladder epithelium of MT-I/II null mice was significantly higher than in dose-matched wild-type mice exposed to DMAA. On the other hand, in both liver and in the alveolar and bronchial areas of the lung, the extent of DMAA-induced apoptosis was not different between wild-type and MT-I/II null mice and was increased in both strains. In addition, the concentration of hepatic MT in wild-type mice increased in a DMAA dose-dependent manner but was undetectable in MT-I/II null mice and could not subsequently be induced by DMAA. In conclusion, DMAA exposure causes oxidative stress, DNA damage and specific induction of apoptosis in target organs of arsenic carcinogenesis, which may be attributable to the mechanism(s) of arsenic-induced carcinogenesis in rodents. MT exhibited some protective roles during DNA damage presumably by acting as an antioxidant.

Folic acid protects SWV/Fnn embryo fibroblasts against arsenic toxicity.

It has been proposed that arsenic exerts its toxic effects, in part, by perturbing cellular methyl metabolism. Based on the hypothesis that folic acid treatment will attenuate the cytotoxic and growth inhibitory effects of arsenic, SWV/Fnn embryo fibroblasts were cultured in media supplemented with various concentrations of folic acid during treatment with sodium arsenite or dimethylarsinic acid (DMA). It was found that folic acid protects SWV/Fnn embryo fibroblasts from sodium arsenite and DMA cytotoxicity in a dose-dependent manner. In contrast, folic acid supplementation has no effect on toxicity resulting from treatment with ethanol or staurosporine, suggesting that folic acid is not generally protective against necrosis and apoptosis. Although folic acid protects against acute arsenic toxicity, this agent shows a modest and delayed ability to attenuate the growth inhibitory effect of arsenic on these cells. These results support a model in which perturbations of methyl metabolism contribute to the acute cytotoxicity of arsenic.