Previous work has suggested that arsenic exposure contributes to skin carcinogenesis by preserving the proliferative potential of human epidermal keratinocytes, thereby slowing the exit of putative target stem cells into the differentiation pathway. To find a molecular basis for this action, present work has explored the influence of arsenite on keratinocyte responses to epidermal growth factor (EGF). The ability of cultured keratinocytes to found colonies upon passaging several days after confluence was preserved by arsenite and EGF in an additive fashion, but neither was effective when the receptor tyrosine kinase activity was inhibited. Arsenite prevented the loss of EGF receptor protein and phosphorylation of tyrosine 1173, preserving its capability to signal. The level of nuclear beta-catenin was higher in cells treated with arsenite and EGF in parallel to elevated colony forming ability, and expression of a dominant negative beta-catenin suppressed the increase in both colony forming ability and yield of putative stem cells induced by arsenite and EGF. As judged by expression of three genes regulated by beta-catenin, this transcription factor had substantially higher activity in the arsenite/EGF-treated cells. Trivalent antimony exhibited the same effects as arsenite. A novel finding is that insulin in the medium induced the loss of EGF receptor protein, which was largely prevented by arsenite exposure.
Sodium arsenite is much more potent than sodium arsenate in producing adverse effects in animals and in cultured cells. Although arsenate may exhibit toxicity as a phosphate analogue, its potency in vivo appears to be enhanced by reduction to arsenite. To understand the relative importance of this reduction, which is critical in evaluating the responsiveness of cell culture models to the different oxidation states and thus to elucidating the mechanism of arsenic action, present work has correlated the extent of reduction with biological activity in human keratinocytes. The results show that at biologically relevant concentrations, arsenate reduction to appreciable levels required several days, helping rationalize a previous empirical observation that it was approximately one-third as potent as arsenite. The relatively low conversion rate also emphasizes a limitation of culture; arsenate was nearly as efficacious as arsenite, but the time required for it to reach maximal effect exceeded ordinary medium change intervals. In keratinocytes, an important role for purine nucleoside phosphorylase in the reduction could not be demonstrated, indicating that another pathway is dominant in this cell type. Methylation of inorganic arsenic, uptake of methylated forms, and their reduction were all very slow. These findings suggest that the reduced methylated forms have only a small contribution to skin carcinogenesis unless they are supplied through the circulation. In parallel experiments, trivalent antimony was similar to arsenite in potency and efficacy, whereas pentavalent antimony was virtually without biological effect. Conversion of antimony in the pentavalent to the trivalent oxidation state was not detectable in keratinocytes. These findings emphasize the importance of intracellular reduction of the metalloids for biological effects.
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