Inorganic arsenite-induced malignant transformation of human prostate epithelial cells.

Although several epidemiologic studies show an association between arsenic exposure and prostate cancer, it is still unknown whether human prostate epithelial cells are directly susceptible to arsenic-induced transformation. This study was designed to determine whether the nontumorigenic human prostate epithelial cell line RWPE-1 could be malignantly transformed in vitro by arsenite. RWPE-1 cells were continuously exposed to 5 micro M arsenite and monitored for signs of transformation, assessed as changes in matrix metalloproteinase-9 levels. After 29 weeks of exposure, the arsenite-exposed RWPE-1 cells (referred to as CAsE-PE) showed a marked increase in matrix metalloproteinase-9 secretion, a common finding in prostate malignancies. Malignant transformation was confirmed when CAsE-PE cells produced aggressive undifferentiated malignant epithelial tumors in nude mice. The tumors stained positive for human prostate-specific antigen, confirming their origin. These results are the first report of arsenite-induced malignant transformation of a human epithelial cell line and provide an important in vitro model for studying the mechanisms underlying arsenic-induced carcinogenesis in humans.

Chronic arsenic-exposed human prostate epithelial cells exhibit stable arsenic tolerance: mechanistic implications of altered cellular glutathione and glutathione S-transferase.

Acquisition of stable arsenic tolerance in human cells following chronic arsenic exposure has not been previously reported. In the present work, we describe acquisition of stable arsenic tolerance in the human prostate epithelial cell line RWPE-1 following chronic arsenic exposure in vitro. RWPE-1 cells continuously exposed to 5 microM sodium arsenite for > or =18 weeks exhibited dramatic resistance to acute arsenite toxicity. The LC50 for acute arsenite exposure in these chronic arsenic-exposed prostate epithelial (CAsE-PE) cells was 43.8 microM versus 17.6 microM in control cells. Similar results were obtained using the antineoplastic agent arsenic trioxide. This tolerance was stable, as CAsE-PE cells grown in arsenic-free medium for 5 weeks retained their resistant phenotype. Compared to control cells, CAsE-PE cells showed a 90% reduction in arsenic accumulation over 24 h coupled with a 2.6-fold increase in the rate of arsenic efflux. CAsE-PE cells had increased basal GSH levels (4.9-fold) and increased GST activity (2.4-fold) and both GSH depletion and inhibition of GST activity abolished arsenic tolerance. Arsenic tolerance was also abolished by treatment with inhibitors of the Mdr1 and Mrp1 transporters, although no increases in mdr1 or mrp1 gene expression were observed. Our results indicate that this tolerance in human cells involves increases in GSH levels and GST activity that allow for more efficient arsenic efflux by MRP1 and MDR1. This study represents the first report of stable acquired arsenic tolerance in human cells, which could have important implications for both the toxicology and the pharmacology of arsenic.