Modulation of cadmium chloride toxicity by sulphur amino acids in hepatoma cells.

Cadmium is a toxic metal and no effective antidote exists at present. The aim of this study was to examine whether sulphur amino acids, involved in glutathione synthesis, can modulate cadmium toxicity in vitro. Two hepatoma cell lines (HepG2 and HTC cells) were exposed to cadmium chloride (0-100 microM) for 8h in control media or in media containing 1mM of homocysteine, cysteine or cystathionine. Cell viability was then assessed with the neutral red assay. In order to assess the mechanism by which homocysteine and cysteine modulate cadmium toxicity their ability to scavenge reactive oxygen species was determined as well as the potential to increase intracellular glutathione levels. The ability of the sulphur amino acids to prevent cadmium uptake by HTC and HepG2 cells was also assessed. The results indicate that homocysteine and cysteine protect efficiently both cell lines from cadmium chloride toxicity whereas cystathionine protects efficiently HTC cells but not HepG2 cells. This effect was shown to be dependent on the dose of each amino acid and increased protection from cadmium was observed with increasing concentrations of homocysteine and cysteine. Both amino acids prevented the formation of reactive oxygen species only when they were administered together with cadmium chloride. In addition homocysteine and cysteine did not increase intracellular glutathione levels. The results indicate that the mechanism by which sulphur amino acids protect from cadmium toxicity in vitro is due to the reduced uptake of the metal by the cells possibly by direct binding to the -SH group of the amino acids.

Role of trace elements in cadmium chloride uptake in hepatoma cell lines.

Cadmium coexists with other metals in various products. Releases of cadmium in the environment occur in parallel to the release of other metals including copper, iron and zinc which also have an essential role in human homeostasis as they participate in various biochemical pathways. We studied the interaction of iron, copper, zinc and calcium channel blockers (nifedipine and verapamil) with cadmium chloride in two hepatoma cell lines (HepG2 and HTC cells) in order to determine if these trace elements can affect CdCl(2) uptake and interfere with its toxicity. Both cell lines were initially exposed to CdCl(2) (0-200 microM) for 2h and the uptake of the metal was determined. Cadmium chloride uptake by HepG2 and HTC cells shows an increase with increasing doses of the metal. Cells were also pretreated with 100 uM of FeCl(2) or ZnCl(2) or CuCl(2) or with a nifedipine/verapamil (100 uM) mixture for 2h and then exposed to 200 uM CdCl(2) for 1h in the presence of the trace elements. The uptake of CdCl(2) was determined as well as the membrane integrity (LDH leakage assay), the cell viability (neutral red assay) and cell proliferation (protein assay). Zinc and calcium channel blockers inhibited the uptake of cadmium chloride by both cell lines. On the other hand iron loading resulted in increased uptake of CdCl(2) by both cell lines whereas copper loading increased the uptake of cadmium chloride from HTC cells and inhibited the uptake by HepG2 cells. These findings are of importance when the effects of cadmium on living organisms are examined since co-exposure to cadmium and other metals can occur.

In vitro cytotoxicity assays: comparison of LDH, neutral red, MTT and protein assay in hepatoma cell lines following exposure to cadmium chloride.

The aim of this study was to compare four in vitro cytotoxicity assays and determine their ability to detect early cytotoxic events. Two hepatoma cell lines, namely HTC and HepG2 cells, were exposed to cadmium chloride (0-300 microM) for 3, 5 and 8 h. Following exposure to the toxic metal cytotoxicity was determined with the lactate dehydrogenase leakage assay (LDH), a protein assay, the neutral red assay and the methyl tetrazolium (MTT) assay. In HTC cells no toxicity was observed for any incubation period when the LDH leakage, the MTT and the protein assay were employed whereas the neutral red assay revealed early cytotoxicity starting after incubation of HTC cells with CdCl(2) for 3 h. In the case of HepG2 cells the MTT assay reveals cytotoxicity due to CdCl(2) exposure after 3 h whereas no such effect is seen with the other three assays. Following 5 h exposure of HepG2 cells to CdCl(2), toxicity is observed with the MTT assay at lower concentrations compared to the ones required for detection of toxicity with the LDH leakage and the neutral red assay. In conclusion different sensitivity was observed for each assay with the neutral red and the MTT assay being the most sensitive in detecting cytotoxic events compared to the LDH leakage and the protein assay.

Sulfur amino acid deprivation in cadmium chloride toxicity in hepatoma cells.

The aim of this study was to investigate the effect of individual sulfur amino acid deprivation in cadmium chloride toxicity. HTC cells were deprived of cystine and/or methionine for 12h and then exposed to CdCl(2) for 12h. HepG2 cells were deprived of cystine for 3 and 5h and exposed to CdCl(2) for 3h. In addition HepG2 cells were deprived of methionine for 12h and then exposed to CdCl(2) for 5 and 12h. Our results indicate that only cystine depletion increased cadmium toxicity in HTC cells but not in HepG2 cells as indicated by the neutral red assay. This effect was due to glutathione depletion as indicated by measurement of intracellular glutathione in HTC cells following deprivation of cystine. Methionine depletion had only a slight effect on the viability of HepG2 cells.

Cadmium chloride-induced DNA and lysosomal damage in a hepatoma cell line.

Cadmium is a toxic metal and no uniform mechanism of toxicity has so far been proposed. The aim of this study was to investigate the biochemical effects of cadmium chloride in a rat hepatoma cell line (HTC cells) and the cellular events mediating DNA damage. HTC cells were exposed to various concentrations of cadmium chloride for 5 and 8 h and lysosomal damage was assessed with the neutral red assay (NR) and fluorescence microscopy. Mitochondrial integrity was assessed from ATP levels and DNA damage determined with the single cell gel electrophoresis/comet assay. The formation of reactive oxygen species (ROS) was also determined under the same experimental conditions with the dichlorofluorescein assay. Cytotoxicity was assessed with the LDH leakage assay and the levels of glutathione were measured and correlated with the other effects. The results indicate that lysosomal damage occurs at a lower concentration of cadmium chloride (20 microM) than DNA damage (500 microM) in HTC cells. The latter effect was accompanied by an increase of reactive oxygen species without any significant LDH leakage whereas lysosomal damage was significant as determined by the neutral red assay and confirmed with fluorescence microscopy. The effect of CdCl2 on mitochondria and glutathione levels were observed at concentrations or incubation times higher than the ones required to induce lysosomal damage. The data suggest that DNA damage may be due to the formation of reactive oxygen species. It is possible that cadmium induced lysosomal damage is an earlier event than DNA damage and can mediate other cellular events that lead to cell death.