Effect of enlarged glutathione on zinc-mediated toxicity in lung-derived cell lines.

Zinc-mediated toxicity has been linked to cellular glutathione content in isolated cells. In addition, treatment of alveolar epithelial type II cells with glucocorticoids diminishes cellular glutathione content, and this is followed by an increase in zinc-mediated toxicity. The question arises whether an increase in glutathione synthesis might decrease zinc-mediated toxicity. For this purpose an administration of 200 micromol/l N-acetyl-L-cysteine (NAC) was given to the cells, while cysteine was used up to 100 micromol/l. Zinc-mediated toxicity was assessed by measuring protein synthesis inhibition and glutathione dependent parameters. De novo synthesis of glutathione was assessed as compared to controls by N-acetyl-D-cysteine (NADC) treatment. Comparing NAC and NADC treatment no differences in zinc-mediated toxicity were found. Furthermore only in one (of three) cell line tested a significant increase in GSH content by NAC as compared to NADC treatment was achieved. But even in this cell line no changes by zinc-mediated toxicity were found. It is concluded that the cell lines tested can use other sources of cys for glutathione synthesis. Furthermore the increased zinc-mediated toxicity due to hydrocortisone was abolished in the alveolar epithelial cell lines by the NADC/NAC treatment. It is therefore discussed that additionally to glutathione some other antioxidative defence mechanisms can influence zinc-mediated toxicity as well.

Decreased zinc toxicity resulting from doxorubicin without increased GSSG export in three human lung cell lines.

Zinc-mediated cytotoxicity is recognized, at least in part, by a decrease of reduced glutathione (GSH) and an increase in the oxidized form of glutathione (GSSG). Doxorubicin is a common inducer of multidrug-resistance-associated proteins and such proteins might, furthermore, be associated by an increased GSSG export rate. Therefore, zinc-mediated toxicity should be abolished after doxorubicin pretreatment. In the present study, zinc toxicity was characterized by methionine incorporation, glutathione content, and the GSSG/GSH ratio. Experiments were performed in three established lung cell lines comparing doxorubicin-pretreated cells with controls. Zinc-mediated toxicity was significantly decreased after pretreatment with doxorubicin as assessed by methionine-incorporation inhibition, GSH depletion, and/or GSSG increase in the two nonmalignant cell lines. Unexpectedly, zinc-associated GSSG export was not increased after doxorubicin pretreatment. This inconsistency might be explained as a result of a decreased zinc content in these cells, probably because of an increased export rate of zinc. The findings are in contradiction to the opinion of metal excretion by multidrug-resistance-associated proteins, matched to GSH conjugate excretion, as it is discussed for cadmium, for example.

Antioxidative vitamins decrease cytotoxicity of HEMA and TEGDMA in cultured cell lines.

OBJECTIVES AND METHODS: In a previous study it was postulated that toxicity of 2-hydroxyethylmethacrylate (HEMA) and triethleneglycoldimethacrylate (TEGDMA) is based on oxidative metabolites. In this study the influence of antioxidative vitamins (including uric acid) on the toxicity of HEMA or TEGDMA was tested. Toxicity of HEMA and TEGDMA was determined in rat alveolar epithelial L2, human malignant A549, and human fibroblast-like 11Lu cells by inhibition of methionine incorporation (as a marker of protein synthesis inhibition) and by determination of glutathione depletion, as well as by measurement of GSSG increase. RESULTS: Toxicity of the composite components HEMA and TEGDMA was demonstrated by GSH depletion as the most sensitive method. Five hundred micromoles per litre Vitamin C or 250 micromol/l Vitamin E were mostly able to decrease toxicity of HEMA and TEGDMA in the cell lines tested. In addition, 250 micromol/l Vitamin A was only effective in L2 cells impairing HEMA toxicity and 250 micromol/l uric acid impairing TEGDMA toxicity as assessed by decreased GSH depletion. In A549 cells only methionine incorporation inhibition but not GSH depletion was significantly affected. By contrast, in 11Lu cells methionine incorporation inhibition was not significantly changed, but GSH depletion was. CONCLUSIONS: The postulated mechanism of HEMA or TEGDMA toxicity based on radical metabolites is supported by the effectivity of the antioxidative substances tested in mitigating toxicity and by the greater susceptibility of the glutathione redox system as compared to protein synthesis inhibition in assessing toxicity.

Decreased GSSG reductase activity enhances cellular zinc toxicity in three human lung cell lines.

Cellular reduced glutathione (GSH) levels have been identified as an essential determinant in zinc-induced cytotoxicity. However, cytotoxic effects of zinc have also been observed without depletion of GSH stores. In a previous study, the intracellular activity of GSSG reductase (GR) has come into focus (Walther et al. 2000, Biol Trace Elem Res 78:163-177). In the present paper we have tried to address this issue more deeply by inhibiting the activity of cellular GR without any appreciable decreases of cellular glutathione. In three pulmonary cell lines, GR activity was inhibited in a dose-dependent manner by the alkylating agent carmustine (BCNU), a known inhibitor of GR. Cells were pretreated with BCNU for 14 h, followed by exposure to various concentrations of zinc chloride. Then we determined the incorporation of radiolabelled methionine (to assess protein synthesis), and measured the GSH and oxidized glutathione (GSSG) levels. Additionally, GR activity of controls was measured. IC(50) values for zinc-induced inhibition of methionine incorporation, as well as GSH contents, was strongly correlated to the decreased GR activity. These results firmly suggest that GR is an important factor in the event chain of zinc cytotoxicity. Together with the results from our previously cited study where impaired regeneration of GSH levels were accompanied by a decrease in total cellular glutathione (GSH + GSSG) we conclude that GSSG itself is an important effector in zinc cytotoxicity.

Cytotoxicity of ingredients of various dental materials and related compounds in L2- and A549 cells.

Various ingredients of dental materials and related compounds were tested for cytotoxicity in two alveolar epithelial cell lines (L2 and A549 cells). Release of lactate dehydrogenase (LDH) from cells was measured after incubation with the test substances for time intervals up to 48 h and expressed as percentage of total LDH content of lysed cells. Furthermore, the glutathione content of cells was determined in the nonmalignant L2 cells. Additionally, cell viability was assessed by microscopic examination. The highest cytotoxicity was observed with mercury compounds (methylmercuric chloride and mercury dichloride) in the range of 5-20 micromol/l. The composite components 2-hydroxyethylmethacrylate (HEMA) and triethleneglycoldimethacrylate (TEGDMA) showed time- and concentration-dependent effects of cytotoxicity at high concentrations (about 1-5 mmol/l). A time dependence for GSH decrease was mainly found for the composite components up to 12 h of cellular exposure. L2 cells were more sensitive to both mercury and composite compounds than A549 cells. Gold compounds (sodiumaurothiomalate and gold particles < 1.5 microm) did not produce any sign of toxic reactions. A time-dependent increased toxicity in pulmonary cell lines was found for the composite components HEMA and TEGDMA, but not for mercury and gold compounds.

Effect of low level zinc pretreatment on zinc-mediated toxicity in different lung cell lines.

Reduced toxicity of high zinc exposure was observed after pretreatment of various lung cells with nonlethal zinc concentrations. This effect became significant when various parameters of cytotoxicity were assessed (e.g., inhibition of protein synthesis, depletion of reduced glutathione [GSH], increase of oxidized glutathione [GSSG], release of lactate dehydrogenase [LDH]). Similar protective effects by zinc have already been shown by several investigators for a variety of toxicity studies dealing with cadmium, in vitro and in vivo. Zinc-induced toxicity has been linked to glutathione metabolism and cellular GSH contents. Activity of glutathione reductase (GR) and rates of glutathione synthesis were identified as determinants of zinc (cyto)toxicity. However, these variables were virtually unaffected in our adapted cells. Consequently, another variable appears to be crucial for modulating cellular suscepticibility in zinc pretreated cells. Protection in our cells was achieved by pretreatment with 80-120 micromol/L zinc chloride for 24-72 h, roughly 10-fold more zinc in the medium than is normally found in human plasma. Protection was not observed when the cells were concomitantly exposed to cycloheximide, an inhibitor of protein synthesis, or actinomycin D, an inhibitor of RNA synthesis, but it was found in the presence of amanitin, an inhibitor of mRNA synthesis. It is therefore concluded that the altered zinc tolerance of pretreated cells is not attributable to the induction of metallothionein.

Effect of zinc chloride on GSH synthesis rates in various lung cell lines.

Zinc toxicity has been linked to decreased reduced glutathione (GSH) and increased oxidized glutathione (GSSG) contents, which might be caused by a GSSG reductase inhibition by zinc. In this study we investigated zinc effects on GSH synthesis rates in various lung cell lines by thin-layer chromatography after (35)S-cysteine incorporation. Two alveolar epithelial cell lines (A549 and L2) and two human fibroblast-like lung cell lines (11Lu and 16Lu) were used in this study. Equipotent protein synthesis inhibition for the different cell lines was reached after 2 h (L2, 11Lu), 3 h (16Lu), and 4 h (A549) zinc exposure (15-200 microM) to cells. Here GSH depletion and GSSG increase in A549 cells were markedly lower than in the other cell lines tested. Incorporation of cysteine (Cys) into GSH was not different in the cell lines tested, while 11Lu cells only demonstrated a decrease of newly synthesized GSH after 1 h of (35)S-Cys exposure when cells were exposed to zinc. Only 11Lu cells showed a markedly decreased Cys availability as compared with the other cell lines. In all cell lines the availability of Cys was not affected by exposure to zinc. No compensating increase in GSH synthesis rates was found after zinc-mediated cellular GSH depletion.