Spyridon Vamvakas

Bacterial β-lyase mediated cleavage and mutagenicity of cysteine conjugates derived from the nephrocarcinogenic alkenes trichloroethylene, tetrachloroethylene and hexachlorobutadiene

The metabolism of beta-lyase and the mutagenicity of the synthetic cysteine conjugates S-1,2-dichlorovinylcysteine (DCVC), S-1,2,2-trichlorovinylcysteine (TCVC), S-1,2,3,4,4-pentachlorobuta-1,3-dienylcysteine (PCBC) and S-3-chloropropenylcysteine (CPC) were investigated in Salmonella typhimurium strains TA100, TA2638 and TA98. The bacteria contained significantly higher concentrations of beta-lyase than mammalian subcellular fractions. Bacterial 100,000 X g supernatants cleaved benzthiazolylcysteine to equimolar amounts of mercaptobenzthiazole and pyruvate. DCVC, TCVC and PCBC produced a linear time-dependent increase in pyruvate formation when incubated with bacterial 100,000 X g supernatants; pyruvate formation was inhibited by the beta-lyase inhibitor aminooxyacetic acid (AOAA). CPC was not cleaved by bacterial enzymes to pyruvate. DCVC, TCVC and PCBC were mutagenic in three strains of S. typhimurium (TA100, TA2638 and TA98) in the Ames-test without addition of mammalian subcellular fractions; their mutagenicity was decreased by the addition of AOAA to the preincubation mixture. CPC was not mutagenic in any of the strains of bacteria tested. These results indicate that beta-lyase plays a key role in the metabolism and mutagenicity of haloalkenylcysteines when tested in S. typhimurium systems. The demonstrated formation in mammals of the mutagens DCVC, TCVC and PCBC during biotransformation of trichloroethylene (Tri), tetrachloroethylene (Tetra) and hexachlorobutadiene (HCBD) may provide a molecular explanation for the nephrocarcinogenicity of these compounds.

Renal cell cancer correlated with occupational exposure to trichloroethene

Green and Lash (1999) commented, in a letter to the editor, on our paper reporting an increased incidence of renal cell cancer in workers exposed to high concentrations of trichloroethene over extended periods of time (Vamvakas et al. 1998). Unfortunately, because of irregular handling of the letter by the editorial management of the journal, we were not in a position to follow common practice, that is to respond immediately and in the same issue (see footnote). We do not accept the statement at the outset of Green and Lashs letter that signi®cant methodological ̄aws make our results unreliable. Rather, we regard their criticism as unsubstantiated, for following reasons.

Changes in the classification of carcinogenic chemicals in the work area

Abstract Carcinogenic chemicals in the work area are currently classified into three categories in section III of the German List of MAK and BAT Values (list of values on maximum workplace concentrations and biological tolerance for occupational exposures). This classification is based on qualitative criteria and reflects essentially the weight of evidence available for judging the carcinogenic potential of the chemicals. It is proposed that these categories – IIIA1, IIIA2, IIIB – be retained as Categories 1, 2, and 3, to correspond with European Union regulations. On the basis of our advancing knowledge of reaction mechanisms and the potency of carcinogens, these three categories are supplemented with two additional categories. The essential feature of substances classified in the new categories is that exposure to these chemicals does not contribute significantly to risk of cancer to man, provided that an appropriate exposure limit (MAK value) is observed. Chemicals known to act typically by nongenotoxic mechanisms and for which information is available that allows evaluation of the effects of low-dose exposures, are classified in Category 4. Genotoxic chemicals for which low carcinogenic potency can be expected on the basis of dose-response relationships and toxicokinetics, and for which risk at low doses can be assessed are classified in Category 5.The basis for a better differentiation of carcinogens is discussed, the new categories are defined, and possible criteria for classification are described. Examples for Category 4 (1,4-dioxane) and Category 5 (styrene) are presented.

Changes in the classification of carcinogenic chemicals in the work area :(Section III of the German List of MAK and BAT values)

Abstract Carcinogenic chemicals in the work area were previously classified into three categories in section III of the German List of MAK and BAT values (the list of values on maximum workplace concentrations and bio‐logical tolerance for occupational exposures). This classification was based on qualitative criteria and reflected essentially the weight of evidence available for judging the carcinogenic potential of the chemicals. In the new classification scheme the former sections IIIA1, IIIA2, and IIIB are retained as categories 1, 2, and 3, to correspond with European Union regulations. On the basis of our advancing knowledge of reaction mechanisms and the potency of carcinogens, these three categories are supplemented with two additional categories. The essential feature of substances classified in the new categories is that exposure to these chemicals does not contribute significantly to the risk of cancer to man, provided that an appropriate exposure limit (MAK value) is observed. Chemicals known to act typically by non-genotoxic mechanisms, and for which information is available that allows evaluation of the effects of low-dose exposures, are classified in category 4. Genotoxic chemicals for which low carcinogenic potency can be expected on the basis of dose/response relationships and toxicokinetics and for which risk at low doses can be assessed are classified in category 5. The basis for a better differentiation of carcinogens is discussed, the new categories are defined, and possible criteria for classification are described. Examples for category 4 (1,4-dioxane) and category 5 (styrene) are presented.

Characterization of an Unscheduled DNA Synthesis Assay with a Cultured Line of Porcine Kidney Cells (LLC-PK1)

Proximal tubular cells are a primary site of tumour formation in the kidney probably due both to high exposure to absorbed chemicals and their multiple transport and bioactivation capacities (1). It is therefore important to develop appropriate short-term tests for investigating the organ specific genotoxicity of various chemicals. Since somatic mutations are considered as a crucial initiating step in chemical carcinogenesis (2), short-term tests detecting interactions of chemicals with DNA such as repair processes in damaged DNA sites are widely used for predicting potential carcinogenic properties of chemicals. The most appropriate method of estimating DNA repair is probably determination of unscheduled DNA synthesis (UDS) in exposed cells by monitoring the non-S-phase uptake of 3H-thymidine (3H-dThd) either by autoradiography of intact cells (3) or by liquid scintillation counting of the extracted DNA (4). UDS induction in renal tissue have already been undertaken using primary kidney cells exposed in vivo or in vitro to known or potential renal carcinogens and determining 3H-dThd incorporation by autoradiography (5). This method is highly specific, but its disadvantages lie in the long duration and the relative high costs of the experiments as well as in the difficulty of obtaining cell preparations of reliable and reproducible quality.

Dose-dependent stimulation/inhibition effects of cyclosporin A on lysosomal cathepsin activities in cultured proximal tubule cells

The effects of cyclosporin A on the activities of lysosomal cysteine proteinases (cathepsin B, H, L+B) in LLC-Pk1 cells were investigated to elucidate their potential role in cyclosporin A-induced nephrotoxicity. Cyclosporin A at lower doses (0.1–1,000 ng/ml) stimulated cathepsin B, H, L+B. In contrast, at a higher dose (10,000 ng/ml), it inhibited these proteinase activities associated with a reduction in protein degradation. In line with the altered proteinase activities, cellular protein content was decreased at the lower dose (10 ng/ml) and increased at the higher dose. The higher dose of cyclosporin A also enhanced cellular lipid peroxide content after an exposure of 4 and 10h. Co-incubation with superoxide dismutase (40 U/ml) did not ameliorate the inhibition of cathepsin B activity induced by the high dose of cyclosporin A. On the contrary, the calcium channel blocker verapamil (10−6 M) prevented this inhibition. In conclusion, cyclosporin A exerts a dose-dependent biphasic effect on lysosomal cysteine proteinase activities. A rise in cytosolic Ca2+ concentration, but not an enhanced lipid peroxidation, may be involved in the suppression of cathepsin B activity induced by the higher dose of cyclosporin A. These studies raise the possibility that alterations of tubular proteinase activity may play a role in the cyclosporin A-induced nephrotoxicity.

Insulin-Like Growth Factor I Induced Reduction in Cysteine Proteinase Activity in Freshly Isolated Proximal Tubule Cells of the Rat

The potential effects of insulin-like growth factor I (IGF-I) on lysosomal cysteine proteinases (cathepsin B, H and L+B activities) were investigated in the freshly isolated proximal tubule cells of rats. IGF-I significantly inhibited these enzyme activities after an incubation time of 80 min. This effect was associated with a dose-dependent increase in cellular protein content. The study suggests that, besides the established enhanced protein synthesis, IGF-I-induced cellular hypertrophy is mediated by a suppression of the proteolytic enzyme activity in proximal tubular cells.