Wolfram Parzefall

Single cell gel electrophoresis assay: a new technique for human biomonitoring studies.

Human biomonitoring using the single cell gel electrophoresis (SCGE) or comet assay is a novel approach for the assessment of genetic damage in exposed populations. This assay enables the detection of various forms of DNA damage in individual cells with ease and speed and is, therefore, well suited to the analysis of a large group in a population. Here, application of SCGE assay in the identification of dietary protective factors, in clinical studies and in monitoring the risk of DNA damage resulting from occupational, environmental or lifestyle exposures is reviewed. Also, the comparative sensitivity of SCGE assay and conventional cytogenetic tests to detect genetic damage is discussed. Finally, strengths and shortcomings of the SCGE assay are addressed.

Use of metabolically competent human hepatoma cells for the detection of mutagens and antimutagens.

The human hepatoma line (Hep G2) has retained the activities of various phase I and phase II enzymes which play a crucial role in the activation/detoxification of genotoxic procarcinogens and reflect the metabolism of such compounds in vivo better than experimental models with metabolically incompetent cells and exogenous activation mixtures. In the last years, methodologies have been developed which enable the detection of genotoxic effects in Hep G2 cells. Appropriate endpoints are the induction of 6-TGr mutants, of micronuclei and of comets (single cell gel electrophoresis assay). It has been demonstrated that various classes of environmental carcinogens such as nitrosamines, aflatoxins, aromatic and heterocyclic amines and polycyclic aromatic hydrocarbons can be detected in genotoxicity assays with Hep G2 cells. Furthermore, it has been shown that these assays can distinguish between structurally related carcinogens and non-carcinogens, and positive results have been obtained with rodent carcinogens (such as safrole and hexamethylphosphoramide) which give false negative results in conventional in vitro assays with rat liver homogenates. Hep G2 cells have also been used in antimutagenicity studies and can identify mechanisms not detected in conventional in vitro systems such as induction of detoxifying enzymes, inactivation of endogenously formed DNA-reactive metabolites and intracellular inhibition of activating enzymes.

Genotoxic effects of crude juices from Brassica vegetables and juices and extracts from phytopharmaceutical preparations and spices of cruciferous plants origin in bacterial and mammalian cells

Crude juices of eight Brassica vegetables as well as juices and extracts of spices and phytopharmaceutical preparations from cruciferous vegetables were tested for induction of point mutations in Salmonella TA98 and TA100, repairable DNA damage in E.coli K-12 cells and clastogenic effects in mammalian cells. In bacterial assays, all juices caused genotoxic effects in the absence of metabolic activation, the ranking order being: Brussels sprouts > white cabbage > cauliflower > green cabbage > kohlrabi > broccoli > turnip > black radish. In experiments with mammalian cells, six juices induced structural chromosome aberrations. Brussels sprouts, white and green cabbage caused the strongest effects (800 microliters of juice induced a 5-fold increase over the background). In sister chromatid exchange assays, positive results were measured as well, but the effects were less pronounced. With all juices the genotoxic effects seen in mammalian cells were paralleled by a pronounced decrease in cell viability. Column fractionation experiments showed that 70-80% of the total genotoxic activity of the juices is found in the fraction which contains isothiocyanates and other breakdown products of glucosinolates, whereas phenolics and flavonoids contributed to a lesser extent to the overall effects. On the basis of these findings, and considering the negative results obtained with non-cruciferous vegetables (tomato, carrot and green pepper), it seems likely that the genotoxic effects of the juices are due to specific constituents of cruciferous plants such as glucosinolates and/or their breakdown products, in particular, isothiocyanates, which we found previously to be potent genotoxins in bacterial and mammalian cells. Finally, spices (mustards and horse radish paste) and phytopharmaceutical preparations were tested in bacterial assays. Mustards and horse radish caused very weak effects while most of the pharmaceutical preparations gave negative results, except cabbage tablets, which caused a strong and dose dependent induction of his revertants in Salmonella TA100. The present findings clearly indicate that cruciferous vegetables contain DNA damaging constituents. These observations are in contrast to earlier findings, which emphasized the antimutagenic effects of vegetable juices and also raise the question whether greatly increased consumption of Brassica vegetables or their concentrated constituents as a means for cancer prevention is indeed recommendable.

Search for Compounds That Inhibit the Genotoxic and Carcinogenic Effects of Heterocyclic Aromatic Amines

Over the last 30 years approximately 160 reports have been published on dietary compounds that protect from the mutagenic and carcinogenic effects of heterocyclic aromatic amines (HAAs). In the first section of this review, the current state of knowledge is briefly summarized. Based on the evaluation of the available data, various protective mechanisms are described, and the use of different methodologies for the detection of protective effects is critically discussed. In most antimutagenicity studies (>70%) bacterial indicators (predominantly Salmonella strain TA98) were used, and about 600 individual compounds and complex mixtures have been identified that attenuate the effects of HAAs. The most frequently used in vivo method to detect protective effects are adduct measurements; anticarcinogenic dietary factors were identified by aberrant crypt foci assays and liver foci tests with rats. The mechanisms of protection include inactivation of HAAs and their metabolites by direct binding, inhibition of enzymes involved in the metabolic activation of the amines, induction of detoxifying enzymes, and interaction with DNA repair processes. The detection spectrum of conventional in vitro mutagenicity assays with metabolically incompetent indicator cells is limited. These procedures reflect only simple mechanisms such as direct binding of the HAAs to pyrroles and fibers. It has been shown that these compounds are also effective in rodents. More complex mechanisms, namely, interactions with metabolic activation reactions are not adequately represented in in vitro assays with exogenous enzyme homogenates, and false-negative as well as false-positive results may be obtained. More appropriate approaches for the detection of protective effects are recently developed test systems with metabolically competent cells such as the human Hep G2 line or primary hepatocytes. SCGE tests and DNA adduct measurements with laboratory rodents enable the detection of antigenotoxic effects in different organs, including those that are targets for tumor induction by the amines. Medium term assays based on aberrant crypt foci in colon and liver foci tests have been used to prove that certain compounds that prevented DNA damage by HAAs also reduced their carcinogenic effects. These experiments are costly and time consuming and, due to the weak induction capacity of the amines, only pronounced anticar-cinogenic effects can be detected. Over the years, a large bulk of data on HAA protective compounds has accumulated, but only for a few (e.g., fibers, pyrroles, constituents of teas, and lactic acid bacteria) is there sufficient evidence to support the assumption that they are protective in humans as well.

Risk assessment of dioxin contamination in human food

Dioxins are highly toxic by-products of incineration processes and of production of chloro-organic chemicals. Accidental poisonings have occurred repeatedly. The main human exposure is via the dietary route. Species comparisons of toxic effects on the basis of ingested doses are not possible because of the highly differing toxicokinetics between humans and experimental animals. On the basis of internal doses or body burdens acute toxic and tumorigenic responses are observed at similar levels in humans and rats. PCB/PCDD/F contamination at levels which have been reported of marketed chicken meat and eggs in 1999 in Belgium may have increased body burdens by approximately 10%. However, it is estimated that a several hundred-fold higher uptake would be necessary to reach body burdens leading to overt toxicity in normal human subjects.

Apoptosis and Hepatocarcinogenesis

Cells may die by active mechanisms (cellular suicide). The concept of active cell death goes back to the 19th and early 20th century [1]. Active or programmed cell death serves to eliminate excessive cells, e.g. from hyperplastic organs, or cells damaged by moderate injury. Morphologically and biochemically, mechanisms of active cell death may be diVerent in diVerent organs and in different physiological states. Apoptosis (type I) is characterized by cytoplasmic and nuclear condensation, fragmentation, and heterophagy [2]; in type II cell death autophagic/lysosomal processes are prominent which produce cytoplasmic degradation well before nuclear alterations [3, 4].

Modification of N-acetyltransferases and glutathione S-transferases by coffee components: possible relevance for cancer risk.

Enzymes of xenobiotic metabolism are involved in the activation and detoxification of carcinogens and can play a pivotal role in the susceptibility of individuals toward chemically induced cancer. Differences in such susceptibility are often related to genetically predetermined enzyme polymorphisms but may also be caused by enzyme induction or inhibition through environmental factors or in the frame of chemopreventive intervention. In this context, coffee consumption, as an important lifestyle factor, has been under thorough investigation. Whereas the data on a potential procarcinogenic effect in some organs remained inconclusive, epidemiology has clearly revealed coffee drinkers to be at a lower risk of developing cancers of the colon and the liver and possibly of several other organs. The underlying mechanisms of such chemoprotection, modifications of xenobiotic metabolism in particular, were further investigated in rodent and in vitro models, as a result of which several individual chemoprotectants out of the >1000 constituents of coffee were identified as well as some strongly metabolized individual carcinogens against which they specifically protected. This chapter discusses the chemoprotective effects of several coffee components and whole coffee in association with modifications of the usually protective glutathione-S-transferase (GST) and the more ambivalent N-acetyltransferase (NAT). A key role is played by kahweol and cafestol (K/C), two diterpenic constituents of the unfiltered beverage that were found to reduce mutagenesis/tumorigenesis by strongly metabolized compounds, such as 2-amino-1-methyl-6-phenylimidazo-[4,5-b]pyridine, 7,12-dimethylbenz[a]anthracene, and aflatoxin B(1), and to cause various modifications of xenobiotic metabolism that were overwhelmingly beneficial, including induction of GST and inhibition of NAT. Other coffee components such as polyphenols and K/C-free coffee are also capable of increasing GST and partially of inhibiting NAT, although to a somewhat lesser extent.

Toxic Effects of Griseofulvin: Disease Models, Mechanisms, and Risk Assessment

Griseofulvin (GF) has been in use for more than 30 years as a pharmaceutical drug in humans for the treatment of dermatomycoses. Animal studies give clear evidence that it causes a variety of acute and chronic toxic effects, including liver and thyroid cancer in rodents, abnormal germ cell maturation, teratogenicity, and embroyotoxicity in various species. No sufficient data from human studies are available at present to exclude a risk in humans: therefore, attempts were made to elucidate the mechanisms responsible for the toxic effects of GF and to address the question whether such effects might occur in humans undergoing GF therapy. It is well documented that GF acts as a spindle poison and its reproductive toxicity as well as the induction of numerical chromosome aberrations and of micronuclei in somatic cells possibly may result from disturbance of microtubuli formation. Likewise, a causal relationship between aneuploidy and cancer has been repeatedly postulated. However, a critical survey of the data available on aneuploidogenic chemicals revealed insufficient evidence for such an association. Conceivably, other mechanisms may be responsible for the carcinogenic effects of the drug. The induction of thyroid tumors in rats by GF is apparently a consequence of the decrease of thyroxin levels and it is unlikely that such effects occur in GF-exposed humans. The appearance of hepatocellular carcinomas (HCC) in mice on GF-supplemented diet is preceded by various biochemical and morphological changes in the liver. Among these, hepatic porphyria is prominent, it may result from inhibition of ferrochelatase and (compensatory) induction of ALA synthetase. GF-induced accumulation of porphyrins in mouse liver is followed by cell damage and necrotic and inflammatory processes. Similar changes are known from certain human porphyrias which are also associated with an increased risk for HCC. However, the porphyrogenic effect of GF therapy in humans is moderate compared with that in the mouse model, although more detailed studies should be performed in order to clarify this relationship on a quantitative basis. A further important effect of GF-feeding in mice is the formation of Mallory bodies (MBs) in hepatocytes. These cytoskeletal abnormalities occur also in humans, although under different conditions; their appearance is associated with the induction of liver disease and HCC. Chronic liver damage associated with porphyria and MB formation, enhanced cell proliferation, liver enlargement, and enzyme induction all may contribute to the hepatocarcinogenic effect of GF in mice. In conclusion, further investigation is required for adequate assessment of health risks to humans under GF therapy.

Induction by cyproterone acetate of DNA synthesis and mitosis in primary cultures of adult rat hepatocytes in serum free medium

The aim of this study was to elucidate whether serum-free conditions could be found in primary hepatocyte cultures under which the growth inducing properties of xenobiotics and hormones could be tested. Cyproterone acetate (CPA), a steroid with anti-androgenic and progestogenic activity, was chosen as a model compound because of its known strong mitogenic properties in rat liver in vivo. EGF served as a positive control. Induction of DNA synthesis was studied by [3H]-thymidine labeling and autoradiography. Mitoses were counted in hematoxylin stained specimens. The main steps which led to an efficient stimulation of DNA synthesis by CPA were (i) reduction of hormone concentrations to levels approaching (approx. 10 x) physiological concentrations better than the previously used pharmacological ones (up to 2500 x); (ii) supplementation with glucocorticoid (most effective at 10–100 nM dexamethasone); (iii) selection of the interval for cumulative labeling with thymidine at 44–68 h; (iv) lowering of cell density at seeding to 50 000 cells/cm2 (subconfluency); (v) treatment with concentrations of 10–100 μM CPA. With these conditions CPA labelling was 13–20% (increase 4-to 9-fold). Mitotic incidence was 0.56% (CPA) versus 0.08% in controls. From a dose response study (0.1–100 μM) a no-effect-level for induction of DNA synthesis was found in the range of 0.1–1 μM. None of the high concentrations of CPA did cause cytotoxicity as estimated by morphological observations or release of lactate dehydrogenase into the medium. This work demonstrates that CPA under appropriate, defined culture conditions induces DNA synthesis and mitosis. The findings suggest that CPA action on the liver in vivo is at least in part a direct one. The extent of induction was in the same range as found in vivo. The effective concentrations were almost equivalent to CPA liver concentrations after treatment in vivo. Thus the present culture conditions appear to simulate quite well in vivo liver growth control mechanisms. This stresses the versatility of primary hepatocyte cultures as a tool in toxicology for the study of normal and drug-induced growth responses.

Genotoxic effects of wastewater from an oncological ward.

Aim of this study was the evaluation of the genotoxic activities of hospital wastewaters. Samples from an oncological ward of the general hospital of Vienna, Austria, were tested in the Salmonella/microsome assay in strains TA98, TA100 and TA1535 with or without metabolic activation, and in the single-cell gel electrophoresis (SCGE) assay with primary rat hepatocytes. In the bacterial tests, consistently negative results were obtained while in the experiments with liver cells a significant and dose-dependent induction of DNA damage (up to two-fold over the background) was found. Membrane filtration resulted in a substantial (62-77%) reduction of these effects, while additional treatments (activated carbon filtration and UV-irradiation) did not lead to a further decrease of the genotoxic activity of the samples. SCGE experiments with cisplatin, carboplatin and 5-fluorouracil, which were detected in the water samples, showed that these cytostatics cause a significant induction of DNA damage only at concentrations that are substantially higher than those in the native waters. These findings indicate that other chemicals, possibly quaternary ammonium compounds, account for the effects of the hospital wastewaters.