The Multicenter Evaluation of In Vitro Cytotoxicity (MEIC) programme provided a battery of three basal cytotoxicity tests with a good (R2 = 0.77) prediction of human acute lethal blood ...concentrations. The predictive power of this battery would be considerably improved by the addition of new supplementary in vitro tests. The development of these new tests will be facilitated by a close coupling of test development to evaluation. The Cytotoxicology Laboratory, Uppsala (CTLU), is therefore inviting all interested in vitro toxicologists to take part in the Evaluation-guided Development of In Vitro Toxicity and Toxicokinetic Tests (EDIT). All EDIT activities (subprojects) will be designed on a case-by-case basis, but will follow a common pattern. The CTLU will use the accumulated MEIC/EDIT data, and its experience from the previous MEIC evaluation, to suggest priority areas, i.e. the need for certain in vitro toxicity data/tests as supplements to existing in vitro models/batteries on human systemic toxicity. Detailed research programmes corresponding to these areas will be published on the Internet. The CTLU will also try to raise funds for some projects and will coordinate multilaboratory studies. Interested laboratories developing or already using priority tests are encouraged to join the subprojects and to test specific sets of substances (usually sets of MEIC reference chemicals) in their new assays. The CTLU will provide adequate human reference data and will also evaluate results as single components of complex models, together with the laboratory conducting the test. At present, ten priority areas have been identified: a) repeat dose toxicity in vitro; b) urgent mechanistic information from in vitro studies of protein denaturation, morphology of cell injury, differential toxicity between various rapidly measured endpoints (10-60 minutes) and 24-hour cytotoxicity, toxicity to aerobic cells, and discrimination between rapid and slow cytotoxic mechanisms; c) in vitro tests on vitally important, specific receptor toxicity in humans; d) excitatory cytotoxicity; e) reversibility of cell toxicity; f) in vitro tests on passage across the blood-brain barrier; g) in vitro tests on absorption in the gut; h) protein binding in vitro; i) in vitro tests on distribution volumes (Vd); and j) in vitro tests on biotransformation to more-toxic metabolites (hepatocytes plus target cells). This paper gives a short presentation of the rationale for each subproject and reports on ongoing activities.
The mechanism responsible for the modification of mutagenicity by chlorophyllin has been investigated using mutagenic compounds with different mechanisms of action, including the monofunctional ...alkylating agents, N-methyl-N'-nitrosourea (MNU) and ethylmethanesulphonate (EMS); nitrosamines related to tobacco products, i.e. dimethyl-nitrosamine (DMN), N-nitrosonornicotine (NNN) and 4-(N-methyl-N-nitrosoamino)-1-(3-pyridinyl)-2-butanone (NNK); the polycyclic aromatic hydrocarbon (PAH) benzoapyrene (BaP) and two of its metabolites, i.e. (-)-7 beta,8 alpha-dihydroxy-7,8-dihydrobenzoapyrene (7,8-diol) and (+)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-oxy-7,8,9,10- tetrahydrobenzoapyrene (BPDE); and a complex mutagenic mixture, an extract and subfractions of Swedish moist oral snuff (SMOS). Mutagenicity was monitored with the Ames Salmonella/microsome assays (STY) and hprt V79 point mutation assay (V79). The effects of chlorophyllin on the mutagenicity of the nitrosamines in the STY assays were found to be complex. In the presence of either NNN or NNK, low concentrations of chlorophyllin actually potentiated the mutagenicity > 2-fold. However, at higher, but still non-toxic concentrations, chlorophyllin decreased the mutagenicity of both compounds. The same type of dose-response relationship for chlorophyllin was indicated in the V79 assay system with DMN, although the effect was much weaker. The results with STY were further confirmed by replacing chlorophyllin with another porphyrin compound, hemin. In contrast, biliverdin, a porphyrin structure without the central metal ion, was unable to potentiate the mutagenicity of NNK in STY.
The aim of the Evaluation-guided Development of New In Vitro Test Batteries (EDIT) multicentre programme is to establish and validate in vitro tests relevant to toxicokinetics and for organ-specific ...toxicity, to be incorporated into optimal test batteries for the estimation of human acute systemic toxicity. The scientific basis of EDIT is the good prediction of human acute toxicity obtained with three human cell line tests (R
2
= 0.77), in the Multicentre Evaluation of In Vitro Cytotoxicity (MEIC) programme. However, the results from the MEIC study indicated that at least two other types of in vitro test ought to be added to the existing test battery to improve the prediction of human acute systemic toxicity — to determine key kinetic events (such as biotransformation and passage through biological barriers), and to predict crucial organ-specific mechanisms not covered by the tests in the MEIC battery. The EDIT programme will be a case-by-case project, but the establishment and validation of new tests will be carried through by a common, step-wise procedure. The Scientific Committee of the EDIT programme defines the need for a specific set of toxicity or toxicokinetic data. Laboratories are then invited to perform the defined tests in order to provide the “missing” data for the EDIT reference chemicals. The results obtained will be evaluated against the MEMO (the MEIC Monograph programme) database, i.e. against human acute systemic lethal and toxicity data. The aim of the round-table discussions at the 19th Scandinavian Society for Cell Toxicology (SSCT) workshop, held in Ringsted, Denmark on 6–9 September 2001, was to identify which tests are the most important for inclusion in the MEIC battery, i.e. which types of tests the EDIT programme should focus on. It was proposed that it is important to include in vitro methods for various kinetic events, such as biotransformation, absorption in the gut, passage across the blood–brain barrier, distribution volumes, protein binding, and renal clearance/accumulation. Models for target organ toxicity were also discussed. Because several of the outlier chemicals (paracetamol, digoxin, malathion, nicotine, paraquat, atropine and potassium cyanide) in the MEIC in vivo–in vitro evaluation have a neurotoxic potential, it was proposed that the development within the EDIT target organ programme should initially be focused on the nervous system.
A new international project to evaluate the relevance for human systemic and local toxicity of in vitro tests of general toxicity of chemicals has been organized by the Scandinavian Society of Cell ...Toxicology under the title Multicenter Evaluation of In Vitro Cytotoxicity (MEIC). The basic assumptions underlying the project, as well as the practical goals and the design of the program are outlined. The list of the first 50 reference chemicals is presented. The chemicals are an otherwise unbiased selection of compounds with known human acutely lethal dosage and blood concentrations, including LD50-values in the rat or mouse. Most agents also have other data on human toxicity and toxicokinetics, including more extensive animal toxicity data. International laboratories already using or developing in vitro tests of various partial aspects of general toxicity are invited to test the substances, the results of which will be evaluated by us. The predictivity of the in vitro results for both partial and gross human toxicity data will be determined with combined use of univariate regression analysis and soft multivariate modeling. The predictivity of the in vitro results will be compared with the predictivity of conventional animal tests for the same chemicals. Finally, batteries of tests with optimal prediction power for various types of human toxicity will be selected. The need for and possible uses of such batteries are discussed.
Isolated rabbit pulmonary alveolar macrophages were found to be a convenient biological model system, relevant for studies of the toxicity of air pollutants. The phagocytic capacity and the oxygen ...consumption were used as test parameters and studied simultaneously on the same cells. The toxicity of extracts of airborne particles (ø < 15 μm) collected in urban and rural areas was investigated and compared to a cigarette-smoke condensate. An extract of particles from a car tunnel was found to be the most toxic air sample, inhibiting phagocytosis as well as respiration of the macrophages at a concentration representing 5 m
3
air/ml cell suspension. A corresponding sample collected on a roof of a five-storied building in the central area of a city (population 600,000} was found to inhibit phagocytosis but did not affect respiration. Further investigations revealed that one effect of the "tunnel" extract could be explained as an uncoupling of the mitochondria! respiratory control. Compared to the cigarette-smoke condensate, the toxicity of the air samples was infinitesimal.
The glutathione transferases (GST) belonging to class pi are primarily responsible for the intracellular detoxification of the highly mutagenic and carcinogenic compound (+)-7 beta, 8 ...alpha-dihydroxy-9 alpha, 10 alpha-oxy-7,8,9,10-tetrahydrobenzoapyrene (BPDE). The aim of the present investigation was to study the nature and function of the GST pi gene in relation to the mutagenicity of BPDE in different cell lines. The studies were performed on three cell lines commonly used in toxicological studies, i.e. rat hepatoma cells (H4IIE), human mammary carcinoma cells (MCF-7) and Chinese hamster lung fibroblasts (V79). Western blotting with antisera against GST pi revealed a high level of reaction with cytosol from V79 and H4IIE cells. Furthermore, cytosol from the V79 cells demonstrated low levels of GSTs belonging to the alpha and mu classes, suggesting that a considerable portion of the total capacity of these cells to conjugate chlorodinitrobenzene (CDNB) was provided by GST pi. The level of mRNA for GST pi, as measured by Northern blots, was high in V79 and H4IIE and undetectable in the MCF-7 cell line. Analysis of the DNA fragment patterns using a series of restriction enzymes, revealed that all three cell lines have the pi class gene, although with different band patterns. The findings with H4IIE and MCF-7 cells with respect to their expression of the GST pi gene and their ability to conjugate BPDE were in agreement with the mutagenic effects of BPDE, produced by metabolic activation of (-)-7 beta, 8 alpha-dihydroxybenzoa-pyrene in the cells. In contrast, V79 cells although expressing high levels of GST pi, showed no ability to conjugate BPDE or to inhibit the mutagenicity of this compound. Based on these results, we suggest that V79 Chinese hamster lung cells contain a GST pi with a different substrate specificity from those of the human and rat GST pi enzymes.
The nitrosated form of cimetidine (Tagamet), nitrosocimetidine (NC), belongs to a group of nitrosoamidines in which the mutagenic and carcinogenic properties of N-methyl-N'-nitro-N-nitrosoguanidine ...(MNNG) and N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG) have been studied in detail. The common mechanism of action of these compounds is that nucleophilic atoms can attack their iminocarbon, thereby leading to the formation of alkyldiazohydroxide and, subsequently of an alkylating and mutagenic diazonium ion. A competitive, non-mutagenic pathway involves denitrosation, which is strongly dependent on pH and can be enhanced by glutathione transferase. The influence of different thiols (e.g. glutathione and the L- and D-forms of N-acetylcysteine (L-NAC and D-NAC respectively at different extra- and intracellular concentrations on the mutagenicity of these nitrosoamidines in V79 cells has been studied in the present investigation. The results demonstrate that the mutagenicity of MNNG and ENNG is highly dependent on where their reaction with thiols takes place. Thus, an increase in the intracellular glutathione level in combination with treatment with MNNG (or ENNG) in thiol-free medium elevated the mutagenicity, whereas treatment with thiols in the medium reduced mutagenicity. The mutagenicity of NC was, on the other hand, only slightly affected by increasing extra- or intracellular thiol levels. The dependence of NC-induced mutagenicity on thiols was indicated, however, by the finding that depletion of intracellular glutathione reduced this mutagenicity almost completely. The effects of treatments with thiols alone or in combination with glutathione transferases suggest that, under our assay conditions (e.g. physiological pH and thiol levels, in combination with low levels of the nitrosoamidines), no denitrosation occurs. On the contrary, our results indicate that intracellular thiols, and possibly glutathione transferases, potentiate the production of mutagenic species from these nitrosamidines.
In this study, 50 chemicals selected on the basis of existence of particularly reliable human toxicity data were screened in a cytotoxicity test involving inhibition of the growth of Ascites Sarcoma ...BP8 cells. These test results are part of an international validation program, the Multicenter Evaluation of In Vitro Cytotoxicity (MEIC), the aim of which is to recommend batteries of in vitro tests to be used for prediction of human toxicity. The cytotoxicities (expressed as the concentrations causing 50% inhibition of cell growth) were compared to acute toxicity data in humans (LDL0) and rodents (LD50), showing the best correlation to rodent data. The results are discussed in relationship to what is usually referred to as basal cytotoxic mechanisms as a cause of in vivo toxicity. It could be concluded that the predicted results on the basis of mechanistic reasoning were not always obtained.
This study deals with the role of glutathione transferase (GST)-mediated conjugation of (+)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-oxy-7,8,9,10- tetrahydrobenzoapyrene (BPDE) in two mammalian cell ...lines, human mammary carcinoma cells (MCF-7) and rat hepatoma cells (H4IIE), in relation to their capacity to metabolize (-)-trans-7,8-dihydroxy-7,8-dihydrobenzoapyrene (-)-BP-7,8-diol to products that induce mutations in co-cultivated V79 cells. Both MCF-7 and H4IIE cells metabolized (-)-BP-7,8-diol to BPDE, but mutations in co-cultivated V79 cells were only detected with MCF-7 cells. However, depletion of glutathione (GSH) in H4IIE cells increased the mutagenicity of (-)-BP-7,8-diol to a similar level to that found with MCF-7 cells. Measurements of GST activity using GSH and post-microsomal supernatants from H4IIE, V79 and MCF-7 cells indicated a substantial difference in conjugation capacity. Although preparations from all three cell-lines showed GST activity with 1-chloro-2,4-dinitrobenzene as the substrate, GST activity towards BPDE could only be detected in supernatants from H4IIE cells. This is consistent with the presence of GST 7-7 an isoenzyme highly efficient in catalysing BPDE-GSH conjugation. The difference in GSH-conjugation activity towards BPDE was confirmed using intact H4IIE and MCF-7 cells in culture. These results indicate that GSH-conjugation plays a pivotal role in mutagenesis induced by polycyclic aromatic hydrocarbons (PAH). Accordingly, a deficiency in GSH-conjugation capacity may be regarded as one important factor in defining a target cell population with an increased risk for tumour initiation following exposure to PAH.
