Initiating activity of 1,1,2,2-tetrachloroethane in two-stage BALB/c 3T3 cell transformation.

By using in vitro two-stage BALB/c 3T3 cell transformation assay, we have tested the effect of promoting treatment with tetradecanoylphorbol acetate (TPA) on transformation induced by 1,1,2,2-tetrachloroethane (1,1,2,2-TTCE). Cells were treated with subeffective or transforming concentrations of 1,1,2,2-TTCE in the presence of an S9-mix activating system, followed by TPA promoting treatment. The transforming activity of 1,1,2,2-TTCE is evident only by reseeding confluent cells and allowing additional rounds of cell replications in the amplification test. Treatment with TPA leads to a marked transformation yield in all plates scored even at the lowest assayed dosage of 1,1,2,2-TTCE, without performing amplification of transformation.

In vitro effects of fenretinide on cell-matrix interactions.

BACKGROUND: Understanding the molecular basis of the metastatic spread of cancer and the underlying mechanisms is crucial for the development and appropriate clinical use of novel therapeutic agents directed at prevention of metastasis. Retinoids have been reported to inhibit cell proliferation, modulate cell differentiation, enhance apoptosis and to prevent the conversion of in situ cancer to locally invasive malignancy by suppressing the invasive process as well as by inhibiting angiogenesis. Fenretinide (4-HPR), a synthetic derivative of retinoic acid, is less toxic than natural retinoids and is active in the prevention and treatment of a variety of tumours in animal models. Its efficacy in cancer chemoprevention and therapy has been investigated in clinical trials. MATERIALS AND METHODS: In order to evaluate the effects of 4-HPR on the late stages of tumour progression, chemically transformed BALB/c 3T3 cells, showing a fully malignant phenotype, were exposed to 4-HPR (0.25-10 microM; 72 hours pre-treatment) and then analysed for in vitro invasive ability. The possible mechanisms of action responsible for the anti-invasive activity of 4-HPR were investigated, analysing cellular adhesion, motility, and proteolytic capability. RESULTS: Data showed that 4-HPR significantly inhibited the invasive phenotype of chemically transformed cells; the reduction in Matrigel invasion was dose-dependent and seemed not to be related to cytotoxic effects or reduction in cell proliferation rates induced by 4-HPR assayed doses. The 4-HPR-induced decrease in chemotactic motility of transformed cells correlated well with the invasion inhibition. 4-HPR, at active concentrations, differently affected cell adhesion to the extracellular matrix, depending on the coating substrate used (laminin, collagen IV, fibronectin and vitronectin). 4-HPR treatment significantly enhanced cell adhesion to laminin, while reducing cell-vitronectin attachment. It did not modify the attachment of the cells to fibronectin and collagen IV. Zymographic analysis failed to demonstrate 4-HPR involvement in the modulation of the activity and expression of gelatine degrading enzymes. CONCLUSION: These data suggest that 4-HPR inhibits tumour cell invasion through a basement-like matrix, by suppressing chemotactic motility and by altering cell-matrix interactions.

Effects of the protease inhibitor antipain on cell malignant transformation.

BACKGROUND: Several natural products have been found to exhibit a chemopreventive activity both in in vivo and in vitro experimental systems. Among them, protease inhibitors seem to play a key role in the regulation of growth and phenotypic expression of transformed cells as well as in the regulation of the late events of carcinogenesis. We evaluated the effect of antipain (AP), a natural protease inhibitor, on chemically induced BALB/c 3T3 cell transformation, on invasion and chemotactic motility of transformed cells and on their gelatinase expression. METHODS: BALB/c 3T3 cells were plated and exposed to 2.5 micrograms/ml 3-MCA or 50 micrograms/ml, 1,2-DBE. The effect of a non-cytotoxic dosage of AP (10 microM) was studied by: a) pretreating cells with AP for 48 hours before the carcinogen exposure; b) adding AP simultaneously to the carcinogen treatment; c) chronic addition of AP at each medium change throughout the experimental duration. The effectiveness of the treatment was analysed as the ability to reduce or inhibit the occurrence of transformed foci. Modulation of the invasive phenotype by anti-transforming dosages of AP was evaluated by in vitro Matrigel invasion assay. Gelatin zymography was performed in order to assess AP regulation of proteolytic enzymes, such as metalloproteases, involved in invasion and metastasis. RESULTS: AP treatment can reduce the transformation rate both in 3-MCA- and 1,2-DBE-initiated cells. Its effectiveness depends on the administration schedule, and chronic addition seems to be the most effective treatment. The concentration of AP, which is effective in the antitransformation assay, is not able to significantly affect the migration and invasion of chemically transformed cells or their gelatinase activity. CONCLUSIONS: AP can suppress chemically induced BALB/c 3T3 cell transformation through mechanisms which do not involve modulation of the invasive phenotype.

The covalent interaction of 1,4-dibromobenzene with rat and mouse nucleic acids: in vivo and in vitro studies.

1,4-Dibromobenzene (1,4-DBB) was covalently bound to DNA from liver, kidney, lung and stomach of mice after intraperitoneal administration. The covalent binding index (CBI) value (23 in mouse liver) was typical of weak initiators. On the contrary, no interaction with DNA from rat organs was observed (CBI detection limit: 1.3-2.6). The in vitro interaction of 1,4-DBB with calf thymus DNA was mediated mainly by microsomes, especially those from liver of both species and from mouse lung. Mouse subcellular fractions were more active then rat subcellular fractions. Unlike liver cytosol, subcellular cytosolic fractions from lung, kidney and stomach were capable of bioactivating 1,4-DBB, although to a lesser extent than liver microsomes. Both cytochrome P-450 and GSH-transferases are involved in 1,4-DBB bioactivation.

Isolation of a novel metabolizing system enriched in phase-II enzymes for short-term genotoxicity bioassays.

Murine S9 liver fractions isolated from mice fed 7.5 g kg-1 2(3)-tert-Butyl-4-hydroxyanisole (BHA) for 3 weeks were tested to determine: (a) the profile of both phase-I and phase-II xenobiotic metabolizing enzymes; (b) their ability to induce in vitro covalent binding of some precarcinogens to calf thymus DNA; and (c) their activation in a standard genetic toxicology assay. With regard to phase-I pathway, the S9 fraction expressed various cytochrome P-450-(CYP) (classes 1A1, 1A2, 2B1, 2E1, and 3A)-dependent biotransformation enzymes at levels comparable with those present in murine control liver. For post-oxidative enzymes, the S9 expressed high levels of glutathione S-transferases (up to 12-fold increase), glutathione S-epoxide-transferase (up to 2.6-fold), UDP-glucuronosyl transferase (up to 5.3-fold) and epoxide hydrolase (up to 2.6-fold) activities, as compared to untreated mice. The in vitro DNA binding of the precarcinogenic agents [14C]-1,4-dichlorobenzene, [14C]-1,2-dichlorobenzene and [14C]-1,4-dibromobenzene, mediated by BHA-induced cytosol and/or microsomal preparation, showed an increase in specific activity comparable to that observed with phase-I (PB/beta NF) induced S9. In some instances, covalent binding was even more elevated using the BHA-induced systems as compared with traditional S9 fractions. For example, cytosol derived from BHA-administered mice was able to induce a significant binding to calf thymus DNA up to 26.2-fold increase for [14C]-1,4-dichlorobenzene, while cytosol from PB/beta NF was not. A high mutagenic response on diploid D7 strain of Saccharomyces cerevisiae as exemplified by a marked induction of mitotic gene conversion and point (reverse) mutation confirmed that BHA-derived S9 fractions activate precarcinogens to final genotoxins. Because a number of chemicals are activated by either oxidative or post-oxidative enzymes, the use of metabolizing biosystems, with an enhanced phase-II pathway, together with classical S9 fractions, can improve the sensitivity of the assay in detecting unknown genotoxins.

In vivo and in vitro interaction of 1,2-dichlorobenzene with nucleic acids and proteins of mice and rats.

Twenty-two hours after i.p. injection into male Wistar rats and BALB/c mice, 1,2-dichlorobenzene (1,2-DCB) was covalently bound to DNA, RNA, and proteins of liver, kidney, lung and stomach. The covalent binding index to liver DNA was typical of carcinogens classified as weak initiators. The enzyme-mediated in vitro interaction of 1,2-DCB with calf thymus DNA of synthetic polyribonucleotides was carried out by a microsomal mixed-function oxidase system and microsomal GSH-transferases, which seemed to be effective only in liver and lung of rat and mouse. Cytosolic GSH-transferases played a minor role in 1,2-DCB bioactivation. The latter finding provides the first evidence of 1,2-DCB genotoxicity in mammalian cells. The type of halide, the number of halosubstituents and their spatial disposition on the benzene ring are the major determinants of halobenzenes activability to intermediate(s) capable of interacting covalently with DNA and other macromolecules in biologic systems.

Chloroform bioactivation leading to nucleic acids binding.

Chloroform was bound covalently to DNA, RNA and proteins of rat and mouse organs in vivo after i.p. injection. Covalent Binding Index values of rat and mouse liver DNA classify chloroform as a weak initiator. Labelings of RNA and proteins from various organs of both species were higher than that of DNA. In an in vitro cell-free system, chloroform was bioactivated by cytochrome P450-dependent microsomal fractions, by cytosolic GSH-transferases from rat and mouse liver, and particularly by the latter enzymes from mouse lung. This observation suggests that GSH plays a role in the binding of chloroform metabolites to DNA. The presence of both microsomal and cytosolic enzymatic systems in the standard incubation mixture generally led to an additive or synergistic bioactivating effect for rat and mouse, respectively.

Growth suppression of transformed BALB/c 3T3 cells by transforming growth factor beta 1 occurs only in the presence of their normal counterparts.

Transforming growth factor beta 1 (TGF-beta 1) enhances the yield of transformed foci of BALB/c 3T3 cells, but the continuous presence of TGF-beta 1 after foci formation inhibits the growth of transformed foci. The focus-forming ability of Ha-ras-, v-src- and PyMT-transformed cells growing on a monolayer of non-transformed cells was completely suppressed by TGF-beta 1, whereas growth of the transformed cells was little inhibited by TGF-beta 1 in the absence of their normal counterparts. The inhibition by TGF-beta 1 of focus formation by transformed BALB/c 3T3 cells on a normal cell monolayer remained when TGF-beta 1 was removed from the culture medium after 2 weeks. However, the transformed cells were not killed, since they grew in culture conditions under which only transformed cells are able to grow (soft agar). These results suggest that TGF-beta 1 suppresses growth of transformed cells in the presence of normal cells. Furthermore, when non-transformed cells were treated with TGF-beta 1 before co-culture with Ha-ras-transformed cells, formation of transformed foci was inhibited. When normal and transformed cells were cultured in the same dish but separated physically, focus formation was still inhibited. On the other hand, TGF-beta 1 enhanced the growth and changed the morphology of non-transformed cells only in the presence of transformed counterparts. The growth inhibitory effect of TGF-beta 1 on transformed cells and its growth stimulatory effect on non-transformed cells in co-culture conditions suggest the induction of reciprocal paracrine growth regulatory factors. As TGF-beta 1 inhibits the growth of transformed BALB/c 3T3 cells only in the presence of their normal counterparts, a paracrine negative growth control mechanism appears to be operating.

Strategies for advancement of short-term mutagenicity tests: on the optimal ionic strength for the liver microsomal assay.

The aim of this work was to optimize the ionic strength (tau) in the liver microsomal assay (LMA) in performing short-term genotoxicity tests. tau optimization would increase the sensitivity (i.e. decrease false negatives) and at the same time increase the specificity (decrease false positives). Such optimization depends upon the relative activities and stabilities of the liver polysubstrate cytochrome P450- and FAD-containing monooxygenase-dependent metabolizing enzymes present in the incubation mixtures. With regard to phase-I pathway, the expression of various P450-like activities (IA1, IA2, IIB1, IIE1, IIIA P450 classes) and thiobenzamide s-oxidase (as FAD-MFO marker), were examined in terms of their exact incubation conditions for the LMA during a period of preincubation (1 h) over the tau range 0.06-1.40. As a comparison with the phase-II pathway, the behaviour of glutathione S-transferases (total and pi class), glutathione S-epoxide transferase, epoxide hydrolase and UDP-glucuronosyl transferase were studied. Lipid peroxidation (LP) was also determined. Experiments were performed on S9 fractions derived from sodium phenobarbital, beta-naphthoflavone, isosafrol, ethanol and pregnenolone 16-alpha carbonitrile super-induced mouse liver. The maximal value of the mean specific activity (Asp), up to a 46% increase, was found at tau = 0.864 for oxidative reactions considered. On the contrary, a slight modulation of Asp for post-oxidative reactions was seen. LP was not changed appreciably by varying tau. In vitro DNA binding of the well-known premutagenic agent [14C]dimethylnitrosamine ([14C]DMNA), mediated by mouse hepatic microsomal enzymes, showed a significant increase of specific activity at tau = 0.864 (2.25-fold) compared to the usual tau (0.06) used. Additional confirmation of these results stems from mutagenesis experiments using DMNA on the diploid D7 strain of Saccharomyces cerevisiae as a biological test system. Indeed, a significant enhancement of mitotic gene conversion (up to 1.8-fold), mitotic crossing-over (2.6-fold) and reverse point mutation (2.6-fold) frequencies was achieved at tau = 0.86 compared to tau = 0.06 (traditional). These data show that tau = 0.86 can provide more convenient conditions for in vitro bioactivation (as exemplified by an increased Asp phase-I/Asp phase-II ratio), as well as DNA binding and genotoxic response.

Enhancement of BALB/c 3T3 cells transformation by 1,2-dibromoethane promoting effect.

Two of the most representative halogenated aliphatic hydrocarbons, 1,2-dibromoethane and 1,1,2,2-tetrachloroethane, were tested in the two-stage cell transformation model for analysing the promoting ability. Both of these compounds had previously been found to exert genotoxic effects, probably acting as moderate initiators. BALB/c 3T3 cells were initiated with subtransforming doses of N-methyl-N-nitro-N-nitrosoguanidine or 3-methylcholanthrene and then exposed to a chronic treatment with different non-transforming dosages of the two haloalkanes. 1,1,2,2-Tetrachloroethane did not exert any promoting activity in that system. By contrast, significant promoting effects by 1,2-dibromoethane were observed both in cells treated with N-methyl-N-nitro-N-nitrosoguanidine and in cells treated with 3-methylcholanthrene. Promotion of the transformation process initiated with 3-methylcholanthrene was detectable when confluent cells in the chemical-treated plates were replated in the level-II amplification test. This experimental procedure allowed cells to perform further rounds of replications and transformed foci to became detectable. Results gave evidence for a promoting role of 1,2-dibromoethane in multistep carcinogenesis, probably responsible for the higher oncogenic ability of this compound with respect to 1,1,2,2-tetrachloroethane.

In vivo and in vitro interaction of trichloroethylene with macromolecules from various organs of rat and mouse.

Trichloroethylene was covalently bound in vivo to DNA, RNA and proteins of rat and mouse organs 22 hr after ip injection. The covalent binding index values of rat and mouse liver DNA classify trichloroethylene as a weak initiator. Labeling of RNA and proteins from various organs of both species was higher than that of DNA. In vitro, trichloroethylene was bioactivated by microsomal fractions dependent on cytochrome P450, mainly from liver of both species, to intermediate(s) capable of binding to exogenous DNA. No particular species-specific difference was evident except for mouse lung microsomes which were more efficient than rat lung microsomes. GSH-transferases capable of bioactivating P450-dependent were present in mouse lung microsomes and in liver microsomes of both species. These data, along those previously reported, provide sufficient evidence for a weak ability of TCY to interact covalently with DNA.

1,2-Dibromoethane as an initiating agent for cell transformation.

The two-stage transformation assay increases the sensitivity of cells to chemicals and permits detection of carcinogens acting as initiating agents. 1,2-Dibromoethane, a representative halogenated aliphatic, has been tested in the two-stage BALB/c 3T3 cells transformation test at dosage from 16 microM to 128 microM. This dose range is much lower than those previously found efficient in transforming BALB/c 3T3 cells. Apart from the lowest dose, which induced borderline effects, all the other assayed dosages appeared to induce heritable changes in the target cells. The initiated cells were revealed as fully transformed foci both in the combination with a chronic promoting treatment and also by allowing cells to perform more rounds of cell replication. The results clearly show that 1,2-dibromoethane can act as an initiator of cell transformation.