The effects of antioxidants and enzymes involved in glutathione metabolism on mutagenesis by glutathione and L-cysteine.

The effects of small molecular weight antioxidants and antioxidant enzymes on the mutagenicities of glutathione (GSH) and L-cysteine were studied in Salmonella typhimurium strain TA102. GSH and cysteine mutagenesis were inhibited by antioxidants and radical scavengers such as alpha-tocopherol, Trolox C, butylated hydroxyanisole (BHA), and retinyl acetate. Superoxide dismutase (SOD) had no effect, but catalase and horseradish peroxidase (HRP) inhibited mutagenesis. The heat-denatured enzymes had no effect on mutagenesis. Cysteine mutagenesis was enhanced by native and by heat-denatured rat-kidney post-mitochondrial supernatant, and by ferric ions. H2O2 and the H2O2-generating system of glucose-glucose oxidase (GOX) were mutagenic in TA102. Synergistic increases in mutagenesis were obtained in systems containing combinations of GSH or cysteine, with either H2O2 or the H2O2-generating system of glucose-GOX. GSH peroxidase (GPX) had no effect on mutagenesis of GSH or of H2O2, whereas the synergistic increase in mutagenesis by a combination of GSH and H2O2 was effectively inhibited by GPX. The results suggest strongly that, at least in biochemically-defined systems, GSH and cysteine mutagenesis are oxidative in nature, and involve reactive forms of oxygen and/or other radicals.

Localization of oxidative damage by a glutathione-gamma-glutamyl transpeptidase system in preneoplastic lesions in sections of livers from carcinogen-treated rats.

Previous studies from our laboratories have shown that catabolism of glutathione (GSH) by gamma-glutamyl transpeptidase (GGT) in the presence of transition metals leads to oxidative damage (OD). This damage is exemplified in vitro by GGT-dependent GSH mutagenesis which involves reactive oxygen species and by GGT-dependent accumulation of lipid peroxidation (LPO) products in systems containing polyunsaturated fatty acid and GSH. In order to test whether catabolism of GSH by membranal GGT in enzyme-altered preneoplastic hepatic lesions can induce oxidative damage in situ, and to test whether the OD is localized in these lesions, 21 day old Fischer rats were treated with 12 mg/kg diethylnitrosamine (DEN) followed by 0.1% or 0.25% phenobarbital (PB) in the diet. Cryostat sections were examined histochemically for GGT-rich hepatic lesions. Adjacent sections were incubated with GSH and iron and examined for areas staining for lipid peroxidation. Distinct LPO-positive areas were shown to correspond well with the GGT-positive hepatic lesions. Promotion with 0.25% PB led to increasing proportions of LPO-positive lesions with time among GGT-positive lesions. The visualization of LPO in GGT-rich hepatic lesions depended on the presence of GSH and iron, and was not observed following chelation of iron by diethyl triaminopentaacetic acid (DTPA), in the presence of acivicin, an inhibitor of GGT, or in the presence of the radical scavenger butylated hydroxytoluene (BHT). The factors affecting GSH-GGT-dependent LPO in the GGT-rich foci were identical to those affecting GSH-GGT-driven LPO in vitro, and were similar to those affecting oxidative GSH-mutagenesis catalyzed by GGT. The results indicate that metabolism of GSH by GGT in preneoplastic liver foci can initiate an oxidative process leading to a radical-rich environment and to oxidative damage. Such damage may contribute to the processes by which cells within such foci progress to malignancy.

Glutathione metabolism by gamma-glutamyltranspeptidase leads to lipid peroxidation: characterization of the system and relevance to hepatocarcinogenesis.

Glutathione (GSH)-driven lipid peroxidation (LPO) in vitro was catalyzed by gamma-glutamyltranspeptidase (GGT; EC 2.3.2.2.). The reaction required iron, iron chelators and oxygen, was accelerated by glycylglycine (gly)2, a GGT enhancer, and was inhibited by the GGT inhibitors serine--borate and acivicin. LPO occurred at rat plasma concentrations of GSH and transferrin, and in the presence of putative physiological chelators such as citrate and ADP. GSH-driven LPO was inhibited by butylated hydroxytoluene, but not by catalase, peroxidase or superoxide dismutase. These results suggest that metabolism of GSH initiated by GGT may lead to oxidative damage. Such oxidative damage may be induced in vivo by GSH in proximity to GGT-rich preneoplastic foci in rat liver.

Conditions for detecting the mutagenicity of divalent metals in Salmonella typhimurium.

The mutagenesis of metals in bacteria, as reported in the literature, can best be described as inconsistent. We report that cobalt chloride (Co++), ferrous sulfate (Fe++), manganese sulfate (Mn++), cadmium chloride (Cd++), and zinc chloride (Zn++) could be reproducibly detected as mutagens in Salmonella strain TA97 when preincubation exposures were made in sterile, distilled, deionized water, or in Hepes buffer in NaCl2/KCl2, rather than the standard sodium phosphate buffer. Co++ was also mutagenic under standard preincubation conditions. The individual components of Vogel-Bonner medium, i.e., potassium and ammonium phosphate, citrate, and magnesium sulfate, inhibit mutagenesis by these metals. The phosphates and the citrate probably inhibit by chelating the metals, while data are presented to suggest that Mg++ inhibition of metal mutagenesis is due to competitive inhibition for active transport via the magnesium active transport system in Salmonella. The chelator, diethyldithiocarbamate, inhibited the mutagenicity of Co++, Fe++, Zn++, and Mn++, but enhanced the mutagenicity of Cd++. The results presented show that divalent metals can be detected as mutagens in Salmonella, and that their lack of detection as mutagens is not due to an inherent insensitivity of Salmonella but to their interaction with media components and/or passive and active transport processes.

Autoxidation and mutagenicity of sodium bisulfite.

An inverse correlation exists between the autoxidation of bisulfite and its mutagenicity in Salmonella. Temperature, pH, and the addition of mannitol, ethanol, or Oxoid broth affect both autoxidation and mutagenicity. A decrease in autoxidation resulted in an increase in the half-life of the parent compound, bisulfite, and its availability for uptake by the cells, leading to increased mutagenesis. The autoxidation of bisulfite is known to produce both sulfur- and oxygen-centered free radicals. The lack of mutagenicity of ammonium persulfate and peroxymonosulfate, which generate the radicals SO4- and SO5-, respectively, argues against the involvement of these oxygen-centered radicals in bisulfite mutagenesis. Inhibition of mutagenesis by the radical spin-trapping agent, DMPO, is consistent with the hypothesis that the sulfur-centered radical, SO3-, plays an important role in bisulfite mutagenesis. The mechanism of bisulfite mutagenesis suggested in this study may have relevance to other known effects attributed to bisulfite, i.e., co-carcinogenesis and immune hypersensitivity.

Prostaglandin hydroperoxidase-dependent activation of heterocyclic aromatic amines.

Heterocyclic aromatic amines, derived from the pyrolysis of amino acids and proteins, are potent mutagens in the Ames Salmonella assay with rodent liver activation. Additionally, heterocyclic aromatic amines are multipotent carcinogens. We report evidence that these compounds are substrates for the hydroperoxidase activity of prostaglandin H synthase, as measured by alterations in UV/visible spectra, and are bioactivated to macromolecule-reactive species by this enzyme. Indirect electron paramagnetic resonance studies indicate that this activation may occur via a one-electron mechanism. 2-Amino-3-methylimidazo[4,5f]quinoline (IQ), 2-amino-3,4-dimethylimidazo[4,5-f]quinoline (MeIQ), and 3-amino-1-methyl-5H-pyrido[4,3-b]indole (Trp-P-2) are direct-acting mutagens in TA98. The mutagenicity of IQ and MeIQ, but not Trp-P-2, were enhanced by activation with ram seminal vesicle microsomes (a rich source of prostaglandin H synthase). Subsequent experiments utilized the newly constructed tester strain TA1538/1,8-DNP6 (pYG 121), which has enhanced arylamine N-acetyltransferase activity. In this strain IQ, MeIQ and 2-amino-6-methyldipyrido-[1,2-a:3',2'-d]imidazole (Glu-P-1) were mutagenic with ram seminal vesicle microsome activation. 3-Amino-1,4-dimethyl-5H-pyrido[4,3-b]indole (Trp-P-1) was a weak direct-acting mutagen, and was not activated by the ram seminal vesicles (RSV) system. The responses of IQ and MeIQ were markedly enhanced in TA1538/1.8-DNP6 (pYG 121), relative to TA98. These data are consistent with the involvement of prostaglandin H synthase-catalyzed activation in heterocyclic aromatic amine-induced extrahepatic neoplasia.

Effect of pH on mutagenesis by thiols in Salmonella typhimurium TA102.

The mutagenicity of thiol (SH)-containing compounds was tested in Salmonella typhimurium TA102 in the liquid preincubation method. Cysteinyl-glycine (CG), cysteine ethyl ester (CEE), L- and D-penicillamine (PA), cysteine (Cys) and glutathione (GSH) were mutagenic to strain TA102 without metabolic activation. On a molar basis, CG was the most potent mutagen. The mutagenicity of the remaining compounds decreased in the order specified above. The mutagenic response of each thiol-containing compound was a function of the pKa of the thiol group and the pH of the preincubation mixture. This indicates that a thiolate anion, rather than a free thiol, is required for mutagenesis.

Mutagenicity of the human carcinogen treosulphan in Salmonella.

The human carcinogen treosulphan was mutagenic in Salmonella typhimurium TA100 and TA1535, as was dl-1,2:3,4-diepoxybutane (DEB), a proposed hydrolysis product of treosulphan. Another proposed hydrolysis product, methane- sulfonic acid, was not mutagenic in these strains. The pattern of the mutagenic responses at pH 6,7, and 8 to treosulphan and DEB suggests that DEB formation may be responsible for the mutagenicity of treosulphan.

Glutathione mutagenesis in Salmonella typhimurium is a gamma-glutamyltranspeptidase-enhanced process involving active oxygen species.

Reduced glutathione (GSH) is mutagenic in Salmonella in the presence of gamma-glutamyltranspeptidase (GGT), with the highest response obtained in strain TA102. Reduced cysteinylglycine, one of the products of GGT metabolism of GSH, is mutagenic in the absence of GGT. In strain TA102, GSH mutagenesis was dependent on molecular oxygen, enhanced by iron, inhibited by EDTA, desferrioxamine mesylate, mannitol, butylated hydroxyanisole, peroxidase and catalase, but not by superoxide dismutase. Binding of GSH or its GGT-dependent metabolites to DNA in vitro was not detected. This is consistent with a model of an indirect mechanism of mutagenesis, i.e. cleavage of GSH by GGT, followed by facile auto-oxidation of the resulting cysteinylglycine, with the production of free radicals which lead to the (pen)ultimate mutagen, H2O2.

Conditions affecting the mutagenicity of sodium bisulfite in Salmonella typhimurium.

Sodium bisulfite is a weak mutagen at pH 5 and 6 in S. typhimurium strains carrying the hisG46 and hisD6610 mutations, but is not mutagenic in strains with the hisC3076 or hisD3052 mutations. The bisulfite-induced base-pair substitution mutations were slightly enhanced by the presence of the plasmid, pKM101, but inhibited by the presence of the uvrB and rfa mutations. The hisO1242 mutation which causes constitutive expression of the histidine operon, produced a slight enhancement of frameshift (hisD6610), but not base-pair substitution (hisG46) mutations. Bisulfite-induced mutations appear to be the result of two different mechanisms which may be a function of the repair capacity of the strains. The data suggest that the deamination of cytosine may not be responsible for frameshift mutations, but may be responsible for base-pair substitution mutagenesis. Because the rate of bisulfite autooxidation appears to play a role in the mutagenic process, we are suggesting that the deamination of cytosine may be the result of oxidative damage rather than through the direct formation of a cytosine-bisulfite adduct. This is further supported by the much lower concentrations of bisulfite needed to cause mutagenicity than the 1 M concentrations cited to produce cytosine-bisulfite adducts.

Glutathione mutagenesis in Salmonella typhimurium TA100: dependence on a single enzyme, gamma-glutamyltranspeptidase.

Glutathione was mutagenic in Salmonella typhimurium strain TA100 in the presence of purified mammalian gamma-glutamyltranspeptidase. Glutathione disulfide, gamma-glutamyl glutamic acid, and S-methyl-glutathione were not mutagenic under the same conditions. Glutathione-mediated, gamma-glutamyltranspeptidase-dependent mutagenesis of TA100 cells was inhibited by serine-borate complex, a known gamma-glutamyltranspeptidase inhibitor, and potentiated by glycylglycine, a known gamma-glutamyltranspeptidase enhancer. It is concluded that this enzyme is necessary and sufficient to activate glutathione to a mutagen.

The stability of mutagenic chemicals stored in solution.

Using the Salmonella/microsome assay, we have evaluated the stability of mutagenic responses of chemicals stored frozen over a period of 18 months. Each of the standard mutagens was prepared in January 1982, and aliquots were stored at -20 degrees C and at -80 degrees C. Sodium azide (NaN3) was dissolved in water; 4-nitro-o-phenylenediamine (4NOP), 4-nitroquinoline-N-oxide (4NQO), benzo(a)pyrene (B[a]P), and 2-aminoanthracene (2AA) were dissolved in DMSO, all at 100 micrograms/ml. At various times, aliquots were removed, thawed, and tested in parallel with freshly prepared mutagen samples using strain TA100 in a standard plate test and freshly prepared Aroclor 1254-induced rat liver S-9 mix where needed. 4NOP (2-10 micrograms/plate), 4NQO (0.01-0.10 micrograms/plate), B(a)P (0.5-2.5 micrograms/plate), and 2AA (0.25-2.0 micrograms/plate) showed no significant differences between the freshly prepared solutions and the solutions stored at -20 degrees C and -80 degrees C. NaN3 (0.1-0.8 micrograms/plate) did show a statistically significant difference, with the fresh samples giving the lowest mean responses (over all doses) and the -80 degrees C treatment giving the highest. The freezing of mutagen solutions is adaptable to routine use and provides the advantage of reducing the time required to prepare positive control chemicals and reducing the exposure of laboratory personnel to known mutagens.

Suppressive effects of chemicals in mixture on the Salmonella plate test response in the absence of apparent toxicity.

There are chemicals that affect the number of his+ revertant colonies of Salmonella in the plate test at doses that are apparently nontoxic, but may be causing nonlethal, toxic effects. When mixed with mutagens, these chemicals reduce the numbers of his+ revertant colonies on the plate with no accompanying visible toxic effect on the background lawn. Some of these plates are indistinguishable from spontaneous control plates, leading to the possibility that the mutagens under test would be evaluated as nonmutagenic, or that the mutagenic response would be underestimated. The reduction in mutagen-induced revertant colonies in most cases is equivalent to the reduction in spontaneous revertants in the absence of mutagen. A spot test that permits a rapid screen of chemicals for inhibitory effects has been developed; a plate incorporation assay is used to confirm the effect. Toxic effects can be seen in the background lawns of plates examined at magnifications of 100X or greater.

Structure-activity studies on the mutagenicity of tris(2,3-dibromopropyl) phosphate (Tris-BP) and its metabolites in Salmonella.

A series of methylated metabolites of the flame retardant tris(2,3-dibromopropyl) phosphate (Tris-BP) were tested for mutagenicity in Salmonella, along with the parent chemical and other structurally related chemicals. The metabolites produced a gradient of mutagenic responses in TA1535 in the same dose range and up to the same magnitude as the Tris-BP response. None of the metabolites tested appeared to be the ultimate mutagen, since they all required S-9 for their mutagenic activity.

Mutagenicity of (R) and (S) styrene 7,8-oxide and the intermediary mercapturic acid metabolites formed from styrene 7,8-oxide.

We have tested the two enantiomers of styrene 7,8-oxide and various thioether metabolites of racemic styrene 7,8-oxide for their direct mutagenicity in Salmonella typhimurium TA100. The mutagenicity data suggests that the (R) enantiomer is more mutagenic than the (S) enantiomer, with the racemic mixture intermediate between the two. The thioether metabolites were not mutagenic. The difference in the mutagenicities of enantiomers probably resulted from a stereoselective process in the Salmonella tester strain. At the present time it is not clear whether the rate-limiting reaction is the interaction of the enantiomers with DNA or some other cellular component.

A rapid and simple scheme for confirmation of Salmonella tester strain phenotype.

A simple scheme has been developed for confirming the phenotype of the standard set of Salmonella typhimurium tester strains. This scheme employs a series of filter paper discs impregnated with diagnostic mutagens or bacterial toxins. Up to 6 diagnostic discs can be placed on a petri dish to test a single Salmonella strain. The Salmonellae are distinguished by their responses to ampicillin, crystal violet, nitrofuratoin, 9-aminoacridine, 4-nitro-o-phenylenediamine and sodium azide.