Release of nitric oxide together with carbon-centered radicals from N-nitrosamines by ultraviolet light irradiation

Solutions of N-nitrosamines, N-nitrosodimethylamine, N-nitrosodiethylamine, N-nitrosomorpholine and N-nitrosopyrrolidine in phosphate buffer (pH 7.4) were irradiated by ultraviolet (UV) light at room temperature. The N-nitrosamines were extensively degraded due to irradiation for 120 min in a time-dependent fashion as monitored by UV-absorption or high performance liquid chromatographic analysis. Carbon-centered radicals were generated from four N-nitrosamines during the short time irradiation of 10–60 s as monitored by electron spin resonance (ESR) technique using 5,5-dimethyl-1-pyrroline N-oxide and N-tert-butyl-α-phenylnitrone as spin traps. Nitric oxide (NO) was generated during the short time irradiation as monitored by ESR technique using cysteine-Fe(II) complex, N-methyl-d-glucamine dithiocarbamate and 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide. Significant amounts of nitrite (4–16%) from four N-nitrosamines and also a significant amount of nitrate (4%) was produced from N-nitrosodimethylamine during the irradiation time of 120 min. Released NO from the N-nitrosamines must be converted into nitrite through intermediary reactive nitrogen oxide species including nitrogen dioxide and dinitrogen trioxide in contact with dissolved oxygen.     

The mutagenicity of heterocyclic N-nitrosamines for Salmonella typhimurium

14 carcinogenic and noncarcinogenic heterocyclic N-nitrosamines were evaluated for mutagenicity to Salmonella typhimurium TA-1535, which responds to mutagens inducing base-pair substitutions. Both suspension and plate tests were used, with mouse and rat liver in vitro metabolic activation systems.All carcinogenic nitrosamines showed a positive response in at least one test system, as did the noncarcinogens. In general, the mutagenic responses obtained with mouse liver were equal to, or greater than, the responses obtained with rat liver in both the suspension and plate tests. Although it is difficult to make quantitative comparisons between plate and suspension tests, both systems appeared to be responsive to the same dose ranges for the individual nitrosamines.     

Inhibition of mutagenicity of N-nitrosamines by tobacco smoke and its constituents

Tobacco smoke is a complex chemical mixture including pyridine alkaloids and N-nitrosamines, with the concentration of the former several orders of magnitude higher than that of the N-nitrosamines. The major biologically important N-nitrosamines present in tobacco smoke are N-nitrosodimethylamine (NDMA), 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), and N-nitrosonornicotine (NNN). These nitrosamines require metabolic activation by cytochrome P-450s for the expression of mutagenicity. Although nicotine, the major pyridine alkaloid in tobacco, has been shown to inhibit the metabolic activation of NNK, its effect on the mutagenicity of NNK and other N-nitrosamines has not been reported. In the present study, the ability of three pyridine alkaloids (nicotine, cotinine, nornicotine) and aqueous cigarette smoke condensate extract (ACE) to inhibit the mutagenicity of tobacco-related N-nitrosamines was tested on Salmonella typhimurium strain TA1535 in the presence of a metabolic activation system (S9). All three of the pyridine alkaloids tested, as well as ACE, inhibited the mutagenicity of NDMA and NNK, but not NNN, in a concentration-dependent manner. The induction of SCEs in mammalian cells (CHO) by NNK in the presence of metabolic activation was also significantly reduced by nicotine and cotinine. None of the observed reductions in mutagenicity could be explained by cytotoxicity. These results demonstrate that tobacco smoke contains chemicals, pyridine alkaloids and other unidentified constituent(s), which inhibit the mutagenicity of N-nitrosamines.     

Factors for efficiency of the Salmonella/microsome mutagenicity assay.

Factors were studied which modify the enzymatic capacity of mouse liver microsomal mixed-function oxidase to convert vinylidene chloride (1.1-dichloroethylene) (VDC) into mutagens in the Salmonella/microsome mutagenicity test. A microsomal fraction incorporated in soft agar layer converted VDC into mutagens during 7 h at a constant rate; these were detected with S. typhimurium TA100. In absence of VDC the enzymatic activity declined gradually to nil after 14 h of incubation at 37 degrees C. The presence of EDTA greatly enhanced the microsome-mediated mutagenicity of VDC and led to prolonged enzymatic viability, but only when liver fractions from phenobarbitone (PB) pretreated mice were used. The efficiency of the plate incorporation assay for the detection of mutagens is discussed in comparison with assays in liquid suspension.     

Measurements of Mutagenic and Antimutagenic Activities of Bile Acids by Rec-assay

To study the carcinogenic activity of bile acids, we examined the mutagenic activity of bile acids by Rec-assay using B. subtilis H17 and M45 strains. Cholic, chenodeoxycholic, lithocholic, and glycolithocholic acids exerted much weaker mutagenicity than mitomicin C (MMC), and deoxycholic and glycodeoxycholic acids showed toxicity toward the bacteria. Most of the conjugated bile acids (glycocholic, taurocholic, and taurodexycholic acids) and their amino acid components (glycine and taurine) were neither toxic nor mutagenic. No bile acids enhanced the mutagenicity of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), but glycine enhanced both toxicity and mutagenicity of MNNG in a dose-dependent manner. On the other hand, taurine decreased the mutagenicity of MNNG, and most of the bile acids decreased the mutagenicity of MMC. Furthermore, taurocholic acids decreased toxicity and/or mutagenicity of other bile acids. These results suggested that the mutagenic and comutagenic activities of bile acids can be disregarded, but they are antimutagenic in some situations.     

Decomposition of N-nitrosamines, and concomitant release of nitric oxide by Fenton reagent under physiological conditions

N-Nitrosodimethylamine (NDMA) in phosphate buffer was rapidly decomposed by Fenton reagent composed of H₂O₂, and Fe(II) ion. Electron spin resonance (ESR) studies using 5,5-dimethyl-1-pyrroline N-oxide (DMPO) showed that characteristic four line 1:2:2:1 ESR signals due to the DMPO-OH adduct formed on treatment of DMPO with Fenton reagent disappeared in the presence of NDMA, and N-nitrosodiethylamine (NDEA), suggesting the interaction of the N-nitrosamines with Fenton reagent. Treatment of the N-nitrosamines with Fenton reagent generated nitric oxide (NO) as estimated by ESR technique using cysteine–Fe(II), and N-methyl- -glucaminedithiocarbamate (MGD)–Fe(II) complexes. Characteristic 3, and single line signals due to 2 cysteine–Fe(II)–NO, and 2 cysteine–Fe(II)–2 NO complexes, respectively, and three line signals due to MGD–Fe(II)–NO were observed. Considerable amount of NO were liberated as determined by NO₂⁻, the final oxidation product of NO formed by reaction with dissolved oxygen in the aqueous medium. Spontaneous release of a small amount of NO from the N-nitrosamines was observed only on incubation in neutral buffers. Above results indicate that the N-nitrosamines were decomposed accompanying concomitant release of NO on contact with reactive oxygen species.     

Aphidicolin allows a rapid and simple evaluation of DNA-repair synthesis in damaged human cells

The decrease in microbial mutagenicity of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and N-methyl-N-nitrosourea (MNU) was compared in an animal mediation with rats and in direct incubation with human as well as rat blood and blood components. The mutagenic activity was assayed by reverse mutation from streptomycin (SM) dependence to non-dependence in Escherichia coli, strain Sd-B (TC). The mutagenic response curves of both MNNG and MNU were approximately linear and parallel at non-cytotoxic concentrations. However, the mutagenic capabilities of MNNG were estimated to be 10-fold more potent than those of MNU. The mutagenic activity in blood and liver preparations from rats killed immediately after intravenous injection of MNNG, 50 mg/kg, was negative. Results with MNU, 100 mg/kg, were positive in both cases.For the detection of mutagenicity, blood was diluted 50 times for the final testing mixture (1 ml) to avoid bactericidal effects of the blood itself. When a larger amount of liver preparation was used in the tests, and diluted 8 times, mutagenic activity was still detected 15 min after injection of MNU, 80 mg/kg. Comparisons of the diminished rate of mutagenicity between MNNG and MNU during certain periods of incubation with blood indicated that MNNG was inactivated much more rapidly than MNU with both human and rat blood. Plasma showed a moderate inactivating effect on both MNNG and MNU. Red blood cells inactivated MNNG at a remarkably rapid rate similar to that of whole blood, but was less effective on MNU. In further experiments with red- cell components, the cell contents inactivated both MNNG and MNU at rates similar to those with red cells, but cell membrane had absolutely no effect in decreasing the mutagenicity in either MNNG or MNU.     

Quantitative comparison of carcinogenicity, mutagenicity and electrophilicity of 10 direct-acting alkylating agents and of the initial O: 7-alkylguanine ratio in DNA with carcinogenic potency in rodents

The quantitative relationship between carcinogenicity in rodents and mutagenicity in Salmonella typhimurium was examined, by using 10 monofunctional alkylating agents, including N-nitrosamides, alkyl methanesulfonates, epoxides, β-propiolactone and 1,3-propane sultone. The compounds were assayed for mutagenicity in two S. typhimurium strains (TA1535 and TA100) and in plate and liquid assays. The mutagenic activity of the agents was compared with their alkylating activity towards 4-(4′-nitrobenzyl)pyridine and with their half-lives (solvolysis constants) in an aqueous medium. No correlations between these variables were found, nor was mutagenic activity correlated with estimates of carcinogenicity in rodents.There was a positive relationship between carcinogenicity and the initial ratios of 7-: O⁶-alkylguanine formed or expected after their reaction with double-stranded DNA in vitro. The results suggest that alkylation of guanine at position O⁶ (or at other O atoms of DNA bases) may be a critical DNA-base modification that determines the overall carcinogenicity of these alkylating agents in rodents.     

Changes in mutagenicity during crude oil degradation by fungi

Two fungal strains, Cunninghamella elegans and Penicillium zonatum, that grow with crude oil as a sole carbon source were exposed to three crude oils that exhibit a range of mutagenic activity. At regular time intervals following fungal incubation with the various crude oils, extracts were tested for the presence of mutagenic activity using the spiral Salmonella assay. When the most mutagenic of the oils, Pennsylvania crude oil, was degraded by C. elegans or by P. zonatum, its mutagenicity was significantly reduced; corresponding uninoculated (weathered) controls of Pennsylvania crude remained mutagenic. West Texas Sour crude oil, a moderately mutagenic oil, exhibited little change in mutagenicity when incubated with either C. elegans or P. zonatum. Swanson River Field crude oil from Cook Inlet, Alaska is a slightly mutagenic oil that became more mutagenic when incubated with C. elegans; weathered controls of this oil showed little change in mutagenicity. Mycelial mat weights measured during growth on crude oils increased corresponding to the biodegradation of about 25% of the crude oil.     

Effect of glutathione and uridine 5'-diphosphoglucuronic acid on mutagenesis by benzo[a]pyrene and aflatoxin B1 in the Salmonella/microsome assay

In the Salmonella/microsome plate or liquid assay, the addition of glutathione (GSH) and uridine 5'-diphosphoglucuronic acid (UDPGA), both cofactors for GSH-S-transferases or UDPGA-transferases, altered the rat-liver microsome-mediated mutagenesis of benzo[a]pyrene (BP) and aflatoxin B1 (AFB). With either BP or AFB, an increased, unchanged or decreased number of revertant colonies of S. typhimurium was observed, depending on the substrate concentration, the source of rat-liver 9000 X g supernatant (S9), the time of incubation and the type of mutagenicity test (liquid or plate assay). Several factors responsible for quantitative changes in the pattern of BP and AFB metabolites under various assay conditions in vitro, which alter the overall mutagenic activity of the parent compound, are discussed.     

Testing of some azo dyes and their reduction products for mutagenicity using Salmonella typhimurium TA 1538

A series of ten azo dyes as well as various single ring aromatic amines substituted on the benzene ring were tested for bacterial mutagenicity with Salmonella typhimurium TA 1538 using a soft-agar overlay method. Two dyes, sudan 2 and chrysoidin induced mutation but only in the presence of a rat liver preparation. Chrysoidin was the more active. Testing of its reduction products, aniline and 1,2,4-triaminobenzene showed a liver metabolite of the latter compound could be responsible for the mutagenic effect, having a comparable mutagenicity with 1,2-diamino-4-nitro-benzene, one of the mutagenic constituents of hair dyes. Structure-activity studies on a series of ring-substituted anilines indicated that mutagenic activity required at least two positions to be substituted with either amino or nitro groups, or one of each. The bacteria as well as the liver enzyme preparation may partake in the activation of these chemicals. The correlation between mutagenicity and carcinogenicity for this group of compounds is discussed.     

Identification of methylglyoxal as a major mutagen in wood and bamboo pyroligneous acids

To identify the major mutagen in pyroligneous acid (PA), 10 wood and 10 bamboo pyroligneous acids were examined using the Ames test in Salmonella typhimurium strains TA100 and TA98. Subsequently, the mutagenic dicarbonyl compounds (DCs), glyoxal, methylglyoxal (MG), and diacetyl in PA were quantified using high-performance liquid chromatography, and the mutagenic contribution ratios for each DC were calculated relative to the mutagenicity of PA. Eighteen samples were positive for mutagens and showed the strongest mutagenicity in TA100 in the absence of S9 mix. MG had the highest mutagenic contribution ratio, and its presence was strongly correlated with the specific mutagenicity of PA. These data indicate that MG is the major mutagen in PA.     

Monitoring airborne genotoxicants in the rubber industry using genotoxicity tests and chemical analyses

This research was designed to examine the presence of mutagenic/carcinogenic compounds in airborne pollutants in the rubber industry using an integrated chemical/biological approach. Inhalable airborne particulate matter (PM-10: <10 μm) was collected in four rubber factories using a high-volume sampler equipped with a cascade impactor for particle fractionation. The organic extracts of two different fractions (0.5–10 μm and <0.5 μm) were examined for mutagenicity with the Ames test and for in vitro DNA-damaging activity in human leukocytes by single-cell microgel electrophoresis (Comet assay). The extracts were also studied by gas chromatography/mass spectrometry (GC/MS) for polycyclic aromatic hydrocarbon (PAH) content. Nitrosamines in ambient air were sampled on cartridges and analysed by GC with a thermal energy analyser (TEA) detector. Airborne volatile genotoxins were monitored in situ using a clastogenicity plant test (Tradescantia/micronuclei test). The results showed that airborne particulates were mainly very fine (<0.5 μm) and that trace amounts of genotoxic nitrosamines (N-nitrosodimethylamine: 0.10–0.98 μg/m³; N-nitrosomorpholine: 0.77–2.40 μg/m³) and PAH (total PAH: 0.34–11.35 μg/m³) were present in air samples. Some extracts, particularly those obtained from the finest fractions, were mutagenic with the Ames test and genotoxic with the Comet assay. In situ monitoring of volatile mutagens using the Tradescantia/micronuclei test gave positive results in two working environments. The results showed the applicability of this integrated chemical–biological approach for detecting volatile and non-volatile genotoxins and for monitoring genotoxic hazards in the rubber industry.     

Acrylamide and glycidamide: genotoxic effects in V79-cells and human blood

Acrylamide (AA) can be formed in certain foods by heating, predominantly from the precursor asparagine. It is a carcinogen in animal experiments, but the relevance of dietary exposure for humans is still under debate. There is substantial evidence that glycidamide (GA), metabolically formed from AA by Cyp 2E1-mediated epoxidation, acts as ultimate mutagenic agent. We compared the mutagenic potential of AA and GA in V79-cells, using the hprt mutagenicity-test with N-methyl-N′-nitro-N-nitroso-guanidine (MNNG) as positive control. Whereas MNNG showed marked mutagenic effectivity already at 0.5 μM, AA was inactive up to a concentration of 10 mM. In contrast, GA showed a concentration dependent induction of mutations at concentrations of 800 μM and higher. Human blood was used as model system to investigate genotoxic potential in lymphocytes by single cell gel electrophoresis (comet assay) and by measuring the induction of micronuclei (MN) with bleomycin (BL) as positive control. AA did not induce significant genotoxicity or mutagenicity up to 6000 μM. With GA, concentration dependent DNA damage was observed in the dose range of 300–3000 μM after 4 h incubation. Significant MN-induction was not observed with AA (up to 5000 μM) and GA (up to 1000 μM), whereas BL (4 μM) induced significantly enhanced MN frequencies. Thus, in our systems GA appears to exert a rather moderate genotoxic activity.     

Copper, zinc-superoxide dismutase enhances the mutagenicity in Salmonella typhimurium induced by 2-amino-6-methyldipyrido[1,2-a:3',2'-d]imidazole

The mutagenicities of various carcinogens induced by liver microsomes are increased in the presence of liver cytosol in rodents. It still remains, however, to be clarified which factor or factors in the cytosol enhance(s) the microsome-mediated mutagenicities. In the present study, we sought to identify the enhancing factor in liver cytosol prepared from rats using the microsome-mediated Salmonella mutagenicity induced by 2-amino-6-methyldipyrido [1,2-a:3',2'-d] imidazole (Glu-P-1). By a series of chromatographic steps, we purified a 16-kDa protein on SDS-PAGE from the cytosol of rat livers. Partial amino acid sequences of this protein revealed that the 16-kDa protein was copper, zinc-superoxide dismutase (CuZn-SOD). The purified CuZn-SOD enhanced the microsome-mediated mutagenicities of several heterocyclic amines and aromatic amines. Furthermore, bovine and human CuZn-SOD also enhanced the microsome-mediated mutagenicity of Glu-P-1. The CuZn-SOD caused an increase in the mutagenicity of N-hydroxylated Glu-P-1 formed from Glu-P-1 by the microsomes, although CuZn-SOD did not affect either the formation or the stability of the N-hydroxylated derivative. These findings suggest that the enhancing cytosol factor for the mutagenicity of Glu-P-1 is CuZn-SOD, which stimulates the mutagenicity of N-hydroxylated Glu-P-1 without changing its metabolism.     

Microsome- and hepatocyte-mediated mutagenicity of hydroxyurea and related aliphatic hydroxamic acids in V79 Chinese hamster cells

The potential of N-hydroxyurea to induce gene mutations in V79 Chinese hamster cells was investigated. Upon metabolic activation by liver microsomes from phenobarbital-treated rats or by isolated rat hepatocytes co-cultured with the V79 cells, hydroxyurea caused a concentration-dependent increase in the frequency of HGPRT-deficient mutants. Hydroxyurea was not mutagenic in the absence of metabolic activation. Addition of catalase inhibited microsome-mediated mutagenicity, indicating that hydrogen peroxide was involved in the formation of the mutagenic DNA lesion. Acetohydroxamic acid and N-hydroxyurethane also induced hepatocyte-mediated mutagenicity, suggesting that the potential to elicit metabolism-dependent mutagenicity may be a common property of aliphatic hydroxamic acids.     

Urethane and N-nitrosodiethylamine are mutagenic for the Syrian hamster fetus

Urethane and N-nitrosodiethylamine are soluble environmental carcinogens that initiate tumors transplacentally, but have a mixed history of effectiveness in mutagenesis assays in vitro or in vivo with adult rodents. To test for their transplacental mutagenicity, Syrian hamster fetuses at 12 days in gestation were exposed transplacentally to urethane or N-nitrosodiethylamine at 0.5 or 1.0 mM/kg. The fetal cells were isolated on day 13 of gestation and tested for diphtheria toxin resistance as a mutation marker. Both compounds were significantly mutagenic, at both doses, causing 6- to 20-fold increases in mutations compared with controls. Compared with N-nitrosodiethylamine, urethane was somewhat more effective as a mutagen with a more marked dose–response. These results are consistent with mutagenesis as part of the mechanism of transplacental carcinogenicity of urethane and N-nitrosodiethylamine.     

Evaluation of the antimutagenic potential of chitosan oligosaccharide: Rec, Ames and Umu tests

Two types of chitosan oligosaccharides (COS), COS I (1-kDa < MW < 3-kDa) and COS II (3-kDa < MW < 5-kDa), were tested for antimutagenic activities against chemical mutagens using Umu gene expression, Ames, and Bacillus subtilis Rec mutagenicity tests. At the highest chitosan oligosaccharide dose (1 mg) tested, mutagenic activity of indirect-acting mutagen was inhibited by 50% in the Umu gene expression system and in the Ames test. Chitosan oligosaccharide (0.01, 0.1 and 1 mg) also suppressed 4-nitroquinoline-N-oxide (NQO)-induced mutagenicity in the B. subtilis Rec^– assay.     

Mechanism of comutagenesis of sodium arsenite withn-methyl-n-nitrosourea

Arsenic compounds are known carcinogens. Although many carcinogens are also mutagens, we have previously shown that sodium arsenite is not mutagenic at either the Na⁺/K⁺ ATPase orhprt locus in Chinese hamster V79 cells. It can, however, enhance UV-mutagenesis. We now confirm the nonmutagenicity of sodium arsenite in line G12, a pSV2gpt-transformed V79 (hprt ⁻) cell line, which is able to detect multilocus deletions in addition to point mutations and small deletions. The lack of arsenic mutagenicity has led to studies emphasizing its comutagenicity. Sodium arsenite at relatively nontoxic concentrations (5 μM for 24 h or 10 μM for 3 h) is comutagenic withN-methyl-N-nitrosourea (MMU) at thehprt locus in V79 cells. Using a nick translation assay, which measures DNA strand breaks by incorporating radioactive deoxyribonucleoside monophosphate at their 3′OH ends in permeabilized cells, we found that much more incorporation was seen in cells treated with MNU (4 mM, 15 min) followed by 3-h incubation with 10 μM sodium arsenite compared with cells exposed to the same MNU treatment followed by 3-h incubation without sodium arsenite. This result shows that in the presence of arsenite, strand breaks resulting from MNU or its repair accumulate over a 3-h period. We suggest that the repair of MNU-induced DNA lesions may be inhibited by arsenite either by affecting the incorporation of dNMPs into the MNU-damaged DNA template or by interfering with the ligation step.