Bio-antimutagenic effects of tannic acid on UV and chemically induced mutagenesis in Escherichia coli B/r

Tannic acid suppressed the mutagenesis in E. coli B/r WP2 trp- induced by UV or 4-nitroquinoline 1-oxide (4NQO), but not that induced by gamma-rays or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). The depression of mutations induced by UV was most remarkable in the DNA-repair-proficient strain (WP2). Tannic acid, however, showed no bio-antimutagenic effect in the excision repair-deficient strain (WP2s uvrA- or ZA159 uvrB-) under the test conditions where no cellular toxicity was observed. The effect ceased within 30 min after UV irradiation. The inhibition of the expression of Trp+ phenotype and the delay of the first cell division after UV irradiation were not observed in the presence of tannic acid. From these results we conclude that tannic acid may enhance the excision-repair system probably by activating the repair enzymes or by interacting with DNA.     

Sodium arsenite inhibits spontaneous and induced mutations in Escherichia coli

Sodium arsenite at a non-toxic concentration was found to inhibit strongly mutagenesis induced by ultraviolet light (UV), 4-nitroquinoline-1-oxide (4NQO), furylfuramide (AF-2) and methyl methane-sulfonate (MMS) as well as spontaneous mutation in the reversion assay of E. coli WP2uvrA/pKM101. The effect was not, however, seen in the case of the mutagenesis induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). In order to elucidate the mechanism of the mutation-inhibitory effect of sodium arsenite, its action on umuC gene expression and DNA-repair systems was investigated. It was found that sodium arsenite depressed beta-galactosidase induction, corresponding to the umuC gene expression. For UV-irradiated E. coli strains possessing different DNA-repair capacities, sodium arsenite decreased the UV survival rates of WP2, WP2uvrA[uvrA] and WP67[uvrA polA], increased those of SOS-uninducible strains having either the recA+ or uvrA+ such as CM571 [recA], CM561 [lexA(Ind-)] and CM611[uvrA lexA (Ind-)], and did not affect that of the uvrA recA double mutant, WP100. From these results, we assume that sodium arsenite may have at least two roles in its antimutagenesis: as an inhibitor of umuC gene expression, and as an enhancer of the error-free repairs depending on the uvrA and recA genes.     

Evaluation of drug candidates in a battery of short-term genetic toxicology assays: overview

2-Hydroxy-3-methoxybenzaldehyde (omicron-vanillin), the antimutagenic effect of which has been reported on mutagenesis induced by 4-nitroquinoline 1-oxide (4NQO) in Escherichia coli WP2s, enhanced N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced mutagenesis in the same strain. A remarkable enhancement of mutagenesis provoked by N-methyl-N-nitrosourea (MNU) was also observed by the addition of omicron-vanillin. No enhancing effect was observed on mutagenesis induced by other mutagens such as methyl methanesulfonate (MMS), dimethylsulfate, N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG), N-ethyl-N-nitrosourea (ENU), ethyl methanesulfonate, diethylsulfate, 4NQO and furylfuramide (AF-2). On the contrary, omicron-vanillin greatly suppressed AF-2- and 4NQO-induced mutagenesis and showed a slight suppressing effect against mutagenesis induced by MMS, ENNG and ENU. One possible explanation for the enhancing effect of omicron-vanillin on the mutagenesis induced by MNNG or MNU in E. coli WP2s may be inhibition of an inducible adaptive response. Among 7 derivatives of omicron-vanillin, 2-hydroxy-3-ethoxy-benzaldehyde, omicron-hydroxybenzaldehyde and m-methoxybenzaldehyde showed an enhancing effect on MNNG-induced mutagenesis.     

Comparative analysis of deletion and base-change mutabilities of Escherichia coli B strains differing in DNA repair capacity (wild-type, uvrA-, polA-, recA-) by various mutagens.

Dose-response curves were compared for deletions [ColBR (resistant to colicin B) mutations being more than 80% deletions] and base changes (reversion of argFam to prototrophy argplus) induced in the same set of E. coli strains (wild-type for DNA repair, uvrA-, polA- and recA-) by N-methyl-N'-nitro-N-nitrosoguanidine (NTG), ethyl methanesulfonate (EMS), hydroxylamine (HA), 4-nitroquinoline I-oxide (4NQO), mitomycin C (MTC, UV and X-rays. All these agents induced deletions as well as base changes in the wild-type strain. Thus chemical mutagenesis differed in E. coli and bacteriophages in vitro, for HA, NTG, EMS and perhaps UV produced only point mutations in phage Tr. The patterns of deletion and base-change mutability in E. coli were surprisingly similar. (I) The recombination less recA- strain was mutable by only three (NTG, EMS, HA) of the seven mutagens for either deletions or base changes. (2) The uvrA- strain, unable to excise pyrimidine dimers, was very highly mutable by 4NQO and UV but immutable by MTC for both deletions and base changes. (3) The polA- strain, defective in DNA polymerase I due to a non-suppressible mutation, was very highly mutable by HA and highly mutable by MTC and 4NQO for both deletions and base changes but was highly mutable only for deletions by UV and X-rays, remaining normally mutable by the other agents for both deletions and base changes despite its high sensitivity to their inactivating action. We conclude that errors in the recA-dependent repair of induced DNA damage (after 4NQO, MTC, UV and X-rays) or errors in replication enhanced by damage to the replication system or to the template strands (after NTG, EMS, and HA) give rise to deletions as well as to base changes. From a comparative analysis of 14 dose-response curves for deletions and base changes, we conclude that the order of mutagenic efficiency relative to killing is (EMS, NTG) greater than (UV, 4NQO) greater than HA greater than (X-rays, MTC), and that X-rays, 4NQO, HA and MTC induce more ColBR deletions than Argplus base changes, whereas UV and EMS induce ColBR deletions and Argplus base changes at nearly equal rates and the specificity of NTG is intermediate between these two types.     

A comprehensive exercise in comparative mutagenesis with exciting outcome or how good are mutation assays in predicting carcinogens?

Cultivation of E. coli B/r strain WP2 in low concentrations of either 4-nitroquinoline N-oxide (4NQO) or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) had no effect on the mutagenic or cytotoxic consequences of subsequent challenge with dichlorvos (DCV). However, although the sensitivity of E. coli cells taken from cultures grown in low concentrations of DCV to the effects of 4NQO was unchanged, the cells were more resistant to the mutagenic (but not cytotoxic) consequences of MNNG challenge. This phenomenon was not observed in WP2 derivatives deficient in either error-free (uvrA-) or error-prone (lexA-) DNA-repair, suggesting that a factor common to both these repair pathways may be involved.     

Rat liver S9 preparations contain comutagenic activity

Rat liver S9 preparations contain material which causes enhancement of UV mutagenesis in Escherichia coli WP2. This comutagenic activity is present in S9 preparations from both uninduced and Aroclor-induced rats. Strains of E. coli which are defective in the uvr-dependent excision repair pathway fail to show comutagenic action by S9. The comutagenic material is heat-labile and non-dialyzable, suggesting that it might be protein. This differs from the small amount of mutagenic material present in rat liver S9, as the latter is dialyzable and can be demonstrated in the repair-deficient strain E. coli WP2s (uvrA).     

The pyrogallol related compounds reduce UV-induced mutations in Escherichia coli B/r WP2

Plant components with bio-antimutagenic activity were screened on UVC (254 nm)-induced mutagenesis using E. coli B/r WP2. The components with a pyrogallol moiety including gallic acid, (-)-epicatechin gallate (ECG), (-)-epigallocatechin (EGC) and (-)-epigallocatechin gallate (EGCG) reduced the mutation induction, but other components such as caffeic acid, chlorogenic acid and quercetin did not. The above compounds with a pyrogallol moiety were also effective on UVAB (295-400 nm)-induced mutagenesis, while they showed little effect on N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced mutagenesis. As this bio-antimutagenic effect was not seen in the DNA excision-repair-deficient strains WP2s and ZA159, the activity by the above plant components might be based on the promotion of the excision-repair system in E. coli B/r WP2.     

Comparative mutagenesis and interaction between near-ultraviolet (313- to 405-nm) and far-ultraviolet (254-nm) radiation in Escherichia coli strains with differing repair capabilities.

Comparative mutagenesis and possible synergistic interaction between broad-spectrum (313- to 405-nm) near-ultraviolet (black light bulb [BLB]) radiation and 254-nm radiation were studied in Escherichia coli strains WP2 (wild type), WP2s (uvrA), WP10 (recA), WP6 (polA), WP6s (polA uvrA), WP100 (uvrA recA), and WP5 (lexA). With BLB radiation, strains WP2s and WP6s demonstrated a high level of mutagenesis, whereas strains WP2, WP5, WP6, WP10, and WP100 did not demonstrate significant mutagenesis. In contrast, 254-nm radiation was mutagenic in strains WP2, WP2s, WP6, and WP6s, but strains WP5, WP10, and WP100 were not significantly mutated. The absence of mutagenesis by BLB radiation in lexA and recA strains WP10, WP5, and WP100 suggests that lex+ rec+ repair may play a major role in mutagenesis by both BLB and 254-nm radiation. The hypothesis that BLB radiation selectively inhibits rec+ lex+ repair was tested by sequential BLB-254-nm radiation. With strain WP2, a fluence of 30 J/m2 at 254 nm induced trp+ revertants at a frequency of 15 X 10(-6). However, when 10(5) J/m2 or more of BLB radiation preceded the 254-nm exposure, no trp+ revertants could be detected. A similar inhibition of 254-nm mutagenesis was observed with strain WP6 (polA). However, strains WP2s (uvrA) and wP6s (polA uvrA) showed enhanced 254-nm mutagenesis when a prior exposure to BLB radiation was given.     

Mutagenic and error-free DNA repair in Streptomyces

Summary Two mutants of Streptomyces fradiae defective in DNA repair have been characterized for their responses to the mutagenic and lethal effects of several chemical mutagens and ultraviolet (UV) light. S. fradiae JS2 (mcr-2) was more sensitive than wild type to agents which produce bulky lesions resulting in large distortions of the double helix [i.e. UV-light, 4-nitroquinoline-1-oxide (NQO), and mitomycin C (MC)] but not to agents which produce small lesions [i.e. hydroxylamine (HA), methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS) and N-methyl-N-nitro-N-nitrosoguanidine (MNNG)]. JS2 expressed a much higher frequency of mutagenesis induced by UV-light at low doses and thus appeared to be defective in an error-free excision repair pathway for bulky lesions analogous to the uvr ABC pathway of Escherichia coli. S. fradiae JS4 (mcr-4) was defective in repair of damage by most agents which produce small or bulky lesions (i.e., HA, NQO, MMS, MNNG, MC, and UV, but not EMS). JS4 was slightly hypermutable by EMS and MMS but showed reduced mutagenesis by NQO and HA. This unusual phenotype suggests that the mcr-4 ⁺ protein plays some role in error-prone repair in S. fradiae.     

Development of a new E. coli strain to detect oxidative mutation and its application to the fungicide o-phenylphenol and its metabolites

Oxidative mutation is mainly induced by reactive oxygen species (ROS), such as the superoxide anion radical (O(2)(-)) and hydrogen peroxide (H(2)O(2)). However, in Escherichia coli (E. coli), ROS are eliminated by enzymes such as superoxide dismutase and catalase, which are coded by sodAB and katEG genes. In this study, to detect mutagens that induce oxidative mutation, a mutant (WP2katEGsodAB) with katEG and sodAB deleted was constructed by gene manipulation of E. coli WP2. H(2)O(2) and menadione sodium bisulfite generated mutation in WP2katEGsodAB but not in WP2. o-Phenylphenol (OPP) and its metabolites (phenylhydroquinone (PHQ) and phenyl-1,4-benzoquinone (PBQ)), which had been shown to be negative in the Ames test but reported to be carcinogenic, induced mutation in WP2katEGsodAB but not in WP2. These results suggest that the new assay may be useful for the detection of oxidative mutagens.     

Inhibitory effect of cadmium and mercury ions on induction of the adaptive response in Escherichia coli

Cadmium and mercury ions inhibited the promotion of ada and alkA gene expression in the adaptive process induced by methylating agents such as N-methyl-N-nitrosourea (MNU), methyl methanesulfonate (MMS) and methyl iodide in Escherichia coli. In fact, the induction of O6-methylguanine-DNA methyl-transferase (MGTase) by MNU was suppressed in E. coli in the presence of these metal ions. These ions potentiated mutagenesis induced by methylating agents such as MNU and MMS, but not that induced by ethylating agents, UV irradiation, or N4-aminocytidine. These comutagenic effects were observed in wild-type and umuC36 strains of E. coli but not in the ada-5 strain, which is unable to induce the adaptive response. These results suggest that the comutagenic effects of Cd2+ and Hg2+ are due to inhibition of ada and alkA gene expression promoted by methylated MGTase.     

The amyloid peptide induces early genotoxic damage in human preneuron NT2

The antimutagenic activities of benzalacetone (4-phenyl-3-buten-2-one) and its structurally-related compounds were evaluated through their use as post-treatments for the UV-induced mutagenesis in Escherichia coli WP2s (uvrA) and the gamma-induced mutagenesis in Salmonella typhimurium TA2638, the latter of which is sensitive to oxidants. Structure-activity relationships were studied between IC(50) activity values, i.e. the dose (micromol/ml) at which the mutation frequency is reduced to 50% of the control, and electronic and hydrophobicity properties of the studied molecules. Benzalacetone and benzalacetone analogs, cinnamaldehyde and trans-1,1,1-trifluoro-4-phenyl-3-buten-2-one (TF), inhibited both forms of mutagenesis, but methyl cinnamate, cinnamic acid and cinnamamide did not. The IC(50) values of TF, for UV-induced mutagenesis and gamma-induced mutagenesis, were 0.028 and 0.045 micromol/ml, respectively, and one order of magnitude lower than those of cinnamaldehyde and benzalacetone. The three antimutagenic analogs listed in order of decreasing activity are: TF>cinnamaldehyde>benzalacetone. This order is proportional to the electron-withdrawing property of the terminal group attached to an alpha,beta-unsaturated carbonyl moiety in the side chain that is known to play an important role in the antimutagenicities of benzalacetone and related compounds. In UV-induced mutagenesis in E. coli WP2s, mono-substituted benzalacetones - the ring-substituents of which have electron-withdrawing properties - showed antimutagenic activity that correlated with their electronic property. In gamma-induced mutagenesis in S. typhimurium TA2638, the antimutagenic activities of mono-substituted benzalacetones were proportional to the substituent hydrophobicities (pi). The different effects on both the mutation-induced systems is suggested to be related to the relative permeability of the cell membranes and the different sensitivities to mutagens between E. coli WP2s and S. typhimurium TA2638. In addition, the antimutagenic activity against gamma-induced mutagenesis could be due to the ability of parent compounds or their derivatives to scavenge long-lived organic radicals; the radicals have been described to be generated as a result of the X-irradiation of cells by Koyama et al. [Mutat. Res. 421 (1998) 45].     

Ethidium bromide and SYBR Green I enhance the genotoxicity of UV-irradiation and chemical mutagens in E. coli

Ethidium bromide (EtBr) and SYBR Green I are nucleic acid gel stains and used commonly in combination with UV-illumination. EtBr preferentially induces frameshift mutations but only in the presence of an exogenous metabolic activation system, while SYBR Green I is a very weak mutagen that induces frameshift mutations. We found that EtBr and SYBR Green I, without an added metabolic activation system, strongly potentiated the base-substitution mutations induced by UV-irradiation in E. coli B/r WP2 cells. Each DNA stain alone showed no mutagenicity to the strain. Base-substitutions induced by 3-chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone (MX) and 4-nitroquinoline-1-oxide were similarly potentiated by EtBr and SYBR Green I. SYBR Green I had a much greater effect. No enhancing effects were observed on mutations induced by mitomycin C, cisplatin, transplatin, cumene hydroperoxide, base analogs, and alkylating agents. Another DNA stain, acridine orange, showed similar enhancing effects on UV- and MX-mutagenicity, but no effect was observed for 4',6-diamidino-2-phenylindole (DAPI). UV- and MX-induced mutations in E. coli WP2s (uvrA), which is defective in nucleotide excision repair activity, were not potentiated by the addition of EtBr, SYBR Green I, or acridine orange. Those nucleic acid stains might inhibit the nucleotide excision repair of DNA damaged by UV and MX treatment.     

Comparative study of the antimutagenic potential of Vitamin E in different E. coli strains

The antimutagenic potential of Vitamin E due to its antioxidative properties was studied. The new Escherichia coli K12 assay-system designed in our laboratory was employed in order to detect the antimutagenic potential of Vitamin E and to determine its molecular mechanisms of action. The assay is composed of three tests. In Test A, we examine the influence of the antioxidant on induced oxidative mutagenesis in a repair-proficient strain. Spontaneous mutagenesis is monitored in Test B, which is performed with two mutator strains, one mismatch repair-deficient (mutS) and another deficient in 8-oxo-dGTP-ase activity (mutT). In Test M, a repair-proficient strain and its mismatch repair-deficient counterpart (mutH), both carrying a plasmid with microsatellite sequences, are used to measure the level of microsatellite instability. To examine the antimutagenic potential of Vitamin E we also used the WP2 antimutagenicity test. Protective properties of Vitamin E against oxidative mutagenesis were detected in all tests with the E. coli K12 assay-system as well as in the WP2 antimutagenicity test. This study confirms that mismatch repair is essential for repair of oxidative DNA damage. The results obtained indicate that Vitamin E prevents the formation of DNA adducts by lipid peroxidation products rather than those formed by direct oxidation of DNA bases. Moreover, it can reduce microsatellite instability. After further validation, the new E. coli K12 assay-system can be used to test the antimutagenic potential of antioxidants.     

Inducible stable DNA replication in Escherichia coli uvr+ and uvr- cells, treated with genotoxic chemicals.

Inducible stable DNA replication (iSDR) provoked by a damaging treatment with MMS, MNU, MNNG, NFAA, NFN, 4NQO, NAL or MMC, was followed in both repair-competent E. coli PQ35 and its uvrA derivative E. coli PQ37. In contrast to SOS-inducible mutagenesis, which is more pronounced in excision-deficient cells, iSDR was more obvious in repair-competent cells. This may be due to special features of iSDR and need not indicate involvement of the uvrA gene product in it.     

Antimutagenic effects of cinnamaldehyde on chemical mutagenesis in Escherichia coli

Antimutagenic effects of cinnamaldehyde on mutagenesis by chemical agents were investigated in Escherichia coli WP2 uvrA- trpE-. Cinnamaldehyde, when added to agar medium, greatly reduced the number of Trp+ revertants induced by 4-nitroquinoline 1-oxide (4-NQO) without any decrease of cell viability. This antimutagenic effect could not be explained by inactivation of 4-NQO caused by direct interaction with cinnamaldehyde. Mutagenesis by furylfuramide (AF-2) was also suppressed significantly. Mutations induced by methyl methanesulfonate (MMS) and ethyl methanesulfonate (EMS) were slightly inhibited. However, cinnamaldehyde was not at all effective on the mutagenesis of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). Two derivatives of cinnamaldehyde, cinnamyl alcohol and trans-cinnamic acid, did not have as strong antimutagenic effects on 4-NQO mutagenesis as cinnamaldehyde had. Because cinnamaldehyde showed marked antimutagenic effects against mutations induced by UV-mimic mutagens but not those induced by MNNG or EMS, it seems that cinnamaldehyde might act by interfering with an inducible error-prone DNA repair pathway.     

Methyl cinnamate derivatives enhance UV-induced mutagenesis due to the inhibition of DNA excision repair in Escherichia coli B/r

UV-induced mutagenesis in Escherichia coli B/r WP2 was enhanced by certain derivatives of methyl cinnamate which themselves were not mutagenic. Methyl ferulate, methyl isoferulate and methyl sinapate showed this effect markedly. Such an enhancement effect was absent with the derivatives of cinnamic acid and ethyl cinnamate and was not observed in Escherichia coli WP2s uvrA. Methyl sinapate also enhanced 4NQO-induced mutation and suppressed liquid-holding recovery in the above repair-proficient strain. The presence of methyl sinapate in plating agar medium decreased the survival of UV-irradiated cells of a recombination-repair-deficient strain, CM571 recA. However, the effect was not observed with those of WP2s uvrA. In an in vitro experiment in which the removal rate of thymine dimers was measured, methyl sinapate clearly inhibited this repair event. From these results, we conclude that methyl sinapate inhibits DNA excision repair, thus enhancing UV mutagenicity.     

Heat shock inhibits the induced expression of the SOS genes and SoxRS regulons in Escherichia coli

Oxidative stress formed in Escherichia coli cells is known to bring about a complex induction of alternative DNA repair processes, including SOS, SoxRS, and heat-shock response (HSR). The modification by heat shock of the expression of sfiA and soxS genes induced by oxidative agents H2O2, menadione and 4-nitroquinoline-1-oxide (4NQO) was studied for the first time. Quantitative parameters of gene expression were examined in E. coli strains with fused genes (promoters) sfiA::lacZ and soxS::lacZ. The expression of these genes induced by cell treatment with H2O2, but not menadione or 4NQO, was shown to decrease selectively after exposure to heat shock. Since genetic activity of menadione and 4NQO depends mainly on the formation of superoxide anion O2-, it is assumed that the effect of selective inhibition by heat-shock of sfiA and soxS gene expression in experiments with H2O2 is connected with activity of DnaK heat shock protein, which, unlike other heat-shock proteins, cannot be induced by superoxide anion O2-.     

Characterization of the rec-1 gene of Haemophilus influenzae and behavior of the gene in Escherichia coli.

The rec-1 gene of Haemophilus influenzae was cloned into a shuttle vector that replicates in Escherichia coli as well as in H. influenzae. The plasmid, called pRec1, complemented the defects of a rec-1 mutant in repair of UV damage, transformation, and ability of prophage to be induced by UV radiation. Although UV resistance and recombination were caused by pRec1 in E. coli recA mutants, UV induction of lambda and UV mutagenesis were not. We suggest that the ability of the H. influenzae Rec-1 protein to cause cleavage of repressors but not the recombinase function differs from that of the E. coli RecA protein.