A loss of uvrA function decreases the induction of the SOS functions recA and umuC by mitomycin C in Escherichia coli

We have studied the levels of recA and umuC protein synthesis in Escherichia coli as a probe for regulatory and mechanistic events involved in mitomycin C mutagenesis. Both RecA and UmuC protein induction were greatly stimulated by mitomycin C in the wild-type strain, reached a peak at about 60 min for the recA gene, and at 90 min for the umuC gene, respectively, and maintained a plateau. The induction was blocked by recA and lexA(Ind-) mutations that conferred no mutagenesis on the cell. Mutation affecting uvrA protein markedly decreased induction of the recA gene as well as the umuC gene by mitomycin C. The results established that UvrA protein is involved in the induction of recA and umuC, and account, at least in part, for the mitomycin C nonmutability of uvrA mutants.     

Post-replication repair and recombination in uvrA umuC strains of Escherichia coli are enhanced by vanillin, an antimutagenic compound

Effects of vanillin on UV killing of umuC mutant strains of E. coli were investigated in order to analyze the antimutagenic role of vanillin in mutagenesis. UV-irradiated uvrA umuC cells showed higher survival when plated on medium containing vanillin rather than medium without vanillin. This increased survival associated with exposure to vanillin was observed more clearly in uvrA umuC lexA(Ind-) and uvrA umuC recF strains. However, the effect was inhibited by additional recB recC mutations and completely blocked by an additional recA mutation. As far as tested the increased survival of UV-treated cells by vanillin was dependent on a capacity for genetic recombination. The effect of vanillin on recombination frequency between 2 plasmid DNA, pATH4 (Cmr Tcs) and pBMX7 (Apr Tcs), in a uvrA umuC background was investigated. A significantly higher frequency of plasmid recombination was observed when vanillin was present in the culture medium. These findings suggest that the antimutagenic effect of vanillin is the result of enhancement of a recA-dependent, error-free, pathway of post-replication repair.     

Induction of SOS functions by nitrogen dioxide in Escherichia coli with different DNA-repair capacities

The effect of gaseous nitrogen dioxide (NO2) on cytotoxicity, induction of synthesis of UmuC and RecA proteins, and mutagenesis was studied in Escherichia coli strains with different capacities of DNA repair. Gaseous NO2 (90, 180 microliter/l) killed Escherichia coli. The recA mutant was most sensitive, the lexA mutant moderately sensitive, and the uvrA mutant and the wild-type the least sensitive. When 90 microliter/l NO2 gas was bubbled into bacterial suspensions for 30 min at a flow rate of 100 ml/min, the induction of umuC gene expression increased in the wild-type strain. NO2 also induced the recA gene expression in the wild-type strain. The synthesis of neither RecA nor UmuC proteins was induced in the recA and lexA mutants. We further investigated the NO2 mutagenesis in the cells treated with bubbling of NO2 gas. NO2 caused mutation to Trp+ of WP2.     

Induction of SOS responses in Escherichia coli by Panfuran-S, 3-di(hydroxymethyl)amino-6-(5-nitro-2-furylethenyl)-1,2,4-triazine

The inducibility of SOS responses by Panfuran-S, which has been used as an antimicrobial medicine in Japan, was studied in Escherichia coli cells having different DNA-repair capacities for UV lesions. Panfuran-S induced mutations at high frequencies in uvrA and the wild-type strains, and significant killing effects of Panfuran-S were detected in DNA-repair-deficient strains, uvrA and recA. The effective prophage induction was detected in two kinds of lambda-lysogenized cells treated with Panfuran-S. The expression of the umuC+ gene was apparently induced in uvrA and the wild-type strains, but not induced in lexA and recA strains. In particular, high inducibility of the gene expression was detected in uvrA strain as compared with the wild-type strain. From these results, we conclude that Panfuran-S is a DNA-damaging agent and may induce the error-prone SOS responses.     

Radioadaptive enhancement of the repair of UV-induced postreplication gaps in Escherichia coli cells deficient in DNA repair

In UV-irradiated E. coli WP2 uvrA, deficient in excision repair of DNA with pyrimidine dimers, gamma-irradiation in low doses (radioadaptation) before UV-irradiation leads to the intensification of postreplication repair of DNA. This process in WP2 uvrA polA and uvrA lexA mutants is less than in WP2 uvrA cells, but in WP2 uvrA recA both postreplication repair and its radioadaptive intensification are absent. In E. coli AB1157 excising pyrimidine dimers the radioadaptive intensification of postreplication repair of DNA is expressed almost to the same extent as in WP2 uvrA. In GW2100 umuC mutant, deficient in DNA polymerase V, postreplication repair of DNA is expressed, but its radioadaptive intensification is absent, while in AB2463 recA13 both postreplication repair of DNA and radioadaptive intensification of postreplication repair of DNA are absent. The above data suggest that DNA polymerase I and LexA protein are needed for radioadaptive intensification of postreplication repair of DNA in uvrA strain, and DNA polymerase V is needed for radioadaptive intensification in E. coli AB1157, and that RecA protein is required for postreplication repair and radioadaptive intensification of postreplication repair of DNA.     

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.     

Cross-adaptive response in Escherichia coli caused by pretreatment with H2O2 against formaldehyde and other aldehyde compounds.

A cross-adaptive response (CAR), defined as a reduction of the effects of an agent by pretreatment with another agent, was demonstrated when E. coli WP2 cells were pretreated with hydrogen peroxide (H2O2) followed by challenging treatment with aldehyde compounds. Pretreatment with a sublethal dose (60 microM) of H2O2 for 30 min made WP2 cells resistant to the killing effects of formaldehyde (FA), and 4 other mutagenic aldehydes: glutaraldehyde, glyoxal, methyl glyoxal and chloroacetaldehyde. CAR was also observed in WP2uvrA (uvrA-) and ZA12 (umuC-) cells, but not in ZA60 (recA-) and CM561 (lexA- (Ind-] cells. A role of recA and lexA in CAR was further suggested by the lack of beta-galactosidase induction in recA- and lexA- cells by H2O2. CAR and beta-galactosidase induction, however, were found to be separate events since CAR was recovered by introducing the recA+ gene into lexA- cells, but no induction of beta-galactosidase by H2O2 was observed in cells with the same gene transfer. These results suggest that H2O2 has the capacity to induce a function which reduces the killing effects of aldehydes, and the function is controlled by the recA gene without involvement of SOS response.     

Mutagenic DNA repair in Escherichia coli. XV. Mutation frequency decline of ochre suppressor mutations in umuC and lexA bacteria occurring between ultraviolet irradiation and delayed photoreversal

Tryptophan-independent mutations were induced in CM1141 trpE65 umuC122::Tn5 following exposure to ultraviolet light (UV) plus delayed photoreversal. The mutations appeared to be exclusively class 2 ochre suppressors and showed mutation frequency decline (MFD) when the bacteria were incubated in glucose-salts medium after UV and before photoreversal. The phenomenon was similar to MFD after normal UV mutagenesis of umu+ bacteria, being inhibited in the presence of caffeine or in the absence of glucose. Mutations were also induced by UV plus delayed photoreversal in the lexA (Ind-) strain CM561, and the yield was higher than in the umuC strain suggesting that potentially mutagenic configurations might be removed or altered to some extent by the product of a gene under lexA control such that fewer were available for misincorporation events. MFD was also demonstrated in CM561 showing that this process is not dependent on the derepression of any genes under lexA control. MFD could still be demonstrated 23 min after UV at a time when most misincorporations seem to have occurred, but for technical reasons the possibility could not be excluded that the misincorporations in question could have occurred during rather than before the exposure to photoreversing light. Delayed photoreversal mutagenesis of normally non-UV-mutable strains has been interpreted as a first stage (misincorporation) of normal UV mutagenesis. The present results are consistent with this interpretation since MFD of suppressor mutations is a feature of both processes.     

The mutA mistranslator tRNA-induced mutator phenotype requires recA and recB genes, but not the derepression of lexA-regulated functions

The mapping of mutA and mutC mutator alleles to the glyV and glyW glycine tRNA genes, respectively, and the subsequent discovery that the mutA phenotype is abolished in a DeltarecA strain raise the possibility that asp --> gly misinsertion may induce a novel mutagenic pathway. The recA requirement suggests three possibilities: (i) the SOS mutagenesis pathway is activated in mutA cells; (ii) loss of recA function interferes with mutA-promoted asp --> gly misinsertion; or (iii) a hitherto unrecognized recA-dependent mutagenic pathway is activated by translational stress. By assaying the expression levels of a reporter plasmid bearing a umuC :lacZ fusion, we show that the SOS regulon is not in a derepressed state in mutA cells. Neither overexpression of the lexA gene through a multicopy plasmid nor replacement of the wild-type lexA allele with the lexA1[Ind-] allele interferes with the expression of the mutA phenotype. The mutA phenotype is unaffected in cells defective for dinB, as shown here, and is unaffected in cells defective for umuD and umuC genes, as shown previously. We show that mutA-promoted asp --> gly misinsertion occurs in recA- cells and, therefore, the requirement for recA is 'downstream' of mistranslation. Finally, we show that the mutA phenotype is abolished in cells deficient for recB, suggesting that cellular recombination functions may be required for the expression of the mutator phenotype. We propose that translational stress induces a previously unrecognized mutagenic pathway in Escherichia coli.     

Mutagenic action of nitrous acid on prophage lambda

The lethal and mutagenic effects of nitrous acid (0,1 M NaNO2 in 0,1 M acetate buffer, pH 4.6) on prophage lambda cI857 ind- were studied in the wild-type cells of Escherichia coli and in 9 repair-deficient mutants: uvrA6, uvrA6 umuC36, uvrD3, uvrE502, polA1, recA13, lexA102, recF143 and xthA9. After treatment with HNO2, the prophage was heat-induced either immediately or after 90 min incubation in broth at 32 degrees C. The prophage survival after delayed induction was considerably higher than after immediate induction. The lethal action of HNO2 was highly expressed in uvrA- and uvrE- lysogens after delayed induction. The frequency of temperature-independent c mutants forming clear plaques at 32 degrees C reached 4% in the wild-type host after immediate induction, this value being 10-15% in uvrA, uvrA umuC, uvrD, uvrE, polA and xthA mutants, 0,8% in recF- lysogen and only 0,2-0,3% in recA and lexA mutants. Under these conditions, about 90% of c mutants are generated by recA+, lexA+-dependent repair mechanism (most probably, due to W-mutagenesis). After delayed induction, mutation frequency in the wild-type host declines considerably (down to 0,1%). Analogous phenomenon of mutation frequency decline was registered in uvrA, xthA, recF, polA, uvrE and uvrD lysogens. Under conditions of delayed induction, the frequency of HNO2-induced c mutations only slightly depends on the recA+ and lexA+ gene products and mutations are, apparently, fixed by replication.     

Action of plasmid ColIb-P9 on the survival after ultraviolet irradiation and on the mutagenesis of the imiC, uvm, recL, uvrE and tif1 sfiA lexA spr mutants of Escherichia coli K-12 cells

To clarify the mechanisms whereby the ColIb-P9 plasmid affects DNA repair processes, its effect was studied in mutant Escherichia coli K-12 cells with altered mutagenesis and DNA repair. The plasmid was shown to protect umuC, uvm, recL and uvrE mutants after UV irradiation. The frequency of UV-induced his+ revertants increased in the presence of the plasmid in umuC, uvm and recL mutant cells. The ColIb-P9 plasmid completely restored the UV mutability and survival of umuC mutants. These results suggest that the ColIb-P9 plasmid may encode a product similar to that of the umuC gene. In the tif1 sfiA lexA spr mutant cells where SOS functions are constitutively expressed, the ColIb-P9 plasmid increased the number of his+ revertants several times. This suggests that the action of ColIb-P9 is probably brought about not via the derepression of the recA gene but at the subsequent stages of the recA+lexA+-dependent DNA error-prone repair.     

Induction of SOS responses in Escherichia coli by 5-fluorouracil

The inducibility of SOS responses by 5-fluorouracil (5-FU), which has been used as an antitumor drug, was studied in Escherichia coli cells which have different DNA repair capacities for UV lesions. Expression of the umuC gene was apparently induced by 5-FU in the wild-type and uvrA strains, but not in lexA and recA strains. The inducibility of the umuC gene by 5-FU, the metabolite of which inhibits thymidylate synthetase, was abolished in cultures containing deoxythymidine monophosphate which is converted from deoxyuridine monophosphate by thymidylate synthetase. These results suggest that 5-FU may exert its SOS inducibility by inhibiting thymidylate synthetase and then disturbing DNA metabolism but not by incorporating 5-FU residues into RNA. Further, 5-FU weakly induced mutations in E. coli.     

A multicopy phr-plasmid increases the ultraviolet resistance of a recA strain of Escherichia coli

It has been previously reported that the ultraviolet sensitivity of recA strains of Escherichia coli in the dark is suppressed by a plasmid pKY1 which carries the phr gene, suggesting that this is due to a novel effect of photoreactivating enzyme (PRE) of E. coli in the dark (Yamamoto et al., 1983a). In this work, we observed that an increase of UV-resistance by pKY1 in the dark is not apparent in strains with a mutation in either uvrA, uvrB, uvrC, lexA, recBC or recF. The sensitivity of recA lexA and recA recBC multiple mutants to UV is suppressed by the plasmid but that of recA uvrA, recA uvrB and recA uvrC is not. Host-cell reactivation of UV-irradiated lambda phage is slightly more efficient in the recA/pKY1 strain compared with the parental recA strain. On the other hand, the recA and recA/pKY1 strains do not differ significantly in the following properties: Hfr recombination, induction of lambda by UV, and mutagenesis. We suggest that dark repair of PRE is correlated with its capacity of excision repair.     

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.     

Induction of umu gene expression by cross-links and other DNA lesions

The induction of umu gene expression by DNA cross-links was investigated in various strains of E. coli with different DNA-repair capacities. Expression was measured by quantifying enzymatic activity of beta-galactosidase produced under regulation of the umu promoter carried on a plasmid carrying the umuC-lacZ gene fusion. The treatment with MMC induced gene expression more efficiently in a wild-type strain when compared with an excision-repair-deficient strain (uvrA). In contrast, PUVA and cis-Pt treatment induced higher levels of the gene expression in the uvrA strain than in the wild-type strain, as did other DNA-damaging agents including 4NQO, MNNG and MMS. None of these chemicals induced umu expression in either lexA and recA strains. The mechanisms of the induction of umu expression by DNA cross-links in relation to DNA damage and repair are discussed.     

Construction of Escherichia coli K12 phr deletion and insertion mutants by gene replacement

We replaced an Escherichia coli phr gene by a 1.4-kb fragment of DNA coding for resistance to chloramphenicol. Characterization of 2 deletions (phr-19 and phr-36) and 1 insertion (phr-34) in the phr gene revealed no photoreactivation. Photoreactivation-deficient strains of either recA56 or lexA1(ind-) were more sensitive to UV radiation in the dark than phr-proficient counterparts. The presence of the phr defect in uvrA6 strains increased by 1.5-2-fold his-4(Ochre) to His+ mutation induced by ultraviolet light compared to uvrA6 phr+ strains, although there was no difference in UV sensitivity between uvrA6 phr+ and uvrA6 phr- strains. 30-35% of the His+ mutations thus induced were suppressor mutations in uvrA6 phr+ and 49-55% in uvrA6 phr- strains. The UV mutagenesis results are consistent with the previous observations that suppressor mutations targeted by a thymine-cytosine pyrimidine dimer are reduced in the dark in cells with amplified DNA photolyase.     

Genotoxicity assay of oil dispersants in bacteria (mutation, differential lethality, SOS DNA-repair) and yeast (mitotic crossing-over)

5 oil dispersants and a sample of paraffin were devoid of mutagenic activity in the Ames reversion test, with and without S9 mix, using 7 his- S. typhimurium strains (TA1535, TA1537, TA1538, TA97, TA98, TA100, TA102). However, 3 dispersants produced direct DNA damage in E. coli WP2, which was not repairable in repair-deficient strains (WP2uvrA, CM871, TM1080), as shown by two different DNA-repair test procedures. The uvrA excision-repair system was in all cases the most important mechanism involved in repairing the DNA damage produced by oil dispersants, while the combination of uvrA with other genetic defects (polA, recA, lexA) decreased the efficiency of the system. The observed genotoxic effects were considerably lowered in the presence of S9 mix containing liver S9 fractions from Aroclor-treated rats. The sample of oil dispersant yielding the most pronounced DNA damage in repair-deficient E. coli failed to induce gene sfiA in E. coli (strain PQ37), using the SOS chromotest, or mitotic crossing-over in Saccharomyces cerevisiae (strain D5). The direct toxicity of the oil dispersant to both bacterial and yeast cells was markedly decreased in the presence of rat-liver preparations. These two short-term tests were effective in detecting the genotoxicity of both direct-acting compounds (such as 4-nitroquinoline N-oxide and methyl methanesulfonate) and procarcinogens (such as cyclophosphamide, 2-aminoanthracene and 2-aminofluorene). Moreover, the SOS chromotest was successfully applied to discriminate the activity of chromium compounds as related to their valence (i.e. Cr(VI) genotoxic and Cr(III) inactive). Combination of oil dispersants with Cr(VI) compounds did not affect the direct mutagenicity to S. typhimurium (TA102) of a soluble salt (sodium dichromate) nor did it result in any release of a water-soluble salt (lead chromate), as also confirmed by analytical methods. On the other hand, exposure to sunlight tended to decrease, to a slow rate, the direct genotoxicity of an oil dispersant in the bacterial DNA-repair test.     

Mutagenicity of methyl-, ethyl-, propyl- and butylnitrosourea towards Escherichia coli WP2 strains with varying DNA repair capabilities.

Methyl- (MNUA), ethyl- (ENUA), propyl- (PNUA) and butylnitrosourea (BNUA) have been tested for toxicity and mutation in a liquid suspension assay towards Escherichia coli WP2 and some of its repair deficient derivatives. A comparison of survival rates after nitrosourea exposure between WP2 and WP2 uvrA showed no difference between the two strains but a consistent difference in potency between the various nitrosoureas studied. Toxicity increased in the order MNUA less than PNUA less than ENUA less than BNUA. ENUA and PNUA induced a greater number of trp+ revertants in both strains than did MNUA and BNUA, particularly at low survival rates. None of these differences in biological potency could be accounted for by differences in rates of hydrolysis. ENUA, PNUA and BNUA were non-mutagenic towards WP2 lexA, WP2 recA and WP2 uvrA lexA, whereas MNUA did induce mutations. Ethyl methanesulphonate (EMS) was able to mutate WP2 lexA. These results are discussed in the light of current theories regarding the mechanism of action of these compounds.     

Effect of tsl (thermosensitive suppressor of lex) mutation on postreplication repair in Escherichia coli K-12.

Cells of Escherichia coli K-12 carrying lexA or recA mutations are more sensitive to UV radiation than corresponding wild-type cells and are defective in postreplication repair. Supressor mutations (tsl) have been described previously which increase the UV resistance of lexA uvr+, lexA uvrA, and recAI uvr+ strains, but not the resistance of recA1 uvrA strains. We have studied the effect of the tsl-1 mutation on postreplication repair and find that the enhanced survival conferred by this mutation is correlated with an increased capacity for postreplication repair.