Effect of UVM induction on mutation fixation at non-pairing and mispairing DNA lesions

Mutation fixation at an ethenocytosine (εC) residue borne on transfected M13 single-stranded DNA is significantly enhanced in response to pretreatment of Escherichia coli cells with UV, alkylating agents or hydrogen peroxide, a phenomenon that we have called UVM for UV modulation of mutagenesis. The UVM response does not require the E. coli SOS or adaptive responses, and is observed in cells defective for oxyR , an oxidative DNA damage-responsive regulatory gene. UVM may represent either a novel DNA-repair phenomenon, or an unrecognized feature of DNA replication in damaged cells that affects a specific class of non-coding DNA lesions. To explore the range of DNA lesions subject to the UVM effect, we have examined mutation fixation at 3, N  ⁴-ethenocytosine and 1, N  ⁶-ethenoadenine, as well as at O⁶-methylguanine (O⁶mG). M13 viral single-stranded DNA constructs bearing a single mutagenic lesion at a specific site were transfected into cells pretreated with UV or 1-methyl-3-nitro-1-nitrosoguanidine (MNNG). Survival of transfected viral DNA was measured as transfection efficiency, and mutagenesis at the lesion site was analysed by a quantitative multiplex sequence analysis technology. The results suggest that the UVM effect modulates mutagenesis at the two etheno lesions, but does not appear to significantly affect mutagenesis at O⁶mG. Because the modulation of mutagenesis is observed in cells incapable of the SOS response, these data are consistent with the notion that UVM may represent a previously unrecognized DNA damage-inducible response that affects the fidelity of DNA replication at certain mutagenic lesions in Escherichia coli .     

Regulation of RAD54- and RAD52-lacZ gene fusions in Saccharomyces cerevisiae in response to DNA damage.

The RAD52 and RAD54 genes in the yeast Saccharomyces cerevisiae are involved in both DNA repair and DNA recombination. RAD54 has recently been shown to be inducible by X-rays, while RAD52 is not. To further investigate the regulation of these genes, we constructed gene fusions using 5' regions upstream of the RAD52 and RAD54 genes and a 3'-terminal fragment of the Escherichia coli beta-galactosidase gene. Yeast transformants with either an integrated or an autonomously replicating plasmid containing these fusions expressed beta-galactosidase activity constitutively. In addition, the RAD54 gene fusion was inducible in both haploid and diploid cells in response to the DNA-damaging agents X-rays, UV light, and methyl methanesulfonate, but not in response to heat shock. The RAD52-lacZ gene fusion showed little or no induction in response to X-ray or UV radiation nor methyl methanesulfonate. Typical induction levels for RAD54 in cells exposed to such agents were from 3- to 12-fold, in good agreement with previous mRNA analyses. When MATa cells were arrested in G1 with alpha-factor, RAD54 was still inducible after DNA damage, indicating that the observed induction is independent of the cell cycle. Using a yeast vector containing the EcoRI structural gene fused to the GAL1 promoter, we showed that double-strand breaks alone are sufficient in vivo for induction of RAD54.     

Requirement of the Escherichia coli dnaK gene for thermotolerance and protection against H2O2

Thermotolerance in Escherichia coli is induced by exposing cells to a brief heat shock (42 degrees C for 15 min). This results in resistance to the lethal effect of exposure to a higher temperature (50 degrees C). Mutants defective in the recA, uvrA and xthA genes are more sensitive to heat than the wild-type. However, after development of thermotolerance these mutants are like the wild-type in their heat sensitivity. This suggests that thermotolerance is an inducible response capable of protecting cells from the lethal effects of heat, independently of recA, uvrA and xthA. Thermotolerance does not develop in a dnaK mutant. In addition, the dnaK mutant is sensitive to heat and H2O2, but is resistant to UV irradiation. This implies that the E. coli heat-shock response includes a mechanism that protects cells from heat and H2O2, but not from UV.     

Role of mismatch repair in the Escherichia coli UVM response.

Mutagenesis at 3,N4-ethenocytosine (epsilonC), a nonpairing mutagenic lesion, is significantly enhanced in Escherichia coli cells pretreated with UV, alkylating agents, or H2O2. This effect, termed UVM (for UV modulation of mutagenesis), is distinct from known DNA damage-inducible responses, such as the SOS response, the adaptive response to alkylating agents, or the oxyR-mediated response to oxidative agents. Here, we have addressed the hypothesis that UVM results from transient depletion of a mismatch repair activity that normally acts to reduce mutagenesis. To test whether the loss of mismatch repair activities results in the predicted constitutive UVM phenotype, E. coli cells defective for methyl-directed mismatch repair, for very-short-patch repair, or for the N-glycosylase activities MutY and MutM were treated with the UVM-inducing agent 1-methyl-3-nitro-1-nitrosoguanidine, with subsequent transfection of M13 viral single-stranded DNA bearing a site-specific epsilonC lesion. Survival of the M13 DNA was measured as transfection efficiency, and mutation fixation at the lesion was characterized by multiplex sequencing technology. The results showed normal UVM induction patterns in all the repair-defective strains tested. In addition, normal UVM induction was observed in cells overexpressing MutH, MutL, or MutS. All strains displayed UVM reactivation, the term used to describe the increased survival of epsilonC-containing DNA in UVM-induced cells. Taken together, these results indicate that the UVM response is independent of known mismatch repair systems in E. coli and may thus represent a previously unrecognized misrepair or misreplication pathway.     

Dithiothreitol pretreatment and inducible repair in UV-irradiated Escherichia coli K12 cells

The UV radiation survival of several Escherichia coli K12 strains was measured after pretreatment of the cells with dithiothreitol (DTT). In DNA repair-competent cells (AB1157), UV survival was enhanced (ER = 1.2) after pretreating cells for 1.0 h using 10 mmol dm-3 DTT and then incubating the cells for 1.5 h in buffer before UV irradiation. Similar experiments using the excision repair mutant, AB1886uvrA6, or the recombination repair and SOS-deficient mutant, AB2462recA, strains did not show enhanced UV survival. None of the E. coli strains tested were protected against UV killing by simultaneous treatment with DTT (10 mmol dm-3). These results, and the fact that incubation in chloramphenicol removed the wild-type response in DTT-pretreated, UV-irradiated cells, suggest that the observed UV radioprotection was a result of inducible enzymatic repair processes such as recA-dependent repair. The proposed stimulus for inducible repair in these cells is DNA damage caused by intracellular hydroxyl radicals arising from thiol oxidation. The involvement of oxygen radicals in the induction pathway is supported by results that showed superoxide dismutase and catalase could inhibit a portion (one-third) of the inducible repair.     

Effect of UV light on DNA replication and chain elongation in Chinese hamster UV61 cells

Exposure of eukaryotic cells to ultraviolet light results in a temporary inhibition of DNA replication as well as a temporary blockage of DNA fork progression. Recently there has been considerable debate as to whether the (5-6)cyclobutane pyrimidine dimer, the pyrimidine(6-4)pyrimidone lesion or both are responsible for these effects. Using cell lines that repair both of these lesions (CHO AA8), only (6-4) lesions (CHO UV61) or neither (CHO UV5), we have shown that in rodent cells both lesions appear to play a role in both the inhibition of thymidine incorporation and the blockage of DNA fork progression. Specifically, after exposure to 2.5 J/m2, AA8 cells recover normal rates of DNA replication within 5 h after exposure, while UV5 cells exhibit a greater depression in thymidine incorporation for at least 10 h. UV61 cells, on the other hand, show an intermediate response, both with respect to the extent of the initial depression and the rate of recovery of thymidine incorporation. UV61 cells also exhibit an intermediate response with respect to blockage of DNA fork progression. In previous publications we have shown that UV5 cells exhibit extensive blockage of DNA fork progression and only limited recovery of this effect within the first 5 h after exposure to UV. In this report we show that UV61 cells exhibit a more extensive blockage of fork progression than is observed in AA8 cells. These blocks also appear to be removed (or overcome) more slowly than in the AA8 cells, but more rapidly than in UV5 cells. Taken together we conclude that both lesions appear to be involved in the initial depression in thymidine incorporation and the initial blockage of DNA fork progression in rodent cells. These data also indicate that (6-4) lesions may be responsible for the prolonged depression in thymidine incorporation and the prolonged blockage of DNA fork progression observed in UV5 cells.     

Functional recA, lexA, umuD, umuC, polA, and polB genes are not required for the Escherichia coli UVM response.

The Escherichia coli UVM response is a recently described phenomenon in which pretreatment of cells with DNA-damaging agents such as UV or alkylating agents significantly enhances mutation fixation at a model mutagenic lesion (3,N4-ethenocytosine; epsilon C) borne on a transfected M13 single-stranded DNA genome. Since UVM is observed in delta recA cells in which SOS induction should not occur, UVM may represent a novel, SOS-independent, inducible response. Here, we have addressed two specific hypothetical mechanisms for UVM: (i) UVM results from a recA-independent pathway for the induction of SOS genes thought to play a role in induced mutagenesis, and (ii) UVM results from a polymerase switch in which M13 replication in treated cells is carried out by DNA polymerase I (or DNA polymerase II) instead of DNA polymerase III. To address these hypotheses, E. coli cells with known defects in recA, lexA, umuDC, polA, or polB were treated with UV or 1-methyl-3-nitro-1-nitrosoguanidine before transfection of M13 single-stranded DNA bearing a site-specific ethenocytosine lesion. Survival of the transfected DNA was measured as transfection efficiency, and mutagenesis at the epsilon C residue was analyzed by a quantitative multiplex DNA sequencing technology. Our results show that UVM is observable in delta recA cells, in lexA3 (noninducible SOS repressor) cells, in LexA-overproducing cells, and in delta umuDC cells. Furthermore, our data show that UVM induction occurs in the absence of detectable induction of dinD, an SOS gene. These results make it unlikely that UVM results from a recA-independent alternative induction pathway for SOS gene.     

Protective action of colicinogenic factor Ib-P9 on Escherichia coli cells defective in known repair functions after ultraviolet irradiation]

The presence of the plasmid colicinogenic factor Ib-P9 in Escherichia coli wild type cells is shown to increase bacterial survival after UV irradiation and the action of N-methyl-N'-nitro-N-nitrosoguanidine. The ability of the plasmid to cause the UV protection is observed in uvrA, uvrB, uvrC, polA, recB, recF E. coli strains, but the plasmid does not restore the UV resistance of the mutant cells to the wild type level. The protective effect of the plasmid CoI Ib-P9 depends on the recA+lexA+ genotype of the cells. The inhibition of protein synthesis (amino acid starvation) before and after UV irradiation does not prevent the UV protection by ColIb-P9. The nature of the plasmid-associated repair functions is discussed.     

Effects of modulation of RNase H production on the recovery of DNA synthesis following UV-irradiation in Escherichia coli

The requirements for the recovery of DNA synthesis in UV-irradiated Escherichia coli were analysed in strains having varied levels of RNase H and RecA protein. We have previously shown (Khidhir et al. 1985) that the recovery of DNA synthesis in E. coli following UV treatment is an inducible SOS function requiring protein synthesis. We proposed that this reflected the need for the synthesis of specific induced replisome reactivation factor(s) for recovery. In this study we now show that recovery of DNA synthesis can in fact take place in the absence of protein synthesis in a mutant lacking RNase H and having high (constitutive) levels of RecA protein. We also show that expression of rnh is inhibited during the SOS response in recA+ but not in a recA- strain. The results are discussed in relation to the mechanism of recovery of DNA synthesis following UV irradiation in E. coli.     

A grpE mutant of Escherichia coli is more resistant to heat than the wild-type

The grpE gene of Escherichia coli is essential for bacteriophage lambda DNA replication and is also necessary for host RNA and DNA synthesis at high temperature. A grpE mutant of E. coli was found to be substantially more resistant to 50 degrees C heat treatment than the wild-type. Upon receiving a 42 degrees C heat shock for 15 min, both the wild-type and the grpE mutant became more resistant to heat (i.e. they became thermotolerant). A grpE+ revertant behaved similarly to the wild-type in that it was more sensitive to heat than grpE cells. In addition, grpE cells had the same H2O2 and UV sensitivity as the wild-type. This implies that the conditions for which a grpE mutation is beneficial are unique to heat exposure and are not caused by H2O2 or UV exposure. Furthermore, synthesis of heat-shock proteins occurred sooner in the grpE mutant than in the wild-type, indicating that the grpE gene of E. coli may influence the regulation of the heat-shock response.     

Unusual properties of a new division mutant of Escherichia coli

The properties of a division mutant of Escherichia coli were investigated. At 42 degrees C, this mutant forms nonseptate, multinucleate, filamentous cells typical of division mutants, and at the permissive temperature, is sensitive to ultraviolet (UV) irradiation. Temperature and UV sensitivities are probably due to a single mutation. The mutant phenotype is dominant to wild type. The mutant cells make DNA nearly as effectively as control cells at 42 degrees C or following UV irradiation. They exhibit normal host-cell reactivation capacities and can express all manifestations of the SOS response with the exception of Weigle reactivation. The genetic lesion which mediates this pleiotropic effect is located very close to the leu locus of the linkage map.     

Induction of Shiga toxin-converting prophage in Escherichia coli by high hydrostatic pressure

Since high hydrostatic pressure is becoming increasingly important in modern food preservation, its potential effects on microorganisms need to be thoroughly investigated. In this context, mild pressures (<200 MPa) have recently been shown to induce an SOS response in Escherichia coli MG1655. Due to this response, we observed a RecA- and LexA-dependent induction of lambda prophage upon treating E. coli lysogens with sublethal pressures. In this report, we extend this observation to lambdoid Shiga toxin (Stx)-converting bacteriophages in MG1655, which constitute an important virulence trait in Stx-producing E. coli strains (STEC). The window of pressures capable of inducing Stx phages correlated well with the window of bacterial survival. When pressure treatments were conducted in whole milk, which is known to promote bacterial survival, Stx phage induction could be observed at up to 250 MPa in E. coli MG1655 and at up to 300 MPa in a pressure-resistant mutant of this strain. In addition, we found that the intrinsic pressure resistance of two types of Stx phages was very different, with one type surviving relatively well treatments of up to 400 MPa for 15 min at 20 degrees C. Interestingly, and in contrast to UV irradiation or mitomycin C treatment, pressure was not able to induce Stx prophage or an SOS response in several natural Stx-producing STEC isolates.     

Reactivating effect of Escherichia coli exometabolites on UV-irradiated cells

Wild-type and mutant (AB 1157 and K-12) strains of Escherichia coli were shown to synthesize the logarithmic growth phase, exometabolites reactivating UV-irradiated cells of producer strains. The exometabolites of the strain K-12 were of protein nature and had a molecular weight of no more than 10 kDa. The reactivating activity of these exometabolites was inversely related to bacterial survival and slightly increased under the influence of stress factors. The reactivating factor of Luteococcus casei had a cross-reactivating and protective effect on UV-irradiated cells of E. coli strain K-12. Due to activation of the reactivating factor after UV irradiation and heating, the cross-protective effect increased more than threefold. The reactivating effect remained unchanged under these conditions. The protein exometabolites of E. coli did not induce cross-stress response in L. casei.     

Involvement of recA and exr Genes in the In Vivo Inhibition of the recBC Nuclease

When Escherichia coli cells are gamma irradiated they degrade their deoxyribonucleic acid (DNA). The DNA of previously gamma-irradiated T4 phage is also degraded in infected cells. The amount of degradation is not only dependent on the dose but also on the genotype of the cell. The amount of degradation is less in cells carrying a recB or a recC mutation, suggesting that most of the DNA degradation is due to the recB(+) and recC(+) gene product (exonuclease V). In some strains a previous dose of ultraviolet (UV) light followed by incubation renders the cells resistant to DNA degradation after gamma irradiation. We have shown this inhibition to take place for infecting T4 phage also. By using six strains of E. coli selected for mutations in the genes recA, exr (or lex), and uvrB, we have been able to show that the preliminary UV treatment produces no change in recA and exr cells for both endogenous DNA degradation and the degradation of infecting irradiated T4 phage DNA, i.e., inhibition was not detected in these strains. On the other hand, wild-type cells and strains carrying mutations of uvrB show inhibition in both types of experiments. Because the recA gene product and the exr(+) (lex(+)) gene product are necessary for the induction of prophage, it is possible that the phenomenon of inducible inhibition requires recA(+) and exr(+) presence. One interpretation of these results is that an inducible inhibitor may be controlled by the exr gene.     

Effect of chloramphenicol and cyanide on the increase in UV resistance of intracellular bacteriophage T1.

The effects of chloramphenicol and cyanide on the increase in UV resistance of intracellular phage T1 infecting cells of E. coli B or E. coli Bs-1 were investigated. The inhibitiors were added to the cells 3 min prior to infection and to the complexes of phage-bacteria 3.5 and 6.5 min after adsorption of phage by the cells. The data obtained are not in agreement with the suggestion that increase in UV resistance of intracellular phage is mainly due to the accumulation of phage DNA inside the host cells. It is suggested that a very important role in this resistance is played by the interaction of phage DNA with the cell membranes.     

Electron paramagnetic resonance study reveals a putative iron-sulfur cluster in human rpS3 protein

The human ribosomal protein S3 (rpS3) functions as a component of the 40S subunit and as a UV DNA repair endonuclease. This enzyme has an endonuclease activity for UV-irradiated and oxidatively damaged DNAs. DNA repair endonucleases recognize a variety of UV and oxidative base damages in DNA from E. coli to human cells. E. coli endonuclease III is especially known to have an iron-sulfur cluster as a co-factor. Here, we tried an electron paramagnetic resonance (EPR) method for the first time to observe a known iron-sulfur cluster signal from E. coli endonuclease III that was previously reported. We compared it to the human rpS3 in order to find out whether or not the human protein contains an iron-sulfur cluster. As a result, we succeeded in observing a Fe EPR signal that is apparently from an iron-sulfur cluster in the human rpS3 endonuclease. The EPR signal from the human enzyme, consisting of three major parts, is similar to that from the E. coli enzyme, but it has a distinct extra peak.