Effects of vanillin and o-vanillin on induction of DNA-repair networks: modulation of mutagenesis in Escherichia coli

Vanillin and its isomer o-vanillin have an effect on the adaptive and SOS responses, as well as mutagenesis, induced in Escherichia coli by N-methyl-N-nitrosourea (MNU) and UV irradiation, potentiating in some cases and suppressing in others. o-Vanillin markedly inhibited the MNU-induced adaptive response, while both vanillins potentiated the UV-induced SOS response. These phenomena appear to be responsible for the comutagenic or antimutagenic role of these chemicals in MNU and UV mutagenesis.     

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 .     

Alkylating Agents Induce Uvm, a Reca-Independent Inducible Mutagenic Phenomenon in Escherichia Coli

Noninstructive DNA damage in Escherichia coli induces SOS functions hypothesized to be required for mutagenesis and translesion DNA synthesis at noncoding DNA lesions. We have recently demonstrated that in E. coli cells incapable of SOS induction, prior UV-irradiation nevertheless strongly enhances mutagenesis at a noninstructive lesion borne on M13 DNA. Here, we address the question whether this effect, named UVM for UV modulation of mutagenesis, can be induced by other DNA damaging agents. Exponentially growing δrecA cells were pretreated with alkylating agents before transfection with M13 single-stranded DNA bearing a site-specific ethenocytosine residue. Effect of cell pretreatment on survival of the transfected DNA was determined as transfection efficiency. Mutagenesis at the ethenocytosine site in pretreated or untreated cells was analyzed by multiplex DNA sequencing, a phenotype-independent technology. Our data show that 1-methyl-3-nitro-1-nitrosoguanidine, N-nitroso-N-methylurea and dimethylsulfate, but not methyl iodide, are potent inducers of UVM. Because alkylating agents induce the adaptive response to defend against DNA alkylation, we asked if the genes constituting the adaptive response are required for UVM. Our data show that MNNG induction of UVM is independent of ada, alkA and alkB genes and define UVM as an inducible mutagenic phenomenon distinct from the E. coli adaptive and SOS responses.     

Genetic analysis of mutagenesis in aging Escherichia coli colonies

Bacteria live in unstructured and structured environments, experiencing feast and famine lifestyles. Bacterial colonies can be viewed as model structured environments. SOS induction and mutagenesis have been observed in aging Escherichia coli colonies, in the absence of exogenous sources of DNA damage. This cAMP-dependent mutagenesis occurring in Resting Organisms in a Structured Environment (ROSE) is unaffected by a umuC mutation and therefore differs from both targeted UV mutagenesis and recA730 (SOS constitutive) untargeted mutagenesis. As a recB mutation has only a minor effect on ROSE mutagenesis it also differs from both adaptive reversion of the lacI33 allele and from iSDR (inducible Stable DNA Replication) mutagenesis. Besides its recA and lexA dependence, ROSE mutagenesis is also uvrB and polA dependent. These genetic requirements are reminiscent of the untargeted mutagenesis in λ phage observed when unirradiated λ infects UV-irradiated E. coli. These mutations, which are not observed in aging liquid cultures, accumulate linearly with the age of the colonies. ROSE mutagenesis might offer a good model for bacterial mutagenesis in structured environments such as biofilms and for mutagenesis of quiescent eukaryotic cells. Received: 30 April 1997 / Accepted: 1 July 1997     

RecA protein of Escherichia coli has a third essential role in SOS mutator activity.

The DNA damage-inducible SOS response of Escherichia coli includes an error-prone translesion DNA replication activity responsible for SOS mutagenesis. In certain recA mutant strains, in which the SOS response is expressed constitutively, SOS mutagenesis is manifested as a mutator activity. Like UV mutagenesis, SOS mutator activity requires the products of the umuDC operon and depends on RecA protein for at least two essential activities: facilitating cleavage of LexA repressor to derepress SOS genes and processing UmuD protein to produce a fragment (UmuD') that is active in mutagenesis. To determine whether RecA has an additional role in SOS mutator activity, spontaneous mutability (tryptophan dependence to independence) was measured in a family of nine lexA-defective strains, each having a different recA allele, transformed or not with a plasmid that overproduces either UmuD' alone or both UmuD' and UmuC. The magnitude of SOS mutator activity in these strains, which require neither of the two known roles of RecA protein, was strongly dependent on the particular recA allele that was present. We conclude that UmuD'C does not determine the mutation rate independently of RecA and that RecA has a third essential role in SOS mutator activity.     

SOS and UVM pathways have lesion-specific additive and competing effects on mutation fixation at replication-blocking DNA lesions

Escherichia coli cells have multiple mutagenic pathways that are induced in response to environmental and physiological stimuli. Unlike the well-investigated classical SOS response, little is known about newly recognized pathways such as the UVM (UV modulation of mutagenesis) response. In this study, we compared the contributions of the SOS and UVM pathways on mutation fixation at two representative noninstructive DNA lesions: 3,N4-ethenocytosine (epsilonC) and abasic (AP) sites. Because both SOS and UVM responses are induced by DNA damage, and defined UVM-defective E. coli strains are not yet available, we first constructed strains in which expression of the SOS mutagenesis proteins UmuD' and UmuC (and also RecA in some cases) is uncoupled from DNA damage by being placed under the control of a heterologous lac-derived promoter. M13 single-stranded viral DNA bearing site-specific lesions was transfected into cells induced for the SOS or UVM pathway. Survival effects were determined from transfection efficiency, and mutation fixation at the lesion was analyzed by a quantitative multiplex sequence analysis procedure. Our results suggest that induction of the SOS pathway can independently elevate mutagenesis at both lesions, whereas the UVM pathway significantly elevates mutagenesis at epsilonC in an SOS-independent fashion and at AP sites in an SOS-dependent fashion. Although mutagenesis at epsilonC appears to be elevated by the induction of either the SOS or the UVM pathway, the mutational specificity profiles for epsilonC under SOS and UVM pathways are distinct. Interestingly, when both pathways are active, the UVM effect appears to predominate over the SOS effect on mutagenesis at epsilonC, but the total mutation frequency is significantly increased over that observed when each pathway is individually induced. These observations suggest that the UVM response affects mutagenesis not only at class 2 noninstructive lesions (epsilonC) but also at classical SOS-dependent (class 1) lesions such as AP sites. Our results add new layers of complexity to inducible mutagenic phenomena: DNA damage activates multiple pathways that have lesion-specific additive as well as suppressive effects on mutation fixation, and some of these pathways are not directly regulated by the SOS genetic network.     

环境胁迫诱导的细胞适应性突变

细胞具有普遍的突变和进化能力, 如病原菌的抗药性、工业菌株的适应性和人体细胞的癌变等, 但是细胞的适应性突变是如何产生的呢？通过非致死性突变分析模型的建立与应用, 产生了新的适应性进化观点, 即环境胁迫诱导细胞适应性突变。这种环境诱导的细胞突变过程涉及多方面的生理调控, 包括细胞内毒性物质(如氧活性物质)积累并造成DNA损伤、DNA错配修复的活性受到抑制、胞内RpoS反应和SOS反应被激活等。这些反应使胞内高保真的DNA复制状态转变为低保真的DNA修复状态, 提高胞内突变率和重组活性。此外, 基因转录影响基因组的不稳定, 容易产生DNA损伤, 并造成局部的高突变率, 即形成了转录偶联的DNA修复与突变为基础的适应性突变观点。文章围绕环境胁迫诱导细胞突变率增加和转录偶联的DNA修复与突变这两种适应性突变分子机制, 阐述其相关的研究进展, 以期更好地理解环境条件诱导细胞发生适应性突变的过程。     

The SOS response increases bacterial fitness,but not evolvability,under a sublethal dose of antibiotic

Exposure to antibiotics induces the expression of mutagenic bacterial stress–response pathways, but the evolutionary benefits of these responses remain unclear. One possibility is that stress–response pathways provide a short-term advantage by protecting bacteria against the toxic effects of antibiotics. Second, it is possible that stress-induced mutagenesis provides a long-term advantage by accelerating the evolution of resistance. Here, we directly measure the contribution of the Pseudomonas aeruginosa SOS pathway to bacterial fitness and evolvability in the presence of sublethal doses of ciprofloxacin. Using short-term competition experiments, we demonstrate that the SOS pathway increases competitive fitness in the presence of ciprofloxacin. Continued exposure to ciprofloxacin results in the rapid evolution of increased fitness and antibiotic resistance, but we find no evidence that SOS-induced mutagenesis accelerates the rate of adaptation to ciprofloxacin during a 200 generation selection experiment. Intriguingly, we find that the expression of the SOS pathway decreases during adaptation to ciprofloxacin, and this helps to explain why this pathway does not increase long-term evolvability. Furthermore, we argue that the SOS pathway fails to accelerate adaptation to ciprofloxacin because the modest increase in the mutation rate associated with SOS mutagenesis is offset by a decrease in the effective strength of selection for increased resistance at a population level. Our findings suggest that the primary evolutionary benefit of the SOS response is to increase bacterial competitive ability, and that stress-induced mutagenesis is an unwanted side effect, and not a selected attribute, of this pathway.     

Fluence-Response Dynamics of the UV-Induced SOS Response in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Bacteria in nature often suffer sudden stresses, such as ultraviolet (UV) irradiation, nutrient deprivation, and chemotoxins that would cause DNA damage and DNA replication failure, which in turn trigger SOS response. According to the strength and duration of the stress, the SOS system not only repairs DNA damage but also induces mutagenesis, so as to adapt to the changing environment. The key proteins in charge of mutagenesis are UmuD and UmuD’. In this paper, we quantitatively measure the growth rate and cellular levels of proteins UmuD and UmuD’ in Escherichia coli after various fluences of UV irradiation. To compare with the experimental observations, an ordinary differential equation model is built to describe the SOS response. Considering the fact that the DNA lesions affect cellular protein production and replication origination, the simulation results fit well with the experimental data. Our results show how the fluence of UV irradiation determines the dynamics of the inducing signal and the mutation frequency of the cell. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

SOS-inducible DNA polymerases and adaptive mutagenesis

Stability of genomes of living organisms is maintained by various mechanisms that ensure high fidelity of DNA replication. However, cells can reversibly enhance the level of replication errors in response to external factors. As mutable states are potentially involved in carcinogenesis, aging, and resistance for pathogenic agents, the existence of these states is of great importance for human health. A well-known system of inducible mutation is SOS response, whose key component is replication of damaged DNA regions. Inducible mutation implies a contribution of SOS response to the adaptation of a bacterial population to adverse environments. There is ample evidence indicating the primary role of SOS response genes in the phenomenon of adaptive mutation. The involvement of the SOS system in adaptive mutagenesis is discussed.     

SOS-Inducible DNA Polymerases and Adaptive Mutagenesis

Stability of genomes of living organisms is maintained by various mechanisms that ensure high fidelity of DNA replication. However, cells can reversibly enhance the level of replication errors in response to external factors. As mutable states are potentially involved in carcinogenesis, aging, and resistance for pathogenic agents, the existence of these states is of great importance for human health. A well-known system of inducible mutation is SOS response, whose key component is replication of damaged DNA regions. Inducible mutation implies a contribution of SOS response to the adaptation of a bacterial population to adverse environments. There is ample evidence indicating the primary role of SOS response genes in the phenomenon of adaptive mutation. The involvement of the SOS system in adaptive mutagenesis is discussed.     

Overproduction of the beta subunit of DNA polymerase III holoenzyme reduces UV mutagenesis in Escherichia coli.

Overproduction of the beta subunit of DNA polymerase III holoenzyme caused a 5- to 10-fold reduction of UV mutagenesis along with a slight increase in sensitivity to UV light in Escherichia coli. The same effects were observed in excision-deficient cells, excluding the possibility that they were mediated via changes in excision repair. In contrast, overproduction of the alpha subunit of the polymerase did not influence either UV mutagenesis or UV sensitivity. The presence of the mutagenesis proteins MucA and MucB expressed from a plasmid alleviated the effect of overproduced beta on UV mutagenesis. We have previously suggested that DNA polymerase III holoenzyme can exist in two forms: beta-rich form unable to bypass UV lesions and a beta-poor form capable of bypassing UV lesions (O. Shavitt and Z. Livneh, J. Biol. Chem. 264:11275-11281, 1989). The beta-poor form may be related to an SOS form of DNA polymerase III designed to perform translesion polymerization under SOS conditions and thereby generate mutations. On the basis of this model, we propose that the overproduced beta subunit affects the relative abundance of the regular replicative beta-rich polymerase and the SOS bypass-proficient polymerase by sequestering the polymerase molecules to the beta-rich form and blocking the SOS form.     

Roles of E. coli double-strand-break-repair proteins in stress-induced mutation

Special mechanisms of mutation are induced during growth-limiting stress and can generate adaptive mutations that permit growth. These mechanisms may provide improved models for mutagenesis in antibiotic resistance, evolution of pathogens, cancer progression and chemotherapy resistance. Stress-induced reversion of an Escherichia coli episomal lac frameshift allele specifically requires DNA double-strand-break-repair (DSBR) proteins, the SOS DNA-damage response and its error-prone DNA polymerase, DinB. We distinguished two possible roles for the DSBR proteins. Each might act solely upstream of SOS, to create single-strand DNA that induces SOS. This could upregulate DinB and enhance mutation globally. Or any or all of them might function other than or in addition to SOS promotion, for example, directly in error-prone DSBR. We report that in cells with SOS genes derepressed constitutively, RecA, RuvA, RuvB, RuvC, RecF, and TraI remain required for stress-induced mutation, demonstrating that these proteins act other than via SOS induction. RecA and TraI also act by promoting SOS. These and additional results with hyper-mutating recD and recG mutants support roles for these proteins via error-prone DSBR. Such mechanisms could localize stress-induced mutagenesis to small genomic regions, a potentially important strategy for adaptive evolution, both for reducing additional deleterious mutations in rare adaptive mutants and for concerted evolution of genes.     

Weigle reactivation and mutagenesis of bacteriophage lambda in lexA(Def) mutants of E. coli K12

Summary The SOS response in UV-irradiated bacteria enhances the survival and mutagenesis of infecting damaged bacteriophage . In a lexA(Def) strain, SOS bacterial genes are fully derepressed by an inactivating mutation in the LexA repressor gene. We tested several lexA(Def) derivative strains for their capacity to constitutively promote high survival and mutagenesis of irradiated . We showed that UV irradiation of the lexA(Def) host bacteria is still necessary for optimal efficiency of both these SOS functions, which are dependent on the umuC gene product and an activated form of RecA protein.     

Potent induction of the adaptive response by a weak mutagen, methyl iodide, in Escherichia coli

Methyl iodide (MeI), a weakly mutagenic and highly chemoselective chemicals, was tested for its abilities to induced the adaptive and SOS responses in E. coli CSH26/pMCP1000 (alkA′-lacZ′) and CSH26/psK1002 (umuC′-lacZ′). MeI induced the adaptive response effectively but gave a very weak SOS response. Its potent ability in inducing the adaptive response was also demonstrated by adaptation to both the mutagenic and killing effects of N-methyl-N-nitrosourea (MNU) in E. coli WP2 cells. Simultaneous treatment with MeI in a non-growth medium slightly increased the mutagenicity of MNU, probably as a result of depletion of the repair enzyme, O⁶-methylguanine-DNA methyltransferase, which is constitutively present in the cells. As MeI itself proved to be only weakly mutagenic, a small part of the adaptive response which we have observed may involve indirect methylation of the repair enzyme by methyl transfer from MeI-induced O⁶-methylguanine residues in DNA. But the extent of the induced adaptive response seems to be much higher than would be expected from the observed weak mutagenicity of MeI. It is therefore suggested that the mechanism of induction of the adaptive response may involve direct methylation of the O⁶-methylguanine-DNA methyltransferase itself.     

Genetic analysis of mutagenesis in aging Escherichia coli colonies

Bacteria live in unstructured and structured environments, experiencing feast and famine lifestyles. Bacterial colonies can be viewed as model structured environments. SOS induction and mutagenesis have been observed in aging Escherichia coli colonies, in the absence of exogenous sources of DNA damage. This cAMP-dependent mutagenesis occurring in Resting Organisms in a Structured Environment (ROSE) is unaffected by a umuC mutation and therefore differs from both targeted UV mutagenesis and recA730 (SOS constitutive) untargeted mutagenesis. As a recB mutation has only a minor effect on ROSE mutagenesis it also differs from both adaptive reversion of the lacI33 allele and from iSDR (inducible Stable DNA Replication) mutagenesis. Besides its recA and lexA dependence, ROSE mutagenesis is also uvrB and polA dependent. These genetic requirements are reminiscent of the untargeted mutagenesis in λ phage observed when unirradiated λ infects UV-irradiated E. coli. These mutations, which are not observed in aging liquid cultures, accumulate linearly with the age of the colonies. ROSE mutagenesis might offer a good model for bacterial mutagenesis in structured environments such as biofilms and for mutagenesis of quiescent eukaryotic cells.     

Substitution of UmuD' for UmuD does not affect SOS mutagenesis

In order to study the role of UmuDC proteins in SOS mutagenesis, we have constructed new Escherichia coli K-12 strains to avoid i) over-production of Umu proteins, ii) the formation of unwanted mixed plasmid and chromosomal Umu proteins upon complementation. We inserted a mini-kan transposon into the umuD gene carried on a plasmid. The insertion at codon 24 ends protein translation and has a polar effect on the expression of the downstream umuC gene. We transferred umuD24 mutation to the E coli chromosome. In parallel, we subcloned umuD+ umuC+ or umuD' umuC+ genes into pSC101, a low copy number plasmid. In a host with the chromosomal umuD24 mutation, plasmids umuD+ umuC+ or umuD' umuC+ produced elevated resistance to UV light and increased SOS mutagenesis related to a gene dosage of about 3. UV mutagenesis was as high in umuD' umuC+ hosts devoid of UmuD+ protein as in umuD+ umuC+ hosts. UmuD' protein, the maturated form of UmuD, can substitute for UmuD in SOS mutagenesis.