Mutagenic DNA repair in Escherichia coli. XXI. A stable SOS-inducing signal persisting after excision repair of ultraviolet damage.

Mutations to streptomycin resistance induced by ultraviolet light in Escherichia coli can lose their susceptibility to photoreversing light during excision repair and in the absence of chromosomal replication and protein synthesis, i.e., under conditions where SOS induction cannot occur. Using fusions of lac with sulA and umuC we have shown that after excision of UV damage in the presence of chloramphenicol there is a persisting, relatively stable signal capable of inducing SOS genes when protein sysnthesis is subsequently permitted. The persisting signal is formed roughly in proportion to the square of the UV dose and is about 30% photoreversible. It is suggested that the persisting SOS-inducing signal comprises a UV photoproduct (the target lesion) opposite a gap in the opposing DNA strand, and is formed by excision of one (the ancillary lesion) of a pair of closely opposed photoproducts. Calculations suggest that as few as two or three such configurations in a cell can lead to induction a sulA when protein synthesis is permitted. It is not clear whether these configurations can directly induce the SOS system because of their region of single-stranded DNA or whether the ultimate SOS-inducing signal is a more extensive single-stranded region formed when such configurations encounter a replication fork. Photoproduct/gap configurations have been previously suggested to be potentially mutagenic. UV-induced mutations to streptomycin resistance are mostly at A:T sites and are not photoreversible in fully SOS-induced bacteria in the absence of excision repair, indicating that they are not targeted at cyclobutane-type pyrimidine dimers. In SOS-induced excision-proficient bacteria there is about 39% photoreversibility which is rapidly lost after UV. This photoreversibility is attributed to many ancillary lesions being cyclobutane-type pyrimidine dimers which are excised leading to the exposure of target lesions on the opposing strand which, at these particular sites, are mostly non-photoreversible photoproducts.     

Mutagenic DNA repair in Escherichia coli

Summary The photoreversibility of UV-induced mutations to Trp⁺ in strain Escherichia coli WP2 uvrA trp (unable to excise pyrimidine dimers) was lost at different rates during incubation in different media. In Casamino acids medium after a short initial lag, photoreversibility was lost over about one generation time; in minimal medium with tryptophan, photoreversibility persisted for more than two generations; in Casamino acids medium with pantoyl lactone photoreversibility was lost extremely slowly. The rate of loss of photoreversibility was unaffected by UV dose in either Casamino acids medium or in minimal medium. The same eventual number of induced mutants was obtained when cells were incubated for two generations in any of the three media before being transferred to selective plates supplemented with Casamino acids. Thus in each the proportion of cells capable of giving rise to a mutant was the same and only the rate at which these cells did so during post-irradiation growth varied, suggesting that there might be a specific fraction of pyrimidine dimers at a given site capable of initiating a mutagenic repair event, and that the size of this fraction is dose dependent. Segregation experiments have shown that error-prone repair appears to occur once only and is not repeated in subsequent replication cycles, in contrast to (presumed error-free) recombination repair.The results are discussed in the light of current models of UV mutagenesis.     

Translesion synthesis is the main component of SOS repair in bacteriophage lambda DNA.

Agents that interfere with DNA replication in Escherichia coli induce physiological adaptations that increase the probability of survival after DNA damage and the frequency of mutants among the survivors (the SOS response). Such agents also increase the survival rate and mutation frequency of irradiated bacteriophage after infection of treated bacteria, a phenomenon known as Weigle reactivation. In UV-irradiated single-stranded DNA phage, Weigle reactivation is thought to occur via induced, error-prone replication through template lesions (translesion synthesis [P. Caillet-Fauquet, M: Defais, and M. Radman, J. Mol. Biol. 117:95-112, 1977]). Weigle reactivation occurs with higher efficiency in double-stranded DNA phages such as lambda, and we therefore asked if another process, recombination between partially replicated daughter molecules, plays a major role in this case. To distinguish between translesion synthesis and recombinational repair, we studied the early replication of UV-irradiated bacteriophage lambda in SOS-induced and uninduced bacteria. To avoid complications arising from excision of UV lesions, we used bacterial uvrA mutants, in which such excision does not occur. Our evidence suggests that translesion synthesis is the primary component of Weigle reactivation of lambda phage in the absence of excision repair. The greater efficiency in Weigle reactivation of double-stranded DNA phage could thus be attributed to some inducible excision repair unable to occur on single-stranded DNA. In addition, after irradiation, lambda phage replication seems to switch prematurely from the theta mode to the rolling circle mode.     

DNA damage induced nucleotide excision repair in Saccharomyces cerevisiae

Nucleotide excision repair (NER) is the most versatile and universal pathway of DNA repair that is capable of repairing virtually any damages other than a double strand break (DSB). This pathway has been shown to be inducible in several systems. However, question of a threshold and the nature of the damage that can signal induction of this pathway remain poorly understood. In this study it has been shown that prior exposure to very low doses of osmium tetroxide enhanced the survival of wild type Saccharomyces cerevisiae when the cells were challenged with UV light. Moreover, it was also found that osmium tetroxide treated rad3 mutants did not show enhanced survival indicating an involvement of nucleotide excision repair in the enhanced survival. To probe this further the actual removal of pyrimidine dimers by the treated and control cells was studied. Osmium tetroxide treated cells removed pyrimidine dimers more efficiently as compared to control cells. This was confirmed by measuring the in vitro repair synthesis in cell free extracts prepared from control and primed cells. It was found that the uptake of active ³²P was significantly higher in the plasmid substrates incubated with extracts of primed cells. This induction is dependent on de novo synthesis of proteins as cycloheximide treatment abrogated this response. The nature of induced repair was found to be essentially error free. Study conclusively shows that NER is an inducible pathway in Saccharomyces cerevisiae and its induction is dependent on exposure to a threshold of a genotoxic stress.     

A new model for SOS-induced mutagenesis: how RecA protein activates DNA polymerase V

In Escherichia coli, cell survival and genomic stability after UV radiation depends on repair mechanisms induced as part of the SOS response to DNA damage. The early phase of the SOS response is mostly dominated by accurate DNA repair, while the later phase is characterized with elevated mutation levels caused by error-prone DNA replication. SOS mutagenesis is largely the result of the action of DNA polymerase V (pol V), which has the ability to insert nucleotides opposite various DNA lesions in a process termed translesion DNA synthesis (TLS). Pol V is a low-fidelity polymerase that is composed of UmuD′₂C and is encoded by the umuDC operon. Pol V is strictly regulated in the cell so as to avoid genomic mutation overload. RecA nucleoprotein filaments (RecA*), formed by RecA binding to single-stranded DNA with ATP, are essential for pol V-catalyzed TLS both in vivo and in vitro. This review focuses on recent studies addressing the protein composition of active DNA polymerase V, and the role of RecA protein in activating this enzyme. Based on unforeseen properties of RecA*, we describe a new model for pol V-catalyzed SOS-induced mutagenesis.     

Mutagenic DNA repair in Escherichia coli. XIV. Influence of two DNA polymerase III mutator alleles on spontaneous and UV mutagenesis

Summary We introduced the dnaE486 and polC74 mutations (which are associated with decreased DNA polymerase III replication fidelity) into excision defective Escherichia coli strains with varying SOS responses. These mutations increased the UV-induced frequency of base pair substitution mutations in all strains tested, except recA430 and umuC122 derivatives. This UV mutator effect therefore requires expression of the SOS error-prone repair system. In recA441 lexA51 strains where the SOS system is constitutively expressed, the UV mutator effect of the dnaE alleles was similar in relative terms (though greater in absolute terms). Since these dnaE alleles decrease rather than increase survival after UV it is argued that they promote a burst of untargeted mutations close to UV photoproducts (hitch-hiking mutations) rather than increase the number of translesion synthesis events. The fact that there was no UV mutagenesis in dnaE486 umuC122 or polC74 umuC122 strains indicates that infidelity associated with these dnaE alleles did not of itself enable translesion synthesis to occur. The spontaneous mutator effect conferred by dnaE486 and polC74 was not affected by umuC122 or recA430 indicating that it is not dependent upon error-prone repair ability. In recA441 lexA51 bacteria, where SOS error-prone repair is constitutively induced, the mutator effect of dnaE486 was greater and was largely blocked by umuC122. It is suggested that spontaneously occurring cryptic lesions that are themselves unable to induce the SOS system are subject to translesion synthesis under these conditions and trigger a burst of hitch-hiking mutations that are therefore effectively umuC dependent.     

The relative rate of synthesis and levels of single-stranded DNA binding protein during induction of SOS repair in Escherichia coli

Summary Induction of the SOS response in Escherichia coli results in an increase in the relative rate of synthesis of single-stranded DNA binding protein (SSB). In contrast to RecA protein, this increase is slow and does not lead to higher SSB levels. The significance of ssb induction to SOS repair is discussed.     

In UV-irradiated Escherichia coli PQ35 overproducing the RecA protein, expression of the sfiA gene and dimer excision are alleviated

Summary Escherichia coli PQ 35 cells carrying thesfiA-:lacZ operon fusion were transformed either with a multicopy plasmid containing therecA gene (pHSG262recA) or with a multicopy plasmid alone (pHSG262). Both transformants were UV irradiated. Then induction of thesfiA gene and dimer excision were followed. Amplification of therecA gene partly inhibited bothsfiA gene induction and dimer excision. The following interpretation of this phenomenon is proposed. When the RecA protein is in bundance, pyrimidine dimers are quickly masked by it. The masked dimers are less efficiently distinguished by excision nuclease and do not provide the induction signal. Due to this, induction of thesfiA gene as well as dimer excision are inhibited early.     

Analysis of the SOS inducing signal in Bacillus subtilis using Escherichia coli LexA as a probe.

We analyzed the Bacillus subtilis SOS response using Escherichia coli LexA protein as a probe to measure the kinetics of SOS activation and DNA repair in wild-type and DNA repair-deficient strains. By examining the effects of DNA-damaging agents that produce the SOS inducing signal in E. coli by three distinct pathways, we obtained evidence that the nature of the SOS inducing signal has been conserved in B. subtilis. In particular, we used the B. subtilis DNA polymerase III inhibitor, 6-(p-hydroxyphenylazo)-uracil, to show that DNA replication is required to generate the SOS inducing signal following UV irradiation. We also present evidence that single-stranded gaps, generated by excision repair, serve as part of the UV inducing signal. By assaying the SOS response in B. subtilis dinA, dinB, and dinC mutants, we identified distinct deficiencies in SOS activation and DNA repair that suggest roles for the corresponding gene products in the SOS response.     

The role of thiol redox systems in the response of <Emphasis Type="Italic">Escherichia coli</Emphasis> to far-UV irradiation

Escherichia coli mutants deficient in glutathione (gshA), glutaredoxin (grxA), thioredoxin (trxA), and thioredoxin reductase (trxB) synthesis were studied with respect to their resistance to far-UV (UV₂₅₄) exposure. The trxA, trxB, and grxA mutants subjected to a short-term UV exposure were found to be more resistant to UV irradiation than the parent cells. Under the same conditions, the trxA and trxB mutants demonstrated a high level of induction of the sulA gene, a component of the SOS regulon. The mutagenic effect of long-term UV exposure of all the mutants with redox deficiencies was more pronounced than in the case of the parent strain, and the trxA and trxB mutants were found to be the least viable microorganisms. Pretreatment of the cells with low concentrations of the thiol-oxidizing agent diamide enhanced the sulA gene expression; however, high concentrations of diamide inhibited sulA expression. The data obtained indicate that the thiol redox systems of E. coli are involved in its response to far-UV irradiation.     

Efficient UV stimulation of yeast integrative transformation requires damage on both plasmid strands

The nature of UV-induced pre-recombinational structures was studied using transformation of Saccharomyces cerevisiae cells with non-replicative plasmids. Transformation by double-stranded plasmids irradiated with UV was stimulated up to 50-fold, and both plasmid integration and conversion of the mutated chromosomal selective gene were found to be equally increased. The stimulation observed with such totally irradiated plasmids was not found with plasmids bearing lesions in only one strand. This effect is attributed to the formation by excision repair of recombinogenic structures consisting of a pyrimidine dimer opposite a gap. When single-stranded integrative plasmids were irradiated, their transforming potential was decreased but the proportion of transformants that arose by gene conversion, rather than by plasmid integration, was increased from 8% to 49% as a function of the UV dose. Possible reasons why single-strand UV lesions favour gene conversion are discussed.     

60 years of SOS repair

This review integrates 60 years of research on SOS repair and SOS mutagenesis in prokaryotes and eukaryotes, from Jean Weigle’s experiment in 1953 (mutagenesis of lambda bacteriophage in UV-irradiated bacteria) to the latest achievements in studying SOS mutagenesis on all living organisms, i.e., Eukarya, Archaea and Bacteria. A key role in establishing of a biochemical basis for SOS mutagenesis belongs to the finding in 1998–1999 that specific error-prone DNA polymerases (PolV and others) catalyzed translesion synthesis on damaged DNA. This review focuses on recent studies that address new models for SOS-induced mutagenesis in Escherichia coli and Homo sapiens cells.     

The Role of Pyrimidine Dimers as Premutagenic Lesions: A Study of Targeted VS. Untargeted Mutagenesis in the lacI Gene of ESCHERICHIA COLI

We have employed conjugal transfer of an F' lac episome to examine targeted and untargeted mutagenesis in the lacI gene of Escherichia coli and to determine the relative importance of pyrimidine dimers as premutational UV lesions compared to (6-4) photoproducts that also may have a mutational role. This conjugal system allowed us to assess the premutagenic role of UV lesions independently from any role as inducers of SOS functions. F' DNA was transferred to an SOS-induced recipient strain from: unirradiated donor cells, UV-treated donor cells or donor cells that were irradiated and then exposed to photoreactivating light. The results indicate that SOS-related, untargeted events may account for as much as one-third of the nonsense mutations (i.e., base substitutions) recovered after undamaged F' DNA is transferred to UV-irradiated recipients. When the donor strain also is irradiated, in excess of 90% of the mutations detected following conjugation appear to be targeted. Photoreactivation of the UV-treated donors cells, prior to F' transfer to the SOS-induced recipient strain, demonstrated that in this experimental system virtually all recovered UV-induced mutations are targeted by photoreactivable lesions. We presume that these lesions are pyrimidine dimers because (6-4) photoproducts are not photoreactivable.     

Mechanism of replication of ultraviolet-irradiated single-stranded DNA by DNA polymerase III holoenzyme of Escherichia coli. Implications for SOS mutagenesis

Replication of UV-irradiated oligodeoxynucleotide-primed single-stranded phi X174 DNA with Escherichia coli DNA polymerase III holoenzyme in the presence of single-stranded DNA-binding protein was investigated. The extent of initiation of replication on the primed single-stranded DNA was not altered by the presence of UV-induced lesions in the DNA. The elongation step exhibited similar kinetics when either unirradiated or UV-irradiated templates were used. Inhibition of the 3'----5' proofreading exonucleolytic activity of the polymerase by dGMP or by a mutD mutation did not increase bypass of pyrimidine photodimers, and neither did purified RecA protein influence the extent of photodimer bypass as judged by the fraction of full length DNA synthesized. Single-stranded DNA-binding protein stimulated bypass since in its absence the fraction of full length DNA decreased 5-fold. Termination of replication at putative pyrimidine dimers involved dissociation of the polymerase from the DNA, which could then reinitiate replication at other available primer templates. Based on these observations a model for SOS-induced UV mutagenesis is proposed.     

DNA repair in Bacillus subtilis. I. The presence of an inducible system.

Summary Following UV irradiation of Bacillus subtilis there is a coordinate induction of: 1) a new protein, 2) a W-reactivation system, 3) a DNA modification system, and 4) prophages. These functions are induced following UV irradiation of repair proficient bacteria and mutants deficient in excision repair (uvr-1) and DNA polymerase I activity (polA5). However, they are not induced, or are impaired in their ability to be induced in bacteria containing the recA1 and the recG13 mutations. This inducible system is compared to the SOS system observed in E. coli.     

Effect of a lexA41(Ts) mutation on DNA repair in recA(Def) derivatives of Escherichia coli K-12

Summary Derivatives of Escherichia coli K-12 carrying a deletion of the recA gene survive exposure to UV (254 nm) better if they also contain the lexA41 mutation which codes for a labile LexA protein. This effect of the lexA41 mutation is not observed in comparable strains carrying a uvr A6 mutation. Using two independent methods to detect pyrimidine dimers we found that UV irradiated RecA deficient cells removed dimers from their DNA more rapidly if they contained the lexA41 mutation than if the contained the wild-type lexA gene. Our results are consistent with the idea that a relatively high level of UvrABC incision nuclease resulting from inefficient repression of the corresponding genes by the labile LexA41 protein facilitates excision of pyrimidine dimers from the DNA of UV irradiated cells.     

Mutagenic DNA repair in Escherichia coli. XIX. On the roles of RecA protein in ultraviolet light mutagenesis

An experimental system was used in which His+ mutations induced by ultraviolet light (UV) arise from non-photo-reversible photoproducts whereas lethality is largely determined by photoreversible photoproducts. By exposing a strain with a deletion through recA to light immediately after UV, it was possible to examine mutagenesis under conditions where survival was not significantly different from 100%. No UV mutagenesis was seen in the absence of RecA protein even though the rest of the SOS system was fully expressed due to the presence of a defective LexA repressor and the active carboxy-terminal fragment of UmuD was present as a result of an engineered plasmid-borne gene. We conclude that RecA protein has a third essential function if UV mutagenesis is to be detected in excision-deficient-bacteria. Another experiment showed that in exerting this function RecA protein does not need activation by pyrimidine dimers elsewhere on the genome, in contrast to its protein-cleavage mediation functions with LexA and UmuD proteins. RecA1730 protein blocked UV mutagenesis unless delayed photoreversal was given showing that the third function of RecA protein is not in the misincorporation step. It is therefore most likely to be in the bypass step where UmuD' and UmuC are postulated to act, although the possibility cannot be excluded that RecA protein is required for some other survival function distinct from translesion synthesis.     

Repair and recombination of nonreplicating UV-irradiated phage DNA in E. coli III. Enhancement of excision repair in UV-treated bacteria

Summary The question of whether induction of the SOS response in Escherichia coli increases the efficiency of excision repair was addressed by measuring repair of UV-damaged nonreplicating lambda phage DNA in previously irradiated bacteria. Prior UV irradiation of lex ⁺ bacteria enhanced both the rate of regeneration of infective phage DNA (about 10-fold) and the rate of cyclobutane dimer removal early in repressed infections. Indirect induction of SOS-regulated repair activities by the nonreplicating irradiated phage DNA itself seemed negligible. Prior bacterial irradiation reduced the frequency of recombination (loss of a tandem chromosomal duplication) of nonreplicating UV-irradiated DNA. In this respect UV-stimulated recombination of nonreplicating DNA differs from RecF-dependent recombination processes that are stimulated by increased SOS expression.Surprisingly, prior UV irradiation of lexA3 bacteria caused a small but reproducible increase in the regeneration of infective phage DNA.