TheisfA mutation inhibits mutator activity and processing of UmuD protein inEscherichia coli recA730 strains

Further studies on theisfA mutation responsible for anti-SOS and antimutagenic activities inEscherichia coli are described. We have previously shown that theisfA mutation inhibits mutagenesis and other SOS-dependent phenomena, possibly by interfering with RecA coprotease activity. TheisfA mutation has now been demonstrated also to suppress mutator activity inE. coli recA730 andrecA730 lexA51(Def) strains that constitutively express RecA coprotease activity. We further show that the antimutator activity of theisfA mutation is related to inhibition of RecA coprotease-dependent processing of UmuD. Expression of UmuD' from plasmid pGW2122 efficiently restores UV-induced mutagenesis in therecA730 isfA strain and partially restores its mutator activity. On the other hand, overproduction of UmuD'C proteins from pGW2123 plasmid markedly enhances UV sensitivity with no restoration of mutability.     

A new mutation inEscherichia coli K12,isfA,which is responsible for inhibition of SOS functions

A new mutation inEscherichia coli K12,isfA, is described, which causes inhibition of SOS functions. The mutation, discovered in a ΔpolA ⁺ mutant, is responsible for inhibition of several phenomena related to the SOS response inpolA ⁺ strains: UV- and methyl methanesulfonate-induced mutagenesis, resumption of DNA replication in UV-irradiated cells, cell filamentation, prophage induction and increase in UV sensitivity. TheisfA mutation also significantly reduces UV-induced expression of β-galactosidase fromrecA::lacZ andumuC′::lacZ fusions. The results suggest that theisfA gene product may affect RecA^* coprotease activity and may be involved in the regulation of the termination of the SOS response after completion of DNA repair. TheisfA mutation was localized at 85 min on theE. coli chromosome, and preliminary experiments suggest that it may be dominant to the wild-type allele.     

A new mutation inEscherichia coli K12,isfA, which is responsible for inhibition of SOS functions

A new mutation inEscherichia coli K12,isfA, is described, which causes inhibition of SOS functions. The mutation, discovered in a ΔpolA ⁺ mutant, is responsible for inhibition of several phenomena related to the SOS response inpolA ⁺ strains: UV- and methyl methanesulfonate-induced mutagenesis, resumption of DNA replication in UV-irradiated cells, cell filamentation, prophage induction and increase in UV sensitivity. TheisfA mutation also significantly reduces UV-induced expression of β-galactosidase fromrecA::lacZ andumuC′::lacZ fusions. The results suggest that theisfA gene product may affect RecA^* coprotease activity and may be involved in the regulation of the termination of the SOS response after completion of DNA repair. TheisfA mutation was localized at 85 min on theE. coli chromosome, and preliminary experiments suggest that it may be dominant to the wild-type allele.     

RecA,Tus protein and constitutive stable DNA replication inEscherichia coli rnhA mutants

Constitutive stable DNA replication (cSDR), which uniquely occurs inEscherichia coli rnhA mutants deficient in ribonuclease HI activity, requires RecA function. TherecA428 mutation, which inactivates the recombinase activity but imparts a constitutive coprotease activity, blocks cSDR inrnhA mutants. The result indicates that the recombinase activity of RecA, which promotes homologous pairing and strand exchange, is essential for cSDR. Despite the requirement for RecA recombinase activity, mutations inrecB, recD, recJ, ruvA andruvC neither inhibit nor stimulate cSDR. It was proposed that the property of RecA essential for homologous pairing and strand exchange is uniquely required for initiation of cSDR inrnhA mutants without involving the homologous recombination process. The possibility that RecA protein is necessary to counteract the action of Tus protein, a contra-helicase which stalls replication forks in theter region of the chromosome, was ruled out because introduction of thetus : :kan mutation, which inactivates Tus protein, did not alleviate the RecA requirement for cSDR.     

Nature of the SOS mutator activity: genetic characterization of untargeted mutagenesis in Escherichia coli

Summary In Escherichia coli, induction of the SOS functions by UV irradiation or by mutation in the recA gene promotes an SOS mutator activity which generates mutations in undamaged DNA. Activation of RecA protein by the recA730 mutation increases the level of spontaneous mutation in the bacterial DNA. The number of recA730-induced mutations is greatly increased in mismatch repair deficient strains in which replication errors are not corrected. This suggests that the majority of recA730-induced mutations (90%) arise through correctable, i.e. non-targeted, replication errors. This recA730 mutator effect is suppressed by a mutation in the umuC gene. We also found that dam recA730 double mutants are unstable, segregating clones that have lost the dam or the recA mutations or that have acquired a new mutation, probably in one of the genes involved in mismatch repair. We suggest that the genetic instability of the dam recA730 mutants is provoked by the high level of replication errors induced by the recA730 mutation, generating killing by coincident mismatch repair on the two unmethylated DNA strands. The recA730 mutation increases spontaneous mutagenesis of phage poorly. UV irradiation of recA730 host bacteria increases phage untargeted mutagenesis to the level observed in UV-irradiated recA ⁺ strains. This UV-induced mutator effect in recA730 mutants is not suppressed by a umuC mutation. Therefore UV and the recA730 mutation seem to induce different SOS mutator activities, both generating untargeted mutations.     

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.     

RecA, Tus protein and constitutive stable DNA replication inEscherichia coli rnhA mutants

Constitutive stable DNA replication (cSDR), which uniquely occurs inEscherichia coli rnhA mutants deficient in ribonuclease HI activity, requires RecA function. TherecA428 mutation, which inactivates the recombinase activity but imparts a constitutive coprotease activity, blocks cSDR inrnhA mutants. The result indicates that the recombinase activity of RecA, which promotes homologous pairing and strand exchange, is essential for cSDR. Despite the requirement for RecA recombinase activity, mutations inrecB, recD, recJ, ruvA andruvC neither inhibit nor stimulate cSDR. It was proposed that the property of RecA essential for homologous pairing and strand exchange is uniquely required for initiation of cSDR inrnhA mutants without involving the homologous recombination process. The possibility that RecA protein is necessary to counteract the action of Tus protein, a contra-helicase which stalls replication forks in theter region of the chromosome, was ruled out because introduction of thetus : :kan mutation, which inactivates Tus protein, did not alleviate the RecA requirement for cSDR.     

Genetic Requirements for High Constitutive SOS Expression in recA730 Mutants of Escherichia coli

The RecA protein in its functional state is in complex with single-stranded DNA, i.e., in the form of a RecA filament. In SOS induction, the RecA filament functions as a coprotease, enabling the autodigestion of the LexA repressor. The RecA filament can be formed by different mechanisms, but all of them require three enzymatic activities essential for the processing of DNA double-stranded ends. These are helicase, 5′–3′ exonuclease, and RecA loading onto single-stranded DNA (ssDNA). In some mutants, the SOS response can be expressed constitutively during the process of normal DNA metabolism. The RecA730 mutant protein is able to form the RecA filament without the help of RecBCD and RecFOR mediators since it better competes with the single-strand binding (SSB) protein for ssDNA. As a consequence, the recA730 mutants show high constitutive SOS expression. In the study described in this paper, we studied the genetic requirements for constitutive SOS expression in recA730 mutants. Using a β-galactosidase assay, we showed that the constitutive SOS response in recA730 mutants exhibits different requirements in different backgrounds. In a wild-type background, the constitutive SOS response is partially dependent on RecBCD function. In a recB1080 background (the recB1080 mutation retains only helicase), constitutive SOS expression is partially dependent on RecBCD helicase function and is strongly dependent on RecJ nuclease. Finally, in a recB-null background, the constitutive SOS expression of the recA730 mutant is dependent on the RecJ nuclease. Our results emphasize the importance of the 5′–3′ exonuclease for high constitutive SOS expression in recA730 mutants and show that RecBCD function can further enhance the excellent intrinsic abilities of the RecA730 protein in vivo.     

Genetic requirements and mutational specificity of the Escherichia coli SOS mutator activity.

To better understand the mechanisms of SOS mutagenesis in the bacterium Escherichia coli, we have undertaken a genetic analysis of the SOS mutator activity. The SOS mutator activity results from constitutive expression of the SOS system in strains carrying a constitutively activated RecA protein (RecA730). We show that the SOS mutator activity is not enhanced in strains containing deficiencies in the uvrABC nucleotide excision-repair system or the xth and nfo base excision-repair systems. Further, recA730-induced errors are shown to be corrected by the MutHLS-dependent mismatch-repair system as efficiently as the corresponding errors in the rec+ background. These results suggest that the SOS mutator activity does not reflect mutagenesis at so-called cryptic lesions but instead represents an amplification of normally occurring DNA polymerase errors. Analysis of the base-pair-substitution mutations induced by recA730 in a mismatch repair-deficient background shows that both transition and transversion errors are amplified, although the effect is much larger for transversions than for transitions. Analysis of the mutator effect in various dnaE strains, including dnaE antimutators, as well as in proofreading-deficient dnaQ (mutD) strains suggests that in recA730 strains, two types of replication errors occur in parallel: (i) normal replication errors that are subject to both exonucleolytic proofreading and dnaE antimutator effects and (ii) recA730-specific errors that are not susceptible to either proofreading or dnaE antimutator effects. The combined data are consistent with a model suggesting that in recA730 cells error-prone replication complexes are assembled at sites where DNA polymerization is temporarily stalled, most likely when a normal polymerase insertion error has created a poorly extendable terminal mismatch. The modified complex forces extension of the mismatch largely at the exclusion of proofreading and polymerase dissociation pathways. SOS mutagenesis targeted at replication-blocking DNA lesions likely proceeds in the same manner.     

The appearance of the UmuD'C protein complex in Escherichia coli switches repair from homologous recombination to SOS mutagenesis

The process of SOS mutagenesis in Escherichia coli requires (i) the replisome enzymes, (ii) RecA protein, and (iii) the formation of the UmuD'C protein complex which appears to help the replisome to resume DNA synthesis across a lesion. We found that the UmuD'C complex is an antagonist of RecA-mediated recombination. Homologous recombination in an Hfr x F^- cross decreased as a function of the UmuD'C cell concentration; this effect was challenged by increasing RecA concentration. Recombination of a u.v.-damaged F-lac with the lac gene of an F^- recipient was reduced by increasing the UmuD'C concentration while lac mutagenesis increased, showing an inverse relationship between recombination and SOS mutagenesis. We explain our data with the following model. The kinetics of appearance of the UmuD'C complex after DNA damage is slow, reaching a maximum after an hour. Within that period, excision and recombinational repair have had time to occur. When the UmuD'C concentration relative to the number of residual RecA filaments, not resolved by recombinational repair, becomes high enough, UmuD'C proteins provide a processive factor for the replisome to help replication bypass and repel the standing RecA filament. Thus, at a high enough concentration, the UmuD'C complex will switch repair from recombination to SOS mutagenesis.     

Suppression of the E. coli SOS response by dNTP pool changes

The Escherichia coli SOS system is a well-established model for the cellular response to DNA damage. Control of SOS depends largely on the RecA protein. When RecA is activated by single-stranded DNA in the presence of a nucleotide triphosphate cofactor, it mediates cleavage of the LexA repressor, leading to expression of the 30⁺-member SOS regulon. RecA activation generally requires the introduction of DNA damage. However, certain recA mutants, like recA730, bypass this requirement and display constitutive SOS expression as well as a spontaneous (SOS) mutator effect. Presently, we investigated the possible interaction between SOS and the cellular deoxynucleoside triphosphate (dNTP) pools. We found that dNTP pool changes caused by deficiencies in the ndk or dcd genes, encoding nucleoside diphosphate kinase and dCTP deaminase, respectively, had a strongly suppressive effect on constitutive SOS expression in recA730 strains. The suppression of the recA730 mutator effect was alleviated in a lexA-deficient background. Overall, the findings suggest a model in which the dNTP alterations in the ndk and dcd strains interfere with the activation of RecA, thereby preventing LexA cleavage and SOS induction.     

Constitutive expression of the SOS response in recA718 mutants of Escherichia coli requires amplification of RecA718 protein.

In recA718 lexA+ strains of Escherichia coli, induction of the SOS response requires DNA damage. This implies that RecA718 protein, like RecA+ protein, must be converted, by a process initiated by the damage, to an activated form (RecA) to promote cleavage of LexA, the cellular repressor of SOS genes. However, when LexA repressor activity was abolished by a lexA-defective mutation [lexA(Def)], strains carrying the recA718 gene (but not recA+) showed strong SOS mutator activity and were able to undergo stable DNA replication in the absence of DNA damage (two SOS functions known to require RecA activity even when cleavage of LexA is not necessary). lambda lysogens of recA718 lexA(Def) strains exhibited mass induction of prophage, indicative of constitutive ability to cleave lambda repressor. When the cloned recA718 allele was present in a lexA+ strain on a plasmid, SOS mutator activity and beta-galactosidase synthesis under LexA control were expressed in proportion to the plasmid copy number. We conclude that RecA718 is capable of becoming activated without DNA damage for cleavage of LexA and lambda repressor, but only if it is amplified above its base-line level in lexA+ strains. At amplified levels, RecA718 was also constitutively activated for its roles in SOS mutagenesis and stable DNA replication. The nucleotide sequence of recA718 reveals two base substitutions relative to the recA+ sequence. We propose that the first allows the protein to become activated constitutively, whereas the second partially suppresses this capability.     

recA mutations that reduce the constitutive coprotease activity of the RecA1202(Prtc) protein: possible involvement of interfilament association in proteolytic and recombination activities.

Twenty-eight recA mutants, isolated after spontaneous mutagenesis generated by the combined action of RecA1202(Prtc) and UmuDC proteins, were characterized and sequenced. The mutations are intragenic suppressors of the recA1202 allele and were detected by the reduced coprotease activity of the gene product. Twenty distinct mutation sites were found, among which two mutations, recA1620 (V-275-->D) and recA1631 (I-284-->N), were mapped in the C-terminal portion of the interfilament contact region (IFCR) in the RecA crystal. An interaction of this region with the part of the IFCR in which the recA1202 mutation (Q-184-->K) is mapped could occur only intermolecularly. Thus, altered IFCR and the likely resulting change in interfilament association appear to be important aspects of the formation of a constitutively active RecA coprotease. This observation is consistent with the filament-bundle theory (R. M. Story, I. T. Weber, and T. A. Steitz, Nature (London) 335:318-325, 1992). Furthermore, we found that among the 20 suppressor mutations, 3 missense mutations that lead to recombination-defective (Rec-) phenotypes also mapped in the IFCR, suggesting that the IFCR, with its putative function in interfilament association, is required for the recombinase activity of RecA. We propose that RecA-DNA complexes may form bundles analogous to the RecA bundles (lacking DNA) described by Story et al. and that these RecA-DNA bundles play a role in homologous recombination.     

New mutations in and around the L2 disordered loop of the RecA protein modulate recombination and/or coprotease activity.

The RecA protein plays a key role in Escherichia coli recombination and DNA repair. We have created new recA mutants with mutations in the vicinity of the recA430 mutation (Gly-204----Ser) which is known to affect RecA coprotease activity. Mutants carrying recA659 or recA611, located 3 and 7 amino acids downstream of residue 204, respectively, lose all RecA activities, while the mutant carrying recA616, which is located at 12 amino acids from this residue, keeps the coprotease activity but is unable to promote recombination. Complementation experiments show that both mutations recA611 and recA659 are dominant over the wild-type or recA430 allele while recA616 seems to be recessive to recA+ and dominant over recA430. It is suggested that these mutations are located in RecA domains which direct conformational modifications.     

Plasmid pKM101-dependent repair and mutagenesis in Escherichia coli cells with mutations lexB30 tif and zab-53 in the recA gene

Bacterial survival after UV irradiation was increased in E. coli K12 lexB30 and tif zab-53 mutants harboring plasmid pKM101. Mutagenesis in response to UV was observed in these bacteria which, in absence of pKM101, are not UV-mutable. The mutator effect observed in unirradiated wild-type cells containing pKM101 was higher after incubation at 30°C with adenine than at 37°C. This effect was still enhanced by tif mutation, even in the tif zab-53 strain, but it was abolished by lexB30 mutation. In the tif zab-53 (pKM101) strain, repair and mutagenesis of UV-irradiated phage λ was observed, but not in the lexB30 mutant carrying pKM101. The pKM101 mutant, pGW1, was unable to protect tif zab-53 bacteria against killing by UV, whereas the protection of lexB30 was intermediate; moreover, it did not promote the mutator effect at 30°C or enhance phage repair and mutagenesis in tif zab-53 cells. All UV-induced bacterial mutations in lexB30 (pKM101) strain were suppressors; in contrast, true revertants were found after UV irradiation of the tif zab-53 (pKM101) cells.We suggest that the constitutive activity of RecA protein is enough for the production of UV-promoted suppressor mutations, whereas true reversions require a more active form of this protein which could exert its effects directly or by acting at a regulatory level on other cellular functions.     

Site-directed mutagenesis in the Escherichia coli recA gene

Escherichia coli RecA protein plays a fundamental role in genetic recombination and in regulation and expression of the SOS response. We have constructed 6 mutants in the recA gene by site-directed mutagenesis, 5 of which were located in the vicinity of the recA430 mutation responsible for a coprotease deficient phenotype and one which was at the Tyr 264 site. We have analysed the capacity of these mutants to accomplish recombination and to express SOS functions. Our results suggest that the region including amino acid 204 and at least 7 amino acids downstream interacts not only with LexA protein but also with ATP. In addition, the mutation at Tyr 264 shows that this amino acid is essential for RecA activities in vivo, probably because of its involvement in an ATP binding site, as previously shown in vitro.     

New recA mutations that dissociate the various RecA protein activities in Escherichia coli provide evidence for an additional role for RecA protein in UV mutagenesis.

To isolate strains with new recA mutations that differentially affect RecA protein functions, we mutagenized in vitro the recA gene carried by plasmid mini-F and then introduced the mini-F-recA plasmid into a delta recA host that was lysogenic for prophage phi 80 and carried a lac duplication. By scoring prophage induction and recombination of the lac duplication, we isolated new recA mutations. A strain carrying mutation recA1734 (Arg-243 changed to Leu) was found to be deficient in phi 80 induction but proficient in recombination. The mutation rendered the host not mutable by UV, even in a lexA(Def) background. Yet, the recA1734 host became mutable upon introduction of a plasmid encoding UmuD*, the active carboxyl-terminal fragment of UmuD. Although the recA1734 mutation permits cleavage of lambda and LexA repressors, it renders the host deficient in the cleavage of phi 80 repressor and UmuD protein. Another strain carrying mutation recA1730 (Ser-117 changed to Phe) was found to be proficient in phi 80 induction but deficient in recombination. The recombination defect conferred by the mutation was partly alleviated in a cell devoid of LexA repressor, suggesting that, when amplified, RecA1730 protein is active in recombination. Since LexA protein was poorly cleaved in the recA1730 strain while phage lambda was induced, we conclude that RecA1730 protein cannot specifically mediate LexA protein cleavage. Our results show that the recA1734 and recA1730 mutations differentially affect cleavage of various substrates. The recA1730 mutation prevented UV mutagenesis, even upon introduction into the host of a plasmid encoding UmuD* and was dominant over recA+. With respect to other RecA functions, recA1730 was recessive to recA+. This demonstrates that RecA protein has an additional role in mutagenesis beside mediating the cleavage of LexA and UmuD proteins.     

A umuDC-independent SOS pathway for frameshift mutagenesis.

Summary The chemical carcinogen N-acetoxy-N-2-acetylaminofluorene induces mainly frameshift mutations, which occur within two types of sequences (mutation hot spots): –1 frameshift mutations within contiguous guanine sequences and –2 frameshift mutations within alternating GC sequences such as the NarI and BssHII restriction site sequences. We have investigated the genetic control of mutagenesis at these sequences by means of a reversion assay using plasmids pW17 and pX2, which contain specific targets for contiguous guanine and alternating GC sequences, respectively. Our results suggest that mutations at these hot spot sequences are generated by two different genetic pathways, both involving induction of SOS functions. The two pathways differ both in their LexA-controlled gene and RecA protein requirements. In the mutation pathway that acts at contiguous guanine sequences, the RecA protein participates together with the umuDC gene products. In contrast, RecA is not essential for mutagenesis at alternating GC sequences, except to cleave the LexA repressor. The LexA-regulated gene product(s), which participate in this latter mutational pathway, do not involve umuDC but another as yet uncharacterized inducible function. We also show that wild-type RecA and RecA430 proteins exert an antagonistic effect on mutagenesis at alternating GC sequences, which is not observed either in the presence of activated RecA (RecA^*), RecA730 or RecA495 proteins, or in the complete absence of RecA as in recA99. It is concluded that the –1 mutation pathway presents the same genetic requirements as the pathway for UV light mutagenesis, while the –2 mutation pathway defines a distinct SOS pathway for frameshift mutagenesis.     

Non-mutability by ultraviolet light in uvrD recB derivatives of Escherichia coli WP2 uvrA is due to inhibition of RecA protein activation

The deficiency in UV mutagenesis in uvrD3 recB21 strains of E. coli is almost completely overcome by constitutive activation of RecA protein and expression of the SOS system (by recA730 or 43 degrees C treated recA441 lexA71). When SOS was expressed but RecA protein not self-activated (recA441 lexA71 at 30 degrees C), uvrD3 recB21 still reduced UV mutagenesis at low doses. The uvrD3 recB21 combination is therefore inhibiting activation of RecA protein. It is suggested that the DNA unwinding activity of the products of the uvrD and recB genes may be involved in generating single-stranded DNA needed to activate RecA protein both for the cleavage of LexA repressor and for a further role in UV mutagenesis.     

PsiB polypeptide prevents activation of RecA protein in Escherichia coli

Summary We further characterize a novel plasmid function preventing SOS induction called Psi (Plasmid SOS Inhibition). We show that Psi function is expressed by psiB, a gene located at coordinate 54.9 of plasmid R6-5 and near oriT, the origin of conjugal transfer. Deletions and amber mutations of the psiB gene permitted us to demonstrate that PsiB polypeptide (apparent molecular weight, 12 kDa) is responsible for Psi function. PsiB protein prevents recA730-promoted mutagenesis and intra-chromosomal recombination but not recombination following conjugation. Overproduction of PsiB protein sensitizes the host cell to UV irradiation. We propose that PsiB polypeptide has an anti-SOS action by inhibiting activation of RecA protein, thus preventing the occurrence of LexA-controlled functions.