Isolation and characterization of an operator-constitutive mutation in the recA gene of E. coli K-12

Positive Charges Are Important for the SOS Constitutive Phenotype in recA730 and recA1202 Mutants of Escherichia coli K-12

In Escherichia coli K-12, RecA binds to single-strand DNA (ssDNA) created by DNA damage to form a protein-DNA helical filament that serves to catalyze LexA autoproteolysis, which induces the SOS response. The SOS constitutive (SOS^C) mutations recA730(E38K) and recA1202(Q184K) are both on the outside of the RecA filament, opposite to the face that binds DNA. recA730(E38K) is also able to suppress the UV sensitivity caused by recF mutations. Both SOS^C expression and recF suppression are thought to be due to RecA730's ability to compete better for ssDNA coated with ssDNA-binding protein than the wild type. We tested whether other positively charged residues at these two positions would lead to SOS^C expression and recF suppression. We found that 5/6 positively charged residues were SOS^C and 4/5 of these were also recF suppressors. While other mutations at these two positions (and others) were recF suppressors, none were SOS^C. Three recF suppressors could be made moderately SOS^C by adding a recA operator mutation. We hypothesize two mechanisms for SOS^C expression: the first suggests that the positive charge at positions 38 and 184 attract negatively charged molecules that block interactions that would destabilize the RecA-DNA filament, and the second involves more stable filaments caused by increases in mutant RecA concentration. IMPORTANCE In Escherichia coli K-12, SOS constitutive (SOS^C) mutants of recA turn on the SOS response in the absence of DNA damage. Some SOS^C mutants are also able to indirectly suppress the UV sensitivity of recF mutations. Two SOS^C mutations, recA730(E38K) and recA1202(Q184K), define a surface on the RecA-DNA filament opposite the surface that binds DNA. Both introduce positive charges, and recA730 is a recF suppressor. We tested whether the positive charge at these two positions was required for SOS^C expression and recF suppression. We found a high correlation between the positive charge, SOS^C expression and recF suppression. We also found several other mutations (different types) that provide recF suppression but no SOS^C expression.

RecBCD- RecFOR-independent pathway of homologous recombination in Escherichia coli

The RecA protein is a key bacterial recombination enzyme that catalyzes pairing and strand exchange between homologous DNA duplexes. In Escherichia coli, RecA protein assembly on DNA is mediated either by the RecBCD or RecFOR protein complexes. Correspondingly, two recombination pathways, RecBCD and RecF (or RecFOR), are distinguished in E. coli. Inactivation of both pathways in recB(CD) recF(OR) mutants results in severe recombination deficiency. Here we describe a novel, RecBCD- RecFOR-independent (RecBFI) recombination pathway that is active in ΔrecBCD sbcB15 sbcC(D) ΔrecF(OR) mutants of E. coli. In transductional crosses, these mutants show only four-fold decrease of recombination frequency relative to the wild-type strain. At the same time they recombine 40- to 90-fold better than their sbcB⁺ sbcC⁺ and ΔsbcB sbcC counterparts. The RecBFI pathway strongly depends on recA, recJ and recQ gene functions, and moderately depends on recG and lexA functions. Inactivation of dinI, helD, recX, recN, radA, ruvABC and uvrD genes has a slight effect on RecBFI recombination. After exposure to UV and gamma irradiation, the ΔrecBCD sbcB15 sbcC ΔrecF mutants show moderately increased DNA repair proficiency relative to their sbcB⁺ sbcC⁺ and ΔsbcB sbcC counterparts. However, introduction of recA730 allele (encoding RecA protein with enhanced DNA binding properties) completely restores repair proficiency to ΔrecBCD sbcB15 sbcC ΔrecF mutants, but not to their sbcB⁺ sbcC⁺ and ΔsbcB sbcC derivatives. Fluorescence microscopy with UV-irradiated recA-gfp fusion mutants suggests that the kinetics of RecA filament formation might be slowed down in the RecBFI pathway. Inactivation of 3'-5' exonucleases ExoVII, ExoIX and ExoX cannot activate the RecBFI pathway in ΔrecBCD ΔsbcB sbcC ΔrecF mutants. Taken together, our results show that the product of the sbcB15 allele is crucial for RecBFI pathway. Besides protecting 3' overhangs, SbcB15 protein might play an additional, more active role in formation of the RecA filament.

The SOS system: A complex and tightly regulated response to DNA damage

Genomes of all living organisms are constantly threatened by endogenous and exogenous agents that challenge the chemical integrity of DNA. Most bacteria have evolved a coordinated response to DNA damage. In Escherichia coli, this inducible system is termed the SOS response. The SOS global regulatory network consists of multiple factors promoting the integrity of DNA as well as error-prone factors allowing for survival and continuous replication upon extensive DNA damage at the cost of elevated mutagenesis. Due to its mutagenic potential, the SOS response is subject to elaborate regulatory control involving not only transcriptional derepression, but also post-translational activation, and inhibition. This review summarizes current knowledge about the molecular mechanism of the SOS response induction and progression and its consequences for genome stability. Environ. Mol. Mutagen. 60:368-384, 2019. © 2018 The Authors. Environmental and Molecular Mutagenesis published by Wiley Periodicals, Inc. on behalf of Environmental Mutagen Society.

SOS System Induction Inhibits the Assembly of Chemoreceptor Signaling Clusters in Salmonella enterica

Swarming, a flagellar-driven multicellular form of motility, is associated with bacterial virulence and increased antibiotic resistance. In this work we demonstrate that activation of the SOS response reversibly inhibits swarming motility by preventing the assembly of chemoreceptor-signaling polar arrays. We also show that an increase in the concentration of the RecA protein, generated by SOS system activation, rather than another function of this genetic network impairs chemoreceptor polar cluster formation. Our data provide evidence that the molecular balance between RecA and CheW proteins is crucial to allow polar cluster formation in Salmonella enterica cells. Thus, activation of the SOS response by the presence of a DNA-injuring compound increases the RecA concentration, thereby disturbing the equilibrium between RecA and CheW and resulting in the cessation of swarming. Nevertheless, when the DNA-damage decreases and the SOS response is no longer activated, basal RecA levels and thus polar cluster assembly are reestablished. These results clearly show that bacterial populations moving over surfaces make use of specific mechanisms to avoid contact with DNA-damaging compounds.

Plasmid-linked nif and "nod" genes in fast-growing rhizobia that nodulate Glycine max, Psophocarpus tetragonolobus, and Vigna unguiculata

Forty-nine fast-growing Rhizobium strains from the nodules of 26 different tropical legume genera were screened to find isolates that would (i) nodulate, e.g., winged beans, so producing large nodules for RNA and protein isolation; (ii) also nodulate various small-seeded legumes, thus allowing screening of large numbers of mutants; and (iii) harbor plasmids containing nif structural genes as well as other functions involved in nodulation. On the basis of six different criteria, this rhizobial group appeared intermediate between classical fast- and slow-growing organisms, yet all contained plasmids. Plasmid numbers varied from one to five. Hybridizations between DNA prepared from nifDH and the putatative "nod" region of R. meliloti and these plasmids bound to nitrocellulose filters suggested that nif-nod genes are linked on a single sym plasmid. A broad-host-range strain containing a single sym plasmid was chosen for further study. Its plasmid, pMPIK3030a, was isolated on cesium chloride gradients and cloned in the cosmid pJB8, and the overlapping fragments were mapped by homology with the nif and nod regions of R. meliloti. As the wild-type plasmid pMPIK3030a was not self-transmissible, confirmation that the nod genes detected by homology were responsible for nodulation was obtained by introducing the mobilization functions of RP(4) (together with Tn5) and selecting transconjugants resistant to kanamycin and neomycin. Transconjugants (obtained at a frequency of about 10(-6) per recipient) in Agrobacterium tumefaciens cured of the Ti plasmid produced ineffective nodules on Vigna unguiculata, those in nonnodulating (Nod(-)) R. meliloti were partially effective, while those in Nod(-)R. leguminosarum were often fully effective.

Overexpression of the recA gene decreases oral but not intraperitoneal fitness of Salmonella enterica

Transcription of the Salmonella enterica recA gene is negatively controlled by the LexA protein, the repressor of the SOS response. The introduction of a mutation (recAo6869) in the LexA binding site, in the promoter region of the S. enterica ATCC 14028 recA gene, allowed the analysis of the effect that RecA protein overproduction has on the fitness of this virulent strain. The fitness of orally but not intraperitoneally inoculated recAo6869 cells decreased dramatically. However, the SOS response of this mutant was induced normally, and there was no increase in the sensitivity of the strain toward DNA-damaging agents, bile salts, or alterations in pH. Nevertheless, S. enterica recAo6869 cells were unable to swarm and their capacity to cross the intestinal epithelium was significantly reduced. The swarming deficiency in recAo6869 cells is independent of the flagellar phase. Moreover, swimming activity of the recAo6869 strain was not diminished with respect to the wild type, indicating that the flagellar synthesis is not affected by RecA protein overproduction. In contrast, swarming was recovered in a recAo6869 derivative that overproduced CheW, a protein known to be essential for this function. These data demonstrate that an equilibrium between the intracellular concentrations of RecA and CheW is necessary for swarming in S. enterica. Our results are the first to point out that the SOS response plays a critical role in the prevention of DNA damage by abolishing bacterial swarming in the presence of a genotoxic compound.

Evidence that selected amplification of a bacterial lac frameshift allele stimulates Lac(+) reversion (adaptive mutation) with or without general hypermutability

In the genetic system of Cairns and Foster, a nongrowing population of an E. coli lac frameshift mutant appears to specifically accumulate Lac(+) revertants when starved on medium including lactose (adaptive mutation). This behavior has been attributed to stress-induced general mutagenesis in a subpopulation of starved cells (the hypermutable state model). We have suggested that, on the contrary, stress has no direct effect on mutability but favors only growth of cells that amplify their leaky mutant lac region (the amplification mutagenesis model). Selection enhances reversion primarily by increasing the mutant lac copy number within each developing clone on the selection plate. The observed general mutagenesis is attributed to a side effect of growth with an amplification-induction of SOS by DNA fragments released from a tandem array of lac copies. Here we show that the S. enterica version of the Cairns system shows SOS-dependent general mutagenesis and behaves in every way like the original E. coli system. In both systems, lac revertants are mutagenized during selection. Eliminating the 35-fold increase in mutation rate reduces revertant number only 2- to 4-fold. This discrepancy is due to continued growth of amplification cells until some clones manage to revert without mutagenesis solely by increasing their lac copy number. Reversion in the absence of mutagenesis is still dependent on RecA function, as expected if it depends on lac amplification (a recombination-dependent process). These observations support the amplification mutagenesis model.

Efficient repair of hydrogen peroxide-induced DNA damage by Escherichia coli requires SOS induction of RecA and RuvA proteins

The survival of Escherichia coli following treatment with a low dose (1-3 mM) of hydrogen peroxide (H(2)O(2)) that causes extensive mode-one killing of DNA repair mutants is stimulated by the induction of the SOS regulon. Results for various mutants indicate that induction of recA and RecA protein-mediated recombination are critical factors contributing to the repair of H(2)O(2)-induced oxidative DNA damage. However, because DNA damage activates RecA protein's coprotease activity essential to cleavage of LexA repressor protein and derepression of all SOS genes, it is unclear to what extent induction of RecA protein stimulates this repair. To make this determination, we examined mode-one killing of DeltarecA cells carrying plasmid-borne recA (P(tac)-recA(+)) and constitutively expressing a fully induced level of wild-type RecA protein when SOS genes other than recA are non-inducible in a lexA3 (Ind(-)) genetic background or inducible in a lexA(+) background. At a H(2)O(2) dose resulting in maximal killing, DeltarecA lexA3 (Ind(-)) cells with P(tac)-recA(+) show 40-fold greater survival than lexA3 (Ind(-)) cells with chromosomal recA having a low, non-induced level of RecA protein. However, they still show 10- to 15-fold lower survival than wild-type cells and DeltarecA lexA(+) cells with P(tac)-recA(+). To determine if the inducible RuvA protein stimulates survival, we examined a ruvA60 mutant that is defective for the repair of UV-induced DNA damage. This mutant also shows 10- to 15-fold lower survival than wild-type cells. We conclude that while induction of RecA protein has a pronounced stimulatory effect on the recombinational repair of H(2)O(2)-induced oxidative DNA damage, the induction of other SOS proteins such as RuvA is essential for wild-type repair.

Chromosome segregation and cell division defects in recBC sbcBC ruvC mutants of Escherichia coli

The RuvC protein is important for DNA recombination and repair in Escherichia coli. The present work shows that a ruvC null mutation introduced into a recBC sbcBC background causes severe defects in chromosome segregation and cell division. Both defects were found to result from abortive recombination initiated by the RecA protein.

Recovery of respiration following the SOS response of Escherichia coli requires RecA-mediated induction of 2-keto-4-hydroxyglutarate aldolase

Agents that damage DNA in Escherichia coli or interfere with its replication induce DNA repair and mutagenesis via the SOS response. This well-known activity is regulated by the RecA protein and the LexA repressor. Following repair or bypass of the DNA lesion, the cell returns to its resting state by a largely unknown process. We found that 2-keto-4-hydroxyglutarate aldolase (4-hydroxy-2-oxoglutarate aldolase; EC 4.1.3.16) is necessary for the recovery of respiration and that it is regulated by the SOS response. This protein was induced by DNA-damaging agents. Induction required RecA activation. When the LexA regulon was repressed, activation of RecA was not sufficient for induction, indicating the requirement for an additional protein under LexA control. Finally, a mutant in the corresponding hga gene was UV sensitive. 2-Keto-4-hydroxyglutarate aldolase also plays a role in respiratory metabolic pathways, which suggests a mechanism for respiration resumption during the termination of the SOS response.

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.

Function of the SOS process in repair of DNA damage induced by modern 4-quinolones

The recA13 mutant of Escherichia coli strain K-12, which lacks recombination and SOS error-prone DNA repair is hypersensitive to nalidixic acid and to the newer 4-quinolones ciprofloxacin, norfloxacin and ofloxacin. However, whereas recombination-proficient but SOS repair-deficient strains, such as those carrying the lexA3 or recA430 alleles are no more sensitive to nalidixic than the lexA+ recA+ parent, they are more sensitive to the newer quinolones, although not as sensitive as the recA13 derivative. Nalidixic acid possesses only bactericidal mechanism A (which requires RNA and protein synthesis and is only effective on actively dividing cells), whereas the newer 4-quinolones exhibit additional mechanisms B (which does not require RNA and protein synthesis and is effective on bacteria unable to multiply) and C (which requires RNA and protein synthesis but does not depend on cell division). Results obtained with bacteria suspended in phosphate-buffered saline, which inhibits mechanism A, and with bacteria suspended in nutrient broth plus rifampicin, which inhibits mechanisms A and C, showed that the lexA3 mutant was still more sensitive than the lexA+ parent under these conditions. The results suggest that, unlike bactericidal mechanism A, DNA damage that results from bactericidal mechanisms B and C of the newer 4-quinolones is subject to SOS error-prone (mutagenic) repair.

Induction of only one SOS operon, umuDC, is required for SOS mutagenesis in Escherichia coli

The actions of UmuDC and RecA proteins, respectively in SOS mutagenesis are studied here with the following experimental strategy. We used lexAl (Ind-) bacteria to maintain all SOS proteins at their basal concentrations and then selectively increased the concentration of either UmuDC or RecA protein. For this purpose, we isolated operator-constitutive mutations oc in the umuDC and umuD'C operons and also used the oc98-recA mutation. The oc1-umuDC mutation prevents LexA repressor from binding to the operator and improves the Pribnow box consensus sequence. As a result, 5000 UmuD and 500 UmuC molecules per cell were produced in lexAl bacteria. This concentration is sufficient to restore SOS mutagenesis. The level of RecA protein present in the repressed state promoted full UmuD cleavage. Overproduction of RecA alone did not promote SOS mutagenesis. Increasing the level of RecA in the presence of high concentrations of UmuDC proteins has no further effect on SOS mutagenesis. We conclude that, after DNA damage, umuDC is the only SOS operon that must be induced in Escherichia coli to promote SOS mutagenesis.

Relationship between the functional regions of the RecA protein and ATP hydrolysis in UV-irradiated Escherichia coli cells

The time course of the intracellular ATP concentration in several UV-irradiated RecA protease constitutive (Cptc) mutants of E. coli has been studied. All Cptc mutants harboring a mutation in region 3 of the RecA protein (including amino acid residues 298-301) increased ATP after UV damage but without any subsequent decrease. Nevertheless, these mutants induced the SOS response after UV irradiation. Likewise, truncated RecA proteins lacking region 3 are also unable to carry out massive ATP hydrolysis in UV-irradiated cells. On the other hand, mutants in region 1 (including amino acids 25-39) or 2 (amino acids 157-184) of the RecA protein showed an increase in ATP concentration during the first 20 min following UV irradiation, which dropped afterwards to the basal level. All these data indicate that region 3 of the RecA protein must be involved in the ATP hydrolysis process. Furthermore, a relationship between the quantity of the UV-mediated ATP produced and the strength of the different RecA Cptc mutants has also been found. Accordingly, both lexA71::Tn5 and null lexA mutants of E. coli only show a cellular ATP increase after UV irradiation when containing a multicopy plasmid carrying either a wild-type lexA or a lexA (Ind-) gene.

A partially deficient mutant, recA1730, that fails to form normal nucleoprotein filaments

The phenotype of the recA1730 mutant is highly dependent on the level of expression of the RecA1730 protein. If the recA1730 gene was expressed from its own promoter, the cells were deficient in recombination and SOS induction. In contrast, when the recA1730 gene was expressed under the control of recAo98, a constitutive operator that increased the RecA1730 concentration 20-fold, cells became proficient in recombination and SOS induction. Likewise, in crude extracts, fivefold more RecA1730 than RecAwt was required to produce full cleavage of LexA protein. The requirement for a high RecA1730 concentration for recombination and LexA cleavage suggests that the recA1730 defect alters a common reaction step. In fact, in vitro data show that the impaired assembly of RecA1730 protein on single-stranded DNA (ssDNA) can account for the mutant phenotype. Purified RecA1730 protein was assayed in vitro for ssDNA binding and ATPase activities. RecA1730, like RecAwt, retained ssDNA equally well on nitrocellulose filters; this activity was specifically inhibited by a monoclonal anti-RecA antibody. However, RecA1730 protein did not form complete filaments on ssDNA, as shown by two observations: (i) most of the protein did not elute with ssDNA during gel filtration; and (ii) binding of RecA1730 to ssDNA did not protect it from being digested by DNaseI. RecA1730 hydrolysed ATP in high salt but was defective in ssDNA-dependent ATP hydrolysis. These results strongly suggest that RecA1730 binds to ATP and ssDNA but does not form normal nucleoprotein filaments.

Bactericidal activities of five quinolones for Escherichia coli strains with mutations in genes encoding the SOS response or cell division

The bactericidal effects of five quinolones (at the optimum bactericidal concentration for strain AB1157) on 15 strains of Escherichia coli with mutations in genes for the SOS response or cell division was studied by a viable-count method. The kill rate data were normalized for growth rate and compared to those for the wild type, AB1157. Similar MICs of enoxacin and fleroxacin were obtained for all mutants; however, different mutants had differing susceptibilities to ciprofloxacin, norfloxacin, and nalidixic acid. Killing kinetic studies showed that mutants with constitutive RecA expression (recA730 and spr-55 mutants) survived longer than AB1157 with all quinolones. Mutants deficient in SOS induction, e.g., recA430 and lexA3 mutants, also survived longer, suggesting that induction of the SOS response by quinolones is harmful to wild-type cells. Recombination repair-deficient mutants (recB21, recC22, and recD1009 mutants) were killed more rapidly than AB1157, as were excision repair mutants, except with nalidixic acid. Mutants which were unable to filament (sfiA11 and sfiB114 mutants) survived longer than AB1157 with all agents, but a mutant defective in the Lon protease was killed more quickly. It was concluded that (i) recombination and excision repair were involved in the repair of quinolone-damaged DNA and (ii) continuous induction (in response to exposure to quinolones) of the SOS response, and hence induction of the cell division inhibitor SfiA, causes cell filamentation and thereby contributes to the bactericidal activity of quinolones.

Inhibition of the recBCD-dependent activation of Chi recombinational hot spots in SOS-induced cells of Escherichia coli

Nucleotide sequences called Chi (5'-GCTGGTGG-3') enhance homologous recombination near their location by the RecBCD enzyme in Escherichia coli (Chi activation). A partial inhibition of Chi activation measured in lambda red gam mutant crosses was observed after treatment of wild-type cells with DNA-damaging agents including UV, mitomycin, and nalidixic acid. Inhibition of Chi activation was not accompanied by an overall decrease of recombination. A lexA3 mutation which blocks induction of the SOS system prevented the inhibition of Chi activation, indicating that an SOS function could be responsible for the inhibition. Overproduction of the RecD subunit of the RecBCD enzyme from a multicopy plasmid carrying the recD gene prevented the induced inhibition of Chi activation, whereas overproduction of RecB or RecC subunits did not. It is proposed that in SOS-induced cells the RecBCD enzyme is modified into a Chi-independent recombination enzyme, with the RecD subunit being the regulatory switch key.

Levels of chromosomally encoded Umu proteins and requirements for in vivo UmuD cleavage

Most of the inducible mutagenesis observed in Escherichia coli after treatment with many DNA damaging agents is dependent upon the products of the umuD,C operon. RecA-mediated proteolytic processing of UmuD yields a carboxyl-terminal fragment (UmuD') that is active for mutagenesis. Processing of UmuD is therefore a critical step in the fixation of mutations. In this paper we have analyzed the requirements for UmuD processing in vivo. Standard immuno-detection assays, coupled with a sensitive chemiluminescence detection assay, have been utilized to probe levels of chromosomally encoded Umu proteins from whole-cell E. coli extracts. We found that the derepression of additional SOS gene products, other than RecA, was not required for UmuD processing. Moreover, efficient cleavage of UmuD was observed only in the presence of elevated levels of activated RecA, suggesting that efficient processing would occur only under conditions of severe DNA damage. Detection of chromosomally encoded Umu proteins has allowed us, for the first time, to measure directly the cellular steady-state levels of these proteins under various SOS inducing conditions. UmuD was present at approximately 180 copies per uninduced cell and was measured at approximately 2400 copies per cell in strains that lacked a functional repressor. Induced levels of UmuC were approximately 12-fold lower than UmuD with approximately 200 molecules per cell. These levels of cellular UmuC protein suggest that it functions through specific protein-DNA or protein-protein interactions, possibly as a lesion recognition protein or by interacting with DNA polymerase III.

Properties of RecA441 protein reveal a possible role for RecF and SSB proteins in Escherichia coli

We examined the possibility that the recA441 mutation, which partially suppresses the UV sensitivity of uvr recF mutant bacteria, exerts its effect by coding for an altered RecA protein that competes more efficiently than the RecA+ protein with SSB for ssDNA in vivo. Using an assay measuring recombination between UV-damaged lambda DNA and intact homologous DNA, we found that the introduction of the recA441 mutation partially suppressed the defects in recombination in bacteria lacking RecF activity but not in bacteria with excess SSB, although recombination was affected more in recF mutants than in bacteria overproducing SSB. These results therefore do not support the hypothesis that RecA441 protein, or RecA protein with the help of RecF protein, is required during recombination of UV-damaged DNA to compete with SSB for ssDNA.

Inhibition of cell division in hupA hupB mutant bacteria lacking HU protein

Escherichia coli hupA hypB double mutants that lack HU protein have severe cellular defects in cell division, DNA folding, and DNA partitioning. Here we show that the sfiA11 mutation, which alters the SfiA cell division inhibitor, reduces filamentation and production of anucleate cells in AB1157 hupA hupB strains. However, lexA3(Ind-) and sfiB(ftsZ)114 mutations, which normally counteract the effect of the SfiA inhibitor, could not restore a normal morphology to hupA hupB mutant bacteria. The LexA repressor, which controls the expression of the sfiA gene, was present in hupA hupB mutant bacteria in concentrations half of those of the parent bacteria, but this decrease was independent of the specific cleavage of the LexA repressor by activated RecA protein. One possibility to account for the filamentous morphology of hupA hupB mutant bacteria is that the lack of HU protein alters the expression of specific genes, such as lexA and fts cell division genes.

Effects of mutations altering SOS regulation on a nalidixic acid-inducible system for the production of heterologous proteins in Escherichia coli

The major leftward early promoter of phage lambda pL, has frequently been used to drive expression of heterologous genes in Escherichia coli. pL is typically maintained fully repressed by the lambda cl protein. When induction of heterologous protein synthesis is desired, one of several potential mechanisms of destroying cl function is employed and the expression of the foreign gene commences. One method of derepressing pL involves exposing cells to nalidixic acid, which results in the "activation" of RecA protein and the subsequent RecA-mediated proteolytic cleavage of cl. Activated RecA also mediates the cleavage of the E. coli LexA protein, resulting in induction of the SOS regulon (at least 15 E. coli genes, including recA). We have examined the effect of two chromosomal mutations on the productivity of nalidixic acid inductions. One of the tested mutations (recA o) increased the intracellular concentration of RecA prior to induction; the other (lexAind-) resulted in a mutated lexA protein insensitive to RecA-mediated cleavage. These mutations were introduced into a strain carrying a cl+ defective lysogen. Synthesis of two heterologous proteins, human alpha 1-antitrypsin and a fusion protein partially derived from the Plasmodium falciparum circumsporozoite surface antigen, was examined in the wild-type and mutant strains. The maximum alpha-1 antitrypsin concentration achieved was improved by 50% when the recA o strain was used rather than the wild-type; however, only smaller changes (20% or less) in the maximum concentration of the malaria fusion protein were observed. Use of the lexAind- strain resulted in a decrease in the maximum concentration attained for both heterologous products.

Increase in plasmid transformation efficiency in SOS-induced Escherichia coli cells

UV irradiation of competent cells of Escherichia coli K12 produced an increase in the efficiency of transformation with plasmid DNA. This phenomenon has been called IPTE (increase in plasmid transformation efficiency) and is dependent on the activated state of the RecA protein. IPTE is independent of the lexA, recB recC, and recF genes. It is not related to the size or the replicon type of the plasmid. Furthermore, it is also induced in cells which have been previously treated with other SOS system-inducing agents such as bleomycin, mitomycin C, or nalidixic acid. IPTE is therefore similar to other repair (SOS) functions inducible by DNA damage since all of them are dependent upon activation of the RecA protein. IPTE differs from other SOS functions in the absence of a direct control by the LexA repressor.

Inhibition of the SOS response of Escherichia coli by the Ada protein

Induction of the adaptive response by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) caused a decrease in the UV-mediated expression of both recA and sfiA genes but not of the umuDC gene. On the other hand, the adaptive response did not affect the temperature-promoted induction of SOS response in a RecA441 mutant. The inhibitory effect on the UV-triggered expression of the recA and sfiA genes was not dependent on either the alkA gene or the basal level of RecA protein, but rather required the ada gene. Furthermore, an increase in the level of the Ada protein, caused by the runaway plasmid pYN3059 in which the ada gene is regulated by the lac promoter, inhibited UV-mediated recA gene expression even in cells to which the MNNG-adaptive treatment had not been applied. This inhibitory effect of the adaptive pretreatment was not observed either in RecBC- strains or in RecBC mutants lacking exonuclease V-related nuclease activity. However, RecF- mutants showed an adaptive response-mediated decrease in UV-promoted induction of the recA gene.

Activated RecA protein may induce expression of a gene that is not controlled by the LexA repressor and whose function is required for mutagenesis and repair of UV-irradiated bacteriophage lambda

The activated form of the RecA protein (RecA) is known to be involved in the reactivation and mutagenesis of UV-irradiated bacteriophage lambda and in the expression of the SOS response in Escherichia coli K-12. The expression of the SOS response requires cleavage of the LexA repressor by RecA and the subsequent expression of LexA-controlled genes. The evidence presented here suggests that RecA induces the expression of a gene(s) that is not under LexA control and that is also necessary for maximal repair and mutagenesis of damaged phage. This conclusion is based on the chloramphenicol sensitivity of RecA -dependent repair and mutagenesis of damaged bacteriophage lambda in lexA(Def) hosts.

Molecular cloning and characterization of the recA gene from the cyanobacterium Synechococcus sp. strain PCC 7002

The recA gene of Synechococcus sp. strain PCC 7002 was detected and cloned from a lambda gtwes genomic library by heterologous hybridization by using a gene-internal fragment of the Escherichia coli recA gene as the probe. The gene encodes a 38-kilodalton polypeptide which is antigenically related to the RecA protein of E. coli. The nucleotide sequence of a portion of the gene was determined. The translation of this region was 55% homologous to the E. coli protein; allowances for conservative amino acid replacements yield a homology value of about 74%. The cyanobacterial recA gene product was proficient in restoring homologous recombination and partial resistance to UV irradiation to recA mutants of E. coli. Heterologous hybridization experiments, in which the Synechococcus sp. strain PCC 7002 recA gene was used as the probe, indicate that a homologous gene is probably present in all cyanobacterial strains.

Regulatory role of recF in the SOS response of Escherichia coli: impaired induction of SOS genes by UV irradiation and nalidixic acid in a recF mutant

We isolated a new recF mutant of Escherichia coli K-12 by insertion of transposon Tn5 into the recF gene. This recF400::Tn5 allele displayed the same phenotypic characteristics as the classic recF143 mutation. By using Mu d(Ap lac) fusions, the induction of nine SOS genes, including recA, umuC, dinA, dinB, dinD, dinF, recN, and sulA, by UV irradiation and nalidixic acid was examined. Induction of eight genes by the two agents was impaired by recF400::Tn5 to different extents. The ninth fused SOS gene, dinF, was no longer inducible by UV when combined with recF400::Tn5. The generally impaired SOS response in recF strains did not result from weak induction of recA protein synthesis, since a recA operator-constitutive mutation did not alleviate the inhibitory effect of the recF mutation. The results suggest that recF plays a regulatory role in the SOS response. It is proposed that this role is to optimize the signal usage by recA protein to become a protease.

Nucleotide sequence binding specificity of the LexA repressor of Escherichia coli K-12

The specificity of LexA protein binding was investigated by quantifying the repressibility of several mutant recA and lexA operator-promoter regions fused to the Escherichia coli galactokinase (galK) gene. The results of this analysis indicate that two sets of four nucleotides, one set at each end of the operator (terminal-nucleotide contacts), are most critical for repressor binding. In addition, our results suggest that the repressor-operator interaction is symmetric in nature, in that mutations at symmetrically equivalent positions in the recA operator have comparable effects on repressibility. The symmetry of this interaction justified reevaluation of the consensus sequence by half-site comparison, which yielded the half-site consensus (5')CTGTATAT. Although the first four positions of this sequence were most important, the last four were well conserved among binding sites and appeared to modulate repressor affinity. The role of the terminal-nucleotide contacts and the mechanism by which the internal sequences affected repressor binding are discussed.

Dual role for Escherichia coli RecA protein in SOS mutagenesis

Induction of the Escherichia coli SOS system increases the ability of the cells to perform DNA repair and mutagenesis. Previous work has shown that this increased mutagenesis is the result of derepression of specific genes through a complex regulatory mechanism controlled by LexA and RecA proteins. One role of RecA protein in this process is to facilitate proteolytic cleavage of LexA protein (the repressor) in response to an inducing signal that reversibly activates RecA protein to perform this function. We show that activated RecA protein plays a second role in SOS mutagenesis, as revealed by analyzing repair of UV-damaged phage lambda in host mutants with alterations in the SOS regulatory system. First, phage mutagenesis was not expressed constitutively in a mutant that is derepressed through lack of functional LexA protein; activated RecA protein was still required. Second, phage mutagenesis was constitutively expressed in the presence of recA mutations that alter RecA protein so that it is activated in normally growing cells. There was also RecA-dependent constitutive expression of SOS mutagenesis in host mutants that lack functional LexA protein and carry plasmids. We discuss several possible biochemical mechanisms for this second role of activated RecA protein in SOS mutagenesis.

Efficiency of induction of prophage lambda mutants as a function of recA alleles

Mutants of the cI gene of prophage lambda have been defined phenotypically in a recA+ host as noninducible (Ind-), inducible (Ind+), or induction sensitive (Inds). We showed that a phage lambda cI+ carrying operator mutations v2 and v3 displays an Inds phenotype, as does lambda cI inds-1. We characterized a fourth induction phenotype called induction resistant (Indr). Using these four prophage types, we tested the influence of bacterial recA mutations on prophage induction. Indr prophages were fully induced in recA441 bacteria whose RecA441 protein is activated constitutively. Indr prophages were not induced in a mutant overproducing RecA+ protein, confirming that RecA+ protein must be activated to promote prophage induction. Inds prophages were induced in recA142 and recA453-441 lysogens, previously described as deficient in prophage induction.

Physiology of the SOS response: kinetics of lexA and recA transcriptional activity following induction

The products of the lexA and recA genes play central roles in the regulation of the Escherichia coli SOS response. We have measured the rate of mRNA synthesis from each gene at intervals following various inducing treatments in order to obtain a more precise timing of the induction process. Further, we provide quantitative evidence for kinetics of decay from fully induced levels of mRNA synthesis to basal levels as the cells shut down the SOS response which are in agreement with previously published data on the expression of specific SOS functions. The induction kinetics of lexA and recA gene expression are parallel except for nalidixic acid (NAL) treatment, with the actual levels of lexA mRNA synthesis being about 10-fold lower than that of recA. Reestablishment of repression from RecA commenced over 30 min earlier than from lexA. These results are fully consistent with the model that the functions result from the increased gene expression.

Genetic control of damage-inducible restriction alleviation in Escherichia coli K12: an SOS function not repressed by lexA

The alleviation of K-specific DNA restriction after treatment of cells by UV or nalidixic acid has been studied in mutants with various alleles of recA and lexA and combinations of these alleles and with recB and recF mutations. The studies show that induction of restriction alleviation by UV or nalidixic acid is abolished in mutants in which the recA protein is defective (recA13, recA56), its protease activity is altered (recA430) or in which it cannot be efficiently activated (recA142). Thermoinduction of restriction alleviation was observed in tif mutant (recA441). In lexA amber mutants restriction alleviation is not constitutive but is still inducible. In a lexA3 mutant restriction alleviation is inducible by nalidixic acid provided that recA protein is overproduced as a result of a recA operator mutation. Induction by UV depends on the recF function and an unidentified function (Y) which is controlled by the lexA protein. The recBC enzyme is necessary for induction by UV or by nalidixic acid. Temperature shift experiments with a thermosensitive recB mutant indicate that the recBC enzyme functions in an early step during UV-induction. It is concluded that the damage-inducible function which alleviates restriction is similar to other damage inducible repair (SOS) functions in the dependence on activated recA protease for induction, but that it differs from these functions by the absence of a direct control through the lexA repressor.

Analysis of mRNA synthesis following induction of the Escherichia coli SOS system

Escherichia coli responds to impairment of DNA synthesis by inducing a system of DNA repair known as the SOS response. Specific genes are derepressed through proteolytic cleavage of their repressor, the lexA gene product. Cleavage in vivo requires functional RecA protein in a role not yet understood. We used mRNA hybridization techniques to follow the rapid changes that occur with induction in cells with mutations in the recA operator or in the repressor cleavage site. These mutations allowed us to uncouple the induction of RecA protein synthesis from its role in inducing the other SOS functions. Following induction with ultraviolet light, we observed increased rates of mRNA synthesis from five SOS genes within five minutes, maximum expression ten to 20 minutes later and then a later decline to near the initial rates. The presence of a recA operator mutation did not significantly influence these kinetics, whereas induction was fully blocked by an additional mutation in the repressor cleavage site. These experiments are consistent with activation of RecA protein preceding repressor cleavage and derepression of SOS genes. The results also suggest that the timing and extent of induction of individual SOS genes may be different.

Two-dimensional electrophoretic analysis of the regulation of SOS proteins in three ssb mutants

A previously undescribed mutation in the ssb gene, which codes for a major single strand DNA binding protein essential for DNA replication, was mapped on the Escherichia coli chromosome. Three ssb mutants were analyzed under parallel physiological conditions for the induction of SOS proteins (products of recA, uvrA, and an unknown gene), the production of mutants, the induction of lambda prophage, and sensitivity to DNA damaging agents. Two-dimensional electrophoretic techniques were used to quantitate changes in the rate of synthesis of proteins. The previously unpublished position of the uvrA gene-product in the two-dimensional matrix of E. coli proteins was described. These ssb strains exhibited varying sensitivities to ultraviolet irradiation and methylmethane sulfonate that correlated with the rate of constitutive synthesis of SOS proteins, spontaneous commitment to virulent growth of lambda lysogens, and elevation of endogenous mutation rates.

The SOS regulatory system: control of its state by the level of RecA protease

Our current understanding of the SOS regulatory system suggests that it can exist in two extreme states: in the repressed state, LexA protein is active, and it represses a particular set of genes called SOS genes. In the induced state, which results from various impairments to DNA replication, LexA repressor is cleaved by the specific protease activity of the RecA protein; in consequence, the SOS genes are derepressed and they express various functions that are believed to aid cell survival in induced cells. Since high levels of RecA protease activity turn on this system, it seems plausible that the level of protease activity will also control the transitions between the two states of the system. In order to assess the in vivo level of protease activity, antibody techniques were used to study the stability of LexA repressor during various phases of the SOS regulatory cycle. Repressor was reasonably stable in the repressed state, but it was degraded within a few minutes after an inducing treatment. Cleavage depended upon the RecA protease activity and resulted in the same products as seen in vitro. Cleavage preceded, and did not depend upon, derepression of any SOS gene. During the transition to the repressed state, LexA repressor became increasingly stable with time, suggesting that as DNA damage was repaired the level of protease declined. This decline depended upon derepression of the regulatory system, consistent with the belief that an inducing signal, resulting from DNA damage, reversibly activates the RecA protease and is removed by the action of one or more SOS functions. At low levels of DNA damage, a subinduced state was observed in which repressor level was reduced by a low level of cleavage. These data indicate that the level of RecA protease activity controls the state of the system and the transitions between its two states.

Inducible expression of a gene specific to the RecF pathway for recombination in Escherichia coli K12

The Mud(Aplac) operon fusion technique of Casadaban and Cohen (1979) was used to search for inducible functions specific to the RecF pathway of conjugal recombination. A fusion mutant of a recBC sbcB mutant which showed less than 1% of the normal level of recombination in Hfr crosses has been isolated and designated as rec-259. The mutation is shown to be closely linked to tyrA at approximately 57.5 min in relation to the standard genetic map, and is quite distinct from recA. Two point mutations within this gene have also been obtained. Mutation of this gene interferes specifically with the RecF pathway of recombination, and also causes increased sensitivity to mitomycin C and UV light. Expression of the lac genes in the rec-259 fusion strain is increased following damage to DNA, but not in lexA and recA derivatives. These observations demonstrate the existence of an inducible gene which is regulated by lexA and whose expression is required for RecF recombination and DNA repair.

Cell survival, UV-reactivation and induction of prophage lambda in Escherichia coli K12 overproducing RecA protein

The effect of the cellular level of RecA protein on the ability of E. coli K12 bacteria to (i) survive UV-irradiation (ii) promote UV-reactivation of UV-damaged phage lambda (iii) induce prophage lambda was determined in bacterial mutants with discrete increasing levels of RecA protein. The various levels of RecA protein were obtained by combining lexA and recA alleles. Except for the double mutant lexA3 recAo98, whose repair ability was 25% less than that observed in wild type bacteria, bacterial survival was proportional to the level of RecA protein measured after 90 min of incubation. In lexA3 recAo98 bacteria, RecA protein, at a constitutive high basal level, failed to compensate totally for the lack of LexA repressor cleavage; UV-reactivation of UV-damaged phage lambda was not restored; yet, prophage lambda was induced with 35% efficiency. Efficient UV-induction of prophage lambda is linked to the induction of lexA-controlled host processes that repair the UV-damaged prophage.