Suppression of Escherichia coli recF mutations by recA-linked srfA mutations

The DNA damage response of Escherichia coli, revisited: Differential gene expression after replication inhibition

In 1967, in this journal, Evelyn Witkin proposed the existence of a coordinated DNA damage response in Escherichia coli, which later came to be called the "SOS response." We revisited this response using the replication inhibitor azidothymidine (AZT) and RNA-Seq analysis and identified several features. We confirm the induction of classic Save our ship (SOS) loci and identify several genes, including many of the pyrimidine pathway, that have not been previously demonstrated to be DNA damage-inducible. Despite a strong dependence on LexA, these genes lack LexA boxes and their regulation by LexA is likely to be indirect via unknown factors. We show that the transcription factor "stringent starvation protein" SspA is as important as LexA in the regulation of AZT-induced genes and that the genes activated by SspA change dramatically after AZT exposure. Our experiments identify additional LexA-independent DNA damage inducible genes, including 22 small RNA genes, some of which appear to activated by SspA. Motility and chemotaxis genes are strongly down-regulated by AZT, possibly as a result of one of more of the small RNAs or other transcription factors such as AppY and GadE, whose expression is elevated by AZT. Genes controlling the iron siderophore, enterobactin, and iron homeostasis are also strongly induced, independent of LexA. We confirm that IraD antiadaptor protein is induced independent of LexA and that a second antiadaptor, IraM is likewise strongly AZT-inducible, independent of LexA, suggesting that RpoS stabilization via these antiadaptor proteins is an integral part of replication stress tolerance.

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.

λ Recombination and Recombineering

The bacteriophage λ Red homologous recombination system has been studied over the past 50 years as a model system to define the mechanistic details of how organisms exchange DNA segments that share extended regions of homology. The λ Red system proved useful as a system to study because recombinants could be easily generated by co-infection of genetically marked phages. What emerged from these studies was the recognition that replication of phage DNA was required for substantial Red-promoted recombination in vivo, and the critical role that double-stranded DNA ends play in allowing the Red proteins access to the phage DNA chromosomes. In the past 16 years, however, the λ Red recombination system has gained a new notoriety. When expressed independently of other λ functions, the Red system is able to promote recombination of linear DNA containing limited regions of homology (∼50 bp) with the Escherichia coli chromosome, a process known as recombineering. This review explains how the Red system works during a phage infection, and how it is utilized to make chromosomal modifications of E. coli with such efficiency that it changed the nature and number of genetic manipulations possible, leading to advances in bacterial genomics, metabolic engineering, and eukaryotic genetics.

RecQ helicase and RecJ nuclease provide complementary functions to resect DNA for homologous recombination

Recombinational DNA repair by the RecF pathway of Escherichia coli requires the coordinated activities of RecA, RecFOR, RecQ, RecJ, and single-strand DNA binding (SSB) proteins. These proteins facilitate formation of homologously paired joint molecules between linear double-stranded (dsDNA) and supercoiled DNA. Repair starts with resection of the broken dsDNA by RecQ, a 3'→5' helicase, RecJ, a 5'→3' exonuclease, and SSB protein. The ends of a dsDNA break can be blunt-ended, or they may possess either 5'- or 3'-single-stranded DNA (ssDNA) overhangs of undefined length. Here we show that RecJ nuclease alone can initiate nucleolytic resection of DNA with 5'-ssDNA overhangs, and that RecQ helicase can initiate resection of DNA with blunt-ends or 3'-ssDNA overhangs by DNA unwinding. We establish that in addition to its well-known ssDNA exonuclease activity, RecJ can display dsDNA exonuclease activity, degrading 100-200 nucleotides of the strand terminating with a 5'-ssDNA overhang. The dsDNA product, with a 3'-ssDNA overhang, is an optimal substrate for RecQ, which unwinds this intermediate to reveal the complementary DNA strand with a 5'-end that is degraded iteratively by RecJ. On the other hand, RecJ cannot resect duplex DNA that is either blunt-ended or terminated with 3'-ssDNA; however, such DNA is unwound by RecQ to create ssDNA for RecJ exonuclease. RecJ requires interaction with SSB for exonucleolytic degradation of ssDNA but not dsDNA. Thus, complementary action by RecJ and RecQ permits initiation of recombinational repair from all dsDNA ends: 5'-overhangs, blunt, or 3'-overhangs. Such helicase-nuclease coordination is a common mechanism underlying resection in all organisms.

Homologous Recombination-Enzymes and Pathways

Homologous recombination is an ubiquitous process that shapes genomes and repairs DNA damage. The reaction is classically divided into three phases: presynaptic, synaptic, and postsynaptic. In Escherichia coli, the presynaptic phase involves either RecBCD or RecFOR proteins, which act on DNA double-stranded ends and DNA single-stranded gaps, respectively; the central synaptic steps are catalyzed by the ubiquitous DNA-binding protein RecA; and the postsynaptic phase involves either RuvABC or RecG proteins, which catalyze branch-migration and, in the case of RuvABC, the cleavage of Holliday junctions. Here, we review the biochemical properties of these molecular machines and analyze how, in light of these properties, the phenotypes of null mutants allow us to define their biological function(s). The consequences of point mutations on the biochemical properties of recombination enzymes and on cell phenotypes help refine the molecular mechanisms of action and the biological roles of recombination proteins. Given the high level of conservation of key proteins like RecA and the conservation of the principles of action of all recombination proteins, the deep knowledge acquired during decades of studies of homologous recombination in bacteria is the foundation of our present understanding of the processes that govern genome stability and evolution in all living organisms.

Single molecule analysis of a red fluorescent RecA protein reveals a defect in nucleoprotein filament nucleation that relates to its reduced biological functions

Fluorescent fusion proteins are exceedingly useful for monitoring protein localization in situ or visualizing protein behavior at the single molecule level. Unfortunately, some proteins are rendered inactive by the fusion. To circumvent this problem, we fused a hyperactive RecA protein (RecA803 protein) to monomeric red fluorescent protein (mRFP1) to produce a functional protein (RecA-RFP) that is suitable for in vivo and in vitro analysis. In vivo, the RecA-RFP partially restores UV resistance, conjugational recombination, and SOS induction to recA(-) cells. In vitro, the purified RecA-RFP protein forms a nucleoprotein filament whose k(cat) for single-stranded DNA-dependent ATPase activity is reduced approximately 3-fold relative to wild-type protein, and which is largely inhibited by single-stranded DNA-binding protein. However, RecA protein is also a dATPase; dATP supports RecA-RFP nucleoprotein filament formation in the presence of single-stranded DNA-binding protein. Furthermore, as for the wild-type protein, the activities of RecA-RFP are further enhanced by shifting the pH to 6.2. As a consequence, RecA-RFP is proficient for DNA strand exchange with dATP or at lower pH. Finally, using single molecule visualization, RecA-RFP was seen to assemble into a continuous filament on duplex DNA, and to extend the DNA approximately 1.7-fold. Consistent with its attenuated activities, RecA-RFP nucleates onto double-stranded DNA approximately 3-fold more slowly than the wild-type protein, but still requires approximately 3 monomers to form the rate-limited nucleus needed for filament assembly. Thus, RecA-RFP reveals that its attenuated biological functions correlate with a reduced frequency of nucleoprotein filament nucleation at the single molecule level.

Reconstitution of initial steps of dsDNA break repair by the RecF pathway of E. coli

The RecF pathway of Escherichia coli is important for recombinational repair of DNA breaks and gaps. Here ;we reconstitute in vitro a seven-protein reaction that recapitulates early steps of dsDNA break repair using purified RecA, RecF, RecO, RecR, RecQ, RecJ, and SSB proteins, components of the RecF system. Their combined action results in processing of linear dsDNA and its homologous pairing with supercoiled DNA. RecA, RecO, RecR, and RecJ are essential for joint molecule formation, whereas SSB and RecF are stimulatory. This reconstituted system reveals an unexpected essential function for RecJ exonuclease: the capability to resect duplex DNA. RecQ helicase stimulates this processing, but also disrupts joint molecules. RecO and RecR have two indispensable functions: They mediate exchange of RecA for SSB to form the RecA nucleoprotein filament, and act with RecF to load RecA onto the SSB-ssDNA complex at processed ssDNA-dsDNA junctions. The RecF pathway has many parallels with recombinational repair in eukaryotes.

The RecF protein antagonizes RecX function via direct interaction

The RecX protein inhibits RecA filament extension, leading to net filament disassembly. The RecF protein physically interacts with the RecX protein and protects RecA from the inhibitory effects of RecX. In vitro, efficient RecA filament formation onto single-stranded DNA binding protein (SSB)-coated circular single-stranded DNA (ssDNA) in the presence of RecX occurs only when all of the RecFOR proteins are present. The RecOR proteins contribute only to RecA filament nucleation onto SSB-coated single-stranded DNA and are unable to counter the inhibitory effects of RecX on RecA filaments. RecF protein uniquely supports substantial RecA filament extension in the presence of RecX. In vivo, RecF protein counters a RecX-mediated inhibition of plasmid recombination. Thus, a significant positive contribution of RecF to RecA filament assembly is to antagonize the effects of the negative modulator RecX, specifically during the extension phase.

Modulation of DNA repair and recombination by the bacteriophage lambda Orf function in Escherichia coli K-12

The orf gene of bacteriophage lambda, fused to a promoter, was placed in the galK locus of Escherichia coli K-12. Orf was found to suppress the recombination deficiency and sensitivity to UV radiation of mutants, in a Delta(recC ptr recB recD)::P(tac) gam bet exo pae cI DeltarecG background, lacking recF, recO, recR, ruvAB, and ruvC functions. It also suppressed defects of these mutants in establishing replication of a pSC101-related plasmid. Compared to orf, the recA803 allele had only small effects on recF, recO, and recR mutant phenotypes and no effect on a ruvAB mutant. In a fully wild-type background with respect to known recombination and repair functions, orf partially suppressed the UV sensitivity of ruvAB and ruvC mutants.

RecFOR proteins load RecA protein onto gapped DNA to accelerate DNA strand exchange: a universal step of recombinational repair

Genetic evidence suggests that the RecF, RecO, and RecR (RecFOR) proteins participate in a common step of DNA recombination and repair, yet the biochemical event requiring collaboration of all three proteins is unknown. Here, we show that the concerted action of the RecFOR complex directs the loading of RecA protein specifically onto gapped DNA that is coated with single-stranded DNA binding (SSB) protein, thereby accelerating DNA strand exchange. The RecFOR complex recognizes the junction between the ssDNA and dsDNA regions and requires a base-paired 5' terminus at the junction. Thus, the RecFOR complex is a structure-specific mediator that targets recombinational repair to ssDNA-dsDNA junctions. This reaction reconstitutes the initial steps of recombinational gapped DNA repair and uncovers an event also common to the repair of ssDNA-tailed intermediates of dsDNA-break repair. We propose that the behavior of the RecFOR proteins is mimicked by functional counterparts that exist in all organisms.

Mutations in yeast Rad51 that partially bypass the requirement for Rad55 and Rad57 in DNA repair by increasing the stability of Rad51-DNA complexes

Yeast Rad51 promotes homologous pairing and strand exchange in vitro, but this activity is inefficient in the absence of the accessory proteins, RPA, Rad52, Rad54 and the Rad55-Rad57 heterodimer. A class of rad51 alleles was isolated that suppresses the requirement for RAD55 and RAD57 in DNA repair, but not the other accessory factors. Five of the six mutations isolated map to the region of Rad51 that by modeling with RecA corresponds to one of the DNA-binding sites. The other mutation is in the N-terminus of Rad51 in a domain implicated in protein-protein interactions and DNA binding. The Rad51-I345T mutant protein shows increased binding to single- and double-stranded DNA, and is proficient in displacement of replication protein A (RPA) from single-stranded DNA, suggesting that the normal function of Rad55-Rad57 is promotion and stabilization of Rad51-ssDNA complexes.

Gene products encoded in the ninR region of phage lambda participate in Red-mediated recombination

BACKGROUND

The ninR region of phage lambda contains two recombination genes, orf (ninB) and rap (ninG), that were previously shown to have roles when the RecF and RecBCD recombination pathways of E. coli, respectively, operate on phage lambda.

RESULTS

When lambda DNA replication is blocked, recombination is focused at the termini of the virion chromosome. Deletion of the ninR region of lambda decreases the sharpness of the focusing without diminishing the overall rate of recombination. The phenotype is accounted for in large part by the deletion of rap and of orf. Mutation of the recJ gene of the host partially suppresses the Rap- phenotype.

CONCLUSION

ninR functions Orf and Rap participate in Red recombination, the primary pathway operating when wild-type lambda grows lytically in rec+ cells. The ability of recJ mutation to suppress the Rap- phenotype indicates that RecJ exonuclease can participate in Red-mediated recombination, at least in the absence of Rap function. A model is presented for Red-mediated RecA-dependent recombination that includes these newly identified participants.

Genetic requirements of phage lambda red-mediated gene replacement in Escherichia coli K-12

Recombination between short linear double-stranded DNA molecules and Escherichia coli chromosomes bearing the red genes of bacteriophage lambda in place of recBCD was tested in strains bearing mutations in genes known to affect recombination in other cellular pathways. The linear DNA was a 4-kb fragment containing the cat gene, with flanking lac sequences, released from an infecting phage chromosome by restriction enzyme cleavage in the cell; formation of Lac(-) chloramphenicol-resistant bacterial progeny was measured. Recombinant formation was found to be reduced in ruvAB and recQ strains. In this genetic background, mutations in recF, recO, and recR had large effects on both cell viability and on recombination. In these cases, deletion of the sulA gene improved viability and strain stability, without improving recombination ability. Expression of a gene(s) from the nin region of phage lambda partially complemented both the viability and recombination defects of the recF, recO, and recR mutants and the recombination defect of ruvC but not of ruvAB or recQ mutants.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

Involvement of recF, recO, and recR genes in UV-radiation mutagenesis of Escherichia coli

The recF, recO, and recR genes were originally identified as those affecting the RecF pathway of recombination in Escherichia coli cells. Several lines of evidence suggest that the recF, recO, and recR genes function at the same step of recombination and postreplication repair. In this work, we report that null mutations in recF, recO, or recR greatly reduce UV-radiation mutagenesis (UVM) in an assay for reversion from a Trp- (trpE65) to a Trp+ phenotypes. Introduction of the defective lexA51 mutation [lexA51(Def)] and/or UmuD' into recF, recO, and recR mutants failed to restore normal UVM in the mutants. On the other hand, the presence of recA2020, a suppressor mutation for recF, recO, and recR mutations, restored normal UVM in recF, recO, and recR mutants. These results indicate an involvement of the recF, recO, and recR genes and their products in UVM, possibly by affecting the third role of RecA in UVM.

Biochemical basis of hyper-recombinogenic activity of Pseudomonas aeruginosa RecA protein in Escherichia coli cells

The replacement of Escherichia coli recA gene (recA[Ec]) with the Pseudomonas aeruginosa recA(Pa) gene in Escherichia coli cells results in constitutive hyper-recombination (high frequency of recombination exchanges per unit length of DNA) in the absence of constitutive SOS response. To understand the biochemical basis of this unusual in vivo phenotype, we compared in vitro the recombination properties of RecA(Pa) protein with those of RecA(Ec) protein. Consistent with hyper-recombination activity, RecA(Pa) protein appeared to be more proficient both in joint molecule formation, producing extensive DNA networks in strand exchange reaction, and in competition with single-stranded DNA binding (SSB) protein for single-stranded DNA (ssDNA) binding sites. The RecA(Pa) protein showed in vitro a normal ability for cleavage of the E. coli LexA repressor (a basic step in SOS regulon derepression) both in the absence and in the presence (i.e. even under suboptimal conditions for RecA(Ec) protein) of SSB protein. However, unlike other hyper-recombinogenic proteins, such as RecA441 and RecA730, RecA(Pa) protein displaced insufficient SSB protein from ssDNA at low magnesium concentration to induce the SOS response constitutively. In searching for particular characteristics of RecA(Pa) in comparison with RecA(Ec), RecA441 and RecA803 proteins, RecA(Pa) showed unusually high abilities: to be resistant to the displacement by SSB protein from poly(dT); to stabilize a ternary complex RecA::ATP::ssDNA to high salt concentrations; and to be much more rapid in both the nucleation of double-stranded DNA (dsDNA) and the steady-state rate of dsDNA-dependent ATP hydrolysis at pH7.5. We hypothesized that the high affinity of RecA(Pa) protein for ssDNA, and especially dsDNA, is the factor that directs the ternary complex to bind secondary DNA to initiate additional acts of recombination instead of to bind LexA repressor to induce constitutive SOS response.

Interactions of RecF protein with RecO, RecR, and single-stranded DNA binding proteins reveal roles for the RecF-RecO-RecR complex in DNA repair and recombination

The products of the recF, recO, and recR genes are thought to interact and assist RecA in the utilization of single-stranded DNA precomplexed with single-stranded DNA binding protein (Ssb) during synapsis. Using immunoprecipitation, size-exclusion chromatography, and Ssb protein affinity chromatography in the absence of any nucleotide cofactors, we have obtained the following results: (i) RecF interacts with RecO, (ii) RecF interacts with RecR in the presence of RecO to form a complex consisting of RecF, RecO, and RecR (RecF-RecO-RecR); (iii) RecF interacts with Ssb protein in the presence of RecO. These data suggested that RecO mediates the interactions of RecF protein with RecR and with Ssb proteins. Incubation of RecF, RecO, RecR, and Ssb proteins resulted in the formation of RecF-RecO-Ssb complexes; i.e., RecR was excluded. Preincubation of RecF, RecO, and RecR proteins prior to addition of Ssb protein resulted in the formation of complexes consisting of RecF, RecO, RecR, and Ssb proteins. These data suggest that one role of RecF is to stabilize the interaction of RecR with RecO in the presence of Ssb protein. Finally, we found that interactions of RecF with RecO are lost in the presence of ATP. We discuss these results to explain how the RecF-RecO-RecR complex functions as an anti-Ssb factor.

Preferential binding of Escherichia coli RecF protein to gapped DNA in the presence of adenosine (gamma-thio) triphosphate

Escherichia coli RecF protein binds, but does not hydrolyze, ATP. To determine the role that ATP binding to RecF plays in RecF protein-mediated DNA binding, we have determined the interaction between RecF protein and single-stranded (ss)DNA, double-stranded (ds)DNA, and dsDNA containing ssDNA regions (gapped [g]DNA) either alone or in various combinations both in the presence and in the absence of adenosine (gamma-thio) triphosphate, gamma-S-ATP, a nonhydrolyzable ATP analog. Protein-DNA complexes were analyzed by electrophoresis on agarose gels and visualized by autoradiography. The type of protein-DNA complexes formed in the presence of gamma-S-ATP was different with each of the DNA substrates and from those formed in the absence of gamma-S-ATP. Competition experiments with various combinations of DNA substrates indicated that RecF protein preferentially bound gDNA in the presence of gamma-S-ATP, and the order of preference of binding was gDNA > dsDNA > ssDNA. Since gDNA has both ds- and ssDNA components, we suggest that the role for ATP in RecF protein-DNA interactions in vivo is to confer specificity of binding to dsDNA-ssDNA junctions, which is necessary for catalyzing DNA repair and recombination.

Homologous pairing of single-stranded DNA and superhelical double-stranded DNA catalyzed by RecO protein from Escherichia coli

The recO gene product is required for DNA repair and some types of homologous recombination in wild-type Escherichia coli cells. RecO protein has been previously purified and shown to bind to single- and double-stranded DNA and to promote the renaturation of complementary single-stranded DNA molecules. In this study, purified RecO protein was shown to catalyze the assimilation of single-stranded DNA into homologous superhelical double-stranded DNA, an activity also associated with RecA protein. The RecO protein-promoted strand assimilation reaction requires Mg2+ and is ATP independent. Because of the biochemical similarities between RecO and RecA proteins, the ability of RecO protein to substitute for RecA protein in DNA repair in vivo was also assessed in this study. The results show that overexpression of RecO protein partially suppressed the UV repair deficiency of a recA null mutant and support the hypothesis that RecO and RecA proteins are functionally similar with respect to strand assimilation and the ability to enhance UV survival. These results suggest that RecO and RecA proteins may have common functional properties.

The phage lambda orf gene encodes a trans-acting factor that suppresses Escherichia coli recO, recR, and recF mutations for recombination of lambda but not of E. coli

Bacteriophage lambda can recombine in recBC sbcB sbcC mutant cells by using its own gene orf, the Escherichia coli recO, recR, and recF genes, or both. Expression of an orf-containing plasmid complements the recombination defects of orf mutant phage. However, this clone does not complement a recO mutation for conjugational recombination or recO, recR, or recF mutations for repair of UV-induced DNA damage. A plasmid clone of orf produces a protein with an apparent molecular mass of 15 kDa.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

Chi-dependent formation of linear plasmid DNA in exonuclease-deficient recBCD+ strains of Escherichia coli

Escherichia coli strains carrying mutations in sbcB (exonuclease I) or xthA (exonuclease III) accumulate high-molecular-weight linear plasmid concatemers when transformed with plasmids containing the chi sequence, 5'-GCTGGTGG-3'. Chi-dependent formation of high-molecular-weight plasmid DNA is dependent on recA and recF functions. In addition, chi stimulation occurs only in cis. Our data are consistent with models in which RecA and RecF proteins bind to and protect the DNA ends produced by RecBCD-chi interaction.

RecOR suppression of recF mutant phenotypes in Escherichia coli K-12

The recF, recO, and recR genes form the recFOR epistasis group for DNA repair. recF mutants are sensitive to UV irradiation and fail to properly induce the SOS response. Using plasmid derivatives that overexpress combinations of the recO+ and recR+ genes, we tested the hypothesis that high-level expression of recO+ and recR+ (recOR) in vivo will indirectly suppress the recF mutant phenotypes mentioned above. We found that overexpression of just recR+ from the plasmid will partially suppress both phenotypes. Expression of the chromosomal recO+ gene is essential for the recR+ suppression. Hence we call this RecOR suppression of recF mutant phenotypes. RecOR suppression of SOS induction is more efficient with recO+ expression from a plasmid than with recO+ expression from the chromosome. This is not true for RecOR suppression of UV sensitivity (the two are equal). Comparison of RecOR suppression with the suppression caused by recA801 and recA803 shows that RecOR suppression of UV sensitivity is more effective than recA803 suppression and that RecOR suppression of UV sensitivity, like recA801 suppression, requires recJ+. We present a model that explains the data and proposes a function for the recFOR epistasis group in the induction of the SOS response and recombinational DNA repair.

Novel mechanism for UV sensitivity and apparent UV nonmutability of recA432 mutants: persistent LexA cleavage following SOS induction

The recA432 mutant allele was isolated (T. Kato and Y. Shinoura, Mol. Gen. Genet. 156:121-131, 1977) by virtue of its defect in cellular mutagenesis (Mut-) and its hypersensitivity to damage by UV irradiation (UVs), which were phenotypes expected for a recA mutant. However, we found that in a different genetic background (lexA51 sulA211 uvrB+), recA432 mutants expressed certain mutant phenotypes but not the Mut- and UVs phenotypes (D.G. Ennis, N. Ossanna, and D.W. Mount, J. Bacteriol. 171:2533-2541, 1989). We present several lines of evidence that these differences resulted from the sulA genotype of the cell and that the apparent UVs and Mut- phenotypes of the sulA+ derivatives resulted from lethal filamentation of induced cells because of persistent derepression of sulA. First, transduction of sulA(Def) mutations into the recA432 strains restored cellular mutagenesis and resistance to UV. Second, recA432 sulA+ strains underwent filamentous death following SOS-inducing treatments. Third, cleavage of LexA repressor in a recA432 strain continued at a rapid rate long after UV induction, at a time when cleavage of the repressor in the recA+ parental strain had substantially declined. Fourth, we confirmed that a single mutation (recA432) conferring both the UVs and Mut- phenotypes mapped to the recA gene. These findings indicate that the RecA432 mutant protein is defective in making the transition back to the deactivated state following SOS induction; thus, the SOS-induced state of recA432 mutants is prolonged and can account for an excess of SulA protein, leading to filamentation. These results are discussed in the context of molecular models for RecA activation for LexA and UmuD cleavage and their roles in the control of mutagenesis and cell division in the SOS response.

Cosuppression of recF, recR and recO mutations by mutant recA alleles in Escherichia coli cells

The ability of recA718, recA720, recA730, recA750 and two known recA(Srf) alleles (recA2020 and recA441) to act as suppressors of recF, recR and recO mutations was examined by studying their UV radiation sensitivity in uvrA cells of Escherichia coli. With the exception of recA718, all the mutant recA alleles examined were able to suppress the UV radiation sensitivity caused by recF, recR or recO mutations, but not by the recB mutation. The suppression by recA750 was minimal. The suppression of recF, recR and recO mutations by other recA alleles was more pronounced, but none of them could exert full suppression. Heterozygotes containing a mutant recA allele (recA720, recA730 or recA441) and recA2020 (or recA803, another known recA(Srf) allele) failed to produce any additive or synergistic suppression of recF, indicating that these suppressors did not use different mechanisms for their suppression. Similar to a requirement of recJ+ in the suppression of recF, the suppression of recR and recO mutations by mutant recA alleles also required recJ+. The similar phenotypes conferred by recF, recR, and recO mutations and the observations that a number of mutant recA alleles can cosuppress these three mutations suggest that the recF, recR and recO gene products may function together as a complex.

Evidence for ATP binding and double-stranded DNA binding by Escherichia coli RecF protein

RecF protein is one of the important proteins involved in DNA recombination and repair. RecF protein has been shown to bind single-stranded DNA (ssDNA) in the absence of ATP (T. J. Griffin IV and R. D. Kolodner, J. Bacteriol. 172:6291-6299, 1990; M. V. V. S. Madiraju and A. J. Clark, Nucleic Acids Res. 19:6295-6300, 1991). In the present study, using 8-azido-ATP, a photo-affinity analog of ATP, we show that RecF protein binds ATP and that the binding is specific in the presence of DNA. 8-Azido-ATP photo-cross-linking is stimulated in the presence of DNA (both ssDNA and double-stranded DNA [dsDNA]), suggesting that DNA enhances the affinity of RecF protein for ATP. These data suggest that RecF protein possesses independent ATP- and DNA-binding sites. Further, we find that stable RecF protein-dsDNA complexes are obtained in the presence of ATP or ATP-gamma-S [adenosine-5'-O-(3-thio-triphosphate)]. No other nucleoside triphosphates served as necessary cofactors for dsDNA binding, indicating that RecF is an ATP-dependent dsDNA-binding protein. Since a mutation in a putative phosphate-binding motif of RecF protein results in a recF mutant phenotype (S. J. Sandler, B. Chackerian, J. T. Li, and A. J. Clark, Nucleic Acids Res. 20:839-845, 1992), we suggest on the basis of our data that the interactions of RecF protein with ATP, with dsDNA, or with both are physiologically important for understanding RecF protein function in vivo.

Sequence and complementation analysis of recF genes from Escherichia coli, Salmonella typhimurium, Pseudomonas putida and Bacillus subtilis: evidence for an essential phosphate binding loop

We have compared the recF genes from Escherichia coli K-12, Salmonella typhimurium, Pseudomonas putida, and Bacillus subtilis at the DNA and amino acid sequence levels. To do this we determined the complete nucleotide sequence of the recF gene from Salmonella typhimurium and we completed the nucleotide sequence of recF gene from Pseudomonas putida begun by Fujita et al. (1). We found that the RecF proteins encoded by these two genes contain respectively 92% and 38% amino acid identity with the E. coli RecF protein. Additionally, we have found that the S. typhimurium and P. putida recF genes will complement an E. coli recF mutant, but the recF gene from Bacillus subtilis [showing about 20% identity with E. coli (2)] will not. Amino acid sequence alignment of the four proteins identified four highly conserved regions. Two of these regions are part of a putative phosphate binding loop. In one region (position 36), we changed the lysine codon (which is essential for ATPase, GTPase and kinase activity in other proteins having this phosphate binding loop) to an arginine codon. We then tested this mutation (recF4101) on a multicopy plasmid for its ability to complement a recF chromosomal mutation and on the E. coli chromosome for its effect on sensitivity to UV irradiation. The strain with recF4101 on its chromosome is as sensitive as a null recF mutant strain. The strain with the plasmid-borne mutant allele is however more UV resistant than the null mutant strain. We conclude that lysine-36 and possibly a phosphate binding loop is essential for full recF activity. Lastly we made two chimeric recF genes by exchanging the amino terminal 48 amino acids of the S. typhimurium and E. coli recF genes. Both chimeras could complement E. coli chromosomal recF mutations.

Phage lambda has an analog of Escherichia coli recO, recR and recF genes

The RecF pathway catalyzes generalized recombination in Escherichia coli that is mutant for recBC, sbcB and sbcC. This pathway operating on conjugational recombination requires the recA, recF, recJ, recN, recO, recQ, recR, ruvA, ruvB and ruvC genes. In contrast, lambda mutant for its own recombination genes, int, red alpha and red beta, requires only the recA and recJ genes to recombine efficiently in recBC sbcB sbcC cells. Deletion of an open reading frame in the ninR region of lambda results in an additional requirement for recO, recR and recF in order to recombine in recBC sbcB sbcC mutant cells. This function, designated orf for recO-, recR- and recF-like function, is largely RecF pathway specific.

Effect of RecF protein on reactions catalyzed by RecA protein

RecF protein is one of at least three single strand DNA (ssDNA) binding proteins which act in recombination and repair in Escherichia coli. In this paper we show that our RecF protein preparation complexes with ssDNA so as to retard its electrophoretic movement in an agarose gel. The apparent stoichiometry of RecF-ssDNA-binding measured in this way is one RecF molecule for every 15 nucleotides and the binding appears to be cooperative. Interaction of the other two ssDNA-binding proteins, RecA and Ssb proteins, has been studied extensively; so in this paper we begin the study of the interaction of RecF and RecA proteins. We found that the RecF protein preparation inhibits the activity of RecA protein in the formation of joint molecules whether added before or after addition of RecA protein to ssDNA. It, therefore, differs from Ssb protein which stimulates joint molecule formation when added to ssDNA after RecA protein. We found that our RecF protein preparation inhibits two steps prior to joint molecule formation: RecA protein binding to ssDNA and coaggregate formation between ssDNA-RecA complexes and dsDNA. We found that it required a much higher ratio of RecF to RecA protein than normally occurs in vivo to inhibit joint molecule formation. The insight that these data give to the normal functioning of RecF protein is discussed.

Constitutive and UV-mediated activation of RecA protein: combined effects of recA441 and recF143 mutations and of addition of nucleosides and adenine

The recF143 mutant of Escherichia coli is deficient in certain functions that also require the RecA protein: cell survival after DNA damage, some pathways of genetic recombination, and induction of SOS genes and temperate bacteriophage through cleavage of the LexA and phage repressors. To characterize the role of RecF in SOS induction and RecA activation, we determined the effects of the recF143 mutation on the rate of RecA-promoted cleavage of LexA, the repressor of the SOS genes. We show that RecA activation following UV irradiation is delayed by recF143 and that RecF is specifically involved in the SOS induction pathway that requires DNA replication. At 32 degrees C, the recA441 mutation partially suppresses the defect of recF mutants in inducing the SOS system in response to UV irradiation (A. Thomas and R. G. Lloyd, J. Gen. Microbiol. 129:681-686, 1983; M. R. Volkert, L. J. Margossian, and A. J. Clark, J. Bacteriol. 160:702-705, 1984); we find that this suppression occurs at the earliest detectable phase of LexA cleavage and does not require protein synthesis. Our results support the idea that following UV irradiation, RecF enhances the activation of RecA into a form that promotes LexA cleavage (A. Thomas and R. G. Lloyd, J. Gen. Microbiol. 129:681-686, 1983; M. V. V. S. Madiraju, A. Templin, and A. J. Clark, Proc. Natl. Acad. Sci. USA 85:6592-6596, 1988). In contrast to the constitutive activation phenotype of the recA441 mutant, the recA441-mediated suppression of recF is not affected by adenine and nucleosides. We also find that wild-type RecA protein is somewhat activated by adenine in the absence of DNA damage.

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.

Activation of RecA protein in recombination-deficient strains of Escherichia coli following DNA-damaging treatments

Activation of the RecA protein following UV-irradiation or bleomycin (BM) treatment was measured in rec mutants of E. coli by monitoring beta-galactosidase activity. We provide evidence here that the defect in the recN mutant results in high constitutive and induced levels of activated RecA protein. In all rec mutants studied, with the exception of the recN mutant, induction of enzyme activity, following DNA-damaging treatments, was reduced relative to the wild type. The kinetics of induced sfiA expression indicates that the DNA-unwinding activity of the RecBCD enzyme plays a major role in SOS-signal formation. The RecF protein is not needed for BM induction in strains with a functional RecBCD pathway of recombination. However, a functional product of recF gene is implied in the formation of an efficient inducing signal after UV-irradiation, as well as in the additional processing of BM-induced lesions after exposure to the drug. A fully expressed RecF pathway of recombination does not provide a high level of activated RecA protein following DNA-damaging treatments.

The single-stranded DNA-binding protein of Escherichia coli

The single-stranded DNA-binding protein (SSB) of Escherichia coli is involved in all aspects of DNA metabolism: replication, repair, and recombination. In solution, the protein exists as a homotetramer of 18,843-kilodalton subunits. As it binds tightly and cooperatively to single-stranded DNA, it has become a prototypic model protein for studying protein-nucleic acid interactions. The sequences of the gene and protein are known, and the functional domains of subunit interaction, DNA binding, and protein-protein interactions have been probed by structure-function analyses of various mutations. The ssb gene has three promoters, one of which is inducible because it lies only two nucleotides from the LexA-binding site of the adjacent uvrA gene. Induction of the SOS response, however, does not lead to significant increases in SSB levels. The binding protein has several functions in DNA replication, including enhancement of helix destabilization by DNA helicases, prevention of reannealing of the single strands and protection from nuclease digestion, organization and stabilization of replication origins, primosome assembly, priming specificity, enhancement of replication fidelity, enhancement of polymerase processivity, and promotion of polymerase binding to the template. E. coli SSB is required for methyl-directed mismatch repair, induction of the SOS response, and recombinational repair. During recombination, SSB interacts with the RecBCD enzyme to find Chi sites, promotes binding of RecA protein, and promotes strand uptake.

Purification and preliminary characterization of the Escherichia coli K-12 recF protein

The recF gene of Escherichia coli is known to encode an Mr-40,000 protein that is involved in DNA recombinationa nd postreplication DNA repair. To characterize the role of the recF gene product in these processes, the recF gene was cloned downstream of a tac promoter to facilitate overproduction of the recF gene product. The RecF protein was overproduced and purified to apparent homogeneity. N-terminal protein sequence analysis demonstrated that the purified protein had the sequence that was predicted from the DNA sequence of the recF gene, except that the predicted N-terminal Met was not present. The RecF protein bound to single-stranded oligonucleotides in filter binding and gel filtration assays. Maximal binding required 2 to 3 min of incubation at 37 degrees C; the binding reaction had a pH optimum of 7.0, did not require divalent cations, and was inhibited by NaCl concentrations of greater than 250 mM. The Kd of RecF protein binding to a 59-base single-stranded oligonucleotide was on the order of 1.3 X 10(-7) M, and the reaction did not show cooperativity. Experiments measuring the binding to various DNA substrates and competition binding experiments with different DNA molecules demonstrated that RecF protein binds preferentially to single-stranded, linear DNA molecules.

Use of recA803, a partial suppressor of recF, to analyze the effects of the mutant Ssb (single-stranded DNA-binding) proteins in vivo and in vitro

We examined the possibility that the ssb-1 and ssb-113 mutants exert some of their effects by interfering with the normal function of wild-type RecF protein. Consistent with this possibility, we found that recA803, which partially suppresses recF mutations, also partially suppresses both ssb mutations, as detected by an increase in UV resistance. No evidence was obtained for suppression of the defect in lexA regulon inducibility caused by the ssb mutations. Consequently we suggest that suppression occurs by increasing recombinational repair. In vitro tests of Ssb mutant and wild-type proteins revealed that the single-stranded DNA dependent ATPase activity of RecA protein is more susceptible to inhibition than the joint-molecule-forming activity. All three Ssb proteins inhibit the ATPase activity of RecA wild-type protein almost completely while under similar conditions they inhibit the joint-molecule-forming activity only slightly. Both activities of RecA803 protein were found to be less inhibited by the three Ssb proteins than those of RecA wild-type protein. This is consistent with the suppressing ability of recA803. We found no evidence to contradict the previously proposed hypothesis that ssb-1 affects recombinational repair by acting as a weaker form of Ssb protein. We found, however, only very weak evidence that Ssb-113 protein interferes directly with recombinational repair so that the possibility that it interferes with a normal function of RecF protein must remain open.

Participation of rec genes of Escherichia coli K 12 in W-reactivation of UV-irradiated phage lambda

The effect of the recombinational deficiency on W-reactivation of UV-damaged phage lambda was explored. In this paper we show that W-reactivation is reduced by the recB21 and recF143 mutations after bleomycin (BM) and UV treatment. Combination of these mutations in the recB21recF143 double mutant blocks W-reactivation completely after BM induction, but leaves residual W-reactivation ability after UV-irradiation, which is abolished by the introduction of uvrB deficiency (delta(uvrB-chlA]. W-reactivation has been rendered constitutive in recB21C22sbcB15, but the efficiency of reactivation remained virtually constant over the range of BM and UV doses, indicating the role of the RecBC(D) enzyme in W-reactivation.

Factors affecting expression of the recF gene of Escherichia coli K-12

This report describes four factors which affect expression of the recF gene from strong upstream lambda promoters under temperature-sensitive cIAt2-encoded repressor control. The first factor was the long mRNA leader sequence consisting of the Escherichia coli dnaN gene and 95% of the dnaA gene and lambda bet, N (double amber) and 40% of the exo gene. When most of this DNA was deleted, RecF became detectable in maxicells. The second factor was the vector, pBEU28, a runaway replication plasmid. When we substituted pUC118 for pBEU28, RecF became detectable in whole cells by the Coomassie blue staining technique. The third factor was the efficiency of initiation of translation. We used site-directed mutagenesis to change the mRNA leader, ribosome-binding site and the 3 bp before and after the translational start codon. Monitoring the effect of these mutational changes by translational fusion to lacZ, we discovered that the efficiency of initiation of translation was increased 30-fold. Only an estimated two- or threefold increase in accumulated levels of RecF occurred, however. This led us to discover the fourth factor, namely sequences in the recF gene itself. These sequences reduce expression of the recF-lacZ fusion genes 100-fold. The sequences responsible for this decrease in expression occur in four regions in the N-terminal half of recF. Expression is reduced by some sequences at the transcriptional level and by others at the translational level.

A mutation of Streptomyces lividans which prevents intraplasmid recombination has no effect on chromosomal recombination

A mutation (rec-46) of Streptomyces lividans, previously shown to prevent (or greatly diminish) homologous and illegitimate intraplasmid recombination, was shown to have no effect on generalised chromosomal recombination occurring in matings or in protoplast fusions, nor to affect homologous recombination between a recombinant plasmid and the host chromosome. By comparison with Escherichia coli mutants defective in various aspects of recombination, the rec-46 mutation is similar to those in recF, recJ, recO and topA.

Suppression of recA deficiency in plasmid recombination by bacteriophage lambda beta protein in RecBCD- ExoI- Escherichia coli cells

Plasmid recombination, like other homologous recombination in Escherichia coli, requires RecA protein in most conditions. We have found that the plasmid recombination defect in a recA mutant can be efficiently suppressed by the beta protein of bacteriophage lambda. beta protein is required for homologous recombination of lambda chromosomes during lytic phage growth in a recA host and is known to have a strand-annealing activity resembling that of RecA protein. The bioluminescence recombination assay was used for genetic analysis of beta-protein-mediated plasmid recombination. Efficient suppression of the recA mutation by beta protein required the absence of the E. coli nucleases exonuclease I and RecBCD nuclease. These nucleases inhibit a RecA-mediated plasmid recombination pathway that is more efficient than the pathway functioning in wild-type cells. Like RecA-mediated plasmid recombination in RecBCD- ExoI- cells, beta-protein-mediated plasmid recombination depended on concurrent DNA replication and on the activity of the recQ gene. However, unlike RecA-mediated plasmid recombination, beta-protein-mediated recombination in RecBCD- ExoI- cells was independent of recF and recJ activities. We propose that inactivation of exonuclease I and RecBCD nuclease stabilizes a recombination intermediate that is involved in RecA- and beta-protein-catalyzed homologous pairing reactions. We suggest that the intermediate may be linear plasmid DNA with a protruding 3' end, since these nucleases are known to interfere with the synthesis of such linear forms. The different recF and recJ requirements for beta-protein-dependent and RecA-dependent recombinations imply that the mechanisms of formation or processing of the putative intermediate differ in the two cases.

Genetic separation of Escherichia coli recA functions for SOS mutagenesis and repressor cleavage

Evidence is presented that recA functions which promote the SOS functions of mutagenesis, LexA protein proteolysis, and lambda cI repressor proteolysis are each genetically separable from the others. This separation was observed in recombination-proficient recA mutants and rec+ (F' recA56) heterodiploids. recA430, recA433, and recA435 mutants and recA+ (F' recA56) heterodiploids were inducible for only one or two of the three functions and defective for mutagenesis. recA80 and recA432 mutants were constitutively activated for two of the three functions in that these mutants did not have to be induced to express the functions. We propose that binding of RecA protein to damaged DNA and subsequent interaction with small inducer molecules gives rise to conformational changes in RecA protein. These changes promote surface-surface interactions with other target proteins, such as cI and LexA proteins. By this model, the recA mutants are likely to have incorrect amino acids substituted as sites in the RecA protein structure which affect surface regions required for protein-protein interactions. The constitutively activated mutants could likewise insert altered amino acids at sites in RecA which are involved in the activation of RecA protein by binding small molecules or polynucleotides which metabolically regulate RecA protein.

Altered induction of the adaptive response to alkylation damage in Escherichia coli recF mutants

Escherichia coli recF mutants are hypermutable when treated with methyl methanesulfonate (G. C. Walker, Mol. Gen. Genet. 152:93-103, 1977). In this study, methylation hypermutability of recF mutant strains was examined, and it was found that recF+ is required for normal induction of the adaptive response to alkylation damage. Although this regulatory effect of recF mutations results in reduced levels of enzymes that specifically repair methyl lesions in DNA, it only partially explains the hypermutability. Further examination showed that methylation hypermutability of recF mutant strains required a functional umuDC operon, a component of the SOS response. These results lead to the hypothesis that methylation hypermutability results from the effects of recF mutations on the induction of both the SOS response and the adaptive response.

Properties of a mutant recA-encoded protein reveal a possible role for Escherichia coli recF-encoded protein in genetic recombination

A mutation partially suppressing the UV sensitivity caused by recF143 in a uvrA6 background was located at codon 37 of recA where GTG (valine) became ATG (methionine). This mutation, originally named srf-803, was renamed recA803. Little if any suppression of the recF143 defect in UV induction of a lexA regulon promoter was detected. This led to the hypothesis that a defect in recombination repair of UV damage was suppressed by recA803. The mutant RecA protein (RecA803) was purified and compared with wild-type protein (RecA+) as a catalyst of formation of joint molecules. Under suboptimal conditions, RecA803 produces both a higher rate of formation and a higher yield of joint molecules. The suboptimal conditions tested included addition of single-stranded DNA binding protein to single-stranded DNA prior to addition of RecA. We hypothesize that the ability of RecA803 to overcome interference by single-stranded DNA binding protein is the property that allows recA803 to suppress partially the deficiency in repair caused by recF mutations in the uvrA6 background. Implications of this hypothesis for the function of RecF protein in recombination are discussed.

Suppression of the UV-sensitive phenotype of Escherichia coli recF mutants by recA(Srf) and recA(Tif) mutations requires recJ+

Mutations in recA, such as recA801(Srf) (suppressor of RecF) or recA441(Tif) (temperature-induced filamentation) partially suppress the deficiency in postreplication repair of UV damage conferred by recF mutations. We observed that spontaneous recA(Srf) mutants accumulated in cultures of recB recC sbcB sulA::Mu dX(Ap lac) lexA51 recF cells because they grew faster than the parental strain. We show that in a uvrA recB+ recC+ genetic background there are two prerequisites for the suppression by recA(Srf) of the UV-sensitive phenotype of recF mutants. (i) The recA(Srf) protein must be provided in increased amounts either by SOS derepression or by a recA operator-constitutive mutation in a lexA(Ind) (no induction of SOS functions) genetic background. (ii) The gene recJ, which has been shown previously to be involved in the recF pathway of recombination and repair, must be functional. The level of expression of recJ in a lexA(Ind) strain suffices for full suppression. Suppression by recA441 at 30 degrees C also depends on recJ+. The hampered induction by UV of the SOS gene uvrA seen in a recF mutant was improved by a recA(Srf) mutation. This improvement did not require recJ+. We suggest that recA(Srf) and recA(Tif) mutant proteins can operate in postreplication repair independent of recF by using the recJ+ function.

Overproduction of single-stranded-DNA-binding protein specifically inhibits recombination of UV-irradiated bacteriophage DNA in Escherichia coli

Overproduction of single-stranded DNA (ssDNA)-binding protein (SSB) in uvr Escherichia coli mutants results in a wide range of altered phenotypes. (i) Cell survival after UV irradiation is decreased; (ii) expression of the recA-lexA regulon is slightly reduced after UV irradiation, whereas it is increased without irradiation; and (iii) recombination of UV-damaged lambda DNA is inhibited, whereas recombination of nonirradiated DNA is unaffected. These results are consistent with the idea that in UV-damaged bacteria, SSB is first required to allow the formation of short complexes of RecA protein and ssDNA that mediate cleavage of the LexA protein. However, in a second stage, SSB should be displaced from ssDNA to permit the production of longer RecA-ssDNA nucleoprotein filaments that are required for strand pairing and, hence, recombinational repair. Since bacteria overproducing SSB appear identical in physiological respects to recF mutant bacteria, it is suggested that the RecF protein (alone or with other proteins of the RecF pathway) may help RecA protein to release SSB from ssDNA.

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.

Role of rec genes in SOS-induced inhibition of cell division in Escherichia coli

The inhibition of cell division induced by bleomycin (BM) and UV irradiation in the set of rec mutants of E. coli K12 was studied. Data presented in this work indicate that BM treatment requires mainly the RecBC pathway for the induction of cell filamentation. In the recB21 mutant cell filamentation is delayed and reduced compared to the wild type. Cell filamentation is BM-induced with similar kinetics in strains with a proficient RecBC recombination pathway (rec+, recF143 and recN262), as well as in the strain with a fully expressed RecF pathway (recB21recC22sbcB15). Induction is completely abolished in the recB21recF143 double mutant. On the other hand cell filamentation was induced similarly by UV irradiation in all strains with a functional recF gene and in the strain with a fully operative RecF pathway, but it was delayed in the recF143 and recB21recF143 mutants.