Genetic analysis of regulation of the RecF pathway of recombination in Escherichia coli K-12

The Roles of Bacterial DNA Double-Strand Break Repair Proteins in Chromosomal DNA Replication

It is well established that DNA double-strand break (DSB) repair is required to underpin chromosomal DNA replication. Because DNA replication forks are prone to breakage, faithful DSB repair and correct replication fork restart are critically important. Cells, where the proteins required for DSB repair are absent or altered, display characteristic disturbances to genome replication. In this review, we analyze how bacterial DNA replication is perturbed in DSB repair mutant strains and explore the consequences of these perturbations for bacterial chromosome segregation and cell viability. Importantly, we look at how DNA replication and DSB repair processes are implicated in the striking recent observations of DNA amplification and DNA loss in the chromosome terminus of various mutant Escherichia coli strains. We also address the mutant conditions required for the remarkable ability to copy the entire E. coli genome, and to maintain cell viability, even in the absence of replication initiation from oriC, the unique origin of DNA replication in wild type cells. Furthermore, we discuss the models that have been proposed to explain these phenomena and assess how these models fit with the observed data, provide new insights and enhance our understanding of chromosomal replication and termination in bacteria.

RecO protein initiates DNA recombination and strand annealing through two alternative DNA binding mechanisms

Recombination mediator proteins (RMPs) are important for genome stability in all organisms. Several RMPs support two alternative reactions: initiation of homologous recombination and DNA annealing. We examined mechanisms of RMPs in both reactions with Mycobacterium smegmatis RecO (MsRecO) and demonstrated that MsRecO interacts with ssDNA by two distinct mechanisms. Zinc stimulates MsRecO binding to ssDNA during annealing, whereas the recombination function is zinc-independent and is regulated by interaction with MsRecR. Thus, different structural motifs or conformations of MsRecO are responsible for interaction with ssDNA during annealing and recombination. Neither annealing nor recombinase loading depends on MsRecO interaction with the conserved C-terminal tail of single-stranded (ss) DNA-binding protein (SSB), which is known to bind Escherichia coli RecO. However, similarly to E. coli proteins, MsRecO and MsRecOR do not dismiss SSB from ssDNA, suggesting that RMPs form a complex with SSB-ssDNA even in the absence of binding to the major protein interaction motif. We propose that alternative conformations of such complexes define the mechanism by which RMPs initiate the repair of stalled replication and support two different functions during recombinational repair of DNA breaks.

Toxicity and tolerance mechanisms for azidothymidine, a replication gap-promoting agent, in Escherichia coli

Azidothymidine (AZT, zidovudine) is used to treat HIV-AIDS and prevent maternal transmission to newborns. Because the azido group replaces the 3' OH of thymidine, AZT is believed to act as a chain terminator during reverse transcription of viral RNA into DNA, although other mechanisms of viral inhibition have been suggested. There is evidence that AZT is genotoxic, particularly to the mitochondria. In this study, we use the bacterium Escherichia coli to investigate the mechanism of AZT toxicity and the cellular mechanisms that aid survival. We show that that replication arrests quickly after treatment, accompanied by induction of the SOS DNA damage response. AZT appears to produce single-strand DNA gaps, as evident by RecF-dependent induction of the SOS response and visualization of single-strand DNA binding protein foci within the cell. Some of these gaps must be converted to breaks, since mutants in the RecBCD nuclease, required for recombinational double-strand break repair, are highly sensitive to AZT. Blocks in the late recombination functions, the RuvAB branch migration helicase and RuvC Holliday junction endonuclease, caused extreme AZT sensitivity that could be relieved by mutations in the early recombination functions, such as RecF, suggesting gaps engage in recombination reactions. Finally, our data suggest that the proofreading exonucleases of DNA polymerases play little role in AZT tolerance. Rather, Exonuclease III appears to be the enzyme that removes AZT: xthA mutants are highly AZT-sensitive, with a sustained SOS response, and overproduction of the enzyme protects wild-type cells. Our findings suggest that incorporation of AZT into human nuclear and mitochondrial DNA has the potential to promote genetic instability and toxicity through the production of ssDNA gaps and dsDNA breaks, and predicts that the human Exonuclease III ortholog, APE1, will be important for drug tolerance.

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.

Involvement of recQ in the ultraviolet damage repair pathway in Deinococcus radiodurans

Deinococcus radiodurans is a bacterium which can survive extremely DNA damage. To investigate the relationship between recQ and the ultraviolet radiation (UV) damage repair pathway, we created a four mutant strain by constructing recQ knockout mutants in uvrA1, uvrA2, and uvsE backgrounds. Using the rpoB/Rif(r) system, we measured the mutation frequencies and rates in wild type, recQ (MQ), uvsE uvrA1 uvrA2 (TNK006), and uvsE uvrA1 uvrA2 recQ (TQ). We then isolated Rif(r) mutants of these strains and sequenced the rpoB gene. The mutation frequency of TQ was 6.4, 10.1, and 2.43 times that of wild type, MQ, and TNK006, respectively, and resulted in rates of 4.7, 6.71, and 2.15 folds higher than that of wild type, MQ, and TNK006, respectively. All the strains demonstrated specific mutational hotspots. Furthermore, the TQ strain showed a transversion bias that was different from the other three strains. The results indicate that recQ is involved in the ultraviolet damage repair pathway via the interaction between recQ and uvrA1, uvrA2, and uvsE in D. radiodurans.

Conjugational hyperrecombination achieved by derepressing the LexA regulon, altering the properties of RecA protein and inactivating mismatch repair in Escherichia coli K-12

The frequency of recombinational exchanges (FRE) that disrupt co-inheritance of transferred donor markers in Escherichia coli Hfr by F(-) crosses differs by up to a factor of two depending on physiological factors and culture conditions. Under standard conditions we found FRE to be 5.01 +/- 0.43 exchanges per 100-min units of DNA length for wild-type strains of the AB1157 line. Using these conditions we showed a cumulative effect of various mutations on FRE. Constitutive SOS expression by lexA gene inactivation (lexA71::Tn5) and recA gene mutation (recA730) showed, respectively, approximately 4- and 7-fold increases of FRE. The double lexA71 recA730 combination gave an approximately 17-fold increase in FRE. Addition of mutS215::Tn10, inactivating the mismatch repair system, to the double lexA recA mutant increased FRE to approximately 26-fold above wild-type FRE. Finally, we showed that another recA mutation produced as much SOS expression as recA730 but increased FRE only 3-fold. We conclude that three factors contribute to normally low FRE under standard conditions: repression of the LexA regulon, the properties of wild-type RecA protein, and a functioning MutSHL mismatch repair system. We discuss mechanisms by which the lexA, recA, and mutS mutations may elevate FRE cumulatively to obtain hyperrecombination.

IF3-mediated suppression of a GUA initiation codon mutation in the recJ gene of Escherichia coli

A mutational change of the initiation codon to GUA was found to reduce, but not abolish, expression of the recJ gene of Escherichia coli. Specific mutations in translational initiation factor IF3 have been isolated as second-site suppressors of this GUA initiation codon mutation. One of these, infC135, with an arginine-to-proline change at amino acid 131, completely restores a wild-type phenotype to recJ GUA initiation codon mutants and acts in a semidominant fashion. The infC135 mutation increased expression of RecJ from the GUA mutant but had no effect on the normal GUG start. The infC135 mutation also abolished autoregulation of IF3 in cis and in trans. The behavior of this IF3 mutant suggests that it has specifically lost its ability to abort initiation from poor initiation codons such as GUA of recJ and the AUU of infC. Because of the impact of IF3 on recJ, a recombination and repair gene, this role of IF3 must be general and not restricted to translation genes. The dominance of infC135 suggests that the other functions of IF3, for instance its ability to bind to 30S ribosomes, must remain intact. Although the ability to discriminate among initiation codons has been lost in the infC135 mutant, translational initiation was still restricted to the normal initiation site in recJ, even in the presence of a closely juxtaposed alternative initiation codon. Because the recJ gene lacks a canonical Shine-Dalgarno sequence, other unknown features of the mRNA must serve to specify the initiation site.

Recombination-dependent growth in exonuclease-depleted recBC sbcBC strains of Escherichia coli K-12

Analysis of the aroLM-sbcCD interval of the Escherichia coli K-12 chromosome revealed a new gene (rdgC) encoding a function required for growth in recombination-deficient recBC sbcBC strains. Deletion of rdgC does not reduce viability, conjugational recombination, or DNA repair in rec+, recA, recB, recF, or recJ mutants. However, it makes the growth of recBC sbcBC strains reliant on the RecA, RecF, and RuvC proteins and, to a large extent, on RuvAB. The recBC sbcBC delta rdgC ruvAB construct forms colonies, but cell viability is reduced to < 5%. A recBC sbcBC delta rdgC derivative carrying the temperature-sensitive recA200 allele grows at 32 degrees but not 42 degrees. Multicopy rdgC+ plasmids reduce the growth rate of recBC sbcBC strains, while multicopy sbcC+ plasmids that reactivate SbcCD nuclease cannot be maintained without RdgC protein. The data presented are interpreted to suggest that exonuclease-depleted recBC sbcBC strains have difficulty removing the displaced arm of a collapsed replication fork and that this problem is compounded in the absence of RdgC. Recombination then becomes necessary to repair the fork and allow chromosome duplication to be completed. The possibility that RdgC is an exonuclease is discussed.

The recA gene of Chlamydia trachomatis: cloning, sequence, and characterization in Escherichia coli

The recA gene of Chlamydia trachomatis was isolated by complementation of an Escherichia coli recA mutant. The cloned gene restored resistance to methyl methanesulfonate in E. coli recA mutants. The DNA sequence of the chlamydial gene was determined and the deduced protein sequence compared with other RecA proteins. In E. coli recA deletion mutants, the cloned gene conferred moderate recombinational activity as assayed by Hfr matings. The chlamydial recA gene was efficient in repairing alkylated DNA but less so in repairing of UV damage when compared with the E. coli homologue. As detected by an SOS gene fusion, a small but measurable amount of LexA co-cleavage was indicated.

Molecular cloning of cDNA encoding human DNA helicase Q1 which has homology to Escherichia coli Rec Q helicase and localization of the gene at chromosome 12p12

A complementary DNA encoding DNA-dependent ATPase Q1 possessing DNA helicase activity, which is the major DNA-dependent ATPase in human cell extracts, was cloned from a cDNA library of human KB cells. The predicted amino acid sequence has seven consecutive motifs conserved in the RNA and DNA helicase super family and DNA helicase Q1 belongs to DEXH helicase family. A homology search indicated that helicase Q1 had 47% homology in the seven conserved regions with Escherichia coli RecQ protein. Three RNA bands of 4.0, 3.3, and 2.2 kilobases were detected in HeLa cells by Northern blotting. Analysis of the genomic DNA indicated the presence of a homologous gene in mouse cells. The DNA helicase Q1 gene was localized on the short arm of human chromosome 12 at 12p12.

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.

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.

Suppression of recJ mutations of Escherichia coli by mutations in translation initiation factor IF3

We have isolated genetic suppressors of mutations in the recJ gene of Escherichia coli in a locus we term srjA. These srjA mutations cause partial to complete alleviation of the recombination and UV repair defects conferred by recJ153 and recJ154 mutations in a recBC sbcA genetic background. The srjA gene was mapped to 37.5 min on the E. coli chromosome. This chromosomal region from the srjA5 strain was cloned into a plasmid vector and was shown to confer recJ suppression in a dominant fashion. Mutational analysis of this plasmid mapped srjA to the infC gene encoding translation initiation factor 3 (IF3). Sequence analysis revealed that all three srjA alleles cause amino acid substitutions of IF3. Suppression of recJ was shown to be allele specific: recJ153 and recJ154 mutations were suppressible, but recJ77 and the insertion allele recJ284::Tn10 were not. In addition, growth medium-conditional lethality was observed for strains carrying srjA mutations with the nonsuppressible recJ alleles. When introduced into recJ+ strains, srjA mutations conferred hyperrecombinational and hyper-UVr phenotypes. An interesting implication of these genetic properties of srjA suppression is that IF3 may regulate the expression of recJ and perhaps other recombination genes and hence may regulate the recombinational capacity of the cell.

Conjugational recombination in resolvase-deficient ruvC mutants of Escherichia coli K-12 depends on recG

ruvC mutants of Escherichia coli appear to lack an activity that resolves Holliday intermediates into recombinant products. Yet, these strains produce close to normal numbers of recombinants in genetic crosses. This recombination proficiency was found to be a function of recG. A "mini-kan" insertion in recG was introduced into ruvA, ruvB, and ruvC strains. Conjugational recombination was reduced by more than 100-fold in recG ruvA::Tn10, recG ruvB, and recG ruvC strains and by about 30-fold in a recG ruvA strain carrying a ruvA mutation that is not polar on ruvB. The double mutants also proved very deficient in P1 transduction and are much more sensitive to UV light than ruv single mutants. Since mutation of recG alone has very modest effects on recombination and sensitivity to UV, it is concluded that there is a functional overlap between the RecG and Ruv proteins. However, this overlap does not extend to circular plasmid recombination. The possibility that RecG provides a second resolvase that can substitute for Ruv is discussed in light of these findings.

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 recA-recBCD dependent recombination pathways of Serratia marcescens and Proteus mirabilis in Escherichia coli: functions of hybrid enzymes and hybrid pathways

The physical maps of cloned recBCD gene regions of Serratia marcescens and Proteus mirabilis were correlated to genes located in this region. The genes thyA, recC, recB, recD and argA were organized as in Escherichia coli. The 3 rec genes code for the 3 different subunits of the RecBCD enzyme and produced enzymes promoting recombination and repair of UV damage in E coli. The recBCD-dependent stimulation of recombination at specific nucleotide sequences called Chi (Chi-activation) was determined in lambda red-gam-crosses. Chi-activation by the different RecBCD enzymes decreased in the order E coli greater than S marcescens greater than P mirabilis. In E coli cloned subunits genes from S marcescens and P mirabilis led to the formation of functional hybrid enzymes consisting of subunits from 2 or even 3 species. The origin of the RecC subunit present in the hybrid enzymes affected the degree of Chi-activation. Further, changes in Chi-activation occurred when the RecD subunit in the enzyme from E coli was replaced by RecD proteins from S marcescens or P mirabilis. This suggested that the RecD subunit determines not only whether or not Chi-activation is possible but also to which extent it occurs. Finally we have reconstituted recombination pathways of S marcescens and P mirabilis by combining the cloned recA and recBCD genes from these species in E coli deleted for recA and recBCD. Both pathways can efficiently promote recombination and repair. Studies are summarized which showed that levels of repair and recombination promoted by the recA-recBCD genes are mostly higher when the recA and recBCD genes came from the same species than from 2 different species (hybrid RecBCD recombination pathway). The data are interpreted to provide evidence that in vivo the RecA protein co-operates with the RecBCD enzyme in recombination and repair of UV damage.

Genetic control of recombination exchange frequency in Escherichia coli K-12

The frequency of recombination exchanges per unit length of DNA (Freuld) can be estimated by measuring the scale of the genetic map that is the mean statistical distance between two neighboring crossovers. The scales appear to be equal for the alternative pathways of recombination, RecBCD (wild-type cells) or RecF (recBC- sbcB- sbcC- genotypes). The absolute value of the scale depends on specific experimental conditions. recR, recQ, ruv, recJ and recN genes of the RecF pathway of recombination (recBC- sbcBC- cell genotypes) do not appear to be silent in wild-type cells where the RecBCD pathway predominates. On the contrary, these genes are responsible for the Freuld. The list recF504::Kmr greater than recQ61::Tn3 greater than ruv-54 greater than recJ284::Tn10 shows decreasing efficiency in inhibiting recombination exchanges by these mutations. The recN264 mutation gives a small, but opposite effect of increasing the frequency of recombination exchanges. The effect of the recF and recQ mutations appears to be additive, but that is not the case in combinations of ruv-54 with recF504::Kmr or recQ61::Tn3.

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.

Linear multimer formation of plasmid DNA in Escherichia coli hopE (recD) mutants

The hopE mutants of Escherichia coli, which cannot stably maintain a mini-F plasmid during cell division, have mutations in the recD gene coding for subunit D of the RecBCD enzyme (exonuclease V). A large amount of linear multimer DNA of mini-F and pBR322 plasmid accumulates in these hopE mutants. The linear multimers of plasmid DNA in the hopE (recD) mutants accumulate in sbc+ genetic backgrounds and this depends on the recA+ gene function. Linear plasmid multimers also accumulated in a recBC xthA triple mutant, but not an isogenic xth A mutant or an isogenic recBC mutant. The recBC xth A mutant is defective in the conjugative type of recombination. Linear plasmid multimers were not detected in the recBC strain. We propose models to account for linear multimer formation of plasmids in various mutants.

Genetic and physical analysis of plasmid recombination in recB recC sbcB and recB recC sbcA Escherichia coli K-12 mutants

The effect of mutations in known recombination genes (recA, recB, recC, recE, recF, recJ, recN, recO, recQ and ruv) on intramolecular recombination of plasmids was studied in recB recC sbcB and recB recC sbcA Escherichia coli mutants. The rate of recombination of circular dimer plasmids was at least 1000-fold higher in recB recC sbcB or recB recC sbcA mutants as compared to wild-type cells. The rate was decreased by mutations in recA, recF, recJ, recO, ruv or mutS in recB recC sbcB mutants, and by mutations in recE, recN, recO, recQ, ruv or mutS in recB recC sbcA mutants. In addition to measuring the recombination rate of circular dimer plasmids, the recombination-mediated transformation of linear dimer plasmids was also studied. Linear dimer plasmids transformed recB recC sbcB and recB recC sbcA mutants 20- to 40-fold more efficiently than wild-type cells. The transformation efficiency of linear dimer plasmids in recB recC sbcB mutants was decreased by mutations in recA, recF, recJ, recO, recQ or lexA (lexA3). In recB recC sbcA mutants the transformation efficiency of linear dimers was decreased only by a recE mutation. Physical analysis of linear dimer- or circular dimer-transformed recB recC sbcB mutants revealed that all transformants contained recombinant monomer genotypes. This suggests that recombination in recB recC sbcB cells is very efficient.

Genetic and physical mapping of the mcrA (rglA) and mcrB (rglB) loci of Escherichia coli K-12

We have genetically analyzed, cloned and physically mapped the modified cytosine-specific restriction determinants mcrA (rglA) and mcrB (rglB) of Escherichia coli K-12. The independently discovered Rgl and Mcr restriction systems are shown to be identical by three criteria: 1) mutants with the RglA- or RglB- phenotypes display the corresponding McrA- or McrB- phenotypes, and vice versa; 2) the gene(s) for RglA and McrA reside together at one locus, while gene(s) for RglB and McrB are coincident at a different locus; and 3) RglA+ and RglB+ recombinant clones complement for the corresponding Mcr-deficient lesions. The mcrA (rglA) gene(s) is on the excisable element e14, just clockwise of purB at 25 min. The mcrB (rglB) gene(s), at 99 min, is in a cluster of restriction functions that includes hsd and mrr, determinants of host-specific restriction (EcoK) and methyladenine-specific restriction respectively. Gene order is mcrB-hsdS-hsdM-hsdR-mrr-serB. Possible models for the acqusition of these restriction determinants by enteric bacteria are discussed.

Repair of the plasmid pBR322 damaged by gamma-irradiation or by restriction endonucleases using different recombination-proficient E. coli strains

The plasmid pBR322 was treated with BamHI, PvuII and gamma-irradiation to generate double-strand breaks (dsb) containing differently structured ends. Transformation efficiencies, mutation frequencies and clone analyses of enzymatically damaged DNA are compared with the corresponding results from radiolytically damaged DNA. In E. coli K-12 SFX, the yield of transformants produced by the action of BamHI, PvuII and gamma-irradiation (30 Gy) is 4.3%, 0.14%, and 0.10%, respectively. The survival of open circular DNA (ocDNA) produced by 30 Gy is 1.3%. The transformation efficiencies show only a slight dependence on SOS induction and on the RecA protein. Mutation frequencies to tetracycline sensitivity (tets) per surviving plasmid are 2.6% (BamHI), 11.8% (PvuII) and 0.2% (gamma-irradiated DNA with 30 Gy containing approximately 50% ocDNA and 50% linearized (lin) DNA). The mutation frequency is low at all radiation doses studied (1-50 Gy). Only 15% of the DNA of the tets mutants from gamma-irradiated plasmids contained deletions whereas with enzymatically damaged DNA, 30-50% (BamHI) or 90% (PvuII) contained deletions. In all cases, the deletions comprised 500-1700 base pairs (bp). After SOS induction of the host cells, the mutation frequency of gamma-irradiated plasmids increased by a factor of 4, whereas that of the enzymatically damaged plasmids did not change. For the repair of the enzymatically linearized DNA 2 recombinational pathways are discussed which lead to deletant (pathway I) and non-deletant transformants (pathway II). In addition, BamHI-linearized plasmids may be repaired by enzyme-induced or spontaneous circular alignment followed by ligation. The high percentage of deletions of the tets mutations for PvuII-linearized DNA with blunt ends is explained by the illegitimate or site-specific recombination pathway I (see text). The lower percentage of deletions of the tets mutations with BamHI-linearized DNA with short cohesive ends (4 bp) is proposed to be due to a greater contribution of pathway II and/or by circular alignment followed by ligation. The very small yield and the low percentage of deletant mutations of tets mutants from radiolytically damaged DNA is proposed to be due to the large overlapping ends (16-100 bp) of the linDNA which easily leads to circular alignment followed by excision repair. The repair of radiolytically produced ocDNA is predominantly due to excision repair. In agreement with this interpretation is the observation that SOS induction of the host increases the mutation incidence of radiolytically damaged DNA but not of enzymatically damaged DNA.

The genetic dependence of recombination in recD mutants of Escherichia coli

RecBCD enzyme has multiple activities including helicase, exonuclease and endonuclease activities. Mutations in the genes recB or recC, encoding two subunits of the enzyme, reduce the frequency of many types of recombinational events. Mutations in recD, encoding the third subunit, do not reduce recombination even though most of the activities of the RecBCD enzyme are severely reduced. In this study, the genetic dependence of different types of recombination in recD mutants has been investigated. The effects of mutations in genes in the RecBCD pathway (recA and recC) as well as the genes specific for the RecF pathway (recF, recJ, recN, recO, recQ, ruv and lexA) were tested on conjugational, transductional and plasmid recombination, and on UV survival. recD mutants were hyper-recombinogenic for all the monitored recombination events, especially those involving plasmids, and all recombination events in recD strains required recA and recC. In addition, unlike recD+ strains, chromosomal recombination events and the repair of UV damage to DNA in recD strains were dependent on one RecF pathway gene, recJ. Only a subset of the tested recombination events were affected by ruv, recN, recQ, recO and lexA mutations.

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.

Different effects of recJ and recN mutations on the postreplication repair of UV-damaged DNA in Escherichia coli K-12

Two mutations known to affect recombination in a recB recC sbsBC strain, recJ284::Tn10 and recN262, were examined for their effects on the postreplication repair of UV-damaged DNA. The recJ mutation did not affect the UV radiation sensitivity of uvrB and uvrB recF cells, but it increased the sensitivity of uvrB recN (approximately 3-fold) and uvrB recB (approximately 8-fold) cells. On the other hand, the recN mutation did not affect the UV sensitivity of uvrB recB cells, but it increased the sensitivity of uvrB (approximately 1.5-fold) and uvrB recF (approximately 4-fold) cells. DNA repair studies indicated that the recN mutation produced a partial deficiency in the postreplication repair of DNA double-strand breaks that arise from unrepaired daughter strand gaps, while the recJ mutation produced a deficiency in the repair of daughter strand gaps in uvrB recB cells (but not in uvrB cells) and a deficiency in the repair of both daughter strand gaps and double-strand breaks in uvrA recB recC shcBC cells. Together, these results indicate that the recJ and recN genes are involved in different aspects of postreplication repair.

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.

Formation of recombinant lacZ+ DNA in conjugational crosses with a recB mutant of Escherichia coli K12 depends on recF, recJ, and recO

Conjugational recombination in Escherichia coli was investigated by monitoring synthesis of the lacZ+ product, beta-galactosidase, in crosses between lacZ mutants. We report here that mutation of recB and any combination of recF, recJ, or recO reduces enzyme production by a factor of between 10- and 25-fold whereas mutation of only one of these genes or any combination of recF, recJ, or recO has no more than a 2-fold effect. Mutation of recN has no effect either alone or in combination with the other mutations. We suggest that the products of recF, recJ, and recO may provide an efficient alternative to the RecBCD enzyme for the initiation of recombination in conjugational crosses but that RecBCD activity is needed in this case to produce a viable recombinant product.

Nucleotide sequence and LexA regulation of the Escherichia coli recN gene

The nucleotide sequence of a 2224 bp region of the Escherichia coli chromosome that carries the LexA regulated recN gene has been determined. A region of 1701 nucleotides encoding a polypeptide of 567 amino acids with a predicted molecular weight of 63,599 was identified as the most probable sequence for the recN structural gene. The proposed initiation codon is preceded by a reasonable Shine-Dalgarno sequence and a promoter region containing two 16 bp sequences, separated by 6 bp, that match the consensus sequence (SOS box) for binding LexA protein. DNA fragments containing this putative promoter region are shown to bind LexA in vitro and to have LexA-regulated promoter activity in vivo. The amino acid sequence of RecN predicted from the DNA contains a region that is homologous to highly conserved sequences found in several DNA repair enzymes and other proteins that bind ATP. A sequence of 9 amino acids was found to be homologous to a region of the RecA protein of E. coli postulated to have a role in DNA/nucleotide binding.

Genetic analysis of constitutive stable DNA replication in rnh mutants of Escherichia coli K12

Escherichia coli rnh mutants deficient in ribonuclease H (RNase H) are capable of DNA replication in the absence of protein synthesis. This constitutive stable DNA replication (SDR) is dependent upon the recA+ gene product. The requirement of SDR for recA+ can be suppressed by rin mutations (for recA+-independent), or by lexA(Def) mutations which inactivate the LexA repressor. Thus, there are at least three genetically distinct types of SDR in rnh mutants: recA+-dependent SDR seen in rnh- rin+ lexA+ strains, recA+-independent in rnh- rin- lexA+, and recA+-independent in rnh- rin+ lexA(Def). The expression of SDR in rin- and lexA(Def) mutants demonstrated a requirement for RNA synthesis and for the absence of RNase H. The suppression of the recA+ requirement by rin mutations was shown to depend on some new function of the recF+ gene product. In contrast, the suppression by lexA-(Def) mutations was not dependent on recF+. The lexA3 mutation inhibited recA+-dependent SDR via reducing the amount of recA+ activity available, and was suppressed by the recAo254 mutation. The SDR in rnh- rin- cells was also inhibited by the lexA3 mutation, but the inhibition was not reversed by the recAo254 mutation, indicating a requirement for some other lexA+-regulated gene product in the recA+-independent SDR process. A model is presented for the regulation of the expression of these three types of SDR by the products of the lexA+, rin+ and recF+ genes.

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.

Genetic analysis of UV mutagenesis of the Escherichia coli glyU gene

By genetic analysis we examined UV mutagenesis of the Escherichia coli glyU gene. When carried by M13 phage mp9, glyU is subject to induced UV mutagenesis which is dependent on the umuC+ and recF+ genes. When carried by M13 phage mp8, glyU is not subject to induced UV mutagenesis. This difference is correlated with the nature of the target nucleotides: CTC in the mp9 derivative and GAG in the mp8 derivative. Thus, we conclude that the induced (umuC and recF dependent) mutagenesis is locally targeted on pyrimidine cyclobutane or 6-4 dimers. glyU carried by M13 is equally subject to uninduced UV mutagenesis whether carried by mp8 or mp9. This uninduced mutagenesis is independent of the umuC+, recF+ and recA+ genes and we hypothesize that it is regionally targeted on pyrimidine cyclobutane or 6-4 dimers in the vicinity of the target CTC and GAG nucleotides. The role of recF in UV mutagenesis was tested in two ways. First, mutagenesis of glyU carried by M13 mp9 in a recA730 genetic background was found to be recF dependent. Because recA730 renders induced UV mutagenesis partially constitutive, we conclude that the RecF product plays a direct role in UV mutagenesis rather than, or in addition to, any indirect regulatory role it may play. Second, UV mutagenesis of E. coli chromosomal glyU was found to be recF independent while UV mutagenesis of M13-bourne glyU was recF dependent. We conclude that the mechanism of induced UV mutagenesis of the E. coli chromosome is at least partly different from that of M13 phage and we discuss the biochemical basis for such a difference.

Synthesis of linear plasmid multimers in Escherichia coli K-12

Linear plasmid multimers were identified in extracts of recB21 recC22 strains containing derivatives of the ColE1-type plasmids pACYC184 and pBR322. A mutation in sbcB increases the proportion of plasmid DNA as linear multimers. A model to explain this is based on proposed roles of RecBC enzyme and SbcB enzyme (DNA exonuclease I) in preventing two types of rolling-circle DNA synthesis. Support for this hypothesis was obtained by derepressing synthesis of an inhibitor of RecBC enzyme and observing a difference in control of linear multimer synthesis and monomer circle replication. Reinitiation of rolling-circle DNA synthesis was proposed to occur by recA+-dependent and recA+-independent recombination events involving linear multimers. The presence of linear plasmid multimers in recB and recC mutants sheds new light on plasmid recombination frequencies in various mutant strains.

Complete nucleotide sequence of the Escherichia coli recC gene and of the thyA-recC intergenic region

The nucleotide sequence of a 6,000 bp region of the E. coli chromosome that includes the 3' end of the coding region for the thyA gene and the entire recC gene has been determined. The proposed coding region for the RecC protein is 3369 nucleotides long, which would encode a polypeptide consisting of 1122 amino acids with a calculated molecular mass of 129 kDa. Mung bean nuclease mapping of a recC specific transcript produced in vivo indicates that transcription of recC is initiated 80 bp upstream of the translational start point. A weak promoter sequence situated 5' to the transcription initiation point has been identified. In the 1953 bp thyA-recC intergenic region there are three open reading frames that would code for polypeptides of molecular mass 30 kDa, 13.5 kDa and 12 kDa, respectively. Although the first and third of these open reading frames are preceded by possible ribosome binding sites, no obvious promoter sequences could be identified. Moreover, transcripts for these reading frames could not be detected.

Lack of UV-induced respiration shutoff in a recF strain of Escherichia coli: temperature conditional suppression at 30 degrees C by the sfrA mutation

A mutation in the recF gene of Escherichia coli results in a radiation-sensitive strain. The RecF pathway and the RecBC pathway account for nearly all of the conjugative recombination occurring in E. coli. recBC cells are radiation-sensitive and carry only out a small amount of recombination but these deficiencies are suppressed by an sbcB as recombination is shunted to the RecF pathway. A recBC sbcB recF strain is very radiation-sensitive and is devoid of recombination ability. These deficiencies are suppressed by the srfA mutation; srfA is a recA allele. UV-induced respiration shutoff is a recA+, lexA+ and recBC+ dependent. We report in this paper that respiration does not shutoff in a recF strain at 37 and 30 degrees C. an srfA mutation suppresses this lack of respiration shutoff effect in a recF srfA mutant at 30 degrees C but not at 37 degrees C; no suppression by this mutation occurs at either temperature in a recF recBC sbcB strain. An srfA strain also does not shut off its respiration at 37 degrees C and shows a temperature conditional UV-induced respiration shutoff response at 30 degrees C. The srfA mutation is thought to cause an altered RecA protein to be produced and we suggest that at 37 degrees This altered protein is temperature sensitive. We conclude from the results in this paper that the recF gene product is required for UV-induced respiration shutoff and that the RecA protein plays a special role in the induction process.

RecBC enzyme activity is required for far-UV induced respiration shutoff in Escherichia coli K12

Shutoff of respiration is one of a number of recA+ lexA+ dependent (SOS) responses caused by far ultraviolet (245 nm) radiation (UV) damage of DNA in Escherichia coli cells. Thus far no rec/lex response has been shown to require the recB recC gene product, the RecBC enzyme. We report in this paper that UV-induced respiration shutoff did not occur in either of these radiation-sensitive derivatives of K12 strain AB1157 nor in the recB recC double mutant. The sbcB gene product is exonuclease I and it has been reported that the triple mutant strain recB recC sbcB has near normal recombination efficiency and resistance to UV. The sbcB strain shut off its respiration after UV but the triple mutant did not show UV-induced respiration shutoff; the shutoff and death responses were uncoupled. We concluded that respiration shutoff requires RecBC enzyme activity. The RecBC enzyme has ATP-dependent double-strand exonuclease activity, helicase activity and several other activities. We tested a recBC+ (double dagger) mutant strain (recC 1010) that had normal recombination efficiency and resistance to UV but which possessed no ATP-dependent double-strand exonuclease activity. This strain did not shut off its respiration. The presence or absence of other RecBC enzyme activities in this mutant is not known. These results support the hypothesis that ATP-dependent double-strand exonuclease activity is necessary for UV-induced respiration shutoff.

Intramolecular recombination of linear DNA catalyzed by the Escherichia coli RecE recombination system

Transformation of different Escherichia coli strains by linear dimers of pBR322 containing different tet alleles was investigated. Linear dimers transformed wild-type strains 0.1 to 1% as efficiently as circular dimers. In contrast, linear dimers transformed recBrecCsbcA strains, where the RecE recombination system is functional, as efficiently as circular dimers. The transformants contained plasmids that had a single recombinant monomer genotype, indicating that transformation was mediated by a recombination-dependent cyclization reaction. Altering the position of the double-strand break changed the frequency of recovering different recombination products, but had no effect on the frequency of transformation. Both the frequency of transformation and the production of Tcr recombinants were decreased by recE mutations, while recA and recF mutations were slightly stimulatory (twofold). Several recombination models consistent with these results are presented.

Repair and recombination of nonreplicating UV-irradiated phage DNA in E. coli II. Stimulation of RecF-dependent recombination by excision repair of cyclobutane pyrimidine dimers and of other photoproducts

Three aspects of recombination of UV-irradiated nonreplicating lambda phage DNA were addressed: the photoproduct(s) responsible, the role of UvrABC-mediated excision repair, and the dependence on RecF function. Cyclobutane pyrimidine dimers appeared responsible for some recombination because photoreactivation reduced the frequency of 254-nm-stimulated recombination and because photosensitized 313-nm irradiation stimulated recombination. Other photoproducts seemed recombinogenic as well, because high fluences of 254-nm irradiation stimulated recombination considerably more, per cyclobutane dimer induced, than photosensitized 313-nm irradiation, and because photoreactivation did not eliminate 254-nm stimulated recombination. For both treatments, much, but not all, of the recombination was UvrABC-dependent. Recombination was mostly RecF-dependent, but was not affected by recB recC or recE mutations

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

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

Identification of the Escherichia coli recN gene product as a major SOS protein

The recA+ lexA+-dependent induction of four Escherichia coli SOS proteins was readily observed by two-dimensional gel analysis. In addition to the 38-kilodalton (kDa) RecA protein, which was induced in the greatest amounts and was readily identified, three other proteins of 115, 62, and 12 kDa were seen. The 115-kDa protein is the product of the uvrA gene, which is required for nucleotide excision repair and has previously been shown to be induced in the SOS response. The 62-kDa protein, which was induced to high intracellular levels, is the product of recN, a gene required for recBC-independent recombination. The recA and recN genes were partially derepressed in a recBC sbcB genetic background, a phenomenon which might account for the recombination proficiency of such strains. The 12-kDa protein has yet to be identified.

Identification and genetic analysis of sbcC mutations in commonly used recBC sbcB strains of Escherichia coli K-12

Evidence is presented to show that Escherichia coli JC7618, JC7621, and JC7623, previously regarded as having a recB recC sbcB genotype, carry an additional mutation in a new gene designated sbcC at minute 9 on the standard genetic map. In the absence of the sbcC mutation these strains are sensitive to mitomycin C and have a reduced efficiency of recombination. Cultures of recBC sbcB (sbcC+) strains grow slowly, contain many inviable cells, and rapidly accumulate fast-growing variants due to mutation of sbcC. sbcC has been identified on recombinant plasmids and tentatively located by Tn1000 mutagenesis to a 0.9-kilobase DNA section between proC and phoR.

Analysis of the ruv locus of Escherichia coli K-12 and identification of the gene product

The ruv gene of Escherichia coli, which is associated with inducible mechanisms of DNA repair and recombination, has been cloned into the low-copy plasmid vector pHSG415. The recombinant plasmid pPVA101 fully complements the DNA repair-deficient phenotype of ruv mutants. Restriction endonuclease analysis of this plasmid revealed a 10.6-kilobase (kb) HindIII DNA insert which contained a 7.7-kb PstI fragment identified as being from the chromosomal ruv region. Deletion analysis and Tn1000 insertional inactivation of ruv function located the ruv coding region to a 2.2-kb section of the cloned DNA fragment. A comparison of the proteins encoded by ruv wild-type and mutant plasmids identified the gene product as a protein of molecular weight 41,000.

Viability of Escherichia coli K-12 DNA adenine methylase (dam) mutants requires increased expression of specific genes in the SOS regulon

We have examined the level of expression of the SOS regulon in cells lacking DNA adenine methylase activity (dam-). Mud (Ap, lac) fusions to several SOS operons (recA, lexA, uvrA, uvrB, uvrD, sulA, dinD and dinF) were found to express higher levels of beta-galactosidase in dam- strains than in isogenic dam+ strains. The attempted construction of dam- strains that were also mutant in one of several SOS genes indicated that the viability of methylase-deficient strains correlates with the inactivation of the SOS repressor (LexA protein). Consistent with this, the wild-type functions of two LexA-repressed genes (recA and ruv) appear to be required for dam- strain viability.

Stimulation of recombination between homologous sequences on carcinogen-treated plasmid DNA and chromosomal DNA by induction of the SOS response in Escherichia coli K12

Previous studies have shown that transformation of Escherichia coli by plasmid DNA modified in vitro by carcinogens leads to RecA-dependant recombination between homologous plasmid and chromosomal DNA sequences. The mechanism of this recombination has now been studied using recombination-deficient mutants, and the influence of induction of the SOS response on the level of recombination investigated. Plasmid pNO1523, containing the str+ operon (Sms), has been modified in vitro by either irradiation with UV light, or by reaction with (+/-) trans-benzo(a)pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE) and used to transform streptomycin-resistant hosts. The formation of Ampr transformants which also carry streptomycin resistance was used as a measure of the level of recombination between plasmid and chromosomal DNA. Transformation of recB and recC mutants produced no change in the level of recombination while in the recF mutant a significant decrease was observed compared to the wild type host. Thermal induction of the SOS response in tif-1 and tif-1 umuC mutants followed by transformation led to a four-fold increase in recombination in both cases. The results suggest that the streptomycin-resistant transformants arise exclusively via a recombinational pathway which is largely dependant on the recF gene product, and that this pathway is influenced by induction of the SOS response. These results are discussed in terms of the mechanism of this recombination.

Genetic recombination of bacterial plasmid DNA: effect of RecF pathway mutations on plasmid recombination in Escherichia coli

Tn5 insertion mutations in the recN gene, and in what appears to be a new RecF pathway gene designated recO and mapping at approximately 55.4 min on the standard genetic map, were isolated by screening Tn5 insertion mutations that cotransduced with tyrA. The recO1504::Tn5 mutation decreased the frequency of recombination during Hfr-mediated crosses and increased the susceptibility to killing by UV irradiation and mitomycin C when present in a recB recC sbcB background, but only increased the sensitivity to killing by UV irradiation when present in an otherwise Rec+ background. The effects of these and other RecF pathway mutations on plasmid recombination were tested. Mutations in the recJ, recO, and ssb genes, when present in otherwise Rec+ E. coli strains, decreased the frequency of plasmid recombination, whereas the lexA3, recAo281, recN, and ruv mutations had no effect on plasmid recombination. Tn5 insertion mutations in the lexA gene increased the frequency of plasmid recombination. These data indicate that plasmid recombination events in wild-type Escherichia coli strains are catalyzed by a recombination pathway that is related to the RecF recombination pathway and that some component of this pathway besides the recA gene product is regulated by the lexA gene product.

Cloning of the Escherichia coli recJ chromosomal region and identification of its encoded proteins

A 9.6-kilobase BamHI-SalI fragment carrying recJ+ was cloned into vector pBR322. Deletion and transposon mutagenesis were used to map the recJ gene on this fragment. The maxicell protein-labeling technique was used to correlate a functional recJ gene with the presence of a polypeptide of 53,000 apparent molecular weight. Two additional genes, one encoding two proteins of 26,000 and 25,000 Mr and the other encoding a 31,000-Mr protein, were mapped on a 3.7-kilobase HindIII-SalI subfragment with recJ. Functions for these adjacent genes are not known; however, insertion mutations in these genes lessen the expression of the putative recJ protein detected in maxicells. A 9.6-kilobase BamHI-SalI fragment carrying the temperature-sensitive mutation recJ147 was also cloned and used for complementation studies to identify other recJ mutations.