Escherichia coli RuvC protein is an endonuclease that resolves the Holliday structure.

Genetic evidence suggests that the Escherichia coli ruvC gene is involved in DNA repair and in the late step of RecE and RecF pathway recombination. To study the biochemical properties of RuvC protein, we overproduced and highly purified the protein. By employing model substrates, we examined the possibility that RuvC protein is an endonuclease that resolves the Holliday structure, an intermediate in genetic recombination in which two double-stranded DNA molecules are linked by single-stranded crossover. RuvC protein cleaves cruciform junctions, which are formed by the extrusion of inverted repeat sequences from a supercoiled plasmid and which are structurally analogous to Holliday junctions, by introducing nicks into strands with the same polarity. The nicked ends are ligated by E.coli or T4 DNA ligases. Analysis of the cleavage sites suggests that DNA topology rather than a particular sequence determines the cleavage site. RuvC protein also cleaves Holliday junctions which are formed between gapped circular and linear duplex DNA by the function of RecA protein. However, it does not cleave a synthetic four-way junction that does not possess homology between arms. The active form of RuvC protein, as studied by gel filtration, is a dimer. This is mechanistically suited for an endonuclease involved in swapping DNA strands at the crossover junctions. From these properties of RuvC protein and the phenotypes of the ruvC mutants, we infer that RuvC protein is an endonuclease that resolves Holliday structures in vivo.     

Processing of intermediates in recombination and DNA repair: identification of a new endonuclease that specifically cleaves Holliday junctions.

The formation and subsequent resolution of Holliday junctions are critical stages in recombination. We describe a new Escherichia coli endonuclease that resolves Holliday intermediates by junction cleavage. The 14 kDa Rus protein binds DNA containing a synthetic four-way junction (X-DNA) and introduces symmetrical cuts in two strands to give nicked duplex products. Rus also processes Holliday intermediates made by RecA into products that are characteristic of junction resolution. The cleavage activity on X-DNA is remarkably similar to that of RuvC. Both proteins preferentially cut the same two strands at the same location. Increased expression of Rus suppresses the DNA repair and recombination defects of ruvA, ruvB and ruvC mutants. We conclude that all ruv strains are defective in junction cleavage, and discuss pathways for Holliday junction resolution by RuvAB, RuvC, RecG and Rus.     

Biological roles of the Escherichia coli RuvA, RuvB and RuvC proteins revealed

In Escherichia coli, the ruvA, ruvB and ruvC gene products are required for genetic recombination and the recombinational repair of DNA damage. New studies suggest that these three proteins function late in recombination and process Holliday junctions made by RecA protein-mediated strand exchange. In vitro, RuvA protein binds a Holliday junction with high affinity and, together with RuvB (an ATPase), promotes ATP-dependent branch migration of the junction leading to the formation of heteroduplex DNA. The third protein, RuvC, which acts independently of RuvA and RuvB, resolves recombination intermediates by specific endonucleolytic cleavage of the Holliday junction.     

Resolution of Holliday intermediates in recombination and DNA repair: indirect suppression of ruvA, ruvB, and ruvC mutations.

The ruvA, ruvB, and ruvC genes of Escherichia coli provide activities that catalyze branch migration and resolution of Holliday junction intermediates in recombination. Mutation of any one of these genes interferes with recombination and reduces the ability of the cell to repair damage to DNA. A suppressor of ruv mutations was identified on the basis of its ability to restore resistance to mitomycin and UV light and to allow normal levels of recombination in a recBC sbcBC strain carrying a Tn10 insertion in ruvA. The mutation responsible was located at 12.5 min on the genetic map and defines a new locus which has been designated rus. The rus suppressor works just as well in recBC sbcA and rec+ sbc+ backgrounds and is not allele specific. Mutations in ruvB and ruvC are suppressed to an intermediate level, except when ruvA is also inactive, in which case suppression is complete. In all cases, suppression depends on RecG protein, a DNA-dependent ATPase that catalyzes branch migration of Holliday junctions. The rus mutation activates an additional factor that probably works with RecG to process Holliday junction intermediates independently of the RuvAB and RuvC proteins. The possibility that this additional factor is a junction-specific resolvase is discussed.     

Two cDNAs from the plant Arabidopsis thaliana that partially restore recombination proficiency and DNA-damage resistance to E. coli mutants lacking recombination-intermediate-resolution activities.

Escherichia coli ruvC recG mutants lack RuvC endonuclease, which resolves crossed-strand joint molecules (Holliday junctions) formed during homologous recombination into recombinant products, and an activity (RecG) thought to partially replace RuvC. They are therefore highly deficient in homologous recombination, and sensitive to UV light and chemical DNA-damaging agents, presumably because of inability to tolerate unrepaired DNA damage by recombinational mechanisms (Lloyd, R.G. (1991) J. Bacteriol. 173:5414-5418). We transformed these mutants with plasmids expressing cDNAs from the plant Arabidopsis thaliana. Selection for bacteria with increased resistance to methylmethanesulfonate yielded two cDNAs, designated DRT111 and DRT112 (DNA-damage-repair/toleration). Expression of these plant cDNAs, especially DRT111, restored conjugal recombination proficiencies in ruvC and ruvC recG mutants to nearly wild-type levels. Both plant cDNAs significantly increased resistance of both mutants to UV light and several chemical DNA-damaging agents, but did not fully correct the mutant phenotypes. Drt111 activity, but not Drt112, also increased, to nearly wild-type levels, resistance of recG single mutants to UV plus mitomycin C. The predicted Drt111 and Drt112 polypeptides, 383 and 167 amino acids respectively, show no similarity with one another or with prokaryotic Holliday resolvases. Both appear chloroplast targeted; Drt112 is highly homologous to Arabidopsis plastocyanin. DRT111 and DRT112 probes hybridize only to DNA from closely related plants.     

Roles of RuvC and RecG in Phage λ Red-Mediated Recombination

The recombination properties of Escherichia coli strains expressing the red genes of bacteriophage lambda and lacking recBCD function either by mutation or by expression of lambda gam were examined. The substrates for recombination were nonreplicating lambda chromosomes, introduced by infection; Red-mediated recombination was initiated by a double-strand break created by the action of a restriction endonuclease in the infected cell. In one type of experiment, two phages marked with restriction site polymorphisms were crossed. Efficient formation of recombinant DNA molecules was observed in ruvC+ recG+, ruvC recG+, ruvC+ recG, and ruvC recG hosts. In a second type of experiment, a 1-kb nonhomology was inserted between the double-strand break and the donor chromosome's restriction site marker. In this case, recombinant formation was found to be partially dependent upon ruvC function, especially in a recG mutant background. In a third type of experiment, the recombining partners were the host cell chromosome and a 4-kb linear DNA fragment containing the cat gene, with flanking lac sequences, released from the infecting phage chromosome by restriction enzyme cleavage in the cell; the formation of chloramphenicol-resistant bacterial progeny was measured. Dependence on RuvC varied considerably among the three types of cross. However, in all cases, the frequency of Red-mediated recombination was higher in recG than in recG+. These observations favor models in which RecG tends to push invading 3'-ended strands back out of recombination intermediates.     

Resolution of Holliday junctions in Escherichia coli: identification of the ruvC gene product as a 19-kilodalton protein.

The ruvC gene of Escherichia coli specifies a nuclease that resolves Holliday junction intermediates in genetic recombination (B. Connolly, C.A. Parsons, F.E. Benson, H.J. Dunderdale, G.J. Sharples, R.G. Lloyd, and S.C. West, Proc. Natl. Acad, Sci. USA 88:6063-6067, 1991). The gene was located between aspS and the ruvAB operon by DNA sequencing and deletion analysis of ruvC plasmids and was shown to encode a protein of 18,747 Da. Analysis of the DNA flanking ruvC indicated that the gene is transcribed independently of the LexA-regulated ruvAB operon and is not under direct SOS control. ruvC lies downstream of an open reading frame, orf-33, for a protein which migrates during sodium dodecyl sulfate-polyacrylamide gel electrophoresis as a 33-kDa polypeptide. These two genes probably form an operon. However, expression of ruvC was found to be very poor relative to that of orf-33. A double ribosomal frameshift between these genes is proposed as a possible reason for the low level of RuvC. Two further open reading frames of unknown function were identified, one on either side of the orf-33-ruvC operon.     

A role for topoisomerase III in a recombination pathway alternative to RuvABC

The physiological role of topoisomerase III is unclear for any organism. We show here that the removal of topoisomerase III in temperature sensitive topoisomerase IV mutants in Escherichia coli results in inviability at the permissive temperature. The removal of topoisomerase III has no effect on the accumulation of catenated intermediates of DNA replication, even when topoisomerase IV activity is removed. Either recQ or recA null mutations, but not helD null or lexA3, partially rescued the synthetic lethality of the double topoisomerase III/IV mutant, indicating a role for topoisomerase III in recombination. We find a bias against deleting the gene encoding topoisomerase III in ruvC53 or DeltaruvABC backgrounds compared with the isogenic wild-type strains. The topoisomerase III RuvC double mutants that can be constructed are five- to 10-fold more sensitive to UV irradiation and mitomycin C treatment and are twofold less efficient in transduction efficiency than ruvC53 mutants. The overexpression of ruvABC allows the construction of the topoisomerase III/IV double mutant. These data are consistent with a role for topoisomerase III in disentangling recombination intermediates as an alternative to RuvABC to maintain the stability of the genome.     

Processing of recombination intermediates by the RecG and RuvAB proteins of Escherichia coli.

The RuvAB, RuvC and RecG proteins of Escherichia coli process intermediates in recombination and DNA repair into mature products. RuvAB and RecG catalyse branch migration of Holliday junctions, while RuvC resolves these structures by nuclease cleavage around the point of strand exchange. The overlap between RuvAB and RecG was investigated using synthetic X- and Y-junctions. RuvAB is a complex of RuvA and RuvB, with RuvA providing the DNA binding subunit and RuvB the ATPase activity that drives branch migration. Both RuvA and RecG form defined complexes with each of the junctions. The gel mobilities of these complexes suggests that the X-junction attracts two tetramers of RuvA, but mainly monomers of RecG. Dissociation of the junction in the presence of ATP requires high levels of RuvAB. RecG is shown to have a much higher specific activity to the extent that very little of this protein would be required to match RuvAB in vivo. Both proteins also dissociate a Y-junction, which is consistent with helicase activity. However, RecG shows no ability to unwind more conventional substrates and the suggestion is made that its helicase activity is directed towards specific DNA structures such as junctions.     

Chromosome Segregation and Cell Division Defects in recBC sbcBC ruvC Mutants of Escherichia coli

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

DprB facilitates inter- and intragenomic recombination in Helicobacter pylori

For naturally competent microorganisms, such as Helicobacter pylori, the steps that permit recombination of exogenous DNA are not fully understood. Immediately downstream of an H. pylori gene (dprA) that facilitates high-frequency natural transformation is HP0334 (dprB), annotated to be a putative Holliday junction resolvase (HJR). We showed that the HP0334 (dprB) gene product facilitates high-frequency natural transformation. We determined the physiologic roles of DprB by genetic analyses. DprB controls in vitro growth, survival after exposure to UV or fluoroquinolones, and intragenomic recombination. dprB ruvC double deletion dramatically decreases both homologous and homeologous transformation and survival after exposure to DNA-damaging agents. Moreover, the DprB protein binds to synthetic Holliday junction structures rather than double-stranded or single-stranded DNA. These results demonstrate that the dprB product plays important roles affecting inter- and intragenomic recombination. We provide evidence that the two putative H. pylori HJRs (DprB and RuvC) have overlapping but distinct functions involving intergenomic (primarily DprB) and intragenomic (primarily RuvC) recombination.     

Mutational analysis of conserved glycines 42 and 256 in Cephalosporium acremonium isopenicillin N synthase.

Isopenicillin N synthase (IPNS) is critical for the catalytic conversion of delta-(L-alpha-aminoadipoyl)-L-cysteinyl-D-valine to isopenicillin N in the penicillin and cephalosporin biosynthetic pathway. Two conserved glycine residues in Cephalosporium acremonium IPNS (cIPNS), namely glycine-42 and glycine-256, were identified by multiple sequence alignment and investigated by site-directed mutagenesis to study the effect of the substitution on catalysis. Our study showed that both the mutations from glycine to alanine or to serine reduced the catalytic activity of cIPNS and affected its soluble expression in a heterologous host at 37 degrees C. Soluble expression was restored at a reduced temperature of 25 degrees C, and thus, it is possible that these glycine residues may have a role in maintaining the local protein structure and are critical for the soluble expression of cIPNS.     

Ensuring productive resolution by the junction-resolving enzyme RuvC: large enhancement of the second-strand cleavage rate

RuvC is the principal junction-resolving enzyme of Escherichia coli, cleaving four-way DNA junctions created in homologous recombination. It binds with structural specificity to DNA junctions as a dimer, whereupon each subunit cleaves a phosphodiester bond of diametrically disposed strands. To generate a productive resolution event, these cleavages must be symmetrically located with respect to the point of strand exchange, and in the context of a branch-migrating junction, this requires near-simultaneous cleavage by the two subunits. Using a supercoil-stabilized cruciform as a substrate, we have analyzed the kinetics of strand cleavage. Coordinated bilateral cleavage is not essential in RuvC action, because a heterodimer comprising active and inactive subunits is active in unilateral cleavage. However, in operational terms, fully active RuvC appears to introduce simultaneous cleavages of two strands, because the rate of second-strand cleavage is accelerated by a factor of almost 150 relative to the first. We suggest that relief of strain following the first cleavage could lead to acceleration of subsequent cleavage, and show that DNA junctions rendered more flexible by the presence of strand breaks or bulges are subject to faster cleavage by RuvC. Cleavage of one strand of a junction generated in situ by the action of RuvC can accelerate cleavage at an intrinsically poor site by a factor of 500. Very large rate enhancement of second-strand cleavage by RuvC is likely to be essential to ensure productive resolution of a junction that is being actively branch migrated by the RuvAB machinery.     

Molecular analysis of mutations in a patient with purine nucleoside phosphorylase deficiency.

Purine nucleoside phosphorylase (PNP) deficiency is an inherited autosomal recessive disorder resulting in severe combined immunodeficiency. The purpose of this study was to determine the molecular defects responsible for PNP deficiency in one such patient. The patient's PNP cDNA was amplified by PCR and sequenced. Point mutations leading to amino acid substitutions were found in both alleles. One point mutation led to a Ser-to-Gly substitution at amino acid 51 and was common to both alleles. In addition, an Asp-to-Gly substitution at amino acid 128 and an Arg-to-Pro substitution at amino acid 234 were found in the maternal and paternal alleles, respectively. In order to prove that these mutations were responsible for the disease state, each of the three mutations was constructed separately by site-directed mutagenesis of the normal PNP cDNA, and each was transiently expressed in COS cells. Lysates from cells transfected with the allele carrying the substitution at amino acid 51 retained both function and immunoreactivity. Lysates from cells transfected with PNP alleles carrying a substitution at either amino acid 128 or amino acid 234 contained immunoreactive material but had no detectable human PNP activity. In summary, molecular analysis of this patient identified point mutations within the PNP gene which are responsible for the enzyme deficiency.     

Hypothesis. RuvA,RuvB and RuvC proteins: Cleaning-up after recombinational repairs in E. coli

After the completion of RecA protein-mediated recombinational repair of daughter-strand gaps in E. coli, participating chromosomes are held together by Holliday junctions. Until recently, it was not known how the cell disengages the connected chromosomes. Accumulating genetic data suggested that the product of the ruv locus participates in recombinational repair and acts after the formation of Holliday junctions. Molecular characterization of the locus revealed that there are three genes – ruvA, ruvB and ruvC; mutations in any one of the genes confer the same phenotype. Recently, the RuvC protein was found to be a Holliday junction resolvase. At first glance, the resolving activity of RuvC alone would appear to be sufficient for the separation of recombining chromosomes. However, in vitro studies show that the filament of RecA protein is unable to dissociate from the products of the recombination reaction. Thus, in vivo, even if the Holliday junctions are resolved by RuvC, RecA filament must be holding two DNA duplexes together. New findings about enzymatic activities of RuvA and RuvB proteins foster the hope that the machinery for removing the RecA filament from DNA has been found.     

Dissociation of synthetic Holliday junctions by E. coli RecG protein.

The RecG protein of Escherichia coli is needed for normal levels of recombination and for repair of DNA damaged by ultraviolet light, mitomycin C and ionizing radiation. The true extent of its involvement in these processes is masked to a large degree by what appears to be a functional overlap with the products of the three ruv genes. RuvA and RuvB act together to promote branch migration of Holliday junctions, while RuvC catalyses the resolution of these recombination intermediates into viable products by endonuclease cleavage. In this paper, we describe the overproduction and purification of RecG and demonstrate that the overlap extends to the biochemistry. We show that the 76 kDa RecG protein is a DNA-dependent ATPase, like RuvB. Using gel retardation assays we demonstrate that it binds specifically to a synthetic Holliday junction, like RuvA and RuvC. Finally, we show that in the presence of ATP and Mg2+, RecG dissociates these junctions to duplex products, like RuvAB. We suggest that RecG and RuvAB provide alternative activities than can promote branch migration of Holliday junctions in recombination and DNA repair.     

Protein engineering of Bacillus megaterium CYP102.The oxidation of polycyclic aromatic hydrocarbons.

Cytochrome P450 (CYP) enzymes are involved in activating the carcinogenicity of polycyclic aromatic hydrocarbons (PAHs) in mammals, but they are also utilized by microorganisms for the degradation of these hazardous environmental contaminants. Wild-type CYP102 (P450(BM-3)) from Bacillus megaterium has low activity for the oxidation of the PAHs phenanthrene, fluoranthene and pyrene. The double hydrophobic substitution R47L/Y51F at the entrance of the substrate access channel increased the PAH oxidation activity by up to 40-fold. Combining these mutations with the active site mutations F87A and A264G lead to order of magnitude increases in activity. Both these mutations increased the NADPH turnover rate, but the A264G mutation increased the coupling efficiency while the F87A mutation had dominant effects in product selectivity. Fast NADPH oxidation rates were observed (2250 min-1 for the R47L/Y51F/F87A mutant with phenanthrene) but the coupling efficiencies were relatively low (< 13%), resulting in a highest substrate oxidation rate of 110 min-1 for fluoranthene oxidation by the R47L/Y51F/A264G mutant. Mutation of M354 and L437 inside the substrate access channel reduced PAH oxidation activity. The PAHs were oxidized to a mixture of phenols and quinones. Notably mutants containing the A264G mutation showed some similarity to mammalian CYP enzymes in that some 9,10-phenanthrenequinone, the K-region oxidation product from phenanthrene, was formed. The results suggest that CYP102 mutants could be useful models for PAH oxidation by mammalian CYP enzymes, and also potentially for the preparation of novel PAH bioremediation systems.     

Requirement for GLY-60 of Escherichia coli adenylyl cyclase for ATP binding and catalytic activity.

The region of Escherichia coli adenylyl cyclase spanned by glycine-55 to threonine-65 was tested for its importance for enzyme activity. Site-directed mutagenesis was used to replace glycine-55 and glycine-60 as well as lysine-59, leucine-63 and threonine-65 with other amino acids. While substitution of glycine-55 with aspartic acid produced no significant change in kinetic parameters, the change of glycine-60 to aspartic acid or asparagine eliminated binding to 8-azido-ATP and decreased the Vmax (two orders of magnitude) and Km (factor of four-five). Smaller effects on kinetic parameters were observed with substitutions of lysine-59, leucine-63 or threonine-65.     

Sequence and functional-group specificity for cleavage of DNA junctions by RuvC of Escherichia coli.

RuvC is the DNA junction-resolving enzyme of Escherichia coli. While the enzyme binds to DNA junctions independently of base sequence, it exhibits considerable sequence selectivity for the phosphodiester cleavage reaction. We have analyzed the sequence specificity using a panel of DNA junctions, measuring the rate of cleavage of each under single-turnover conditions. We have found that the optimal sequence for cleavage can be described by (A approximately T)TT downward arrow(C>G approximately A), where downward arrow denotes the position of backbone scission. Cleavage is fastest when the cleaved phosphodiester linkage is located at the point of strand exchange. However, cleavage is possible one nucleotide 3' of this position when directed by the sequence, with a rate that is 1 order of magnitude slower than the optimal. The maximum sequence discrimination occurs at the central TT in the tetranucleotide site, where any alteration of sequence results in a rate reduction of at least 100-fold and cleavage is undetectable for some changes. However, certain sequences in the outer nucleotides are strongly inhibitory to cleavage. Introduction of base analogues around the cleavage site reveals a number of important functional groups and suggests that major-groove contacts in the center of the tetranucleotide are important for the cleavage process. Since RuvC binds to all the variant junctions with very similar affinity, any contacts affecting the rate of cleavage must be primarily important in the transition state. Introduction of the optimal cleavage sequence into a three-way DNA junction led to relatively efficient cleavage by RuvC, at a rate only 3-fold slower than the optimal four-way junction. This is consistent with a protein-induced alteration in the conformation of the DNA.