Reciprocal control of catalysis by the tyrosine recombinases XerC and XerD: an enzymatic switch in site-specific recombination

In Xer site-specific recombination, sequential DNA strand exchange reactions are catalyzed by a heterotetrameric complex composed of two recombinases, XerC and XerD. It is demonstrated that XerC and XerD catalytic activity is controlled by an interaction involving the C-terminal end of each protein (the donor region) and an internal region close to the active site (the acceptor region). Mutations in these regions reciprocally alter the relative activity of XerC and XerD, with their combination producing synergistic effects on catalysis. The data support a model in which C-terminal intersubunit interactions contribute to coupled protein-DNA conformational changes that lead to sequential activation and reciprocal inhibition of pairs of active sites in the recombinase tetramer during recombination.     

Switching catalytic activity in the XerCD site-specific recombination machine.

The tyrosine family site-specific recombinases, XerCD, function in the conversion of circular dimer replicons to monomers. In the recombining complex that contains two synapsed recombination sites and two molecules each of XerC and XerD, the DNA strand-exchange reactions are separated in time and space. XerC initiates recombination to form a Holliday junction intermediate, which undergoes a conformational change to provide a substrate for strand exchange by XerD. XerCD are two-domain proteins, whose C-terminal domains contain all of the catalytic residues. We show that XerC or XerD variants lacking their N-terminal domains are active in recombination when combined with their wild-type partner. Nevertheless, the normal pattern of catalysis is dramatically altered; strand exchange by the recombinase variant is stimulated, while that by the wild-type partner recombinase is impaired. The primary determinants for the mutant phenotype reside in the region of alpha-helix B of XerD. We propose that altered interactions within the recombining heterotetramer lead to changes in the relative concentrations of the two alternative Holliday junction substrates that are recombined by XerC or XerD, respectively.     

Coordinated control of XerC and XerD catalytic activities during Holliday junction resolution

Site-specific recombinases XerC and XerD function in the segregation of circular bacterial replicons. In a recombining nucleoprotein complex containing two molecules each of XerC and XerD, coordinated reciprocal switches in recombinase activity ensure that only XerC or XerD is active at any one time. Mutated recombinases that carry sub?stitutions of a catalytic arginine residue stimulate cleavage and strand exchange mediated by the partner recombinase on DNA substrates that are normally recombined poorly by the partner. This is associated with a reciprocal impairment of the recombinase's own ability to initiate catalysis. The extent of this switch in catalysis is modulated by changes in recombination site sequence and is not a direct consequence of any catalytic defect. We propose that altered interactions between the mutated proteins and their wild-type partners lead to an increased level of an alternative Holliday junction intermediate that has a conformation appropriate for resolution by the partner recombinase. The results indicate how subtle changes in protein-DNA architecture at a Holliday junction can redirect recombination outcome.     

Antagonistic effect of CRP and KdgR in the transcription control of the Erwinia chrysanthemi pectinolysis genes

XerC and XerD are related 298-amino-acid site-specific recombinases, each of which is responsible for the exchange of one pair of strands in Xer recombination. Both recombinases encode functions necessary for sequence-specific DNA-binding, co-operative XerC/D interactions, synapsis and catalysis. These functions were related to the primary amino acid sequence by constructing and analysing internal and C-terminal XerD deletions. An XerD derivative containing residues 1–233 was proficient in specific DNA binding, but did not interact co-operatively with XerC. Deletion of a further five C-terminal amino acids abolished binding to DNA. Proteins deleted for residues 32–88 and for residues 145–159 were deficient in DNA binding. Deletion of residues 244–281, a region containing amino acids necessary for catalysis, gave a protein that bound to DNA. An XerD derivative containing residues 1–268 retained co-operative interactions with XerC; nevertheless, it did not support XerC strand exchange and was defective in XerD catalysis. Residues 1–283 retain a functional catalytic active site, though a protein lacking the five C-terminal amino acids was still unable to mediate normal in vivo recombination, indicating that these residues are needed for a function that is not directly related to DNA binding or catalysis.     

C-terminal interactions between the XerC and XerD site-specific recombinases

Studies of the site-specific recombinase Cre suggest a key role for interactions between the C-terminus of the protein and a region located about 30 residues from the C-terminus in linking in a cyclical manner the four recombinase monomers present in a recombination complex, and in controlling the catalytic activity of each monomer. By extrapolating the Cre DNA recombinase structure to the related site-specific recombinases XerC and XerD, it is predicted that the extreme C-termini of XerC and XerD interact with alpha-helix M in XerD and the equivalent region of XerC respectively. Consequently, XerC and XerD recombinases deleted for C-terminal residues, and mutated XerD proteins containing single amino acid substitutions in alphaM or in the C-terminal residues were analysed. Deletion of C-terminal residues of XerD has no measurable effect on co-operative interactions with XerC in DNA-binding assays to the recombination site dif, whereas deletion of 5 or 10 residues of XerC reduces co-operativity with XerD some 20-fold. Co-operative interactions between pairs of truncated proteins during dif DNA binding are reduced 20- to 30-fold. All of the XerD mutants, except one, were catalytically proficient in vitro; nevertheless, many failed to mediate a recombination reaction on supercoiled plasmid in vivo or in vitro, implying that the ability to form a productive recombination complex and/or mediate a controlled recombination reaction is impaired.     

Xer site-specific recombination in vitro.

Two related recombinases, XerC and XerD, belonging to the lambda integrase family of enzymes, are required for Xer site-specific recombination in vivo. In order to understand the roles of these proteins in the overall reaction mechanism, an in vitro recombination system using a synthetic Holliday junction-containing substrate has been developed. Recombination of this substrate is efficient and requires both XerC and XerD. However, only exchange of one pair of strands, the one corresponding to the conversion of the Holliday junction intermediate back to the substrate, has been observed. Recombination reactions using XerC and XerD derivatives that are mutant in their presumptive catalytic residues, or are maltose-binding fusion recombinase derivatives, have demonstrated that this pair of strand exchanges is catalysed by XerC. The site of XerC-mediated cleavage has been located to between the last nucleotide of the XerC binding site and the first nucleotide of the central region. Cleavage at this site generates a free 5'-OH and a covalent complex between XerC and the 3' end of the DNA.     

Xer site-specific recombination. DNA strand rejoining by recombinase XerC

Xer site-specific recombination functions in the stable maintenance of circular replicons in Escherichia coli. Each of two related recombinase proteins, XerC and XerD, cleaves a specific pair of DNA strands, exchanges them, and rejoins them to the partner DNA molecule during a complete recombination reaction. The rejoining activity of recombinase XerC has been analyzed using isolated covalent XerC-DNA complexes resulting from DNA cleavage reactions upon Holliday junction substrates. These covalent protein-DNA complexes are competent in the rejoining reaction, demonstrating that covalently bound XerC can catalyze strand rejoining in the absence of other proteins. This contrasts with a recombinase-mediated cleavage reaction, which requires the presence of both recombinases, the recombinase mediating catalysis at any given time requiring activation by the partner recombinase. In a recombining nucleoprotein complex, both cleavage and rejoining can occur prior to dissociation of the complex.     

Asymmetric activation of Xer site-specific recombination by FtsK

Chromosome dimers, which frequently form in Escherichia coli, are resolved by the combined action of two tyrosine recombinases, XerC and XerD, acting at a specific site on the chromosome, dif, together with the cell division protein FtsK. The C-terminal domain of FtsK (FtsK(C)) is a DNA translocase implicated in helping synapsis of the dif sites and in locally promoting XerD strand exchanges after synapse formation. Here we show that FtsK(C) ATPase activity is directly involved in the local activation of Xer recombination at dif, by using an intermolecular recombination assay that prevents significant DNA translocation, and we confirm that FtsK acts before Holliday junction formation. We show that activation only occurs with a DNA segment adjacent to the XerD-binding site of dif. Only one such DNA extension is required. Taken together, our data suggest that FtsK needs to contact the XerD recombinase to switch its activity on using ATP hydrolysis.     

Interactions of the site-specific recombinases XerC and XerD with the recombination site dif.

The Xer site-specific recombination system of Escherichia coli is involved in the stable inheritance of circular replicons. Multimeric replicons, produced by homologous recombination, are converted to monomers by the action of two related recombinases XerC and XerD. Site-specific recombination at a locus, dif, within the chromosomal replication terminus region is thought to convert dimeric chromosomes to monomers, which can then be segregated prior to cell division. The recombinases XerC and XerD bind cooperatively to dif, where they catalyse recombination. Chemical modification of specific bases and the phosphate-sugar backbone within dif was used to investigate the requirements for binding of the recombinases. Site-directed mutagenesis was then used to alter bases implicated in recombinase binding. Characterization of these mutants by in vitro recombinase binding and in vivo recombination, has demonstrated that the cooperative interactions between XerC and XerD can partially overcome DNA alterations that should interfere with specific recombinase-dif interactions.     

The single-stranded genome of phage CTX is the form used for integration into the genome of Vibrio cholerae

A major determinant of Vibrio cholerae pathogenicity, the cholera enterotoxin, is encoded in the genome of an integrated phage, CTXvarphi. CTXvarphi integration depends on two host-encoded tyrosine recombinases, XerC and XerD. It occurs at dif1, a 28 bp site on V. cholerae chromosome 1 normally used by XerCD for chromosome dimer resolution. The replicative form of the phage contains two pairs of binding sites for XerC and XerD in inverted orientations. Here we show that in the single-stranded genome of the phage, these sites fold into a hairpin structure, which creates a recombination target for XerCD. In the presence of XerD, XerC can catalyze a single pair of strand exchanges between this target and dif1, resulting in integration of the phage. This integration strategy explains why the rules that normally apply to tyrosine recombinase reactions seemed not to apply to CTXvarphi integration and, in particular, why integration is irreversible.     

Effects of Holliday junction position on Xer-mediated recombination in vitro.

Site-specific recombination mediated by XerC and XerD functions in the segregation of circular replicons in Escherichia coli. A key feature of most models of recombination for the family of recombinases to which XerC and XerD belong is that a Holliday junction forms at the position of the first pair of recombinase-mediated strand exchanges and then branch migrates 6-8 bp to the position of the second pair of strand exchanges. We have tested this hypothesis for Xer recombination by studying the effects of junction position on XerC-mediated strand exchange in vitro. Recombination of synthetic Holliday junction substrates in which junction mobility was constrained to a region extending over or removed away from the normal cleavage and exchange point was analysed. All substrates undergo strand cleavage at the normal position. We infer that the Holliday junction need not be at this position during strand cleavage and exchange. With substrates in which the Holliday junction is constrained to a region away from the XerC-mediated cleavage point, strand exchange generates products with the predicted mispaired bases.     

Sequential strand exchange by XerC and XerD during site-specific recombination at dif

Successful segregation of circular chromosomes in Escherichia coli requires that dimeric replicons, produced by homologous recombination, are converted to monomers prior to cell division. The Xer site-specific recombination system uses two related tyrosine recombinases, XerC and XerD, to catalyze resolution of circular dimers at the chromosomal site, dif. A 33-base pair DNA fragment containing the 28-base pair minimal dif site is sufficient for the recombinases to mediate both inter- and intramolecular site-specific recombination in vivo. We show that Xer-mediated intermolecular recombination in vitro between nicked linear dif "suicide" substrates and supercoiled plasmid DNA containing dif is initiated by XerC. Furthermore, on the appropriate substrate, the nicked Holliday junction intermediate formed by XerC is converted to a linear product by a subsequent single XerD-mediated strand exchange. We also demonstrate that a XerC homologue from Pseudomonas aeruginosa stimulates strand cleavage by XerD on a nicked linear substrate and promotes initiation of strand exchange by XerD in an intermolecular reaction between linear and supercoiled DNA, thereby reversing the normal order of strand exchanges.     

Action of site-specific recombinases XerC and XerD on tethered Holliday junctions.

In Xer site-specific recombination, two related recombinases, XerC and XerD, mediate the formation of recombinant products using Holliday junction-containing DNA molecules as reaction intermediates. Each recombinase catalyses the exchange of one pair of specific strands. By using synthetic Holliday junction-containing recombination substrates in which two of the four arms are tethered in an antiparallel configuration by a nine thymine oligonucleotide, we show that XerD catalyses efficient strand exchange only when its substrate strands are 'crossed'. XerC also catalyses very efficient strand exchange when its substrate strands are 'crossed', though it also appears to be able to mediate strand exchange when its substrate strands are 'continuous'. By using chemical probes of Holliday junction structure in the presence and absence of bound recombinases, we show that recombinase binding induces unstacking of the bases in the centre of the recombination site, indicating that the junction branch point is positioned there and is distorted as a consequence of recombinase binding.     

Xer-mediated site-specific recombination in vitro.

The Xer site-specific recombination system acts at ColE1 cer and pSC101 psi sites to ensure that these plasmids are in a monomeric state prior to cell division. We show that four proteins, ArgR, PepA, XerC and XerD are necessary and sufficient for recombination between directly repeated cer sites on a supercoiled plasmid in vitro. Only PepA, XerC and XerD are required for recombination at psi in vitro. Recombination at cer and psi in vitro requires negative supercoiling and is exclusively intramolecular. Strand exchange at cer produces Holliday junction-containing products in which only the top strands have been exchanged. This reaction requires the catalytic tyrosine residue of Xer C but not that of XerD. Recombination at psi gives catenated circular resolution products. Strand exchange at psi is sequential. XerC catalyses the first (top) strand exchange to make a Holiday junction intermediate and XerD catalyses the second (bottom) strand exchange.     

Dissection of a functional interaction between the DNA translocase, FtsK, and the XerD recombinase

Successful bacterial circular chromosome segregation requires that any dimeric chromosomes, which arise by crossing over during homologous recombination, are converted to monomers. Resolution of dimers to monomers requires the action of the XerCD site-specific recombinase at dif in the chromosome replication terminus region. This reaction requires the DNA translocase, FtsK(C), which activates dimer resolution by catalysing an ATP hydrolysis-dependent switch in the catalytic state of the nucleoprotein recombination complex. We show that a 62-amino-acid fragment of FtsK(C) interacts directly with the XerD C-terminus in order to stimulate the cleavage by XerD of BSN, a dif-DNA suicide substrate containing a nick in the 'bottom' strand. The resulting recombinase-DNA covalent complex can undergo strand exchange with intact duplex dif in the absence of ATP. FtsK(C)-mediated stimulation of BSN cleavage by XerD requires synaptic complex formation. Mutational impairment of the XerD-FtsK(C) interaction leads to reduction in the in vitro stimulation of BSN cleavage by XerD and a concomitant deficiency in the resolution of chromosomal dimers at dif in vivo, although other XerD functions are not affected.     

Norfloxacin-induced DNA cleavage occurs at the dif resolvase locus in Escherichia coli and is the result of interaction with topoisomerase IV

The dif locus is a site-specific recombination site located within the terminus region of the chromosome of Escherichia coli. Recombination at dif resolves circular dimer chromosomes to monomers, and this recombination requires the XerC, XerD and FtsK proteins, as well as cell division. In order to characterize other enzymes that interact at dif, we tested whether quinolone-induced cleavage occurs at this site. Quinolone drugs, such as norfloxacin, inhibit the type 2 topoisomerases, DNA gyrase and topoisomerase IV, and can cleave DNA at sites where these enzymes interact with the chromosome. Using strains in which either DNA gyrase or topoisomerase IV, or both, were resistant to norfloxacin, we determined that specific interactions between dif and topoisomerase IV caused cleavage at that site. This interaction required XerC and XerD, but did not require the C-terminal region of FtsK or cell division.     

The XerC recombinase of Proteus mirabilis: characterization and interaction with other tyrosine recombinases

XerC and XerD are two site-specific recombinases, which act on different sites to maintain replicons in a monomeric state. This system, which was first discovered and studied in Escherichia coli, is present in several species including Proteus mirabilis, where the XerD recombinase was previously characterized by our laboratory. In this paper, we report the presence of the xerC gene in P. mirabilis. Using in vitro reactions, we show that the two P. mirabilis recombinases display binding and cleavage activity on the E. coli dif site and the ColE1 cer site, together or in collaboration with E. coli recombinases. In vivo, P. mirabilis XerC and XerD are able to resolve and monomerize a plasmid containing two cer sites, increasing its stability. However, P. mirabilis XerC, in combination with E. coli XerD, is unable to perform these functions.     

Growth temperature regulation of some genes that define the superficial capsular carbohydrate composition of Escherichia coli K92

XerC and XerD are members of the tyrosine recombinase family and mediate site-specific recombination that contributes to the stability of circular chromosomes in bacteria by resolving plasmid multimers and chromosome dimers to monomers prior to cell division. Homologues of xerC/xerD genes have been found in many bacteria, and in the lactococci and streptococci, a single recombinase called XerS can perform the functions of XerC and XerD. The xerS gene of Streptococcus suis was cloned, overexpressed and purified as a maltose-binding protein (MBP) fusion. The purified MBP-XerS fusion showed specific DNA-binding activity to both halves of the dif site of S.?suis, and covalent protein-DNA complexes were also detected with dif site suicide substrates. These substrates were also cleaved in a specific fashion by MBP-XerS, generating cleavage products separated by an 11-bp spacer region, unlike the traditional 6-8-bp spacer observed in most tyrosine recombinases. Furthermore, xerS mutants of S.?suis showed significant growth and morphological changes.     

Differences in resolution of mwr-containing plasmid dimers mediated by the Klebsiella pneumoniae and Escherichia coli XerC recombinases: potential implications in dissemination of antibiotic resistance genes

Xer-mediated dimer resolution at the mwr site of the multiresistance plasmid pJHCMW1 is osmoregulated in Escherichia coli containing either the Escherichia coli Xer recombination machinery or Xer recombination elements from K. pneumoniae. In the presence of K. pneumoniae XerC (XerC(Kp)), the efficiency of recombination is lower than that in the presence of the E. coli XerC (XerC(Ec)) and the level of dimer resolution is insufficient to stabilize the plasmid, even at low osmolarity. This lower efficiency of recombination at mwr is observed in the presence of E. coli or K. pneumoniae XerD proteins. Mutagenesis experiments identified a region near the N terminus of XerC(Kp) responsible for the lower level of recombination catalyzed by XerC(Kp) at mwr. This region encompasses the second half of the predicted alpha-helix B and the beginning of the predicted alpha-helix C. The efficiencies of recombination at other sites such as dif or cer in the presence of XerC(Kp) or XerC(Ec) are comparable. Therefore, XerC(Kp) is an active recombinase whose action is impaired on the mwr recombination site. This characteristic may result in restriction of the host range of plasmids carrying this site, a phenomenon that may have important implications in the dissemination of antibiotic resistance genes.     

Smarter than the average phage

The seventh cholera pandemic emerged in the poorer nations of the world towards the end of the 20th century and continues to kill thousands of people per year. The causative agent of cholera, the Gram-negative bacterium Vibrio cholera, is only pathogenic when it contains a lysogenic bacteriophage, CTXphi, that encodes the toxin responsible for inducing massive fluid loss from the human host. Site-specific integration of CTXphi into chromosome I of V. cholera occurs at a site, dif, that is normally required for resolution of chromosome dimers generated by homologous recombination. An article in this issue of Molecular Microbiology reports the analysis of interactions between two host encoded recombinases, XerC and XerD, and the recombination sites involved in lysogeny. Surprisingly, recombination between the CTXphi attP site and the chromosomal dif site requires additional recombinase binding sites, downstream from the positions of strand exchange, which might play an architectural role. The positions of strand cleavage also differ significantly between the two sites, suggesting a novel recombination mechanism that implicates additional host factors in resolution of the Holliday junction intermediate.