Recombination at ColE1 cer requires the Escherichia coli xerC gene product, a member of the lambda integrase family of site-specific recombinases

FtsK functions in the processing of a Holliday junction intermediate during bacterial chromosome segregation

In bacteria with circular chromosomes, homologous recombination can generate chromosome dimers that cannot be segregated to daughter cells at cell division. Xer site-specific recombination at dif, a 28-bp site located in the replication terminus region of the chromosome, converts dimers to monomers through the sequential action of the XerC and XerD recombinases. Chromosome dimer resolution requires that dif is positioned correctly in the chromosome, and the activity of FtsK, a septum-located protein that coordinates cell division with chromosome segregation. Here, we show that cycles of XerC-mediated strand exchanges form and resolve Holliday junction intermediates back to substrate irrespective of whether conditions support a complete recombination reaction. The C-terminal domain of FtsK is sufficient to activate the exchange of the second pair of strands by XerD, allowing both intra- and intermolecular recombination reactions to go to completion. Proper positioning of dif in the chromosome and of FtsK at the septum is required to sense the multimeric state of newly replicated chromosomes and restrict complete Xer reactions to dimeric chromosomes.

Root colonization by phenazine-1-carboxamide-producing bacterium Pseudomonas chlororaphis PCL1391 is essential for biocontrol of tomato foot and root rot

The phenazine-1-carboxamide-producing bacterium Pseudomonas chlororaphis PCL1391 controls tomato foot and root rot caused by Fusarium oxysporum f. sp. radicislycopersici. To test whether root colonization is required for biocontrol, mutants impaired in the known colonization traits motility, prototrophy for amino acids, or production of the site-specific recombinase, Sss/XerC were tested for their root tip colonization and biocontrol abilities. Upon tomato seedling inoculation, colonization mutants of strain PCL1391 were impaired in root tip colonization in a gnotobiotic sand system and in potting soil. In addition, all mutants were impaired in their ability to control tomato foot and root rot, despite the fact that they produce wild-type levels of phenazine-1-carboxamide, the antifungal metabolite previously shown to be required for biocontrol. These results show, for what we believe to be the first time, that root colonization plays a crucial role in biocontrol, presumably by providing a delivery system for antifungal metabolites. The ability to colonize and produce phenazine-1-carboxamide is essential for control of F. oxysporum f. sp. radicis-lycopersici. Furthermore, there is a notable overlap of traits identified as being important for colonization of the rhizosphere and animal tissues.

The sss colonization gene of the tomato-Fusarium oxysporum f. sp. radicis-lycopersici biocontrol strain Pseudomonas fluorescens WCS365 can improve root colonization of other wild-type pseudomonas spp.bacteria

We show that the disease tomato foot and root rot caused by the pathogenic fungus Fusarium oxysporum f. sp. radicis-lycopersici can be controlled by inoculation of seeds with cells of the efficient root colonizer Pseudomonas fluorescens WCS365, indicating that strain WCS365 is a biocontrol strain. The mechanism for disease suppression most likely is induced systemic resistance. P. fluorescens strain WCS365 and P. chlororaphis strain PCL1391, which acts through the production of the antibiotic phenazine-1-carboxamide, were differentially labeled using genes encoding autofluorescent proteins. Inoculation of seeds with a 1:1 mixture of these strains showed that, at the upper part of the root, the two cell types were present as microcolonies of either one or both cell types. Microcolonies at the lower root part were predominantly of one cell type. Mixed inoculation tended to improve biocontrol in comparison with single inoculations. In contrast to what was observed previously for strain PCL1391, mutations in various colonization genes, including sss, did not consistently decrease the biocontrol ability of strain WCS365. Multiple copies of the sss colonization gene in WCS365 improved neither colonization nor biocontrol by this strain. However, introduction of the sss-containing DNA fragment into the poor colonizer P. fluorescens WCS307 and into the good colonizer P. fluorescens F113 increased the competitive tomato root tip colonization ability of the latter strains 16- to 40-fold and 8- to 16-fold, respectively. These results show that improvement of the colonization ability of wild-type Pseudomonas strains by genetic engineering is a realistic goal.

Mutational analysis of Escherichia coli PepA, a multifunctional DNA-binding aminopeptidase

Escherichia coli PepA is a hexameric aminopeptidase that is also endowed with a DNA-binding activity that functions in transcription control and plasmid dimer resolution. To gain further insight into the functioning of PepA, mutants were selected on the basis of reduced repressibility of a genomic carA-lacZ fusion and studied for the various cellular processes requiring PepA, i.e. repression of the carAB operon, autoregulation, resolution of ColE1 multimers, and peptide proteolysis. The methylation status of the carAB control region was analysed in several pepA mutants and purified proteins were assayed in vitro for car operator DNA binding. This study provides a critical test of predictions advanced on the basis of the structural analysis of PepA and demonstrates the importance for DNA binding of several secondary structural elements in the N-terminal domain and near the very C terminus. By analysis of single amino acid substitutions, we could distinguish the mode of PepA action in car regulation from its action in plasmid resolution. We demonstrate that mere binding of PepA to the car control region is not sufficient to explain its role in pyrimidine-specific regulation; protein-protein interactions appear to play an important role in transcriptional repression. The multifunctional character of PepA and of an increasing number of transcriptional regulators that combine catalytic and regulatory properties, of which several participate in the metabolism of arginine and of the pyrimidines, suggests that enzymes and DNA (RNA) binding proteins fulfilling an essential primeval function may have been recruited in evolution to fulfil an additional regulatory task.

Cell division, guillotining of dimer chromosomes and SOS induction in resolution mutants (dif, xerC and xerD) of Escherichia coli

We have studied the growth and division of xerC, xerD and dif mutants of Escherichia coli, which are unable to resolve dimer chromosomes. These mutants express the Dif phenotype, which includes reduced viability, SOS induction and filamentation, and abnormal nucleoid morphology. Growth was studied in synchronous cultures and in microcolonies derived from single cells. SOS induction and filamentation commenced after an apparently normal cell division, which sheared unresolved dimer chromosomes. This has been called guillotining. Microcolony analysis demonstrated that cell division in the two daughter cells was inhibited after guillotining, and microcolonies formed that consisted of two filaments lying side by side. Growth of these filaments was severely reduced in hipA+ strains. We propose that guillotining at dif destroys the expression of the adjacent hipBA genes and, in the absence of continued formation of HipB, HipA inhibits growth. The length of the filaments was also affected by SfiA: sfiA dif hipA mutants initially formed filaments, but cell division at the ends of the filaments ultimately produced a number of DNA-negative cells. If SOS induction was blocked by lexA3 (Ind-), filaments did not form, and cell division was not inhibited. However, pedigree analysis of cells in microcolonies demonstrated that lethal sectoring occurred as a result of limited growth and division of dead cells produced by guillotining.

Functional polarization of the Escherichia coli chromosome terminus: the dif site acts in chromosome dimer resolution only when located between long stretches of opposite polarity

In Escherichia coli, chromosome dimers are generated by recombination between circular sister chromosomes. Dimers are lethal unless resolved by a system that involves the XerC, XerD and FtsK proteins acting at a site (dif) in the terminus region. Resolution fails if dif is moved from its normal position. To analyse this positional requirement, dif was transplaced to a variety of positions, and deletions and inversions of portions of the dif region were constructed. Resolution occurs only when dif is located at the convergence of multiple, oppositely polarized DNA sequence elements, inferred to lie in the terminus region. These polar elements may position dif at the cell septum and be general features of chromosome organization with a role in nucleoid dynamics.

Stability by multimer resolution of pJHCMW1 is due to the Tn1331 resolvase and not to the Escherichia coli Xer system

The plasmid pJHCMW1 encodes resistance to several aminoglycosides and beta-lactams and consists of a copy of the transposon Tn1331, a region including the replication functions, and a sequence with homology to ColE1 cer, designated mwr. In this work, the role of this cer-like site in ensuring the stable inheritance of pJHCMW1 by multimer resolution was studied. The Escherichia coli Xer site-specific recombination system acts at sites such as ColE1 cer to resolve plasmid multimers formed by homologous recombination, thereby maintaining plasmids in a monomeric state and helping to ensure stable plasmid inheritance. Despite its high similarity to ColE1 cer, the pJHCMW1 mwr was a poor substrate for Xer recombination in E. coli and did not contribute significantly to plasmid stability. Instead, the Tn1331 co-integrate resolution system was highly active at resolving pJHCMW1 multimers and ensured the stable inheritance of pJHCMW1. Although Xer recombination at pJHCMW1 mwr was inefficient in E. coli, the recombination that did occur was dependent on ArgR, PepA, XerC and XerD. A supercoiled circular DNA molecule containing two pJHCMW1 mwr sites in direct repeat yielded Holliday-junction-containing product when incubated with ArgR, PepA, XerC and XerD in vitro, confirming that pJHCMW1 mwr is a functional recombination site. However, unlike cer, some Holliday-junction-containing product could be detected for mwr in the absence of ArgR, although addition of this protein resulted in formation of more Holliday junctions. Binding experiments demonstrated that XerD bound to pJHCMW1 mwr core with a high affinity, but that XerC bound to this site very poorly, even in the presence of XerD.

Prophage lambda induces terminal recombination in Escherichia coli by inhibiting chromosome dimer resolution. An orientation-dependent cis-effect lending support to bipolarization of the terminus

A prophage lambda inserted by homologous recombination near dif, the chromosome dimer resolution site of Escherichia coli, is excised at a frequency that depends on its orientation with respect to dif. In wild-type cells, terminal hyper- (TH) recombination is prophage specific and undetectable by a test involving deletion of chromosomal segments between repeats identical to those used for prophage insertion. TH recombination is, however, detected in both excision and deletion assays when Deltadif, xerC, or ftsK mutations inhibit dimer resolution: lack of specialized resolution apparently results in recombinogenic lesions near dif. We also observed that the presence near dif of the prophage, in the orientation causing TH recombination, inhibits dif resolution activity. By its recombinogenic effect, this inhibition explains the enhanced prophage excision in wild-type cells. The primary effect of the prophage is probably an alteration of the dimer resolution regional control, which requires that dif is flanked by suitably oriented (polarized) stretches of DNA. Our model postulates that the prophage inserted near dif in the deleterious orientation disturbs chromosome polarization on the side of the site where it is integrated, because lambda DNA, like the chromosome, is polarized by sequence elements. Candidate sequences are oligomers that display skewed distributions on each oriC-dif chromosome arm and on lambda DNA.

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.

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.

RecD function is required for high-pressure growth of a deep-sea bacterium

A genomic library derived from the deep-sea bacterium Photobacterium profundum SS9 was conjugally delivered into a previously isolated pressure-sensitive SS9 mutant, designated EC1002 (E. Chi and D. H. Bartlett, J. Bacteriol. 175:7533-7540, 1993), and exconjugants were screened for the ability to grow at 280-atm hydrostatic pressure. Several clones were identified that had restored high-pressure growth. The complementing DNA was localized and in all cases found to possess strong homology to recD, a DNA recombination and repair gene. EC1002 was found to be deficient in plasmid stability, a phenotype also seen in Escherichia coli recD mutants. The defect in EC1002 was localized to a point mutation that created a stop codon within the recD gene. Two additional recD mutants were constructed by gene disruption and were both found to possess a pressure-sensitive growth phenotype, although the magnitude of the defect depended on the extent of 3' truncation of the recD coding sequence. Surprisingly, the introduction of the SS9 recD gene into an E. coli recD mutant had two dramatic effects. At high pressure, SS9 recD enabled growth in the E. coli mutant strain under conditions of plasmid antibiotic resistance selection and prevented cell filamentation. Both of these effects were recessive to wild-type E. coli recD. These results suggest that the SS9 recD gene plays an essential role in SS9 growth at high pressure and that it may be possible to identify additional aspects of RecD function through the characterization of this activity.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Timing, self-control and a sense of direction are the secrets of multicopy plasmid stability

Multicopy plasmids of Escherichia coli are distributed randomly at cell division and, as long as copy number remains high, plasmid-free cells arise only rarely. Copy number variation is minimized by plasmid-encoded control circuits, and the limited data available suggest that deviations are corrected efficiently under most circumstances. However, plasmid multimers confuse control circuits, leading to copy number depression. To make matters worse, multimers out-replicate monomers and accumulate clonally within the culture, creating a subpopulation of cells with a significantly increased rate of plasmid loss. Multimers of natural multicopy plasmids, such as ColE1, are resolved to monomers by a site-specific recombination system (Xer-cer) whose activity is limited to intramolecular recombination. Recombination requires the heterodimeric XerCD recombinase plus two accessory proteins (ArgR and PepA), which activate recombination and prevent intermolecular events. Evidence is accumulating that Xer-cer recombination is relatively slow, and there is a risk that cells might divide before multimer resolution is complete. The Rcd transcript encoded within cer may solve this problem by preventing the division of multimer-containing cells. Working in concert, the triumvirate of copy number control, multimer resolution and cell division control achieve an extremely high fidelity of plasmid maintenance.

Complete nucleotide sequence of the Hsd plasmid pECO29 and identification of its functional regions

The complete nucleotide sequence of the Hsd plasmid pECO29 has been determined. The plasmid DNA consists of 3895 base pairs. These include 4 genes and 5 sites. Two genes encoding the proteins (restriction endonuclease and DNA methyltransferase) have been fully characterized. The pECO29 comprises a Co1El-type replication system coding for untranslated genes RNAI and RNAII, the emr recombination site containing palindromic sequences and involved in stable maintenance of the plasmid, two pseudo oriT sites homologous to the oriT site of R64 and F plasmids, as well as the bom locus of a Co1El-like plasmid. There are no genes involved in the mobilization of pECO29 plasmid.

A site-specific recombinase is required for competitive root colonization by Pseudomonas fluorescens WCS365

A colonization mutant of the efficient root-colonizing biocontrol strain Pseudomonas fluorescens WCS365 is described that is impaired in competitive root-tip colonization of gnotobiotically grown potato, radish, wheat, and tomato, indicating a broad host range mutation. The colonization of the mutant is also impaired when studied in potting soil, suggesting that the defective gene also plays a role under more natural conditions. A DNA fragment that is able to complement the mutation for colonization revealed a multicistronic transcription unit composed of at least six ORFs with similarity to lppL, lysA, dapF, orf235/233, xerC/sss, and the largely incomplete orf238. The transposon insertion in PCL1233 appeared to be present in the orf235/233 homologue, designated orf240. Introduction of a mutation in the xerC/sss homologue revealed that the xerC/sss gene homologue rather than orf240 is crucial for colonization. xerC in Escherichia coli and sss in Pseudomonas aeruginosa encode proteins that belong to the lambda integrase family of site-specific recombinases, which play a role in phase variation caused by DNA rearrangements. The function of the xerC/sss homologue in colonization is discussed in terms of genetic rearrangements involved in the generation of different phenotypes, thereby allowing a bacterial population to occupy various habitats. Mutant PCL1233 is assumed to be locked in a phenotype that is not well suited to compete for colonization in the rhizosphere. Thus we show the importance of phase variation in microbe-plant interactions.

The ArcA/ArcB two-component regulatory system of Escherichia coli is essential for Xer site-specific recombination at psi

Two recombinases, XerC and XerD, act at the recombination sites psi and cer in plasmids pSC101 and Co1E1 respectively. Recombination at these sites maintains the plasmids in a monomeric state and helps to promote stable plasmid inheritance. The accessory protein PepA acts at both psi and cer to ensure that only intramolecular recombination takes place. An additional accessory protein, ArgR, is required for recombination at cer but not at psi. Here, we demonstrate that the ArcA/ArcB two-component regulatory system of Escherichia coli, which mediates adaptation to anaerobic growth conditions, is required for efficient recombination in vivo at psi. Phosphorylated ArcA binds to psi in vitro and increases the efficiency of recombination at this site. Binding of ArcA to psi may contribute to the formation of a higher order synaptic complex between a pair of psi sites, thus helping to ensure that recombination is intramolecular.

Nuclease overexpression mutants of Serratia marcescens

A family of mutants overexpressing the Serratia marcescens extracellular nuclease has been known for decades. A number of these alleles are characterized here at the molecular level, and the mutant genes are identified, yielding a likely model for their phenotype. The known mutations exert their effect indirectly on nucA expression by elevating the basal SOS response of the cell. Mutations have been found in xerC and uvrD, both of which result in partial SOS induction. A classic nucsu allele, that of strain W1050, is also likely to be in xerC.

Similarities and differences among 105 members of the Int family of site-specific recombinases

Alignments of 105 site-specific recombinases belonging to the Int family of proteins identified extended areas of similarity and three types of structural differences. In addition to the previously recognized conservation of the tetrad R-H-R-Y, located in boxes I and II, several newly identified sequence patches include charged amino acids that are highly conserved and a specific pattern of buried residues contributing to the overall protein fold. With some notable exceptions, unconserved regions correspond to loops in the crystal structures of the catalytic domains of lambda Int (Int c170) and HP1 Int (HPC) and of the recombinases XerD and Cre. Two structured regions also harbor some pronounced differences. The first comprises beta-sheets 4 and 5, alpha-helix D and the adjacent loop connecting it to alpha-helix E: two Ints of phages infecting thermophilic bacteria are missing this region altogether; the crystal structures of HPC, XerD and Cre reveal a lack of beta-sheets 4 and 5; Cre displays two additional beta-sheets following alpha-helix D; five recombinases carry large insertions. The second involves the catalytic tyrosine and is seen in a comparison of the four crystal structures. The yeast recombinases can theoretically be fitted to the Int fold, but the overall differences, involving changes in spacing as well as in motif structure, are more substantial than seen in most other proteins. The phenotypes of mutations compiled from several proteins are correlated with the available structural information and structure-function relationships are discussed. In addition, a few prokaryotic and eukaryotic enzymes with partial homology with the Int family of recombinases may be distantly related, either through divergent or convergent evolution. These include a restriction enzyme and a subgroup of eukaryotic RNA helicases (D-E-A-D proteins).

Cell division is required for resolution of dimer chromosomes at the dif locus of Escherichia coli

The dif locus is a RecA-independent resolvase site in the terminus region of the chromosome of Escherichia coli. The locus reduces dimer chromosomes, which result from sister chromatid exchange, to monomers. A density label assay demonstrates that recombination occurs at dif, and that it requires XerC and XerD. The frequency of this recombination is approximately 14% per site per generation, which is doubled in polA12 mutants. We have determined that recombination occurs late in the cell cycle, and that resolution is blocked if cell division is inhibited with cephalexin or by a ftsZts mutation. Fluorescence microscopy has demonstrated that abnormal nucleoids are present in cells incubated in cephalexin, and this is increased in polA12 mutants.

Structure-function correlations in the XerD site-specific recombinase revealed by pentapeptide scanning mutagenesis

Xer-mediated site-specific recombination contributes to the stability of circular chromosomes in bacteria by resolving plasmid multimers and chromosome dimers to monomers prior to cell division. Two related site-specific recombinases, XerC and XerD, each catalyse one pair of strand exchange during Xer recombination. In order to relate the recently determined structure of XerD to its function, the XerD protein was subjected to pentapeptide scanning mutagenesis, which leads to a variable five amino acid cassette being introduced randomly into the target protein. This has allowed identification of regions of XerD involved in specific DNA binding, in communicating with the partner recombinase, XerC, and in catalysis and its control. The C-terminal domain of XerD, comprising two-thirds of the protein, contains the catalytic active site and comprises ten alpha helices (alphaE to alphaN) and a beta hairpin. A flexible linker connects this domain to the N-terminal domain that comprises four alpha helices (alphaA to alphaD). Pentapeptide insertions into alphaB, alphaD, alphaG, or alphaJ interfered with DNA binding. Helices alphaG and alphaJ comprise a pseudo helix-turn-helix DNA binding motif that may provide specificity of recombinase binding. An insertion in alphaL, adjacent to an active site arginine residue, led to loss of cooperative interactions between XerC and XerD and abolished recombination activity. Other insertions close to active site residues also abolished recombination activity. Proteins with an insertion in the beta hairpin turn bound DNA, interacted cooperatively with XerC and had a phenotype that is consistent with the protein being defective in XerD catalysis. This beta hairpin appears to be highly conserved in related proteins. Insertions at a number of dispersed locations did not impair XerD catalytic activity or DNA binding, but failed to allow XerC catalysis in vivo, indicating that several sites of interaction between XerD and XerC may be important for activation of XerC catalysis by XerD.

Salmonella typhimurium specifies a circular chromosome dimer resolution system which is homologous to the Xer site-specific recombination system of Escherichia coli

The Xer site-specific recombination system of Escherichia coli resolves both chromosome dimers and multimers of certain plasmids including those of ColE1. In this manner, Xer site-specific recombination contributes to the accurate distribution of circular chromosomes at cell division. Two related site-specific recombinases, XerC and XerD, are required for this process. The xerC and xerD genes of Salmonella typhimurium LT2 were isolated from libraries of LT2 genomic DNA by genetic complementation of E. coli Xer mutants. The putative proteins specified by the S. typhimurium genes can substitute for and are highly homologous to the corresponding proteins in E. coli. The distribution of amino acid dissimilarities differs, however, between pairs of cognate Xer proteins. The immediate genetic contexts of equivalent xer genes, i.e., in operons with genes of apparently unrelated function, are conserved between the two bacteria. This is the first description of the identification of a pair of functional homologues of the xerC and xerD genes of E. coli.

Structural analysis of the 6 kb cryptic plasmid pFAJ2600 from Rhodococcus erythropolis NI86/21 and construction of Escherichia coli-Rhodococcus shuttle vectors

The complete nucleotide sequence of the 5936 bp cryptic plasmid pFAJ2600 from Rhodococcus erythropolis NI86/21 was determined. Based on the characteristics of its putative replication genes, repA and repB, pFAJ2600 was assigned to the family of pAL5000-related small replicons identified in Mycobacterium (pAL5000), Corynebacterium (pXZ10142), Brevibacterium (pRBL1), Bifidobacterium (pMB1) and Neisseria (pJD1). The replication systems of these plasmids show striking similarities to the ones used by the ColE2 family of plasmids from Enterobacteria with respect to both trans-acting factors and ori sequences. Two possible plasmid stabilization systems are encoded on pFAJ2600: a site-specific recombinase (PmrA) related to the Escherichia coli Xer proteins for plasmid multimer resolution and an ATPase (ParA) related to the A-type of proteins in sop/par partitioning systems. The proposed replication termination region of pFAJ2600 has features in common with the Ter loci of Bacillus subtilis. Chimeras composed of a pUC18-Cmr derivative inserted in the parA-repA intergenic region of vector pFAJ2600 produced vectors that could be shuttled between Escherichia coli and several Rhodococcus species (R. erythropolis, R. fascians, R. rhodochrous, R. ruber). The pFAJ2600-based shuttle vector pFAJ2574 was stably maintained in R. erythropolis and R. fascians growing under non-selective conditions.

Direct interaction of aminopeptidase A with recombination site DNA in Xer site-specific recombination

Xer site-specific recombination at ColE1 cer converts plasmid multimers into monomers, thus ensuring the heritable stability of ColE1. Two related recombinase proteins, XerC and XerD, catalyse the strand exchange reaction at a 30 bp recombination core site. In addition, two accessory proteins, PepA and ArgR, are required for recombination at cer. These two accessory proteins are thought to act at 180 bp of accessory sequences adjacent to the cer recombination core to ensure that recombination only occurs between directly repeated sites on the same molecule. Here, we demonstrate that PepA and ArgR interact directly with cer, forming a complex in which the accessory sequences of two cer sites are interwrapped approximately three times in a right-handed fashion. We present a model for this synaptic complex, and propose that strand exchange can only occur after the formation of this complex.

Xer recombination in Escherichia coli. Site-specific DNA topoisomerase activity of the XerC and XerD recombinases

Xer site-specific recombination functions in maintaining circular replicons in the monomeric state in Escherichia coli. Two recombinases of the bacteriophage lambda integrase family, XerC and XerD, are required for recombination at the chromosomal site, dif, and at a range of plasmid-borne sites. Xer recombination core sites contain the 11-base pair binding sites for each recombinase separated by a 6 to 8-base pair central region. We report that both XerC and XerD act as site-specific type I topoisomerases by relaxing supercoiled plasmids containing a dif site. Relaxation by either XerC or XerD occurs in the absence of the partner recombinase and requires only a single recombination core site. XerC or XerD relaxation activities are completely inhibited by the addition of the partner recombinase, providing that the DNA recognition sequence for the inhibiting partner is present.

Effect of DNA topology on Holliday junction resolution by Escherichia coli RuvC and bacteriophage T7 endonuclease I

Holliday junctions are key intermediates in homologous genetic recombination. Their resolution requires specialised nucleases that nick pairs of strands at the junction point, leading to the separation of mature recombinants. Resolution occurs in either of two orientations, according to which DNA strands are cut. We show that DNA topology can determine the efficiency and outcome of a recombination reaction. Using two Holliday junction resolvases, Escherichia coli RuvC protein and T7 endonuclease I, we observed that supercoiled figure-8 DNA molecules containing Holliday junctions were resolved with a specific orientation bias, and that this bias was reversed by the presence of a topological tether (catenation). In contrast, when all topological constraints were removed by restriction digestion, the recombination intermediates were resolved equally in the two orientations. These results show that topological constraints affecting Holliday junction structure influence the orientation of resolution by cellular resolvases.

Recombinase binding specificity at the chromosome dimer resolution site dif of Escherichia coli

Xer site-specific recombination functions in Escherichia coli chromosome segregation and cell division apparently by resolving chromosome dimers, which arise through homologous recombination, to monomers. Xer recombination requires two closely related site-specific recombinases, XerC and XerD, which bind cooperatively to the recombination site dif and catalyse separate pairs of strand exchanges. The dif site is an imperfect palindrome whose left and right halves are bound by XerC and XerD, respectively. By using variant dif sites in which the symmetry between the XerC and XerD binding sites was increased incrementally, the determinants in the dif site that specifically direct binding of XerC and XerD to their cognate sites were elucidated. The primary specificity nucleotides in the XerC and XerD binding sites were identified and their relative contributions to specificity assessed. The biological affects of these mutations on site-specific recombination, chromosome segregation and cell division were examined. The specificity determinants are confined to the non-palindromic outer ends of the binding sites. Replacement of the wild-type dif site with mutated dif sites at the normal location in the replication terminus region of the chromosome revealed that the sequence of the dif site can be altered substantially while retaining apparently normal chromosome segregation activity.

Enteropathogenic Escherichia coli: identification of a gene cluster coding for bundle-forming pilus morphogenesis

Sequence flanking the bfpA locus on the enteroadherent factor plasmid of the enteropathogenic Escherichia coli (EPEC) strain B171-8 (O111:NM) was obtained to identify genes that might be required for bundle-forming pilus (BFP) biosynthesis. Deletion experiments led to the identification of a contiguous cluster of at least 12 open reading frames, including bfpA, that could direct the synthesis of a morphologically normal BFP filament. Within the bfp gene cluster, we identified open reading frames that share homology with other type IV pilus accessory genes and with genes required for transformation competence and protein secretion. Immediately upstream of the bfp gene cluster, we identified a potential replication origin including genes that are predicted to encode proteins homologous with replicase and resolvase. Restriction fragment length polymorphism analysis of DNA from six additional EPEC serotypes showed that the organization of the bfp gene cluster and its juxtaposition with a potential plasmid origin of replication are highly conserved features of the EPEC biotype.

Genetic characterization of site-specific integration functions of phi AAU2 infecting "Arthrobacter aureus" C70

All the essential genetic determinants for site-specific integration of corynephage phi AAU2 are contained within a 1,756-bp DNA fragment, carried on the integrative plasmid p5510, and are shown to be functional in Escherichia coli. One open reading frame, ORF4, encoding a protein of 266 amino acids was shown to represent the phi AAU2 integrase. The nucleotide sequence of the phi AAU2 attachment site, attP, and the attB, attL, and attR sequences in the host "Arthrobacter aureus" C70 were determined. Identical nucleotide sequences were shown to be responsible for the integration of p5510 in the chromosomes of Corynebacterium glutamicum, Brevibacterium divaricatum, and B. lactofermentum, and a sequence almost identical to attB was found to be present in these three strains. In contrast to other phage site-specific recombination systems, a plasmid encompassing only int-attP failed to integrate into the host chromosome. This led to the identification of an 800-bp noncoding region, immediately upstream of int, absolutely required for site-specific integration of p5510.

Determinants of selectivity in Xer site-specific recombination

A remarkable property of some DNA-binding proteins that can interact with and pair distant DNA segments is that they mediate their biological function only when their binding sites are arranged in a specific configuration. Xer site-specific recombination at natural plasmid recombination sites (e.g., cer in ColE1) is preferentially intramolecular, converting dimers to monomers. In contrast, Xer recombination at the Escherichia coli chromosomal site dif can occur intermolecularly and intramolecularly. Recombination at both types of site requires the cooperative interactions of two related recombinases, XerC and XerD, with a 30-bp recombination core site. The dif core site is sufficient for recombination when XerC and XerD are present, whereas recombination at plasmid sites requires approximately 200 bp of adjacent accessory sequences and accessory proteins. These accessory factors ensure that recombination is intramolecular. Here we use a model system to show that selectivity for intramolecular recombination, and the consequent requirement for accessory factors, can arise by increasing the spacing between XerC- and XerD-binding sites from 6 to 8 bp. This reduces the affinity of the recombinases for the core site and changes the geometry of the recombinase/DNA complex. These changes are correlated with altered interactions of the recombinases with the core site and a reduced efficiency of XerC-mediated cleavage. We propose that the accessory sequences and proteins compensate for these changes and provide a nucleoprotein structure of fixed geometry that can only form and function effectively on circular molecules containing directly repeated sites.

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.

Lateral transfer of rfb genes: a mobilizable ColE1-type plasmid carries the rfbO:54 (O:54 antigen biosynthesis) gene cluster from Salmonella enterica serovar Borreze

Plasmid pWQ799 is a 6.9-kb plasmid isolated from Salmonella enterica serovar Borreze. Our previous studies have shown that the plasmid contains a functional biosynthetic gene cluster for the expression of the O:54 lipopolysaccharide O-antigen of this serovar. The minimal replicon functions of pWQ799 have been defined, and a comparison with nucleotide and protein databases revealed this replicon to be virtually identical to ColE1. This is the first report of involvement of ColE1-related plasmids in O-antigen expression. The replicon of pWQ799 is predicted to encode two RNA molecules, typical of other ColE1-type plasmids. RNAII, the putative replication primer from pWQ799, shares regions of homology with RNAII from ColE1. RNA1 is an antisense regulator of DNA replication in ColE1-related plasmids. The coding region for RNAI from pWQ799 shares no homology with any other known RNAI sequence but is predicted to adopt a secondary structure characteristic of RNAI molecules. pWQ799 may therefore represent a new incompatibility group within this family. pWQ799 also possesses cer, rom, and mob determinants, and these differ minimally from those of ColE1. The plasmid is mobilizable in the presence of either the broad-host-range helper plasmid pRK2013 or the IncI1 plasmid R64drd86. Mobilization and transfer of pWQ799 to other organisms provides the first defined mechanism for lateral transfer of O-antigen biosynthesis genes in S. enterica and explains both the distribution of related plasmids and coexpression of the O:54 factor with other O-factors in different Salmonella serovars. The base composition of the pWQ799 replicon sequences gives an average percent G+C value typical of Salmonella spp. In contrast, the percent G+C value is dramatically lower with rfb0:54, consistent with the possibility that the cluster was acquired from an organism with much lower G+C composition.

Detection of XerC and XerD recombinases in gram-negative bacteria of the family Enterobacteriaceae

XerC and XerD are site-specific recombinases of the lambda integrase family which resolve multimeric replicons to monomers by acting at specific sites such as cer, ckr, nmr, parB, and psi, which are found in plasmids, or at the dif site found in the Escherichia coli chromosome. By using Southern hybridizations to cloned E. coli xerC and xerD genes and a cer-nmr plasmid-based resolution assay, the presence of these genes in several species of Enterobacteriaceae is shown.

Molecular characterization of a deletion-prone region of plasmid pAE1 of Alcaligenes eutrophus H1

A 93-kb region (D region) of plasmid pAE1 of Alcaligenes eutrophus H1 has been found to have a high rate of spontaneous deletion. In this study, we constructed a restriction endonuclease map and carried out limited sequencing of an approximately 100-kb region from pAE1 which includes the D region (the deleted region) in order to detect and characterize repetitive sequences. Two types of repetitive sequences, the R1 and R2 sequences, were observed to flank the D region; within the D region are three copies of insertion element ISAE1. The R1 and R2 sequences are arranged in direct and inverted orientations, respectively. Molecular analysis of the end product of the deletion is consistent with the hypothesis that the loss of the D-region DNA is the result of recombination between two copies of the R1 sequence. The R1 sequence encodes a 415-amino-acid protein which exhibits substantial sequence similarity to the lambda integrase family of site-specific recombinases. Its genetic function remains to be determined.

Site-specific recombination between ColE1 cer and NTP16 nmr sites in vivo

The site-specific recombination system used by multicopy plasmids of the ColE1 family uses two identical plasmid-encoded recombination sites and four bacterial proteins to catalyze the recombination reaction. In the case of the Escherichia coli plasmid ColE1, the recombination site, cer, is a 280 bp DNA sequence which is acted on by the products of the argR, pepA, xerC and xerD genes. We have constructed a model system to study this recombination system, using tandemly repeated recombination sites from the plasmids ColE1 and NTP16. These plasmids have allowed us precisely to define the region of strand exchange during site-specific recombination, and to derive a model for cer intramolecular site-specific recombination.

Characterization of pPvu1, the autonomous plasmid from Proteus vulgaris that carries the genes of the PvuII restriction-modification system

Plasmid pPvu1 from Proteus vulgaris carries the genes of the PvuII restriction-modification system [Blumenthal et al., J. Bacteriol. 164 (1985) 501-509]. This report focuses on physical and functional features of the 4.84-kb plasmid, which shows a composite genetic architecture. Plasmid pPvu1 has a replication origin and an incompatibility locus that each function in Escherichia coli, and an apparent cer recombination site. The replication origin includes a possible RNA I gene, and the incompatibility locus closely resembles a rom gene. These loci show substantial sequence similarity to corresponding loci from the E. coli plasmids P15A, ColEI and pSC101, and closely flank the PvuII genes. The close association between a recombinational locus and the PvuII genes has implications for their mobility.

Involvement of ArgR and PepA in the pairing of ColE1 dimer resolution sites

Dimer formation and associated copy number depression is an important cause of multicopy plasmid instability. Natural multicopy plasmids employ site-specific recombination to convert dimers to monomers, thus maximizing the number of independently segregating molecules at cell division. Resolution of dimers of Escherichia coli plasmid ColE1 requires the plasmid cer site and at least four chromosome-encoded proteins: the XerC and XerD recombinases, and accessory factors ArgR and PepA. It has been suggested that ArgR has a role in the initial pairing of recombination sites and we describe here an attempt to detect this process in vivo. Our approach exploits a previous observation that a cer-like site known as the type II hybrid supports inter-molecular recombination and causes extensive multimerization of plasmids. We report that type-II-mediated multimerization can be repressed by a cer site in cis or in trans and propose that this is due to a physical interaction between the sites. If this hypothesis is correct, suppression of multimer formation provides an assay of site pairing. Our results demonstrate that the putative pairing interaction is independent of the topological relationship of the sites and that both PepA and ArgR are involved. Although most recombination-deficient mutant derivatives of ArgR are unable to pair recombination sites, we have found two (ArgR110 and ArgR115) which retain pairing activity. The validity of the pairing hypothesis is discussed in the light of alternative explanations for our data.

The dif resolvase locus of the Escherichia coli chromosome can be replaced by a 33-bp sequence, but function depends on location

The dif locus (deletion-induced filamentation) of Escherichia coli is a resolvase site, located in the terminus region of the chromosome, that reduces chromosome multimers to monomers. In strains in which this site has been deleted, a fraction of the cells is filamentous, has abnormal nucleoid structure, and exhibits elevated levels of the SOS repair system. We have demonstrated that a 33-bp sequence, which is sufficient for RecA-independent recombination and which shows similarity to the cer site of pColE1, suppresses the Dif phenotype when inserted in the terminus region. Flanking sequences were not required, since suppression occurred in strains in which dif as well as 12 kb or 173 kb of DNA had been deleted. However, location was important, and insertions at a site 118 kb away from the normal site did not suppress the Dif phenotype. These sites were otherwise still functional, and they exhibited wild-type levels of RecA-independent recombination with dif-containing plasmids and recombined with other chromosomal dif sites to cause deletions and inversions. It is proposed that the functions expressed by a dif site depend on chromosome location and structure, and analysis of these functions provides a way to examine the structure of the terminus region.

A gene required for nutritional repression of the Bacillus subtilis dipeptide permease operon

An insertion mutation was isolated that resulted in derepressed expression of the Bacillus subtillis dipeptide transport operon (dpp) during the exponential growth phase in rich medium. DNA flanking the site of insertion was found to encode an operon (codVWXY) of four potential open reading frames (ORFs). The deduced product of the codV ORF is similar to members of the lambda Int family; CodW and CodX are homologous to HsIV and HsIU, two putative heat-shock proteins from Escherichia coli, and to LapC and LapA, two gene products of unknown function from Pasteurella haemolytica. CodX also shares homology with a family of ATPases, including ClpX, a regulatory subunit of the E. coli ClpP protease. CodY does not have any homologues in the data-bases. The insertion mutation and all previously isolated spontaneous cod mutations were found to map in codY. In-frame deletion mutations in each of the other cod genes revealed that only codY is required for repression of dpp in nutrient-rich medium. The codY mutations partially relieved amino acid repression of the histidine utilization (hut) operon but had no effect on regulation of certain other early stationary phase-induced genes, such as spoVG and gsiA.

The actinophage RP3 DNA integrates site-specifically into the putative tRNA(Arg)(AGG) gene of Streptomyces rimosus

The temperate actinophage RP3 integrates site-specifically into the chromosome of Streptomyces rimosus R6-554. The phage attachment site attP and the hybrid attachment sites of the integrated prophage--attL and attR--were cloned and sequenced. The 54nt core sequence, common to all RP3 related attachment sites, comprises the 3' terminal end of a putative tRNA(Arg)(AGG) gene. AttB bears the complete tRNA gene which is restored in attL after integration. A 7.5kb HindIII fragment, bearing attP, was used to construct an integrative plasmid to simulate the integration process in vivo and to localize the phage genes necessary for site specific integration. The int and xis genes were sequenced and compared to other recombination genes.

Selection of species-specific DNA probes which detect strain restriction polymorphism in four Bifidobacterium species

Randomly cloned fragments (in a size range 1 to 2.5 kb) of DNA from Bifidobacterium longum ATCC 15707, B. adolescentis CIP 64.59T, B. bifidum CIP 64.65 and B. animalis ATCC 25527 were used as hybridization probes to characterize strains of these species and distinguish them from closely related Bifidobacterium species. The fragments were screened for hybridization with native DNA from 41 different Bifidobacterium strains. For each species, a fragment hybridizing specifically with DNA from strains of the same species was isolated. Each fragment was then hybridized with restriction digests in order to study the genome polymorphism. In some of the tested B. longum strains including strain ATCC 15707, the species-specific fragment L6/45 hybridized with 2 fragments instead of one as expected. Sequence of the fragment revealed the presence of an ORF which had an amino acid sequence similar to the site-specific recombinases of lambda integrase family. Moreover, Southern analysis demonstrated that at least 3 copies of this fragment are present in the chromosome of B. longum ATCC 15707 and in some other B. longum strains. The species-specific fragment A6/17 of B. adolescentis hybridized with the same restriction fragment on the eight strains of this species tested. The B. bifidum-specific fragment hybridized with different DNA restriction fragments according to the strain. The restriction fragment an1 from B. animalis ATCC 25527 hybridized with the same restriction fragment from strain B. animalis ATCC 27536. However, these two strains could be differentiated by another restriction pattern. Thus, hybridization results highlight the genetic polymorphism which exists among Bifidobacterium strains of the same species.

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.

Comparative analysis of the replicon regions of eleven ColE2-related plasmids

The incA gene product of ColE2-P9 and ColE3-CA38 plasmids is an antisense RNA that regulates the production of the plasmid-coded Rep protein essential for replication. The Rep protein specifically binds to the origin and synthesizes a unique primer RNA at the origin. The IncB incompatibility is due to competition for the Rep protein among the origins of the same binding specificity. We localized the regions sufficient for autonomous replication of 15 ColE plasmids related to ColE2-P9 and ColE3-CA38 (ColE2-related plasmids), analyzed their incompatibility properties, and determined the nucleotide sequences of the replicon regions of 9 representative plasmids. The results suggest that all of these plasmids share common mechanisms for initiation of DNA replication and its control. Five IncA specificity types, 4 IncB specificity types, and 9 of the 20 possible combinations of the IncA and IncB types were found. The specificity of interaction of the Rep proteins and the origins might be determined by insertion or deletion of single nucleotides and substitution of several nucleotides at specific sites in the origins and by apparently corresponding insertion or deletion and substitution of amino acid sequences at specific regions in the C-terminal portions of the Rep proteins. For plasmids of four IncA specificity types, the nine-nucleotide sequences at the loop regions of the stem-loop structures of antisense RNAs are identical, suggesting an evolutionary significance of the sequence. The mosaic structures of the replicon regions with homologous and nonhomologous segments suggest that some of them were generated by exchanging functional parts through homologous recombination.

The sss gene product, which affects pyoverdin production in Pseudomonas aeruginosa 7NSK2, is a site-specific recombinase

Pyoverdin production by Pseudomonas aeruginosa strain 7NSK2 was induced by Zn(II) in the presence of iron. A mutant was isolated in which Zn(II) no longer induced pyoverdin production. The sss gene which was inactivated in this mutant was cloned and sequenced. Its protein sequence showed 50% identity to the XerC protein of Escherichia coli, which is a member of the lambda integrase family of site-specific recombinases. An open reading frame was found upstream of sss whose protein sequence showed strong identity to DapF, the diaminopimelate epimerase. In E. coli, xerC is part of a multicistronic unit that also contains dapF. The sss gene of P. aeruginosa could restore site-specific recombination at cer in an E. coli xerC mutant and the E. coli xerC gene could complement a genomic sss mutation in P. aeruginosa.

Comparative studies of genes encoding thermostable L-2-halo acid dehalogenase from Pseudomonas sp. strain YL, other dehalogenases, and two related hypothetical proteins from Escherichia coli

We have determined the nucleotide sequence of the gene encoding thermostable L-2-halo acid dehalogenase (L-DEX) from the 2-chloroacrylate-utilizable bacterium Pseudomonas sp. strain YL. The open reading frame consists of 696 nucleotides corresponding to 232 amino acid residues. The protein molecular weight was estimated to be 26,179, which was in good agreement with the subunit molecular weight of the enzyme. The gene was efficiently expressed in the recombinant Escherichia coli cells: the amount of L-DEX corresponds to about 49% of the total soluble proteins. The predicted amino acid sequence showed a high level of similarity to those of L-DEXs from other bacterial strains and haloacetate dehalogenase H-2 from Moraxella sp. strain B (38 to 57% identity) but a very low level of similarity to those of haloacetate dehalogenase H-1 from Moraxella sp. strain B (10%) and haloalkane dehalogenase from Xanthobacter autotrophicus GJ10 (12%). By searching the protein amino acid sequence database, we found two E. coli hypothetical proteins similar to the Pseudomonas sp. strain YL L-DEX (21 to 22%).

Mutant Escherichia coli arginine repressor proteins that fail to bind L-arginine, yet retain the ability to bind their normal DNA-binding sites

The Escherichia coli arginine repressor (ArgR) is an L-arginine-dependent DNA-binding protein that controls expression of the arginine biosynthetic genes and is required as an accessory protein in Xer site-specific recombination at cer and related recombination sites in plasmids. Site-directed mutagenesis was used to isolate two mutants of E. coli ArgR that were defective in arginine binding. Results from in vivo and in vitro experiments demonstrate that these mutants still act as repressors and bind their specific DNA sequences in an arginine-independent manner. Both mutants support Xer site-specific recombination at cer. One of the mutant proteins was purified and shown to bind to its DNA target sequences in vitro with different affinity and as a different molecular species to wild-type ArgR.

Molecular recognition of DNA structure by proteins that mediate genetic recombination

The latter half of genetic recombination is mediated by proteins that recognise the structure of the four-way DNA junction, and manipulate this structure. In solution the four-way junction adopts a stacked X-structure in the presence of metal ions. The folding is brought about by the pairwise coaxial stacking of helices in a right-handed antiparallel X-shaped structure. The four-way junction is cleaved by structure-selective resolving enzymes that have been isolated from a wide variety of sources, from eubacteria and their phages through to mammals. In addition, another class of proteins accelerate the branch migration of the junction. These proteins all appear to be divisible into a component that recognises structure and another that carries out a reaction on the junction. Thus the ability of structure-selective binding to the four-way DNA junction is a key feature of enzymes important in genetic recombination.

Plasmid pSC101 harbors a recombination site, psi, which is able to resolve plasmid multimers and to substitute for the analogous chromosomal Escherichia coli site dif

Plasmid pSC101 harbors a 28-bp sequence which is homologous to dif, the target site of the XerC/XerD-dependent recombination system in Escherichia coli. Using a technique which allows very sensitive detection of plasmid loss, we show that recombination at this site, termed psi for pSC101 stabilized inheritance, causes a moderate increase in pSC101 stability. The role of the psi sequence in site-specific recombination has been explored in two other contexts. It was cloned in a derivative of plasmid p15A and inserted into the chromosome in place of dif. In the first situation, psi activity requires accessory sequences and results in multimer resolution; in the second situation, it suppresses the effects of the dif deletion and can promote intermolecular exchanges. Thus, psi is a site whose recombinational activity depends on the context, the first in the cer/dif family known to exhibit such flexibility.

Analysis of the multimer resolution system encoded by the parCBA operon of broad-host-range plasmid RP4

The broad-host-range plasmid RP4 encodes a highly efficient partitioning function, termed par, that is capable of stabilizing plasmids in a variety of Gram-negative bacteria independently of the nature of the replicon. The mechanism responsible for plasmid stabilization by this locus appears to be a complex system which includes a site-specific recombination system mediating resolution of plasmid multimers. In this report we present a detailed study on this multimer resolution system (mrs). The parA gene encodes two forms of a resolvase capable of catalysing site-specific recombination between specific sites situated in the promoter region of the parCBA operon. The two ParA proteins that are produced as a result of independent translation initiation at two different start codons within the same open reading frame were overexpressed in Escherichia coli and partially purified. Both forms of the enzyme are able to recombine a supercoiled cointegrate substrate containing two cis-acting elements with the same orientation in an in vitro resolution assay. ParA-mediated, site-specific recombination was found to be independent of any other gene product encoded by the RP4 par locus in vitro and in vivo. The DNA-binding sites for the ParA resolvase were determined using DNase I protection experiments. The results identified three binding sites within the mrs cis-acting region. Both the biochemical properties of the ParA protein and the organization of the cis-acting recombination site revealed a high degree of similarity to the site-specific recombination systems of Tn3-like transposable elements suggesting an evolutionary relationship.