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

DNA Segregation in Enterobacteria

DNA segregation ensures that cell offspring receive at least one copy of each DNA molecule, or replicon, after their replication. This important cellular process includes different phases leading to the physical separation of the replicons and their movement toward the future daughter cells. Here, we review these phases and processes in enterobacteria with emphasis on the molecular mechanisms at play and their controls.

Identification of Evolutionary Trajectories Associated with Antimicrobial Resistance Using Microfluidics

In vitro experimental evolution of pathogens to antibiotics is commonly used for the identification of clinical biomarkers associated with antibiotic resistance. Microdroplet emulsions allow exquisite control of spatial structure, species complexity, and selection microenvironments for such studies. We investigated the use of monodisperse microdroplets in experimental evolution. Using Escherichia coli adaptation to doxycycline, we examined how changes in environmental conditions such as droplet size, starting lambda value, selection strength, and incubation method affected evolutionary outcomes. We also examined the extent to which emulsions could reveal potentially new evolutionary trajectories and dynamics associated with antimicrobial resistance. Interestingly, we identified both expected and unexpected evolutionary trajectories including large-scale chromosomal rearrangements and amplification that were not observed in suspension culture methods. As microdroplet emulsions are well-suited for automation and provide exceptional control of conditions, they can provide a high-throughput approach for biomarker identification as well as preclinical evaluation of lead compounds.

Grand scale genome manipulation via chromosome swapping in Escherichia coli programmed by three one megabase chromosomes

In bacterial synthetic biology, whole genome transplantation has been achieved only in mycoplasmas that contain a small genome and are competent for foreign genome uptake. In this study, we developed Escherichia coli strains programmed by three 1-megabase (Mb) chromosomes by splitting the 3-Mb chromosome of a genome-reduced strain. The first split-chromosome retains the original replication origin (oriC) and partitioning (par) system. The second one has an oriC and the par locus from the F plasmid, while the third one has the ori and par locus of the Vibrio tubiashii secondary chromosome. The tripartite-genome cells maintained the rod-shaped form and grew only twice as slowly as their parent, allowing their further genetic engineering. A proportion of these 1-Mb chromosomes were purified as covalently closed supercoiled molecules with a conventional alkaline lysis method and anion exchange columns. Furthermore, the second and third chromosomes could be individually electroporated into competent cells. In contrast, the first split-chromosome was not able to coexist with another chromosome carrying the same origin region. However, it was exchangeable via conjugation between tripartite-genome strains by using different selection markers. We believe that this E. coli-based technology has the potential to greatly accelerate synthetic biology and synthetic genomics.

XerD-dependent integration of a novel filamentous phage Cf2 into the Xanthomonas citri genome

Filamentous Inoviridae phages integrate into the chromosome of plant pathogens Xanthomonas as prophages, but their diversity and integrative mechanism are not completely understood. A proviral Cf2 sequence of 6454 bases from Xanthomonas citri genome was revived as infectious virions able to lysogenize its host. Unlike other Xanthomonas phages (Cf1c, φLf, Xf109, XacF1), Cf2 phage has RstA/RstB replication protein, and its attP has XerD binding arm and dif central region but lacks XerC binding arm. XerC+/Xf109 and XerD+/Cf2 attPs are in the opposite direction in phage genomes. Moreover, XerCD binding and XerD catalysis for strand exchange are necessary for site-specific integration of XerD+/Cf2 and XerC+/Xf109 attPs. Taken together, these results provide a new insight into the mechanism of XerCD-mediated recombination at XerD + attP.

Characterization of the Chromosome Dimer Resolution Site in Caulobacter crescentus

Chromosome dimers occur in bacterial cells as a result of the recombinational repair of DNA. In most bacteria, chromosome dimers are resolved by XerCD site-specific recombination at the dif (deletion-induced filamentation) site located in the terminus region of the chromosome. Caulobacter crescentus, a Gram-negative oligotrophic bacterium, also possesses Xer recombinases, called CcXerC and CcXerD, which have been shown to interact with the Escherichia coli dif site in vitro Previous studies on Caulobacter have suggested the presence of a dif site (referred to in this paper as dif1_CC ), but no in vitro data have shown any association with this site and the CcXer proteins. Using recursive hidden Markov modeling, another group has proposed a second dif site, which we call dif2_CC , which shows more similarity to the dif consensus sequence. Here, by using a combination of in vitro experiments, we compare the affinities and the cleavage abilities of CcXerCD recombinases for both dif sites. Our results show that dif2_CC displays a higher affinity for CcXerC and CcXerD and is bound cooperatively by these proteins, which is not the case for the original dif1_CC site. Furthermore, dif2_CC nicked substrates are more efficiently cleaved by CcXerCD, and deletion of the site results in about 5 to 10% of cells showing an altered cellular morphology.IMPORTANCE Bacteria utilize site-specific recombination for a variety of purposes, including the control of gene expression, acquisition of genetic elements, and the resolution of dimeric chromosomes. Failure to resolve dimeric chromosomes can lead to cell division defects in a percentage of the cell population. The work presented here shows the existence of a chromosomal resolution system in C. crescentus Defects in this resolution system result in the formation of chains of cells. Further understanding of how these cells remain linked together will help in the understanding of how chromosome segregation and cell division are linked in C. crescentus.

Xer Site-Specific Recombination: Promoting Vertical and Horizontal Transmission of Genetic Information

Two related tyrosine recombinases, XerC and XerD, are encoded in the genome of most bacteria where they serve to resolve dimers of circular chromosomes by the addition of a crossover at a specific site, dif. From a structural and biochemical point of view they belong to the Cre resolvase family of tyrosine recombinases. Correspondingly, they are exploited for the resolution of multimers of numerous plasmids. In addition, they are exploited by mobile DNA elements to integrate into the genome of their host. Exploitation of Xer is likely to be advantageous to mobile elements because the conservation of the Xer recombinases and of the sequence of their chromosomal target should permit a quite easy extension of their host range. However, it requires means to overcome the cellular mechanisms that normally restrict recombination to dif sites harbored by a chromosome dimer and, in the case of integrative mobile elements, to convert dedicated tyrosine resolvases into integrases.

The FtsK family of DNA translocases finds the ends of circles

A global view of bacterial chromosome choreography during the cell cycle is emerging, highlighting as a next challenge the description of the molecular mechanisms and factors involved. Here, we review one such factor, the FtsK family of DNA translocases. FtsK is a powerful and fast translocase that reads chromosome polarity. It couples segregation of the chromosome with cell division and controls the last steps of segregation in time and space. The second model protein of the family SpoIIIE acts in the transfer of the Bacillus subtilis chromosome during sporulation. This review focuses on the molecular mechanisms used by FtsK and SpoIIIE to segregate chromosomes with emphasis on the latest advances and open questions.

[Progress on XerCD/dif site-specific recombination]

In Escherichia coli, 10% to 15% of growing bacteria produce chromosome dimers during DNA replication. These dimers are resolved by XerC and XerD, two chromosome recombinases that target the dif sequence in the replication terminus of chromosome. Phage CTXΦ integrates into vibrio cholerae chromosome in a site-specific manner. However, CTXΦ genome does not encode any recombinase, while recombinase XerC and XerD, which is coded by vibrio cholerae chromosome are required for the integration of CTXΦ into the vibrio cholerae chromosome. The CTXΦ integration site overlaps with the dif site. The wide distribution of XerCD recombinase and dif site among bacteria genome suggests that it may be universal in resolve of chromosome dimers and phage integration. In this article, we reviewed the research progresses on chromosome dimer resolve and phage integration through XerCD/dif site-specific recombination.

Construction of consecutive deletions of the Escherichia coli chromosome

The minimal set of genetic information necessary and sufficient to sustain a functioning cell contains not only trans-acting genes, but also cis-acting chromosomal regions that cannot be complemented by plasmids carrying these regions. In Escherichia coli (E. coli), only one chromosomal region, the origin of replication has been identified to be cis-acting. We constructed a series of mutants with long-range deletions, and the chromosomal regions containing trans-acting essential genes were deleted in the presence of plasmids complementing the deleted genes. The deleted regions cover all regions of the chromosome except for the origin and terminus of replication. The terminus affects cell growth, but is not essential. Our results indicate that the origin of DNA replication is the only vital, unique cis-acting DNA sequence in the E. coli chromosome necessary for survival.

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.

Genetic recombination and the cell cycle: what we have learned from chromosome dimers

Genetic recombination is central to DNA metabolism. It promotes sequence diversity and maintains genome integrity in all organisms. However, it can have perverse effects and profoundly influence the cell cycle. In bacteria harbouring circular chromosomes, recombination frequently has an unwanted outcome, the formation of chromosome dimers. Dimers form by homologous recombination between sister chromosomes and are eventually resolved by the action of two site-specific recombinases, XerC and XerD, at their target site, dif, located in the replication terminus of the chromosome. Studies of the Xer system and of the modalities of dimer formation and resolution have yielded important knowledge on how both homologous and site-specific recombination are controlled and integrated in the cell cycle. Here, we briefly review these advances and highlight the important questions they raise.

Isolation of SOS constitutive mutants of Escherichia coli

The bacterial SOS regulon is strongly induced in response to DNA damage from exogenous agents such as UV radiation and nalidixic acid. However, certain mutants with defects in DNA replication, recombination, or repair exhibit a partially constitutive SOS response. These mutants presumably suffer frequent replication fork failure, or perhaps they have difficulty rescuing forks that failed due to endogenous sources of DNA damage. In an effort to understand more clearly the endogenous sources of DNA damage and the nature of replication fork failure and rescue, we undertook a systematic screen for Escherichia coli mutants that constitutively express the SOS regulon. We identified mutant strains with transposon insertions in 42 genes that caused increased expression from a dinD1::lacZ reporter construct. Most of these also displayed significant increases in basal levels of RecA protein, confirming an effect on the SOS system. As expected, this collection includes genes, such as lexA, dam, rep, xerCD, recG, and polA, which have previously been shown to cause an SOS constitutive phenotype when inactivated. The collection also includes 28 genes or open reading frames that were not previously identified as SOS constitutive, including dcd, ftsE, ftsX, purF, tdcE, and tynA. Further study of these SOS constitutive mutants should be useful in understanding the multiple causes of endogenous DNA damage. This study also provides a quantitative comparison of the extent of SOS expression caused by inactivation of many different genes in a common genetic background.

Bacterial chromosome segregation

Recent studies have made great strides toward our understanding of the mechanisms of microbial chromosome segregation and partitioning. This review first describes the mechanisms that function to segregate newly replicated chromosomes, generating daughter molecules that are viable substrates for partitioning. Then experiments that address the mechanisms of bulk chromosome movement are summarized. Recent evidence indicates that a stationary DNA replication factory may be responsible for supplying the force necessary to move newly duplicated DNA toward the cell poles. Some factors contributing to the directionality of chromosome movement probably include centromere-like-binding proteins, DNA condensation proteins, and DNA translocation proteins.

Filamentous phage integration requires the host recombinases XerC and XerD

Many bacteriophages and animal viruses integrate their genomes into the chromosomal DNA of their hosts as a method of promoting vertical transmission. Phages that integrate in a site-specific fashion encode an integrase enzyme that catalyses recombination between the phage and host genomes. CTX phi is a filamentous bacteriophage that contains the genes encoding cholera toxin, the principal virulence factor of the diarrhoea-causing Gram-negative bacterium Vibrio cholerae. CTX phi integrates into the V. cholerae genome in a site-specific manner; however, the approximately 6.9-kilobase (kb) CTX phi genome does not encode any protein with significant homology to known recombinases. Here we report that XerC and XerD, two chromosome-encoded recombinases that ordinarily function to resolve chromosome dimers at the dif recombination site, are essential for CTX phi integration into the V. cholerae genome. The CTX phi integration site was found to overlap with the dif site of the larger of the two V. cholerae chromosomes. Examination of sequences of the integration sites of other filamentous phages indicates that the XerCD recombinases also mediate the integration of these phage genomes at dif-like sites in various bacterial species.

oriC region and replication termination site, dif, of the Xanthomonas campestris pv. campestris 17 chromosome

A 13-kb DNA fragment containing oriC and the flanking genes thdF, orf900, yidC, rnpA, rpmH, oriC, dnaA, dnaN, recF, and gyrB was cloned from the gram-negative plant pathogen Xanthomonas campestris pv. campestris 17. These genes are conserved in order with other eubacterial oriC genes and code for proteins that share high degrees of identity with their homologues, except for orf900, which has a homologue only in Xylella fastidiosa. The dnaA/dnaN intergenic region (273 bp) identified to be the minimal oriC region responsible for autonomous replication has 10 pure AT clusters of four to seven bases and only three consensus DnaA boxes. These findings are in disagreement with the notion that typical oriCs contain four or more DnaA boxes located upstream of the dnaA gene. The X. campestris pv. campestris 17 attB site required for site-specific integration of cloned fragments from filamentous phage phiLf replicative form DNA was identified to be a dif site on the basis of similarities in nucleotide sequence and function with the Escherichia coli dif site required for chromosome dimer resolution and whose deletion causes filamentation of the cells. The oriC and dif sites were located at 12:00 and 6:00, respectively, on the circular X. campestris pv. campestris 17 chromosome map, similar to the locations found for E. coli sites. Computer searches revealed the presence of both the dif site and XerC/XerD recombinase homologues in 16 of the 42 fully sequenced eubacterial genomes, but eight of the dif sites are located far away from the 6:00 point instead of being placed opposite the cognate oriC. The differences in the relative position suggest that mechanisms different from that of E. coli may participate in the control of chromosome replication.

Osmoregulation of dimer resolution at the plasmid pJHCMW1 mwr locus by Escherichia coli XerCD recombination

Xer-mediated dimer resolution at the mwr site of plasmid pJHCMW1 is osmoregulated in Escherichia coli. Whereas under low-salt conditions, the site-specific recombination reaction is efficient, under high-salt conditions, it proceeds inefficiently. Regulation of dimer resolution is independent of H-NS and is mediated by changes in osmolarity rather than ionic effects. The low level of recombination at high salt concentrations can be overcome by high levels of PepA or by mutating the ARG box to a sequence closer to the E. coli ARG box consensus. The central region of the mwr core recombination site plays a role in regulation of site-specific recombination by the osmotic pressure of the medium.

Interplay between recombination, cell division and chromosome structure during chromosome dimer resolution in Escherichia coli

Chromosome dimers form in bacteria by recombination between circular chromosomes. Resolution of dimers is a highly integrated process involving recombination between dif sites catalysed by the XerCD recombinase, cell division and the integrity of the division septum-associated FtsK protein and the presence of dif inside a restricted region of the chromosome terminus, the dif activity zone (DAZ). We analyse here how these phenomena collaborate. We show that (i) both inter- and intrachromosomal recombination between dif sites are activated by their presence inside the DAZ; (ii) the DAZ-specific activation only occurs in conditions supporting the formation of chromosome dimers; (iii) overexpression of FtsK leads to a general increase in dif recombination irrespective of dif location; (iv) overexpression of FtsK does not improve the ability of dif sites inserted outside the DAZ to resolve chromosome dimers. Our results suggest that the formation of an active XerCD-FtsK-dif complex is restricted to when a dimer is present, the features of chromosome organization that determine the DAZ playing a central role in this control.

Polarization of the Escherichia coli chromosome. A view from the terminus

The E. coli chromosome replication arms are polarized by motifs such as RRNAGGGS oligomers, found preferentially on leading strands. Their skew increases regularly from the origin to dif (the site in the center of the terminus where chromosome dimer resolution occurs), to reach a value of 90% near dif. Convergent information indicates that polarization in opposite directions from the dif region controls tightly the activity of dif, probably by orienting mobilization of the terminus at cell division. Another example of polarization is the presence, in the region peripheral to the terminus, of small non-divisible zones whose inversion interferes with spatial separation of sister nucleoids. The two phenomena may contribute to the organization of the Ter macrodomain.

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.

All major regions of FtsK are required for resolution of chromosome dimers

Resolution of chromosome dimers, by site-specific recombination between dif sites, is carried out in Escherichia coli by XerCD recombinase in association with the FtsK protein. We show here that a variety of altered FtsK polypeptides, consisting of the N-terminal (cell division) domain alone or with deletions in the proline-glutamine-rich part of the protein, or polypeptides consisting of the C-terminal domain alone are all unable to carry out dif recombination. Alteration of the putative nucleotide-binding site also abolishes the ability of FtsK to carry out recombination between dif sites.

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.

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.

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.

Recombinational DNA repair in bacteria and the RecA protein

In bacteria, the major function of homologous genetic recombination is recombinational DNA repair. This is not a process reserved only for rare double-strand breaks caused by ionizing radiation, nor is it limited to situations in which the SOS response has been induced. Recombinational DNA repair in bacteria is closely tied to the cellular replication systems, and it functions to repair damage at stalled replication forks, Studies with a variety of rec mutants, carried out under normal aerobic growth conditions, consistently suggest that at least 10-30% of all replication forks originating at the bacterial origin of replication are halted by DNA damage and must undergo recombinational DNA repair. The actual frequency may be much higher. Recombinational DNA repair is both the most complex and the least understood of bacterial DNA repair processes. When replication forks encounter a DNA lesion or strand break, repair is mediated by an adaptable set of pathways encompassing most of the enzymes involved in DNA metabolism. There are five separate enzymatic processes involved in these repair events: (1) The replication fork assembled at OriC stalls and/or collapses when encountering DNA damage. (2) Recombination enzymes provide a complementary strand for a lesion isolated in a single-strand gap, or reconstruct a branched DNA at the site of a double-strand break. (3) The phi X174-type primosome (or repair primosome) functions in the origin-independent reassembly of the replication fork. (4) The XerCD site-specific recombination system resolves the dimeric chromosomes that are the inevitable by-product of frequent recombination associated with recombinational DNA repair. (5) DNA excision repair and other repair systems eliminate lesions left behind in double-stranded DNA. The RecA protein plays a central role in the recombination phase of the process. Among its many activities, RecA protein is a motor protein, coupling the hydrolysis of ATP to the movement of DNA branches.

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.

Site-specific recombination at dif by Haemophilus influenzae XerC

Xer site-specific recombination at the Escherichia coli chromosomal site dif converts chromosomal dimers to monomers, thereby allowing chromosome segregation during cell division. dif is located in the replication terminus region and binds the E. coli site-specific recombinases EcoXerC and EcoXerD. The Haemophilus influenzae Xer homologues, HinXerC and HinXerD, bind E. coli dif and exchange strands of dif Holliday junctions in vitro. Supercoiled dif sites are not recombined by EcoXerC and EcoXerD in vitro, possibly as a consequence of a regulatory process, which ensures that in vivo recombination at dif is confined to cells that can initiate cell division and contain dimeric chromosomes. In contrast, the combined action of HinXerC and EcoXerD supports in vitro recombination between supercoiled dif sites, thereby overcoming the barrier to dif recombination exhibited by EcoXerC and EcoXerD. The recombination products are catenated and knotted molecules, consistent with recombination occurring with synaptic complexes that have entrapped variable numbers of negative supercoils. Use of catalytically inactive recombinases provides support for a recombination pathway in which HinXerC-mediated strand exchange between directly repeated duplex dif sites generates a Holliday junction intermediate that is resolved by EcoXerD to catenated products. These can undergo a second recombination reaction to generate odd-noded knots.

Inversion/dimerization of plasmids mediated by inverted repeats

In contrast with earlier studies on the lambda and Escherichia coli genomes, recombination between inverted repeats on plasmids is highly efficient and shown to be recA-independent. In addition, the recombination product is exclusively a head-to-head inverted dimer. Here, we show that this recombination/rearrangement event can occur on different plasmid replicons and is not specific to the particular sequence within the inverted repeats. Transcription readthrough into the inverted repeats has little effect on this event. Genetic analysis has also indicated that most known recombination enzymes are not involved in this process. Specifically, single or double mutants defective in Holliday junction resolution systems (RuvABC and/or RecG/RusA) do not abolish this recombination/rearrangement event. This result does not support the previous models (i.e. the reciprocal-strand-switching and the cruciform-dumbbell models) in which intermediates containing Holliday junctions are proposed. Further analysis has demonstrated that the recombination/rearrangement frequency is dramatically (over 1000-fold) reduced if mismatches (2.8 %) are present within the inverted repeats. Mutations in dam, mutH and mutL genes partially or completely restored the recombination/rearrangement frequency to the level exhibited by the perfect inverted repeats, suggesting the formation of heteroduplexes during recombination/rearrangement. Sequencing analysis of the recombination/rearrangement products have indicated that the majority of the products do not involve crossing-over. We discuss a possible mechanism in which blockage of the lagging strand polymerase by a hairpin triggers recombination/rearrangement mediated by inverted repeats.

The cytoplasmic domain of FtsK protein is required for resolution of chromosome dimers

Chromosome dimers, formed by homologous recombination between sister chromosomes, normally require cell division to be resolved into monomers by site-specific recombination at the dif locus of Escherichia coli. We report here that it is not in fact cell division per se that is required for dimer resolution but the action of the cytoplasmic domain of FtsK, which is a bifunctional protein required both for cell division and for chromosome partition.

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.

A broadening view of recombinational DNA repair in bacteria

Recombinational DNA repair is both the most complex and least understood of DNA repair pathways. In bacterial cells grown under normal laboratory conditions (without a DNA damaging treatment other than an aerobic environment), a substantial number (10-50%) of the replication forks originating at oriC encounter a DNA lesion or strand break. When this occurs, repair is mediated by an elaborate set of recombinational DNA repair pathways which encompass most of the enzymes involved in DNA metabolism. Four steps are discussed: (i) The replication fork stalls and/or collapses. (ii) Recombination enzymes are recruited to the location of the lesion, and function with nearly perfect efficiency and fidelity. (iii) Additional enzymatic systems, including the phiX174-type primosome (or repair primosome), then function in the origin-independent reassembly of the replication fork. (iv) Frequent recombination associated with recombinational DNA repair leads to the formation of dimeric chromosomes, which are monomerized by the XerCD site-specific recombination system.

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.

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.

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.

Use of a transposon (Tndif) to obtain suppressing and nonsuppressing insertions of the dif resolvase site of Escherichia coli

The dif locus is a RecA-independent recombination site, located in the terminus region of the chromosome of Escherichia coli. This site functions to reduce circular dimer chromosomes to monomers before cell division. Strains lacking this site exhibit the Dif phenotype, in which a fraction of the cells form extended filaments with abnormal nucleoids, and the SOS system is induced. We have used a transposon (Tndif), as well as linear transformation, to position dif in 19 locations around the chromosome. All of the suppressing insertions that we obtained were within 10 kb of the normal site, even in strains in which the normal symmetry, between the origin of replication and dif had been altered by 200 kb. We also observed that the nonsuppressing insertions in the terminus region became suppressing if a deletion occurred that extended from the ectopic site up to or past the normal location of dif. We propose that dif is normally located at the center of converging polarities in the terminus region and that deletions that restore suppression do so by placing ectopic sites once again at the center of this polarity. Similar results and conclusions are described in this issue.

Restriction of the activity of the recombination site dif to a small zone of the Escherichia coli chromosome

The recombination site dif is the target on the Escherichia coli chromosome of the site-specific recombinases XerC and XerD. The dif/XerC-D system plays a role during the cell cycle, probably by favoring sister chromosome monomerization or separation. A phenomenon of regional control over dif activity, also analyzed in this issue, is demonstrated here by translocation of dif to a series of loci close to the normal locus. We found that the site is physiologically active only within a narrow zone around its natural position. Competence for dif activity does not depend on the sequence of the normal dif activity zone (DAZ), because delta(dif) deletions larger than the DAZ result in Dif+ bacteria when dif is reinserted at the junction point. Although dif maps where replication normally terminates, termination of replication is not the elicitor. A strain with a large inversion that places dif and its surrounding region close to oriC remains Dif+, even when a Tus- mutation allows replication to terminate far away from it. Preliminary data suggest the possibility that specialized sequences separate the competent zone from the rest of the chromosome. We suspect that these sequences are members of a set of sequences involved in a polarized process of postreplicative reconstruction of the nucleoid structure. We propose that this reconstruction forces catenation links between sister chromosomes to accumulate within the DAZ, where they eventually favor recombination at dif.