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.     

Escherichia coli XerC recombinase is required for chromosomal segregation at cell division

XerC is a site-specific recombinase of the bacteriophage lambda integrase family that is encoded by xerC at 3700 kbp on the genetic map of Escherichia coli. The protein was originally identified through its role in converting multimers of plasmid ColE1 to monomers; only monomers are stably inherited. Here we demonstrate that XerC also has a role in the segregation of replicated chromosomes at cell division. xerC mutants form filaments with aberrant nucleotides that appear unable to partition correctly. A DNA segment (dif) from the replication terminus region of the E. coli chromosome binds XerC and acts as a substrate for XerC-mediated site-specific recombination when inserted into multicopy plasmids. This dif segment contains a region of 28 bp with sequence similarity to the crossover region of ColE1 cer. The cell division phenotype of xerC mutants is suppressed in strains deficient in homologous recombination, suggesting that the role of XerC/dif in chromosomal metabolism is to convert any chromosomal multimers (arising through homologous recombination) to monomers.     

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 ≈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.     

Site-specific recombination in the replication terminus region of Escherichia coli: functional replacement of dif.

The replication terminus region of the Escherichia coli chromosome encodes a locus, dif, that is required for normal chromosome segregation at cell division. dif is a substrate for site-specific recombination catalysed by the related chromosomally encoded recombinases XerC and XerD. It has been proposed that this recombination converts chromosome multimers formed by homologous recombination back to monomers in order that they can be segregated prior to cell division. Strains mutant in dif, xerC or xerD share a characteristic phenotype, containing a variable fraction of filamentous cells with aberrantly positioned and sized nucleoids. We show that the only DNA sequences required for wild-type dif function in the terminus region of the chromosome are contained within 33 bp known to bind XerC and XerD and that putative active site residues of the Xer recombinases are required for normal chromosome segregation. We have also shown that recombination by the loxP/Cre system of bacteriophage P1 will suppress the phenotype of a dif deletion strain when loxP is inserted in the terminus region. Suppression of the dif deletion phenotype did not occur when either dif/Xer or loxP/Cre recombination acted at other positions in the chromosome close to oriC or within lacZ, indicating that site-specific recombination must occur within the replication terminus region in order to allow normal chromosome segregation.     

dif, a recA-independent recombination site in the terminus region of the chromosome of Escherichia coli.

dif (deletion induced filamentation) is a newly identified locus that lies within the terminus region of the Escherichia coli chromosome. The Dif phenotype was characterized by a subpopulation of filamentous cells with abnormal nucleoids and induction of the SOS repair system. Interactions between dif-carrying plasmids as well as between such plasmids and the bacterial chromosome demonstrated that dif is a cis-acting, recA-independent recombination site. Filamentation continued in dif mutants in which SOS-associated division inhibitors were inoperative, which showed that induction of these inhibitors was not the primary cause of filamentation. Filamentation was not observed in dif recA or dif recBC mutants, which were unable to carry out homologous recombination. The dif site shows homology with the cer site of plasmid ColE1, which resolves plasmid multimers to monomers. It is proposed that dif functions to resolve dimeric chromosomes produced by sister chromatid exchange, and that the Dif phenotype is due to the inability of these mutants to resolve multimers prior to cell division.     

Two DNA translocases synergistically affect chromosome dimer resolution in Bacillus subtilis

In Bacillus subtilis, chromosome dimers that block complete segregation of sister chromosomes arise in about 15% of exponentially growing cells. Two dedicated recombinases, RipX and CodV, catalyze the resolution of dimers by site-specific recombination at the dif site, which is located close to the terminus region on the chromosome. We show that the two DNA translocases in B. subtilis, SftA and SpoIIIE, synergistically affect dimer resolution, presumably by positioning the dif sites in close proximity, before or after completion of cell division, respectively. Furthermore, we observed that both recombinases, RipX and CodV, assemble on the chromosome at the dif site throughout the cell cycle. The preassembly of recombinases probably ensures that dimer resolution can occur rapidly within a short time window around cell division.     

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

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

Evidence from terminal recombination gradients that FtsK uses replichore polarity to control chromosome terminus positioning at division in Escherichia coli

Chromosome dimers in Escherichia coli are resolved at the dif locus by two recombinases, XerC and XerD, and the septum-anchored FtsK protein. Chromosome dimer resolution (CDR) is subject to strong spatiotemporal control: it takes place at the time of cell division, and it requires the dif resolution site to be located at the junction between the two polarized chromosome arms or replichores. Failure of CDR results in trapping of DNA by the septum and RecABCD recombination (terminal recombination). We had proposed that dif sites of a dimer are first moved to the septum by mechanisms based on local polarity and that normally CDR then occurs as the septum closes. To determine whether FtsK plays a role in the mobilization process, as well as in the recombination reaction, we characterized terminal recombination in an ftsK mutant. The frequency of recombination at various points in the terminus region of the chromosome was measured and compared with the recombination frequency on a xerC mutant chromosome with respect to intensity, the region affected, and response to polarity distortion. The use of a prophage excision assay, which allows variation of the site of recombination and interference with local polarity, allowed us to find that cooperating FtsK-dependent and -independent processes localize dif at the septum and that DNA mobilization by FtsK is oriented by the polarity probably due to skewed sequence motifs of the mobilized material.     

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

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

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.     

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.     

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.     

Identification and characterization of the dif Site from Bacillus subtilis

Bacteria with circular chromosomes have evolved systems that ensure multimeric chromosomes, formed by homologous recombination between sister chromosomes during DNA replication, are resolved to monomers prior to cell division. The chromosome dimer resolution process in Escherichia coli is mediated by two tyrosine family site-specific recombinases, XerC and XerD, and requires septal localization of the division protein FtsK. The Xer recombinases act near the terminus of chromosome replication at a site known as dif (Ecdif). In Bacillus subtilis the RipX and CodV site-specific recombinases have been implicated in an analogous reaction. We present here genetic and biochemical evidence that a 28-bp sequence of DNA (Bsdif), lying 6 degrees counterclockwise from the B. subtilis terminus of replication (172 degrees ), is the site at which RipX and CodV catalyze site-specific recombination reactions required for normal chromosome partitioning. Bsdif in vivo recombination did not require the B. subtilis FtsK homologues, SpoIIIE and YtpT. We also show that the presence or absence of the B. subtilis SPbeta-bacteriophage, and in particular its yopP gene product, appears to strongly modulate the extent of the partitioning defects seen in codV strains and, to a lesser extent, those seen in ripX and dif strains.     

Extent of the activity domain and possible roles of FtsK in the Escherichia coli chromosome terminus

Escherichia coli FtsK protein couples cell division and chromosome segregation. It is a component of the septum essential for cell division. It also acts during chromosome dimer resolution by XerCD-specific recombination at the dif site, with two distinct activities: DNA translocation oriented by skewed sequence elements and direct activation of Xer recombination. Dimer resolution requires that the skewed elements polarize in opposite directions 30-50 kb on either side of dif. This constitutes the DIF domain, approximately coincident with the region where replication terminates. The observation that the ftsK1 mutation increases recombination near dif was exploited to determine whether the chromosome region on which FtsK acts is limited to the DIF domain. A monitoring of recombination activity at multiple loci in a 350 kb region to the left of dif revealed (i) zones of differing activities unconnected to dimer resolution and (ii) a constant 10-fold increase of recombination in the 250 kb region adjacent to dif in the ftsK1 mutant. The latter effect allows definition of an FTSK domain whose total size is at least fourfold that of the DIF domain. Additional analyses revealed that FtsK activity responds to polarization in the whole FTSK domain and that displacement of the region where replication terminates preserves differences between recombination zones. Our interpretation is that translocation by FtsK occurs mostly on DNA belonging to a specifically organized domain of the chromosome, when physical links between either dimeric or still intercatenated chromosomes force this DNA to run across the septum at division.     

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.     

Identification and characterization of recD, a gene affecting plasmid maintenance and recombination in Escherichia coli.

We isolated mutations that reduce plasmid stability in dividing cell populations and mapped these mutations to a previously undescribed gene, recD, that affects recombination frequency and consequently the formation of plasmid concatemers. Insertions of the transposable element Tn10 into recD resulted in increased concatemerization and loss of pSC101 and ColE1-like replicons during nonselective growth. Both concatemer formation and plasmid instability in recD mutants require a functional recA gene. Mutations in recD are recessive to recD+ and map to a small region of the Escherichia coli chromosome located between recB and argA. Although the recD locus is distinct from loci encoding the two previously identified subunits of the RecBC enzyme, mutations in recD appear to affect the exonuclease activity of this enzyme.     

Resolution of holliday junctions by RuvABC prevents dimer formation in rep mutants and UV-irradiated cells

In this work, we present evidence that indicates that RuvABC proteins resolve Holliday junctions in a way that prevents dimer formation in vivo. First, although arrested replication forks are rescued by recombinational repair in cells deficient for the Rep helicase, rep mutants do not require the XerCD proteins or the dif site for viability. This shows that the recombination events at arrested replication forks are generally not accompanied by the formation of chromosome dimers. Secondly, resolution of dimers into monomers is essential in the rep ruv strain because of an increased frequency of RecFOR recombination events in the chromosome of this mutant. This suggests that, in the absence of the Ruv proteins, chromosomal recombination leads to frequent dimerization. Thirdly, dif or xerC mutations increase the UV sensitivity of ruv-deficient cells 100-fold, whereas they do not confer UV sensitivity to ruv+ cells. This shows that recombinational repair of UV lesions is not accompanied by dimer formation provided that the RuvABC proteins are active. The requirement for dimer resolution in ruv strains is suppressed by the expression of the RusA Holliday junction resolvase; therefore, RusA also prevents dimer formation. We conclude that the inviability arising from a high frequency of dimer formation in rep or UV-irradiated cells is only observed in the absence of known enzymes that resolve Holliday junctions.     

Differential Management of the Replication Terminus Regions of the Two Vibrio cholerae Chromosomes during Cell Division

The replication terminus region (Ter) of the unique chromosome of most bacteria locates at mid-cell at the time of cell division. In several species, this localization participates in the necessary coordination between chromosome segregation and cell division, notably for the selection of the division site, the licensing of the division machinery assembly and the correct alignment of chromosome dimer resolution sites. The genome of Vibrio cholerae, the agent of the deadly human disease cholera, is divided into two chromosomes, chrI and chrII. Previous fluorescent microscopy observations suggested that although the Ter regions of chrI and chrII replicate at the same time, chrII sister termini separated before cell division whereas chrI sister termini were maintained together at mid-cell, which raised questions on the management of the two chromosomes during cell division. Here, we simultaneously visualized the location of the dimer resolution locus of each of the two chromosomes. Our results confirm the late and early separation of chrI and chrII Ter sisters, respectively. They further suggest that the MatP/matS macrodomain organization system specifically delays chrI Ter sister separation. However, TerI loci remain in the vicinity of the cell centre in the absence of MatP and a genetic assay specifically designed to monitor the relative frequency of sister chromatid contacts during constriction suggest that they keep colliding together until the very end of cell division. In contrast, we found that even though it is not able to impede the separation of chrII Ter sisters before septation, the MatP/matS macrodomain organization system restricts their movement within the cell and permits their frequent interaction during septum constriction.     

Analysis of the terminus region of the Caulobacter crescentus chromosome and identification of the dif site

The terminus region of the Caulobacter crescentus chromosome and the dif chromosome dimer resolution site were characterized. The Caulobacter genome contains skewed sequences that abruptly switch strands at dif and may have roles in chromosome maintenance and segregation. Absence of dif or the XerCD recombinase results in a chromosome segregation defect. The Caulobacter terminus region is unusual, since it contains many essential or highly expressed genes.     

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.