Partitioning of the F plasmid: Overproduction of an essential protein for partition inhibits plasmid maintenance

Summary Multicopy plasmids carrying the sopB gene of the F plasmid inhibit stable inheritance of a coexisting mini-F plasmid. This incompatibility, termed IncG, is found to be caused by excess amounts of the SopB protein, which is essential for accuratepartitioning of plasmid DNA molecules into daughter cells. A sopB-carrying multicopy plasmid that shows the IncG⁺ phenotype was mutagenized in vitro and IncG negative mutant plasmids were isolated. Among these amber and missense mutants of sopB, mutants with a low plasmid copy number and a mutant in the Shine-Dalgarno sequence for translation of the SopB protein were obtained. These results demonstrate that the IncG phenotype is caused by the SopB protein, and that the incompatibility is expressed only when the protein is overproduced. This suggests that the protein must be kept at appropriate concentrations to ensure stable maintenance of the plasmid.     

Chromosomal genes essential for stable maintenance of the mini-F plasmid in Escherichia coli

We have isolated mutants of Escherichia coli which do not support stable maintenance of mini-F plasmids (delta ccd rep+ sop+). These host mutations, named hop, were classified into five linkage groups on the E. coli chromosome. Genetic analyses of these hop mutations by Hfr mating and P1 transduction showed their loci on the E. coli genetic map to be as follows: hopA in the gyrB-tnaA region, hopB in the bglB-oriC region, hopD between 8 and 15 min, and hopE in the argA-thyA region. Kinetics of stability of the sop+ and delta sop mini-F plasmids in these hop mutants suggest that the hopA mutants are defective in partitioning of mini-F rather than in plasmid replication. The hopB, hopC, and hopD mutants were partially defective in replication of mini-F. The physical structure of the plasmid DNA was normal in hopA, B, C, and D mutants. Large amounts of linear multimers of plasmid DNA accumulated in mutants of the fifth linkage group (hopE). None of the hop mutations in any linkage group affected the normal growth of cells.     

Regulation of DNA replication by iterons: an interaction between the ori2 and incC regions mediated by RepE-bound iterons inhibits DNA replication of mini-F plasmid in Escherichia coli.

In bacteria, plasmids and some DNA viruses, DNA replication is initiated and regulated by binding of initiator proteins to repetitive sequences. To understand the control mechanism we used the plasmid mini-F, whose copy number is stringently maintained in Escherichia coli, mainly by its initiator protein RepE and the incC region. The monomers of RepE protein bound to incC iterons, which exert incompatibility in trans and control the copy number of mini-F plasmid in cis. Many incompatibility defective mutants carrying mutations in their incC iterons had lost the affinity to bind to RepE, while one mutant retained high level binding affinity. The mutated incC mini-F plasmids lost the function to control the copy number. The copy number of the wild-type mini-F plasmid did not increase in the presence of excess RepE. These results suggested that the control of replication by incC iterons does not rely on their capacity to titrate RepE protein. Using a ligation assay, we found that RepE proteins mediated a cross-link structure between ori2 and incC, for which the dimerization domain of RepE and the structure of incC seem to be important. The structure probably causes inhibition of extra rounds of DNA replication initiation on mini-F plasmids, thereby keeping mini-F plasmid at a low copy number.     

Regions on the F plasmid which affect plasmid maintenance and the ability to segregate into Escherichia coli minicells

Certain derivative mini-F plasmids were found to segregate into Escherichia coli minicells, in contrast to the intact mini-F plasmid which does not. Segregation was not related to the presence or absence of the normal origin of vegetative replication, but appeared to be affected by regions of F which encode replication, incompatibility, copy number control, and partitioning functions. Segregation of mini-F plasmids into minicells was not random; the plasmid concentration in minicells did not correlate with the plasmid concentration in cells. Genes, or gene products, of F from the region spanning the sequences 44.1–49.3F appeared to affect the ability of mini-F plasmids to segregate into minicells. Segregation of mini-F plasmids into minicells was not directly related to stable plasmid inheritance. These results argue for the sequestration of mini-F plasmids in host cells.     

F plasmid ccd mechanism in Escherichia coli.

The ccd mechanism specified by the ccdA and ccdB genes of the mini-F plasmid determines fate of plasmid-free segregants in Escherichia coli (Jaffé et al., J. Bacteriol. 163:841-849, 1985). The killing function in plasmid-free segregants by the ccd mechanism did not affect cell growth of coexisting cells in the same culture. Elongated cells and anucleate cells caused by the ccd mechanism were clearly detected by flow cytometry in cultures of bacterial strains harboring Ccd+ Sop- mini-F plasmids defective in partitioning. This indicates that the defect in correct partitioning of plasmid DNA molecules into daughter cells also induces the ccd mechanism to operate.     

The iteron regions necessary for the RepE-iteron interaction in vivo in mini-F plasmids of Escherichia coli

We have determined the nucleotide positions of an incC iteron essential for RepE binding by analyzing mutated incC iterons defective in exerting incompatibility towards mini-F plasmids. The mutations affecting this incompatibility occurred mostly at two positions within the incC iteron, i.e. an iteron conserved position and a mini-F specific position. Most of the iterons with a base-change at either of these two positions had lost the binding affinity for RepE. This agrees with the crystallographic structure of the RepE-iteron complex which showed that the N and C terminal domains of RepE interact with the two major grooves on one face of the iteron DNA. These grooves contain the iteron conserved and mini-F specific positions necessary for RepE binding. Thus the binding mode may be common to in the case of mini-F like plasmids.     

Genetic analysis of the inter-relationship between plasmid replication and incompatibility

Summary The relationship between replication control and plasmid incompatibility has been investigated using a composite replicon, pPM1, which consists of the pSC101 plasmid ligated to another small multicopy plasmid, RSF1050. Since pPM1 can utilise the replication system of either of the two functionally distinct components, propagation of the composite plasmid can occur in the presence of a mutation of one of its moieties. Such mutants are detected by their inability to rescue the composite plasmid under conditions not permissive for replication of the other moiety. Mutations in incompatibility functions can be detected by the failure of the composite replicon to exclude co-existing plasmids carrying a replication system identical to the one on pPM1.The inability of the composite plasmid to replicate at 42° in a host synthesizing temperature-sensitive DNA polymerase I, which is required by the RSF1050 replication system, was used to isolate pPM1 mutants defective in replication of the pSC101 component. Mutants defective in the incompatibility functions of pSC101 were obtained by selecting derivatives that allow the stable coexistence of a second pSC101 replicon in the same cell. Analysis of these two classes of mutants indicates that plasmids selected for defective pSC101 replication ability nevertheless retain pSC101 incompatibility. In contrast, plasmid mutants that have lost incompatibility functions were found always to be defective in replication ability.     

Probing plasmid partition with centromere-based incompatibility

Low-copy number plasmids of bacteria rely on specific centromeres for regular partition into daughter cells. When also present on a second plasmid, the centromere can render the two plasmids incompatible, disrupting partition and causing plasmid loss. We have investigated the basis of incompatibility exerted by the F plasmid centromere, sopC, to probe the mechanism of partition. Measurements of the effects of sopC at various gene dosages on destabilization of mini-F, on repression of the sopAB operon and on occupancy of mini-F DNA by the centromere-binding protein, SopB, revealed that among mechanisms previously proposed, no single one fully explained incompatibility. sopC on multicopy plasmids depleted SopB by titration and by contributing to repression. The resulting SopB deficit is proposed to delay partition complex formation and facilitate pairing between mini-F and the centromere vector, thereby increasing randomization of segregation. Unexpectedly, sopC on mini-P1 exerted strong incompatibility if the P1 parABS locus was absent. A mutation preventing the P1 replication initiation protein from pairing (handcuffing) reduced this strong incompatibility to the level expected for random segregation. The results indicate the importance of kinetic considerations and suggest that mini-F handcuffing promotes pairing of SopB-sopC complexes that can subsequently segregate as intact aggregates.     

Evidence that IncG (IncP-6) and IncU plasmids form a single incompatibility group

The Escherichia coli IncG and IncU plasmid incompatibility groups were assigned in 1980 and 1981, respectively. Complete plasmid sequences have recently been published for both these groups, and revealed that their replication proteins are related. We show that when cloned at high-copy-number, putative iterons from the previously identified IncG replicon cause strong incompatibility with IncU plasmids. Incompatibility, albeit weaker, was also demonstrated between the two replicons at their normal low-copy-number. This suggests that a single incompatibility group exists. The only known IncG plasmid, Rms149, can replicate in Pseudomonas species where it is designated IncP-6. We recommend that the combined group be known as IncU (IncP-6 in Pseudomonas spp.).     

Control of F plasmid replication by a host gene: evidence for interaction of the mafA gene product of Escherichia coli with the mini-F incC region.

Replication of F (including mini-F) and some related plasmids is known to be specifically inhibited in mafA mutants of Escherichia coli K-12. We have now isolated and characterized mini-F mutants that can overcome the replication inhibition. Such plasmids, designated pom (permissive on maf), were obtained spontaneously or after mutagenesis with hydroxylamine or by transposon (Tn3) insertion. In addition to their ability to replicate in mafA mutant bacteria, the pom mutant plasmids exhibit an increased copy number and resistance to "curing" by acridine dye in the mafA+ host. In agreement with these results, Tn3-induced pom mutants were found to carry Tn3 inserted at the incC region of mini-F DNA, known to be involved in incompatibility, control of copy number, and sensitivity to acridine dye. Furthermore, three of the seven mini-F plasmids tested that carry Tn3 within the tandem repeat sequences of the incC region (previously isolated by other workers) exhibit all the phenotypes of pom plasmids, the ability to replicate in the mafA strain, and high copy number and acridine resistance in the mafA+ strain. The rest of the plasmids that contain Tn3 just outside the tandem repeats remain wild type in all these properties. These results strongly suggest that the putative mafA gene product of host bacteria controls mini-F replication through interaction with the incC region.     

An amber replication mutant of F plasmid mapped in the minimal replication region

We have constructed a mini-F derivative (pKP1013) consisting of a 5.4 kilobase pairs (kb) segment (44.0 to 49.4 kb) of mini-F and fragments carrying the chloramphenicol and spectinomycin resistance genes that originated from the R plasmid NR1. The plasmid pKP1013 replicates autonomously in a manner indistinguishable from that of the parental mini-F. An amber mutant defective in replication has been isolated from pKP1013 by localized mutagenesis using N-methyl-N'-nitro-N-nitrosoguanidine. The virtual absence of incorporation of [3H]-thymidine into the plasmid DNA as well as the kinetics of appearance of plasmid-free segregants suggest that plasmid DNA synthesis is primarily affected under nonpermissive conditions. The amber mutation has been mapped within the 530 base pairs (bp) region that extends from 45.25 (XmaI) to 45.78 Kb (PstI) by extensive analysis of in vitro recombinants constructed from rep+ and rep- plasmids.     

Linear multimer formation of plasmid DNA in Escherichia coli hopE (recD) mutants

Summary The hopE mutants of Escherichia coli, which cannot stably maintain a mini-F plasmid during cell division, have mutations in the recD gene coding for subunit D of the RecBCD enzyme (exonuclease V). A large amount of linear multimer DNA of mini-F and pBR322 plasmids accumulates in these hopE mutants. The linear multimers of plasmid DNA in the hopE (recD) mutants accumulate in sbc ⁺ genetic backgrounds and this depends on the recA ⁺ gene function. Linear plasmid multimers also accumulated in a recBC xthA triple mutant, but not an isogenic xthA mutant or an isogenic recBC mutant. The recBC xthA mutant is defective in the conjugative type of recombination. Linear plasmid multimers were not detected in the recBC strain. We propose models to account for linear multimer formation of plasmids in various mutants.     

Studies on plasmid replication. III. Isolation and characterization of replication-defective mutants

Some 85 Staphylococcus aureus mutants phenotypically thermosensitive for penicillinase plasmid segregation (Seg-) have been isolated and characterized. Some of the mutations were plasmid-linked and those studied in detail were found to be defective in plasmid replication, most problbly at the initiation stage. Analysis of the segregation behavior of these mutants suggested a figure of 2.7 for the average number of plasmid copies per cell in a random culture. Other mutations were host chromosome-linked and these could be divided into at least three classes on the basis of their ability to maintain plasmids of the two different incompatibility sets: some were defective for type I plasmids, some for type II, and some for both types. One host mutant, defective in segregation of type I but not type II plasmids, was defective in polymerization of both.     

Defective plasmid partition in ftsH mutants of Escherichia coli

FtsH is an ATP-dependent protease that is essential for cell viability in Escherichia coli. The essential function of FtsH is to maintain the proper balance of biosynthesis of major membrane components, lipopolysaccharide and phospholipids. F plasmid uses a partitioning system and is localized at specific cell positions, which may be related to the cell envelope, to ensure accurate partitioning. We have examined the effects of ftsH mutations on the maintenance of a mini-F plasmid, and have found that temperature-sensitive ftsH mutants are defective in mini-F plasmid partition, but not replication, at permissive temperature for cell growth. A significant fraction of replicated plasmid molecules tend to localize close together on one side of the cell, which may result in failure to pass the plasmid to one of the two daughter cells upon cell division. By contrast, an ftsH null mutant carrying the suppressor mutation sfhC did not affect partitioning of the plasmid. The sfhC mutation also suppressed defective maintenance in temperature-sensitive ftsH mutants. Using this new phenotype caused by ftsH mutations, we also isolated a new temperature-sensitive ftsH mutant. Mutations in ftsH cause an increase in the lipopolysaccharide/ phospholipid ratio due to stabilization of the lpxC gene product, which is involved in lipopolysaccharide synthesis and is a substrate for proteolysis by the FtsH protease. It is likely that altered membrane structure affects the localization or activity of a putative plasmid partitioning apparatus located at positions equivalent to 1/4 and 3/4 of the cell length.     

Different phenotypes of Walker-like A box mutants of ParA homolog IncC of broad-host-range IncP plasmids

The promiscuous IncPα plasmids RK2 and R995 encode a broad-host-range partition system, whose essential components include the incC and korB genes and a DNA site (O(B)) to which the korB product binds. IncC2, the smaller of the two incC products, is sufficient for stabilization of R995ΔincC. It is a member of the type Ia ParA family of partition ATPases. To better understand the role of ATP in partition, we constructed three alanine-substitution mutants of IncC2. Each mutation changed a different residue of the Walker-like ATP-binding and hydrolysis motif, including a lysine (K10) conserved solely among members of the ParA and MinD families. All three IncC2 mutants were defective in plasmid partition, but they differed from one another in other respects. The IncC2 T16A mutant, predicted to be defective in Mg2? coordination, was severely impaired in all activities tested. IncC2 K10A, predicted to be defective in ATP hydrolysis, mediated enhanced incompatibility with R995 derivatives. IncC2 K15A, predicted to be defective in ATP binding, exhibited two distinct incompatibility properties depending on the genotype of the target plasmid. When in trans to plasmids carrying a complementable incC deletion, IncC2 K15A caused dramatic plasmid loss, even at low levels of expression. In trans to wild-type R995 or to R995ΔincC carrying a functional P1 partition system, IncC2 K15A-mediated incompatibility was significantly less than that caused by wild-type IncC2. All three Walker-like A box mutants were also defective for the host toxicity that normally results from co-overexpression of incC and korB. The phenotypes of the mutants support a model in which nucleotide hydrolysis is required for separation of paired plasmid complexes and possible interaction with a host factor.     

Replication of mini-F plasmid in vitro promoted by purified E protein

Summary An in vitro system for replication of mini-F plasmid DNA was constructed. This system consists of an ammonium sulfate fraction II (Fuller et al. 1981) from Escherichia coli extract, exogeneously added purified E protein encoded by mini-F plasmid, and mini-F DNA in a closed circular form. Experiments with this system showed that the 217 bp DNA region which contains the A+T rich cluster and the four 19 bp direct repeats responsible for incB incompatibility is essential for mini-F DNA replication.     

A class of gyrB mutants, substantially unaffected in DNA topology, suppresses the Escherichia coli K12 ftsZ84 mutation.

Previous work in our laboratory suggested that DNA topology could be implicated in the regulation of the division gene ftsZ. To settle this question, we have selected and characterized mutants in the gyrB gene able to phenotypically suppress the defects of the ftsZ84 mutation. No strict correlation was found between the degree of plasmid DNA relaxation and the level of suppression of the thermosensitivity of the ftsZ84 strain. Interestingly, the class of mutants that shows maximal suppression is substantially unaffected in DNA topology. In addition, the amount of ftsZ-specific mRNA in this class of mutants is comparable to that present in the ftsZ84 strain. These results hint that the ability of these gyrB mutants to correct the effects of the ftsZ84 mutation is largely unrelated to the function of the GyrB (as a part of DNA gyrase) in the control of DNA superhelicity and suggest hitherto unsuspected interaction between the ftsZ and gyrB gene products.     

IncD, a genetic locus in F responsible for incompatibility with several plasmids of the IncFI group

Summary Cloning of mini-F DNA segments has led to the identification and mapping of a locus, incD, involved in incompatibility reactions with many IncFI plasmids. The cloned incD locus expressed incompatibility with F, R386, and six other IncFI plasmids but not with ColV3-K30 or pHH507 which lack sequence homology with the incD region. A sequence of 360 bp (48.66–49.02 FKB) was found to be sufficient for expression of incD incompatibility. Multicopy vectors containing incD are compatible with each other, but can be displaced by mini-F plasmids deleted for incD. These results indicate that incD-mediated incompatibility reactions require the presence of replication genes to which incD is normally linked. The degree of incompatibility exercised by incD is moderate compared with that of other inc loci in F, suggesting that incD is involved in an aspect of plasmid maintennce, such as partition, different from the functions of the other inc loci.     

Genetic and heteroduplex analysis of deletion mutants of plasmid pAS8]

Heteroduplex analysis of deletion mutants of plasmid pAS8 permitted to construct a physical map and to elaborate in greater detail the genetic map of RP4 plasmid. The correlation between the ability of mutants to replicate in cells lacking functional DNA-polymerase I and the length of the deleted segment permitted to map rep genes of RP4 on DNA region with coordinates 9.8-17.3 kb. A relationship between the manifestation of incompatibility of mutants with IncP-1 plasmids and the length of deletions indicates that inc genes(s) are located on DNA region with coordinates 2.1-9.8 kb. The analysis of replication of deletion mutants and the manifestation of incompatibility just as of the data about the size of appropriate deletions permitted to make the conclusion about the functional and genetic non-identity of the replication control and incompatibility control in RP4 plasmid. Different degrees of incompatibility manifested by different plasmids suggest a possible polygenic control of the incompatibility.     

Comparative analysis of the P-1-group plasmids of incompatibility

Wide host range plasmids (IncP-1) R906, R751 and R702 have several cleavage sites for BamHI, HindIII and EcoRI enzymes, in contrast to RP4 plasmid. Using these enzymes, deletion mutants of R906 plasmid have been obtained in vitro which only lost short DNA fragments (1 to 14 kb). A narrow host range pAV1 plasmid of the same incompatibility group has been transformed into the cells of Escherichia coli. pAV1 is stably maintained in the new host and retains its narrow host range in the course of conjugation. Different restriction fragments of R702, R751, R906 and R906-derived deletion mutants hybridize with the nick-translated probe of RP4 DNA. It is suggested that the wide host range plasmids have a similarity in structural and functional organization.