Excess intracellular concentration of the pSC101 RepA protein interferes with both plasmid DNA replication and partitioning.

RepA, a plasmid-encoded gene product required for pSC101 replication in Escherichia coli, is shown here to inhibit the replication of pSC101 in vivo when overproduced 4- to 20-fold in trans. Unlike plasmids whose replication is prevented by mutations in the repA gene, plasmids prevented from replicating by overproduction of the RepA protein were lost rapidly from the cell population instead of being partitioned evenly between daughter cells. Removal of the partition (par) locus increased the inhibitory effect of excess RepA on replication, while host and plasmid mutations that compensate for the absence of par, or overproduction of the E. coli DnaA protein, diminished it. A repA mutation (repA46) that elevates pSC101 copy number almost entirely eliminated the inhibitory effect of RepA at high concentration and stimulated replication when the protein was moderately overproduced. As the RepA protein can exist in both monomer and dimer forms, we suggest that overproduction promotes RepA dimerization, reducing the formation of replication initiation complexes that require the RepA monomer and DnaA; we propose that the repA46 mutation alters the ability of the mutant protein to dimerize. Our discovery that an elevated intracellular concentration of RepA specifically impedes plasmid partitioning implies that the RepA-containing complexes initiating pSC101 DNA replication participate also in the distribution of plasmids at cell division.     

Boundaries of the pSC101 minimal replicon are conditional.

The DNA segment essential for plasmid replication commonly is referred to as the core or minimal replicon. We report here that host and plasmid genes and sites external to the core replicon of plasmid pSC101 determine the boundaries and competence of the replicon and also the efficiency of partitioning. Missense mutations in the plasmid-encoded RepA protein or mutation of the Escherichia coli topoisomerase I gene enable autonomous replication of a 310-bp pSC101 DNA fragment that contains only the actual replication origin plus binding sites for RepA and the host-encoded DnaA protein. However, in the absence of a repA or topA mutation, the DNA-bending protein integration host factor (IHF) and either of two cis-acting elements are required. One of these, the partitioning (par) locus, is known to promote negative DNA supercoiling; our data suggest that the effects of the other element, the inverted repeat (IR) sequences that overlap the repA promoter, are mediated through the IR's ability to bind RepA. The concentrations of RepA and DnaA, which interact with each other and with plasmid DNA in the origin region (T. T. Stenzel, T. MacAllister, and D. Bastia, Genes Dev. 5:1453-1463, 1991), also affect both replication and partitioning. Our results, which indicate that the sequence requirements for replication of pSC101 are conditional rather than absolute, compel reassessment of the definition of a core replicon. Additionally, they provide further evidence that the origin region RepA-DnaA-DNA complex initiating replication of pSC101 also mediates the partitioning of pSC101 plasmids at cell division.     

New pSC101-derivative cloning vectors with elevated copy numbers

Mutations that increase the copy number of the pSC101 replicon have been used for construction of new cloning vectors. Replacement of glutamate at position 93 in RepA yields plasmids that replicate at medium (27 copies/cell) and high (approximately 240 copies/cell) copy numbers. Based on the crystal structure of RepE, a structurally similar replication initiator protein from the F factor, the pSC101 repA mutants are predicted to be defective in dimerization. The cloning vectors permit increased expression of gene products along with the advantages of pSC101-derivative plasmids, including stable maintenance and compatibility with ColE1 plasmids. The plasmids also allow blue/white screening for DNA inserts and impart resistance to ampicillin, chloramphenicol and kanamycin. The vectors were used in a genetic assay to suppress temperature-sensitive mutants of ffh, encoding the protein component of the Escherichia coli signal recognition particle, by overproduction of 4.5S RNA. While expression of 4.5S RNA from a wild type pSC101-derivative plasmid was not sufficient for suppression, use of the new vectors did suppress the temperature-sensitive phenotype.     

The partition (par) locus of pSC101 is an enhancer of plasmid incompatibility

The incompatibitity that pSC101-derived plasmids express toward each other is mediated by directly repeated sequences (iterons) located near the plasmid's replication origin. We report here that the pSC101 par locus, which stabilizes plasmid inheritance in dividing cell populations and alters DNA superheliclty, can function as a cis-acting enhancer of incompatibility, which we show is determined jointly by the copy number of the plasmid and the number of iterons per copy. A single synthetic 32 bp iteron sequence carried by the pUC19 plasmid confers strong pSC101-specific incompatibility in the absence of any other pSC101 sites but requires the par locus to express strong incompatibility when carried by a lower-copy-number plasmid. We propose a model by which the par locus can enchance the apparently antagonistic processes of incompatibility and pSC101 DNA replication while concurrently facilitating plasmid distribution during cell division.     

Separate roles of Escherichia coli replication proteins in synthesis and partitioning of pSC101 plasmid DNA

We report here that the Escherichia coli replication proteins DnaA, which is required to initiate replication of both the chromosome and plasmid pSC101, and DnaB, the helicase that unwinds strands during DNA replication, have effects on plasmid partitioning that are distinct from their functions in promoting plasmid DNA replication. Temperature-sensitive dnaB mutants cultured under conditions permissive for DNA replication failed to partition plasmids normally, and when cultured under conditions that prevent replication, they showed loss of the entire multicopy pool of plasmid replicons from half of the bacterial population during a single cell division. As was observed previously for DnaA, overexpression of the wild-type DnaB protein conversely stabilized the inheritance of partition-defective plasmids while not increasing plasmid copy number. The identification of dnaA mutations that selectively affected either replication or partitioning further demonstrated the separate roles of DnaA in these functions. The partition-related actions of DnaA were localized to a domain (the cell membrane binding domain) that is physically separate from the DnaA domain that interacts with other host replication proteins. Our results identify bacterial replication proteins that participate in partitioning of the pSC101 plasmid and provide evidence that these proteins mediate plasmid partitioning independently of their role in DNA synthesis.     

Role of DNA superhelicity in partitioning of the pSC101 plasmid

Previous work has shown that a cis-acting locus (termed par for partitioning) on the pSC101 plasmid accomplishes its stable inheritance in dividing cell populations. We report here that the DNA of pSC101 derivatives lacking the par region shows a decrease in overall superhelical density as compared with DNA of wild-type pSC101. Chemicals and bacterial mutations that reduce negative DNA supercoiling increase the rate of loss of par plasmids and convert normally stable plasmids that have minimal par region deletions into unstable replicons. topA gene mutations, which increase negative DNA supercoiling, reverse the instability of partition-defective plasmids that utilize the pSC101, p15A, F, or oriC replication systems. Our observations show that the extent of negative supercoiling of plasmid DNA has major effects on the plasmid's inheritance and suggest a mechanism by which the pSC101 par region may exert its stabilizing effects.     

Replication origin mutations affecting binding of pSC101 plasmid-encoded Rep initiator protein.

To investigate the role of binding sites for Rep initiation protein in the replication of pSC101, a series of plasmids was constructed which carried different combinations of mutations in three binding sites within the minimal origin of replication. Mutation of all three sites reduced the affinity of purified Rep protein for the origin by 100-fold, as measured by a competition binding assay. Mutations in individual binding sites prevented binding of Rep protein to the mutant site but not to adjacent wild-type sites. Transformation efficiency, copy number, and stability over 150 generations were measured for each of the mutant plasmids. Unlike other similar plasmids related to pSC101, the Rep binding sites were found not to be equivalent. A mutation in the site RS1, proximal to repeated sequences which serve as DnaB helicase entry sites in oriC, had a severe effect on replication activity. A similar mutation in the distal site RS3 caused a reduction in copy number, but the mutant plasmid was stably maintained despite a broadened distribution of copy number within the population. A mutation in the middle RS2 site had no significant effect on pSC101 replication.     

Characterization of copy number mutants of plasmid pSC101

We have characterized three copy number mutants of the plasmid pSC101. These mutations caused single amino acid substitutions at the 46th, 83rd and 115th codons in the rep gene and an increase in the copy number by 4- to 8-fold. Although the in vivo and in vitro repressor activities of these mutated Rep proteins were quite different from each other, the intracellular concentrations of the proteins were maintained at higher levels than the wild-type protein. It has been reported that excess amounts of Rep inhibit pSC101 replication (Ingmer and Cohen, 1993). This inhibitory activity of Rep was markedly decreased in all three mutants. When both the wild-type and one of the mutated rep genes were retained in the same plasmids, the copy number of these plasmids was decreased compared with plasmids retaining a single mutated rep gene. These results support the theory that the inhibitory activity of Rep for its own replication plays an important role in copy number regulation.     

Plasmid pSC101 replication mutants generated by insertion of the transposon Tn1000

A derivative of pSC101, pLC709, was constructed by ligation of the HincII-A fragment of pSC101 to the mini-colEI plasmid pVH51 and to a DNA fragment encoding resistance to the antibiotics streptomycin and spectinomycin. Insertions of the transposon Tn1000 (gamma-delta) into the pSC101 replication region of pLC709 were isolated following cotransfer of the plasmid with the sex factor F. The sites of insertion of the transposon were determined by restriction enzyme analysis and the replication and incompatibility properties of the insertion plasmids and DNA fragments cloned from them were analysed. The insertion mutations defined a locus, inc, of approximately 200 base-pairs that is responsible for pSC101-specific incompatibility. Two mutations adjacent to this region inactivate pSC101 replication but can be complemented in trans by a wild-type pSC101 plasmid, and thus define a trans-acting replication function, rep. The inc locus is within a larger region of some 450 base-pairs that is essential for pSC101 replication and that includes the origin of replication. This 450 base-pair segment can replicate in the presence of a helper plasmid that supplies the rep function in trans.     

A set of temperature sensitive-replication/-segregation and temperature resistant plasmid vectors with different copy numbers and in an isogenic background (chloramphenicol, kanamycin, lacZ, repA, par, polA)

A set of plasmid vectors conferring chloramphenicol resistance (Cm(R)), 3064bp in size, or kanamycin resistance (Km(R)), 2972bp in size, were developed, having multiple cloning sites in lacZ' genes for alpha-complementation. pTH18cs1, pTH19cs1, pTH18ks1 and pTH19ks1 are temperature-sensitive (ts) in DNA replication (ts-Rep); pTH18cs5, pTH19cs5, pTH18ks5 and pTH19ks5 are ts in plasmid segregation (ts-Seg); and pTH18cr, pTH19cr, pTH18kr and pTH19kr are temperature resistant (tr) in both. They are based on the pSC101 replicon consisting merely of the replication origin and repA gene, compatible with ColE1/pMB1/p15-derived plasmids, and thus do not require polA function of host cells. The copy numbers of the ts-Rep, tr and ts-Seg plasmids were 14, 5 and 1 per chromosome at 30 degrees C, respectively. These plasmids are fairly stable when inherited at 30 degrees C, but not above 37 degrees C or 41.5 degrees C, depending on the repA mutations and host strains. They are isogenic apart from the ts mutations in the repA gene, and thus provide with useful tools for having appropriate controls in various experiments including bacterial gene-targeting, transposon mutagenesis, toxic gene expression, differential substitution on host functions, gene dosage analysis and so on.     

The RepA protein of plasmid pSC101 controls Escherichia coli cell division through the SOS response

Although plasmid copy number varies widely among different plasmid species, normally copy number is maintained within a narrow range for any given plasmid. Such copy number control has been shown to occur by regulation of the rate of plasmid DNA replication. Here we report a novel mechanism by which the pSC101 plasmid also can detect an imbalance between the cellular level of its replication protein, RepA, and plasmid-borne RepA binding sites to inhibit bacterial DNA replication and delay host cell division when RepA is in relative excess. We show that delayed cell division occurs by RepA-mediated induction of the SOS response and can be reversed by over-expression of the host DNA primase, DnaG. The effects of RepA excess are prevented by introducing a surfeit of RepA binding sites. The mechanism reported here may help to limit variation in plasmid copy number and allow repopulation of cells with plasmids when copy number falls--potentially pre-empting plasmid loss in cultures of dividing cells.     

Interaction of the IciA protein with AT-rich regions in plasmid replication origins.

A set of AT-rich repeats is a common motif in prokaryotic replication origins. We have screened for proteins binding to the AT-rich repeat region in plasmids F, R1 and pSC101 using an electrophoretic mobility shift assay with PCR-amplified DNA fragments from the origins. The IciA protein, which is known to bind to the AT-rich repeat region in the Escherichia coli origin of chromosome replication, oriC, was found to bind to the corresponding region from plasmids F (oriS) and R1, but not to pSC101. DNase I footprint analysis showed that IciA interacted with the AT-rich region in both F and R1. When the IciA gene was deleted, the copy number of plasmid F increased somewhat, whereas there was no major effect on the replication of pSC101 and R1, or on the E. coli chromosome.     

Partitioning of bacterial plasmids during cell division: a cis-acting locus that accomplishes stable plasmid inheritance

We have identified and characterized a genetic function (designated par, for partition) that is required for stable maintenance of plasmids within exponentially growing cell populations. This function, which accomplishes the active distribution of plasmid DNA molecules to daughter cells, has been localized within the pSC101 plasmid to a 270 bp segment adjacent to the replication origin. The par locus, which appears to be functionally equivalent to the centromere of eucaryotic cells, is able to rescue unstable pSC101-derived replicons or an unrelated par- P15A-derived multicopy replicon in the cis, but not the trans, configuration. It is independent of copy number control and dose not specify plasmid incompatibility. Furthermore, it is not associated directly with plasmid replication functions.     

Negative control of plasmid pSC101 replication by increased concentrations of both initiator protein and iterons

Increased intracellular concentrations of the initiator protein Rep (or RepA) interfere with pSC101 DNA replication, and mutated Rep proteins that result in an increase in plasmid copy numbers do not inhibit the replication. A rep mutant (rep(inh)) defective in the inhibitory activity was isolated and found to be a new high copy number mutant. The inhibitory function of Rep was enhanced by the coexistence of directly repeated sequences (DR; iterons) in the replication origin region (ori), but not by the inverted repeat sequences (IR) in ori and the rep promoter. This synergistic effect of Rep and DR sequences for the replication inhibition was dependent on their intracellular concentrations. Considering that DR sequences are the specific binding sites of the Rep monomer form, the Rep monomer-DR complex might be responsible for the inhibition of the plasmid replication. Furthermore, the Rep monomer in the crude cell extracts facilitated dimerization of DR DNA fragments by DNA ligase. Neither synergistic inhibitory function with DR nor Rep mediated dimerization of DR DNA was observed in high copy number mutant Rep proteins. The role of the Rep-iteron complex in the copy number control of pSC101 is discussed.     

Specific-purpose plasmid cloning vectors. I. Low copy number, temperature-sensitive, mobilization-defective pSC101-derived containment vectors

Two cloning vector plasmids, pHSG415 (7100 bp) and a lambda phage cos site-containing derivative (cosmid) thereof, pHSG422 (8760 bp), were constructed from a low copy number plasmid (pSC101) replicon to permit the propagation of cloned DNA segments at low gene dosage levels. Two features of the vectors, namely temperature sensitivity of replication and inability to be mobilized by conjugative plasmids, cause them to exhibit a high level of "biological containment". The essential characteristics of pHSG415 and pHSG422 may be summarized as follows: (1) their genome copy number is low (4--6 copies/chromosome); (2) their replication ceases at high temperature and they are rapidly lost from host cells grown at temperatures of 37 degrees C and above; (3) the relaxation nick site of pSC101, which is thought to be synonymous with its origin of transfer replication, is absent from the vectors; as a consequence, they are not mobilized to a significant extent by co-existing conjugative plasmids that are able to mobilize wild-type pSC101; (4) they contain unique insertion sites for DNA fragments generated by the following restriction endonucleases: EcoRI, XhoI, XmaI, HindIII and PstI; pHSG415 additionally contains single BamHI, BstEII and HincII sites and may also be used to clone PvuI-generated fragments; (5) the plasmids confer upon their host cells resistance to chloramphenicol, kanamycin and ampicillin, and every unique cloning site, except those of BamHI and BstEII, is located within one of these antibiotic-resistance genes.     

Effect of dna mutations on the replication of plasmid pSC101 in Escherichia coli K-12.

Escherichia coli strains with mutations in genes dnaB, dnaC, and dnaG were tested for their capacity to replicate pSC101 deoxyribonucleic acid (DNA) at a nonpermissive temperature. Only a small amount of radioactive thymine was incorporated into pSC101 DNA in the dna mutants at 42 degrees C, whereas active incorporation into plasmid DNA took place in wild-type strains under the same conditions. The effects of the dnaB and dnaC mutations were greater on plasmid DNA synthesis than on host chromosomal DNA synthesis, suggesting that these gene products are directly involved in the process of pSC101 DNA replication. In dnaG mutants, both plasmid and chromosomal DNA synthesis were blocked soon after the shift to high temperature; although the extent of inhibition of the plasmid DNA synthesis was greater during the early period of temperature shift to 42 degrees C as compared with that of the host DNA synthesis, during the later period it was less. It was found that the number of copies of pSC101 per chromosome in dnaA and dnaC strains, grown at 30 degrees C, was considerably lower than that in wildtype strains, suggesting that the replication of pSC101 in these mutant strains was partially suppressed even under the permissive conditions. No correlation was found between the number of plasmid copies and the tetracycline resistance level of the host bacterium.     

Replication of the mini-R1 plasmid Rsc11 and Rsc11 hybrid plasmids.

Replication of the multicopy mini-R1 plasmid, Rsc11, is dependent on host replication functions dna A, B, C, E and G but independent of polA1. Chloramphenicol immediately stops its replication. A stable relaxation complex is not formed. Composite plasmids were constructed with Rsc11 and other small replicons like pSC101, ColE1 and mini-ColE1. In all combinations the amount of hybrid plasmid DNA in the cell never exceeds the amount of Rsc11 DNA itself. This leads to varying copy numbers of the hybrid plasmids depending on the size of the second plasmid. Replication of the composite plasmids proceeds probably always under the control of the Rsc11 part although the second replicon is still functional. The composite plasmids are incompatible with both the parent replicons.