P1 plasmid replication. Role of initiator titration in copy number control

The copy number control locus incA of unit copy plasmid P1 maps in a region containing nine 19 base-pair repeats. Previous results from studies in vivo and in vitro indicated that incA interacts with the plasmid-encoded RepA protein, which is essential for replication. It has been proposed that the repeat sequences negatively control copy number by sequestering the RepA protein, which is rate-limiting for replication. Our results lend further support to this hypothesis. Here we show that the repeats can be deleted completely from P1 miniplasmids and the deletion results in an approximately eightfold increase in plasmid copy number. So, incA sequences are totally dispensable for replication and have only a regulatory role. The copy number of incA-deleted plasmids can be reduced if incA sequences are present in trans or are reincorporated at two different positions in the plasmid. This reduction in copy number is not due to lowered expression of the repA gene in the presence of incA. We show that one repeat sequence is sufficient to bind RepA and can reduce the copy number of incA-deleted plasmids. When part of the repeat was deleted, it lost its ability to bind as well as influence copy number. These results show a strong correlation between the capacity of incA repeats to bind RepA protein both in vivo and in vitro, and the function of incA in the control of copy number.     

Origin pairing ('handcuffing') as a mode of negative control of P1 plasmid copy number.

In one family of bacterial plasmids, multiple initiator binding sites, called iterons, are used for initiation of plasmid replication as well as for the control of plasmid copy number. Iterons can also pair in vitro via the bound initiators. This pairing, called handcuffing, has been suggested to cause steric hindrance to initiation and thereby control the copy number. To test this hypothesis, we have compared copy numbers of isogenic miniP1 plasmid monomer and dimer. The dimer copy number was only one-quarter that of the monomer, suggesting that the higher local concentration of origins in the dimer facilitated their pairing. Physical evidence consistent with iteron-mediated pairing of origins preferentially in the dimer was obtained in vivo. Thus, origin handcuffing can be a mechanism to control P1 plasmid replication.     

Analysis of dominant copy number mutants of the plasmid pMB1.

We characterize two dominant copy number mutants of a derivative of plasmid pMB1. One of the two mutations maps in the -35 region of the primer promoter and results in increased promoter activity. The analysis of the secondary structure in the proximity of the mutant sequence suggests a possible mechanism which could be the basis of the promoter-up phenotype. By comparing the properties of the mutant and the wild type plasmid in an in vitro system, we confirm that the primer and not its coding sequence is the target of RNA I inhibition. The second mutation affects the sequence of the primer so that it is less sensitive to inhibition by RNA I. We propose that this mutation stabilizes a secondary structure necessary for primer formation.     

A mathematical model for lambda dv plasmid replication: analysis of copy number mutants

A mathematical model based on the molecular control mechanisms for lambda dv plasmid replication in a single Escherichia coli cell has been applied to simulate replication of mutant lambda dv plasmids. Model simulations of changes in repressor level and copy number resulting from mutations in the promoter-operator PROR region are consistent with experimental data. Calculated effects on lambda dv plasmid copy number of oligomer formation and of alternations in termination efficiency at tR1 also agree with experiment. The model has been employed to simulate the influence of cro mutants and of cro and tR1 double mutants on copy number and stable maintenance of lambda dv plasmid copy number. The genetic structure included in formulation of the replicon model provides a framework for relating changes in specific genetic loci on the plasmid with resulting alterations in host-plasmid system function.     

How the R1 replication control system responds to copy number deviations

The copy number of R1 and of a repA-lacZ gene fusion was increased above normal by coupling to a plasmid which is present at a fivefold higher copy number at 30 degrees C. This carrier plasmid is deficient in replication at 42 degrees C, and it was thus possible after a temperature shift to analyze the response to the increased plasmid concentration of the R1 replication control system. Both the frequency of replication per plasmid molecule and the rate of repA expression per gene copy were reduced under these conditions, and the data strongly suggest that there is an inverse proportionality between the specific rate of plasmid replication viz repA expression and the copy number/gene dosage of the plasmid.     

DnaA boxes in the P1 plasmid origin: the effect of their position on the directionality of replication and plasmid copy number.

The DnaA protein is essential for initiation of DNA replication in a wide variety of bacterial and plasmid replicons. The replication origin in these replicons invariably contains specific binding sites for the protein, called DnaA boxes. Plasmid P1 contains a set of DnaA boxes at each end of its origin but can function with either one of the sets. Here we report that the location of origin-opening, initiation site of replication forks and directionality of replication do not change whether the boxes are present at both or at one of the ends of the origin. Replication was bidirectional in all cases. These results imply that DnaA functions similarly from the two ends of the origin. However, origins with DnaA boxes proximal to the origin-opening location opened more efficiently and maintained plasmids at higher copy numbers. Origins with the distal set were inactive unless the adjacent P1 DNA sequences beyond the boxes were included. At either end, phasing of the boxes with respect to the remainder of the origin influenced the copy number. Thus, although the boxes can be at either end, their precise context is critical for efficient origin function.     

Analysis of copy number control elements in the region of the vegetative replication origin of the broad host range plasmid RK2.

Broad host-range plasmid RK2 is able to replicate in a controlled manner in most Gram negative bacterial species. To analyze the elements of its control mechanism, we have measured the copy number in Escherichia coli of mini-RK2 replicons isogenic except for defined deletions in regions adjacent to the vegetative replication origin, oriVRK2, which have previously been implicated in copy number control because of their expression of plasmid incompatibility. The results indicate that while the previously defined 700-bp HaeII oriVRK2 fragment carries one copy control element (copA), a second (copB) lies at least partly outside this fragment towards the tetracycline resistance genes of RK2. Deletions affecting both these regions give a mini replicon with a copy number of 35-40 compared with 4-7 for parental RK2. Further incompatibility experiments indicate that targets for both incA (copA) and incB (copB) lie within the 700-bp HaeII oriVRK2 fragment.     

Host components required for the replication of the resistance plasmid R124 and a copy mutant derivative

The replication of R124, and a copy mutant derivative of it, was measured with respect to dependence on the host DnaA, DnaB, DnaC, DnaE, DnaG, and PolA gene products. Both plasmids replicated under conditions where the DnaA gene product was inactivated or where the polymerising activity of the PolA gene product was reduced. In contrast, neither plasmid replicated to any appreciable extent, if the DnaB, DnaC, DnaE or DnaG gene products were inactivated. R124 integratively suppressed the lesion of the dnaA mutant but the copy mutant derivative had only a very weak suppressing effect. Neither plasmid suppressed the lesions of any of the other dna mutants.     

Growth-rate dependence reveals design principles of plasmid copy number control

Genetic circuits in bacteria are intimately coupled to the cellular growth rate as many parameters of gene expression are growth-rate dependent. Growth-rate dependence can be particularly pronounced for genes on plasmids; therefore the native regulatory systems of a plasmid such as its replication control system are characterized by growth-rate dependent parameters and regulator concentrations. This natural growth-rate dependent variation of regulator concentrations can be used for a quantitative analysis of the design of such regulatory systems. Here we analyze the growth-rate dependence of parameters of the copy number control system of ColE1-type plasmids in E. coli. This analysis allows us to infer the form of the control function and suggests that the Rom protein increases the sensitivity of control.     

The level of the pUB110 replication initiator protein is autoregulated, which provides an additional control for plasmid copy number.

Plasmids control their copy number by limiting the amount of the initiator for DNA replication. The plasmid pUB110 initiator protein is termed RepU. Expression of the pUB110 repU gene is controlled by two antisense RNAs that interfere with repU mRNA translation. Genetic evidence suggests that Rep protein levels may be regulated by additional uncharacterized mechanisms. The repU gene product was radiolabeled and purified by monitoring the radioactive label. RepU overproduction was performed in cells containing the plasmid leading strand replication origin (dso), to allow for a putative inactivation of RepU. Polypeptides with apparent molecular masses of 42 (RepU*) and 39 (RepU) kDa were purified, both having the N-terminal sequence expected for the repU gene. The RepU/RepU* protein mixture bound specifically to dso. At low protein concentrations, about six RepU/RepU* protomers bound to the dso region. At higher concentrations, an extended nucleoprotein complex was formed. The promoter for the repU gene was localized downstream of the dso region. The results suggest that the extended RepU/RepU*-dso DNA complex interferes with repU promoter utilization. This provides an additional copy number control by limiting RepU concentration. Our results suggest that during replication the RepU protein might be converted into an inactive RepU-RepU* hetero-oligomer, further limiting the amount of RepU protein available for replication initiation.     

Molecular cloning and functional characterization of a copy number control gene (copB) of plasmid R1.

Deletions or insertions in the copB gene of plasmid R1 result in a copy mutant phenotype. The wild-type copB gene has been cloned on various plasmid vectors. The presence of such chimeric plasmids reduced the copy number of R1 copB mutant plasmids to normal or subnormal levels, indicating the expression of a trans-acting inhibitor activity from the copB chimeras. However, the cloned copB gene did not affect the copy number of wild-type R1, and no incompatibility was exerted by the cloned copB gene against wild-type R1 (or R100). Although the copB gene is not normally required for the incompatibility exerted by copA, it is shown that the CopB function is required for expression of incompatibility by the copA gene from some types of chimeric plasmids. Mutant plasmids that have lost both Cop functions replicate in an uncontrolled fashion.     

Purification and characterization of RepA, a protein involved in the copy number control of plasmid pLS1.

The promiscuous streptococcal plasmid pLS1 encodes for the 5.1 kDa RepA protein, involved in the regulation of the plasmid copy number. Synthesis of RepA was observed both in Bacillus subtilis minicells and in an Escherichia coli expression system. From this system, the protein has been purified and it appears to be a dimer of identical subunits. The amino acid sequence of RepA has been determined. RepA shows the alpha helix-turn-alpha helix motif typical of many DNA-binding proteins and it shares homology with a number of repressors, specially with the TrfB repressor encoded by the broad-host-range plasmid RK2. DNase I footprinting revealed that the RepA target is located in the region of the promoter for the repA and repB genes. Trans-complementation analysis showed that in vivo, RepA behaves as a repressor by regulating the plasmid copy number. We propose that the regulatory role of RepA is by limitation of the synthesis of the initiator protein RepB.     

Isolation and characterization of a priB mutant of Escherichia coli influencing plasmid copy number of delta rop ColE1-type plasmids.

The lethality induced by the overproduction in Escherichia coli of a heterologous protein was used to select bacterial mutants. In one of these, the mutation responsible was mapped to priB. We describe the isolation of this mutant, the sequencing of the mutated gene, and its in vivo effect on plasmid replication.     

Loss of secreted hemolysin activity in the mutant strain Hsb. 1 is due to a lesion in a plasmid copy number locus

Further studies have been carried out on mutation hsb which was previously suggested to block hemolysin secretion (Mu?oa et al., 1988, FEMS Microbiol. Lett. 56: 167-172). We show that the reported reduction in the extracellular hemolytic activity of mutant Hsb. 1 is due to lower hemolysin synthesis and that this is itself a consequence of a decrease in plasmid copy number. We suggest that the hsb is identical to the pcnB lesion located at minute 3.6 of the chromosome.