Random replication of the stringent plasmid R1 in Escherichia coli K-12.

The R-factor R1 is present in a low number of copies per genome (near unity, so-called stringent control of replication). The replication of R1 was studied in a density-shift experiment. One generation after the shift about 20% of the R1 copies had not replicated, whereas about 20% had replicated at least twice. The results are in quantitative accordance with a random replication of R1 in which the replicating molecules are taken from a cytoplasmic plasmid pool and transferred back to the pool after replication. This is analogous to the results obtained by Bazaral and Helinski (1970) and Rownd (1969) for plasmids that are present in 10 to 20 copies per genome (so-called relaxed control of replication). Hence, there seem to be no difference between stringent and relaxed plasmids with respect to selection of plasmid molecules for replication. However, we cannot tell whether all R1 copies in a cell replicate during a fraction of or throughout the cell cycle. The random selction of plasmid copies for replication has to be considered when models for control of replication are constructed.     

Molecular clocks reduce plasmid loss rates: the R1 case

Plasmids control their replication so that the replication frequency per plasmid copy responds to the number of plasmid copies per cell. High sensitivity amplification in replication response to copy number deviations generally reduces variation in copy numbers between different single cells, thereby reducing the plasmid loss rate in a cell population. However, experiments show that plasmid R1 has a gradual, insensitive replication control predicting considerable copy number variation between single cells. The critical step in R1 copy number control is regulation of synthesis of a rate-limiting cis-acting replication protein, RepA. De novo synthesis of a large number of RepA molecules is required for replication, suggesting that copy number control is exercised at multiple steps. In this theoretical kinetic study we analyse R1 multistep copy number control and show that it results in the insensitive replication response found experimentally but that it at the same time effectively prohibits the existence of only one plasmid copy in a dividing cell. In combination with the partition system of R1, this can lead to very high segregational stability. The R1 control mechanism is compared to the different multistep copy number control of plasmid ColE1 that is based on conventional sensitivity amplification. This implies that while copy number control for ColE1 efficiently corrects for fluctuations that have already occurred, R1 copy number control prevents their emergence in cells that by chance start their cycle with only one plasmid copy. We also discuss how regular, clock-like, behaviour of single plasmid copies becomes hidden in experiments probing collective properties of a population of plasmid copies because the individual copies are out of phase. The model is formulated using master equations, taking a stochastic approach to regulation, but the mathematical formalism is kept to a minimum and the model is simplified to its bare essence. This simplicity makes it possible to extend the analysis to other replicons with similar design principles.     

Regulation of plasmid R1 replication: PcnB and RNase E expedite the decay of the antisense RNA, CopA

The replication frequency of plasmid R1 is controlled by an unstable antisense RNA, CopA, which, by binding to its complementary target, blocks translation of the replication rate-limiting protein RepA. Since the degree of inhibition is directly correlated with the intracellular concentration of CopA, factors affecting CopA turnover can also alter plasmid copy number. We show here that PcnB (PAP I — a poly(A)polymerase of Escherichia coli  ) is such a factor. Previous studies have shown that the copy number of ColE1 is decreased in pcnB mutant strains because the stability of the RNase E processed form of RNAI, the antisense RNA regulator of ColE1 replication, is increased. We find that, analogously, the twofold reduction in R1 copy number caused by a pcnB lesion is associated with a corresponding increase in the stability of the RNase E-generated 3' cleavage product of CopA. These results suggest that CopA decay is initiated by RNase E cleavage and that PcnB is involved in the subsequent rapid decay of the 3' CopA stem-loop segment. We also find that, as predicted, under conditions in which CopA synthesis is unaffected, pcnB mutation reduces RepA translation and increases CopA stability to the same extent.     

Clustering versus random segregation of plasmids lacking a partitioning function: a plasmid paradox?

Plasmids lacking a functional partition system are randomly distributed to the daughter cells; plasmid-free daughter cells are formed with a frequency of (1/2)2n per cell and cell generation where 2n is the (average) copy number at cell division. Hence, the unit of segregation is one plasmid copy. However, plasmids form clusters in the cells. A putative solution to this potential paradox is presented: one plasmid copy at a time is recruited from the plasmid clusters to the replication factories that are located in the cell centres. Hence, replication offers the means of declustering that is necessary in a growing host population. The daughter copies diffuse freely and each copy may with equal probability end up in either of the two cell halves. In this way, the random segregation of the plasmids is coupled to replication and occurs continuously during the cell cycle, and is not linked to cell division. The unit of segregation is the plasmid copy and not the plasmid clusters. In contrast, the two daughters of a Par+ plasmid are directed in opposite directions by the plasmid-encoded partition system, thereby assuring that each daughter cell receives the plasmid.     

Integrative suppression of dnaA46 by broad host-range plasmid R1162

Summary Replication of plasmid R1162 DNA does not require the product of the dnaA gene. An integrated copy of the plasmid can suppress the temperature-sensitive dnaA46 allele when (1) additional plasmid copies are present in the cytoplasm and (2) an inactive replication origin, generated by deletion, is also present in the chromosome. We propose that the inactive origin sets the rate of initiation of chromosome replication at a level compatible with cell viability, possibly by providing additional binding sites for an R1162-encoded protein that is rate-limiting for plasmid replication.     

Control of Plasmid R1 Replication: Kinetics of Replication in Shifts Between Different Copy Number Levels

Plasmid R1 replication was studied in shifts between two steady states of copy number. The copy number was varied in two ways. First, we utilized the fact that it decreases with increasing growth rate. To minimize the metabolic effects of changes in the growth rate, the downshifts were obtained by adding α-methylglucoside to cultures growing in glucose-minimal medium, and the upshifts were obtained by adding glucose to cultures growing in the presence of glucose plus α-methylglucoside. Second, we used a temperature-dependent copy mutant of plasmid R1 (pKN301). Plasmid pPK301 shows a threefold higher copy number at 40 than at 30°C. In both types of shift, plasmid replication immediately adjusted to the postshift differential rate. The copy number asymptotically adjusted to the new steady state. Hence, the system that controls plasmid R1 replication sets the frequency of replication without measuring the actual copy number. It has been suggested that plasmid R1 replication is under negative control by an R1-mediated repressor protein. Among the replication control models that involve negative control, the Pritchard inhibitor dilution model, the Sompayrac-Maaløe autorepressor model, and the plasmid λdv system all predict gene dose-independent copy number control.     

Selection and timing of replication of plasmids R1drd-19 and F'lac in Escherichia coli.

The selection and timing of plasmid replication was studied in exponentially growing cultures of Escherichia coli K-12 carrying the plasmid R1drd-19 and E. coli strains B/r A and B/r F carrying the plasmid F′lac. In all cases plasmid replication was studied by analysis of covalently closed circular (CCC) DNA. The turnover time of replicating plasmid DNA into CCC-DNA was found to be less than 4 min. Density shift experiments (from ¹⁵NH₄⁺, D₂O to ¹⁴NH₄⁺, H₂O) showed that plasmids R1drd-19 and F′lac are selected randomly for replication. This means that one of the plasmid copies in a cell is selected and replicated. There is no further plasmid replication in the cell until all plasmid copies, including the newly formed ones, have the same probability of being selected for replication. The early kinetics of the appearance of light plasmid DNA after the density shift showed that the time interval between successive replications of plasmids R1drd-19 and F′lac is $\text{τ}\text{n}$, where τ is the generation time and n is the average number of plasmid replications per cell and cell cycle. In a second type of experiment, exponentially growing cells were separated into a series of size classes by low-speed centrifugation in sucrose step gradients. Replication of plasmids R1drd-19 and F′lac was equally frequent in all size classes. This result is in accordance with the results of the density shift experiment. It can therefore be concluded that replication of plasmids R1drd-19 and F′lac is evenly spread over the whole cell cycle, which means that one plasmid replication occurs every time the cell volume has increased by one initiation mass.     

Eclipse period of R1 plasmids during downshift from elevated copy number: Nonrandom selection of copies for replication

The classical Meselson-Stahl density-shift method was used to study replication of pOU71, a runaway-replication derivative of plasmid R1 in Escherichia coli. The miniplasmid maintained the normal low copy number of R1 during steady growth at 30°C, but as growth temperatures were raised above 34°C, the copy number of the plasmid increased to higher levels, and at 42°C, it replicated without control in a runaway replication mode with lethal consequences for the host. The eclipse periods (minimum time between successive replication of the same DNA) of the plasmid shortened with rising copy numbers at increasing growth temperatures (Olsson et al., 2003). In this work, eclipse periods were measured during downshifts in copy number of pOU71 after it had replicated at 39 and 42°C, resulting in 7- and 50-fold higher than normal plasmid copy number per cell, respectively. Eclipse periods for plasmid replication, measured during copy number downshift, suggested that plasmid R1, normally selected randomly for replication, showed a bias such that a newly replicated DNA had a higher probability of replication compared to the bulk of the R1 population. However, even the unexpected nonrandom replication followed the copy number kinetics such that every generation, the plasmids underwent the normal inherited number of replication, n, independent of the actual number of plasmid copies in a newborn cell.     

The heat-shock DnaK protein is required for plasmid R1 replication and it is dispensable for plasmid ColE1 replication.

Plasmid R1 replication in vitro is inactive in extracts prepared from a dnaK756 strain but is restored to normal levels upon addition of purified DnaK protein. Replication of R1 in extracts of a dnaKwt strain can be specifically inhibited with polyclonal antibodies against DnaK. RepA-dependent replication of R1 in dnaK756 extracts supplemented with DnaKwt protein at maximum concentration is partially inhibited by rifampicin and it is severely inhibited at sub-optimal concentrations of DnaK protein. The copy number of a run-away R1 vector is reduced in a dnaK756 background at 30 degrees C and at 42 degrees C the amplification of the run-away R1 vector is prevented. However a runaway R1 vector containing dnaK gene allows the amplification of the plasmid at high temperature. These data indicate that DnaK is required for both in vitro and in vivo replication of plasmid R1 and show a partial compensation for the low level of DnaK by RNA polymerase. In contrast ColE1 replication is not affected by DnaK as indicated by the fact that ColE1 replicates with the same efficiency in extracts from dnaKwt and dnaK756 strains.     

Properties of R1162, a broad-host-range, high-copy-number plasmid.

Regions of plasmid DNA encoding characteristic properties of the IncQ (P-4) group plasmid R1162 were identified by mutagenesis and in vitro cloning. Coding sequences sufficient for expression of incompatibility and efficient conjugal mobilization by plasmid R751 were found to be linked to the origin of DNA replication. In contrast, there was a region remote from the origin, and active in trans, that was required for plasmid maintenance. A derivative that was temperature sensitive for stability was isolated. The defect mapped at or near the region required for plasmid maintenance and resulted in far fewer copies of supercoiled plasmid DNA per cell under permissive conditions. A second region required for stability was also identified from the behavior of a deletion derivative of R1162, which did not, however, show an altered number of supercoiled plasmid DNA copies. Finally, a plasmid DNA mutation resulting in a substantially higher copy number was isolated. Plasmid reconstruction experiments suggested that the mutation was linked to the replicative origin.     

Clustering of genes involved in replication, copy number control, incompatibility, and stable maintenance of the resistance plasmid R1drd-19.

Plasmid R1drd-19 is present in a small number of copies per cell of Escherichia coli. The plasmid was reduced in size by in vivo as well as in vitro (cloning) techniques, resulting in a series of plasmid derivatives of different molecular weight. All plasmids isolated contain a small region (about 2 x 10(6) daltons of deoxyribonucleic acid) of the resistance transfer factor part of the plasmid located close to one of the IS1 sequences that separates the resistance transfer factor part from the resistance determinant. All these derivatives were present at the same copy number, retained the incompatibility properties of plasmid R1drd-19, and were stably maintained during cell division. Genes mutated to yield copy mutations also were found to be located in the same region.     

Rep*: a Viral Element That Can Partially Replace the Origin of Plasmid DNA Synthesis of Epstein-Barr Virus

Replication of the Epstein-Barr viral (EBV) genome occurs once per cell cycle during latent infection. Similarly, plasmids containing EBV’s plasmid origin of replication, oriP, are replicated once per cell cycle. Replication from oriP requires EBV nuclear antigen 1 (EBNA-1) in trans; however, its contributions to this replication are unknown. oriP contains 24 EBNA-1 binding sites; 20 are located within the family of repeats, and 4 are found within the dyad symmetry element. The site of initiation of DNA replication within oriP is at or near the dyad symmetry element. We have identified a plasmid that contains the family of repeats but lacks the dyad symmetry element whose replication can be detected for a limited number of cell cycles. The detection of short-term replication of this plasmid requires EBNA-1 and can be inhibited by a dominant-negative inhibitor of EBNA-1. We have identified two regions within this plasmid which can independently contribute to this replication in the absence of the dyad symmetry element of oriP. One region contains native EBV sequences within the BamHI C fragment of the B95-8 genome of EBV; the other contains sequences within the simian virus 40 genome. We have mapped the region contributing to replication within the EBV sequences to a 298-bp fragment, Rep*. Plasmids which contain three copies of Rep* plus the family of repeats support replication more efficiently than those with one copy, consistent with a stochastic model for the initiation of DNA synthesis. Plasmids with three copies of Rep* also support long-term replication in the presence of EBNA-1. These observations together indicate that the latent origin of replication of EBV is more complex than formerly appreciated; it is a multicomponent origin of which the dyad symmetry element is one efficient component. The experimental approach described here could be used to identify eukaryotic sequences which mediate DNA synthesis, albeit inefficiently.     

Partitioning of plasmid R1 in Escherichia coli,: I. Kinetics of loss of plasmid derivatives deleted of the par region

The stability of inheritance of plasmid R1drd-19 was tested. The copy number of the plasmid was determined in two different ways: As the ratio between covalently closed circular DNA and chromosomal DNA, and by quantitative determination of single-cell resistance to ampicillin. In the latter case, strains carrying the R1 ampicillin transposon Tn3 on prophage λ was used as standard. The values were transformed to copy number per cell by using the Cooper-Helmstetter model for chromosome replication as well as by determination of chromosomal DNA per cell by the diphenylamine method. The copy number was found to be five to six per cell (or about four per newborn cell). Nevertheless, plasmid R1drd-19 was found to be completely stably inherited. This stability was shown not to be due to retransfer of the plasmid by the R1 conjugation system, since transfer-negative derivatives of the plasmid were also completely stably inherited. Smaller derivatives of plasmid R1drd-19 were found to be lost at a frequency of about 1.5% per cell generation. The copy-number control was not affected in these miniplasmids, since their copy numbers were the same as that of the full size plasmid. Quantitatively, the instability of the miniplasmids was in accord with random partitioning. It is, therefore, suggested that the plasmid R1drd-19 carries genetic information for partitioning (par) of plasmid copies at cell division, and that the par mechanism is distinct from the copy number control (cop) system. Finally, the par gene maps on the resistance transfer part of the plasmid, but far away from the origin of replication and the so-called basic replicon; this is in accord with the approximate location of the repB gene (Yoshikawa, 1974, J. Bacteriol.,, 118, 1123–1131).     

Translational control by antisense RNA in control of plasmid replication

Control of replication of plasmids involves two processes: measurement of the copy number of the plasmid and adjustment of the replication frequency accordingly. For both these processes IncFII plasmids use an antisense RNA (CopA RNA) that forms a duplex with the upstream region (CopT) of the mRNA of the rate-limiting RepA protein. The kinetics of duplex formation was measured in vitro for the wild type and for a cop mutant plasmid; the mutant showed a reduction in the second-order rate constant for the formation of the RNA duplex and a similar increase in copy number. Hence, the kinetics of duplex formation and the concentration of CopA RNA determines the copy number of the plasmid.     

Eclipse period during replication of plasmid R1: contributions from structural events and from the copy-number control system

The eclipse period (the time period during which a newly replicated plasmid copy is not available for a new replication) of plasmid R1 in Escherichia coli was determined with the classic Meselson-Stahl density-shift experiment. A mini-plasmid with the wild-type R1 replicon and a mutant with a thermo-inducible runaway-replication phenotype were used in this work. The eclipses of the chromosome and of the wild-type plasmid were 0.6 and 0.2 generation times, respectively, at temperatures ranging from 30 degrees C to 42 degrees C. The mutant plasmid had a similar eclipse at temperatures up to 38 degrees C. At 42 degrees C, the plasmid copy number increased rapidly because of the absence of replication control and replication reached a rate of 350-400 plasmid replications per cell and cell generation. During uncontrolled replication, the eclipse was about 3 min compared with 10 min at controlled replication (the wild-type plasmid at 42 degrees C). Hence, the copy-number control system contributed significantly to the eclipse. The eclipse in the absence of copy-number control (3 min) presumably is caused by structural requirements: the covalently closed circular plasmid DNA has to regain the right degree of superhelicity needed for initiation of replication and it takes time to assemble the initiation factors.     

Cell cycle analysis of plasmid-containing Escherichia coli HB101 populations with flow cytometry

The relationship between cell mass and cell number dynamics for bacteria such as Escherichia coli depends on the cell cycle parameters C and D. Effects of plasmid copy number on these cell cycle parameters have been studied for Escherichia coli HB101 containing pMB1 plasmids propagated at different copy numbers ranging from 12 to 122. Determination of cell cycle and cell size parameters was accomplished using flow cytometry data on single-cell light scattering and DNA content frequency functions in conjunction with a mathematical model of cell population statistics. Two independent methods for estimating C and D intervals based on flow cytometry were developed and applied with essentially identical results. The presence of plasmids decreases the C and D periods, mean cell sizes, and initiation masses for chromosome replication by 14, 24, 38, and 18%, respectively, relative to corresponding values for plasmid-free host cells. Plasmid copy number has a negligible influence on these parameters, suggesting that host-plasmid inter actions which determine these properties are centered on the single plasmid selected for replication according to the random selection model established for ColE1-type plasmids.