Kurt Nordström

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 lambda 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).

Plasmids with temperature-dependent copy number for amplification of cloned genes and their products

Miniplasmids (pKN402 and pKN410) were isolated from runaway-replication mutants of plasmid R1. At 30 degrees C these miniplasmids are present in 20--50 copies per cell of Escherichia coli, whereas at temperatures above 35 degrees C the plasmids replicate without copy number control during 2--3 h. At the end of this period plasmid DNA amounts to about 75% of the total DNA. During the gene amplification, growth and protein synthesis continue at normal rate leading to a drastic amplification of plasmid gene products. Plasmids pKN402 (4.6 Md) and pKN410 (10 Md) have single restriction sites for restriction endonucleases EcoRI and HindIII; in addition plamid pKN410 has a single BamHI site and carries ampicillin resistance. The plasmids can therefore be used as cloning vectors. Several genes were cloned into these vectors using the EcoRI sites; chromosomal as well as plasmid-coded beta-lactamase was found to be amplified up to 400-fold after thermal induction of the runaway replication. Vectors of this temperature-dependent class will be useful in the production of large quantities of genes and gene products. These plasmids have lost their mobilization capacity. Runaway replication is lethal to the host bacteria in rich media. These two properties contribute to the safe use of the plasmids as cloning vehicles.

Control of replication of bacterial plasmids: genetics, molecular biology, and physiology of the plasmid R1 system

Plasmids are autonomously replicating DNA molecules that are present in defined copy numbers in bacteria. This number may for some plasmids be very low (2-5 per average cell). In order to be stably inherited, replication and partitioning of the plasmid have to be strictly controlled. Plasmids carry genetic information for both processes. In the present paper we summarize what is known about the replication control system of one low-copy-number plasmid, R1, belonging to the FII incompatibility group. We do so because the FII group seems to be one of the best understood examples with respect to genetics, molecular biology, and physiology of the replication control system. The paper is not a classical review, but rather an essay in which we discuss the aspects of replication control that we regard as being important.

A runaway-replication mutant of plasmid R1drd-19: Temperature-dependent loss of copy number control

SummaryA two-step mutant plasmid, originating from the resistance plasmid R1drd-19, was shown to replicate without control of the plasmid copy number when the host bacteria were grown at temperatures above 35°C. The uncontrolled plasmid replication, so called runaway-replication, eventually inhibits the host cell growth and results in a conditionally lethal phenotype. As much as 75% of the total DNA in the cells was found to be covalently closed circular plasmid DNA at the stage when the cell growth stopped. At 30°C the mutant plasmid had a strictly controlled copy number and the onset and kinetics of runaway-replication was studied by temperatureshift experiments. The synthesis of plasmid DNA after a temperature shift from 30°C to 40°C (or 37°C) was found to be exponential with a doubling time of about half the doubling time of the host bacteria, in broth medium as well as in minimal salt-glucose medium. In broth medium the plasmid population had a doubling time of about 12 min which is longer than expected if it is assumed that the rate of elongation during the DNA polymerization is the only limitation on the uncontrolled replication. The results indicate that the minimum time required between successive replications of a plasmid copy is determined by some rate-limiting step(s) presumably after the duplication process. The uncontrolled plasmid replication was shown to be inhibited by the protein synthesis inhibitor chloramphenicol. The plasmid synthesis stopped within 20 min after the addition of the drug and the plasmid DNA increment was less than 50%, suggesting that the uncontrolled plasmid replication requires de novo protein synthesis. Similarly, the RNA polymerase inhibitor rifampicin did inhibit the plasmid replication. The mutational alteration could be reversed, and the copy number control restored, by lowering the temperature before the host cell growth was inhibited. This type of plasmid mutant offers new possibilities in studies of host cell-plasmid interactions.

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 , 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.

Partitioning of plasmid R1 in Escherichia coli: II. Incompatibility properties of the partitioning system

Abstract A theoretical as well as an experimental study of the effect of the partitioning system on plasmid R1drd-19 incompatibility was performed. The theoretical numerical analysis (by computer) was based upon the following assumptions: (i) The partitioning (par) mechanism is independent of the replication (rep) and replication control (cop) mechanism. (ii) A par mutation causes random (binomial) distribution of plasmid copies between the daughter cells at cell division. (iii) In the par+ case, the plasmid copies are equipartitioned and selected randomly for partitioning. (iv) Selection of plasmid copies for replication is random. (v) Two different replication control systems were considered: Model 1 assumes that the plasmid copy number is set to exactly 2n before cell division, whereas in Model 2 exactly n copies are synthesized per cell per cell cycle. Numerical analysis was performed for the n values 2–8. The result was that in all cases (par+/par+, par+/par, par/par), steady states with respect to copy number distribution within the heteroplasmid population were rapidly (within five or six generations) established, giving constant loss rates. The rate of loss was slightly higher in the par/par case than in the other two. The two replication control models gave almost identical loss rates. In the par+/par case, the par+ plasmid had an advantage over the par plasmid. The experimental approach was to create heteroplasmid populations of Escherichia coli by introducing two genetically marked derivatives of plasmid R1drd-19 and then follow the reduction in the relative size of this population during exponential growth in LB medium. The loss rate was essentially the same in the par+/par+ and par+/par combination and slightly higher in the par/par case, suggesting that plasmid incompatibility mainly is caused by the replication and copy number control system. In the par+/par situation, the par+ plasmid had a pronounced advantage over the par plasmid. The par region of plasmid R1 (without the basic replicon) was cloned onto the vector pSF2124. A par (deletion) mutation was not complemented by par+. Plasmid pSF2124, which does not seem to carry a par system of its own, could use the R1 par system, adding to the conclusion that par is independent of rep and cop. Plasmids pSF2124 and R1drd-19 are completely compatible, whereas plasmid pSF2124 carrying the R1 par system and plasmid R1drd-19 showed a weak incompatibility although the copy numbers of the two plasmids were not affected in the heteroplasmid cells. Hence, the partitioning system causes incompatibility, but the effect is weak compared to that of the cop system. The result is consistent with some sort of assortment of plasmids before partitioning.

Isolation and characterization of new copy mutants of plasmid R1, and identification of a polypeptide involved in copy number control

SummarySite-specific deletions and insertions in the replication region of plasmid R1 have generated a new class of copy mutants that are present in the cell with 10–15-fold increased copy number. All mutations described inactivate a copy number control gene which is distinct from another cop inc gene that was identified previously (Molin and Nordström 1980). Insertion of the lac operon lacking the normal lac promoter has been used to determine the direction of transcription of this cop gene. The mutants may all be complemented by wild-type plasmid derivatives and are thus recessive. In incompatibility tests with wild-type R1 plasmids, these mutants are indistinguishable from the wild-type plasmid. It therefore seems that this cop function does not play an important role for the incompatibility function. A polypeptide, molecular weight 11,000, has been identified as being the product of this cop gene.

The nucleotide sequence of the replication control region of the resistance plasmid R1drd-19

SummaryThe region of plasmid R1 containing the replication control genes has been sequenced using the Maxam-Gilbert method. The nucleotide sequence of two small PstI restriction fragments (a total of about 1,000 base pairs) was determined for the wildtype R1 plasmid as well as for two different copy mutants. It was found that one copy mutant has a single base substitution in the fragment which was recently shown to harbor an important inc/cop gene (Molin and Nordström 1980). Furthermore, the sequence indicates the presence of a structural gene that codes for a polypeptide of size 10,500 daltons. Possible gene products predicted from the nucleotide sequences and their role in replication control are discussed.

Temperature-dependent and amber copy mutants of plasmid R1drd-19 in Escherichia coli.

Abstract The isolation of conditional mutants with an altered copy number of the R plasmid R1drd-19 is described. Temperature-dependent as well as amber-suppressible mutants were found. These mutant plasmids have been named pKN301 and pKN303, respectively. Both types of mutations reside on the R plasmid. No difference in molecular weight could be detected by neutral sucrose gradient centrifugation for any of the mutant plasmids when compared with the wild-type plasmid. The number of copies of the plasmids was determined by measurement of the specific activity of the R plasmid-mediated β-lactamase and by measurement of covalently closed circular (CCC) DNA in alkaline sucrose gradients and dye-CsCl density gradients. Below 34 °C the temperature-dependent mutant, pKN301, had the same copy number as the wild type, while this was four times that of the wild type above 37 °C. The amber mutant pKN303 had a copy number indistinguishable from that of the wild-type plasmid in a strain containing a strong amber suppressor and a copy number about five times that of the wild-type plasmid in a strain lacking an amber suppressor. In a strain containing a temperature-sensitive amber suppressor, the amber mutants copy number increased with the decrease in amber suppressor activity. Thus, the existence of the temperature-dependent and the amber-suppressible R-plasmid copy mutants indicates that the system that controls the replication of plasmid R1drd-19 contains an element with a negative function and that this element is a protein.

RecA-Mediated Rescue of Escherichia coli Strains with Replication Forks Arrested at the Terminus

The recombinational rescue of chromosome replication was investigated in Escherichia coli strains with the unidirectional origin oriR1, from the plasmid R1, integrated within oriC in clockwise (intR1(CW)) or counterclockwise (intR1(CC)) orientations. Only the intR1(CC) strain, with replication forks arrested at the terminus, required RecA for survival. Unlike the strains with RecA-dependent replication known so far, the intR1(CC) strain did not require RecBCD, RecF, RecG, RecJ, RuvAB, or SOS activation for viability. The overall levels of degradation of replicating chromosomes caused by inactivation of RecA were similar in oriC and intR1(CC) strains. In the intR1(CC) strain, RecA was also needed to maintain the integrity of the chromosome when the unidirectional replication forks were blocked at the terminus. This was consistent with suppression of the RecA dependence of the intR1(CC) strain by inactivating Tus, the protein needed to block replication forks at Ter sites. Thus, RecA is essential during asymmetric chromosome replication for the stable maintenance of the forks arrested at the terminus and for their eventual passage across the termination barrier(s) independently of the SOS and some of the major recombination pathways.