An unusual mutation in RepA increases the copy number of a stringently controlled plasmid (Rtsl derivative) by over one hundred fold

A copy number mutant of the Rtsl replicon (copy number 1–2 copies/cell) was obtained. A one-base substitution in the repA region results in a single amino acid change from histidine to asparagine at position 159. This mutation increased the plasmid copy number by up to 120-fold depending upon the growth conditions. At 42.5° C the plasmid with the wild type replicon was unstable while the mutated replicon was relatively stable.     

Effect ofEscherichia coliIHF Mutations on Plasmid p15A Copy Number

Four isogenic strains (himAhimDdouble mutant,himAandhimDsingle mutants, and their wild type counterpart) harboringorip15A plasmid (pACYC184 or pACYC184Amp or pACYC177) show different copy numbers of that plasmid in the early stationary phase of cultivation. The copy number oforip15A plasmid increases about four times in thehimAhimDdouble (65–70 copies per cell) andhimDsingle mutant cells (50–56 copies per cell) and was almost the same inhimAmutant (17–18 copies per cell) and wild type cells (14–16 copies per cell). The results suggest that HimD can form homodimers, which are functionally competent for the regulation oforip15A plasmid copy number. Complementation experiments ofhimAhimDdouble mutant cells using plasmid carryinghimAandhimDgenes (pP_LhiphimA-5) confirm the effect of integration host factor (IHF) absence on increasing the copy number oforip15A plasmid (plasmid producing IHF complemented the defect of IHF mutant). The absence of IHF (usinghimAhimDdouble mutant as host) had no effect on the copy number of the pBR322 (oripMB1) plasmid.     

Mutation and identification of the F plasmid locus determining resistance to acridine orange curing

A region in plasmid F responsible for resistance to acridine orange curing has been identified. Insertion of the transposable element for ampicillin resistance Tn3 at the 45.8- or 46.35-kilobase coordinate in mini-F plasmids results in resistance to curing by acridine orange and also results in increased plasmid copy numbers. In contrast, copy number mutants of mini-F induced by chemical mutagenesis are sensitive to acridine-induced loss of plasmid. Hence, the Tn3-induced acridine orange resistance does not represent a suppression of sensitivity because of elevated plasmid copy numbers. General hypotheses to explain our results are presented.     

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.     

Effect of high density cultivation on plasmid copy number in recombinantEscherichia coli cells

Summary The copy number of plasmid harboringE. coli K 12 strains was examined in fed batch cultivations in semisynthetic and synthetic media. Under conditions of high cell density (45–50 g dry weight/I) the plasmid copy number reached a maximum level between 200 and 400 copies per cell. A decrease of phosphate concentration in the medium was obtained similar to the increase of copy number. A high segregational and structural stability of vectors used in this work was observed.     

The cost of copy number in a selfish genetic element: the 2‐μm plasmid of Saccharomyces cerevisiae

Many autonomously replicating genetic elements exist as multiple copies within the cell. The copy number of these elements is often assumed to have important fitness consequences for both element and host, yet the forces shaping its evolution are not well understood. The 2 μm is a multicopy plasmid of Saccharomyces yeasts, encoding just four genes that are solely involved in plasmid replication. One simple model for the fitness relationship between yeasts and 2 μm is that plasmid copy number evolves as a trade‐off between selection for increased vertical transmission, favouring high copy number, and selection for decreased virulence, favouring low copy number. To test this model, we experimentally manipulated the copy number of the plasmid and directly measured the fitness cost, in terms of growth rate reduction, associated with high plasmid copy number. We find that the fitness burden imposed by the 2 μm increases with plasmid copy number, such that each copy imposes a fitness burden of 0.17% (± 0.008%), greatly exceeding the cost expected for it to be stably maintained in yeast populations. Our results demonstrate the crucial importance of copy number in the evolution of yeast per 2 μm associations and pave the way for future studies examining how selection can shape the cost of multicopy elements.     

Segregational stability and copy number of the theta-type lactococcal replicon Rep22 in Lactococcus

Rep22 is the replication region of the lactococcal theta replicating pUCL22 plasmid. The copy number of Rep22-based plasmids in Lactococcus was determined by using a chromosomal DNA fragment from Lactococcus lactis subsp. lactis MMS368 as reference. Segregational behavior appeared to be linked to copy number and therefore indicated random distribution of copies to daughter cells. Nevertheless, an active partitioning system was detected in the parental plasmid pUCL22. A pUCL22 138-bp DNA restriction fragment bearing a perfect 18-bp inverted repeat was involved in the improvement of Rep22-based plasmid segregational stability during discontinuous exponential growth.     

Plasmid R1 in Salmonella typhimurium: Molecular instability and gene dosage effects

Plasmid R1 drd-19 and two of its copy mutants (pKN102 and pKN103) were transferred from Escherichia coli to Salmonella typhimurium, where the expression of the copy mutations was studied further. The copy number (ratio of plasmid DNA to chromosomal DNA) was the same in S. typhimurium and in E. coli. The activities of the plasmid-coded antibiotic-metabolizing enzymes β-lactamase, chloramphenicol acetyltransferase, and streptomycin adenylyltransferase as well as the resistances to ampicillin and streptomycin were proportional to the gene dosage up to at least a threefold increase in the steady state plasmid copy number, whereas resistance to chloramphenicol showed no increase with increased number of plasmid copies per chromosome equivalent. Also the resistance to rifampicin was affected since S. typhimurium cells became more sensitive the higher the copy number of the resident plasmid. Furthermore, plasmid R1 showed molecular instability in S. typhimurium cells since there was a tendency to dissociate into resistance transfer factors and resistance determinants and also to form miniplasmids. This tendency to instability was more pronounced the higher the plasmid copy number.     

Plasmid copy number mutation in repA gene encoding RepA replication initiator of cryptic plasmid pHM1519 in Corynebacterium glutamicum

ABSTRACT

Cryptic plasmid pHM1519 is a rolling-circular replication mode plasmid of the pCG1 plasmid family in coryneform bacteria. The derived shuttle vector pPK4 is maintained at about 40–50 copies per chromosome in Corynebacterium glutamicum 2256 (ATCC 13869). We found that a mutation (designated copA1) within the repA gene encoding essential initiator protein RepA of the pHM1519-replicon increased the copy number of the mutant plasmid to about 800 copies per chromosome. The mutation was a single G to A base transition, which changed Gly to Glu at position 429 of the amino acid sequence of RepA. In silico secondary structure prediction of RepA suggested that Gly429 is situated in a disordered region in a helix-turn-helix motif, which is a typical DNA-binding domain. This study shows the first example of a high copy number of a C. glutamicum cryptic plasmid caused by an altered replication initiator protein.     

Roles of Escherichia coli heat shock proteins DnaK, DnaJ and GrpE in mini-F plasmid replication

Summary A subset of Escherichia coli heat shock proteins, DnaK, DnaJ and GrpE were shown to be required for replication of mini-F plasmid. Strains of E. coli K12 carrying a missense mutation or deletion in the dnaK, dnaJ, or grpE gene were virtually unable to be transformed by mini-F DNA at the temperature (30° C) that permits cell growth. When excess amounts of the replication initiator protein (repE gene product) of mini-F were provided by means of a multicopy plasmid carrying repE, these mutant bacteria became capable of supporting mini-F replication under the same conditions. However, the copy number of a high copy number mini-F plasmid was reduced in these mutant bacteria as compared with the wild type in the presence of excess RepE protein. Furthermore, mini-F plasmid mutants that produce altered initiator protein and exhibit a very high copy number were able to replicate in strains deficient in any of the above heat shock proteins. These results indicate that the subset of heat shock proteins (DnaK, DnaJ and GrpE) play essential roles that help the functioning of the RepE initiator protein in mini-F DNA replication.     

Overproduction of Gene Products by the Super-High-Copy-Number Plasmid pNR333

The plasmid pNR333 is a kanamycin-resistant, deletion derivative of pNR113 with an extremely high copy number in Escherichia coli and in Proteus mirabilis. In order to determine the usefulness of pNR333 as a replication gene of vector, the genes encoding chloramphenicol acetyltransferase (CAT) and β-galactosidase (β-gal) were cloned individually into both pNR333 and other low-copy-number plasmids. The expression of the cloned genes was compared by measuring the specific activity of each enzyme and the amounts of the proteins produced. A hybrid plasmid pNR333-cat expressed 53 times as much activity of CAT as the low-copy plasmid S-a which had a copy number of four. The lacZ gene cloned in pNR333 produced 17 times as much β-gal as in the low-copy-number plasmid pNR1150. These results suggest that pNR333 is a useful vector plasmid for producing a large amount of polypeptides in E. coli hosts.     

The Streptomyces ghanaensis low copy plasmid pSG2 and its use for vector construction

A plasmid, pSG2, was isolated from Streptomyces ghanaensis and characterized by electron microscopy, buoyant density measurement, and restriction enzyme analysis. The length of 13.8 kb, single restriction sites for HindIII, EcoRV and PvuII and the possibility of deleting non-essential regions of the plasmid made pSG2 a suitable basic replicon for vector development. pSG2 has a copy number of about four. Plasmid pSG2 was fused to a pACYC184 derivative modified to harbour a thiostrepton resistance gene. The resulting plasmid, designated pSW1, is a 16.6 kb shuttle plasmid which replicates in Escherichia coli and in several Streptomyces strains, including S. ghanaensis, S. lividans and S. viridochromogenes. Replacement of a Bg/II-fragment of plasmid pSG2 by a fragment encoding thiostrepton resistance resulted in a low copy 12.2 kb Streptomyces plasmid. This plasmid, designated pSW2, is a Streptomyces broad host range plasmid.     

The effect of the location of the proteic post-segregational stability system within the replicon of plasmid pTF-FC2 on the fine regulation of plasmid replication

The broad host-range IncQ-2 family plasmid, pTF-FC2, is a mobilizable, medium copy number plasmid that lacks an active partitioning system. Plasmid stability is enhanced by a toxin–antitoxin (TA) system known as pas (plasmid addiction system) that is located within the replicon between the repB (primase) and the repA (helicase) and repC (DNA-binding) genes. The discovery of a closely related IncQ-2 plasmid, pRAS3, with a completely different TA system located between the repB and repAC genes raised the question of whether the location of pas within the replicon had an effect on the plasmid in addition to its ability to act as a TA system. In this work we demonstrate that the presence of the strongly expressed, autoregulated pas operon within the replicon resulted in an increase in the expression of the downstream repAC genes when autoregulation was relieved. While deletion of the pas module did not affect the average plasmid copy number, a pas-containing plasmid exhibited increased stability compared with a pas deletion plasmid even when the TA system was neutralized. It is proposed that the location of a strongly expressed, autoregulated operon within the replicon results in a rapid, but transient, expression of the repAC genes that enables the plasmid to rapidly restore its normal copy number should it fall below a threshold.     

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

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 mutant's 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.     

Complete nucleotide sequence of pT181, a tetracycline-resistance plasmid from Staphylococcus aureus

pT181 is a naturally occurring Staphylococcus aureus plasmid, encoding inducible resistance to tetracycline. The plasmid has a copy number of about 20 per cell, and belongs to the incompatibility group inc3. The complete nucleotide sequence of pT181 has been determined and consists of 4437 bp. The nucleotide sequence contains 69.8% A-T and 30.2% G-C pairs. pT181 was found to contain four open reading frames capable of coding for polypeptides containing more than 50 amino acids. All the putative polypeptides are coded by one strand. The molecular weights of the four putative polypeptides are (in daltons): A, 37,500; B, 35,000; C, 23,000, and D, 18,000. Polypeptide A corresponds to the repC protein, earlier shown to be specifically required for pT181 replication. Polypeptide B (and possibly polypeptide D) are involved in tetracycline resistance. No role has yet been established for polypeptide C; deletion of the coding sequence for the C polypeptide has no detectable effect on any property of the pT181 plasmid. A region consisting of about 1200 bp contains information for the replication and copy number control of this plasmid. The sequencing results are discussed in relation to the replication properties and tetracycline resistance associated with the pT181 plasmid.     

Stability of plasmid pA387 derivatives in Amylcolatopsis mediterranei producing rifamycin

Genetic studies on the biosynthesis of rifamycins in producer strains such as Amylcolaptopsis mediterranei U-32 are severely hampered by the availability of efficient transformation procedures and stable plasmid vectors. Using an efficient electroporation procedure we have studied the replication and stability of a pA387 derivative, pDXM32. This plasmid confers enhanced plasmid stability and copy number compared to pA387 derivatives commonly used as cloning vectors in A. mediterranei. Deletion derivatives in the region previously identified as being a minimal replication origin were also examined with respect to their ability to transform A. mediterranei and at least one locus was essential for replication. A 5.4 kbp DNA fragment was sequenced and annotated encoding the replication and plasmid stability functions. A parA homologue was identified which is likely to confer plasmid stability.     

Construction,properties, and application of the pCB5 plasmid,a novel conjugative shuttle vector with a Cupriavidus basilensis origin of replication

Cupriavidus basilensis is a species with diverse metabolic capabilities, including degradation of xenobiotics and heavy metal resistance. Although the genomes of several strains of this species have been sequenced, no plasmid has yet been constructed for genetic engineering in this species. In this study, we identified a novel plasmid, designated pWS, from C. basilensis WS with a copy number of 1–3 per cell and a length of 2150 bp. pWS contained three protein-coding genes, among which only rep was required for plasmid replication. Rep showed no homology with known plasmid replication initiators. Unlike most plasmids, pWS did not have a cis-acting replication origin outside the region of rep. The minimal replicon of pWS was stable in C. basilensis WS without selection. A conjugative C. basilensis/Escherichia coli shuttle vector, pCB5, was constructed using the minimal replicon of pWS. Interestingly, the copy number of pCB5 was flexible and could be manipulated. Enhancing the expression level of Rep in pCB5 by either doubling the promoter or coding region of rep resulted in doubling of the plasmid copy number. Moreover, replacing the native promoter of rep with the lac promoter increased the copy number by over fivefold. Finally, using two different β-galactosidase reporting systems constructed with pCB5, we successfully demonstrated the different regulatory patterns of bph and dmp operons during diphenyl ether (DE) degradation in C. basilensis WS. Thus, this shuttle vector provided an efficient tool for DNA cloning and metabolic engineering in C. basilensis.