Boundaries of the Origin of Replication: Creation of a pET-28a-Derived Vector with p15A Copy Control Allowing Compatible Coexistence with pET Vectors

During our studies involving protein-DNA interactions, we constructed plasmid pSAM to fulfill two requirements: 1) to facilitate transfer of cloned sequences from widely used expression vector pET-28a(+), and 2) to provide a vector compatible with pBR322-derived plasmids for use in cells harboring two different plasmids. Vector pSAM is a pET-28a(+)-derived plasmid with the p15A origin of replication (ori); pET-28a(+) contains the pBR322 replicon that is incompatible with other pBR322-derived plasmids. By replacing the original pET-28a(+) replicon–comprising the ori, RNAI, RNAII, and Rom–with the p15A replicon, we generated pSAM, which contains the pET-28a(+) multiple cloning site and is now compatible with pBR322-derived vectors. Plasmid copy number was assessed using quantitative PCR: pSAM copy number was maintained at 18±4 copies per cell, consistent with that of other p15A-type vectors. Compatibility with pBR322-derived vectors was tested with pGEX-6p-1 and pSAM, which maintained their copy numbers of 49±10 and 14±4, respectively, when both were present within the same cell. Swapping of the ori is a common practice; however, it is vital that all regions of the original replicon be removed. Additional vector pSAMRNAI illustrated that incompatibility remains when portions of the replicon, such as RNAI and/or Rom, are retained; pSAMRNAI, which contains the intact RNAI but not ROM, lowered the copy number of pGEX-6p-1 to 18±2 in doubly transformed cells due to retention of the pET-28a(+)-derived RNAI. Thus, pSAMRNAI is incompatible with vectors controlled by the pBR322 replicon and further demonstrates the need to remove all portions of the original replicon and to quantitatively assess copy number, both individually and in combination, to ensure vector compatibility. To our knowledge, this is the first instance where the nascent vector has been quantitatively assessed for both plasmid copy number and compatibility. New vector pSAM provides ease of transferring sequences from commonly used pET-28a(+) into a vector compatible with the pBR322 family of plasmids. This essential need is currently not filled.     

Role of the rom protein in copy number control of plasmid pBR322 at different growth rates in Escherichia coli K-12

The copy number per cell mass of plasmid pBR322 and a rom- derivative was measured as a function of generation time. In fast growing cells the copy number per cell mass was virtually identical for rom+ and rom- derivatives. However, the copy number of pBR322 only increased 3- to 4-fold from a 20- to 80-min generation time, whereas the copy number of the rom- derivative increased 7- to 10-fold. The copy number stayed constant for the rom+ and rom- plasmids at generation times longer than 80-100 min. Thus, the presence of the rom gene decreased the copy number of plasmid pBR322 in slowly growing cells at least 2-fold when compared with the rom- plasmid. To study the effect of the rom gene in trans we cloned the gene into the compatible P15A-derived rom- plasmid pACYC184. In cells carrying both pACYC184 rom+ and pBR322 rom- the presence of the rom gene in trans had little effect on the copy number of pBR322 rom- at fast growth, but it decreased its copy number at slow growth to the same level as found for pBR322, i.e., complemented the pBR322 rom- plasmid. The pACYC184 plasmid and its rom+ derivatives showed copy numbers similar to those of pBR322 rom- and pBR322 itself, respectively, at fast and slow growth. We conclude that the rom gene product-the Rom protein-is an important element in copy number control of ColE1-type plasmids especially in slowly growing cells.     

A family of arabinose-inducible Escherichia coli expression vectors having pBR322 copy control

The pBAD series of expression vectors have been widely used in Escherichia coli, Salmonella enterica, and related bacteria. However, a complication with pBAD24, the most popular of these plasmids, is that it does not contain the complete functional replication origin of pBR322 as was depicted in the original paper. Instead, pBAD24 has a pBR322-derived origin that lacks the rop gene that negatively regulates copy number and thus pBAD24 has an appreciably higher copy number than that of pBR322, particularly at elevated growth temperatures. A rop-containing derivative of pBAD24 (called pBAD322) having the copy number of pBR322 is reported together with derivatives of pBAD322 that encode resistance to chloramphenicol, kanamycin, tetracycline, spectinomycin/streptomycin, gentamycin, or trimethoprim in place of ampicillin.     

Incompatibility mutants of IncFII plasmid NR1 and their effect on replication control

DNA from the replication control region of plasmid NR1 or of the Inc- copy mutant pRR12 was cloned into a pBR322 vector plasmid. These pBR322 derivatives were mutagenized in vitro with hydroxylamine and transformed into Escherichia coli cells that harbored either NR1 or pRR12. After selection for the newly introduced pBR322 derivatives only, those cells which retained the unselected resident NR1 or pRR12 plasmids were examined further. By this process, 134 plasmids with Inc- mutations in the cloned NR1 or pRR12 DNA were obtained. These mutants fell into 11 classes. Two of the classes had plasmids with deletions or insertions in the NR1 DNA and were not examined further. Plasmids with apparent point mutations were classified by examining (i) their ability to reconstitute a functional NR1-derived replicon (Rep+ or Rep-), (ii) the copy numbers of the Rep+ reconstituted replicons, (iii) the cross-reactivity of incompatability among the various mutant classes and parental plasmids, and (iv) the trans effects of the mutants on the copy number and stable inheritance of a coresident plasmid.     

Absolute and relative QPCR quantification of plasmid copy number in Escherichia coli

Real-time QPCR based methods for determination of plasmid copy number in recombinant Escherichia coli cultures are presented. Two compatible methods based on absolute and relative analyses were tested with recombinant E. coli DH5alpha harboring pBR322, which is a common bacterial cloning vector. The separate detection of the plasmid and the host chromosomal DNA was achieved using two separate primer sets, specific for the plasmid beta-lactamase gene (bla) and for the chromosomal d-1-deoxyxylulose 5-phosphate synthase gene (dxs), respectively. Since both bla and dxs are single-copy genes of pBR322 and E. coli chromosomal DNA, respectively, the plasmid copy number can be determined as the copy ratio of bla to dxs. These methods were successfully applied to determine the plasmid copy number of pBR322 of E. coli host cells. The results of the absolute and relative analyses were identical and highly reproducible with coefficient of variation (CV) values of 2.8-3.9% and 4.7-5.4%, respectively. The results corresponded to the previously reported values of pBR322 copy number within E. coli host cells, 15-20. The methods introduced in this study are convenient to perform and cost-effective compared to the traditionally used Southern blot method. The primer sets designed in this study can be used to determine plasmid copy number of any recombinant E. coli with a plasmid vector having bla gene.     

Construction and characterization of new cloning vehicles V. Mobilization and coding properties of pBR322 and several deletion derivatives including pBR327 and pBR328

A DNA sequence essential for the R64drd11 + ColK-mediated conjugal transfer of pBR322 has been located in a 540 bp HaeIII fragment (HaeIII-2) between the vegetative origin of replication and the tetracycline resistance (Tc^r) gene of this vector. The pBR322 derivatives pBR327 and pBR328 lack this DNA sequence and are not mobilized by conjugation. Two derivatives of pBR328 were constructed by re-inserting the HaeIII-2 fragment in both orientations into the chloramphenicol-resistance gene of the same vector. One orientation of the HaeIII-2 fragment permitted mobilization by conjugation while the opposite orientation prevented mobilization. Further examination of pBR322 and derivatives revealed that the region between the origin of replication and Tc^r gene also plays a role in regulating plasmid copy number.     

Analysis of pBR322 replication kinetics and its dependency on growth rate

Accurate estimates of plasmid copy number in a cell are a prerequisite for predicting plasmid stability and protein production. A refined version of a structured model for the pBR322 plasmid replication mechanism is described. The model is capable of accurately predicting pBR322 plasmid copy number in Escherichia coli B/r for a wide range of growth rates. The refinements include better estimates of promoter strength, the degradation rate of RNA species, binding constant of RNAI-RNAII reaction, and dependency of promoter strength on growth rate. The predictions of the model are verified by recent experimental observations but differ from some previous reports. This model can also be used to predict the binding constant of the RNAI-RNAII reaction of ColE1 type plasmids. At 37 degrees C, the binding constant is estimated to be 77 +/- 11 x 10(-13) mL/molecule-h for pBR322.     

New runaway-replication-plasmid cloning vectors and suppression of runaway replication by novobiocin

Two new cloning vectors (pBEU28 and pBEU50) with temperature-controlled runaway-replication properties are described. pBEU28 is similar to aphA+ (KanR) plasmid pBEU2 but lacks a 1.8-kb duplication which is responsible for plasmid instability. pBEU50 is an analog of pBR313 and pBR322 in that it carries bla+(AmpR), which can be used for selection, and tet+(TetR) which can be inactivated by cloning at HindIII and BamHI restriction sites. Sublethal concentrations of novobiocin were exploited to suppress runaway replication and to restore the viability of the plasmid carriers. By this method copB deletion mutants of two temperature-controlled, conditional runaway-replication plasmids were detected and isolated. The unconditional runaway-replication property of these plasmids leads us to hypothesize that there are at least two controls of plasmid R1 copy number and that the copB-dependent control is temperature-sensitive in the conditional runaway replication mutants. The novobiocin suppression of the runaway replication permitted us to clone dnaN+ on pBEU28 and to identify its presence at 42 degrees C with a dnaN59 transformation recipient which was temperature-sensitive due to a defect in the dnaN gene.     

The minimal replicon of a Streptomycete plasmid produces an ultrahigh level of plasmid DNA

A functional map of Streptomyces coelicolor plasmid SCP2* was deduced from derivatives constructed by in vitro deletions. Functions were analyzed on bifunctional shuttle plasmids that contained pBR322 for selection and replication in Escherichia coli and fragments of SCP2* for replication in Streptomyces griseofuscus C581 and strains of Streptomyces lividans. The aph gene for neomycin resistance from Streptomyces fradiae and the tsr gene for thiostrepton resistance from Streptomyces azureus were incorporated as selectable antibiotic resistance markers in streptomycetes. An 11.8-kb sequence bounded by EcoRI and KpnI restriction sites contains the information for self-transfer and normal replication of the plasmid. A 5.9-kb EcoRI-SalI fragment contains all of the information for normal replication. Partial digestion generated a 2.2-kb Sau3A fragment that is sufficient for replication but it produces ten times higher plasmid copy number than the basic replicon. pHJL400 and PHJL401 are useful shuttle vectors containing the moderate-copy-number streptomycete plasmid combined with the E. coli plasmid pUC19. A 1.4-kb BclI-Sau3A fragment with an additional internal BclI site contains the minimal replicon but it produces 1000 times higher plasmid copy number than the basic replicon. pHJL302 is a useful shuttle vector containing the ultrahigh-copy-number streptomycete plasmid combined with the E. coli plasmid pUC19.     

Cloning of cysE gene of Escherichia coli with a mini-Mu-lac containing a plasmid replicon

The restriction map of cysE gene of Escherichia coli was established after cloning a mini-Mu-lac bacteriophage containing a plasmid replicon and recloning on pBR322 vector plasmid. Enzyme assays of transformants indicated the lack of autoregulation of cysE gene.     

The function of the tet gene in the plasmid pBR322 is not inhibited by expression of an anti-tet gene

The possibility of gene suppression by the expression of anti-sense sequences has been tested for tet gene of pBR322 plasmid. Anti-tet gene has been inserted into lac-promoter regulated site of M13mp 10 single-stranded high copy phage vector. To achieve that, HihdIII-BamHI fragment of pBR322 carrying part of the tet gene was inserted into poly-linker of mp 10. The influence of the anti-tet gene expression on growth parameters of cells with or without tetracycline in the growth media was monitored for JM103 cells. The results indicate that in this system the detectable suppression of the tet gene by anti-tet expression was not manifested.     

The incompatibility product of IncFII R plasmid NR1 controls gene expression in the plasmid replication region.

The incompatibility properties of IncFII R plasmid NR1 were compared with those of two of its copy number mutants, pRR12 and pRR21. pRR12 produced an altered incompatibility product and also had an altered incompatibility target site. The target site appeared to be located within the incompatibility gene, which is located more than 1,200 base pairs from the plasmid origin of replication. The incompatibility properties of pRR21 were indistinguishable from those of NR1. Lambda phages have been constructed which contain the incompatibility region of NR1 or of one of its copy mutants fused to the lacZ gene. In lysogens constructed with these phages, beta-galactosidase was produced under the control of a promoter located within the plasmid incompatibility region. Lysogens containing prophages with the incompatibility regions from pRR12 and pRR21 produced higher levels of beta-galactosidase than did lysogens containing prophages with the incompatibility region from the wild-type NR1. The introduction into these inc-lac lysogens of pBR322 plasmids carrying the incompatibility regions of the wild-type or mutant plasmids resulted in decreased levels of beta-galactosidase production. For a given lysogen, the decrease was greater when the pBR322 derivative expressed a stronger incompatibility toward the plasmid from which the fragment in the prophage was derived. This suggested that the incompatibility product acts on its target to repress gene expression in the plasmid replication region.     

A missense mutation in the rpoC gene affects chromosomal replication control in Escherichia coli.

An RNA polymerase mutant with a single-base-pair change in the rpoC gene affects chromosome initiation control. The mutation, which is recessive, is a G to A transition leading to the substitution of aspartate for glycine at amino acid residue 1033 in the RNA polymerase beta' subunit. The chromosome copy number is increased twofold in the mutant at semipermissive growth temperatures (39 degrees C). In a delta oriC strain, in which chromosome initiation is governed by an F replicon, chromosome copy number is not affected. Plasmid pBR322 copy number is also increased in the mutant at 39 degrees C. The mutation causes a more than fivefold increased expression of the dnaA gene at 39 degrees C. It is conceivable that it is this high DnaA concentration which causes the high chromosome copy number and that the mutant RNA polymerase beta' subunit exerts its effect by altering the expression of the dnaA gene. However, other factors must be affected as well to explain why the RNA polymerase mutant can grow in a balanced fashion with a high chromosome concentration. This is in contrast to wild-type cells, which exhibit higher origin concentrations when DnaA protein is overproduced, but in which the overall DNA concentration is only moderately affected.     

Effects of genes exerting growth inhibition and plasmid stability on plasmid maintenance.

Plasmid stabilization mediated by the parA+ and parB+ genes of the R1 plasmid and the ccd+ and sop+ genes of the F plasmid was tested on a mini-R1 plasmid and a pBR322 plasmid derivative. The mini-R1 plasmid is thought to be unstably inherited owing to a low copy number and to random segregation of the plasmid at cell division, whereas cells harboring the pBR322 derivative used in this work are lost through competition with plasmid-free cells, mainly as a result of the shorter generation time of cells without plasmids. The pBR322 derivative carries a fusion between part of the atp operon of Escherichia coli and the bacteriophage lambda pR promoter, and the cI857 repressor gene. The insertion of sop+ from the F plasmid or parB+ from the R1 plasmid reduced the loss frequency by a factor of 10(3) for the pBR322 derivative and by at least a factor of 10(2) for the mini-R1 plasmid. Insertion of parA+ from the R1 plasmid decreased the loss frequency of the pBR322 derivative by a factor of 10 and that of the mini-R1 plasmid by a factor of 50. When ccd+ from the F plasmid was inserted, the loss frequency of the pBR322 derivative was decreased by a factor of 10, but it had only a marginal effect on the stability of the mini-R1 plasmid. In no case was any significant structural instability of the plasmids observed.