Rifampicin-resistant initiation of DNA synthesis on the isolated strands of ColE plasmid DNA.

The opposite strands of the ColE1 and ColE3 plasmids were isolated as circular single-stranded DNA molecules. These molecules were compared with M13 and phi X174 viral DNA with respect to their capacity to function as templates for in vitro DNA synthesis by a replication enzyme fraction from Escherichia coli. It was found for both ColE plasmids that the conversion of H as well as L strands to duplex DNA molecules closely resembles phi X174 complementary strand synthesis and occurs by a rifampicin-resistant priming mechanism involving the dnaB, dnaC, and dnaG gene products. Restriction analysis of partially double-stranded intermediates indicates that preferred start sites for DNA synthesis are present on both strands of the ColE1 HaeII-C fragment. Inspection of the nucleotide sequence of this region reveals structural similarities with the origin of phi X174 complementary strand synthesis. We propose that the rifampicin-resistant initiation site (rri) in the ColE1 L strand is required for the priming of discontinuous lagging strand synthesis during vegetative replication and that the rri site in the H strand is involved in the initiation of L strand synthesis during conjugative transfer.     

Effect of altering GATC sequences in the plasmid ColE1 primer promoter.

Plasmid ColE1 has three recognition sites for the Escherichia coli DNA adenine methylase in the immediate upstream region of the primer promoter. Two of these sites are conserved among all plasmid relatives of ColE1 and constitute parts of an inverted repeat that can conceivably form a cruciform structure. Recent experiments have indicated that hemimethylated ColE1-type plasmids are inefficiently replicated after transformation (D. W. Russell and N. Zinder, Cell 50:1071-1079, 1987). By mutating the three methylation sites, we found that disruption of all three GATC sites was necessary for complete relief of the hemimethylation-mediated inhibition of replication in vivo. We also found that these three methylation sites acted in a position-specific manner. The putative cruciform, if present, did not play a regulatory role in the hemimethylation-mediated inhibition of replication.     

Processing of plasmid DNA with ColE1-like replication origin

With the increasing utilization of plasmid DNA as a biopharmaceutical drug, there is a rapidly growing need for high quality plasmid DNA for drug applications. Although there are several different kinds of replication origins, ColE1-like replication origin is the most extensively used origin in biotechnology. This review addresses problems in upstream and downstream processing of plasmid DNA with ColE1-like origin as drug applications. In upstream processing of plasmid DNA, regulation of replication of ColE1-like origin was discussed. In downstream processing of plasmid DNA, we analyzed simple, robust, and scalable methods, which can be used in the efficient production of pharmaceutical-grade plasmid DNA.     

Equilibrium melting of plasmid ColE1 DNA: electron-microscopic visualization.

The fine structure of the melting curve for the linear colE1 DNA has been obtained. To find the ColE1 DNA regions corresponding to peaks in the melting curve's fine structure, we fixed the melted DNA regions with glyoxal /12/. Electron-microscopic denaturation maps were obtained for nine temperature points within the melting range. Thereby the whole process of colE1 DNA melting was reconstructed in detail. Spectrophotometric and electron microscopic data were used for mapping the distribution of Gc-pairs over the DNA molecule. The most AT-rich DNA regions (28 and 37% of GC-pairs), 380 and 660 bp long resp., are located on both sides of the site of ColE1 DNA's cleavage by EcoR1 endonuclease. The equilibrium denaturation maps are compared with maps obtained by the method of Inman /20/ for eight points of the kinetic curve of ColE1 DNA unwinding by formaldehyde.     

Adenosine monophosphate-induced amplification of ColE1 plasmid DNA in Escherichia coli

ColE1 plasmid copy number was analyzed in relaxed (relA) and stringent (relA(+)) Escherichia coli cells after supplementation of culture media with adenosine monophosphate (AMP). When a relaxed E. coli strain bearing ColE1 plasmid was cultured in LB medium for 18 h and induced with AMP for 4h, the plasmid DNA yield was significantly increased, from 2.6 to 16.4 mgl(-1). However no AMP-induced amplification of ColE1 plasmid DNA was observed in the stringent host. Some plasmid amplification was observed in relA mutant cultures in the presence of adenosine, while adenine, ADP, ATP, ribose, potassium pyrophosphate and sodium phosphate caused a minor, if any, increase in ColE1 copy number. A mechanism for amplification of ColE1 plasmid DNA with AMP in relA mutant bacteria is suggested, in which AMP interferes with the aminoacylation of tRNAs, increases the abundance of uncharged tRNAs, and uncharged tRNAs promote plasmid DNA replication. According to this proposal, in relA(+) cells, the AMP induction could not increase ColE1 plasmid copy number because of lower abundance of uncharged tRNAs. Our results suggest that the induction with AMP can be used as an effective method of amplification of ColE1 plasmid DNA in relaxed strains of E. coli.     

cea-kil operon of the ColE1 plasmid.

We isolated a series of Tn5 transposon insertion mutants and chemically induced mutants with mutations in the region of the ColE1 plasmid that includes the cea (colicin) and imm (immunity) genes. Bacterial cells harboring each of the mutant plasmids were tested for their response to the colicin-inducing agent mitomycin C. All insertion mutations within the cea gene failed to bring about cell killing after mitomycin C treatment. A cea- amber mutation exerted a polar effect on killing by mitomycin C. Two insertions beyond the cea gene but within or near the imm gene also prevented the lethal response to mitomycin C. These findings suggest the presence in the ColE1 plasmid of an operon containing the cea and kil genes whose product is needed for mitomycin C-induced lethality. Bacteria carrying ColE1 plasmids with Tn5 inserted within the cea gene produced serologically cross-reacting fragments of the colicin E1 molecule, the lengths of which were proportional to the distance between the insertion and the promoter end of the cea gene.     

A functional map of plasmid ColE1

Summary Examination of the properties of ColE1 derivatives containing either deletions or insertions of transposable genetic elements, has enabled a functional map of plasmid ColE1 to be constructed.     

Structural-functional analysis of the par-region of ColE1 plasmid

The DNA fragment identical to the right shoulder of the inverted repeat from the par-region of ColE1 plasmid has been synthesized chemically. It is shown to participate in the plasmid multimers resolution and to define the stable inheritance of the plasmid pKS1 containing the fragment in Escherichia coli C600 cells as well as in the multirecombinogenic strain Escherichia coli JC8679. The efficiency of the fragments functioning in Escherichia coli JC8679 is not enough for resolution of all forms of oligomeric pKS1 DNA. The site for recombinase action is found to be located in the synthesized oligonucleotide. However, some extra sequences of DNA located within the region of inverted repeat are necessary for maximally efficient functioning of the recombinase, the enzyme participating in plasmid multimers resolution.     

Effects of the presence of ColE1 plasmid DNA in Escherichia coli on the host cell metabolism

Background  

Although understanding of physiological interactions between plasmid DNA and its host is important for vector design and host optimization in many biotechnological applications, to our knowledge, global studies on plasmid-host interactions have not been performed to date even for well-characterized plasmids.     

Synthesis and repair of RNA-containing supercoiled plasmid ColE1 DNA in Escherichia coli

Supercoiled plasmid molecules sensitive to nicking by RNase or alkali have been shown to accumulate during replication of colicinogenic factor E1 (ColE1) in Escherichia coli in the presence of chloramphenicol. The possibility that this sensitivity is due to the covalent integration of RNA molecules during the synthesis of plasmid DNA is supported by the demonstration that (a) strands of supercoiled ColE1 newly replicated in the presence of chloramphenicol exhibit sensitivity to RNase and alkali treatment, while (b) RNase- and alkali-resistant circular strands of plasmid DNA synthesized either before or after the addition of chloramphenicol remain resistant during subsequent replication of the plasmid in the presence of chloramphenicol. Furthermore, newly made plasmid DNA strands cannot act as templates for further rounds of replication if they possess an RNA segment. The existence of a repair mechanism for the removal of the RNA segment from supercoiled ColE1 DNA molecules was demonstrated by pulse-chase experiments. It was observed that the proportion of RNase-sensitive molecules is considerably higher in pulse-labeled as compared to continuously labeled ColE1 DNA synthesized in the presence of chloramphenicol, and the proportion of pulse-labeled ColE1 DNA that is RNase sensitive is greatly reduced during a chase period. Removal of the RNA segment is also carried out effectively at the restrictive temperature in temperature-sensitive DNA polymerase I mutants. In a survey of other bacterial mutants defective in the repair of damaged DNA, a substantial increase in the rate of accumulation of RNase-and alkali-sensitive supercoiled ColE1 DNA in the presence of chloramphenicol was observed in recBC and uvrA mutants in comparison with the wild-type strains.