Isolation and characterization of replication-deficient mutants of ColE1 plasmids.

Replication-defective mutants of plasmid ColE1 were isolated from a chimeric plasmid formed by ligating a temperature-sensitive replication derivative of pSC101, pHSG1, with a ColE1-Tn3-containing plasmid. The replication-defective ColE1 mutants isolated were all spontaneous deletion mutants that had lost the ColE1 replication origin and regions adjacent to it. The extent of a deletion was determined by analyzing restriction endonuclease-generated deoxyribonucleic acid fragments of the ColE1 plasmid component of the chimeras by both agarose and polyacrylamide gel electrophoresis. None of the chimeras containing the replication-defective ColE1 mutants was able to replicate in the presence of chloramphenicol. The expression of ColE1 incompatibility was either markedly reduced or not detectable in the replication mutants isolated.     

Control of plasmid incompatibility: characteristics of the bireplicon hybrid pAS8 and its deletion mutants]

The phenomenon of incompatibility has been investigated using deletion mutants of hybrid bireplicon plasmid pAS8. The hybrid pAS8 displays incompatibility specific for both components of its structure. In contrast to P-specificity of pAS8, functions of ColE1-specificity are not effectively expressed. Expression of ColE1-specificity in pAS8 plasmid and its derivatives is characterized by different directions and this is due to the presence or absence of genes of RP4 replication machinery in the plasmid DNA. Mutant plasmids show different efficiency of P-specificity depending on the extension of deletion in the region of essential genes of the RP4 component. Some of the mutants, in spite of the loss of replication genes, including origin of vegetative replication, are incompatible with the representatives of the Inc P group in both directions of testing. Different character and the level of expression of ColE1- and P-specificity in the pAS8 hybrid and its deletion derivatives are not associated with change in the number of plasmid DNA copies, for all of them are subjects to stringent control of replication. The data suggest the existence of incompatibility functions control mechanism which does not seem to include replication genes. Possible ways of realization of the inc genes functions are discussed.     

Regions of homology in small colicinogenic plasmids

Restriction maps have been constructed for the colicinogenic plasmids (ColA, ColD, and ColK. Their regions of homology with the ColE1 plasmid and its deletion derivative pAO3 carrying the region responsible for autonomous replication of ColE1 plasmid were determined by means of blotting hybridization and heteroduplex analysis. The plasmids ColA, ColD, and ColK were shown to contain DNA fragments homologous to the region of ColE1 involved in the regulation of replication.     

Structural and functional organization of ColE2 and ColE3 replicons

Summary The complete nucleotide sequences of the 1.5 kb regions of ColE2 and ColE3 plasmids containing the segments sufficient for autonomous replication have been determined. They are quite homologous (greater than 90%), indicating that these two plasmids share common mechanisms of initiation of replication and its regulation. An open reading frame with a coding capacity for a protein of about 300 amino acids is present in both ColE2 and ColE3 and it actually specifies the Rep (for replication) protein, which is the plasmid specific trans-acting factor required for autonomous replication. The amino acid sequences of the Rep proteins of ColE2 and ColE3 are quite homologous (greater than 90%). The cis-acting sites (origins) where replication initiates in the presence of the trans-acting factors consist of 32 bp for ColE2 and 33 bp for ColE3. They are the smallest of all the prokaryotic replication origins so far reported. They are nonhomologous only at two positions, one of which, a deletion of a single nucleotide in ColE2 (or an insertion in ColE3), determines the plasmid specificity in interaction of the origins with the Rep proteins. Both plasmids carry a region with an identical nucleotide sequence and the one in ColE2, the IncA region, has been shown to express incompatibility against both ColE2 and ColE3. These results indicate that these plasmids share a common IncA determinant. A possibility that a small antisense RNA is involved in copy number control and incompatibility (IncA function) was suggested.     

ColE1 plasmid incompatibility: localization and analysis of mutations affecting incompatibility.

Deletion mutants of plasmid ColE1 that involve the replication origin and adjacent regions of the plasmid have been studied to determine the mechanism by which those mutations affect the expression of plasmid incompatibility. It was observed that (i) a region of ColE1 that is involved in the expression of plasmid incompatibility lies between base pairs -185 and -684; (ii) the integrity of at least part of the region of ColE1 DNA between base pairs -185 and -572 is essential for the expression of ColE1 incompatibility; (iii) the expression of incompatibility is independent of the ability of the ColE1 genome to replicate autonomously; (iv) plasmid incompatibility is affected by plasmid copy number; and (v) ColE1 plasmid-mediated DNA replication of the lambda phage-ColE1 chimera lambda imm434 Oam29 Pam3 ColE1 is inhibited by ColE1-incompatible but not by ColE1-compatible plasmids.     

Isolation and characterization of pHW15, a small cryptic plasmid from Rahnella genomospecies 2

A small cryptic plasmid designated pHW15 was isolated from Rahnella genomospecies 2 WMR15 and its complete nucleotide sequence was determined. The plasmid contained 3002 bp with a G+C content of 47.4%. The origin of replication was identified by deletion analysis as a region of about 600 bp. This region had an identity of 70% to the replication origin of the ColE1 plasmid at the nucleotide level. Sequence analysis revealed the typical elements: RNA I, RNA II and their corresponding promoters, a sequence allowing hybridisation of RNA II to the DNA and favouring processing by RNaseH, a single-strand initiation determinant (ssi) that allows initiation of lagging-strand synthesis, and a terH sequence required for termination of lagging-strand synthesis. The plasmid contained three expressed open reading frames, one of which showed homology to a ColE1 plasmid-encoded protein. Furthermore, a multimer resolution site was identified by sequence analysis. Its deletion resulted in formation of plasmid multimers during growth leading to an increased plasmid loss rate.     

pUb6060: a broad-host-range, DNA polymerase-I-independent ColE2-like plasmid

A ColE2-like, cryptic plasmid, pUB6060, of 5.8 kb has been found in a clinical isolate of Plesiomonas shigelloides. The complete sequence of pUB6060 has been determined and reveals a number of interesting features about the plasmid. The ColE2-like replication locus is linked to a functional ColE1-like mobilization locus. Replication is, unusually for ColE2 replicons, DNA polymerase-I-independent and may involve two, rather than the usual one, plasmid-encoded functions. Additionally, it carries two ORFs encoding products of unknown function. The pUB6060 replicon maintains a moderate plasmid copy number (10 per chromosome copy) and permits replication in diverse gram-negative bacteria.     

Characteristics of replication of small colicinogenic plasmids

Specificity of small multicopy colicinogenic plasmids ColA, ColD, ColE2 and ColK replication has been compared with the one of ColE1 plasmid. Copy number for these plasmids per host cell has been estimated under the normal conditions of cellular growth and under the conditions of chloramphenicol-inhibited growth. DNA polymerase I and dnaB protein, an obligatory component for elongation step in replication, have been shown to be necessary for the plasmids replication. Initiation of plasmids replication has been demonstrated to be independent of dnaA and dnaC proteins. Replication of plasmid ColE2, being similar in its main features to replication of other plasmids from this group, has an important distinction. It requires de novo protein synthesis implying that ColE2 replicon may be different from ColA, ColD, ColK, ColE1 replicons. Thus study of the inducible A, D, K, El colicin synthesis coded by the corresponding plasmids has revealed the similarity regulation of genes, determining the synthesis of each of the mentioned colicins.     

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.     

The effect of dnaA protein and n' sites on the replication of plasmid ColE1

The role of the dna A protein in the replication of plasmid ColE1 and its derivatives was examined. Wild-type and mutant ColE1 plasmids were compared as to their ability to replicate in an in vitro replication system supplemented with ammonium sulfate fractionated extracts from a dnaA-overproducing strain. Synthesis on plasmid templates containing the wild-type origin of replication was stimulated 1.3-fold by addition of the dnaA-overproducing extract. A larger effect was observed after deletion of the primosome assembly site, the n' site, on the leading strand. On the latter template, synthesis was only about one-half that observed with the wild-type templates, but synthesis could be restored to normal levels by addition of the dnaA-overproducing fractions. When the n' site on the lagging strand of pBR322 was deleted, synthesis in the in vitro replication system was reduced to less than 10% of levels seen with intact templates. dnaA-overproducing extract did not restore activity since the dnaA site was also deleted on these plasmids. To verify that the observed stimulation of wild-type and leading strand n' site mutants was due to the dnaA protein, dnaA protein was purified to greater than 50% homogeneity, and antiserum was prepared. The purified protein stimulated synthesis on the plasmid templates to the same extent as the overproducing extracts, and dnaA antiserum blocked stimulation both by extracts and by the purified protein. Thus, dnaA protein, and, by inference, the dnaA recognition site at the ColE1 origin of replication seem to be important for ColE1 replication. The effect of dnaA protein is enhanced when the n'site is defective, suggesting that the dnaA protein plays a role similar to that of the proteins i, n, n', and n' in directing primosome assembly, as proposed by Seufert, W., and Messer, W. ((1987) Cell 48, 73-78).     

Characterization of an F18+ enterotoxigenic Escherichia coli strain from post weaning diarrhoea of swine, and of its conjugative virulence plasmid pTC

The enterotoxigenic Escherichia coli (ETEC) strain Ec2173, causing post weaning diarrhoea in swine, harbours six plasmids ranging from 13 to 200 kb in size. The heat stable toxin genes sta, stb and a tetracycline resistance gene were located on a self conjugative 120-kb plasmid, called pTC. In the cloned ColE1 type origin of replication of pTC a deletion was detected compared to other ColE1 replicons affecting the replication modulator gene rom. Epidemiological studies on ETEC isolates showed that pTC-like plasmids are widely distributed among porcine ETEC strains; thus representing an example of co-evolution of antibacterial resistance and virulence in pathogenic E. coli.     

Nature of the compatible inheritance of hybrid plasmid pAS8 and its deletion mutants with replicon ColE1]

Hybrid plasmid pAS8, that consists of RP4 and ColE1 replicons, is incompatible with RP4 but co-exists with ColE1 replicon. The deletion mutants of pAS8, that replicates under the control of ColE1 replicon only, are incompatible with ColE1 derivatives, although the copy number of pAS8 and its deletion mutants in the cell is the same (1-3 per the chromosome). Incompatibility effect of plasmids is expressed in a sharp decrease in transformant's yield during selection of incoming and resident plasmids markers. In this case incompatibility is a very fast process, that leads to the elimination of resident or incoming plasmid just before plating on the selective medium. On the base of negative control theory, the repressors yield, synthesized in the presence of 1-3 copies of the deletion mutant is enough for the expression of ColE1-specific incompatibility. This ColE1 incompatibility is probably connected with the functional activity of ColE1 replicon. When ColE1 factor replicates under the control of RP4 replicon the expression of ColE1-specific incompatibility does not occur. Possibly, the incompatibility effect takes place when pAS8 deletion mutants cause the synthesis of ColE1-specific repressor. Also, the replicons of ColE1 may competein the membrane attachment site.     

Effect of Inhibitors of Ribonucleic Acid and Protein Synthesis on the Cyclic Adenosine Monophosphate Stimulation of Plasmid ColE1 Replication

Addition of cyclic adenosine 3'-5'-monophosphate (c-AMP) to growing Escherichia coli cells, colicinogenic for the plasmid ColE1, results in a fourfold stimulation in the rate of synthesis of the plasmid deoxyribonucleic acid (DNA). The stimulation is transient (30 min) and is succeeded by a brief period (30 min) of cessation of plasmid DNA replication. The stimulation of ColE1 DNA replication also occurs in chloramphenicol-treated cells. Rifampin inhibits ColE1 DNA replication in the presence or absence of c-AMP. Employing thymine starvation conditions to stop ColE1 DNA synthesis, it was found that c-AMP, added during the period of thymine starvation, effected a stimulation in the amount of subsequent replication which took place when replicating conditions were restored. The stimulatory effect of c-AMP under these conditions was not prevented by chloramphenicol but was completely eliminated when rifampin was present. Under these conditions, when rifampin was added after the effect of c-AMP was allowed to occur, subsequent replication of the plasmid could take place, but only one round of replication occurred. A model to account for the c-AMP effects is presented.     

Construction and characterization of amplifiable multicopy DNA cloning vehicles derived from the P15A cryptic miniplasmid.

Construction and characterization of a class of multicopy plasmid cloning vehicles containing the replication system of miniplasmid P15A are described. The constructed plasmids have cleavage sites within antibiotic resistance genes for a variety of commonly employed site-specific endonucleases, permitting convenient use of the insertional inactivation procedure for the selection of clones that contain hybrid DNA molecules. Although the constructed plasmids showed DNA sequence homology with the ColE1 plasmid within the replication region, were amplifiable by chloramphenicol or spectinomycin, required DNA polymerase I for replication, and shared other replication properties with ColE1, they were nevertheless compatible with ColE1. P15A-derived plasmids were not self-transmissible and were mobilized poorly by Hfr strains; however, mobilization was complemented by the presence of a ColE1 plasmid within the same cell.     

Effect of Growth Conditions on the Formation of the Relaxation Complex of Supercoiled ColE1 Deoxyribonucleic Acid and Protein in Escherichia coli

Colicinogenic factor E1 (ColE1) is present in Escherichia coli strain JC411 (ColE1) cells to the extent of about 24 copies per cell. This number does not appear to vary in situations which give rise to twofold differences in the amount of chromosomal deoxyribonucleic acid (DNA) present per cell. If cells are grown in the absence of glucose, approximately 80% of the ColE1 molecules can be isolated as strand-specific DNA-protein relaxation complexes. When glucose is present in the medium, only about 30% of the plasmid molecules can be isolated as relaxation complexes. Medium shift experiments in which glucose was removed from the medium indicate that within 15 min after the shift the majority (>60%) of the plasmid can be isolated as relaxation complex. This rapid shift to the complexed state is accompanied by a two- to threefold increase in the rate of plasmid replication. The burst of replication and the shift to the complexed state are both inhibited by the presence of chloramphenicol. Inhibition of protein synthesis in log cultures by the addition of chloramphenicol or amino acid starvation allows ColE1 DNA to continue replicating long after chromosomal replication has ceased. Under these conditions, noncomplexed plasmid DNA accumulates while the amount of DNA that can be isolated in the complexed state remains constant at the level that existed prior to treatment. In the presence of chloramphenicol, there appears to be a random dissociation and association of ColE1 DNA and “relaxation protein” during or between rounds of replication.     

Re-examination of the ColE1 DNA regions essential for autonomous replication and their functions

Starting from pAO3, a plasmid consisting of a quarter of colicinogenic factor E1 (ColE1) DNA, various small ColE1 derivatives were constructed by in vitro recombination and their ability to achieve autonomous replication was examined. The 436 base pair HaeIII-C fragment of pAO3 contained information for replication when it was recombined with the non-replicating Amp fragment. However, when it was connected to other DNA fragments, the resulting hybrid molecules were not isolated as plasmids. The present results indicate that the additional region of about 240 base pairs next to the HaeIII-C fragment of ColE1 is also essential for the maintenance of a plasmid state. Moreover, using various small ColE1 derivatives, the DNA region responsible for the interference and incompatibility functions of ColE1 DNAs was located. The results indicate that the interference and incompatibility functions are coded by the same ColE1 DNA segment and are not essential for the maintenance of a plasmid state.