pUB2380: characterization of a ColD-like resistance plasmid

A detailed analysis of the mobilizable, ColE1-like resistance plasmid, pUB2380, is reported. The 8.5-kb genome encodes six (possibly seven) major functions: (1) a ColD-like origin of replication, oriV, with associated replication functions, RNAI and RNAII; (2) a set of active mobilization functions highly homologous to that of ColE1, including the origin of transfer, oriT; (3) a ColE1-like multimer resolution site (cer); (4) a kanamycin-resistance determinant, aph, encoding an aminoglycoside-3'-phosphotransferase type 1; (5) an insertion sequence, IS1294; and (6) two genes, probably cotranscribed, of unknown function(s). The GC content of the various parts of the genome indicates that the plasmid is a hybrid structure assembled from DNA from at least three different sources, of which the replication region, the mobilization functions, and the resistance gene are likely to have originated in the enterobacteriaceae.     

Suppression of Co1E1 replication properties by the Inc P-1 plasmid RK2 in hybrid plasmids constructed in vitro.

Hybrid plasmids were constructed in vitro by linking the Inc P-1 broad host range plasmid RK2 to the colicinogenic plasmid ColE1 at their EcoRI endonuclease cleavage sites. These plasmids were found to be immune to colicin E1, non-colicin-producing, and to exhibit all the characteristics of RK2 including self-transmissibility. These joint replicons have a copy number of 5 to 7 per chromosome which is typical of RK2, but not ColE1. Unlike ColE1, the plasmids will not replicate in the presence of chloramphenicol and are maintained in DNA polymerase I mutants of Escherichia coli. In addition, only RK2 incompatibility is expressed, although functional ColE1 can be rescued from the hybrids by EcoRI cleavage. This suppression of ColE1 copy number and incompatibility was found to be a unique effect of plasmid size on ColE1 properties. However, the inhibition of ColE1 or ColE1-like plasmid replication in chloramphenicol-treated cells is a specific effect of RK2 or segments of RK2 (Cri⁺ phenotype). This phenomenon is not a function of plasmid size and requires covalent linkage of RK2 DNA to ColE1. A specific region of RK2 (50.4 to 56.4 × 10³ base-pairs) cloned in the ColE1-like plasmid pBR313 was shown to carry the genetic determinant(s) for expression of the Cri⁺ phenotype.     

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.     

A model for regulation of ColE1-like plasmid replication by uncharged tRNAs in amino acid-starved Escherichia coli cells

It has been previously observed that various ColE1-like plasmids replicate differentially in Escherichia coli cells during the relaxed response to amino acid starvation. Here we develop a kinetic model to explain these observations based on the possibility of interaction of the 3' CCA-OH sequence with the UGG triplets in loops of RNA I and RNA II encoded by ColE1-like plasmids. According to our model, when the interaction of uncharged CCA with RNA I is possible, the replication of the ColE1-like plasmid is affected by differences in the concentration of various tRNAs in the starved cell, but it is not affected by the tRNA concentration if the hypothetical pairing occurs between the CCA-OH and RNA II. Using the previously determined parameters for the pBR322 plasmid, the concentration of uncharged tRNAs in the amino acid starved relaxed strains and the assumed efficiency of binding of tRNA and RNA I, we show that our model explains the differences in pBR322 copy number in the relaxed strain starved for several amino acids.     

A DNA sequence outside the pUB110 minimal replicon is required for normal replication in Bacillus subtilis.

The origin of lagging strand synthesis in pUB110, oriL, has been localized within 140 bases outside the pUB110 minimal replicon. The oriL DNA sequence is a cis-acting and orientation dependent determinant required for normal plasmid replication. Rearrangements affecting oriL cause plasmid instability, lead to the accumulation of replication intermediates and result in a marked reduction of the plasmid copy number in some recombination deficient mutant strains. In addition, deletion of oriL triggers a dnaB-dependent mode of replication. Insertion of the functionally asymmetric oriL region in the proper orientation into pC194 reduces the accumulation of single-stranded DNA during the replication of this plasmid.     

Replication Control and Switch-Off Function as Observed with a Mini-F Factor Plasmid

Mini-F is a fragment of the F plasmid, consisting of 9,000 base pairs, which carries all of the genes and sites required for replicon maintenance and control. Its copy number is one to two per chromosome. This plasmid is joined to ColE1, whose copy number is 16 to 20. Under normal circumstances the composite plasmid replication exhibited ColE1 characteristics, maintaining a high copy number. However, when ColE1 replication was inhibited by deoxyribonucleic acid polymerase I inactivation, its replication exhibited mini-F characteristics, maintaining a low copy number. These observations are in complete agreement with those of Timmis et al. (Proc. Natl. Acad. Sci. U.S.A. 71:4556-4560, 1974), who examined the behavior of a recombinant plasmid formed between pSC101 and ColE1. The transition from high to low copy number allowed us to examine the control system acting in cells carrying plasmids exhibiting intermediate copy numbers. The initiation of the mini-F replication system as represented by deoxyribonucleic acid synthesis of the composite plasmid was completely blocked when there were multiple copies of mini-F in a cell. It was not restored until the copy number was lowered to one to two, after which replication was first detected. ppF, a mini-F replicon packaged in a phage λ head behaved similarly: its replication was completely shut off when the resident mini-F genome copy number was high and was inhibited partially when the resident mini-F genome copy number was low. These experiments clearly demonstrate that there is a switch-off mechanism acting on deoxyribonucleic acid synthesis (initiation) in a cell carrying mini-F, and its intensity is related to the plasmid copy number. This result supports the “inhibitor dilution model” proposed by Pritchard et al. (Symp. Soc. Gen. Microbiol. 19:263-297, 1969). The nature of the hypothetical inhibitor is discussed.     

Molecular clocks reduce plasmid loss rates: the R1 case

Plasmids control their replication so that the replication frequency per plasmid copy responds to the number of plasmid copies per cell. High sensitivity amplification in replication response to copy number deviations generally reduces variation in copy numbers between different single cells, thereby reducing the plasmid loss rate in a cell population. However, experiments show that plasmid R1 has a gradual, insensitive replication control predicting considerable copy number variation between single cells. The critical step in R1 copy number control is regulation of synthesis of a rate-limiting cis-acting replication protein, RepA. De novo synthesis of a large number of RepA molecules is required for replication, suggesting that copy number control is exercised at multiple steps. In this theoretical kinetic study we analyse R1 multistep copy number control and show that it results in the insensitive replication response found experimentally but that it at the same time effectively prohibits the existence of only one plasmid copy in a dividing cell. In combination with the partition system of R1, this can lead to very high segregational stability. The R1 control mechanism is compared to the different multistep copy number control of plasmid ColE1 that is based on conventional sensitivity amplification. This implies that while copy number control for ColE1 efficiently corrects for fluctuations that have already occurred, R1 copy number control prevents their emergence in cells that by chance start their cycle with only one plasmid copy. We also discuss how regular, clock-like, behaviour of single plasmid copies becomes hidden in experiments probing collective properties of a population of plasmid copies because the individual copies are out of phase. The model is formulated using master equations, taking a stochastic approach to regulation, but the mathematical formalism is kept to a minimum and the model is simplified to its bare essence. This simplicity makes it possible to extend the analysis to other replicons with similar design principles.     

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.     

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.     

Suppression of ColE1 high-copy-number mutants by mutations in the polA gene of Escherichia coli.

We isolated three Escherichia coli suppressor strains that reduce the copy number of a mutant ColE1 high-copy-number plasmid. These mutations lower the copy number of the mutant plasmid in vivo up to 15-fold; the wild-type plasmid copy number is reduced by two- to threefold. The suppressor strains do not affect the copy numbers of non-ColE1-type plasmids tested, suggesting that their effects are specific for ColE1-type plasmids. Two of the suppressor strains show ColE1 allele-specific suppression; i.e., certain plasmid copy number mutations are suppressed more efficiently than others, suggesting specificity in the interaction between the suppressor gene product and plasmid replication component(s). All of the mutations were genetically mapped to the chromosomal polA gene, which encodes DNA polymerase I. The suppressor mutational changes were identified by DNA sequencing and found to alter single nucleotides in the region encoding the Klenow fragment of DNA polymerase I. Two mutations map in the DNA-binding cleft of the polymerase region and are suggested to affect specific interactions of the enzyme with the replication primer RNA encoded by the plasmid. The third suppressor alters a residue in the 3'-5' exonuclease domain of the enzyme. Implications for the interaction of DNA polymerase I with the ColE1 primer RNA are discussed.     

Regulation of copy number and stability of phage λ derived pTCλ1 plasmid in the light of the dimer/multimer catastrophe hypothesis

The dimer catastrophe hypothesis has been proposed previously to explain instability of multicopy plasmids whose partitioning is random, contrary to low copy number plasmids which are stably maintained and actively partitioned. Until now, this hypothesis has been investigated using multicopy ColE1 plasmids. However, for more detailed testing of the dimer/multimer catastrophe hypothesis, one should use a plasmid which can be maintained at either low or high copy number and still possesses the same mechanism of replication regulation. Here we used a modified lambda plasmid, pTC lambda 1. The advantage of this plasmid is that it can be maintained at different copy numbers depending on the concentration of an inducer which stimulates the initiation of plasmid replication. Results obtained with this plasmid in recombination proficient and deficient cells generally support the dimer/multimer catastrophe hypothesis, but also suggest some modification in the model.     

A facile and reversible method to decrease the copy number of the ColE1-related cloning vectors commonly used in Escherichia coli.

We report a technique which uses the cointegrate intermediate of transposon Tn1000 transposition as a means to lower the copy number of ColE1-type plasmids. The transposition of Tn1000 from one replicon to another is considered a two-step process. In the first step, the transposon-encoded TnpA protein mediates fusion of the two replicons to produce a cointegrate. In the second step, the cointegrate is resolved by site-specific recombination between the two transposon copies to yield the final transposition products: the target replicon with an integrated transposon plus the regenerated donor replicon. Using in vitro techniques, the DNA sequence of the Tn1000 transposon was altered so that cointegrate formation occurs but resolution by the site-specific recombination pathway is blocked. When this transposon was resident on an F factor-derived plasmid, a cointegrate was formed between a multicopy ColE1-type target plasmid and the conjugative F plasmid. Conjugational transfer of this cointegrate into a polA strain resulted in a stable cointegrate in which replication from the ColE1 plasmid origin was inhibited and replication proceeded only from the single-copy F factor replication origin. We assayed isogenic strains which harbored plasmids encoding chloramphenicol acetyltransferase to measure the copy number of such F factor-ColE1-type cointegrate plasmids and found that the copy number was decreased to the level of single-copy chromosomal elements. This method was used to study the effect of copy number on the expression of the fabA gene (which encodes the key fatty acid-biosynthetic enzyme beta-hydroxydecanoylthioester dehydrase) by the regulatory protein encoded by the fadR gene.     

The rate of processing and degradation of antisense RNAI regulates the replication of ColE1-type plasmids in vivo.

We show that the rate of degradation of RNAI, an anti-sense repressor of the replication primer RNAII, is a key element of control in the replication of ColE1-type plasmids in vivo. Cleavage of RNAI by RNAase E, a ribosomal RNA-processing enzyme encoded or controlled by the rne (also known as ams) locus, relieves repression by endonucleolytically converting RNAI to a very rapidly decaying product, pRNAI-5. A 5' triphosphate-terminated homolog of pRNAI-5 is degraded slowly and consequently inhibits replication. Nucleotide substitutions within the RNAase E cleavage sequence alter RNAI half-life and plasmid copy number, changing also the incompatibility phenotype. RNAI variants lacking the sequence cleaved by RNAase E are eliminated by growth rate-dependent degradation, resulting in growth-responsive control of plasmid replication and copy number.     

Obligatory coupling of colicin release and lysis in mitomycin-treated Col+ Escherichia coli

Previous work has shown that Escherichia coli K12 strains carrying the small, high copy number ColE2-P9 plasmid produce large amounts of colicin and then lyse and release colicin when grown in broth culture containing mitomycin C. Strains carrying the larger, low copy number ColIa-CA53 plasmid produced much less colicin and did not lyse or discharge more than 15% of their colicin when grown under the same conditions. Naturally-occurring Col+ strains and E. coli K12 derivatives carrying different Col plasmids could be classified either as ColE2+-like or ColIa+-like according to whether or not they produced large amounts of colicin and lysed and discharged colicin when grown in the presence of mitomycin, and also by the size and presumed copy number of the Col plasmid they carried. Strains carrying multiple copies of the cloned colicin Ia structural gene produced large amounts of colicin but did not lyse or release colicin when grown in the presence of mitomycin. This result rules out the possibility that high level accumulation of colicin is sufficient to cause lysis. Conditions were sought under which colicin Ia could be released from the producing cells. It was found that mitomycin-treated cultures of strains carrying both ColE2 and ColIa plasmids released both colicins when they lysed, although colicin Ia release occurred later than colicin E2 release. It was also noted that colicin Ia-laden cells released their colicin when diluted into fresh culture medium.     

Identification and nucleotide sequence of the minimal replicon of the low-copy-number plasmid pBS2

The plasmid pBS2 has a low copy number and is endogenous to Bacillus subtilis. The replication of this plasmid depends on the function of most of the host's dna genes including dnaB, which is unique to B. subtilis and is required for both the initiation of chromosome replication and the DNA-membrane association. We have identified the region that is essential for the replication of pBS2 and determined the complete 2279-bp nucleotide sequence of this region. In this region, there are two stretches of sequence homologous to the 18-bp consensus sequence which commonly appears at the origin of replication of plasmids pUB110 and pC194. The entire region contains six sizable open reading frames. Two of them are probably translated. One open reading frame, designated ORF A, coding for 269 amino acids, has significant homology, in terms of amino acid sequence, with the open reading frame of the gene for the Rep U protein of plasmid pUB110. The similarities between pBS2 and other plasmids suggest that the pBS2 may also replicate as a rolling circle, which appears to be the salient feature of a mechanism of replication that is common to small plasmids in gram-positive bacteria.     

Replication of ColE2 and ColE3 plasmids: The regions sufficient for autonomous replication

Summary We have localized the regions sufficient for autonomous replication on the genomes of the colicin E2 (ColE2) and colicin E3 (ColE3) plasmids and analyzed the replication functions carried by these regions. A 1.3 kb segment of each plasmid is sufficient for autonomous replication. Plasmids carrying this segment retain the replication properties of the original plasmid. The 1.3 kb segment consists of three functional portions. Firstly, a 0.9 kb region which specifies at least one trans-acting factor required for replication of each plasmid. Secondly, a 0.4 kb region located adjacent to one end of the 0.9 kb region, which is required for expression of the trans-acting factor(s) and probably contains the promoter. The region across the border of these two portions of ColE2 is involved in copy number control of the plasmid. The third portion is a 50 bp region adjacent to the other end of the 0.9 kb region, which contains a cis-acting site (origin) where replication initiates in the presence of the trans-acting factor(s). The action of the trans-acting factor(s) on the origin is plasmid specific. The 50 bp regions functioning as the origins of replication of ColE2 and ColE3 are the smallest among those in prokaryotic replicons so far identified and analyzed.     

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.     

Replication of ColE2 and ColE3 plasmids: Two ColE2 incompatibility functions

Summary We have identified and localized two incompatibility determinants (IncA and IncB) within a 1.3 kb segment of ColE2 sufficient for autonomous replication. The IncA determinant is localized in a region shorter than 250 bp and expresses incompatibility against both ColE2 and ColE3. The region which determines sensitivity to the IncA determinant seems to overlap with the region specifying the IncA determinant. The expression of the trans-acting factor(s) specifically required for replication of ColE2 interferes with expression of the IncA determinant against ColE2 but not against ColE3. The IncA determinant might be at least partly responsible for the copy number control of the plasmid. The IncB determinant is localized in a 50 bp region (origin) which is sufficient for initiation of replication in the presence of the trans-acting factor(s). The IncB determinant is specific for ColE2 and seems to be due to titration of the trans-acting essential replication factor(s) by binding.