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.     

Requirements for Rapid Plasmid ColE1 Copy Number Adjustments: A Mathematical Model of Inhibition Modes and RNA Turnover Rates

The random distribution of ColE1 plasmids between the daughter cells at cell division introduces large copy number variations. Statistic variation associated with limited copy number in single cells also causes fluctuations to emerge spontaneously during the cell cycle. Efficient replication control out of steady state is therefore important to tame such stochastic effects of small numbers. In the present model, the dynamic features of copy number control are divided into two parts: first, how sharply the replication frequency per plasmid responds to changes in the concentration of the plasmid-coded inhibitor, RNA I, and second, how tightly RNA I and plasmid concentrations are coupled. Single (hyperbolic)- and multiple (exponential)-step inhibition mechanisms are compared out of steady state and it is shown how the response in replication frequency depends on the mode of inhibition. For both mechanisms, sensitivity of inhibition is “bought” at the expense of a rapid turnover of a replication preprimer, RNA II. Conventional, single-step, inhibition kinetics gives a sloppy replication control even at high RNA II turnover rates, whereas multiple-step inhibition has the potential of working with unlimited precision. When plasmid concentration changes rapidly, RNA I must be degraded rapidly to be “up to date” with the change. Adjustment to steady state is drastically impaired when the turnover rate constants of RNA I decrease below certain thresholds, but is basically unaffected for a corresponding increase. Several features of copy number control that are shown to be crucial for the understanding of ColE1-type plasmids still remain to be experimentally characterized. It is shown how steady-state properties reflect dynamics at the heart of regulation and therefore can be used to discriminate between fundamentally different copy number control mechanisms. The experimental tests of the predictions made require carefully planned assays, and some suggestions for suitable experiments arise naturally from the present work. It is also discussed how the presence of the Rom protein may affect dynamic qualities of copy number control.     

Characterization of a promoter up mutation in the -35 region of the promoter of the primer for ColE1 replication

Summary A point mutation in the -35 region of the promoter of the primer for initiation of DNA replication in the plasmid pMB1 was characterized. This base change causes a promoter up phenotype. The analysis of a second mutant obtained by site-directed mutagenesis allowed the exclusion of a role in the phenotype for the potential intrastrand secondary structure as well as for the methylation state of the DNA in the promoter region. The promoter up phenotype is concluded to be due to a change in the primary structure of the — 35 element with the consequent production of a better cluster of hydrogen bond donors and acceptors for the RNA polymerase.     

Polar mobilization of the Escherichia coli chromosome by the ColE1 transfer origin

Summary Mobilization of the plasmid ColE1 from cells containing a conjugative plasmid (such as F) requires the synthesis of ColE1 mob proteins, and the presence, in cis, of bom (basis of mobility), a region of ColE1 containing the origin of transfer (oriT). The process of ColE1 transfer is thought to resemble that of the conjugative plasmid F, although the plasmids share little sequence homology. In F, conjugation is preceded by a strand-specific nicking event at oriT. The nicked strand is then conducted to the recipient with the 5 end leading. This is believed also to occur with ColE1, but direct biochemical confirmation has been precluded by its small size (6.65 kb). To test this hypothesis genetically, a novel method, using a dv-based vector, has been devised to site-specifically integrate bom (or any other cloned sequence) into the chromosome of Escherichia coli. When provided with suitable mobilizing plasmids, such strains were found to transfer the chromosome in a polar way. From these data, the orientation of transfer of ColE1 was deduced and shown to be analogous to F.     

Replication of ColE2 and ColE3 plasmids In vitro replication dependent on plasmid-coded proteins

Summary We developed an in vitro replication system for ColE2 and ColE3 plasmids using cell extracts prepared from bacteria with or without these plasmids. DNA synthesis depended on host DNA polymerase I and was sensitive to rifampicin and chloramphenicol. Preincubation of the extracts with plasmid DNA, however, allowed replication of template DNA added subsequently in a plasmid-specific manner in the presence of rifampicin and chloramphenicol. The plasmid-specified trans-acting factor(s) was detected in cell extracts from bacteria carrying a recombinant plasmid with the region of ColE2 or ColE3 encoding the Rep protein. The plasmid-specified factor(s) consisted at least in part of protein, probably the Rep protein. In vitro replication started within a region of ColE2 or ColE3 containing the smallest cis-acting segment essential for in vivo replication and proceeded in a fixed direction.     

Isolation and characterization of novel cold-sensitive dnaA mutants of Escherichia coli

We developed an efficient method for isolation of novel dnaA mutations based on PCR mutagenesis in the presence of manganese ion and shuffling of dnaA-carrying plasmids in a dnaA deletion host bacterium. Using this system, we obtained 30 cold-sensitive mutants from 4000 clones carrying plasmids with a mutagenized dnaA gene. All 27 cold-sensitive mutants analyzed were defective in DNA replication; none had a DnaAcos (over-initiation) phenotype. Nucleotide sequencing revealed that novel 15 alleles (mutations in 14 amino acid residues) are responsible for the cold-sensitive phenotype and are all located in the carboxy-terminal half of the DnaA protein.     

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.     

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.     

Identification of a new mutation in Escherichia coli that suppresses a pbpB (Ts) phenotype in the presence of penicillin-binding protein 1B

Analysis of the functional role of penicillin-binding protein 1B (PBP1B) of Escherichia coli led us to find a new mutation able to suppress thermosensitive growth of the pbpB2158(Ts) mutant strain, which harbors a thermosensitive PBP3 protein only in the presence of a ponB+ background. The mutation, originally isolated in a strain with a high dosage of PBP1B, could also suppress the pbpB(Ts) phenotype when a single copy of the ponB gene was introduced. These results clearly give further support to the implication of PPB1B in the septation process in Escherichia coli.     

Identification and characterization of novel ColE1-type, high-copy number plasmid mutants in Legionella pneumophila

ColE1-type plasmids are commonly used in bacterial genetics research, and replication of these plasmids is regulated by interaction of RNA I and RNA II. Although these plasmids are narrow-host-range, they can be maintained in Legionella pneumophila under antibiotic selection, with low-copy number and instability. Here, we have described the isolation of two novel spontaneous mutants of pBC(gfp)Pmip, pBG307 and pBG309, which are able to mark the L. pneumophila with strong green fluorescence when exposed to visible light. One of the mutants, pBG307, has a single CG-->TA mutation in RNA II promoter located 2-bases upstream the - 10 region. Another one, pBG309, has the same mutation, as well as an additional CG-->AT mutation in the 76th nucleotide of RNA I, or in the 6th nucleotide of RNA II. A plasmid with the single mutation in RNA I, pBG308, was also constructed. Characterization of these plasmids carrying the enhanced green fluorescent protein (gfpmut2) gene revealed that the green fluorescence intensities of these plasmids were 2- to 30-fold higher than that of the wild type and both of the mutations contribute to increase the plasmid copy number and/or plasmid stability. The mutation located in RNA II promoter played a more dominant role in elevating the copy number, compared to the mutation in RNA I. We also tested the mutant plasmids for replication in Escherichia coli, and found that their copy number and stability were dramatically decreased, except pBG307. Our data suggest that these plasmids might be useful and convenient in genetic studies in L. pneumophila.     

Isolation and characterization of a ColE1 plasmid containing the entire bio gene cluster of Escherichia coli K12.

Summary Temperature-sensitive mutants of Tetrahymena pyriformis which had previously been selected for their inability to grow at 38°C but which grew normally (or near normally) at 30°C were characterized with respect to their patterns of RNA and protein accumulation at both the permissive and nonpermissive temperatures. Out of 116 such mutants, the majority (72) acted like wild type for these accumulations during a 3 h labelling period although some of them stopped dividing during this time. The remainder exhibited a variety of altered phenotypes for the rate, extent, and timing of RNA and/or protein accumulation. Those mutants which exhibited selective inhibition of RNA accumulation, and were thus potential ribosomal RNA (rRNA) mutants, were further characterized by examining patterns of protein and RNA synthesis in cells starved at the permissive temperature, but re-fed at the permissive and non-permissive temperatures. At least five different types of mutants as defined by patterns of protein and RNA synthesis in refed cells were identified. Direct analysis of the RNA synthesized in cells from 2 of these types of mutants showed that in 5 out of 6 cases rRNA synthesis and/or processing was inhibited within 30 min after shifting to the non-permissive temperature. The other mutant examined was found to show a delayed inhibition of rRNA synthesis.     

Analysis of the temperature-sensitive mutation of Escherichia coli pantothenate kinase reveals YbjN as a possible protein stabilizer

Pantothenate kinase (PanK), a key regulatory enzyme in the coenzyme A (CoA) biosynthetic pathway, catalyzes the rate-limiting phosphorylation of pantothenic acid to form phosphopantothenate during CoA biosynthesis. Escherichia coli ts9 strain manifests temperature-sensitive phenotype on LB media due to its mutation in the coaA gene (coaA1). Sequencing analysis revealed that coaA1 arises from a single base pair mutation that results in an amino acid change, L236F. This change, located proximate to the ATP binding site of CoaA, destabilizes both enzymatic activity and structural integrity or stability of the mutant protein in vitro. Spontaneously, revertants of ts9 were occasionally found on LB medium plates. Two groups of revertants were isolated: for those that can grow at 40 degrees C, a reversion of the original amino acid mutation L236F to L236L or other amino acid (such as L236C) occurs; for those that can grow at 37 degrees C but not 40 degrees C, a mutation at another gene or intergenic suppression is strongly indicated. Towards genetic identification of genes that might interact with coaA1, ybjN, which encodes a putative sensory transduction regulator protein, and whose over-expression is capable of ameliorating the temperature-sensitive phenotype of the structurally unstable CoaA1 or CoaA[L236F], was isolated. Over-expression of ybjN appears to suppress the temperature-sensitive phenotype of several other temperature-sensitive mutations, including coaA14 (carried by DV51 strain), coaA15 (carried by DV70 strain), and ilu-1, suggesting it not only helps CoaA1, but possibly works as a general stabilizer for some other unstable proteins.     

Identification and characterization of recD, a gene affecting plasmid maintenance and recombination in Escherichia coli.

We isolated mutations that reduce plasmid stability in dividing cell populations and mapped these mutations to a previously undescribed gene, recD, that affects recombination frequency and consequently the formation of plasmid concatemers. Insertions of the transposable element Tn10 into recD resulted in increased concatemerization and loss of pSC101 and ColE1-like replicons during nonselective growth. Both concatemer formation and plasmid instability in recD mutants require a functional recA gene. Mutations in recD are recessive to recD+ and map to a small region of the Escherichia coli chromosome located between recB and argA. Although the recD locus is distinct from loci encoding the two previously identified subunits of the RecBC enzyme, mutations in recD appear to affect the exonuclease activity of this enzyme.     

Characterization of the ColE1 mobilization region and its protein products

Summary A third of the 6.6 kb genome of ColE1 is devoted to mobilization (mob) genes necessary to promote its specific transfer in the presence of conjugative plasmids. Themob region is genetically complex: twomob genes are entirely overlapped by a third. Oligonucleotide-directed mutagenesis was used to insert an amber codon into one of the overlapped genes and make possible a full complementation analysis ofmob. Fourmob genes essential for mobilization by R64drd11 were thus identified. Fragments ofmob were subcloned under control of the P_tac promoter in a suitable vector, overexpressed in minicells and the mobilization proteins visualized. A comprehensive alignment of themob region of ColE1 with those of its close relatives ColK and ColA demonstrating that the four essentialmob genes are conserved is also presented.