Effects of chloramphenicol and rifampicin on the replication of R plasmid NR1 deoxyribonucleic acid in Escherichia coli.

The effects of inhibition of protein and ribonucleic acid (RNA) synthesis on the replication of the plasmids NR1 and F′lac in Escherichia coli were studied. When protein synthesis is inhibited, there is approximately a 25% increase in R plasmid deoxyribonucleic acid (DNA), but this newly synthesized DNA is not recoverable in the covalently closed circular (CCC) form until protein synthesis is allowed to resume. When RNA synthesis is inhibited, there is also approximately a 20% increase in R plasmid DNA, but this DNA is immediately recoverable in the CCC form. F′lac DNA, unlike R plasmid DNA, can continue to replicate for at least a generation time in the absence of protein synthesis, and this F′lac DNA is immediately recoverable in the CCC form.     

Replication of ColE1 plasmid deoxyribonucleic acid in a thermosensitive dnaA mutant of Escherichia coli.

The replication of ColE1 deoxyribonucleic acid (DNA) took place at the restrictive temperature in a dnaA mutant, dnaA167(Ts). It proceeded at a constant rate at 42 degrees C for at least 3 h. The replication was insensitive to rifampin, which blocked replication at the permissive temperature or in the presence of chloramphenicol, even at the restrictive temperature. A linear DNA strand of ColE1 longer than unit genome size was synthesized. The structure of the replicating molecules observed by electron microscopy was mostly sigma shaped, composed of a circle of a unit genome length with a double-stranded tail. These observations suggest that the replication of ColE1 DNA proceeds via a rolling-circle type of structure in the absence of dnaA function.     

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.     

Relaxation of supercoiled plasmid DNA by oxidative stresses in Escherichia coli.

The relaxation of plasmid DNA was observed after the visible light irradiation of Escherichia coli AB1157 harboring plasmid pBR322 or some other plasmids in the presence of a photosensitizing dye, such as toluidine blue or acridine orange, and molecular oxygen. Treatment of the cells with hydroperoxides, such as tert-butyl hydroperoxide, cumene hydroperoxide, and hydrogen peroxide, also caused the plasmid DNA relaxation in vivo. Relaxation was not observed in these treatments of purified pBR322 DNA in vitro. Plasmid DNA relaxation was also detected after near-UV irradiation. Far-UV irradiation did not induce such relaxation.     

Transition of R factor NR1 in Proteus mirabilis: molecular structure and replication of NR1 deoxyribonucleic acid.

The structure of R factor NR1 DNA in Proteus mirabilis has been studied by using the techniques of CsCl density gradient centrifugation, sedimentation in neutral and alkaline sucrose gradients, and electron microscopy. It has been shown that the nontransitioned form of NR1 DNA isolated from P. mirabilis cultured in drug-free medium is a37-mum circular deoxyribonucleic acid (DNA) with a density of 1.712 g/ml in a neutral CsCl gradient. This circular molecule is a composite structure consisting of a 29-mum resistance transfer factor containing the tetracycline-resistance genes (RTF-TC) and an 8-mum r-determinants component conferring resistance to chloramphenicol (CM), streptomycin/spectinomycin, and the sulfonamides. There are one to two copies of NR1 per chromosome equivalent of DNA in exponential-phase cells cultured in Penassay broth. After growth of PM15/NR1 in medium containing 100 mug of CM per ml, the density of the NR1 DNA increased from 1.712 g/ml to approximately 1.718 g/ml and the proportion of NR1 DNA relative to the chromosome is amplified about 10-fold. The changes in R factor DNA structure which accompany this phenomenon (termed the transition) have been studied. DNA density profiles of the transitioned NR1 DNA consist of a 1.718 g/ml band which is skewed toward the less dense side. The transitioned NR1 DNA consists of molecules containing the RTF-TC element attached to multiple copies of r-determinants DNA (poly-r-determinant R factors) and multimeric and monomeric autonomous r-determinants structures. Poly-r-determinant R factors have a density intermediate between the basic composite structure (1.712 g/ml) and r-determinants DNA (1.718 g/ml). These species presumably account for the skewing of the 1.718-g/ml DNA band toward the less dense side. When transitioned cells are subsequently cultured in drug-free medium, poly-r-determinant R factors and autonomous poly-r-determinants undergo dissociation to form smaller structures containing fewer copies of r-determinants. This process continues until, after prolonged growth in drug-free medium the NR1 DNA returns to the nontransitioned state which consists of an RTF-TC and a single copy of r-determinants.     

Intermediates of replication of NR1 plasmid DNA in Escherichia coli mini-cells

The pulse label of NRL plasmid-containing mini-cells has been shown to be localized mainly in DNA with a floating density in the CsCl-EtBr gradient different from the floating density of supercoil and open circle DNAs. During the chase of the pulse label, the DNA is transfered from the fraction with the intermediate floating density varying between the values for the supercoil and open circle DNA fractions to the fraction located below supercoil DNA in the equilibrium gradient and further to the open circle fraction. Electron microscopic analysis of the material with a higher floating density as compared to supercoil DNA has demonstrated the presence of "heavy" intermediates--covalently closed loosely supercoiled molecules. It is also supported by the sedimentation pattern of the characterized fraction in neutral and alkaline saccharose gradients. Molecules located in the CsCl-EtBr gradient between supercoil and open circle DNAs have the sedimentation constant characteristic for the elongation intermediates. It is suggested that NRL DNA molecules in E. coli mini-cells pass through all the basic stages of replication which results in the formation of open circle DNA or supercoil relaxation complexes.     

Escherichia coli low-copy-number plasmid R1 centromere parC forms a U-shaped complex with its binding protein ParR

The Escherichia coli low-copy-number plasmid R1 contains a segregation machinery composed of parC, ParR and parM. The R1 centromere-like site parC contains two separate sets of repeats. By atomic force microscopy (AFM) we show here that ParR molecules bind to each of the 5-fold repeated iterons separately with the intervening sequence unbound by ParR. The two ParR protein complexes on parC do not complex with each other. ParR binds with a stoichiometry of about one ParR dimer per each single iteron. The measured DNA fragment lengths agreed with B-form DNA and each of the two parC 5-fold interon DNA stretches adopts a linear path in its complex with ParR. However, the overall parC/ParR complex with both iteron repeats bound by ParR forms an overall U-shaped structure: the DNA folds back on itself nearly completely, including an angle of ~150°. Analysing linear DNA fragments, we never observed dimerized ParR complexes on one parC DNA molecule (intramolecular) nor a dimerization between ParR complexes bound to two different parC DNA molecules (intermolecular). This bacterial segrosome is compared to other bacterial segregation complexes. We speculate that partition complexes might have a similar overall structural organization and, at least in part, common functional properties.     

Properties of proteins produced after damage to deoxyribonucleic acid of Escherichia coli.

Large amounts of extra proteins, X (in the envelope fraction) and X' (in the cytoplasmic fraction) were detected by SDS-polyacrylamide gel electrophoresis when DNA of Escherichia coli was damaged. These two proteins had the same apparent molecular weight (appproximately 40,000) and were produced under identical conditions, including requirement for the recA" and lexA+ genotype. Sucrose density gradient centrifugation revealed that protein X' consisted of relatively large and heterogeneous aggregates in the cytoplasmic fraction; the distribution of protein X in the envelope was not determined. As proteins X and X' were shown to be equivalent, it is suggested that they are identical. Co-precipitation of the aggregates of protein X' with the envelope led to the appearance of protein X in the envelope fraction.     

Transformation of Escherichia coli with plasmid deoxyribonucleic acid: calcium-induced binding of deoxyribonucleic acid to whole cells and to isolated membrane fractions.

Plasmid deoxyribonucleic acid (DNA) was tightly bound to cells of Escherichia coli at 0 degrees C in the presence of divalent cations. During incubation at 42 degrees C, 0.1 to 1% of this DNA became resistant to deoxyribonuclease. Deoxyribonuclease-resistant DNA binding and the ability to produce transformants became saturated when transformation mixtures contained 1 to 2 micrograms of plasmid NTP16 DNA and about 5 X 10(8) viable cells. Under optimum conditions, between 1 and 2 molecule equivalents of 3H-labeled NTP16 DNA per viable cell became deoxyribonuclease resistant. Despite this, only 0.1 to 1% of viable cells became transformed by saturating amounts of the plasmid. The results suggest that transport of DNA across the inner membrane is a limiting step in transformation. After transformation the bulk of labeled plasmid DNA remained associated with outer membranes. However, in vitro assays indicated that plasmid DNA would bind equally well to preparations of inner or outer membranes provided divalent cations were present to preparations of inner or outer membranes provided divalent cations were present. Divalent cations promoted differing levels of binding to isolated inner and outer membranes in the order Ca2+ much greater than Ba2+ greater than Sr2+ greater than Mg2+. This parallels their relative efficiencies in promoting transformation. Binding of plasmid DNA was greatly reduced when outer membranes were treated with trypsin; this suggests that protein components may be required for the binding or transport of DNA (or both) during transformation.     

Effect of growth rate and nutrient limitation on the transformability of Escherichia coli with plasmid deoxyribonucleic acid.

The observed transformation frequency by plasmid deoxyribonucleic acid of Escherichia coli grown in continuous culture was found to depend on both the steady-state growth rate and the type of nutrient used to limit growth. With carbon, nitrogen, or phosphorus limitation, the faster the growth rate, the higher the transformation frequency. The increase in transformation frequency associated with higher rates was shown to be due to more transformable cells in the population rather than an increased efficiency of deoxyribonucleic acid uptake. Growth rate had relatively little effect on the transformability of cells from sulfate- and Mg2+-limited chemostats, indicating that some factor other than the growth rate must influence the frequency of transformation. Regardless of the nutrient limitation or the growth rate, no transformants were obtained in the absence of CaCl2.     

Random replication of the stringent plasmid R1 in Escherichia coli K-12.

The R-factor R1 is present in a low number of copies per genome (near unity, so-called stringent control of replication). The replication of R1 was studied in a density-shift experiment. One generation after the shift about 20% of the R1 copies had not replicated, whereas about 20% had replicated at least twice. The results are in quantitative accordance with a random replication of R1 in which the replicating molecules are taken from a cytoplasmic plasmid pool and transferred back to the pool after replication. This is analogous to the results obtained by Bazaral and Helinski (1970) and Rownd (1969) for plasmids that are present in 10 to 20 copies per genome (so-called relaxed control of replication). Hence, there seem to be no difference between stringent and relaxed plasmids with respect to selection of plasmid molecules for replication. However, we cannot tell whether all R1 copies in a cell replicate during a fraction of or throughout the cell cycle. The random selction of plasmid copies for replication has to be considered when models for control of replication are constructed.     

Transition of deletion mutants of the composite resistance plasmid NR1 in Escherichia coli and Salmonella typhimurium.

Derivatives of the composite R plasmid NR1 from which a portion of the resistance determinants (r-determinants) component had been deleted were found to undergo amplification of the remaining r-determinants region in Escherichia coli and Salmonella typhimurium. The wild-type NR1 plasmid does not amplify in these genera, although all of these plasmids undergo amplification in Proteus mirabilis. The deletion mutants retained the mercuric ion resistance operon (mer) but conferred a much lower level of sulfonamide resistance than NR1. The remaining r-determinants region, which is bounded by direct repeats of the insertion element IS1, formed multiple tandem duplications in E. coli, S. typhimurium, and P. mirabilis after subculturing the host cells in medium containing high concentrations of sulfonamide. Gene amplification was characterized by restriction endonuclease analysis, analytical buoyant density centrifugation, DNA-DNA hybridization, and sedimentation in sucrose gradients. The tandem repeats remained attached to the resistance transfer factor component of the plasmid in at least part of the plasmid population; autonomous tandem repeats of r-determinants were probably also present. Amplification did not occur in host recA mutants. Amplified strains subcultured in drug-free medium lost the amplified r-determinants. By using a strain temperature sensitive for the recA gene, it was possible to obtain gene amplification at the permissive temperature. Loss of r-determinants took place at the permissive temperature, but not at the nonpermissive temperature. The termini of the deletions of several independent mutants which conferred low sulfonamide resistance were found to be located within the adjacent streptomycin-spectinomycin resistance gene.     

Conditional-lethal deoxyribonucleic acid ligase mutant of Escherichia coli.

A new Escherichia coli deoxyribonucleic acid (DNA) ligase mutant has been identified among a collection of temperature-sensitive DNA replication mutants isolated recently (Sevastopoulos, Wehr, and Glaser, Proc. Natl. Acad. Sci. U.S.A. 74:3485-3489, 1977). At the nonpermissive temperature DNA synthesis in the mutant stops rapidly, the DNA is degraded to acid-soluble material, and cell death ensures. This suggests that the mutant may be among the most ligase-deficient strains yet characterized.     

Nature of transforming deoxyribonucleic acid in calcium-treated Escherichia coli.

A study of the reactivation of ultraviolet-irradiated plasmid and phage deoxyribonucleic acid molecules after transformation into Escherichia coli strains indicated that, when double-stranded deoxyribonucleic acid was used as the donor species, it was taken up without conversion to the single-standed form.