Conditions and mutations affecting the maintenance and replication of plasmid DNA in Escherichia coli 15

Summary An Escherichia coli 15 strain has been constructed which contains, in addition to the plasmids inherent to E. coli 15 (P 1-like DNA and minicircular DNA), the colicinogenic factor E₁ (Col E₁). Whereas the P 1-like DNA of E. coli 15 is unaffected by the uptake of the colicin plasmid, the number of copies of minicircular DNA of E. coli 15 decreases and an equivalent amount of Col E₁ DNA becomes established in the cell. The ratio between these two small plasmids is dependent on the growth temperature. The mode of replication of minicircular DNA and Col E₁ DNA is very similar, but is different in various respects from that of the P 1-like plasmid: 1. Both small plasmids continue to replicate in the presence of chloramphenicol, whereas the replication of P 1-like DNA stops like the chromosomal DNA. 2. Rifampicin inhibits the synthesis of both small plasmids rather rapidly. The replication of P 1-like DNA continues during the remaining replication cycle of the chromosome in the presence of rifampicin. 3. The replication of Col E₁ DNA and of the minicircular DNA still proceeds at elevated temperatures (45–50°C), whereas little or no incorporation of ³H-thymidine into P 1-like DNA is observed at these temperatures. 4. Mutants have been obtained, which show altered properties in the maintenance and replication of the plasmids without being affected in the replication of the chromosomal DNA. In all these mutants the replication and (or) maintenance of the minicircular DNA of E. coli 15 and Col E₁ DNA is affected in the same way, but not that of the P 1-like plasmid.     

Method for the isolation of the replication region of a bacterial replicon: construction of a mini-F'kn plasmid.

A purified fragment of deoxyribonucleic acid (DNA) that determines resistance to kanamycin and is incapable of self-replication was used to select a self-replicating fragment from an EcoRI endonuclease digest of the sex factor F'lac. This F'lac fragment, exhibiting a molecular weight of 6 X 10(6), carries the genes essential for maintenance of the F replicon in Escherichia coli cells. The constructed mini-F'km plasmid also retains the incompatibility properties of the parent F'lac plasmid. Large amounts of the kanamycin resistance fragment of a molecular weight of 4.5 X 10(6) with an EcoRI-cleaved, self-replicating derivative of colicinogenic plasmid E1 that has a molecular weight of 2.2 X 10(6), The recombinant plasmid is able to replicate extensively in E. coli in medium containing chloramphenicol, and, therefore, large quantities of this plasmid DNA can be obtained. The substantial difference in size between the two fragments in the recombinant plasmid greatly facilitates their separation by preparative agarose gel electrophoresis.     

Nature of Col E1 Plasmid Replication in Escherichia coli in the Presence of Chloramphenicol

The colicinogenic factor E(1) (Col E(1)) in Escherichia coli continues to replicate by a semiconservative mechanism in the presence of chloramphenicol (CAP) for 10 to 15 hr, long after chromosomal deoxyribonucleic acid (DNA) synthesis has terminated. Following CAP addition, the rate of synthesis of plasmid DNA gradually increases to an extent dependent on the medium employed. Within 2 to 4 hr after the addition of CAP, replication in a glucose-Casamino Acids medium approaches a maximum rate representing approximately eight times an average rate which would be required for a net doubling of DNA per cell in one generation. The number of copies of Col E(1) DNA molecules that accumulate under these conditions approaches about 3,000 copies per cell, representing a 125-fold increase over the normal level of 24 copies per cell. The system is particularly convenient for studying the mechanism of DNA replication.     

Structuro-functional organization of segments of Co1A plasmid DNA, determining its stable inheritance

Two par regions were localized within the structure of a small colicinogenic plasmid ColA. One of them functions at the expense of plasmid multimere resolution. Analysis of the nucleotide sequence of the region revealed the existence of essential homology with the par locus of plasmid ColE1. As compared to E. coli C600, the function of multimere forms' resolution of plasmid DNA in E. coli C is reduced or absent due to par regions of the ColE1 type. Par regions of various degrees of homology with the par locus of ColE1 were localized by Southern hybridization within the structure of colicinogenic plasmids ColN and ColD. The stabilization of the colicinogenic plasmids is believed to be also determined by the functioning of genes connected with the synthesis and action of colicin.     

Genomic DNA hybridizes with the same rate constant on the QCM biosensor as in homogeneous solution

Hybridization rates of sheared, genomic E. coli DNA in 0.14 M, pH 6.7 phosphate buffer at 65 degrees C were determined by: (1) observing the rate of absorbance decrease at 260 nm due to self-hybridization in solution; and (2) measurement of the rate of mass increase caused by hybridization between DNA in solution and DNA photografted to polystyrene. The latter measurement was done using a quartz crystal microbalance (QCM). In both the spectrophotometric and QCM experiments the probe was identical to the target, as both were taken from the same sample of sheared E. coli DNA. In the QCM measurements, viscoelastic effects were made negligible by drying the biopolymer layer on the QCM's surface before taking the frequency readings. Our purpose was to explore the effect of immobilizing DNA on its hybridization rate constant. A second-order constant of 2.32 +/- 0.09 x 10(-6) ml microg(-1) s(-1), n = 14, for hybridization in solution was obtained spectrophotometrically, while the QCM experiment gave a constant of 2.2 +/- 0.3 x 10(-6) ml microg(-1) s(-1), n = 6. These values are not statistically different. The reaction half-lives for the spectrophotometric and QCM experiments were 6.5 h and 13 min, respectively. The shorter half-life on the QCM can be explained solely by the much greater reactant concentration in the QCM experiment. About 25% of the DNA was inactivated by the attachment reaction. After correcting for this, the surface-attached DNA hybridized with the same rate constant as DNA free in solution. Therefore, it is concluded that, in these specific experiments with genomic DNA, the immobilized regions must have been short compared to the length of the molecules. The data demonstrate the high hybridization rate obtainable when nucleic acids are hybridized in a thin-film, micro-volume reaction on a non-porous surface.     

Molecular cloning and expression in E. coli of a yeast gene coding for beta-galactosidase.

The yeast Kluyveromyces lactis synthesizes a beta-galactosidase (EC 3.2.1.32) which is inducible by lactose. We have isolated the gene that codes for this enzyme using recombinant DNA techniques. K. lactis DNA was partially digested with the restriction endonuclease Eco R1 and joined to Eco R1-digested pBR322 plasmid DNA using DNA ligase. ligase. A lac-mutant of Escherichia coli lacking the structural gene for beta-galactosidase was transformed with ligated DNA. Three lac+ transformants containing recombinant plasmids were selected. Two of the plasmids (pK15 and pK17) contain four Eco R1-K. lactis DNA fragments having molecular weights of 2.2, 1.4, 0.55 and 0.5 x 10(6) daltons. The other plasmid (pK16) lacks the smallest fragment. E. coli carrying any of these plasmids produce beta-galactosidase activity that has a sedimentation coefficient and immunological determinants that are nearly identical to K. lactis beta-galactosidase and distinctly different from E. coli beta-galactosidase. DNA-DNA hybridization studies show that the four Eco R1 fragments in pK15 hybridize to K. lactis but not to E. coli DNA.     

Plasmids Controlling Synthesis of Hemolysin in Escherichia coli: Molecular Properties

Covalently closed extrachromosomal deoxyribonucleic acid (DNA) was isolated from alpha-hemolytic wild-type strains of Escherichia coli. Most strains examined were able to transfer the hemolytic property with varying frequencies to nonhemolytic recipient strains. Out of eight naturally isolated alphahemolytic E. coli strains, four contained a set of three different supercoiled DNAs with sedimentation coefficients of 76S (plasmid A), 63S (plasmid B), and 55S (plasmid C). The sedimentation coefficients and the contour lengths of the isolated molecules correspond to molecular weights of 65 x 10(6), 41 x 10(6), and 32 x 10(6). Three alpha-hemolytic wild-type strains carried only one plasmid with a molecular weight of 41 x 10(6), and one strain harbored two plasmids with molecular weights of 41 x 10(6) and 32 x 10(6). Alpha-hemolytic transconjugants were obtained by conjugation of E. coli K-12 with the hemolytic wild-type strains. A detailed examination revealed that plasmids with the same sizes as plasmids B and C of the wild-type strains can be transferred separately or together to the recipients. Both plasmids possess the hemolytic determinant and transfer properties. Plasmid A appears to be, at least in one wild-type strain, an additional transfer factor without a hemolytic determinant. In one case a hemolytic factor was isolated, after conjugation, that is larger in size than plasmid A and appears to be a recombinant of both plasmids B and C.     

Mechanism of action of nalidixic acid on Escherichia coli. Vi. Cell-free studies

The effects of nalidixic acid in vitro on deoxyribonucleic acid (DNA)- polymerase (deoxyribonucleosidetriphosphate: DNA deoxynucleotidyltransferase, EC 2.7.7.7), deoxyribonucleotide kinases (ATP: deoxymono- and diphosphate phosphotransferases), and deoxyribosyl transferase (nucleoside: purine deoxyribosyltransferase, EC 2.4.2.6) were examined employing partially purified and crude extracts of Escherichia coli ATCC 11229 and E. coli 15TAU. Nalidixic acid had no inhibitory effect on the DNA-polymerase of the wild-type strain E. coli ATCC 11229 at concentrations of 1.4 x 10(-3) to 2.8 x 10(-3)m. No inhibition of deoxyribonucleotide kinase activity was observed at concentrations of nalidixic acid ranging from 2 x 10(-3) to 8.6 x 10(-3)m. Nalidixic acid (0.43 x 10(-4) to 0.43 x 10(-3)m) had no inhibitory effect on the deoxyribosyl transferase activity of crude extracts obtained from E. coli ATCC 11229 or E. coli 15TAU. Analytical CsCl density gradient centrifugation demonstrated that the DNA obtained after treatment of E. coli 15TAU with nalidixic acid was not cross-linked. These results suggest that the prevention of DNA synthesis in vivo by nalidixic acid is not attributable to inhibition of DNA polymerase, deoxyribonucleotide kinase, deoxyribosyl transferase, or to cross-linking of the DNA of treated cells.     

Molecular Recombination Between R-Factor Deoxyribonucleic Acid Molecules in Escherichia coli Host Cells

THREE PREVIOUSLY STUDIED R FACTORS WERE USED: 222/R4, controlling transmissible resistance to sulfonamide, streptomycin, chloromycetin, and tetracycline (SU(r) SM(r) CM(r) TC(r)); 222/R3, a derivative of 222/R4 (now termed 222/R3W) having lost TC(r); and R15, controlling infectious resistance to SU and SM only. Two types of derivative R factors were isolated from 222/R4 by serial subculture in Salmonella species. One derivative, termed 222/R1, lost resistance to SU, SM, and CM, and the other, termed 222/R3N, lost only TC(r). Each factor was transferred to a standard Escherichia coli K-12 host. Recombinant factors of 222/R4 phenotype were isolated by selection after mixed culture of E. coli (222/R1)(+) and (222/R3N)(+) strains. Density-gradient equilibrium centrifugation of lysates of E. coli R(+) hosts in the presence of ethidium bromide separated R-factor deoxyribonucleic acid (DNA) as a heavy satellite peak which was subjected to electron microscopy or analytical density gradient centrifugation. Each DNA comprised a unimolecular species of circular DNA. The contour of R15 measured 22.3 mum [equivalent to 46 x 10(6) atomic mass units (AMU)], and that of 222/R4 measured 33.6 mum (70 x 10(6) AMU). 222/R3W appeared to be a point mutant or small deletion of 222/R4 with an almost identical size, whereas 222/R3N had lost a DNA segment of about 3 mum, and measured 30.3 mum or 63 x 10(6) AMU. The 222/R1 factors also appeared to have arisen by loss of DNA from 222/R4, 222/R1A being 22.3 mum or 46 x 10(6) AMU, whereas all other 222/R1 factors appeared to be duplicates, measuring 25.6 mum or 53 x 10(6) AMU. The DNA from six recombinant factors of R4 phenotype was indistinguishable in size and configuration from the parental 222/R4. In most cases, the number of R-factor copies (present as covalently closed circular molecules) per copy of the E. coli chromosome was less than 2, ranging from 1.2 to 3.3.     

Biological properties and physical map of the genome of a new papovavirus, HD virus.

The superhelical DNA of the HD papovavirus is heterogeneous and consists of two discrete size classes with molecular weights of 3.45 X 10(6) and 3.25 X 10(6). Both size classes of DNA are encapsidated into HD virion particles. Their relative intracellular amounts differ, depending on the cell system. Vero-76 carrier cultures in which HD virus was detected contain both size classes of DNA, with the larger molecules prevailing by a factor of 10. Five clonal lines derived from Vero-76 cell cultures contain exclusively the larger DNA. On the other hand, after cocultivation of Vero-76 with CV-1 cells for several passages, minicircular DNA is accumulated such that both size classes are synthesized in equal amounts. Any of the originally viral DNA-producing cell lines may, upon subcultivation, cease yielding virus. The RITA cell line of Cercopithecus aethiops origin is the only cell line among numerous ones tested which upon infection permits the establishment of a one-step growth cycle. However, between 6 and 8 days after infection, viral DNA synthesis is discontinued, and a persistent viral infection cannot be established. Physical maps of the genomes were constructed, and it could be shown that the smaller, minicircular DNA had originated from the larger DNA as the result of a deletion. The sequences missing in the minicircular DNA are confined to the relative map position 0.15 to 0.21.     

Replication of colicinogenic factor E1 DNA in plasmolysed Escherichia coli cells. Coupling of DNA replication and RNA synthesis.

Plasmolysed chloramphenicol-treated Escherichia coli cells carrying the colicinogenic factor E1 utilize deoxynucleoside triphosphates for the semi-conservative synthesis of Col E1 DNA. Col E1 DNA replication in plasmolysed cells can be dissociated into two temporally separated processes: (a) a rifampicin-sensitive RNA synthesis, which is stimulated by adenosine 3':5'-monophosphate (cyclic AMP) and requires all four ribonucleoside triphosphates and (b) an ATP-dependent DNA synthesis, which is inhibited by arabinosylnucleoside triphosphates and sulfhydryl-blocking reagents. Thes two processes exhibit different sensitivities to inhibition by polyamines and actinomycin D.     

The biochemical and genetic basis for high frequency thiomethyl galactoside resistance in lambda,lambdadg lysogens of Escherichia coli.

In a culture of Escherichia coli K12 gal (lambdadg), cells which form large colonies on agar plates containing galactose and thiomethyl beta-D-galactoside (TMG) appear at high frequency. These clones are resistant to growth inhibition by TMG on galactose minimal medium. Biochemical studies of the steady-state levels of galactokinase and UDPgalactose 4-epimerase suggest that the resistant clones have extra copies of the genes for the galactose-metabolizing enzymes. The mutation for TMG resistance is not located in either the bacterial or the bacteriophage genome, but is probably due to an aberrant association between cell and prophage DNA. Mapping the TMG-resistant characteristic by phage P1 indicates that TMG-resistant bacteria posses at least two GAL+ OPERONS, ONE OF WHICH IS COTRANSDUCIBLe with bio+. In addition, TMG-resistant bacteria behave like lambdadg polylysogens when challenged with the phage lambdaI90c17. From these genetic experiments we conclude that TMG-resistant bacteria arise by duplication of the lambdadg prophage. Finally, gal+ bacteria which carry a single, additional, lambdadg prophage are TMG-resistant. TMG resistance is probably a gal+ gene dosage effect.     

Temperature-Sensitive Mutants for the Replication of Plasmids in Escherichia coli: Requirement for Deoxyribonucleic Acid Polymerase I in the Replication of the Plasmid ColE1

An Escherichia coli mutant (polA1), defective in deoxyribonucleic acid (DNA) polymerase I, (EC 2.7.7.7) is unable to maintain colicinogenic factor E1 (ColE1), whereas several sex factor plasmids are maintained normally in this strain. polA1 mutant strains containing these sex factor plasmids do not exhibit a readily detectable plasmid-induced polymerase activity. A series of E. coli mutants that are temperature sensitive for ColE1 maintenance, but able to maintain other plasmids, were isolated and shown to fall into two phenotypic groups. Mutants in one group are defective specifically in ColE1 maintenance at 43 C, but exhibit normal DNA polymerase I activity. Mutations in the second group map in the polA gene of E. coli, and bacteria carrying these mutations are sensitive to methylmethanesulfonate (MMS). Revertants that were selected either for MMS resistance or the ability to maintain ColE1 were normal for both properties. The DNA polymerase I enzyme of two of these mutants shows a pronounced temperature sensitivity when compared to the wild-type enzyme. An examination of the role of DNA polymerase I in ColE1 maintenance indicates that it is essential for normal replication of the plasmid. In addition, the presence of a functional DNA polymerase I in both the donor and recipient cell is required for the ColV-promoted conjugal transfer of ColE1 and establishment of the plasmid in the recipient cell.     

High-frequency phage-mediated gene transfer among Escherichia coli cells, determined at the single-cell level

Recent whole-genome analysis suggests that lateral gene transfer by bacteriophages has contributed significantly to the genetic diversity of bacteria. To accurately determine the frequency of phage-mediated gene transfer, we employed cycling primed in situ amplification-fluorescent in situ hybridization (CPRINS-FISH) and investigated the movement of the ampicillin resistance gene among Escherichia coli cells mediated by phage at the single-cell level. Phages P1 and T4 and the newly isolated E. coli phage EC10 were used as vectors. The transduction frequencies determined by conventional plating were 3x10(-8) to 2x10(-6), 1x10(-8) to 4x10(-8), and <4x10(-9) to 4x10(-8) per PFU for phages P1, T4, and EC10, respectively. The frequencies of DNA transfer determined by CPRINS-FISH were 7x10(-4) to 1x10(-3), 9x10(-4) to 3x10(-3), and 5x10(-4) to 4x10(-3) for phages P1, T4, and EC10, respectively. Direct viable counting combined with CPRINS-FISH revealed that more than 20% of the cells carrying the transferred gene retained their viabilities. These results revealed that the difference in the number of viable cells carrying the transferred gene and the number of cells capable of growth on the selective medium was 3 to 4 orders of magnitude, indicating that phage-mediated exchange of DNA sequences among bacteria occurs with unexpectedly high frequency.     

Temperature-Sensitive Mutants for the Replication of Plasmids in ESCHERICHIA COLI I. Isolation and Specificity of Host and Plasmid Mutations

Temperature-sensitive mutants of Escherichia coli defective in the replication of the plasmid colicinogenic factor E1 (ColE(1)) were isolated following mutagenesis of E. coli K12 strain carrying the ColE(1) factor. Following the mutagenic treatment an enrichment procedure utilizing the replacement of thymine with bromouracil in the ColE(1) DNA duplicated at the restrictive temperature was used. The mutants isolated following this enrichment step were the result of a mutation event either in the host chromosome or in the ColE(1) plasmid. The host mutants fell into three phenotypic classes based on the effect each mutation had on the maintenance of a variety of other extrachromosomal DNA elements. Phenotypic class I mutations affected all E. coli plasmids, both the I and F sex factor types as well as the ColE(1) factor. Phenotypic class II mutations affected the maintenance of the ColE(1) and the F sex factor type plasmids and not the I type, while phenotypic class III mutations affected only ColE(1) replication. None of these mutations was found to have a significant effect on the replication of the E. coli chromosome. The plasmid-linked mutations fell into two phenotypic classes on the basis of the ability of the Flac episome to complement the mutation in the ColE(1) plasmid.     

Molecular hybridization analysis of cloned Vicia faba minicircular DNA sequences

Summary Three types of minicircular DNA isolated from Vicia faba mitochondria were cloned in pBR322 plasmids. The correspondence of cloned sequences to the original molecules was verified by coelectrophoresis and by DNA-DNA hybridization with total mitochondrial DNA preparations. It was found that the cloned sequences hybridized not only with the minicirclar DNAs and their derivates, but also with some discrete classes of higher molecular weight DNA and with the major DNA. The data obtained from restriction enzyme analysis of complementary sequences suggested that the majority of them were represented by the minicircular DNAs and by the oligomers. The physical maps of cloned sequences were also prepared. These maps differed significantly. However, reciprocal DNA-DNA hybridization showed the existence of sequence homology between minicircular DNAs.     

Isolation and Characterization of a New Generalized Transducing Bacteriophage Different from Pl in Escherichia coli

A new generalized transducing bacteriophage in the Escherichia coli system was isolated and characterized. This phage, designated D108, makes clear plaques on E. coli K-10, K-12, K-12(P1kc), K-12(D6), B/r, C, and 15 T(-), and Shigella dysenteriae. The plaque of phage D108 is larger in size than that of phage P1kc. Electron-microscopic observation revealed that phages D108 and P1kc are morphologically different from each other, suggesting that phage D108 belongs to a phage group different from phage P1. The fact that all of the 10 markers tested were transduced by phage D108 indicates that this phage is a generalized transducing phage in the E. coli system. The transduction frequency by phage D108 of chromosomal markers and of a drug resistance factor (R factor) ranged from 2 x 10(-6) to 3 x 10(-8) and 3 x 10(-9) to 6 x 10(-10) per phage, respectively. The cotransduction frequency of the thr and leu markers was 2.8% for phage P1kc and 1.5% for phage D108. The CM and TC markers (chloramphenicol-resistant and tetracycline-resistant markers, respectively) of the R factor were not cotransduced by phage D108, but the markers were generally cotransduced by phage P1kc. The results suggest that the transducing particle of phage D108 contains a smaller amount of host deoxyribonucleic acid than does phage P1kc.     

Molecular comparisons of plasmids isolated from colicinogenic strains of Escherichia coli

The plasmid content of 14 colicinogenic strains of Escherichia coli has been examined. Four strains contained miniplasmids (1.2-2.0 kb). Small plasmids (4-7 kb) were detected in all the strains specifying group A colicins (colicins A, E1, E2, E3 and K; group I plasmids). Larger plasmids (55-130 kb) were detected in seven out of nine strains specifying group B colicins (colicins B, H, Ia, Ib, M, V and S1; group II plasmids). DNA-DNA hybridization with group II plasmids showed a wide variation in the degree of DNA sequence homology among its members. In contrast little (if any) DNA sequence homology was detected with the group I plasmids when the same group II plasmid DNAs were used as hybridization probes. The results of DNA-DNA hybridization studies with the two small group II plasmids (pcolG-CA46 and pcolD-CA23) suggested that these plasmids are equivalent to deleted forms of larger group II plasmids. Our hybridization data thus support the division of colicin plasmids into the two groups (I and II) that have been previously defined from genetic and physiological studies.     

Detection of bacterial pathogens in municipal wastewater using an oligonucleotide microarray and real-time quantitative PCR

As a first step toward building a comprehensive microarray, two low density DNA microarrays were constructed and evaluated for the accurate detection of wastewater pathogens. The first one involved the direct hybridization of wastewater microbial genomic DNA to the functional gene probes while the second involved PCR amplification of 23S ribosomal DNA. The genomic DNA microarray employed 10 functional genes as detection targets. Sensitivity of the microarray was determined to be approximately 1.0 microg of Esherichia coli genomic DNA, or 2 x 10(8) copies of the target gene, and only E. coli DNA was detected with the microarray assay using municipal raw sewage. Sensitivity of the microarray was enhanced approximately by 6 orders of magnitude when the target 23S rRNA gene sequences were PCR amplified with a novel universal primer set and allowed hybridization to 24 species-specific oligonucleotide probes. The minimum detection limit was estimated to be about 100 fg of E. coli genomic DNA or 1.4 x 10(2) copies of the 23S rRNA gene. The PCR amplified DNA microarray successfully detected multiple bacterial pathogens in wastewater. As a parallel study to verify efficiency of the DNA microarray, a real-time quantitative PCR assay was also developed based on the fluorescent TaqMan probes (Applied Biosystems).