Rapid isolation of plasmid DNA by LiCl-ethidium bromide treatment and gel filtration.

We established a simple and rapid plasmid DNA purification method. Crude plasmid DNA preparations are treated with 4 M LiCl in the presence of 0.6 mg/ml ethidium bromide to precipitate RNA and proteins contained in the DNA preparations. After removal of RNA and protein precipitates, the supernatant is filtered through a Sepharose CL6B column to remove low-molecular-weight contaminants. This procedure takes only 30 min and provides pure plasmid DNA preparations that consist mainly of covalently closed circular plasmid DNA but have no detectable RNA and protein. The purified DNA preparations are susceptible to various six- and four-base-recognition restriction endonucleases, T4 DNA ligase, the Klenow fragment of DNA polymerase I, and T7 and Taq DNA polymerase. Since no special equipment is needed for this purification method, 20 or more samples of microgram to milligram levels can be treated in parallel.     

Purification and N-terminal amino acid sequences of two polypeptides encoded by the mcrB gene from Escherichia coli K-12.

This report provides a purification method for the two proteins, 51 kDa and 33 kDa, both encoded by the same mcrB gene of the McrBC restriction system in Escherichia coli K-12. The two proteins were produced in large quantity using a T7 expression system and copurified to near homogeneity by DEAE-Sepharose and Affi-Gel blue column chromatography. The N-terminal amino acid sequences of these purified McrB proteins were the same as those predicted from the mcrB DNA sequence by Ross et al. [J. Bacteriol. 171 (1989b) 1974-1981]. The 33-kDa protein totally overlaps the C-terminal part of the 51-kDa protein.     

Bacteriophage-host interaction and restriction of nonglucosylated T6.

Nonglucosylated T6 phage (T6gtam 16am30, hereafter called T6alpha gt-) were found to have two structural anomalies when compared with wild-type T6. The DNA of T6alpha gt- phage contains single-strand interruptions. These can be seen both during infection, in the pool of replicating DNA, and in DNA extracted from purified phage. In addition, the sodium dodecyl sulfate-polyacrylamide gel pattern of T6alpha gt- phage structural proteins reveals a protein band not found in T6. The altered protein has a mobility slightly faster than that of the major head protein, and it is not removed by osmotic shock. The restriction activity of Escherichia coli B directed against T6alpha gt- phage is abolished by preinfection of the cells for 4 min with T4 im m2. The shut-off of restriction is observed either by the rescue of superinfecting T6alpha gt- or by the failure to detect degradation of incoming T6alpha gt- DNA. This effect is resistant to rifampin and chloramphenicol.     

SAMase gene of bacteriophage T3 is responsible for overcoming host restriction.

Deletion and point mutants of T3 have been isolated and used to show that the early region of T3 DNA is organized in the same way as that of T7 DNA. Homologous early RNAs and proteins of the two phages have been identified by electrophoresis on polyacrylamide gels in the presence of sodium dodecyl sulfate. Both phages have five early mRNA's, numbered 0.3, 0.7, 1,1.1 and 1.3 from left to right, although no T3 protein that corresponds to the 1.1 protein of T7 has yet been identified. In general, corresponding early RNAs and proteins of the two phages migrate differently on gels, indicating that they differ in molecular weight and/or conformation. In both T7 and T3, gene 0.3 is responsible for overcoming the DNA restriction system of the host, gene 0.7 specifies a protein kinase, gene 1 specifies a phage-specific RNA polymerase, and gene 1.3 specifies a polynucleotide ligase. The 0.3 protein of T3 is responsible for the S-adenosylmethionine cleaving activity (SAMase) induced after T3 (but not T7) infection. However, cleaving of S-adenosylmethionine does not appear to be the primary mechanism by which T3 overcomes host restriction, since at least one mutant of T3 has lost the SAMase activity without losing the ability to overcome host restriction.     

Construction of an overproducing strain,purification, and biochemical characterization of the 6His-Eco29kI restriction endonuclease

We constructed a strain of Escherichia coli overproducing 6His-tagged Eco29kI by placing the coding sequence under control of a strong bacteriophage T5 promoter. The yield of 6His-Eco29kI restriction endonuclease expression could be increased to about 20% of the total cellular protein, but inclusion bodies formed consisting of insoluble 6His-Eco29kI protein. We developed a fast and effective protocol for purification of the homogeneous enzyme from both soluble and insoluble fractions and established their identity by catalytic activity assay. The isolated enzymes were tested for recognition specificity and optimal reaction conditions as a function of NaCl and KCl concentrations, temperature, and pH compared with the native Eco29kI restriction endonuclease. The 6His-tagged enzyme retained the specificity of the native protein but had an altered optimum of its catalytic reaction.     

Isolation, purification and properties of restriction endonuclease EcoRII

The restriction endonuclease Eco RII was isolated and purified to homogeneity. The isolation procedure involved the use of the E. coli strain B834/pSK323, containing the recombinant plasmide pSK323 which provides for the oversynthesis of Eco RII enzymes. Data from gel filtration and Na-DS electrophoresis suggest that the restriction endonuclease Eco RII is a protein made up of two subunits, each with molecular weight of 44 000.     

Gene 19 of bacteriophage T7. Overexpression, purification, and characterization of its product

Gene 18 and 19 proteins of bacteriophage T7 are essential for DNA maturation and packaging. The phage capsid is the site of both maturation and packaging of T7 DNA. Both gene 18 and 19 proteins bind to capsid intermediates during DNA packaging but are not found in mature virions, suggesting that they play a direct role in the enzymatic mechanisms of DNA maturation and packaging. As part of an effort to reconstitute T7 DNA maturation and packaging with purified components, we have cloned and overexpressed T7 gene 19 in Escherichia coli. Gene 19 has been inserted downstream from the bacteriophage PL promoter controlled by the temperature-sensitive lambda repressor encoded by c1857. Upon thermal induction, most of the overproduced gene 19 protein is insoluble and inactive. However, by attenuation of the expression of gene 19 from the PL promoter, significant levels of soluble and active gene 19 protein are produced. Soluble gene 19 protein can be monitored by its ability to complement extracts of T7-infected cells for packaging of exogenous DNA. We have used this assay to monitor the activity of gene 19 protein during purification. The native protein is a monomer of molecular weight 66,000. We have also tested for the formation of a stable complex between gene 18 and 19 proteins. Coproduction of gene 18 and 19 proteins has no effect on either the solubility or activity of gene 19 protein, despite the fact that gene 18 protein is produced at at least 10-fold greater rates. Furthermore, we find no evidence for any interaction between soluble gene 18 and 19 proteins in extracts or between the purified proteins.     

The DNA translocation and ATPase activities of restriction-deficient mutants of Eco KI.

Eco KI, a type I restriction enzyme, specifies DNA methyltransferase, ATPase, endonuclease and DNA translocation activities. One subunit (HsdR) of the oligomeric enzyme contributes to those activities essential for restriction. These activities involve ATP-dependent DNA translocation and DNA cleavage. Mutations that change amino acids within recognisable motifs in HsdR impair restriction. We have used an in vivo assay to monitor the effect of these mutations on DNA translocation. The assay follows the Eco KI-dependent entry of phage T7 DNA from the phage particle into the host cell. Earlier experiments have shown that mutations within the seven motifs characteristic of the DEAD-box family of proteins that comprise known or putative helicases severely impair the ATPase activity of purified enzymes. We find that the mutations abolish DNA translocation in vivo. This provides evidence that these motifs are relevant to the coupling of ATP hydrolysis to DNA translocation. Mutations that identify an endonuclease motif similar to that found at the active site of type II restriction enzymes and other nucleases have been shown to abolish DNA nicking activity. When conservative changes are made at these residues, the enzymes lack nuclease activity but retain the ability to hydrolyse ATP and to translocate DNA at wild-type levels. It has been speculated that nicking may be necessary to resolve the topological problems associated with DNA translocation by type I restriction and modification systems. Our experiments show that loss of the nicking activity associated with the endonuclease motif of Eco KI has no effect on ATPase activity in vitro or DNA translocation of the T7 genome in vivo.     

Gene 1.2 protein of bacteriophage T7. Effect on deoxyribonucleotide pools

The gene 1.2 protein of bacteriophage T7, a protein required for phage T7 growth on Escherichia coli optA1 strains, has been purified to apparent homogeneity and shown to restore DNA packaging activity of extracts prepared from E. coli optA1 cells infected with T7 gene 1.2 mutants (Myers, J. A., Beauchamp, B. B., White, J. H., and Richardson, C. C. (1987) J. Biol. Chem. 262, 5280-5287). After infection of E. coli optA1 by T7 gene 1.2 mutant phage, under conditions where phage DNA synthesis is blocked, the intracellular pools of dATP, dTTP, and dCTP increase 10-40-fold, similar to the increase observed in an infection with wild-type T7. However, the pool of dGTP remains unchanged in the mutant-infected cells as opposed to a 200-fold increase in the wild-type phage-infected cells. Uninfected E. coli optA+ strains contain severalfold higher levels of dGTP compared to E. coli optA1 cells. In agreement with this observation, dGTP can fully substitute for purified gene 1.2 protein in restoring DNA packaging activity to extracts prepared from E. coli optA1 cells infected with T7 gene 1.2 mutants. dGMP or polymers containing deoxyguanosine can also restore packaging activity while dGDP is considerably less effective. dATP, dTTP, dCTP, and ribonucleotides have no significant effect. The addition of dGTP or dGMP to packaging extracts restores DNA synthesis. Gene 1.2 protein elevates the level of dGTP in these packaging extracts and restores DNA synthesis, thus suggesting that depletion of a guanine deoxynucleotide pool in E. coli optA1 cells infected with T7 gene 1.2 mutants may account for the observed defects.     

Functional expression in Escherichia coli of proteins B and C from soluble methane monooxygenase of Methylococcus capsulatus (Bath).

Methylococcus capsulatus (Bath) uses a soluble methane monooxygenase (sMMO) to catalyse the oxidation of methane to methanol. sMMO is comprised of three components; A, B and C. Protein C (the reductase) transfers electrons from NADH to protein A (the hydroxylase) which contains the active site, and protein B regulates this electron flow. The five genes encoding the sMMO proteins and their subunits are clustered and have been cloned in Escherichia coli. A DNA fragment containing mmoB, the gene encoding protein B, was subcloned into pT7-5, a plasmid of the T7 RNA polymerase promoter expression system. Upon induction, E. coli expressed protein B which was fully functional after purification. The gene encoding protein C, mmoC, was amplified with unique restriction sites at each end using the polymerase chain reaction and then subcloned into pT7-7 (a plasmid similar to pT7-5 but containing its own ribosome-binding site and ATG start codon). Protein C expressed in E. coli was also found to be functional. This is the first report of the functional expression of methanotroph methane monooxygenase genes in a heterologous host and represents a significant step forward in our analysis of the assembly and catalysis of sMMO.     

Purification and properties of T4 phage thymidylate synthetase produced by the cloned gene in an amplification vector

We have introduced the T4 thymidylate synthetase gene, resident in a 2.7-kilobase EcoRI restriction fragment, into an amplification plasmid, pKC30. By regulating expression of this gene from the phage lambda pL promoter within pKC30 in a thyA host containing a temperature-sensitive lambda repressor, the T4 synthetase could be amplified about 200-fold over that after T4 infection. At this stage, a 20-fold purification was required to obtain homogeneous enzyme, mainly by an affinity column procedure. The purified plasmid-amplified T4 synthetase appeared to be identical with the T2 phage synthetase purified from phage-infected Escherichia coli in molecular weight, amino end group analysis, and immunochemical reactivity. The individual nature of the phage and host proteins was revealed by the fact that neither the T2 nor the T4 enzyme reacted with antibody to the E. coli synthetase, nor did antibody to the phage enzymes react with the E. coli synthetase. These differences were corroborated by DNA hybridization experiments, which revealed the absence of apparent homology between the T4 and E. coli synthetase genes. The techniques and genetic constructions described support the feasibility of employing similar amplification methods to prepare highly purified thymidylate synthetases from other sources.     

Host-Controlled Modification and Restriction of Bacteriophage T7 by Escherichia coli B

T7 phage resists Escherichia coli B host-controlled modification and restriction in vivo, but its DNA carries roughly five sites which are susceptible to the purified enzymes.     

Deoxyribonucleic acid polymerase of bacteriophage T7. Purification and properties of the phage-encoded subunit, the gene 5 protein.

DNA polymerase of bacteriophage T7 is composed of two subunits, the gene 5 protein of the phage and the host-specified thioredoxin. The gene 5 protein has been purified 7400-fold to homogeneity from bacteriophage T7-infected Escherichia coli 7400 trxA cells that lack thioredoxin. The purification procedure has been monitored by using a complementation assay in which thioredoxin interacts with the gene 5 protein to form an active DNA polymerase. The purified gene 5 protein is a single polypeptide having a molecular weight of 87,000. The gene 5 protein itself has only 1 to 2% of the polymerase activity of T7 DNA polymerase. However, T7 DNA polymerase can be reconstituted by the addition of homogeneous thioredoxin to the gene 5 protein. Optimal reconstitution is obtained when the molar ratio of thioredoxin/gene 5 protein is 150. Under these conditions, the gene 5 protein attains approximately 80% of the activity of an equal amount of T7 DNA polymerase. The apparent Km for thioredoxin in the reaction to restore DNA polymerase activity is 2.8 x 10(-8) M. The enzymatic properties of the reconstituted enzyme are indistinguishable from those of T7 DNA polymerase synthesized in vivo; the reconstituted polymerase interacts with T7 gene 4 protein to catalyze DNA synthesis on duplex DNA templates.     

Dark Repair of Ultraviolet-Irradiated Deoxyribonucleic Acid by Bacteriophage T4: Purification and Characterization of a Dimer-Specific Phage-Induced Endonuclease

The purification and properties of an ultraviolet (UV) repair endonuclease are described. The enzyme is induced by infection of cells of Escherichia coli with phage T4 and is missing from extracts of cells infected with the UV-sensitive and excision-defective mutant T4V(1). The enzyme attacks UV-irradiated deoxyribonucleic acid (DNA) containing either hydroxymethylcytosine or cytosine, but does not affect native DNA. The specific substrate in UV-irradiated DNA appears to be pyrimidine dimer sites. The purified enzyme alone does not excise pyrimidine dimers from UV-irradiated DNA. However, dimer excision does occur in the presence of the purified endonuclease plus crude extract of cells infected with the mutant T4V(1).     

Cloning the polB gene of Escherichia coli and identification of its product

Using an in vivo mini-Mu cloning system, we have cloned the polB gene of Escherichia coli into the multicopy plasmid, pUC18. A chromosomal insert of 4.9 kilobases gave 30-40-fold overproduction of DNA polymerase II, and the cells containing the plasmid showed normal growth. The restriction pattern of the polB gene does not match that of either the polA gene or polC gene. Plasmid-directed protein synthesis demonstrates peptides of 99 and 82 kDa which are not expressed by derivative plasmids without DNA polymerase II activity. It appears from in situ gel assays and high performance liquid chromatography that 82- and 55-kDa proteins are derived from the 99-kDa protein by degradation, but all retain activity. DNA polymerase I or DNA polymerase III antibody does not inhibit the synthesis reaction of partially purified DNA polymerase II, but DNA polymerase II antibody does. By the criteria of restriction pattern of the polB gene, molecular weight of the protein, and antibody inhibition of reaction, DNA polymerase II can be demonstrated to be a distinct DNA polymerase.