Letter: The isolation and properties of the specific binding sites for Escherichia coli RNA polymerase on T4 and T7 bacteriophage DNAs.

RNA polymerase of Escherichia coli was allowed to bind to labeled T4 or T7 bacteriophage DNA. The unbound and “weakly” bound polymerase molecules were removed by adding an excess of poly(I) which has a high affinity for the enzyme (Bautz et al., 1972). After the unbound DNA regions were digested with pancreatic DNAase and snake venom phosphodiesterase, the “protected” DNA-RNA polymerase complexes were isolated by Sephadex G200 column chromatography. The protected DNA sites were then isolated by phenol extraction and hydroxylapatite chromatography. Studies of the DNA recognition regions led to the following conclusions. (1) No binding is observed in the absence of the sigma subunit or at low temperatures. (2) The amount of protection ranges from 0·18% to 0·24% of T4 DNA and from 0·25% to 0·34% of T7 DNA. In the absence of poly(I), higher protections are observed and the protected regions display heterogeneity in size and secondary structure. (3) The protected regions are double-stranded, as shown by hydroxylapatite chromatography, base composition analysis, and thermal chromatography. (4) The length of the protected regions comprise about 50 to 55 nucleotide pairs, as suggested by end-group analysis, sucrose density-gradient centrifugation, and polyacrylamide gel electrophoresis. (5) The results suggest the interaction of dimeric polymerase molecules at these sites. On the basis of DNA sizes, there are 7 to 9 such sites on T4 DNA and 2 to 3 on T7 DNA. (6) The protected regions are high in (A + T): 68% for T4 and 62% for T7 DNA. (7) Thermal chromatograms reflect these base compositions and suggest the homogeneity of these regions with respect to size and base composition.     

The interaction of platinum II compounds with bacteriophages T7 and R17

The inactivation of the DNA-containing bacteriophage T7 and of the RNA-containing bacteriophage R17 by dichloro-ethylenediamine Pt II and by cis- and trans-dichloro-diammine Pt II has been studied under a variety of experimental conditions. It has been found that the mean lethal concentrations vary for T7 from 0.007 to 0.5 μg/ml and for R17 from 0.09 to 1.1 μg/ml depending upon which compound is used and the manner in which the experiment is performed. Experiments with the ¹⁴C-labelled ethylenediamine derivative have shown that inactivation is primarily related to the extent of reaction of the compound with the bacteriophage and that variations in inactivation observed under different experimental conditions simply reflect differences in the kinetics of the binding reactions. Quantitative comparisons have shown that at the mean lethal dose 1.5 molecules of platinum compound are bound to each R17 bacteriophage and 5 molecules to each T7.96% of the compound bound to R17 was bound to RNA and 76% of the compound bound to T7 was bound to the DNA.     

Studies of the binding of Escherichia coli RNA polymerase to DNA. V. T7 RNA chain initiation by enzyme-DNA complexes

Initiation of T7 RNA chains by Escherichia coli RNA polymerase-T7 DNA complexes has been followed using incorporation of λ-³²P-labeled ATP and GTP to determine the relation between the enzyme binding sites and RNA chain initiation sites on the T7 genome. If the period of RNA synthesis is limited to less than two minutes, the stoichiometry of RNA chain initiation can be measured in the absence of chain termination and re-initiation. About 70% of the RNA polymerase holoenzyme molecules in current enzyme preparations are able to rapidly initiate a T7 RNA chain. The ratio of ATP- to GTP-initiated T7 RNA chains is not altered by variations in the number of enzyme molecules added per DNA, nor by alterations in the ionic conditions employed for RNA synthesis. This suggests that RNA chain initiation sites are chosen randomly through binding of RNA polymerase to tight (class A) binding sites on T7 DNA.     

Template recognition and chain elongation in DNA synthesis in vitro.

DNA polymerase from Escherichia coli (Pol I) and from avian myeloblastosis virus (AMV polymerase) were compared for the manner in which they catalyze the polymerization of deoxynucleotides upon a variety of synthetic and natural templates. It was found that the rates of nucleotide incorporation with different natural RNAs were similar. Both polymerases have an associated RNA endonuclease which hydrolyses RNA templates containing double-stranded regions. This activity depends on the presence of the complementary deoxynucleoside triphosphates, and/or polymerization. Both enzymes copy natural DNA, which has been sonicated and treated with E. coli exonuclease III, at the same rate. However, avian myeloblastosis virus DNA polymerase, which has no associated DNA exonuclease activity, is unable to copy double-stranded DNA and copies DNAase-treated DNA only 10% as well as Pol I. Pol I copied all the homopolymers investigated at a greater rate than AMV polymerase with the exception of poly(C) · oligo(dG). However, the initial rate of chain elongation, as measured by gel electrophoresis, was the same for the two polymerases, approximately 300 nucleotides incorporated per minute. Template saturation experiments show a stoichiometric relationship between template and enzyme at optimal rates of nucleotide incorporation which suggests that all enzyme molecules are potential catalysts. Enzyme saturation experiments indicate that not all enzyme molecules are “effectively” bound to a template. Fewer AMV polymerase than Pol I molecules are functionally bound to a particular template. From these data, it is concluded that the two polymerases elongate DNA chains in a similar way and that the manner in which the polymerases bind to a particular template accounts for the discrepancies found in their turnover numbers.     

Electron microscopic analysis of DNA forks generated by Escherichia coli DNA helicase II

T7 phage DNA eroded with lambda exonuclease (to create 3'-protruding strands) or exonuclease III (to create 5'-protruding strands) was treated under unwinding assay conditions with DNA helicase II. Single-stranded DNA-binding protein (of Escherichia coli or phage T4) was added to disentangle the denatured DNA and the complexes were examined in the electron microscope. DNA helicase II complexes filtered through a gel column before assay retain the ability to generate forks suggesting that DNA helicase II unwinds in a preformed complex by translocating along the bound DNA strand. The enzyme initiates preferentially at the ends of the lambda-exonuclease-treated duplexes and is found at a fork on the initially protruding strand. It also initiates at the ends of the exonuclease-III-treated duplexes where, as with approximately 5% of the forks traceable back to a single-stranded gap, it is found on the initially recessed strand. The results are consistent with the view that DNA helicase II unwinds in the 3'-5' direction relative to the bound strand. They also confirm that the enzyme can initiate at the end of a fully base-paired strand. At a fork, DNA helicase II is bound as a tract of molecules of approximately 110 nm in length. Tracts of enzyme assemble from non-cooperatively bound molecules in the presence of ATP. During unwinding, DNA helicase II apparently can translocate to the displaced strand which conceivably can deplete the leading strand of the enzyme. Continued adsorption of enzyme to DNA might replenish forks arrested by strand switch of the unwinding enzyme.     

T4 DNA polymerase: Rates and processivity on single-stranded DNA templates

Three different methods have been used to determine the rate at which an individual bacteriophage T4 DNA polymerase molecule moves when synthesizing DNA on a single-stranded DNA template chain. These methods agree in suggesting an in vitro rate for this enzyme of about 250 nucleotides per second at 37 °C. This rate is close to the rate at which bacteriophage T4 replication forks move in vivo (about 500 nucleotides per second). Comparison with the overall amount of DNA synthesis seen in in vitro reactions reveals that only a small fraction of the T4 DNA polymerase molecules present are synthesizing DNA at any one time. This is explicable in terms of the limited processivity of the enzyme in these reactions, along with its capacity for non-productive DNA binding to the DNA template molecules.     

DNA methylases of Hemophilus influenzae Rd. I. Purification and properties

Hemophilus influenzae strain Rd DNA contains small amounts of 5-methylcytosine (0.012%) and significantly greater amounts of N-6-methyladenine (0.34%). Four DNA adenine methylases have been identified and purified from crude extracts of H. influenzae Rd by means of phosphocellulose chromatography. Each of the four enzymes requires (S-adenosyl-l-methionine as a methyl group donor and each differs in its ability to methylate various DNAs in vitro. DNA methylase I is related to the genetically described modification-restriction system in H. influenzae Rd, and is presumably the modification enzyme for that system. DNA methylase II introduces approximately 130 methyl groups into a phage T7 DNA molecule and protects T7 DNA from the H. influenzae Rd restriction enzyme, endonuclease R, described by Smith and Wilcox (1970). These findings indicate that DNA methylase II is the modification enzyme corresponding to endonuclease R. A third modification-restriction system, which does not affect T7 DNA, has been detected in H. influenzae Rd. DNA methylase III is apparently the modification enzyme for this system. The biological function of DNA methylase IV remains unknown.     

Action of ATP-dependent DNase from Hemophilus influenzae on cross-linked DNA molecules.

The ATP-dependent DNase from Hemophilus influenzae digests double-stranded linear DNA molecules exonucleolytically while hydrolyzing large amounts of ATP to ADP. Various cross-linked linear duplex DNA molecules are partially resistant to the exonuclease action. Vaccinia DNA, containing natural terminal cross-links (probably in the form of terminal single-stranded loops), is much more slowly degraded than comparable "open-ended" DNA molecules, and ATP is consumed at a proportionately lower rate. It is postulated that the vaccinia DNA molecules undergo slow terminal cleavage by the single strand specific endonuclease activity of the enzyme, and are then rapidly degraded by the double strand exonuclease activity. Phage T7 DNA, containing an average of 100 4',5'8-trimethylpsoralen cross-links/molecule at random internal sites, is digested only to the extent of 2 to 3%. However, ATP hydrolysis continues at a linear rate long after DNA digestion has ceased. A stable enzyme-DNA complex is formed as demonstrated by co-sedimentation of DNA and ATPase activity in sucrose gradients. The hypothesis is advanced that the enzyme digests exonucleolytically to the first cross-link at each end of the DNA molecules where further movement is prevented. The enzyme then remains bound at the cross-links and functions continuously as an ATPase.     

Investigation of the binding of Escherichia coli RNA polymerase to DNA from bacteriophages T2 and T7 by kinetic formaldehyde method and electron microscopy.

The complexes of T2 DNA with RNA polymerase of Escherichia coli were studied by two methods: kinetic formaldehyde method with preliminary fixation of complexes with low formaldehyde concentrations, and electron microscopy. For electron-microscopic investigations the effect of different conditions of formaldehyde fixation for DNA-RNA-polymerase complexes was studied and optimal fixation conditions were found. The suggested fixation method for DNA-RNA-polymerase complexes allows investigation of RNA polymerase molecule distribution on DNA in a wide range of conditions (ionic strength of the solution, weight ration of enzyme to DNA etc.). The comparison of the concentration of RNA polymerase molecules bound to DNA, determined by electron microscopy, and the concentration of defects in DNA as determined by the kinetic formaldehyde method, showed their coincidence. The electron-microscopic procedure was used to make maps of RNA polymerase distribution on T7 DNA. A correlation between the binding regions of the enzyme and the genetic map of early DNA T7 region was found.     

Studies on deoxyribonucleic acid-dependent ribonucleic acid polymerase from Escherichia coli. Variations of the enzyme activity during growth

1. RNA polymerase activity of Escherichia coli extracts prepared from cells in exponential and stationary phases of growth, when measured in the presence and absence of external template, showed significant qualitative differences. 2. In both extracts, polymerase activity was higher when assayed with external template, suggesting the presence of a pool of enzyme not bound to cellular DNA. 3. In the crude extract, the fraction of enzyme bound to cellular DNA is higher during the exponential phase of growth. 4. A method is described for the purification of enzyme molecules not tightly bound to cellular DNA from exponential- and stationary-phase cultures. 5. Purified enzyme preparations showed differences in template requirement and subunit composition. 6. On phosphocellulose chromatography of stationary-phase enzyme, a major portion of polymerase activity eluted from the column with 0.25m-KCl. In the case of exponential-phase enzyme, polymerase activity eluted from a phosphocellulose column mainly with 0.35m-KCl. 7. Enzyme assays done with excess of bacteriophage T(4) DNA showed a strong inhibition of stationary-phase enzyme by this template. The exponential-phase enzyme was only slightly inhibited by excess of bacteriophage T(4) DNA.     

Gene 3 endonuclease of bacteriophage T7 resolves conformationally branched structures in double-stranded DNA

Gene 3 endonuclease of bacteriophage T7 has been expressed from the cloned gene, purified, and characterized as to its activity on different DNA substrates. Besides its known strong preference for cutting single-stranded DNA rather than double-stranded DNA, the enzyme has a strong preference for cutting conformationally branched structures in double-stranded DNA, either X or Y-shaped branches. Three types of branched DNA substrates were used: relaxed circular DNAs containing large cruciform structures (a model for Holliday structures, presumed intermediates in genetic recombination); X-shaped molecules having a limited potential for branch migration, made from the cloned phage and bacterial arms of the lambda attachment site; and Y-shaped molecules, made by hybridizing molecules homologous except for a 2 X 21 base-pair palindrome in one of them. Gene 3 endonuclease cuts two opposing strands at or near the branchpoint to resolve these substrates into linear molecules, and does not cut the potentially single-stranded tips of the stem-and-loop structure generated from the palindrome. The position of the cleavage points on the equivalent arm of two X-shaped molecules, constructed from wild-type and mutant lambda attachment sites, show that the enzyme can cut at several different sites within or slightly 5' of the limited region of branch migration. The various activities of gene 3 endonuclease are consistent with the known role of this enzyme in genetic recombination, in maturation and packaging of T7 DNA, and in degradation of host DNA, and suggest that the enzyme recognizes a specific structural feature in DNA. Its cleavage specificity, ready availability, and ability to act at physiological pH and ionic conditions may make gene 3 endonuclease useful as a probe for specific DNA structures or for binding of proteins that alter DNA structure.     

Specific labelling of the active site of T7 RNA polymerase.

We describe a method for specifically labelling T7 RNA polymerase at (or near) the active site. Enzyme molecules that have been modified by covalent attachment of a benzaldehyde nucleotide derivative in the presence of template DNA are subsequently incubated with radioactively labelled nucleoside triphosphates. Labelling of the enzyme occurs as a result of the formation of the first phosphodiester bond. The labelling is template-directed and the expected specificity of initiation at individual T7 promoters is observed. The label has been localized to an 80 kd tryptic fragment that contains the carboxy-terminal portion of the enzyme.     

Determination of concentration and activity of immobilized enzymes

Methods that directly measure the concentration of surface-immobilized biomolecules are scarce. More commonly, the concentration of the soluble molecule is measured before and after immobilization, and the bound concentration is assessed by elimination, assuming that all bound molecules are active. An assay was developed for measuring the active site concentration, activity, and thereby the catalytic turnover rate (k_cat) of an immobilized dihydrofolate reductase as a model system. The new method yielded a similar first-order rate constant, k_cat, to that of the same enzyme in solution. The findings indicate that the activity of the immobilized enzyme, when separated from the surface by the DNA spacers, has not been altered. In addition, a new immobilization method that leads to solution-like activity of the enzyme on the surface is described. The approaches developed here for immobilization and for determining the concentration of an immobilized enzyme are general and can be extended to other enzymes, receptors, and antibodies.     

Binding of Escherichia coli RNA polymerase to T7 DNA. Displacement of holoenzyme from promoter complexes by heparin.

Escherichia coli RNA polymerase holoenzyme bound to promoter sites on T7 DNA is attacked and inactivated by the polyanion heparin. The highly stable RNA polymerase-T7 DNA complex formed at the major T7 A1 promoter can be completely inactivated by treatment with heparin, as shown by monitoring the loss of activity of such complexes, and by gel electrophoresis of the RNA products transcribed. The rate of this inactivation is much faster than the rate of dissociation of RNA polymerase from promoter complexes, and thus represents a direct attack of heparin on the polymerase molecule bound at promoter A1. Experiments employing the nitrocellulose filter binding technique suggest that heparin inactivates E. coli RNA polymerase when bound to T7 DNA by directly displacing the enzyme from the DNA. RNA polymerase bound at a minor T7 promoter (promoter C) is much less sensitive to heparin attack than enzyme bound at promoter A1. Thus, the rate of inactivation of RNA polymerase-T7 DNA complexes by heparin is dependent upon the structure of the promoter involved even though the inhibitor binds to a site on the enzyme molecule.     

DNA sequence for the T7 RNA polymerase promoter for T7 RNA species II

The DNA sequence for the T7 late region class III promoter for T7 RNA species II has been determined. I have found that the DNA sequence for this promoter presented in an earlier report (Oakley et al., 1979) is incorrect and that this class III promoter contains a 23 base-pair sequence identical to those present in all other T7 class III promoters (Rosa, 1979). The T7 RNA species II promoter has been located at 68% on the T7 genome.     

T4 endonuclease V exists in solution as a monomer and binds to target sites as a monomer

Endonuclease V, a N-glycosylase/lyase from T4 bacteriophage that initiates the repair of cyclobutane pyrimidine dimers in DNA, has been reported to form a monomer-dimer equilibrium in solution [Nickell and Lloyd (1991) Biochemistry 30, 8638], although the enzyme has only been crystallized in the absence of substrate as a monomer [Morikawa et al. (1992) Science 256, 523]. In this study, analytical gel filtration and sedimentation equilibrium techniques were used to rigorously characterize the association state of the enzyme in solution. In contrast to the previous report, at 100 mM KCl endonuclease V was found to exist predominantly as a monomer in solution by both of these techniques; no evidence for dimerization was seen. To characterize the oligomeric state of the enzyme at its target sites on DNA, the enzyme was bound to oligonucleotides containing a single site specific pyrimidine dimer or tetrahydrofuran residue. These complexes were analyzed by nondenaturing gel electrophoresis at various acrylamide concentrations in order to determine the molecular weights of the enzyme-DNA complexes. The results from these experiments demonstrate that endonuclease V binds to cyclobutane pyrimidine dimer and tetrahydrofuran site containing DNA as a monomer.