Affinity labeling of E. coli RNA polymerase with substrate and template analogues

Irradiation of E.coli RNA polymerase at 330–360 nm in the presence of either 4-thiouridine triphosphate or polydeoxy-4-thiothymidylic acid leads to covalent substitution by substrate or template analogue and causes irreversible inactivation of the enzyme. Evidence for specific inactivation was obtained from kinetic experiments. The sites of chemical modification of RNA polymerase were shown to be exclusively the subunits β′ and β.     

Initiation, elongation and pausing of in vitro DNA synthesis catalyzed by immunopurified yeast DNA primase: DNA polymerase complex.

Yeast DNA primase and DNA polymerase I can be purified by immunoaffinity chromatography as a multipeptide complex which can then be resolved into its functional components and further reassembled in vitro. Isolated DNA primase synthesizes oligonucleotides of a preferred length of 9-10 nucleotides and multiples thereof on a poly(dT) template. In vitro reconstitution of the DNA primase:DNA polymerase complex allows the synthesis of long DNA chains covalently linked to RNA initiators shorter than those synthesized by DNA primase alone. The SS (single-stranded) circular DNA of phage M13mp9 can also be replicated by the DNA primase:DNA polymerase complex. Priming by DNA primase occurs at multiple sites and the initiators are utilized by the DNA polymerase moiety of the complex, so that almost all the SS template is converted into duplex form. The rate of DNA synthesis catalyzed by isolated yeast DNA polymerase I on the M13mp9 template is not constant and is characterized by distinct pausing sites, which partly correlate with secondary structures on the template DNA. Thus, replication of M13mp9 SS DNA with the native primase:polymerase complex gives rise to a series of DNA chains with significantly uniform termini specified by the primase start sites and the polymerase stop sites.     

Apparent suicidal inactivation of DNA polymerase by adenosine 2',3'-riboepoxide 5'-triphosphate.

Adenosine 2',3'-riboepoxide 5'-triphosphate (epoxyATP) has been found to be a suicidal inactivator of DNA polymerase I from Escherichia coli by the following criteria. Inactivation is complete, is first order in enzyme activity, and shows saturation kinetics with an apparent KD of 30 +/- 10 micron for epoxy ATP. This KD is comparable to the KM of the substrate dATP. The t1/2 for inactivation is 1.3 min. Inactivation requires Mg2+ and the complementary template. The enzyme is protected by dATP but not by an excess of template. Gel filtration of the reaction mixture after inactivation with [3H]epoxy ATP results in the comigration of E. coli DNA polymerase I, the tritium-labeled inactivator, and the DNA template. The stoichiometry of binding approaches 1 mol of [3H]epoxy nucleotide per mol of inactivated enzyme. These results are consistent with the hypothesis that epoxy ATP initially serves as a substrate for the polymerase reaction, elongating the DNA chain by a nucleotidyl unit, and subsequently alkylates an essential base at the primer terminus binding site of the enzyme. Epoxy ATP also inactivates human and viral DNA polymerases but not E. coli RNA polymerase or rabbit muscle pyruvate kinase. Hence epoxy ATP may be a specific suicide reagent for DNA polymerases.     

Priming of superhelical SV40 DNA by Escherichia coli RNA polymerase for in vitro DNA synthesis.

When closed circular SV40 DNA containing 58 negative superhelical turns is used as a template for RNA synthesis with Escherichia coli RNA polymerase, a fraction of the RNA product remains complexed with the DNA. The RNA in the complex is resistant to ribonuclease in high salt, and the Tm indicates that it is hydrogen bonded to the DNA. The mole ratio of RNA to DNA nucleotides in the complex ranges from 0.01 to 0.08; the RNA ranges in length from 80 to 600 nucleotides. The formation of the complex is dependent on the circular DNA being topologically underwound since no complex is formed when closed circular DNA containing zero superhelical turns is used as the template. The DNA-RNA complex can serve as a primer-template combination for in vitro DNA synthesis by E. coli DNA polymerase I. After synthesis with (alpha-32P)-labeled deoxyribonucleoside triphosphates followed by alkaline hydrolysis, the isolation of 32P-labeled ribonucleotides is evidence for a covalent linkage between the RNA and the DNA synthesized. During the in vitro DNA synthesis, the template is nicked at a low rate, and the nicked molecules support extensive DNA synthesis. This observation indicates that only limited synthesis can occur on unnicked molecules possibly owing to the topological constraints against unwinding of the helix. Possible models for in vivo priming of double-stranded DNA by E. coli RNA polymerase are discussed.     

DNA primase and the replication of the telomeres in Oxytricha nova.

An enzymatic activity in crude extracts of macronuclei from the hypotrichous ciliate Oxytricha nova catalyzes the synthesis of RNA consisting of (C4A4)n using an oligodeoxynucleotide template of the telomeric sequence (dG4T4)n. Single-stranded (dG4T4)n is an effective template if it has a random sequence at its 5' end. The enzyme will not use a (dG4T4)n template of any length (up to 64 bases) if it lacks a random sequence at the 5' end. With a random, single-stranded sequence at the 5' end, the (dG4T4)n oligodeoxynucleotide must be at least 36 bases long to work as a template. A 16-base, single-stranded region of (dG4T4)2 is an effective template when joined to a 20-base double-stranded region of (dG4T4)n/(dA4dC4)n, a structural arrangement that is the same as the native telomere of Oxytricha macronuclear DNA. The RNA-synthesizing activity is unaffected by 1.0 mg/ml of alpha-amanitin. Macronuclear extracts have an alpha-amanitin-insensitive, RNA-polymerizing activity that can use a random 55mer oligodeoxynucleotide as a template. This enzyme activity may be the same one that uses (dG4T4)n templates to make (C4A4)n RNA. The (C4A4)n RNA made in the reaction can prime DNA synthesis by the E. coli DNA polymerase I Klenow fragment. Therefore, the RNA polymerase activity fulfills the requirements of the telomere DNA primase that we postulated for replication of telomeres in hypotrichs (Zahler and Prescott, 1988, Nucleic Acids Research 16, 6953-6972).     

Yeast DNA primase and DNA polymerase activities. An analysis of RNA priming and its coupling to DNA synthesis

The yeast DNA primase-DNA polymerase activities catalyze de novo oligoribonucleotide primed DNA synthesis on single-stranded DNA templates (Singh, H., and Dumas, L. B. (1984) J. Biol. Chem. 259, 7936-7940). In the presence of ATP substrate and poly(dT) template, the enzyme preparation synthesizes discrete-length oligoribonucleotides (apparent length 8-12) and multiples thereof. The unit length primers are the products of de novo processive synthesis and are precursors to the synthesis of the multimers. Multimeric length oligoribonucleotides are not generated by continuous processive extension of the de novo synthesis products, however, nor do they arise by ligation of unit length oligomers. Instead, dissociation and rebinding of a factor, possibly the DNA primase, results in processive extension of the RNA synthesis products by an additional modal length. Thus, catalysis by the yeast DNA primase can be viewed as repeated cycles of processive unit length RNA chain extension. Inclusion of dATP substrate results in three distinct transitions: (i) coupling of RNA priming to DNA synthesis, (ii) suppression of multimer RNA synthesis, and (iii) attenuation of primer length. The less than unit length RNA primers appear to result from premature DNA chain extension, not degradation from either end of the unit length primer. We discuss possible roles of DNA polymerase and DNA primase in RNA primer attenuation.     

Interaction of human DNA polymerase beta with ions of copper, lead, and cadmium

Under appropriate conditions, divalent copper, lead, and cadmium ions significantly inhibit human DNA polymerase β (following accepted convention, the term DNA polymerase β refers to the low-molecular-weight, 3–4 S DNA polymerase of eukaryotic cells) at concentrations below 10^?5m. Each metal showed apparent linear noncompetitive inhibition kinetics with respect to the template primer and the deoxynucleoside triphosphate substrate, indicating that complex formation with these components does not account for the inhibition. Apparently, neither lead nor cadmium inhibit by displacing required zinc atoms from the polymerase. The interaction of the metals with the enzyme can be reversed or prevented by EDTA or by thiol compounds, except that inhibition by cadmium ions can be reversed by monothiols but not by dithiols. The metals probably do not inhibit through reaction with thiol groups since the inhibition is not decreased by pretreating the enzyme with N-ethylmaleimide. Although divalent zinc is moderately inhibitory in manganese activated poly(dT) synthesis on a poly(dA) template, it can fill the requirement for a divalent metal ion and, under the conditions tested, is about 60% as effective as Mn²⁺.     

Herpes simplex virus type 1 DNA polymerase. Mechanism-based affinity chromatography

The potent inhibition of herpes simplex type 1 (HSV-1) DNA polymerase by acyclovir triphosphate has previously been shown to be due to the formation of a dead-end complex upon binding of the next 2'-deoxynucleoside 5'-triphosphate encoded by the template after incorporation of acyclovir monophosphate into the 3'-end of the primer (Reardon, J. E., and Spector, T. (1989) J. Biol. Chem. 264, 7405-7411). This mechanism of inhibition of HSV-1 DNA polymerase has been used here to design an affinity column for the enzyme. A DNA hook template-primer containing an acyclovir monophosphate residue on the 3'-primer terminus has been synthesized and attached to a resin support. In the absence of added nucleotides, the column behaves as a simple DNA-agarose column, and HSV-1 DNA polymerase can be chromatographed using a salt gradient. The presence of the next required nucleotide encoded by the template (dGTP) increases the affinity of HSV-1 DNA polymerase for the acyclovir monophosphate terminal primer-template attached to the resin, and the enzyme is retained even in the presence of 1 M salt. The enzyme can be eluted from the column with a salt gradient after removal of the nucleotide from the buffer. Traditionally, the affinity purification of an enzyme relies on elution by a salt gradient, pH gradient, or more selectively by addition of a competing ligand (substrate/inhibitor) to the elution buffer. In the present example, elution of HSV-1 polymerase is facilitated by removal of the substrate from the buffer. This represents an example of mechanism-based affinity chromatography.     

Mechanism of inhibition of RNA polymerase II and poly(adenylic acid) polymerase by the O-n-octyloxime of 3-formylrifamycin SV.

Factors affecting the inhibition of RNA polymerase II from rat liver by the O-n-octyloxime of 3-formylrifamycin SV (AF/013) were investigated. Using either native or denatured calf-thymus DNA as template, almost complete inhibition of RNA polymerase II was observed when AF/013 was added directly to the enzyme. Considerable resistance to AF/013 was observed when RNA polymerase II was preincubated with denatured DNA at either 0 or 37 degrees. However, under similar conditions, no resistance was observed when enzyme was preincubated with native DNA. Only when AF/013 was added to the ongoing reaction using native DNA did a resistance to AF/013 occur. The inhibition of RNA polymerase II by AF/013 was competitive with respect to all four nucleoside triphosphate substrates. The inhibition by AF/013 remaining after enzyme-DNA complex formation also appeared competitive with nucleoside triphosphate levels. The effect of exogenous protein (bovine serum albumin, BSA) on the inhibition of RNA polymerase II was also investigated. BSA reduced the extent of inhibition by AF/013, but did not alter the competitive nature of inhibition. Concurrently, the inhibition of highly purified nuclear poly(A) polymerase from rat liver, a template independent enzyme which incorporates AMP in a chain elongation reaction, was examined. As in the case of RNA polymerase, poly(A) polymerase was inhibited by AF/013 in a manner competitive with the nucleoside triphosphate substrate. The competitive nature of inhibition of RNA polymerase by AF/013 with respect to all four nucleoside triphosphate substrates, before and after enzyme-DNA complex formation, as well as the competitive nature of inhibition of poly(A) polymerase with respect to ATP tend to indicate that the major effect of AF/013 on RNA polymerase II is at the level of the substrate binding as opposed to a specific inhibition of initiation.     

The nature of initiation sites on DNA for the core RNA polymerase

Summary The biological significance of the low level of symmetric and non-specific RNA synthesis catalyzed by the core RNA polymerase devoid of the sigma factor has been analyzed. Shearing of DNA's including T4 DNA markedly increased the template activities with the core enzyme but not with the holoenzyme. This finding suggests that RNA synthesis by the core enzyme increases concomittantly with the production of termini in DNA. Double-stranded circular DNA's such as dv and fd-RFI were found to be inactive as templates for the core enzyme, but were made active by introduction of single-strand nicks with deoxyribonuclease. In contrast, single-stranded circular DNA (X 174) served as a good template for RNA synthesis by the core RNA polymerase. These findings suggest that the sigma factor may activate double-stranded DNA at the promotor sites by creating proper initiation points for RNA synthesis. Partial separation of duplex DNA into single-stranded forms at the promotor sites could be one of the processes in the reaction catalyzed by the holoenzyme containing the sigma factor.     

DNA polymerase alpha cofactors C1C2 function as primer recognition proteins

Most, if not all, of the DNA polymerase alpha activity in monkey and human cells was complexed with at least two proteins, C1 and C2, that together stimulated the activity of this enzyme from 180- to 1800-fold on low concentrations of denatured DNA, parvovirus DNA, M13, and phi X174 DNA or RNA-primed DNA templates, and poly(dT):oligo(dA) or oligo(rA). These primer-template combinations, which have from 200 to 5000 bases of template/primer, were then 7- to 50-fold more effective as substrates than DNase I-activated DNA. C1C2 specifically stimulated alpha polymerase, and only from the same cell type. Alpha X C1C2-polymerase reconstituted from purified alpha polymerase and the C1C2 cofactor complex behaved the same as native alpha X C1C2-polymerase and C1C2 had no effect on the sensitivity of alpha polymerase to aphidicolin, dideoxythymidine triphosphate, and N-ethylmaleimide. In the presence of substrates with a high ratio of single-stranded DNA template to either DNA or RNA primar, C1C2 increased the rate of DNA synthesis by decreasing the Km for the DNA substrate, decreasing the Km for the primer itself, increasing the use of shorter primers, and stimulating incorporation of the first deoxyribonucleotide. In contrast, C1C2 had no effect on the Km values for deoxyribonucleotide substrates (which were about 150-fold higher than for DNA replication in isolated nuclei), the ability of specific DNA sequences to arrest alpha polymerase, or the processivity of alpha polymerase. Accordingly, C1C2 function as primer recognition proteins. However, C1C2 did not reduce the comparatively high Km values or stimulate DNA synthesis by alpha polymerase on lambda DNA ends and DNase I-activated DNA, substrates with 12 and about 30-70 bases of template/primer, respectively. DNA restriction fragments with 1 to 4 bases of template/primer were substrates for neither alpha nor alpha X C1C2-polymerase. Therefore, we propose that C1C2 enhances the ability of alpha polymerase to initiate DNA synthesis by eliminating nonproductive binding of the enzyme to single-stranded DNA, allowing it to slide along the template until it recognizes a primer.     

Specificity of sigma-dependent binding of RNA polymerase to DNA

Summary Although a large number of E. coli RNA polymerase molecules can bind to phage T3 DNA, not more than three remain bound per DNA template after addition of poly inosinic acid (poly I) which has a high affinity for the enzyme. These stable complexes are able to initiate RNA chains without lag as the enzyme is resistant against rifampicin if substrate is added simultaneously with the drug. Poly I resistant complexes decay very rapidly in the cold (Fig. 2) and are not formed in the absence of the polymerase factor (Table 2). The data provide additional support for the idea that the factor effects the binding of the enzymes to specific sites on the DNA template.     

Evidence for template-specific sites in DNA polymerases

Using rabbit hemoglobin messenger RNA as template, $\text{E. coli}$ polymerase I produces poly (dT), poly (dA)·(dT) and antimessenger DNA products. Mild heating of the enzyme causes a differential loss in activity as indicated by three rates of inactivation for the three types of synthesis. Heat inactivation studies have also been carried out with DNA polymerases from oncogenic RNA viruses and mammalian sources using various homopolymer-oligomer pairs as primertemplates. In general, for any given enzyme these synthetic primer-templates reveal different extents of inactivation of the polymerase. These findings may be interpreted to suggest a) that the binding of DNA polymerase to various primer-templates produces conformational changes in the enzyme which are dependent on the type of template bound, or b) that many, if not all, DNA polymerases have different subsites for different templates.