Thermal and urea-induced unfolding in T7 RNA polymerase: calorimetry, circular dichroism and fluorescence study.

Structural changes in T7 RNA polymerase (T7RNAP) induced by temperature and urea have been studied over a wide range of conditions to obtain information about the structural organization and the stability of the enzyme. T7RNAP is a large monomeric enzyme (99 kD). Calorimetric studies of the thermal transitions in T7RNAP show that the enzyme consists of three cooperative units that may be regarded as structural domains. Interactions between these structural domains and their stability strongly depend on solvent conditions. The unfolding of T7RNAP under different solvent conditions induces a highly stable intermediate state that lacks specific tertiary interactions, contains a significant amount of residual secondary structure, and undergoes further cooperative unfolding at high urea concentrations. Circular dichroism (CD) studies show that thermal unfolding leads to an intermediate state that has increased beta-sheet and reduced alpha-helix content relative to the native state. Urea-induced unfolding at 25 degrees C reveals a two-step process. The first transition centered near 3 M urea leads to a plateau from 3.5 to 5.0 M urea, followed by a second transition centered near 6.5 M urea. The CD spectrum of the enzyme in the plateau region, which is similar to that of the enzyme thermally unfolded in the absence of urea, shows little temperature dependence from 15 degrees to 60 degrees C. The second transition leads to a mixture of poly(Pro)II and unordered conformations. As the temperature increases, the ellipticity at 222 nm becomes more negative because of conversion of poly(Pro)II to the unordered conformation. Near-ultraviolet CD spectra at 25 degrees C at varying concentrations of urea are consistent with this picture. Both thermal and urea denaturation are irreversible, presumably because of processes that follow unfolding.

Pre-steady-state and steady-state kinetic studies on transcription initiation catalyzed by T7 RNA polymerase and its active-site mutants K631R and Y639F.

The kinetic mechanism of transcription initiation was studied under conditions that allow a single nucleotide addition to an initiating dinucleotide without interference of enzyme-DNA dissociation or protein recycling. Pre-steady-state kinetic studies have provided polymerization rate constants of 3.9, 5.9, and 3.9 s-1, reverse polymerization rate constants of 3.2, 2.1, and 2.8 s-1, and dissociation constants for the incoming nucleotide of 26, 49, and 24 microM at 21 degreesC, respectively, for the wild type and its active-site mutants K631R and Y639F. The results suggest a model in which K631 interacts with the phosphate group(s) of the incoming substrate. The internal equilibrium constants for the bound species are close to unity, consistent with the values for other phosphoryl transfer enzymes. The rate constants for chemical bond formation are at least 50 times higher than the rate constants for product dissociation. The product release rate constants, k3, are comparable to the steady-state rates, suggesting that the rate-determining step for all three enzymes may be a product dissociation step. The existence of two possible conformers E and E' that are in rapid equilibrium is postulated, to reconcile reduced burst sizes with full activity of the mutant enzymes. Both forms can form the quaternary complex, but only the E form is capable of catalyzing phosphodiester bond formation. The fraction of the catalytically active E form varies from essentially 100% for the wild type to 38 and 32% for the mutants K631R and Y639F, respectively. Upon entering the elongation phase, the E form becomes the dominant form in all three enzymes, leading to comparable rates of elongation for the wild type and Y639F mutant. The rate of synthesis of long transcripts is markedly diminished for the K631R mutant due to decreased processivity.

Asp537 and Asp812 in bacteriophage T7 RNA polymerase as metal ion-binding sites studied by EPR, flow-dialysis, and transcription.

Asp537 and Asp812 are essential in the catalytic mechanism of T7 RNA polymerase. The mutants D537N and D812N have no detectable activity whereas the mutants D537E and D812E have significantly reduced activity relative to the wild-type. The hypothesis that these two amino acids act as metal-binding ligands has been tested using EPR with Mn2+ as the metal ion. Mn2+ is able to substitute for Mg2+ in transcription by T7 RNAP on templates containing the T7 promoter. Mg2+ and Mn2+ compete for binding sites, with the former having lower affinity. Mn2+ binding to the wild-type enzyme and the mutants D537N, D812N, D537E, D812E, and Y649F was measured over the concentration range of 25 microM to 1.5 mM. The data were analyzed by nonlinear least-squares fits to the binding isotherms, and the analysis gave approximately two Mn(2+)-binding sites in all cases and a Kd for the wild-type of approximately 340 microM. The Kd value for the mutant Y639F, in which Asp537 and Asp 812 are not mutated, is comparable to the value for the wild-type. Mn2+ binding to the double mutants, D537N/D812N and D537E/D812E, appears to be nonspecific. The Kd values of the Asp-->Asn mutants are only 2-5 times larger than the value for the wild-type, in contrast to the drastic diminution of enzymatic activity in the mutants. The geometry of metal binding to these Asp residues may be crucial in determining the catalytic competence. Mn2+ binding to the wild-type enzyme in the presence of nucleotides, measured by flow dialysis, is characterized by two Mn(2+)-binding sites with a Kd value of ca. 150 microM. The similarity in values of Kd with and without nucleotide suggests that nucleotides do not have a drastic effect on Mn2+ binding. Our results indicate that monodentate carboxylate oxygens of both conserved Asp residues bridge the two metal ions.

Structural analysis of the Bacillus subtilis delta factor: a protein polyanion which displaces RNA from RNA polymerase.

RNA polymerase from Bacillus subtilis is a complex mixture comprising a common core (beta beta' alpha 2), the 20.4 kDa delta (delta) protein, and of one of several sigma (sigma) specificity factors. The delta protein, together with several truncated variants, has been overproduced and purified from Escherichia coli. It is highly acidic (pI = 3.6) and contains two distinct regions, a 13 kDa amino-terminal domain with fairly uniform charge distribution and a glutamate and aspartate residue-rich carboxyl-terminal region. The purified amino-terminal domain (delta N) contains 32% alpha-helix and 16% beta-sheet, as judged by circular dichroism analysis. In contrast, an 8.5 kDa tryptic fragment containing the carboxyl-terminal region (delta C) is largely unstructured and highly charged (net charge of -47). RNA polymerase purified from a B. subtilis mutant with an insertion in the delta gene (rpoE::cat) contains a truncated delta protein, indicating that the amino-terminal domain is stable in vivo and contains a core-binding function. Addition of delta, but not sigma A or delta N, displaces RNA bound to RNA polymerase in a binary complex. The ability of delta to displace RNA efficiently requires the activities of both the amino-terminal core-binding domain and the polyanionic carboxyl-terminal region. Although delta C can also displace nucleic acids from RNA polymerase, this activity requires the addition of a large molar excess of protein and is relatively non specific in that both DNA and RNA are displaced. This suggests that the function of the amino-terminal domain is to bind and orient the carboxyl-terminal region on the surface of RNA polymerase.

Bacteriophage T7 RNA polymerase and its active-site mutants. Kinetic, spectroscopic and calorimetric characterization.

It has been demonstrated that the amino acids Asp537, Asp812, Lys631, His811 and Tyr639 are involved in bacteriophage T7 RNA polymerase catalysis. In the present paper, we report kinetic, spectroscopic and calorimetric characterization of the wild-type and mutant T7 RNA polymerases generated at these five loci (D537N, E; K631M, R; Y639F, S, A, W; H811Q, A; D812N, E). The wild-type enzyme has a substantial amount of secondary structure as determined by CD analysis (alpha-helix, 43%; beta-sheet, 14%; beta-turn, 25%; unordered, 18%). The CD spectra of 12 mutants at five loci are very similar to that of the wild-type, except for the mutant Y639W. Within experimental error, the thermal transition temperatures measured by CD and DSC as well as the lambda max values of the fluorescence spectra were the same for the wild-type and all of the mutants. Therefore, the overall folding and stability of the mutant enzymes are very similar to those of the wild-type enzyme, although small local conformational changes cannot be excluded. For the synthesis of the pentamer pppGGACU, the mutants D537E and D812E showed an approximately two- to threefold decrease in (kcat)app and an approximately two- to threefold increase in (Km)app, relative to the wild-type, in contrast to the mutants D537N and D812N which exhibited no detectable activity. The mutant K631R showed a sevenfold reduction in (kcat)app and a two- to threefold increase in (Km)app, supporting our earlier observation with the mutant K631M that Lys631 may be involved in phosphodiester bond formation. The mutant Y639S can synthesize the trimer GGA with an approximately 50-fold decrease in (kcat)app and a tenfold increase in (Km)app, relative to the wild-type, underlining the importance of the phenyl ring of Tyr639. The mutant H811A, in which the side-chain at position 811 is incapable of forming a hydrogen bond, can synthesize the trimer GGA with an approximately tenfold decrease in (kcat)app and an approximately 35-fold increase in (Km)app. Thus, either the hydrogen-bonding capacity of this residue is non-essential or some other group can functionally substitute for the His811 side-chain. The wild-type enzyme showed significant effects of the base position in the sequence on the apparent binding constants for the NTPs. The kinetics of GpG-primed trimer, tetramer and pentamer synthesis on three 22 bp templates were investigated for the wild-type and mutant enzymes with measurable activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Asp537, Asp812 are essential and Lys631, His811 are catalytically significant in bacteriophage T7 RNA polymerase activity.

To define catalytically essential residues of bacteriophage T7 RNA polymerase, we have generated five mutants of the polymerase, D537N, K631M, Y639F, H811Q and D812N, by site-directed mutagenesis and purified them to homogeneity. The choice of specific amino acids for mutagenesis was based upon photoaffinity-labeling studies with 8-azido-ATP and homology comparisons with the Klenow fragment and other DNA/RNA polymerases. Secondary structural analysis by circular dichroism indicates that the protein folding is intact in these mutants. The mutants D537N and D812N are totally inactive. The mutant K631M has 1% activity, confined to short oligonucleotide synthesis. The mutant H811Q has 25% activity for synthesis of both short and long oligonucleotides. The mutant Y639F retains full enzymatic activity although individual kinetic parameters are somewhat different. Kinetic parameters, (kcat)app and (Km)app for the nucleotides, reveal that the mutation of Lys to Met has a much more drastic effect on (kcat)app than on (Km)app, indicating the involvement of K631 primarily in phosphodiester bond formation. The mutation of His to Gln has effects on both (kcat)app and (Km)app; namely, three- to fivefold reduction in (kcat)app and two- to threefold increase in (Km)app, implying that His811 may be involved in both nucleotide binding and phosphodiester bond formation. The ability of the mutant T7 RNA polymerases to bind template has not been greatly impaired. We have shown that amino acids D537 and D812 are essential, that amino acids K631 and H811 play significant roles in catalysis, and that the active site of T7 RNA polymerase is composed of different regions of the polypeptide chain. Possible roles for these catalytically significant residues in the polymerase mechanism are discussed.

Mapping of the active site of T7 RNA polymerase with 8-azidoATP.

The photoaffinity analog of ATP, 8-azidoATP, labels T7 RNA polymerase. Photoincorporation exhibits saturation behavior and is protected against by the substrate ATP. 8-AzidoATP is a competitive inhibitor of ATP incorporation with Ki approximately 40 microM. The photolabeled T7 RNA polymerase, following cyanogen bromide digestion, was analyzed by phenylboronate agarose column chromatography followed by reverse-phase high pressure liquid chromatography. Sequencing of the peptides labeled with radioactive photoprobe allowed the identification of three peptides, P314-M362 (I), L550-M666 (II), and F751-M861 (III). These peptides are in the proximity of the photoprobe 8-azidoATP and, therefore, expected to contain functionally significant residues and define an active site domain. These peptides (I and II) contain residues previously implicated in T7 RNA polymerase activity or show homology to active site regions of the Klenow fragment of DNA polymerase I (II and III).

Spectroscopic analysis of DNA base-pair opening by Escherichia coli RNA polymerase. Temperature and ionic strength effects.

The interaction of Escherichia coli RNA polymerase with poly[d(A-T)] and poly[d-(I-C)] was studied by difference absorption spectroscopy at temperatures, from 5 to 45 degrees C in the absence and presence of Mg2+. The effect of KCl concentration, at a fixed temperature, was studied from 12.5 to 400 mM. Difference absorption experiments permitted calculation of the extent of DNA opening induced by RNA polymerase and estimation of the equilibrium constant associated with the isomerization from a closed to an open RNA polymerase-DNA complex. delta H0 and delta S0 for the closed-to-open transition with poly[d(A-T)] or poly[d(I-C)] complexed with RNA polymerase are significantly lower than the values associated with the helix-to-coil transition for the free polynucleotides. For the RNA polymerase complexes with poly[d(A-T)] and poly[d(I-C)] in 50 mM KCl, delta H0 approximately 15-16 kcal/mol (63-67 kJ/mol) and delta S0 approximately 50-57 cal/K per mol (209-239 J/K per mol). The presence of Mg2+ does not change these parameters appreciably for the RNA polymerase-poly[d(A-T)] complex, but for the RNA polymerase-poly[d(I-C)] complex in the presence of Mg2+, the delta H0 and delta S0 values are larger and temperature-dependent, with delta H0 approximately 22 kcal/mol (92 kJ/mol) and delta S0 approximately 72 cal/K per mol (approx. 300 J/K per mol) at 25 degrees C, and delta Cp0 approximately 2 kcal/K per mol (approx. 8.3 kJ/K per mol). The circular dichroism (CD) changes observed for helix opening induced by RNA polymerase are qualitatively consistent with the thermally induced changes observed for the free polynucleotides, supporting the difference absorption method. The salt-dependent studies indicate that two monovalent cations are released upon helix opening. For poly[d(A-T)], the temperature-dependence of enzyme activity correlates well with the helix opening, implying this step to be the rate-determining step. In the case of poly[d(I-C)], the same is not true, and so the rate-determining step must be a process subsequent to helix opening.

Characterization of a photoaffinity analog of UTP, 5-azido-UTP for analysis of the substrate binding site on E. coli RNA polymerase.

The substrate binding site on E. coli RNA polymerase was investigated by photoaffinity labeling with a photoaffinity analog of UTP, 5-azido-UTP. We have established that 5-azido-UTP is a substrate for RNA polymerase by specific transcription on 229 bp DNA containing the gene II promoter of M13 phage. Analysis of the initial rate of RNA synthesis gives Km(5-azido-UTP) approximately 80 microM. Photolabeling with varying concentrations of 5-azido-UTP follows a saturation curve with the midpoint occurring at a 5-azido-UTP concentration of 65 microM near to the Km obtained by kinetic analysis. 5-Azido-UTP photolabels the beta', beta, and sigma subunits to about the same extent, both in the presence (33, 31, and 36%) and absence (35, 30 and 35%) of DNA. This labeling pattern is somewhat different from that obtained with 8-azido-ATP (beta' greater than sigma much greater than beta greater than alpha).

Transcription initiation by Escherichia coli RNA polymerase at the gene II promoter of M13 phage: stability of ternary complex, direct photocrosslinking to nascent RNA, and retention of sigma subunit.

The initial stages of transcription have been characterized using a template containing the gene II promoter region of M13 phage. Initiation of transcription in the presence of all four nucleotides gives rise to the 140-residue run-off transcript, with a minor pause at the RNA hexamer stage. Cycling, leading to the accumulation of significant amounts of short oligonucleotides [1], was not observed. An RNA hexamer GUUUUU was the sole product when GpU and UTP were used and the ternary complex with the hexamer was stable and resistant to high salt (0.4 M) and S1 nuclease attack. After direct ultraviolet photocrosslinking of the RNA hexamer to RNA polymerase in the ternary complex, the radioactive label incorporation into various subunits was determined by autoradiography after sodium tetradecyl sulfate gel electrophoresis to be as follows: sigma, 86%; beta, 14%; beta' and alpha, negligible. Both electrophoresis and sucrose gradient centrifugation experiments indicate that the sigma subunit is not released from the ternary complex when either the RNA hexamer or the 140-residue RNA is synthesized on this template, even though the complexes are stable.

Effects of ppGpp on transcription by DNA-dependent RNA polymerase from Escherichia coli: circular dichroism, absorption and specific transcription studies.

Concrete evidence is presented for conformational changes elicited in RNA polymerase upon binding ppGpp by circular dichroism measurements. In the presence of 100 microM ppGpp, the molar ellipticity of RNA polymerase at 220 nm is reduced by 14% from the initial value of - 11,100 deg X cm2 X dmol-1 at 25 degrees C. In vitro transcription on templates containing the beta-lactamase promoter and colicin E1 promoter on poly[d(A-T)] is inhibited by ppGpp. None of these templates had GC-rich nucleotide sequence near the transcription initiation site, and yet they were influenced by ppGpp. Comparison of the effect on the synthesis of mRNAs for beta-lactamase and colicin E1 and the synthesis of the proteins themselves indicates that the effect of ppGpp is at the level of transcription for the former case and involves coupled transcription-translation for the latter case. Difference absorption, polyacrylamide gel electrophoresis, and nitrocellulose filter-binding studies show that the binding of ppGpp to RNA polymerase does not impair the extent of the interaction between enzyme and DNA. Kinetic studies suggest that ppGpp affects transcription initiation on beta-lactamase promoter. On poly[d(A-T)], ppGpp affects the rate of open complex formation and is a mixed inhibitor with respect to the incorporation of nucleotides. Our results are consistent with the idea that ppGpp acts as a regulator by binding at a site different from the active site and changes the RNA polymerase conformation, causing altered transcriptional behavior on different DNA templates.

Salt-dependent binding of Escherichia coli RNA polymerase to DNA and specific transcription by the core enzyme and holoenzyme.

The interaction of the Escherichia coli RNA polymerase with several forms of DNA has been studied by difference absorption spectroscopy, protection against endonucleases, and limited, specific initiation. The core enzyme is able to open duplex poly[d(A-T)] in 10 mM KCl. The core enzyme binds to promoters in linear DNA in a salt-dependent manner, but it does not bind to the same promoters in supercoiled DNA. The binding of the core enzyme is not as tight as that of the holoenzyme. The holoenzyme initiates specific transcription from promoters in a salt-dependent manner. The core enzyme also initiates specific transcription from the same promoters at approximately one-fifth the level of the holoenzyme with a different salt dependence. The profile of the salt dependence of specific transcription initiation varies with the promoter. The origin of differences between holoenzyme-DNA and core enzyme-DNA interactions and the mechanism whereby sigma improves transcriptional specificity are discussed in light of these data.

Characterization of the guanosine-3'-diphosphate-5'-diphosphate binding site on E. coli RNA polymerase using a photoprobe, 8-azidoguanosine-3'-5'-bisphosphate.

Nucleotide binding sites on DNA-dependent RNA polymerase from E. coli have been studied by photoaffinity labeling with a GTP analog [gamma-32P]-8-AzidoGTP and a guanosine-3'-diphosphate-5'-diphosphate analog, 8-Azidoguanosine-3'-phosphate-5'-85'-32P]phosphate. The guanosine diphosphate photoprobe labeled the beta, beta', and sigma subunits with the sigma subunit being most heavily labeled. The GTP photoprobe also labeled the beta, beta', sigma subunits but the beta' subunit was most heavily labeled. In competition experiments guanosine-3'-diphosphate-5'-diphosphate decreased photolabeling by 8-Azidoguanosine-3'-phosphate-5'-[5'-32P]phosphate better than GTP, while the opposite was true for photolabeling with [gamma-32P]8- AzidoGTP. The guanosine diphosphate photoprobe inhibited transcription on E. coli DNA with Ki of ca. 150 microM. Present studies suggest a unique ppGpp binding site distinct from substrate binding site(s) and this photoprobe may be used to localize this binding site(s).

Photoaffinity labeling of DNA-dependent RNA polymerase from Escherichia coli with 8-azidoadenosine 5'-triphosphate.

A photoaffinity analogue of adenosine 5'-triphosphate (ATP), 8-azidoadenosine 5'-triphosphate (8-N3ATP), has been used to elucidate the role of the various subunits involved in forming the active site of Escherichia coli DNA-dependent RNA polymerase. 8-N3ATP was found to be a competitive inhibitor of the enzyme with respect to the incorporation of ATP with Ki = 42 microM, while uridine 5'-triphosphate (UTP) incorporation was not affected. UV irradiation of the reaction mixture containing RNA polymerase and [gamma-32P]-8-N3ATP induced covalent incorporation of radioactive label into the enzyme. Analysis by gel filtration and nitrocellulose filter binding indicated specific binding. Subunit analysis by sodium dodecyl sulfate and sodium tetradecyl sulfate gel electrophoresis and autoradiography of the labeled enzyme showed that the major incorporation of radioactive label was in beta' and sigma, with minor incorporation in beta and alpha. The same pattern was observed in both the presence and absence of poly[d(A-T)] and poly[d(A-T)] plus ApU. Incorporation of radioactive label in all bands was significantly reduced by 100-150 microM ATP, while 100-200 microM UTP did not show a noticeable effect. Our results indicate major involvement of the beta' and sigma subunits in the active site of RNA polymerase. The observation of a small extent of labeling of the beta and alpha subunits, which was prevented by saturating levels of ATP, suggests that these subunits are in close proximity to the catalytic site.

Spectroscopic studies of Congo Red binding to RNA polymerase.

The azo dye Congo Red has a high affinity for nucleotide-binding enzymes. We have studied the binding of Congo Red to RNA polymerase by circular dichroism (CD) and difference absorption spectroscopy, steady-state kinetics, and nitrocellulose filter-binding. Induced CD shows that a large number of Congo Red molecules bind to the holoenzyme. CD also demonstrates that the core enzyme at low ionic strengths has a distinctive Congo Red binding site which is not present in the holoenzyme, nor in the core enzyme at higher ionic strengths or in the presence of poly(dT). CD studies indicate that Congo Red can readily displace double-stranded polynucleotides (T7 DNA or poly[d(A-T)] from RNA polymerase. Single-stranded DNA (poly(dT) and T7 DNA in open complexes) is not displaced from RNA polymerase except at high Congo Red concentrations. Both kinetics and nitrocellulose filter-binding measurements support this conclusion. Difference spectra indicate that the bound Congo Red molecules undergo stacking. We postulate that RNA polymerase binds Congo Red in a region with which a segment of DNA normally interacts, and that Congo Red is a potent inhibitor because the stacked dye has a polyanionic character.

The interaction of RNA polymerase and DNA. Effects on the helix-coil transition and light scattering.

To characterize the interactions of RNA polymerase with DNA, we have investigated the thermal transition of poly[d(A-T] bound to RNA polymerase from Escherichia coli and the aggregation properties of the enzyme with DNA. The melting curve of the DNA-enzyme complex demonstrates a sharply lowered melting temperature for part of the DNA, whereas for another fraction the double helix is stabilized. This indicates that the DNA-binding site of RNA polymerase serves two functions: (1) to disrupt the double helix at one point, and (2) to maintain the duplex form at other points. The aggregation of DNA and RNA polymerase has been monitored by turbidity measurements, and conditions have been delineated under which aggregation is minimized. Holoenzyme added to double-stranded DNA or single-stranded DNA has little or no tendency to aggregate under most conditions. Core enzyme, on the other hand, aggregate extensively with double-stranded DNA, the only under conditions of low salt (10 mM KCl), without Mg2+, or at high salt (300 mM KCl), with or without Mg2+, can this aggregation be eliminated. Core enzyme also does not aggregate in the presence of single-stranded DNA. These aggregation properties are interpreted as evidence for more than one DNA-binding site on RNA polymerase.

Spectroscopic analysis of the interaction of Escherichia coli DNA-dependent RNA polymerase with T7 DNA and synthetic polynucleotides.

We have studied the circular dichroism and ultraviolet difference spectra of T7 bacteriophage DNA and various synthetic polynucleotides upon addition of Escherichia coli RNA polymerase. When RNA polymerase binds nonspecifically to T7 DNA, the CD spectrum shows a decrease in the maximum at 272 but no detectable changes in other regions of the spectrum. This CD change can be compared with those associated with known conformational changes in DNA. Nonspecific binding to RNA polymerase leads to an increase in the winding angle, theta, in T7 DNA. The CD and UV difference spectra for poly[d(A-T)] at 4 degrees C show similar effects. At 25 degrees C, binding of RNA polymerase to poly[d(A-T)] leads to hyperchromicity at 263 nm and to significant changes in CD. These effects are consistent with an opening of the double helix, i.e. melting of a short region of the DNA. The hyperchromicity observed at 263 nm for poly[d(A-T)] is used to determine the number of base pairs disrupted in the binding of RNA polymerase holoenzyme. The melting effect involves about 10 base pairs/RNA polymerase molecule. Changes in the CD of poly(dT) and poly(dA) on binding to RNA polymerase suggest an unstacking of the bases with a change in the backbone conformation. This is further confirmed by the UV difference spectra. We also show direct evidence for differences in the template binding site between holo- and core enzyme, presumably induced by the sigma subunit. By titration of the enzyme with poly(dT) the physical site size of RNA polymerase on single-stranded DNA is approximately equal to 30 bases for both holo- and core enzyme. Titration of poly[d(A-T)] with polymerase places the figure at approximately equal to 28 base pairs for double-stranded DNA.