Affinity labeling the DNA polymerase alpha complex. I. Pyridoxal 5'-phosphate inhibition of DNA polymerase and DNA primase activities of the DNA polymerase alpha complex from Drosophila melanogaster embryos

DNA polymerase alpha from Drosophila melanogaster embryos is a multisubunit enzyme complex which can exhibit DNA polymerase, 3'----5' exonuclease, and DNA primase activities. Pyridoxal 5'-phosphate (PLP) inhibition of DNA polymerase activity in this complex is time dependent and exhibits saturation kinetics. Inhibition can be reversed by incubation with an excess of a primary amine unless the PLP-enzyme conjugate is first reduced with NaBH4. These results indicate that PLP inhibition occurs via imine formation at a specific site(s) on the enzyme. Results from substrate protection experiments are most consistent with inhibition of DNA polymerase activity by PLP binding to either one of two sites. One site (PLP site 1) can be protected from PLP inhibition by any nucleoside triphosphate in the absence or presence of template-primer, suggesting that PLP site 1 defines a nucleotide-binding site which is important for DNA polymerase activity but which is distinct from the DNA polymerase active site. PLP also inhibits DNA primase activity of the DNA polymerase alpha complex, and primase activity can be protected from PLP inhibition by nucleotide alone, arguing that PLP site 1 lies within the DNA primase active site. The second inhibitory PLP-binding site (PLP site 2) is only protected from PLP inhibition when the enzyme is bound to both template-primer and correct dNTP in a stable ternary complex. Since binding of PLP at site 2 is mutually exclusive with template-directed dNTP binding at the DNA polymerase active site, PLP site 2 appears to define the dNTP binding domain of the active site. Results from initial velocity analysis of PLP inhibition argue that there is a rate-limiting step in the polymerization cycle during product release and/or translocation.     

Dehydroaltenusin, a mammalian DNA polymerase alpha inhibitor

Dehydroaltenusin was found to be an inhibitor of mammalian DNA polymerase alpha (pol alpha) in vitro. Surprisingly, among the polymerases and DNA metabolic enzymes tested, dehydroaltenusin inhibited only mammalian pol alpha. Dehydroaltenusin did not influence the activities of the other replicative DNA polymerases, such as delta and epsilon; it also showed no effect even on the pol alpha activity from another vertebrate (fish) or plant species. The inhibitory effect of dehydroaltenusin on mammalian pol alpha was dose-dependent, and 50% inhibition was observed at a concentration of 0.5 microm. Dehydroaltenusin-induced inhibition of mammalian pol alpha activity was competitive with the template-primer and non-competitive with the dNTP substrate. BIAcore analysis demonstrated that dehydroaltenusin bound to the core domain of the largest subunit, p180, of mouse pol alpha, which has catalytic activity, but did not bind to the smallest subunit or the DNA primase p46 of mouse pol alpha. These results suggest that the dehydroaltenusin molecule competes with the template-primer molecule on its binding site of the catalytic domain of mammalian pol alpha, binds to the site, and simultaneously disturbs dNTP substrate incorporation into the template-primer.     

Site-specific modification of Escherichia coli DNA polymerase I large fragment with pyridoxal 5'-phosphate

Pyridoxal 5'-phosphate (PLP) is an inhibitor of DNA polymerase activity of Escherichia coli DNA polymerase I large fragment. Kinetic studies indicated that overall PLP inhibition was noncompetitive with respect to dNTP, and Hill plot analysis revealed that two molecules of PLP were involved in the inhibition. Reduction of the PLP-treated enzyme with sodium [3H]borohydride resulted in covalent incorporation of 3 mol of PLP/mol of enzyme. This incorporation was at lysine residues exclusively, and the PLP-modified enzyme was not capable of DNA polymerase activity. The presence of dNTP during the modification reaction blocked the incorporation of 1 mol of PLP/mol of enzyme. Similar results were obtained in the presence or absence of template-primer. These data indicate that a PLP target lysine is in or around a dNTP binding site that is essential for polymerase activity and that this binding site is functional in the absence of template-primer. The enzyme modified in the presence of dNTP, containing 2 mol of PLP/mol of enzyme, was capable of DNA polymerase activity but was unable to conduct elongation of product molecules beyond a short oligonucleotide length.     

Active-site modification of mammalian DNA polymerase beta with pyridoxal 5'-phosphate: mechanism of inhibition and identification of lysine 71 in the deoxynucleoside triphosphate binding pocket

Pyridoxal 5'-phosphate is a potent inhibitor of the DNA polymerase activity of recombinant rat DNA polymerase beta. Kinetic studies indicate that the mechanism of PLP inhibition is complex. In a lower range of PLP concentration, inhibition is competitive with respect to substrate dNTP, whereas at higher levels of PLP several forms of enzyme combine with PLP and are involved in the overall inhibition, and a possible model for these interactions during the catalytic process is suggested. Reduction of the PLP-treated enzyme with sodium [3H]borohydride results in covalent incorporation of about 4 mol of PLP/mol of enzyme, and the modified enzyme is not capable of DNA polymerase activity. The presence of dNTP during the modification reaction blocks incorporation of 1 mol of PLP/mol of enzyme, and the enzyme so modified is almost fully active. This protective effect is not observed in the absence of template-primer. Tryptic peptide mapping of the PLP-modified enzyme reveals four major sites of modification. Of these four sites, only one is protected by dNTP from pyridoxylation. Sequence analysis of the tryptic peptide corresponding to the protected site reveals that it spans residues 68-80 in the amino acid sequence of the enzyme, with Lys 71 as the site of pyridoxylation. These results indicate that Lys 71 is at or near the binding pocket for the dNTP substrate.     

Purification and characterization of the 180- and 86-kilodalton subunits of the Saccharomyces cerevisiae DNA primase-DNA polymerase protein complex. The 180-kilodalton subunit has both DNA polymerase and 3'----5'-exonuclease activities.

The yeast Saccharomyces cerevisiae catalytic DNA polymerase I 180-kDa subunit and the tightly associated 86-kDa polypeptide have been purified using immunoaffinity chromatography, permitting further characterization of the DNA polymerase activity of the DNA primase-DNA polymerase protein complex. The subunits were purified to apparent homogeneity from separate overproducing yeast strains using monoclonal antibodies specifically recognizing each subunit. When the individual subunits were recombined in vitro a p86p180 physical complex formed spontaneously, as judged by immunoprecipitation of 180-kDa polypeptide and DNA polymerase activity with the anti-86-kDa monoclonal antibody. The 86-kDa subunit stabilized the DNA polymerase activity of the 180-kDa catalytic subunit at 30 degrees C, the physiological temperature. The apparent DNA polymerase processivity of 50-60 nucleotides on poly(dA).oligo(dT)12 or poly(dT).oligo(A)8-12 template-primer was not affected by the presence of the 86-kDa subunit but was reduced by increased Mg2+ concentration. The Km of the catalytic 180-kDa subunit for dATP or DNA primer terminus was unaffected by the presence of the 86-kDa subunit. The isolated 180-kDa polypeptide was sufficient to catalyze all the DNA synthesis that had been observed previously in the DNA primase-DNA polymerase protein complex. The 180-kDa subunit possessed a 3'----5'-exonuclease activity that catalyzed degradation of polynucleotides, but degradation of oligonucleotide substrates of chain lengths up to 50 was not detected. This exonuclease activity was unaffected by the presence of the 86-kDa subunit. Despite the striking physical similarity of the DNA primase-DNA polymerase protein complex in all eukaryotes examined, the data presented here indicate differences in the enzymatic properties detected in preparations of the DNA polymerase subunits isolated from S. cerevisiae as compared with the properties of preparations from Drosophila cells. In particular, the 3'----5'-exonuclease activity associated with the yeast catalytic DNA polymerase subunit was not masked by the 86-kDa subunit.     

A bipartite polymerase-processivity factor interaction: only the internal beta binding site of the alpha subunit is required for processive replication by the DNA polymerase III holoenzyme

Previously, we localized the beta2 interacting portion of the catalytic subunit (alpha) of DNA polymerase III to the C-terminal half, downstream of the polymerase active site. Since then, two different beta2 binding sites within this region have been proposed. An internal site includes amino acid residues 920-924 (QADMF) and an extreme C-terminal site includes amino acid residues 1154-1159 (QVELEF). To permit determination of their relative contributions, we made mutations in both sites and evaluated the biochemical, genetic, and protein binding properties of the mutant alpha subunits. All purified mutant alpha subunits retained near wild-type polymerase function, which was measured in non-processive gap-filling assays. Mutations in the internal site abolished the ability of mutant alpha subunits to participate in processive synthesis. Replacement of the five-residue internal sequence with AAAKK eliminated detectable binding to beta2. In addition, mutation of residues required for beta2 binding abolished the ability of the resulting polymerase to participate in chromosomal replication in vivo. In contrast, mutations in the C-terminal site exhibited near wild-type phenotypes. alpha Subunits with the C-terminal site completely removed could participate in processive DNA replication, could bind beta2, and, if induced to high level expression, could complement a temperature-sensitive conditional lethal dnaE mutation. C-terminal defects that only partially complemented correlated with a defect in binding to tau, not beta2. A C-terminal deletion only reduced beta2 binding fourfold; tau binding was decreased ca 400-fold. The context in which the beta2 binding site was presented made an enormous difference. Replacement of the internal site with a consensus beta2 binding sequence increased the affinity of the resulting alpha for beta2 over 100-fold, whereas the same modification at the C-terminal site did not significantly increase binding. The implications of multiple interactions between a replicase and its processivity factor, including applications to polymerase cycling and interchange with other polymerases and factors at the replication fork, are discussed.     

Localization of the active site of the alpha subunit of the Escherichia coli DNA polymerase III holoenzyme.

Using a deletion approach on the alpha subunit of DNA polymerase III from Escherichia coli, we show that there is an N-proximal polymerase domain which is distinct from a more C-proximal tau and beta binding domain. Although deletion of 60 residues from the alpha N terminus abolishes polymerase activity, deletions of 48, 169, and 342 amino acids from the C terminus progressively impair its catalytic efficiency but preserve an active site. Deletion of 342 C-terminal residues reduces k(cat) 46-fold, increases the Km for gapped DNA 5.5-fold, and increases the Km for deoxynucleoside triphosphates (dNTPs) twofold. The 818-residue protein with polymerase activity displays typical Michaelis-Menten behavior, catalyzing a polymerase reaction that is saturable with substrate and linear with time. With the aid of newly acquired sequences of the polymerase III alpha subunit from a variety of organisms, candidates for two key aspartate residues in the active site are identified at amino acids 401 and 403 of the E. coli sequence by inspection of conserved acidic amino acids. The motif Pro-Asp-X-Asp, where X is a hydrophobic amino acid, is shown to be conserved among all known DnaE proteins, including those from Bacillaceae, cyanobacteria, Mycoplasma, and mycobacteria. The E. coli DnaE deletion protein with only the N-terminal 366 amino acids does not have polymerase activity, consistent with the proposed position of the active-site residues.     

Photoaffinity labeling of DNA polymerase alpha DNA primase complex based on the catalytic competence of a dNTP reactive analog.

FABdCTP was found to be a substrate of DNA polymerization catalyzed by a DNA polymerase alpha-DNA primase complex on the 5'-GTGAGTAAGTGGAGTTTGGCACGAT-3' template and 3'-CTCAAACCGT-5' primer. After complete primer extension in the presence of FABdCTP under UV-irradiation of the reaction mixture, 70% of the template was covalently linked to the primer. Labeling of the 165 kDa subunit of the DNA polymerase alpha, 59 kDa and 49 kDa subunits of the DNA primase and an unknown protein with apparent molecular weight of 31 kDa was observed. By another way of protein labeling FABdCTP was covalently bound to the subunits of the enzyme under UV irradiation and then this moiety was introduced into the 3'-end of the 5'-[32P]primer by the catalytic activity of DNA polymerase or DNA primase. In this case covalent labeling of the 165 kDa, 49 kDa and 31 kDa subunits was observed.     

Constitution of the twin polymerase of DNA polymerase III holoenzyme

It is speculated that DNA polymerases which duplicate chromosomes are dimeric to provide concurrent replication of both leading and lagging strands. DNA polymerase III holoenzyme (holoenzyme), is the 10-subunit replicase of the Escherichia coli chromosome. A complex of the alpha (DNA polymerase) and epsilon (3'-5' exonuclease) subunits of the holoenzyme contains only one of each protein. Presumably, one of the eight other subunit(s) functions to dimerize the alpha epsilon polymerase within the holoenzyme. Based on dimeric subassemblies of the holoenzyme, two subunits have been elected as possible agents of polymerase dimerization, one of which is the tau subunit (McHenry, C. S. (1982) J. Biol. Chem. 257, 2657-2663). Here, we have used pure alpha, epsilon, and tau subunits in binding studies to determine whether tau can dimerize the polymerase. We find tau binds directly to alpha. Whereas alpha is monomeric, tau is a dimer in its native state and thereby serves as an efficient scaffold to dimerize the polymerase. The epsilon subunit does not associate directly with tau but becomes dimerized in the alpha epsilon tau complex by virtue of its interaction with alpha. We have analyzed the dimeric alpha epsilon tau complex by different physical methods to increase the confidence that this complex truly contains a dimeric polymerase. The tau subunit is comprised of the NH2-terminal two-thirds of tau but does not bind to alpha epsilon, identifying the COOH-terminal region of tau as essential to its polymerase dimerization function. The significance of these results with respect to the organization of subunits within the holoenzyme is discussed.     

Stimulation of DNA polymerase alpha activity by microtubule-associated proteins.

Microtubule-associated protein 2 (MAP2) isolated from porcine brains stimulated the activity of DNA polymerase alpha immunopurified from calf thymus or human lymphoma cells, in a dose-dependent manner. This stimulation was pronounced when activated DNA or poly(dA).(dT)10 was used as the template-primer. DNA polymerase alpha bound to a MAP2-immobilized column, whereas preincubation of the enzyme with unbound MAP2 prevented binding to the column. These events suggested that a physical binding occurred between the polymerase and MAP2. Kinetic analyses revealed that MAP2 decreased the Km value of the polymerase for deoxyribonucleotides, irrespective of the species of template-primer. A concomitant increase in Vmax was observed; however, the extent of the increase depended on the species of template-primer. MAP2 also decreased the Km value of the polymerase for template-primers when activated DNA of poly(dA).(dT)10 was used as the template-primer. Product analyses showed that MAP2 did not significantly alter the processivity of the polymerase and the increment of Vmax is considered to be due to an increase in the frequency of initiation of DNA synthesis. The stimulation by MAP2 occurred specifically in the activity of DNA polymerase alpha, but not DNA polymerases beta, gamma, and I from Escherichia coli. Other MAPs, tau and 190-kDa MAP, could substitute for MAP2. Thus, the specific stimulation of DNA polymerase alpha by MAPs supports the notion of a possible involvement of MAPs or MAP-like proteins in DNA replication, in vivo.     

Pyridoxal 5'-phosphate is a selective inhibitor in vivo of DNA polymerase alpha and epsilon

Vitamin B(6) compounds such as pyridoxal 5(')-phosphate (PLP), pyridoxal (PL), pyridoxine (PN), and pyridoxamine (PM), which reportedly have anti-angiogenic and anti-cancer effects, were thought to be inhibitors of some types of eukaryotic DNA polymerases. PL moderately inhibited only the activities of calf DNA polymerase alpha (pol alpha), while PN and PM had no inhibitory effects on any of the polymerases tested. On the other hand, PLP, a phosphated form of PL, was potentially a strong inhibitor of pol alpha and epsilon from phylogenetic-wide organisms including mammals, fish, insects, plants, and protists. PLP did not suppress the activities of prokaryotic DNA polymerases such as Escherichia coli DNA polymerase I and Taq DNA polymerase, or DNA-metabolic enzymes such as deoxyribonuclease I. For pol alpha and epsilon, PLP acted non-competitively with the DNA template-primer and competitively with the nucleotide substrate. Since PL was converted to PLP in vivo after being incorporated into human cancer cells, the anti-angiogenic and anti-cancer effects caused by PL must have been caused by the inhibition of pol alpha and epsilon activities after conversion to PLP.     

Taxol derivatives are selective inhibitors of DNA polymerase alpha

During screening for mammalian DNA polymerase inhibitors, we found and succeeded in isolating a potent inhibitor from a higher plant, Taxus cuspidate. The compound was unexpectedly determined to be taxinine, an intermediate of paclitaxel (taxol) metabolism. Taxinine was found to selectively inhibit DNA polymerase alpha (pol.alpha) and beta (pol.beta). We therefore, tested taxol and other derivatives and found that taxol itself had no such inhibitory effect, and only taxinine could inhibit both pol.alpha and beta. The other compounds used, one derivative, cephalomannine, and five intermediates synthesized chemically inhibited only the pol.alpha activity in vitro. None of the compounds, including taxinine, influenced the activities of the other DNA polymerases, which are reportedly targeted by many pol.beta inhibitors. With both pol.alpha and beta, all of the compounds tested noncompetitively inhibited with respect to both the DNA template-primer and the dNTP substrate.     

DNA polymerase alpha from normal rat liver is different than DNA polymerases alpha from Morris hepatoma strains

To investigate whether DNA replication in rat hepatoma cells is altered compared with that in normal rat liver, the main replicative enzyme, i.e. the DNA polymerase alpha complex, was partially purified from a slow-growing (TC5123) and a fast-growing (MH3924) Morris hepatoma cell strain as well as from normal rat liver. The purified DNA polymerase alpha complexes contained RNA primase. DNA polymerase alpha activities of these complexes were characterized with regard to both their molecular properties and their dNTP and DNA binding sites. The latter were probed with competitive inhibitors of dNTP binding, resulting in Ki values, and with DNA templates, yielding Km values. The sedimentation coefficients of native DNA polymerases alpha from Morris hepatoma cells were found to be lower than that of polymerase alpha from normal rat liver. Consequently, when following the procedure of Siegel and Monty for determination of molecular mass considerably smaller molecular masses were calculated for polymerases of hepatoma strains (TC5123, 127 kDa; MH3924, 138 kDa; rat liver, 168 kDa). Similar differences were found when the dNTP binding site was probed with inhibitors. Ki values obtained with butylphenyl-dGTP were higher for polymerases of the hepatoma strains than for that of normal rat liver. However, Ki values measured with aphidicolin and butylanilino-dATP were lower for DNA polymerase alpha from the fast-growing hepatoma cell strain than for that from normal rat liver, indicating a reduced affinity of the dNTP binding sites for dATP and dCTP. This reduced affinity could be responsible for lowered specificity of nucleotide selection in the base-pairing process which in turn may cause an enhanced error rate in DNA replication in malignant cells. Furthermore, when the DNA binding site was characterized by Michaelis-Menten constants using gapped DNA as a template, Km values were similar for all three DNA polymerases. In contrast, the Km value measured with single-stranded DNA as a template was found to be lower for DNA polymerase alpha from the fast-growing hepatoma MH3924 than for that from normal rat liver. Thus, the DNA-polymerizing complex from MH3924 combines both higher binding strength to single-stranded DNA templates and decreased nucleotide selection, properties which may enhance replication velocity and may lower fidelity.     

DNA structure and polymerase fidelity.

The accuracy of DNA replication results from both the intrinsic DNA polymerase fidelity and the DNA sequence. Although the recent structural studies on polymerases have brought new insights on polymerase fidelity, the role of DNA sequence and structure is less well understood. Here, the analysis of the crystal structures of hotspots for polymerase slippage including (CA)n and (A)n tracts in different intermolecular contexts reveals that, in the B-form, these sequences share common structural alterations which may explain the high rate of replication errors. In particular, a two-faced "Janus-like" structure with shifted base-pairs in the major groove but an apparent normal geometry in the minor groove constitutes a molecular decoy specifically suitable to mislead the polymerases. A model of the rat polymerase beta bound to this structure suggests that an altered conformation of the nascent template-primer duplex can interfere with correct nucleotide incorporation by affecting the geometry of the active site and breaking the rules of base-pairing, while at the same time escaping enzymatic mechanisms of error discrimination which scan for the correct geometry of the minor groove.In contrast, by showing that the A-form greatly attenuates the sequence-dependent structural alterations in hotspots, this study suggests that the A-conformation of the nascent template-primer duplex at the vicinity of the polymerase active site will contribute to fidelity. The A-form may play the role of a structural buffer which preserves the correct geometry of the active site for all sequences. The detailed comparison of the conformation of the nascent template-primer duplex in the available crystal structures of DNA polymerase-DNA complexes shows that polymerase beta, the least accurate enzyme, is unique in binding to a B-DNA duplex even close to its active site. This model leads to several predictions which are discussed in the light of published experimental data.     

Direct observation of translocation in individual DNA polymerase complexes

Complexes of phi29 DNA polymerase and DNA fluctuate on the millisecond time scale between two ionic current amplitude states when captured atop the α-hemolysin nanopore in an applied field. The lower amplitude state is stabilized by complementary dNTP and thus corresponds to complexes in the post-translocation state. We have demonstrated that in the upper amplitude state, the DNA is displaced by a distance of one nucleotide from the post-translocation state. We propose that the upper amplitude state corresponds to complexes in the pre-translocation state. Force exerted on the template strand biases the complexes toward the pre-translocation state. Based on the results of voltage and dNTP titrations, we concluded through mathematical modeling that complementary dNTP binds only to the post-translocation state, and we estimated the binding affinity. The equilibrium between the two states is influenced by active site-proximal DNA sequences. Consistent with the assignment of the upper amplitude state as the pre-translocation state, a DNA substrate that favors the pre-translocation state in complexes on the nanopore is a superior substrate in bulk phase for pyrophosphorolysis. There is also a correlation between DNA sequences that bias complexes toward the pre-translocation state and the rate of exonucleolysis in bulk phase, suggesting that during DNA synthesis the pathway for transfer of the primer strand from the polymerase to exonuclease active site initiates in the pre-translocation state.     

The C-terminal domain of dnaQ contains the polymerase binding site

The Escherichia coli dnaQ gene encodes the 3'-->5' exonucleolytic proofreading (epsilon) subunit of DNA polymerase III (Pol III). Genetic analysis of dnaQ mutants has suggested that epsilon might consist of two domains, an N-terminal domain containing the exonuclease and a C-terminal domain essential for binding the polymerase (alpha) subunit. We have created truncated forms of dnaQ resulting in epsilon subunits that contain either the N-terminal or the C-terminal domain. Using the yeast two-hybrid system, we analyzed the interactions of the single-domain epsilon subunits with the alpha and theta subunits of the Pol III core. The DnaQ991 protein, consisting of the N-terminal 186 amino acids, was defective in binding to the alpha subunit while retaining normal binding to the theta subunit. In contrast, the NDelta186 protein, consisting of the C-terminal 57 amino acids, exhibited normal binding to the alpha subunit but was defective in binding to the theta subunit. A strain carrying the dnaQ991 allele exhibited a strong, recessive mutator phenotype, as expected from a defective alpha binding mutant. The data are consistent with the existence of two functional domains in epsilon, with the C-terminal domain responsible for polymerase binding.