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.     

Abasic template lesions are strong chain terminators for DNA primase but not for DNA polymerase alpha during the synthesis of new DNA strands.

The effects of abasic lesions on both primase activity and DNA polymerase alpha- (pol alpha) catalyzed elongation of primase-synthesized primers were examined. Abasic lesions were strong chain terminators during primer synthesis by primase. However, extension of primase-synthesized primers by pol alpha resulted in 60-93% bypass of abasic lesions. Sequencing of bypass products generated during this primase-coupled pol alpha activity showed that dAMP was preferentially incorporated opposite the abasic lesion, indicating that pol alpha was responsible for bypass. In contrast, previous analyses of pol alpha-catalyzed elongation of exogenously supplied DNA primer-templates showed that abasic lesions strongly terminated DNA synthesis. Thus, elongation of primase-synthesized primers by pol alpha-primase is fundamentally different than elongation of exogenously added primer-templates with respect to interaction with abasic lesions. Furthermore, this high level of abasic lesion bypass during primase-coupled pol alpha activity provides an additional mechanism for how translesional synthesis may occur in vivo, an event hypothesized to be mutagenic.     

Mechanism of initiation of in vitro DNA synthesis by the immunopurified complex between yeast DNA polymerase I and DNA primase

The immunopurified yeast DNA-polymerase-I--DNA-primase complex synthesizes oligo(rA) and oligo(rG) molecules that are used as primer for replication of poly(dT) and poly(dC). Neither initiation nor DNA synthesis is observed with poly(dA) and poly(dI). Nitrocellulose-filter binding shows that the enzyme complex binds to deoxypyrimidine polymers, but not to deoxypurine polymers. Although the yeast complex initiates DNA synthesis on deoxypyrimidine homopolymers, it prefers to elongate pre-existing primer molecules rather than to initiate de novo DNA replication. The size of the oligo(rA) and oligo(rG) primer molecules has been determined by urea/polyacrylamide gel electrophoresis: longer oligoribonucleotides are synthesized when their utilization is prevented by omitting dNTP. An oligodeoxythymidylate template with a chain length as short as five residues can support oligo(rA) synthesis catalyzed by the yeast DNA-polymerase--DNA-primase complex and the size of the oligoribonucleotide products synthesized with oligodeoxythymidylate of differing chain length has also been determined. The mechanistic properties of the DNA-polymerase--DNA-primase complexes, purified from different eukaryotic organisms, appear to be very similar. The possible biological implication of the studies on the mechanism and specificity of initiation of DNA synthesis in a well-defined model template system has been discussed.     

The presence of nucleosomes on a DNA template prevents initiation by RNA polymerase II in vitro

RNA was synthesized in vitro using HeLa cell nuclear extracts and circular DNA templates onto which varying numbers of nucleosomes had been reconstituted with Xenopus oocyte extracts. We found that fully reconstituted templates supported no specific initiation by RNA polymerase II; however, DNA exposed to the reconstitution extracts under conditions which did not allow nucleosome deposition was transcribed normally. A set of successively less reconstituted templates was also transcribed. No initiation occurred on reconstitutes with more than two-thirds of the physiological nucleosome density; reconstitutes with less than one-third of the physiological nucleosome density were transcribed as efficiently as naked DNA.     

Structural and enzymological characterization of immunoaffinity-purified DNA polymerase alpha.DNA primase complex from KB cells

We describe the polypeptide structure and some of the catalytic properties of a DNA polymerase alpha.DNA primase complex that can be prepared from KB cells by immunoaffinity purification. The procedure is based on monoclonal antibodies that were raised against a biochemically purified, catalytically active core protomer of the polymerase. In all respects tested, the basic mechanism of substrate recognition and binding by the immunoaffinity-purified polymerase is qualitatively identical to that of the core protomer. The immunoaffinity-purified KB cell polymerase alpha X DNA primase is structurally complex. On the basis of extensive immunochemical analyses with five independent monoclonal antibodies, three of which are potent neutralizers of polymerase alpha activity, peptide mapping studies, and the application of a sensitive immunoassay that permits detection of polymerase alpha antigens in crude cell lysates, we have established that the principal form of catalytically active DNA polymerase alpha in KB cells is a phosphoprotein with a molecular mass of 180 kilodaltons. This protein is stable in vivo, with an estimated half-life of greater than or equal to 15 h. In contrast, the polypeptide is extremely fragile in vitro and generates partial degradation products of p165, p140, and p125 that explain the "microheterogeneity" typically exhibited by polymerase alpha peptides in denaturing polyacrylamide gels. In addition to the catalytically active polymerase alpha polypeptide(s), the immunopurified enzyme fraction typically contains three other proteins, p77, p55, and p49, the functions of which have not yet been established. These proteins do not display polymerase alpha epitopes and have been shown by peptide mapping to be independent species that are unrelated either to the large polymerase peptides or to one another. The polypeptide p77 is also a phosphoprotein, and in both p180 and p77 the phosphorylated amino acids are exclusively serine and threonine.     

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.     

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.     

Fidelity of DNA polymerase I and the DNA polymerase I-DNA primase complex from Saccharomyces cerevisiae.

We have determined the fidelity of DNA synthesis by DNA polymerase I (yPol I) from Saccharomyces cerevisiae. To determine whether subunits other than the polymerase catalytic subunit influence fidelity, we measured the accuracy of yPol I purified by conventional procedures, which yields DNA polymerase with a partially proteolyzed catalytic subunit and no associated primase activity, and that of yPol I purified by immunoaffinity chromatography, which yields polymerase having a single high-molecular-weight species of the catalytic subunit, as well as three additional polypeptides and DNA primase activity. In assays that score polymerase errors within the lacZ alpha-complementation gene in M13mp2 DNA, yPol I and the yPol I-primase complex produced single-base substitutions, single-base frameshifts, and larger deletions. For specific errors and template positions, the two forms of polymerase exhibited differences in fidelity that could be as large as 10-fold. Nevertheless, results for the overall error frequency and the spectrum of errors suggest that the yPol I-DNA primase complex is not highly accurate and that, just as for the polymerase alone, its fidelity is not sufficient to account for a low spontaneous mutation rate in vivo. The specificity data also suggest models to explain -1 base frameshifts in nonrepeated sequences and certain complex deletions by a direct repeat mechanism involving aberrant loop-back synthesis.     

RNA and DNA synthesis catalyzed by a DNA-polymerase alpha complex with primase from silkworm cells on single-stranded DNA]

Depending on the ionic environment the replicative complex of silkworm Bombyx mori, containing DNA polymerase alpha and primase, catalyzes on single-stranded DNA of phage M13 a NTP-dependent synthesis or elongation of preformed primers. In the presence of NTPs and dNTPs at conditions optimal for the NTP-dependent synthesis the replicative complex synthesizes on M13 DNA oligoribonucleotides of 9-11 residues, which serve as primers for polymerization of DNA. The length of RNA-primers synthesized by primase of the complex depends on concentration of dNTP but does not depend on activity of DNA polymerase alpha. During elongation of exogenic primers annealed to M13 DNA the complex is processive synthesizing DNA fragments of dozens residues without dissociation from the template. Double-stranded structures in DNA such as "hairpins" appear to be barriers for driving of the complex along the template and cause pauses in elongation. DNA-binding proteins the SSB of Escherichia coli or the p32 of phage T4 destabilize double-stranded regions in DNA and eliminate elongation pauses corresponding to these regions. The replicative complex is able to fill in single-stranded gaps in DNA completely and to perform slowly the synthesis with displacement of one of parent strands in duplexes via repeated cycles of binding to the primer-template, limited elongation and dissociation.     

Inhibition of DNA primase and polymerase alpha by arabinofuranosylnucleoside triphosphates and related compounds.

Inhibition of DNA primase and polymerase alpha from calf thymus was examined. DNA primase requires a 3'-hydroxyl on the incoming NTP in order to polymerize it, while the 2'-hydroxyl is advantageous, but not essential. Amazingly, primase prefers to polymerize araATP rather than ATP by 4-fold (kcat/KM). However, after incorporation of an araNMP into the growing primer, further synthesis is abolished. The 2'- and 3'-hydroxyls of the incoming nucleotide appear relatively unimportant for nucleotide binding to primase. Polymerization of nucleoside triphosphates by DNA polymerase alpha onto a DNA primer was similarly analyzed. Removing the 3'-hydroxyl of the incoming triphosphate decreases the polymerization rate greater than 1000-fold (kcat/KM), while a 2'-hydroxyl in the ribo configuration abolishes polymerization. If the 2'-hydroxyl is in the ara configuration, there is almost no effect on polymerization. An araCMP or ddCMP at the 3'-terminus of a DNA primer slightly decreased DNA binding as well as binding of the next correct 2'-dNTP. Changing the primer from DNA to RNA dramatically and unpredictably altered the interactions of pol alpha with araNTPs and ddNTPs. Compared to the identical DNA primer, pol alpha discriminated 4-fold better against araCTP polymerization when the primer was RNA, but 85-fold worse against ddCTP polymerization. Additionally, pol alpha elongated RNA primers containing 3'-terminal araNMPs more efficiently than the identical DNA substrate.     

DNA primase isolated from the yeast DNA primase-DNA polymerase complex. Immunoaffinity purification and analysis of RNA primer synthesis

We have utilized immunoaffinity chromatography as a means of efficiently isolating a stable yeast DNA primase from the DNA primase-DNA polymerase complex, allowing identification of the polypeptides associated with this DNA primase activity and comparison of its enzymatic properties with those of the larger protein complex. A mouse monoclonal antibody specifically recognizing the DNA polymerase subunit was used to purify the complex. Stable DNA primase was subsequently separated from the complex in high yield. The highly purified protein fraction which bound to the DNA polymerase antibody column consisted of polypeptides with apparent molecular masses of 180, 86, 70, 58, 49, and 47 kDa. DNA primase activity eluted with a fraction containing only the 58-, 49-, and 47-kDa polypeptides. Partial chemical cleavage analysis of these three proteins demonstrated that the 49- and 47-kDa polypeptides are structurally related while the 58-kDa protein is unrelated to the other two. A DNA primase inhibitory monoclonal antibody was able to inhibit the activity of the purified DNA primase as well as the activity of the enzyme in the larger complex. In immunoprecipitation experiments, all three polypeptides were found in the immune complex. Thus, these three polypeptides are sufficient for DNA primase activity. In reactions using ribonucleotide substrates and natural as well as synthetic DNA templates, the purified DNA primase exhibited the same precise synthesis of unit length oligomers as did the larger protein complex and was able to extend these RNA oligomers by one additional unit length. An examination of the effects of deoxynucleotides on these DNA primase-catalyzed reactions revealed that the yeast DNA primase is an RNA-polymerizing enzyme and lacks significant DNA-polymerizing activity under the conditions tested.     

Characterization of a stable, major DNA polymerase alpha species devoid of DNA primase activity.

We have purified from Xenopus laevis ovaries a major DNA polymerase alpha species that lacked DNA primase activity. This primase-devoid DNA polymerase alpha species exhibited the same sensitivity as the DNA polymerase DNA primase alpha to BuAdATP and BuPdGTP, nucleotide analogs capable of distinguishing between DNA polymerase delta and DNA polymerase DNA primase alpha. The primase-devoid DNA polymerase alpha species also lacked significant nuclease activity indicative of the alpha-like (rather than delta-like) nature of the DNA polymerase. Using a poly(dT) template, the primase-devoid DNA polymerase alpha species elongated an oligo(rA10) primer up to 51-fold more effectively than an oligo(dA10) primer. In direct contrast, the DNA polymerase DNA primase alpha complex showed only a 4.6-fold preference for oligoribonucleotide primers at the same template/primer ratio. The catalytic differences between the two DNA polymerase alpha species were most dramatic at a template/primer ratio of 300. The primase-devoid DNA polymerase alpha species was found at high levels throughout oocyte and embryonic development. This suggests that the primase-devoid DNA polymerase alpha species could play a physiological role during DNA chain elongation in vivo, even if it is chemically related to DNA polymerase DNA primase alpha.     

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.