Herpes simplex virus-1 primase: a polymerase with extraordinarily low fidelity

We utilized templates of defined sequence to investigate the fidelity and mechanism of NTP misincorporation by DNA primase from herpes simplex virus-1. Herpes primase generated a wide range of mismatches during primer synthesis, including purine-purine, pyrimidine-pyrimidine, and purine-pyrimidine mismatches, and could even polymerize consecutive incorrect NTPs. Polymerization of noncognate NTPs resulted from primase misreading the template, as opposed to a primer slippage or dislocation mutagenesis mechanism. Primase did not efficiently misincorporate NTPs during the initiation reaction (i.e., dinucleotide synthesis). However, during primer elongation (after dinucleotide formation), herpes primase was extraordinarily inaccurate. It misincorporated NTPs at frequencies as high as 1 in 7, although frequencies of 1 in 25 to 1 in 60 were more common. In every case, however, misincorporation frequencies were no less than 1 in 100. For a specific mismatch, the DNA sequences flanking the site where misincorporation occurred could influence the frequency of misincorporation. This remarkably low level of fidelity is as low as that observed for the least accurate members of the Y class DNA polymerases involved in lesion bypass. Thus, herpes primase is one of the least accurate nucleotide polymerizing enzymes known.     

Mechanism of primer synthesis by the herpes simplex virus 1 helicase-primase

We utilized templates of defined sequence to investigate the mechanism of primer synthesis by herpes simplex virus 1 helicase-primase. Under steady-state conditions, the rate of primer synthesis and the size distribution of products remained constant with time, suggesting that the rate-limiting step(s) of primer synthesis occur(s) during primer initiation (at or before the formation of the pppNpN dinucleotide). Consistent with this idea, increasing the concentration of NTPs required for dinucleotide synthesis increased the rate of primer synthesis, whereas increasing the concentration of NTPs not involved in dinucleotide synthesis inhibited primer synthesis. Due to these effects on primer initiation, varying the NTP concentration could affect start site selection on templates containing multiple G-pyr-pyr initiation sites. Increasing the NTP concentration also increased the processivity of primase. However, even at very high concentrations of NTPs, elongation of the dinucleotide into longer products remained relatively inefficient. Primase did not readily elongate preexisting primers under conditions where free template was present in large excess of enzyme. However, if template concentrations were lowered such that primase synthesized primers on all or most of the template present in the reaction, then primase would elongate previously synthesized primers.     

Herpes simplex virus 1 primase employs watson-crick hydrogen bonding to identify cognate nucleoside triphosphates

We utilized NTP analogues containing modified bases to probe the mechanism of NTP selection by the primase activity of the herpes simplex virus 1 helicase-primase complex. Primase readily bound NTP analogues of varying base shape, hydrophobicity, and hydrogen-bonding capacity. Remarkably, primase strongly discriminated against incorporating virtually all of the analogues, even though this enzyme misincorporates natural NTPs at frequencies as high as 1 in 7. This included analogues with bases much more hydrophobic than a natural base (e.g., 4- and 7-trifluoromethylbenzimidazole), a base of similar hydrophobicity as a natural base but with the Watson-Crick hydrogen-bonding groups in unusual positions (7-beta-d-guanine), bases shaped almost identically to the natural bases (4-aminobenzimidazole and 4,6-difluorobenzimidazole), bases shaped very differently than a natural base (e.g., 5- and 6-trifluoromethylbenzimidazole), and bases capable of forming just one Watson-Crick hydrogen bond with the template base (purine and 4-aminobenzimidazole). The only analogues that primase readily polymerized into primers (ITP and 3-deaza-ATP) were those capable of forming Watson-Crick hydrogen bonds with the template base. Thus, herpes primase appears to require the formation of Watson-Crick hydrogen bonds in order to efficiently polymerize a NTP. In contrast to primase's narrow specificity for NTP analogues, the DNA-dependent NTPase activity associated with the herpes primase-helicase complex exhibited very little specificity with respect to NTPs containing unnatural bases. The implications of these results with respect to the mechanism of the helicase-primase and current fidelity models are discussed.     

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.     

Key role of template sequence for primer synthesis by the herpes simplex virus 1 helicase-primase

We investigated the effects of ssDNA template sequence on both primer synthesis and NTP hydrolysis by herpes simplex virus 1 helicase-primase. Primer synthesis was found to be profoundly dependent upon template sequence. Although not absolutely required, an important sequence feature for significant production of longer primers (beyond four nucleotides in length) is a deoxyguanylate-pyrimidine-pyrimidine (3'-G-pyr-pyr-5') triplet in the template. The deoxyguanylate serves both to direct primase to initiate synthesis opposite the adjacent pyrimidine and to dramatically increase primer length. While primase synthesized significantly more long primers on those templates containing a G-pyr-pyr triplet, the enzyme still synthesized massive quantities of di- and trinucleotides on many templates containing this sequence. Varying the sequences around the G-pyr-pyr recognition sequence dramatically altered both the rate of primer synthesis and the fraction of primers longer than four nucleotides, indicating that primase must interact with both the G-pyr-pyr and flanking sequences in the template. In contrast to the large effects that varying the template sequence had on primase activity, ssDNA-dependent NTPase activity was essentially unaffected by changes in template sequence, including the presence or absence of the G-pyr-pyr trinucleotide. In addition to hydrolyzing NTPs the NTPase could also hydrolyze the 5'-terminal phosphate from newly synthesized primers.     

Human DNA primase uses Watson-Crick hydrogen bonds to distinguish between correct and incorrect nucleoside triphosphates

Human DNA primase synthesizes short RNA primers that DNA polymerase alpha further elongates. Primase readily misincorporates the natural NTPs and will generate a wide variety of mismatches. In contrast, primase exhibited a remarkable resistance to polymerizing NTPs containing unnatural bases. This included bases whose shape was almost identical to the natural bases (4-aminobenzimidazole and 4,6-difluorobenzimidazole), bases shaped very differently than a natural base [e.g., 5- and 6-(trifluoromethyl)benzimidazole], bases much more hydrophobic than a natural base [e.g., 4- and 7-(trifluoromethyl)benzimidazole], bases of similar hydrophobicity as a natural base but with the Watson-Crick hydrogen-bonding groups in unusual positions (7-beta-D-guanine), and bases capable of forming only one Watson-Crick hydrogen bond with the template base (purine and 4-aminobenzimidazole). Primase only polymerized NTP analogues containing bases capable of forming hydrogen bonds between the equivalent of both N-1 and the exocyclic group at C-6 of a purine NTP (2-fluoroadenine, 2-chloroadenine, 3-deazaadenine, and hypoxanthine) and N-3 and the exocyclic group at C-4 of a pyrimidine. These data indicate that human primase requires the formation of Watson-Crick hydrogen bonds in order to polymerize a NTP, a situation very different than what is observed with some DNA polymerases. The implications of these results with respect to current theories of how polymerases discriminate between right and wrong (d)NTPs are discussed.     

Synthesis of nucleotide analogues that potently and selectively inhibit human DNA primase

DNA primase synthesizes short RNA oligonucleotides that DNA polymerase alpha further elongates in order to initiate the synthesis of all new DNA strands during eukaryotic DNA replication. To develop potent and specific primase inhibitors, we combined 2'-modified sugars with bases incapable of normal Watson-Crick hydrogen bonding. The presence of a 2'-hydroxyl in either the ara or ribo configuration greatly enhances the ability of primase to polymerize a nucleotide. Further modifying the 2'-position by including both a hydroxyl and methyl group at this position greatly reduced the ability of primase to polymerize the resulting nucleotides. Replacing the base of the NTP with analogues incapable of normal Watson-Crick hydrogen bonding (benzimidazole, nitrobenzimidazole, and dichlorobenzimidazole) resulted in compounds that inhibited primase quite well and with similar potency. We synthesized arabinofuranosylbenzimidazole triphosphate (araBTP) and found that this sugar change increased inhibition by 2-4-fold relative to the ribofuranosyl analogue. AraBTP inhibited polymerization of both purines and pyrimidines, although primase polymerized only small amounts of the compound. Interestingly, even though araBTP was not readily polymerized by primase, it inhibited primase almost as potently as araATP, a compound that primase polymerizes extremely rapidly and that results in very strong chain termination. Importantly, this compound was a very weak inhibitor of and only slowly polymerized by DNA polymerase alpha, indicating that it is a specific primase inhibitor. The potential utility and mechanistic implications of these inhibitors are discussed.     

A model for dynamics of primer extension by eukaryotic DNA primase

A mathematical model is proposed for processive primer extension by eukaryotic DNA primase. The model uses available experimental data to predict rate constants for the dynamic behavior of primase activity as a function of NTP concentration. The model also predicts some data such as the binding affinities of the primase for the DNA template and for the RNA primer.     

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.     

Preparation of partially 2H/13C-labelled RNA for NMR studies. Stereo-specific deuteration of the H5" in nucleotides

An effective in vitro enzymatic synthesis is described for the production of nucleoside triphosphates (NTPs) which are stereo-specifically deuterated on the H5" position with high selectivity (>98%), and which can have a variety of different labels (13C, 15N, 2H) in other positions. The NTPs can subsequently be employed in the enzymatic synthesis of RNAs using T7 polymerase from a DNA template. The stereo-specific deuteration of the H5" immediately provides the stereo-specific assignment of H5' resonances in NMR spectra, giving access to important structural parameters. Stereo-chemical H-exchange was used to convert commercially available 1,2,3,4,5,6,6-2H-1,2,3,4,5,6-13C-D-glucose (d7-13C6-D-glucose) into [1,2,3,4,5,6(R)-2H-1,2,3,4,5,6-13C]-D-glucose (d6-13C6-D-glucose). [1',3',4',5"-2H-1',2',3',4',5'-13C]GTP (d4-13C5-GTP) was then produced from d6-13C6-D-glucose and guanine base via in vitro enzymatic synthesis employing enzymes from the pentose-phosphate, nucleotide biosynthesis and salvage pathways. The overall yield was approximately 60 mg NTP per 1 g glucose, comparable with the yield of NTPs isolated from Escherichia coli grown on enriched media. The d4-13C5-GTP, together with in vitro synthesised d5-UTP, d5-CTP and non-labelled ATP, were used in the synthesis of a 31 nt RNA derived from the primer binding site of hepatitis B virus genomic RNA. (13C,1H) hetero-nuclear multiple-quantum spectra of the specifically deuterated sample and of a non-deuterated uniformly 13C/15N-labelled sample demonstrates the reduced spectral crowding and line width narrowing compared with 13C-labelled non-deuterated RNA.     

Mechanism of sequence-specific template binding by the DNA primase of bacteriophage T7

DNA primases catalyze the synthesis of the oligoribonucleotides required for the initiation of lagging strand DNA synthesis. Biochemical studies have elucidated the mechanism for the sequence-specific synthesis of primers. However, the physical interactions of the primase with the DNA template to explain the basis of specificity have not been demonstrated. Using a combination of surface plasmon resonance and biochemical assays, we show that T7 DNA primase has only a slightly higher affinity for DNA containing the primase recognition sequence (5′-TGGTC-3′) than for DNA lacking the recognition site. However, this binding is drastically enhanced by the presence of the cognate Nucleoside triphosphates (NTPs), Adenosine triphosphate (ATP) and Cytosine triphosphate (CTP) that are incorporated into the primer, pppACCA. Formation of the dimer, pppAC, the initial step of sequence-specific primer synthesis, is not sufficient for the stable binding. Preformed primers exhibit significantly less selective binding than that observed with ATP and CTP. Alterations in subdomains of the primase result in loss of selective DNA binding. We present a model in which conformational changes induced during primer synthesis facilitate contact between the zinc-binding domain and the polymerase domain.     

Nucleotide binding by the poliovirus RNA polymerase.

Cross-linking of ribonucleoside triphosphates (NTPs) to specific binding sites on the poliovirus RNA-dependent RNA polymerase has been performed by ultraviolet irradiation and by reduction of oxidized nucleotide-protein complexes. The latter method approached a cross-linking efficiency of 1 NTP/molecule of enzyme. Nucleotide competition experiments suggested that the same binding site is occupied by all NTPs. Analysis of peptides produced by proteinase Glu-C and trypsin digestion and labeled with [32P]GTP indicated that a lysine residue between Met-189 and Lys-228 in the polymerase was cross-linked to NTP. Nucleotide binding was exploited for rapid purification of the enzyme by GTP-agarose affinity chromatography. In addition, a set of cloned, modified polymerase molecules with reduced or absent polymerization activity was analyzed for binding efficiency to a GTP-agarose column. Some mutations eliminated GTP binding, whereas others generated proteins with varying affinities for GTP. Incubation of the poliovirus polymerase with high concentrations of NTP, particularly GTP, resulted in a dramatic protection against heat denaturation and activity loss. These data suggest that nucleotide binding results in an alteration of the enzyme conformation or the stabilization of an ordered conformation.     

Roles of the helicase and primase domain of the gene 4 protein of bacteriophage T7 in accessing the primase recognition site.

The 63 kDa gene 4 protein of bacteriophage T7 provides both helicase and primase activities. The C-terminal helicase domain of the gene 4 protein is responsible for DNA-dependent NTP hydrolysis and for hexamer formation, whereas the N-terminal primase domain contains the zinc motif that is, in part, responsible for template-directed oligoribonucleotide synthesis. In the presence of beta, gamma-methylene dTTP, the protein forms a hexamer that surrounds and binds tightly to single-stranded DNA and consequently is unable to translocate to primase recognition sites, 5'-GTC-3', or to dissociate from the molecule to which it is bound. Nonetheless, in the presence of beta,gamma-methylene dTTP, it catalyzes the synthesis of pppAC dimers at primase sites on M13 DNA. When bound to single-stranded DNA in the presence of beta,gamma-methylene dTTP, the primase can function at recognition sites on the same molecule to which it is bound provided that a sufficient distance exists between the recognition site and the site to which it is bound. Furthermore, the primase bound to one DNA strand can function at a primase site located on a second DNA strand. The results indicate that the primase domain resides on the outside of the hexameric ring, a location that enables it to access sites distal to its site of binding.     

Human DNA primase: anion inhibition, manganese stimulation, and their effects on in vitro start-site selection.

We examined the effects of Mn(2+) on eukaryotic DNA primase both in the presence and absence of 5 mM Mg(2+). In the absence of Mg(2+), Mn(2+)-supported primase activity to a level 4-fold greater than that obtained with Mg(2+) alone, and adding low levels of Mn(2+) (100 microM) to assays containing 5 mM Mg(2+) greatly stimulated primase. Increased activity was primarily due to more efficient utilization of NTPs, as reflected in a lower K(M) for NTPs. Under conditions of saturating NTPs, Mn(2+) had minimal effects on both the rate of initiation (i.e., dinucleotide synthesis) and processivity. The effects of Mn(2+) involve multiple metal binding sites on primase and may involve both the catalytic p49 subunit as well as the p58 subunit. Physiological levels of salt can inhibit primase activity due to the presence of an anion binding site and low levels of Mn(2+) significantly decreased this salt sensitivity. The implications of these results with respect to the biological role of primase are discussed.     

Role of bacteriophage T7 DNA primase in the initiation of DNA strand synthesis.

Bacteriophage T7 DNA primase (gene-4 protein, 66,000 daltons) enables T7 DNA polymerase to initiate the synthesis of DNA chains on single-stranded templates. An initial step in the process of chain initiation is the formation of an oligoribonucleotide primer by T7 primase. The enzyme, in the presence of natural SS DNA, Mg++ (or Mn++), ATP and CTP (or a mixture of all 4 rNTPs), catalyzes the synthesis of di-, tri-, and tetraribonucleotides all starting at the 5' terminus with pppA. In a subsequent step requiring both T7 DNA polymerase and primase, the short oligoribonucleotides (predominantly pppA-C-C-AOH) are extended by covalent addition of deoxyribonucleotides. With the aid of primase, T7 DNA polymerase can also utilize efficiently a variety of synthetic tri-, tetra-, or pentanucleotides as chain initiators. T7 primase apparently plays an active role in primer extension by stabilizing the short primer segments in a duplex state on the template DNA.