DNA polymerase ß nucleotide-stabilized template misalignment fidelity depends on local sequence context.

DNA polymerase ß has two DNA-binding domains that interact with the opposite sides of short DNA gaps. These domains contribute two activities that modify the 5' and 3' margins of gapped DNA during base excision repair. DNA gaps greater than 1 nucleotide (nt) pose an architectural and logistical problem for the two domains to interact with their respective DNA termini. Here, crystallographic and kinetic analyses of 2-nt gap-filling DNA synthesis revealed that the fidelity of DNA synthesis depends on local sequence context. This was due to template dynamics that altered which of the two template nucleotides in the gap served as the coding nucleotide. We observed that, when a purine nucleotide was in the first coding position, DNA synthesis fidelity was similar to that observed with a 1-nt gap. However, when the initial templating nucleotide was a pyrimidine, fidelity was decreased. If the first templating nucleotide was a cytidine, there was a significantly higher probability that the downstream template nucleotide coded for the incoming nucleotide. This dNTP-stabilized misalignment reduced base substitution and frameshift deletion fidelities. A crystal structure of a binary DNA product complex revealed that the cytidine in the first templating site was in an extrahelical position, permitting the downstream template nucleotide to occupy the coding position. These results indicate that DNA polymerase ß can induce a strain in the DNA that modulates the position of the coding nucleotide and thereby impacts the identity of the incoming nucleotide. Our findings demonstrate that "correct" DNA synthesis can result in errors when template dynamics induce coding ambiguity.

Metal-induced DNA translocation leads to DNA polymerase conformational activation.

Binding of the catalytic divalent ion to the ternary DNA polymerase ß/gapped DNA/dNTP complex is thought to represent the final step in the assembly of the catalytic complex and is consequently a critical determinant of replicative fidelity. We have analyzed the effects of Mg(2+) and Zn(2+) on the conformational activation process based on NMR measurements of [methyl-(13)C]methionine DNA polymerase ß. Unexpectedly, both divalent metals were able to produce a template base-dependent conformational activation of the polymerase/1-nt gapped DNA complex in the absence of a complementary incoming nucleotide, albeit with different temperature thresholds. This conformational activation is abolished by substituting Glu295 with lysine, thereby interrupting key hydrogen bonds necessary to stabilize the closed conformation. These and other results indicate that metal-binding can promote: translocation of the primer terminus base pair into the active site; expulsion of an unpaired pyrimidine, but not purine, base from the template-binding pocket; and motions of polymerase subdomains that close the active site. We also have performed pyrophosphorolysis studies that are consistent with predictions based on these results. These findings provide new insight into the relationships between conformational activation, enzyme activity and polymerase fidelity.

Molecular insights into DNA polymerase deterrents for ribonucleotide insertion.

DNA polymerases can misinsert ribonucleotides that lead to genomic instability. DNA polymerase ß discourages ribonucleotide insertion with the backbone carbonyl of Tyr-271; alanine substitution of Tyr-271, but not Phe-272, resulted in a >10-fold loss in discrimination. The Y271A mutant also inserted ribonucleotides more efficiently than wild type on a variety of ribonucleoside (rNMP)-containing DNA substrates. Substituting Mn(2+) for Mg(2+) decreased sugar discrimination for both wild-type and mutant enzymes primarily by increasing the affinity for rCTP. This facilitated crystallization of ternary substrate complexes of both the wild-type and Y271A mutant enzymes. Crystallographic structures of Y271A- and wild type-substrate complexes indicated that rCTP is well accommodated in the active site but that O2' of rCTP and the carbonyl oxygen of Tyr-271 or Ala-271 are unusually close (∼2.5 and 2.6 Å, respectively). Structure-based modeling indicates that the local energetic cost of positioning these closely spaced oxygens is ∼2.2 kcal/mol for the wild-type enzyme. Because the side chain of Tyr-271 also hydrogen bonds with the primer terminus, loss of this interaction affects its catalytic positioning. Our results support a model where DNA polymerase ß utilizes two strategies, steric and geometric, with a single protein residue to deter ribonucleotide insertion.

B family DNA polymerases asymmetrically recognize pyrimidines and purines.

We utilized a series of pyrimidine analogues modified at O(2), N-3, and N(4)/O(4) to determine if two B family DNA polymerases, human DNA polymerase α and herpes simplex virus I DNA polymerase, choose whether to polymerize pyrimidine dNTPs using the same mechanisms they use for purine dNTPs. Removing O(2) of a pyrimidine dNTP vastly decreased the level of incorporation by these enzymes and also compromised fidelity in the case of C analogues, while removing O(2) from the templating base had more modest effects. Removing the Watson-Crick hydrogen bonding groups of N-3 and N(4)/O(4) greatly impaired polymerization, both of the resulting dNTP analogues and of natural dNTPs opposite these pyrimidine analogues when present in the template strand. Thus, the Watson-Crick hydrogen bonding groups of a pyrimidine clearly play an important role in enhancing correct dNTP polymerization but are not essential for preventing misincorporation. These studies also indicate that DNA polymerases recognize bases extremely asymmetrically, both in terms of whether they are a purine or pyrimidine and whether they are in the template or are the incoming dNTP. The mechanistic implications of these results with regard to how polymerases discriminate between right and wrong dNTPs are discussed.

DNA polymerase beta ribonucleotide discrimination: insertion, misinsertion, extension, and coding.

DNA polymerases must select nucleotides that preserve Watson-Crick base pairing rules and choose substrates with the correct (deoxyribose) sugar. Sugar discrimination represents a great challenge because ribonucleotide triphosphates are present at much higher cellular concentrations than their deoxy-counterparts. Although DNA polymerases discriminate against ribonucleotides, many therapeutic nucleotide analogs that target polymerases have sugar modifications, and their efficacy depends on their ability to be incorporated into DNA. Here, we investigate the ability of DNA polymerase beta to utilize nucleotides with modified sugars. DNA polymerase beta readily inserts dideoxynucleoside triphosphates but inserts ribonucleotides nearly 4 orders of magnitude less efficiently than natural deoxynucleotides. The efficiency of ribonucleotide insertion is similar to that reported for other DNA polymerases. The poor polymerase-dependent insertion represents a key step in discriminating against ribonucleotides because, once inserted, a ribonucleotide is easily extended. Likewise, a templating ribonucleotide has little effect on insertion efficiency or fidelity. In contrast to insertion and extension of a ribonucleotide, the chemotherapeutic drug arabinofuranosylcytosine triphosphate is efficiently inserted but poorly extended. These results suggest that the sugar pucker at the primer terminus plays a crucial role in DNA synthesis; a 3'-endo sugar pucker facilitates nucleotide insertion, whereas a 2'-endo conformation inhibits insertion.

Base excision repair and design of small molecule inhibitors of human DNA polymerase ß.

Base excision repair (BER) can protect a cell after endogenous or exogenous genotoxic stress, and a deficiency in BER can render a cell hypersensitive to stress-induced apoptotic and necrotic cell death, mutagenesis, and chromosomal rearrangements. However, understanding of the mammalian BER system is not yet complete as it is extraordinarily complex and has many back-up processes that complement a deficiency in any one step. Due of this lack of information, we are unable to make accurate predictions on therapeutic approaches targeting BER. A deeper understanding of BER will eventually allow us to conduct more meaningful clinical interventions. In this review, we will cover historical and recent information on mammalian BER and DNA polymerase ß and discuss approaches toward development and use of small molecule inhibitors to manipulate BER. With apologies to others, we will emphasize results obtained in our laboratory and those of our collaborators.

Identifying the features of purine dNTPs that allow accurate and efficient DNA replication by herpes simplex virus I DNA polymerase.

To accurately replicate its viral genome, the Herpes Simplex Virus 1 (HSV-1) DNA polymerase usually polymerizes the correct natural 2'-deoxy-5'-triphosphate (dNTP) opposite the template base being replicated. We employed a series of purine-dNTP analogues to determine the chemical features of the base necessary for the herpes polymerase to avoid polymerizing incorrect dNTPs. The enzyme uses N-3 to prevent misincorporation of purine dNTPs but does not require N-3 for correct polymerization. A free pair of electrons on N-1 also helps prevent misincorporation opposite A, C, and G and strongly drives polymerization opposite T. N6 contributes a small amount both for preventing misincorporation and for correct polymerization. Within the context of guanine in either the incoming dNTP or the template base being replicated, N2 prevents misincorporation opposite adenine but plays at most a minor role for incorporation opposite C. In contrast, adding N2 to the dNTPs of either adenine, purine, 6-chloropurine, or 1-deazapurine greatly enhances incorporation opposite C, likely via the formation of a hydrogen bond between N2 of the purine and O2 of the pyrimidine. Herpes polymerase is very sensitive to the structure of the base pair at the primer 3'-terminus since eliminating N-1, N-3, or N6 from a purine nucleotide at the primer 3'-terminus interfered with polymerization of the next two dNTPs. The biological and evolutionary implications of these data are discussed.

Herpes simplex virus-1 helicase-primase: roles of each subunit in DNA binding and phosphodiester bond formation.

The helicase-primase complex from herpes simplex virus-1 contains three subunits, UL5, UL52, and UL8. We generated each of the potential two-subunit complexes, UL5-UL52, UL5-UL8, and UL52-UL8, and used a series of kinetic and photo-cross-linking studies to provide further insights into the roles of each subunit in DNA binding and primer synthesis. UL8 increases the rate of primer synthesis by UL5-UL52 by increasing the rate of primer initiation (two NTPs --> pppNpN), the rate-limiting step in primer synthesis. The UL5-UL8 complex lacked any detectable catalytic activity (DNA-dependent ATPase, primase, or RNA polymerase using a RNA primer-template and NTPs as substrates) but could still bind DNA, indicating that UL52 must provide some key amino acids needed for helicase function. The UL52-UL8 complex lacked detectable DNA-dependent ATPase activity and could not synthesize primers on single-stranded DNA. However, it exhibited robust RNA polymerase activity using a RNA primer-template and NTPs as substrates. Thus, UL52 must contain the entire primase active site needed for phosphodiester bond formation, while UL5 minimally contributes amino acids needed for the initiation of primer synthesis. Photo-cross-linking experiments using single-stranded templates containing 5-iodouracil either before, in, or after the canonical 3'-GPyPy (Py is T or C) initiation site for primer synthesis showed that only UL5 cross-linked to the DNA. This occurred for the UL5-UL52, UL5-UL52-UL8, and UL5-UL8 complexes and whether the reaction mixtures contained NTPs. Photo-cross-linking of a RNA primer-template, the product of primer synthesis, containing 5-iodouracil in the template generated the same apparent cross-linked species.

Initiation of new DNA strands by the herpes simplex virus-1 primase-helicase complex and either herpes DNA polymerase or human DNA polymerase alpha.

A key set of reactions for the initiation of new DNA strands during herpes simplex virus-1 replication consists of the primase-catalyzed synthesis of short RNA primers followed by polymerase-catalyzed DNA synthesis (i.e. primase-coupled polymerase activity). Herpes primase (UL5-UL52-UL8) synthesizes products from 2 to approximately 13 nucleotides long. However, the herpes polymerase (UL30 or UL30-UL42) only elongates those at least 8 nucleotides long. Surprisingly, coupled activity was remarkably inefficient, even considering only those primers at least 8 nucleotides long, and herpes polymerase typically elongated <2% of the primase-synthesized primers. Of those primers elongated, only 4-26% of the primers were passed directly from the primase to the polymerase (UL30-UL42) without dissociating into solution. Comparing RNA primer-templates and DNA primer-templates of identical sequence showed that herpes polymerase greatly preferred to elongate the DNA primer by 650-26,000-fold, thus accounting for the extremely low efficiency with which herpes polymerase elongated primase-synthesized primers. Curiously, one of the DNA polymerases of the host cell, polymerase alpha (p70-p180 or p49-p58-p70-p180 complex), extended herpes primase-synthesized RNA primers much more efficiently than the viral polymerase, raising the possibility that the viral polymerase may not be the only one involved in herpes DNA replication.