Human DNA polymerase alpha uses a combination of positive and negative selectivity to polymerize purine dNTPs with high fidelity

Active Site Interactions Impact Phosphoryl Transfer during Replication of Damaged and Undamaged DNA by Escherichia coli DNA Polymerase I

Replicative DNA polymerases are able to discriminate between very similar substrates with high accuracy. One mechanism by which E. coli DNA polymerase I checks for Watson-Crick geometry is through a hydrogen bonding fork between Arg668 and the incoming dNTP and the minor groove of the primer terminus. The importance of the Arg-fork was examined by disrupting it with either a guanine to 3-deazaguanine substitution at the primer terminus or the use of a carbocyclic deoxyribose analog of dUTP. Using thio-substituted dNTPs and differential quench techniques, we determined that when the Arg-fork was disrupted, the rate-limiting step changed from a conformational change to phosphodiester bond formation. This result indicates that Arg668 is involved in the phosphoryl transfer step. We examined the role of the Arg-fork in the replication of four DNA damaged templates, O⁶-methylguanine (O⁶-mG), 8-oxo-7,8-dihydroguanine (oxoG), O²-[4-(3-pyridyl)-4-oxobutyl]thymine (O²-POB-T), and N²-[(7S,8R,9S,10R)-7,8,9,10-tetrahydro-8,9,10-trihydroxybenzo[a]pyren-7-yl]-guanine (N²-BP-G). In general, the guanine to 3-deazaguanine substitution caused a decrease in k_pol that was proportional to k_pol over five orders of magnitude. The linear relationship indicates that the Arg668-fork helps catalyze phosphoryl transfer by the same mechanism with all the substrates. Exceptions to the linear relationship were the incorporations of dTTP opposite G, oxoG, and O⁶mG, which showed large decreases in k_pol, similar to that exhibited by the Watson-Crick base pairs. It was proposed that the incorporation of dTTP opposite G, oxoG, and O⁶mG occurred via Watson-Crick-like structures.

Structural and kinetic insights into binding and incorporation of L-nucleotide analogs by a Y-family DNA polymerase

Considering that all natural nucleotides (D-dNTPs) and the building blocks (D-dNMPs) of DNA chains possess D-stereochemistry, DNA polymerases and reverse transcriptases (RTs) likely possess strongD-stereoselectivity by preferably binding and incorporating D-dNTPs over unnatural L-dNTPs during DNA synthesis. Surprisingly, a structural basis for the discrimination against L-dNTPs by DNA polymerases or RTs has not been established although L-deoxycytidine analogs (lamivudine and emtricitabine) and L-thymidine (telbivudine) have been widely used as antiviral drugs for years. Here we report seven high-resolution ternary crystal structures of a prototype Y-family DNA polymerase, DNA, and D-dCTP, D-dCDP, L-dCDP, or the diphosphates and triphosphates of lamivudine and emtricitabine. These structures reveal that relative to D-dCTP, each of these L-nucleotides has its sugar ring rotated by 180° with an unusual O4'-endo sugar puckering and exhibits multiple triphosphate-binding conformations within the active site of the polymerase. Such rare binding modes significantly decrease the incorporation rates and efficiencies of these L-nucleotides catalyzed by the polymerase.

RB69 DNA polymerase structure, kinetics, and fidelity

This review will summarize our structural and kinetic studies of RB69 DNA polymerase (RB69pol) as well as selected variants of the wild-type enzyme that were undertaken to obtain a deeper understanding of the exquisitely high fidelity of B family replicative DNA polymerases. We discuss how the structures of the various RB69pol ternary complexes can be used to rationalize the results obtained from pre-steady-state kinetic assays. Our main findings can be summarized as follows. (i) Interbase hydrogen bond interactions can increase catalytic efficiency by 5000-fold; meanwhile, base selectivity is not solely determined by the number of hydrogen bonds between the incoming dNTP and the templating base. (ii) Minor-groove hydrogen bond interactions at positions n – 1 and n – 2 of the primer strand and position n – 1 of the template strand in RB69pol ternary complexes are essential for efficient primer extension and base selectivity. (iii) Partial charge interactions among the incoming dNTP, the penultimate base pair, and the hydration shell surrounding the incoming dNTP modulate nucleotide insertion efficiency and base selectivity. (iv) Steric clashes between mismatched incoming dNTPs and templating bases with amino acid side chains in the nascent base pair binding pocket (NBP) as well as weak interactions and large gaps between the incoming dNTPs and the templating base are some of the reasons that incorrect dNTPs are incorporated so inefficiently by wild-type RB69pol. In addition, we developed a tC°–tC_nitro Förster resonance energy transfer assay to monitor partitioning of the primer terminus between the polymerase and exonuclease subdomains.

Insights into the roles of desolvation and π-electron interactions during DNA polymerization

This report describes the use of several isosteric non-natural nucleotides as probes to evaluate the roles of nucleobase shape, size, solvation energies, and π-electron interactions as forces influencing key kinetic steps of the DNA polymerization cycle. Results are provided using representative high- and low-fidelity DNA polymerases. Results generated with the E. coli Klenow fragment reveal that this high-fidelity polymerase utilizes hydrophobic nucleotide analogues with higher catalytic efficiencies compared to hydrophilic analogues. These data support a major role for nucleobase desolvation during nucleotide selection and insertion. In contrast, the low-fidelity HIV-1 reverse transcriptase discriminates against hydrophobic analogues and only tolerates non-natural nucleotides that are capable of hydrogen-bonding or π-stacking interactions. Surprisingly, hydrophobic analogues that function as efficient substrates for the E. coli Klenow fragment behave as noncompetitive or uncompetitive inhibitors against HIV-1 reverse transcriptase. In these cases, the mode of inhibition depends upon the absence or presence of a templating nucleobase. Molecular modeling studies suggest that these analogues bind to the active site of reverse transcriptase as well as to a nearby hydrophobic binding pocket. Collectively, the studies using these non-natural nucleotides reveal important mechanistic differences between representative high- and low-fidelity DNA polymerases during nucleotide selection and incorporation.

Substrate and enzyme functional groups contribute to translational quality control by bacterial prolyl-tRNA synthetase

Aminoacyl-tRNA synthetases activate specific amino acid substrates and attach them via an ester linkage to cognate tRNA molecules. In addition to cognate proline, prolyl-tRNA synthetase (ProRS) can activate cysteine and alanine and misacylate tRNA(Pro). Editing of the misacylated aminoacyl-tRNA is required for error-free protein synthesis. An editing domain (INS) appended to bacterial ProRS selectively hydrolyzes Ala-tRNA(Pro), whereas Cys-tRNA(Pro) is cleared by a freestanding editing domain, YbaK, through a unique mechanism involving substrate sulfhydryl chemistry. The detailed mechanism of catalysis by INS is currently unknown. To understand the alanine specificity and mechanism of catalysis by INS, we have explored several possible mechanisms of Ala-tRNA(Pro) deacylation via hybrid QM/MM calculations. Experimental studies were also performed to test the role of several residues in the INS active site as well as various substrate functional groups in catalysis. Our results support a critical role for the tRNA 2'-OH group in substrate binding and catalytic water activation. A role is also proposed for the protein's conserved GXXXP loop in transition state stabilization and for the main chain atoms of Gly261 in a proton relay that contributes substantially to catalysis.

Investigating chelating sulfonamides and their use in metalloproteinase inhibitors

Matrix metalloproteinase inhibitors (MMPi) utilize zinc-binding groups (ZBGs) to chelate the catalytic Zn(II) ion resulting in enzyme inhibition. Adapting findings from the literature of Zn(II) ion sensors, we previously reported chelating sulfonamide inhibitors of MMP-2, some of which showed excellent selectivity over other gelatinases (MMP-9). Herein, we greatly expand our investigation of chelating sulfonamides as MMP inhibitors (MMPi) with the synthesis and screening of several new libraries consisting of 2-phenyl-7-sulfonamidobenzimidazole, 2-phenyl-7-sulfonamidobenzoxazole, 7-sulfonamidobenzimidazole, 7-sulfonamidobenzoxazole, and 2-(2-sulfonamidophenyl)-quinoline ZBG derivatives. A novel microwave irradiation synthetic procedure was utilized to rapidly and efficiently prepare these molecules. To better understand the coordination chemistry underlying these ZBGs, crystal structures of representative molecules with several first row transition metals were determined and differences in coordination preferences were considered. Surprisingly, only compounds with the 2-phenyl-7-sulfonamidobenzimidazole ZBG showed inhibition of MMP-2, suggesting that the specific structure of the ZBG can have a pronounced effect of inhibitory activity.

Kinetics and fidelity of polymerization by DNA polymerase III from Sulfolobus solfataricus

We have biochemically and kinetically characterized the polymerase and exonuclease activities of the third B-family polymerase (Dpo3) from the hyperthermophilic Crenarchaeon, Sulfolobus solfataricus (Sso). We have established through mutagenesis that despite incomplete sequence conservation, the polymerase and exonuclease active sites are functionally conserved in Dpo3. Using pre-steady-state kinetics, we can measure the fidelity of nucleotide incorporation by Dpo3 from the polymerase active site alone to be 10(3)-10(4) at 37 °C. The functional exonuclease proofreading active site will increase fidelity by at least 10(2), making Dpo3 comparable to other DNA polymerases in this family. Additionally, Dpo3's exonuclease activity is modulated by temperature, where a loss of promiscuous degradation activity can be attributed to a reorganization of the exonuclease domain when it is bound to primer-template DNA at high temperatures. Unexpectedly, the DNA binding affinity is weak compared with those of other DNA polymerases of this family. A comparison of the fidelity, polymerization kinetics, and associated functional exonuclease domain with those previously reported for other Sso polymerases (Dpo1 and Dpo4) illustrates that Dpo3 is a potential player in the proper maintenance of the archaeal genome.

Antimutator variants of DNA polymerases

Evolution balances DNA replication speed and accuracy to optimize replicative fitness and genetic stability. There is no selective pressure to improve DNA replication fidelity beyond the background mutation rate from other sources, such as DNA damage. However, DNA polymerases remain amenable to amino acid substitutions that lower intrinsic error rates. Here, we review these 'antimutagenic' changes in DNA polymerases and discuss what they reveal about mechanisms of replication fidelity. Pioneering studies with bacteriophage T4 DNA polymerase (T4 Pol) established the paradigm that antimutator amino acid substitutions reduce replication errors by increasing proofreading efficiency at the expense of polymerase processivity. The discoveries of antimutator substitutions in proofreading-deficient 'mutator' derivatives of bacterial Pols I and III and yeast Pol δ suggest there must be additional antimutagenic mechanisms. Remarkably, many of the affected amino acid positions from Pol I, Pol III, and Pol δ are similar to the original T4 Pol substitutions. The locations of antimutator substitutions within DNA polymerase structures suggest that they may increase nucleotide selectivity and/or promote dissociation of primer termini from polymerases poised for misincorporation, leading to expulsion of incorrect nucleotides. If misincorporation occurs, enhanced primer dissociation from polymerase domains may improve proofreading in cis by an intrinsic exonuclease or in trans by alternate cellular proofreading activities. Together, these studies reveal that natural selection can readily restore replication error rates to sustainable levels following an adaptive mutator phenotype.

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.

Herpes simplex virus type 1 helicase-primase: DNA binding and consequent protein oligomerization and primase activation

The heterotrimeric helicase-primase complex of herpes simplex virus type I (HSV-1), consisting of UL5, UL8, and UL52, possesses 5' to 3' helicase, single-stranded DNA (ssDNA)-dependent ATPase, primase, and DNA binding activities. In this study we confirm that the UL5-UL8-UL52 complex has higher affinity for forked DNA than for ssDNA and fails to bind to fully annealed double-stranded DNA substrates. In addition, we show that a single-stranded overhang of greater than 6 nucleotides is required for efficient enzyme loading and unwinding. Electrophoretic mobility shift assays and surface plasmon resonance analysis provide additional quantitative information about how the UL5-UL8-UL52 complex associates with the replication fork. Although it has previously been reported that in the absence of DNA and nucleoside triphosphates the UL5-UL8-UL52 complex exists as a monomer in solution, we now present evidence that in the presence of forked DNA and AMP-PNP, higher-order complexes can form. Electrophoretic mobility shift assays reveal two discrete complexes with different mobilities only when helicase-primase is bound to DNA containing a single-stranded region, and surface plasmon resonance analysis confirms larger amounts of the complex bound to forked substrates than to single-overhang substrates. Furthermore, we show that primase activity exhibits a cooperative dependence on protein concentration while ATPase and helicase activities do not. Taken together, these data suggest that the primase activity of the helicase-primase requires formation of a dimer or higher-order structure while ATPase activity does not. Importantly, this provides a simple mechanism for generating a two-polymerase replisome at the replication fork.

Substitution of Ala for Tyr567 in RB69 DNA polymerase allows dAMP and dGMP to be inserted opposite Guanidinohydantoin

Continuous oxidative damage inflicted on DNA produces 7,8-dihydro-8-oxoguanine (8-oxoG), a commonly occurring lesion that can potentially cause cancer by producing G → T transversions during DNA replication. Mild oxidation of 8-oxoG leads to the formation of hydantoins, specifically guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp), which are 100% mutagenic because they encode almost exclusively the insertion of dAMP and dGMP (encoding G → T and G → C transversions, respectively). The wild-type (wt) pol α family DNA polymerase from bacteriophage RB69 (RB69pol) inserts dAMP and dGMP with low efficiency when situated opposite Gh. In contrast, the RB69pol Y567A mutant inserts both of these dNMPs opposite Gh with >100-fold higher efficiency than wt. We now report the crystal structure of the "closed" preinsertion complex for the Y567A mutant with dATP opposite a templating Gh (R-configuration) in a 13/18mer primer-template (P/T) at 2.0 Å resolution. The structure data reveal that the Y to A substitution provides the nascent base pair binding pocket (NBP) with the flexibility to accommodate Gh by allowing G568 to move in the major-to-minor groove direction of the P/T. Thus, Gh is rejected as a templating base by wt RB69pol because G568 is inflexible, preventing Gh from pairing with the incoming dATP or dGTP base.

Replication through an abasic DNA lesion: structural basis for adenine selectivity

Abasic sites represent the most frequent DNA lesions in the genome that have high mutagenic potential and lead to mutations commonly found in human cancers. Although these lesions are devoid of the genetic information, adenine is most efficiently inserted when abasic sites are bypassed by DNA polymerases, a phenomenon termed A-rule. In this study, we present X-ray structures of a DNA polymerase caught while incorporating a nucleotide opposite an abasic site. We found that a functionally important tyrosine side chain directs for nucleotide incorporation rather than DNA. It fills the vacant space of the absent template nucleobase and thereby mimics a pyrimidine nucleobase directing for preferential purine incorporation opposite abasic residues because of enhanced geometric fit to the active site. This amino acid templating mechanism was corroborated by switching to pyrimidine specificity because of mutation of the templating tyrosine into tryptophan. The tyrosine is located in motif B and highly conserved throughout evolution from bacteria to humans indicating a general amino acid templating mechanism for bypass of non-instructive lesions by DNA polymerases at least from this sequence family.

Mechanisms by which human DNA primase chooses to polymerize a nucleoside triphosphate

Human DNA primase synthesizes short RNA primers that DNA polymerase alpha then elongates during the initiation of all new DNA strands. Even though primase misincorporates NTPs at a relatively high frequency, this likely does not impact the final DNA product since the RNA primer is replaced with DNA. We used an extensive series of purine and pyrimidine analogues to provide further insights into the mechanism by which primase chooses whether or not to polymerize a NTP. Primase readily polymerized a size-expanded cytosine analogue, 1,3-diaza-2-oxophenothiazine NTP, across from a templating G but not across from A. The enzyme did not efficiently polymerize NTPs incapable of forming two Watson-Crick hydrogen bonds with the templating base with the exception of UTP opposite purine deoxyribonucleoside. Likewise, primase did not generate base pairs between two nucleotides with altered Watson-Crick hydrogen-bonding patterns. Examining the mechanism of NTP polymerization revealed that human primase can misincorporate NTPs via both template misreading and a primer-template slippage mechanism. Together, these data demonstrate that human primase strongly depends on Watson-Crick hydrogen bonds for efficient nucleotide polymerization, much more so than the mechanistically related herpes primase, and provide insights into the potential roles of primer-template stability and base tautomerization during misincorporation.

Nucleotide Analogues as Probes for DNA and RNA Polymerases

Nucleotide analogues represent a major class of anti-cancer and anti-viral drugs, and provide an extremely powerful tool for dissecting the mechanisms of DNA and RNA polymerases. While the basic assays themselves are relatively straight-forward, a key issue is to appropriately design the studies to answer the mechanistic question of interest. This article addresses the major issues involved in designing these studies, and some of the potential difficulties that arise in interpreting the data. Examples are given both of the type of analogues typically used, the experimental approaches with different polymerases, and issues with data interpretation.

Herpes simplex virus-1 DNA primase: a remarkably inaccurate yet selective polymerase

Herpes simplex virus-1 primase misincorporates the natural NTPs at frequencies of around one error per 30 NTPs polymerized, making it one of the least accurate polymerases known. We used a series of nucleotide analogues to further test the hypothesis that primase requires Watson-Crick hydrogen bond formation to efficiently polymerize a NTP. Primase could not generate base pairs containing a complete set of hydrogen bonds in an altered arrangement (isoguanine.isocytosine) and did not efficiently polymerize dNTPs completely incapable of forming Watson-Crick hydrogen bonds opposite templating bases incapable of forming Watson-Crick hydrogen bonds. Similarly, primase did not incorporate most NTPs containing hydrophobic bases incapable of Watson-Crick hydrogen bonding opposite natural template bases. However, 2-pyridone NTP and 4-methyl-2-pyridone NTP provided striking exceptions to this rule. The effects of removing single Watson-Crick hydrogen bonding groups from either the NTP or templating bases varied from almost no effect to completely blocking polymerization depending both on the parental base pair (G.C vs A.T/U) and which base pair of the growing primer (second, third, or fourth) was examined. Thus, primase does not absolutely need to form Watson-Crick hydrogen bonds to efficiently polymerize a NTP. Additionally, we found that herpes primase can misincorporate nucleotides both by misreading the template and by a primer-template slippage mechanism. The mechanistic and biological implications of these results are discussed.

Ambivalent incorporation of the fluorescent cytosine analogues tC and tCo by human DNA polymerase alpha and Klenow fragment

We studied the incorporation of the fluorescent cytidine analogues 1,3-diaza-2-oxophenothiazine (tC) and 1,3-diaza-2-oxophenoxazine (tCo) by human DNA polymerase alpha and Klenow fragment of DNA polymerase I (Escherichia coli). These tricyclic nucleobases possess the regular hydrogen bonding interface of cytosine but are significantly expanded in size toward the major groove. Despite the size alteration, both DNA polymerases insert dtCTP and dtCoTP with remarkable catalytic efficiency. Polymerization opposite guanine is comparable to the insertion of dCTP, while the insertion opposite adenine is only approximately 4-11 times less efficient than the formation of a T-A base pair. Both enzymes readily extend the formed tC(o)-G and tC(o)-A base pairs and can incorporate at least four consecutive nucleotide analogues. Consistent with these results, both DNA polymerases efficiently polymerize dGTP and dATP when tC and tCo are in the template strand. Klenow fragment inserts dGTP with a 4-9-fold higher probability than dATP, while polymerase alpha favors dGTP over dATP by a factor of 30-65. Overall, the properties of tC(o) as a templating base and as an incoming nucleotide are surprisingly symmetrical and may be universal for A and B family DNA polymerases. This finding suggests that the aptitude for ambivalent base pairing is a consequence of the electronic properties of tC(o).

Interaction of human DNA polymerase alpha and DNA polymerase I from Bacillus stearothermophilus with hypoxanthine and 8-oxoguanine nucleotides

To better understand how DNA polymerases interact with mutagenic bases, we examined how human DNA polymerase alpha (pol alpha), a B family enzyme, and DNA polymerase from Bacillus stearothermophilus (BF), an A family enzyme, generate adenine:hypoxanthine and adenine:8-oxo-7,8-dihydroguanine (8-oxoG) base pairs. Pol alpha strongly discriminated against polymerizing dATP opposite 8-oxoG, and removing N1, N(6), or N7 further inhibited incorporation, whereas removing N3 from dATP dramatically increased incorporation (32-fold). Eliminating N(6) from 3-deaza-dATP now greatly reduced incorporation, suggesting that incorporation of dATP (analogues) opposite 8-oxoguanine proceeds via a Hoogsteen base pair and that pol alpha uses N3 of a purine dNTP to block this incorporation. Pol alpha also polymerized 8-oxo-dGTP across from a templating A, and removing N(6) from the template adenine inhibited incorporation of 8-oxoG. The effects of N1, N(6), and N7 demonstrated a strong interdependence during formation of adenine:hypoxanthine base pairs by pol alpha, and N3 of dATP again helps prevent polymerization opposite a templating hypoxanthine. BF very efficiently polymerized 8-oxo-dGTP opposite adenine, and N1 and N7 of adenine appear to play important roles. BF incorporates dATP opposite 8-oxoG less efficiently, and modifying N1, N(6), or N7 greatly inhibits incorporation. N(6) and, to a lesser extent, N1 help drive hypoxanthine:adenine base-pair formation by BF. The mechanistic implications of these results showing that different polymerases interact very differently with base lesions are discussed.

Non-natural nucleotides as probes for the mechanism and fidelity of DNA polymerases

DNA is a remarkable macromolecule that functions primarily as the carrier of the genetic information of organisms ranging from viruses to bacteria to eukaryotes. The ability of DNA polymerases to efficiently and accurately replicate genetic material represents one of the most fundamental yet complex biological processes found in nature. The central dogma of DNA polymerization is that the efficiency and fidelity of this biological process is dependent upon proper hydrogen-bonding interactions between an incoming nucleotide and its templating partner. However, the foundation of this dogma has been recently challenged by the demonstration that DNA polymerases can effectively and, in some cases, selectively incorporate non-natural nucleotides lacking classic hydrogen-bonding capabilities into DNA. In this review, we describe the results of several laboratories that have employed a variety of non-natural nucleotide analogs to decipher the molecular mechanism of DNA polymerization. The use of various non-natural nucleotides has lead to the development of several different models that can explain how efficient DNA synthesis can occur in the absence of hydrogen-bonding interactions. These models include the influence of steric fit and shape complementarity, hydrophobicity and solvation energies, base-stacking capabilities, and negative selection as alternatives to rules invoking simple recognition of hydrogen-bonding patterns. Discussions are also provided regarding how the kinetics of primer extension and exonuclease proofreading activities associated with high-fidelity DNA polymerases are influenced by the absence of hydrogen-bonding functional groups exhibited by non-natural nucleotides.

Discrimination between right and wrong purine dNTPs by DNA polymerase I from Bacillus stearothermophilus

We used a series of dATP and dGTP analogues to determine how DNA polymerase I from Bacillus stearothermophilus (BF), a prototypical A family polymerase, uses N-1, N(2), N-3, and N(6) of purine dNTPs to differentiate between right and wrong nucleotide incorporation. Altering any of these nitrogens had two effects. First, it decreased the efficiency of correct incorporation of the resulting dNTP analogue, with the loss of N-1 and N-3 having the most severe effects. Second, it dramatically increased the rate of misincorporation of the resulting dNTP analogues, with alterations in either N-1 or N(6) having the most severe impacts. Adding N(2) to dNTPs containing the bases adenine and purine increased the degree of polymerization opposite T but also tremendously increased the degree of misincorporation opposite A, C, and G. Thus, BF uses N-1, N(2), N-3, and N(6) of purine dNTPs both as negative selectors to prevent misincorporation and as positive selectors to enhance correct incorporation. Comparing how BF discriminates between right and wrong dNTPs with both B family polymerases and low-fidelity polymerases indicates that BF has chosen a unique solution vis-a-vis these other enzymes and, therefore, that nature has evolved at least three mechanistically distinct solutions.

Techniques used to study the DNA polymerase reaction pathway

A minimal reaction pathway for DNA polymerases was established over 20years ago using chemical-quench methods. Since that time there has been considerable interest in noncovalent steps in the reaction pathway, conformational changes involving the polymerase or its DNA substrate that may play a role in substrate specificity. Fluorescence-based assays have been devised in order to study these conformational transitions and the results obtained have added new detail to the reaction pathway.

RB69 DNA polymerase mutants with expanded nascent base-pair-binding pockets are highly efficient but have reduced base selectivity

We have investigated the effect of systematically enlarging the nascent base-pair-binding pocket (NBP) of a replicative DNA polymerase from bacteriophage RB69 (RB69 pol) on the incorporation efficiency (k(pol)/K(d,app)) for both correct and incorrect dNMPs. Accordingly, we replaced residues L561, Y567, and S565 in the NBP with Ala, Ala, and Gly, respectively. We combined L561A and Y567A to give a double mutant and then introduced the S565G mutation to give a triple mutant. The efficiency of incorrect dNMP insertion increased markedly relative to the wild type with the single mutants and increased further as the number of substitutions in the NBP increased. The difference in incorporation efficiency for mispairs between the mutants and the wild-type RB69 pol was due mainly to k(pol). Unexpectedly, enlarging the NBP had a minimal effect on the incorporation efficiency of correct dNMPs. Our kinetic data suggest that replicative DNA pols exert base discrimination via "negative selection" against mispairs by using residues in the NBP, particularly the three residues analyzed in this study, to allow rapid incorporation of only correct base pairs. This proposal differs from how geometry and "tightness of fit" of the NBP is often invoked to account for rapid incorporation of correct base pairs, namely, that a tighter fit within the NBP leads to an increase in insertion rates [Kool, E. T. (2002) Annu. Rev. Biochem. 71, 191-219]. We related our findings to that of a model translesion DNA pol, Sulfolobus solfataricus Dpo4. We concur with the main conclusion of a previous study [Mizukami, S., et al. (2006) Biochemistry 45, 2772-2778], namely, that lesion bypass pols exhibit low incorporation efficiencies for correct dNMPs (leading to relative promiscuity) not because of a more open NBP but because of a loose fit of substrates bound in the catalytic centers. This is a property not shared by RB69 pol and its mutants.

Kinetic analysis of base-pairing preference for nucleotide incorporation opposite template pyrimidines by human DNA polymerase iota

DNA polymerase (pol) iota, a member of the mammalian Y-family of DNA polymerases involved in translesion DNA synthesis, has been previously suggested to peculiarly utilize Hoogsteen base pairing for DNA synthesis opposite template purines, unlike pols eta and kappa, which utilize Watson-Crick (W-C) base pairing. To investigate the possible roles of Hoogsteen, W-C, and wobble base-pairing modes in the selection of nucleotides opposite template pyrimidines by human pol iota, we carried out kinetic analyses of incorporation of modified purine nucleoside triphosphates including 7-deazapurines, inosine, 2-aminopurine, 2,6-diaminopurine, and 6-chloropurine, which affect H-bonding in base-pair formation opposite template pyrimidines. Carbon substitution at the N7 atom of purine nucleoside triphosphates, which disrupts Hoogsteen base pairing, only slightly inhibited DNA synthesis opposite template pyrimidines by pol iota, which was not substantially different from human pols eta and kappa. Opposite template T, only the relative wobble stabilities (inferred from the potential numbers of H-bonding, steric, and electrostatic interactions but not measured) of base pairs were positively correlated to the relative efficiencies of nucleotide incorporation by pol iota but not the relative W-C or Hoogsteen stabilities, unlike pols eta and kappa. In contrast, opposite C, only the relative W-C stabilities of base pairs were positively correlated to the relative efficiencies of nucleotide incorporation by pol iota, as with pols eta and kappa. These results suggest that pol iota might not indispensably require Hoogsteen base pairing for DNA synthesis opposite pyrimidines but rather might prefer wobble base pairing in the selection of nucleotides opposite T and W-C base pairing opposite C.

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.

Highly efficient incorporation of the fluorescent nucleotide analogs tC and tCO by Klenow fragment

Studies of the mechanisms by which DNA polymerases select the correct nucleotide frequently employ fluorescently labeled DNA to monitor conformational rearrangements of the polymerase-DNA complex in response to incoming nucleotides. For this purpose, fluorescent base analogs play an increasingly important role because they interfere less with the DNA-protein interaction than do tethered fluorophores. Here we report the incorporation of the 5'-triphosphates of two exceptionally bright cytosine analogs, 1,3-diaza-2-oxo-phenothiazine (tC) and its oxo-homolog, 1,3-diaza-2-oxo-phenoxazine (tC(O)), into DNA by the Klenow fragment. Both nucleotide analogs are polymerized with slightly higher efficiency opposite guanine than cytosine triphosphate and are shown to bind with nanomolar affinity to the DNA polymerase active site, according to fluorescence anisotropy measurements. Using this method, we perform competitive binding experiments and show that they can be used to determine the dissociation constant of any given natural or unnatural nucleotide. The results demonstrate that the active site of the Klenow fragment is flexible enough to tolerate base pairs that are size-expanded in the major groove. In addition, the possibility to enzymatically polymerize a fluorescent nucleotide with high efficiency complements the tool box of biophysical probes available to study DNA replication.

13C and 15N NMR spectra of aminobenzimidazoles in solution and in the solid state

The (13)C [hexadeutero-dimethylsulfoxide (DMSO-d(6)), hexamethyl-phosphoramide (HMPA)-d(18)and solid-state] and (15)N (solid-state) NMR spectra of six C-aminobenzimidazoles have been recorded. The tautomerism of 4(7)-aminobenzimidazoles and 5(6)-aminobenzimidazoles has been determined and compared with B3LYP/6-311 + + G(d,p) calculations confirming the clear predominance of the 4-amino tautomer and the slight preference for the 6-amino tautomer. GIAO-calculated absolute shieldings compare well with experimental chemical shifts.

Role of the 2-amino group of purines during dNTP polymerization by human DNA polymerase alpha

We used a series of dNTP analogues in conjunction with templates containing modified bases to elucidate the role that N(2) of a purine plays during dNTP polymerization by human DNA polymerase alpha. Removing N(2) from dGTP had small effects during correct incorporation opposite C but specifically increased misincorporation opposite A. Adding N(2) to dATP and related analogues had small and variable effects on the efficiency of polymerization opposite T. However, the presence of N(2) greatly enhanced polymerization of these dATP analogues opposite a template C. The ability of N(2) to enhance polymerization opposite C likely results from formation of a hydrogen bond between the purine N(2) and pyrimidine O(2). Even in those cases where formation of a wobble base pair, tautomerization, and/or protonation of the base pair between the incoming dNTP and template base cannot occur (e.g., 2-pyridone.purine (or purine analogue) base pairs), N(2) enhanced formation of the base pair. Importantly, N(2) had similar effects on dNTP polymerization both when added to the incoming purine dNTP and when added to the template base being replicated. The mechanistic implications of these results regarding how pol alpha discriminates between right and wrong dNTPs are discussed.

Interaction of herpes primase with the sugar of a NTP

We analyzed the interaction of nucleoside triphosphates (NTPs) containing modified sugars to develop a better understanding of how DNA primase from herpes simplex virus I catalyzes primer synthesis. During the NTP binding reaction, primase tolerated a large number of modifications to the sugar ring. Altering the 2' and 3' carbons and even converting the furanose sugar into an acyclic sugar did not prevent binding. Whether or not the base on the NTP could form a correct base pair with the template base being replicated also had minimal effect on the binding reaction, indicating that primase does not use this process to discriminate between right and wrong NTPs. Rather, the key feature that primase recognizes to bind a NTP is the 5'-gamma-phosphate since converting a NTP into a NDP greatly compromised binding. During the polymerization reaction, primase tolerated substantial modification of the 2'-carbon, including the presence of either an ara or ribo hydroxyl, two hydrogens, or two fluorines. However, polymerization absolutely required that the NTP contain a 3'-hydroxyl and an intact sugar ring. Modifications at the 2'-carbon of the nucleotide at the primer 3'-terminus significantly impaired further polymerization events. Compared to a ribonucleotide, incorporation of a 2'-deoxyribo- or 2',2'-difluoro-2'-deoxyribonucleotide resulted in strong chain termination, while incorporation of an aranucleotide resulted in very strong chain termination. The implications of these data with respect to the mechanism of primase and the relationship between human and herpes primase are discussed.

Effect of β-L-D4A on human DNA polymerases β and δ and its mechanism

AIM: To purify and characterize the DNA polymerase δ and investigate the side effects of β-L-D4A (a novel nucleoside analog) on human DNA polymerases β and δ.

METHODS: Human DNA polymerase δ was separated from crude extract of human Hela cells by ion exchange chromatography. Detailed kinetic parameters were determined for β-L-D4A against DNA polymerases β and δ.

RESULTS: Human DNA polymerase δ was purified and characterized with a yield of 15% and a specific activity of 1911 Ukat/mg. When β-L-D4A was used as an inhibitor, the kinetic parameters of human DNA polymerases β and δ were Km = 1.86 μmol/L and 2.45 μmol/L, IC₅₀ = 25.21 μmol/L and 150.1 μmol/L, Ki = 24.03 μmol/L and 132.7 μmol/L, respectively, suggesting that the inhibitory effect of β-L-D4A on human DNA polymerases β and δ was less than that of lamivudine.

CONCLUSION: β-L-D4A is a competitive inhibitor of DNA polymerases β and δ. Its toxic side effects on DNA polymerases β and δ are less than lamivudine. It can be expected to become a high efficient and low toxic anti-HBV agent.

Effect and mechanism of β-L-D4A on DNA polymerase α

AIM: To investigate the safety of β-L-D4A on DNA polymerase α.

METHODS: Ion exchange chromatography was used to separate DNA polymerase α from crude extract of human Hela cells. Detailed kinetic parameters were determined for β-L-D4A against DNA polymerase α.

RESULTS: DNA polymerase α was purified with 4% yield and 31 000 units/mg specific activity. The Michaelis constant (Km = 3.22 μmol/L), 50% inhibition concentration (IC50 = 178.49 μmol/L) and inhibition constant (Ki = 126 μmol/L) of β-L-D4A were determined by kinetic analysis.

CONCLUSION: β-L-D4A is a more safe nucleoside for hepatitis B virus (HBV) infection with a lower host toxicity.

Model systems for understanding DNA base pairing

The fact that nucleic acid bases recognize each other to form pairs is a canonical part of the dogma of biology. However, they do not recognize each other well enough in water to account for the selectivity and efficiency that is needed in the transmission of biological information through a cell. Thus proteins assist in this recognition in multiple ways, and recent data suggest that these mechanisms of recognition can vary widely with context. To probe how the chemical differences of the four nucleobases are defined in various biological contexts, chemists and biochemists have developed modified versions that differ in their polarity, shape, size, and functional groups. This brief review covers recent advances in this field of research.

Modular and Practical Synthesis of 6-Substituted Pyridin-3-yl C-Nucleosides

A novel modular and practical methodology for preparation of 6-substituted pyridin-3-yl C-nucleosides was developed. The Heck reaction of 2-chloro-5-iodopyridine with a 3'-TBDMS-protected glycal gave a 6-chloropyridin-3-yl nucleoside analogue, which was then desilylated, selectively reduced, and reprotected to give the TBDMS-protected 6-chloropyridin-3-yl C-2'-deoxyribonucleoside as a pure beta-anomer in a total yield of 39% over four steps. This key intermediate was then subjected to a series of palladium-catalyzed cross-coupling reactions, aminations, and alkoxylations to give a series of protected 1beta-(6-alkyl-, 6-aryl-, 6-hetaryl, 6-amino-, and 6-tert-butoxypyridin-3-yl)-2'-deoxyribonucleosides. 6-Unsubstituted pyridin-3-yl C-nucleoside was prepared by catalytic hydrogenation of the chloro derivative and 6-oxopyridine C-nucleoside by treatment of the 6-tert-butoxy derivative with TFA. Deprotection of all the silylated nucleosides by Et3N.3HF gave a series of free C-nucleosides (10 examples).