Evidence for Watson-Crick and not Hoogsteen or wobble base pairing in the selection of nucleotides for insertion opposite pyrimidines and a thymine dimer by yeast DNA pol eta

We have recently reported that pyrene nucleotide is preferentially inserted opposite an abasic site, the 3'-T of a thymine dimer, and most undamaged bases by yeast DNA polymerase eta (pol eta). Because pyrene is a nonpolar molecule with no H-bonding ability, the unusually high efficiencies of dPMP insertion are ascribed to its superior base stacking ability, and underscore the importance of base stacking in the selection of nucleotides by pol eta. To investigate the role of H-bonding and base pair geometry in the selection of nucleotides by pol eta, we determined the insertion efficiencies of the base-modified nucleotides 2,6-diaminopurine, 2-aminopurine, 6-chloropurine, and inosine which would make a different number of H-bonds with the template base depending on base pair geometry. Watson-Crick base pairing appears to play an important role in the selection of nucleotide analogues for insertion opposite C and T as evidenced by the decrease in the relative insertion efficiencies with a decrease in the number of Watson-Crick H-bonds and an increase in the number of donor-donor and acceptor-acceptor interactions. The selectivity of nucleotide insertion is greater opposite the 5'-T than the 3'-T of the thymine dimer, in accord with previous work suggesting that the 5'-T is held more rigidly than the 3'-T. Furthermore, insertion of A opposite both Ts of the dimer appears to be mediated by Watson-Crick base pairing and not by Hoogsteen base pairing based on the almost identical insertion efficiencies of A and 7-deaza-A, the latter of which lacks H-bonding capability at N7. The relative efficiencies for insertion of nucleotides that can form Watson-Crick base pairs parallel those for the Klenow fragment, whereas the Klenow fragment more strongly discriminates against mismatches, in accord with its greater shape selectivity. These results underscore the importance of H-bonding and Watson-Crick base pair geometry in the selection of nucleotides by both pol eta and the Klenow fragment, and the lesser role of shape selection in insertion by pol eta due to its more open and less constrained active site.     

Steric and electrostatic effects in DNA synthesis by the SOS-induced DNA polymerases II and IV of Escherichia coli

The SOS-induced DNA polymerases II and IV (pol II and pol IV, respectively) of Escherichia coli play important roles in processing lesions that occur in genomic DNA. Here we study how electrostatic and steric effects play different roles in influencing the efficiency and fidelity of DNA synthesis by these two enzymes. These effects were probed by the use of nonpolar shape analogues of thymidine, in which substituted toluenes replace the polar thymine base. We compared thymine with nonpolar analogues to evaluate the importance of hydrogen bonding in the polymerase active sites, while we used comparisons among a set of variably sized thymine analogues to measure the role of steric effects in the two enzymes. Steady-state kinetics measurements were carried out to evaluate activities for nucleotide insertion and extension. The results showed that both enzymes inserted nucleotides opposite nonpolar template bases with moderate to low efficiency, suggesting that both polymerases benefit from hydrogen bonding or other electrostatic effects involving the template base. Surprisingly, however, pol II inserted nonpolar nucleotide (dNTP) analogues into a primer strand with high (wild-type) efficiency, while pol IV handled them with an extremely low efficiency. Base pair extension studies showed that both enzymes bypass non-hydrogen-bonding template bases with moderately low efficiency, suggesting a possible beneficial role of minor groove hydrogen bonding interactions at the N-1 position. Measurement of the two polymerases' sensitivity to steric size changes showed that both enzymes were relatively flexible, yielding only small kinetic differences with increases or decreases in nucleotide size. Comparisons are made to recent data for DNA pol I (Klenow fragment), the archaeal polymerase Dpo4, and human pol kappa.     

Significance of nucleobase shape complementarity and hydrogen bonding in the formation and stability of the closed polymerase-DNA complex

DNA polymerases insert a dNTP by a multistep mechanism that involves a conformational rearrangement from an open to a closed ternary complex, a process that positions the incoming dNTP in the proper orientation for phosphodiester bond formation. In this work, the importance and relative contribution of hydrogen-bonding interactions and the geometric shape of the base pair that forms during this process were studied using Escherichia coli DNA polymerase I (Klenow fragment, 3'-exonuclease deficient) and natural dNTPs or non-hydrogen-bonding dNTP analogues. Both the geometric fit of the incoming nucleotide and its ability to form Watson-Crick hydrogen bonds with the template were found to contribute to the stability of the closed ternary complex. Although the formation of a closed complex in the presence of a non-hydrogen-bonding nucleotide analogue could be detected by limited proteolysis analysis, a comparison of the stabilities of the ternary complexes indicated that hydrogen-bonding interactions between the incoming dNTP and the template increase the stability of the complex by 6-20-fold. Any deviation from the Watson-Crick base pair geometry was shown to have a destabilizing effect on the closed complex. This degree of destabilization varied from 3- to 730-fold and was found to be correlated with the size of the mismatched base pair. Finally, a stable closed complex is not formed in the presence of a ddNTP or rNTP. These results are discussed in relation to the steric exclusion model for the nucleotide insertion.     

Structural basis for differential insertion kinetics of dNMPs opposite a difluorotoluene nucleotide residue

We have recently challenged the widely held view that 2,4-difluorotoluene (dF) is a nonpolar isosteric analogue of the nucleotide dT, incapable of forming hydrogen bonds (HBs). To gain a further understanding for the kinetic preference that favors dAMP insertion opposite a templating dF, a result that mirrors the base selectivity that favors dAMP insertion opposite dT by RB69 DNA polymerase (RB69pol), we determined presteady-state kinetic parameters for incorporation of four dNMPs opposite dF by RB69pol and solved the structures of corresponding ternary complexes. We observed that both the F2 and F4 substituent of dF in these structures serve as HB acceptors forming HBs either directly with dTTP and dGTP or indirectly with dATP and dCTP via ordered water molecules. We have defined the shape and chemical features of each dF/dNTP pair in the RB69pol active site without the corresponding phosphodiester-linkage constraints of dF/dNs when they are embedded in isolated DNA duplexes. These features can explain the kinetic preferences exhibited by the templating dF when the nucleotide incorporation is catalyzed by wild type RB69pol or its mutants. We further show that the shapes of the dNTP/dF nascent base pair differ markedly from the corresponding dNTP/dT in the pol active site and that these differences have a profound effect on their incorporation efficiencies.     

Base pair hydrogen bonds are essential for proofreading selectivity by the human mitochondrial DNA polymerase

We have characterized the role of Watson-Crick hydrogen bonding in the 3'-terminal base pair on the 3'-5' exonuclease activity of the human mitochondrial DNA polymerase. Nonpolar nucleoside analogs of thymidine (dF) and deoxyadenosine (dQ) were used to eliminate hydrogen bonds while maintaining base pair size and shape. Exonuclease reactions were examined using pre-steady state kinetic methods. The time dependence of removal of natural nucleotides from the primer terminus paired opposite the nonpolar analogs dF and dQ were best fit to a double exponential function. The double exponential kinetics as well as the rates of excision (3-6 s(-1) fast phase, 0.16-0.3 s(-1) slow phase) are comparable with those observed during mismatch removal of natural nucleotides even when the analog was involved in a sterically correct base pair. Additionally, incorporation of the next correct base beyond a nonpolar analog was slow (0.04-0.22 s(-1)), so that more than 95% of terminal base pairs were removed rather than extended. The polymerase responds to all 3'-terminal base pairs containing a nonpolar analog as if it were a mismatch regardless of the identity of the paired base, and kinetic partitioning between polymerase and exonuclease sites failed to discriminate between correct and incorrect base pairs. Thus, sterics alone are insufficient, whereas hydrogen bond formation is essential for proper proofreading selectivity by the mitochondrial polymerase. The enzyme may use the alignment and prevention of fraying provided by proper hydrogen bonding and minor groove hydrogen bonding interactions as critical criteria for correct base pair recognition.     

Exploration of factors driving incorporation of unnatural dNTPS into DNA by Klenow fragment (DNA polymerase I) and DNA polymerase alpha

In order to further understand how DNA polymerases discriminate against incorrect dNTPs, we synthesized two sets of dNTP analogues and tested them as substrates for DNA polymerase α (pol α) and Klenow fragment (exo⁻) of DNA polymerase I (Escherichia coli). One set of analogues was designed to test the importance of the electronic nature of the base. The bases consisted of a benzimidazole ring with one or two exocyclic substituent(s) that are either electron-donating (methyl and methoxy) or electron-withdrawing (trifluoromethyl and dinitro). Both pol α and Klenow fragment exhibit a remarkable inability to discriminate against these analogues as compared to their ability to discriminate against incorrect natural dNTPs. Neither polymerase shows any distinct electronic or steric preferences for analogue incorporation. The other set of analogues, designed to examine the importance of hydrophobicity in dNTP incorporation, consists of a set of four regioisomers of trifluoromethyl benzimidazole. Whereas pol α and Klenow fragment exhibited minimal discrimination against the 5- and 6-regioisomers, they discriminated much more effectively against the 4- and 7-regioisomers. Since all four of these analogues will have similar hydrophobicity and stacking ability, these data indicate that hydrophobicity and stacking ability alone cannot account for the inability of pol α and Klenow fragment to discriminate against unnatural bases. After incorporation, however, both sets of analogues were not efficiently elongated. These results suggest that factors other than hydrophobicity, sterics and electronics govern the incorporation of dNTPs into DNA by pol α and Klenow fragment.     

Crystal structures of a ddATP-, ddTTP-, ddCTP, and ddGTP- trapped ternary complex of Klentaq1: insights into nucleotide incorporation and selectivity

The mechanism by which DNA polymerase I enzymes function has been the subject of extensive biochemical and structural studies. We previously determined the structure of a ternary complex of the large fragment of DNA polymerase I from Thermus aquaticus (Klentaq1) bound to a primer/template DNA and a dideoxycytidine 5'-triphosphate (ddCTP). In this report, we present the details of the 2.3-A resolution crystal structures of three additional ternary complexes of Klentaq1 bound to a primer/template DNA and a dideoxyguanosine 5'-triphosphate (ddGTP), a dideoxythymidine 5'-triphosphate (ddTTP), or a dideoxyadenosine 5'-triphosphate (ddATP). Comparison of the active site of the four ternary complexes reveals that the protein residues around the nascent base pair (that formed between the incoming dideoxynucleoside triphosphate [ddNTP] and the template base) form a snug binding pocket into which only a correct Watson-Crick base pair can fit. Except in the ternary complex bound to dideoxyguanosine 5'-triphosphate, there are no sequence specific contacts between the protein side chains and the nascent base pair, suggesting that steric constraints imposed by the protein onto the nascent base pair is the major contributor to nucleotide selectivity at the polymerase active site. The protein around the polymerase active site also shows plasticity, which may be responsible for the substrate diversity of the enzyme. Two conserved side chains, Q754 and R573, form hydrogen bonds with the N3 atom in the purine base and O2 atom in the pyrimidine base at the minor groove side of the base pair formed by the incorporated ddNMP and the corresponding template base in all the four ternary complexes. These hydrogen-bonding interactions may provide a means of detecting misincorporation at this position.     

Requirement of Watson-Crick hydrogen bonding for DNA synthesis by yeast DNA polymerase eta

Classical high-fidelity DNA polymerases discriminate between the correct and incorrect nucleotides by using geometric constraints imposed by the tight fit of the active site with the incipient base pair. Consequently, Watson-Crick (W-C) hydrogen bonding between the bases is not required for the efficiency and accuracy of DNA synthesis by these polymerases. DNA polymerase eta (Poleta) is a low-fidelity enzyme able to replicate through DNA lesions. Using difluorotoluene, a nonpolar isosteric analog of thymine unable to form W-C hydrogen bonds with adenine, we found that the efficiency and accuracy of nucleotide incorporation by Poleta are severely impaired. From these observations, we suggest that W-C hydrogen bonding is required for DNA synthesis by Poleta; in this regard, Poleta differs strikingly from classical high-fidelity DNA polymerases.     

Replication of non-hydrogen bonded bases by DNA polymerases: A mechanism for steric matching

Recent experiments have presented evidence that Watson–Crick hydrogen bonds in a base pair are not absolute requirements for efficient synthesis of that pair by DNA polymerase enzymes. Here we examine quantitative steady-state kinetic data from several published studies involving poorly hydrogen-bonding DNA base analogues and adducts, and analyze the results in terms of solvation, hydrogen bonding, and steric effects. We propose a mechanism that can explain the surprising lack of hydrogen-bonding requirement accompanied by significant selectivity in pairing. This hypothesis makes use of steric matching, enforced both by the tightly confined polymerase active site and by the DNA backbone, as a chief factor determining nucleotide selection during DNA synthesis. The results also suggest that hydrogen bonds from bases to water (solvation) may be important in increasing the effective size of DNA bases, which may help prevent misinsertion of small bases opposite each other. © 1998 John Wiley & Sons, Inc. Biopoly 48: 3–17, 1998     

DNA polymerase beta fidelity: halomethylene-modified leaving groups in pre-steady-state kinetic analysis reveal differences at the chemical transition state

The mechanism of DNA polymerase beta-catalyzed nucleotidyl transfer consists of chemical steps involving primer 3' OH deprotonation, nucleophilic attack, and pyrophosphate leaving-group elimination, preceded by dNTP binding which induces a large-amplitude conformational change for Watson-Crick nascent base pairs. Ambiguity in the nature of the rate-limiting step and active-site structural differences between correct and incorrect base-paired transition states remain obstacles to understanding DNA replication fidelity. Analogues of dGTP where the beta-gamma bridging oxygen is replaced with fluorine-substituted methylene groups have been shown to probe the contribution of leaving-group elimination to the overall catalytic rate (Biochemistry 46, 461-471). Here, the analysis is expanded substantially to include a broad range of halogen substituents with disparate steric and electronic properties. Evaluation of linear free energy relationships for incorporation of dGTP analogues opposite either template base C or T reveals a strong correlation of log(kpol) to leaving group pKa. Significantly different kpol behavior is observed with a subset of the analogues, with magnitude dependent on the identity of the nascent base pair. This observation, and the absence of an analogous effect on ground state analogue binding (Kd values), points to active-site structural differences at the chemical transition state. Reduced catalysis with bulky halo-containing substrates is manifested in the fidelity of T-G incorporation, where the CCl2-bridging analogue shows a 27-fold increase in fidelity over the natural dGTP. Solvent pH and deuterium isotope-effect data are also used to evaluate mechanistic differences between correct and mispaired incorporation.     

Kinetic analysis of the unique error signature of human DNA polymerase ν

The fidelity of DNA synthesis by A-family DNA polymerases ranges from very accurate for bacterial, bacteriophage, and mitochondrial family members to very low for certain eukaryotic homologues. The latter include DNA polymerase ν (Pol ν) which, among all A-family polymerases, is uniquely prone to misincorporating dTTP opposite template G in a highly sequence-dependent manner. Here we present a kinetic analysis of this unusual error specificity, in four different sequence contexts and in comparison to Pol ν's more accurate A-family homologue, the Klenow fragment of Escherichia coli DNA polymerase I. The kinetic data strongly correlate with rates of stable misincorporation during gap-filling DNA synthesis. The lower fidelity of Pol ν compared to that of Klenow fragment can be attributed primarily to a much lower catalytic efficiency for correct dNTP incorporation, whereas both enzymes have similar kinetic parameters for G-dTTP misinsertion. The major contributor to sequence-dependent differences in Pol ν error rates is the reaction rate, k(pol). In the sequence context where fidelity is highest, k(pol) for correct G-dCTP incorporation by Pol ν is ~15-fold faster than k(pol) for G-dTTP misinsertion. However, in sequence contexts where the error rate is higher, k(pol) is the same for both correct and mismatched dNTPs, implying that the transition state does not provide additional discrimination against misinsertion. The results suggest that Pol ν may be fine-tuned to function when high enzyme activity is not a priority and may even be disadvantageous and that the relaxed active-site specificity toward the G-dTTP mispair may be associated with its cellular function(s).     

Influence of DNA structure on DNA polymerase beta active site function: extension of mutagenic DNA intermediates

In the ternary substrate complex of DNA polymerase (pol) beta, the nascent base pair (templating and incoming nucleotides) is sandwiched between the duplex DNA terminus and polymerase. To probe molecular interactions in the dNTP-binding pocket, we analyzed the kinetic behavior of wild-type pol beta on modified DNA substrates that alter the structure of the DNA terminus and represent mutagenic intermediates. The DNA substrates were modified to 1) alter the sequence of the duplex terminus (matched and mismatched), 2) introduce abasic sites near the nascent base pair, and 3) insert extra bases in the primer or template strands to mimic frameshift intermediates. The results indicate that the nucleotide insertion efficiency (k(cat)/K(m), dGTP-dC) is highly dependent on the sequence identity of the matched (i.e. Watson-Crick base pair) DNA terminus (template/primer, G/C approximately A/T > T/A approximately C/G). Mismatches at the primer terminus strongly diminish correct nucleotide insertion efficiency but do not affect DNA binding affinity. Transition intermediates are generally extended more easily than transversions. Most mismatched primer termini decrease the rate of insertion and binding affinity of the incoming nucleotide. In contrast, the loss of catalytic efficiency with homopurine mismatches at the duplex DNA terminus is entirely due to the inability to insert the incoming nucleotide, since K(d)((dGTP)) is not affected. Abasic sites and extra nucleotides in and around the duplex terminus decrease catalytic efficiency and are more detrimental to the nascent base pair binding pocket when situated in the primer strand than the equivalent position in the template strand.     

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.     

Fidelity of mispair formation and mispair extension is dependent on the interaction between the minor groove of the primer terminus and Arg668 of DNA polymerase I of Escherichia coli

The hydrogen bonding interactions between the Klenow fragment of Escherichia coli DNA polymerase I with the proofreading exonuclease inactivated (KF(-)) and the minor groove of DNA were examined with modified oligodeoxynucleotides in which 3-deazaguanine (3DG) replaced guanine. This substitution would prevent a hydrogen bond from forming between the polymerase and that one site on the DNA. If the hydrogen bonding interaction were important, then we should observe a decrease in the rate of reaction. The steady-state and pre-steady-state kinetics of DNA replication were measured with 10 different oligodeoxynucleotide duplexes in which 3DG was placed at different positions. The largest decrease in the rate of replication was observed when 3DG replaced guanine at the 3'-terminus of the primer. The effect of this substitution on mispair extension and formation was then probed. The G to 3DG substitution at the primer terminus decreased the k(pol) for the extension past G/C, G/A, and G/G base pairs but not the G/T base pair. The G to 3DG substitution at the primer terminus also decreased the formation of correct base pairs as well as incorrect base pairs. However, in all but two mispairs, the effect on correct base pairs was much greater than that of mispairs. These results indicate that the hydrogen bond between Arg668 and the minor groove of the primer terminus is important in the fidelity of both formation and extension of mispairs. These experiments support a mechanism in which Arg668 forms a hydrogen bonding fork between the minor groove of the primer terminus and the ring oxygen of the deoxyribose moiety of the incoming dNTP to align the 3'-hydroxyl group with the alpha-phosphate of the dNTP. This is one mechanism by which the polymerase can use the geometry of the base pairs to modulate the rate of formation and extension of mispairs.     

Evaluating the contribution of base stacking during translesion DNA replication

Despite the nontemplating nature of the abasic site, dAMP is often preferentially inserted opposite the lesion, a phenomenon commonly referred to as the "A-rule". We have evaluated the molecular mechanism accounting for this unique behavior using a thorough kinetic approach to evaluate polymerization efficiency during translesion DNA replication. Using the bacteriophage T4 DNA polymerase, we have measured the insertion of a series of modified nucleotides and have demonstrated that increasing the size of the nucleobase does not correlate with increased insertion efficiency opposite an abasic site. One analogue, 5-nitroindolyl-2'-deoxyriboside triphosphate, was unique as it was inserted opposite the lesion with approximately 1000-fold greater efficiency compared to that for dAMP insertion. Pre-steady-state kinetic measurements yield a kpol value of 126 s(-1) and a Kd value of 18 microM for the insertion of 5-nitroindolyl-2'-deoxyriboside triphosphate opposite the abasic site. These values rival those associated with the enzymatic formation of a natural Watson-Crick base pair. These results not only reiterate that hydrogen bonding is not necessary for nucleotide insertion but also indicate that the base-stacking and/or desolvation capabilities of the incoming nucleobase may indeed play the predominant role in generating efficient DNA polymerization. A model accounting for the increase in catalytic efficiency of this unique nucleobase is provided and invokes pi-pi stacking interactions of the aromatic moiety of the incoming nucleobase with aromatic amino acids present in the polymerase's active site. Finally, differences in the rate of 5-nitroindolyl-2'-deoxyriboside triphosphate insertion opposite an abasic site are measured between the bacteriophage T4 DNA polymerase and the Klenow fragment. These kinetic differences are interpreted with regard to the differences in various structural components between the two enzymes and are consistent with the proposed model for DNA polymerization.     

Using a Fluorescent Cytosine Analogue tC(o) To Probe the Effect of the Y567 to Ala Substitution on the Preinsertion Steps of dNMP Incorporation by RB69 DNA Polymerase

Residues in the nascent base pair binding pocket (NBP) of bacteriophage RB69 DNA polymerase (RB69pol) are responsible for base discrimination. Replacing Tyr567 with Ala leads to greater flexibility in the NBP, increasing the probability of misincorporation. We used the fluorescent cytosine analogue, 1,3-diaza-2-oxophenoxazine (tC(o)), to identify preinsertion step(s) altered by NBP flexibility. When tC(o) is the templating base in a wild-type (wt) RB69pol ternary complex, its fluorescence is quenched only in the presence of dGTP. However, with the RB69pol Y567A mutant, the fluorescence of tC(o) is also quenched in the presence of dATP. We determined the crystal structure of the dATP/tC(o)-containing ternary complex of the RB69pol Y567A mutant at 1.9 ? resolution and found that the incoming dATP formed two hydrogen bonds with an imino-tautomerized form of tC(o). Stabilization of the dATP/tC(o) base pair involved movement of the tC(o) backbone sugar into the DNA minor groove and required tilting of the tC(o) tricyclic ring to prevent a steric clash with L561. This structure, together with the pre-steady-state kinetic parameters and dNTP binding affinity, estimated from equilibrium fluorescence titrations, suggested that the flexibility of the NBP, provided by the Y567 to Ala substitution, led to a more favorable forward isomerization step resulting in an increase in dNTP binding affinity.     

Mismatched base-pair simulations for ASFV Pol X/DNA complexes help interpret frequent G*G misincorporation

DNA polymerase X (pol X) from the African swine fever virus is a 174-amino-acid repair polymerase that likely participates in a viral base excision repair mechanism, characterized by low fidelity. Surprisingly, pol X's insertion rate of the G*G mispair is comparable to that of the four Watson-Crick base pairs. This behavior is in contrast with another X-family polymerase, DNA polymerase beta (pol beta), which inserts G*G mismatches poorly, and has higher DNA repair fidelity. Using molecular dynamics simulations, we previously provided support for an induced-fit mechanism for pol X in the presence of the correct incoming nucleotide. Here, we perform molecular dynamics simulations of pol X/DNA complexes with different incoming incorrect nucleotides in various orientations [C*C, A*G, and G*G (anti) and A*G and G*G (syn)] and compare the results to available kinetic data and prior modeling. Intriguingly, the simulations reveal that the G*G mispair with the incoming nucleotide in the syn configuration undergoes large-scale conformational changes similar to that observed in the presence of correct base pair (G*C). The base pairing in the G*G mispair is achieved via Hoogsteen hydrogen bonding with an overall geometry that is well poised for catalysis. Simulations for other mismatched base pairs show that an intermediate closed state is achieved for the A*G and G*G mispair with the incoming dGTP in anti conformation, while the protein remains near the open conformation for the C*C and the A*G syn mismatches. In addition, catalytic site geometry and base pairing at the nascent template-incoming nucleotide interaction reveal distortions and misalignments that range from moderate for A*G anti to worst for the C*C complex. These results agree well with kinetic data for pol X and provide a structural/dynamic basis to explain, at atomic level, the fidelity of this polymerase compared with other members of the X family. In particular, the more open and pliant active site of pol X, compared to pol beta, allows pol X to accommodate bulkier mismatches such as guanine opposite guanine, while the more structured and organized pol beta active site imposes higher discrimination, which results in higher fidelity. The possibility of syn conformers resonates with other low-fidelity enzymes such as Dpo4 (from the Y family), which readily accommodate oxidative lesions.     

Varying DNA base-pair size in subangstrom increments: evidence for a loose, not large, active site in low-fidelity Dpo4 polymerase

We describe the first systematic test of steric effects in the active site of a Y-family DNA polymerase, Dpo4. It has been hypothesized that low-fidelity repair polymerases in this family more readily accept damaged or mismatched base pairs because of a sterically more open active site, which might place lower geometric constraints on the incipient pair. We have tested the origin of low fidelity by use of five nonpolar thymidine analogues that vary in size by a total of 1.0 A over the series. The efficiency and fidelity of base-pair synthesis was measured by steady-state kinetics for single-nucleotide insertions. Analogues were examined both as incoming deoxynucleoside triphosphate (dNTP) derivatives and as template bases. The results showed that Dpo4 preferred to pair the thymidine shape mimics with adenine and, surprisingly, the preferred size was at the center of the range, the same optimum size as recently found for the high-fidelity Klenow fragment (Kf) of Escherichia coli DNA Pol I. However, the size preference with Dpo4 was quite small, varying by a factor of only 30-35 from most to least efficient thymidine analogue. This is in marked contrast to Kf, which showed a rigid size preference, varying by 1100-fold from best to worst. The fidelity for the non-hydrogen-bonding analogues in pairing with A over T, C, or G was much lower in Dpo4 than in the previous high-fidelity enzyme. The data establish that, unlike Kf, Dpo4 has very low steric selectivity and that steric effects alone cannot explain the fidelity (albeit low) that Dpo4 has for a correct base pair; the findings suggest that hydrogen bonds may be important in determining the fidelity of this enzyme. The results suggest that the low steric selectivity of this enzyme is the result of a conformationally flexible or loose active site that adapts with small energetic cost to different base-pair sizes (as measured by the glycosidic C1'-C1' distance), rather than a spatially large active site.