Prechemistry versus preorganization in DNA replication fidelity

The molecular origin of nucleotide insertion catalysis and fidelity of DNA polymerases is explored by means of computational simulations. Special attention is paid to the examination of the validity of proposals that invoke prechemistry effects, checkpoints concepts, and dynamical effects. The simulations reproduce the observed fidelity in Pol β, starting with the relevant observed X-ray structures of the complex with the right (R) and wrong (W) nucleotides. The generation of free energy surfaces for the R and W systems also allowed us to analyze different proposals about the origin of the fidelity and to reach several important conclusions. It is found that the potential of mean force (PMF) obtained by proper sampling does not support QM/MM-based proposals of a large barrier before the prechemistry state. Furthermore, examination of dynamical proposals by the renormalization approach indicates that the motions from open to close configurations do not contribute to catalysis or fidelity. Finally we discuss and analyze the induced fit concept and show that, despite its importance, it does not explain fidelity. That is, the fidelity is apparently due to the change in the preorganization of the chemical site, as a result of the relaxation of the binding site upon binding of the incorrect nucleotide. Finally and importantly, since the issue is the barrier associated with the enzyme-substrate (ES)/DNA complex at the chemical transition state and not the path to this complex formation (unless this path involves rate determining steps), it is also not useful to invoke checkpoints while discussing fidelity.     

Functional evidence for a small and rigid active site in a high fidelity DNA polymerase: probing T7 DNA polymerase with variably sized base pairs

Hypotheses on the origins of high fidelity in replicative DNA polymerases have recently focused on the importance of geometric or steric effects in this selectivity. Here we reported a systematic study of the effects of base pair size in T7 DNA polymerase (pol), the replicative enzyme for bacteriophage T7. We varied base pair size in very small (0.25 A) increments by use of a series of nonpolar thymidine shape mimics having gradually increasing size. Steady-state kinetics were evaluated for the 5A7A exonuclease-deficient mutant in a 1:1 complex with thioredoxin. For T7 pol, we studied insertion of natural nucleotides opposite variably sized T analogs in the template and, conversely, for variably sized dTTP analogs opposite natural template bases. The enzyme displayed extremely high selectivity for a specific base pair size, with drops in efficiency of as much as 280-fold for increases of 0.4 A beyond an optimum size approximating the size of a natural pair. The enzyme also strongly rejected pairs that were smaller than the optimum by as little as 0.3 A. The size preferences with T7 DNA pol were generally smaller, and the steric rejection was greater than DNA pol I Klenow fragment, correlating with the higher fidelity of the former. The hypothetical effects of varied active site size and rigidity are discussed. The data lend direct support to the concept that active site tightness is a chief determinant of high fidelity of replicative polymerases and that a less rigid (looser) and larger active site can lead to lower fidelity.     

New insights into DNA polymerase mechanisms provided by time-lapse crystallography

DNA polymerases play central roles in DNA replication and repair by catalyzing template-directed nucleotide incorporation. Recently time-lapse X-ray crystallography, which allows one to observe reaction intermediates, has revealed numerous and unexpected mechanistic features of DNA polymerases. In this article, we will examine recent new discoveries that have come from time-lapse crystallography that are currently transforming our understanding of the structural mechanisms used by DNA polymerases. Among these new discoveries are the binding of a third metal ion within the polymerase active site, the mechanisms of translocation along the DNA, the presence of new fidelity checkpoints, a novel pyrophosphatase activity within the active site, and the mechanisms of pyrophosphorolysis.     

Characterization of a replicative DNA polymerase mutant with reduced fidelity and increased translesion synthesis capacity

Changing a highly conserved amino acid in motif A of any of the four yeast family B DNA polymerases, DNA polymerase alpha, delta, epsilon or zeta, results in yeast strains with elevated mutation rates. In order to better understand this phenotype, we have performed structure-function studies of homologous mutants of RB69 DNA polymerase (RB69 pol), a structural model for family B members. When Leu415 in RB69 pol is replaced with phenylalanine or glycine, the mutant polymerases retain high-catalytic efficiency for correct nucleotide incorporation, yet have increased error rates due to increased misinsertion, increased mismatch extension and inefficient proofreading. The Leu415Phe mutant also has increased dNTP insertion efficiency opposite a template 8-oxoG and opposite an abasic site. The 2.5 A crystal structure of a ternary complex of RB69 L415F pol with a correctly base-paired incoming dTTP reveals that the phenylalanine ring is accommodated within a cavity seen in the wild-type enzyme, without steric clash or major change in active site geometry, consistent with retention of high-catalytic efficiency for correct incorporation. In addition, slight structural differences were observed that could be relevant to the reduced fidelity of L415F RB69 pol.     

In silico studies of the African swine fever virus DNA polymerase X support an induced-fit mechanism

The African swine fever virus DNA polymerase X (pol X), a member of the X family of DNA polymerases, is thought to be involved in base excision repair. Kinetics data indicate that pol X catalyzes DNA polymerization with low fidelity, suggesting a role in viral mutagenesis. Though pol X lacks the fingers domain that binds the DNA in other members of the X family, it binds DNA tightly. To help interpret details of this interaction, molecular dynamics simulations of free pol X at different salt concentrations and of pol X bound to gapped DNA, in the presence and in the absence of the incoming nucleotide, are performed. Anchors for the simulations are two NMR structures of pol X without DNA and a model of one NMR structure plus DNA and incoming nucleotide. Our results show that, in its free form, pol X can exist in two stable conformations that interconvert to one another depending on the salt concentration. When gapped double stranded DNA is introduced near the active site, pol X prefers an open conformation, regardless of the salt concentration. Finally, under physiological conditions, in the presence of both gapped DNA and correct incoming nucleotide, and two divalent ions, the thumb subdomain of pol X undergoes a large conformational change, closing upon the DNA. These results predict for pol X a substrate-induced conformational change triggered by the presence of DNA and the correct incoming nucleotide in the active site, as in DNA polymerase beta. The simulations also suggest specific experiments (e.g., for mutants Phe-102Ala, Val-120Gly, and Lys-85Val that may reveal crucial DNA binding and active-site organization roles) to further elucidate the fidelity mechanism of pol X.     

A single highly mutable catalytic site amino acid is critical for DNA polymerase fidelity

DNA polymerases contain active sites that are structurally superimposable and conserved in amino acid sequence. To probe the biochemical and structure-function relationship of DNA polymerases, a large library (200,000 members) of mutant Thermus aquaticus DNA polymerase I (Taq pol I) was created containing random substitutions within a portion of the dNTP binding site (Motif A; amino acids 605-617), and a fraction of all selected active Taq pol I (291 out of 8000) was tested for base pairing fidelity; seven unique mutants that efficiently misincorporate bases and/or extend mismatched bases were identified and sequenced. These mutants all contain substitutions of one specific amino acid, Ile-614, which forms part of the hydrophobic pocket that binds the base and ribose portions of the incoming nucleotide. Mutant Taq pol Is containing hydrophilic substitution I614K exhibit 10-fold lower base misincorporation fidelity, as well as a high propensity to extend mispairs. In addition, these low fidelity mutants containing hydrophilic substitution for Ile-614 can bypass damaged templates that include an abasic site and vinyl chloride adduct ethenoA. During polymerase chain reaction, Taq pol I mutant I614K exhibits an error rate that is >20-fold higher relative to the wild-type enzyme and efficiently catalyzes both transition and transversion errors. These studies have generated polymerase chain reaction-proficient mutant polymerases containing substitutions within the active site that confers low base pairing fidelity and a high error rate. Considering the structural and sequence conservation of Motif A, it is likely that a similar substitution will yield active low fidelity DNA polymerases that are mutagenic.     

Efficient translesion replication past oxaliplatin and cisplatin GpG adducts by human DNA polymerase eta

Platinum anticancer agents form bulky DNA adducts which are thought to exert their cytotoxic effect by blocking DNA replication. Translesion synthesis, one of the pathways of postreplication repair, is thought to account for some resistance to DNA damage and much of the mutagenicity of bulky DNA adducts in dividing cells. Oxaliplatin has been shown to be effective in cisplatin-resistant cell lines and less mutagenic than cisplatin in the Ames assay. We have shown that the eukaryotic DNA polymerases yeast pol zeta, human pol beta, and human pol gamma bypass oxaliplatin-GG adducts more efficiently than cisplatin-GG adducts. Human pol eta, a product of the XPV gene, has been shown to catalyze efficient translesion synthesis past cis, syn-cyclobutane pyrimidine dimers. In the present study we compared translesion synthesis past different Pt-GG adducts by human pol eta. Our data show that, similar to other eukaryotic DNA polymerases, pol eta bypasses oxaliplatin-GG adducts more efficiently than cisplatin-GG adducts. However, pol eta-catalyzed translesion replication past Pt-DNA adducts was more efficient and less accurate than that seen for previously tested polymerases. We show that the efficiency and fidelity of translesion replication past Pt-DNA adducts appear to be determined by both the structure of the adduct and the DNA polymerase active site.     

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.     

DNA structure and aspartate 276 influence nucleotide binding to human DNA polymerase beta. Implication for the identity of the rate-limiting conformational change

Structures of DNA polymerase (pol) beta bound to single-nucleotide gapped DNA had revealed that the lyase and pol domains form a "doughnut-shaped" structure altering the dNTP binding pocket in a fashion that is not observed when bound to non-gapped DNA. We have investigated dNTP binding to pol beta-DNA complexes employing steady-state and pre-steady-state kinetics. Although pol beta has a kinetic scheme similar to other DNA polymerases, polymerization by pol beta is limited by at least two partially rate-limiting steps: a conformational change after dNTP ground-state binding and product release. The equilibrium binding constant, K(d)((dNTP)), decreased and the insertion efficiency increased with a one-nucleotide gapped DNA substrate, as compared with non-gapped DNA. Valine substitution for Asp(276), which interacts with the base of the incoming nucleotide, increased the binding affinity for the incoming nucleotide indicating that the negative charge contributed by Asp(276) weakens binding and that an interaction between residue 276 with the incoming nucleotide occurs during ground-state binding. Since the interaction between Asp(276) and the nascent base pair is observed only in the "closed" conformation of pol beta, the increased free energy in ground-state binding for the mutant suggests that the subsequent rate-limiting conformational change is not the "open" to "closed" structural transition, but instead is triggered in the closed pol conformation.     

The effect of DNA structure on the catalytic efficiency and fidelity of human DNA polymerase beta on templates with platinum-DNA adducts

DNA adducts formed by platinum-based anticancer drugs interfere with DNA replication. The carrier ligand of the platinum compound is likely to affect the conformation of the Pt-DNA adducts. In addition, the conformation of the adduct can also change upon binding of damaged DNA to the active site of DNA polymerase. From the crystal structures of pol beta ternary complexes it is evident that undamaged gapped and primed single-stranded (non-gapped) DNA templates exist in very different conformations when bound to pol beta. Therefore, one might expect that the constraints imposed on the damaged templates by binding to the polymerase active site should also affect the conformation of the Pt-DNA adducts and their ability to inhibit DNA replication. In support of this hypothesis we have found that the efficiency, carrier ligand specificity, site of discrimination (3'-G versus 5'-G of the Pt-GG adducts), and fidelity of translesion synthesis past Pt-DNA adducts by pol beta are strongly affected by the structure of the DNA template. Previous studies have suggested that the conformation of Pt-DNA adducts may be affected by the sequence context of the adduct. In support of this hypothesis, our data show that sequence context affects the efficiency, fidelity, and pattern of misincorporation by pol beta.     

Highly organized but pliant active site of DNA polymerase beta: compensatory mechanisms in mutant enzymes revealed by dynamics simulations and energy analyses

To link conformational transitions noted for DNA polymerases with kinetic results describing catalytic efficiency and fidelity, we investigate the role of key DNA polymerase beta residues on subdomain motion through simulations of five single-residue mutants: Arg-283-Ala, Tyr-271-Ala, Asp-276-Val, Arg-258-Lys, and Arg-258-Ala. Since a movement toward a closed state was only observed for R258A, we suggest that Arg(258) is crucial in modulating motion preceding chemistry. Analyses of protein/DNA interactions in the mutant active site indicate distinctive hydrogen bonding and van der Waals patterns arising from compensatory structural adjustments. By comparing closed mutant complexes with the wild-type enzyme, we interpret experimentally derived nucleotide binding affinities in molecular terms: R283A (decreased), Y271A (increased), D276V (increased), and R258A (decreased). Thus, compensatory interactions (e.g., in Y271A with adjacent residues Phe(272), Asn(279), and Arg(283)) increase the overall binding affinity for the incoming nucleotide although direct interactions may decrease. Together with energetic analyses, we predict that R258G might increase the rate of nucleotide insertion and maintain enzyme fidelity as R258A; D276L might increase the nucleotide binding affinity more than D276V; and R283A/K280A might decrease the nucleotide binding affinity and increase misinsertion more than R283A. The combined observations regarding key roles of specific residues (e.g., Arg(258)) and compensatory interactions echo the dual nature of polymerase active site, namely versatility (to accommodate various basepairs) and specificity (for preserving fidelity) and underscore an organized but pliant active site essential to enzyme function.     

Efficiency of extension of mismatched primer termini across from cisplatin and oxaliplatin adducts by human DNA polymerases beta and eta in vitro

DNA polymerases beta and eta are among the few eukaryotic polymerases known to efficiently bypass cisplatin and oxaliplatin adducts in vitro. Our laboratory has previously established that both polymerases misincorporated dTTP with high frequency across from cisplatin- and oxaliplatin-GG adducts. This decrease in polymerase fidelity on platinum-damaged DNA could lead to in vivo mutations, if this base substitution were efficiently elongated. In this study, we performed a steady-state kinetic analysis of the steps required for fixation of dTTP misinsertion during translesion synthesis past cisplatin- and oxaliplatin-GG adducts by pol beta and pol eta. The efficiency of translesion synthesis by pol eta past Pt-GG adducts was very similar to that observed for this polymerase when the template contains thymine-thymine dimers. This finding suggested that pol eta could play a role in translesion synthesis past platinum-GG adducts in vivo. On the other hand, translesion synthesis past platinum-GG adducts by pol beta was much less efficient. Translesion synthesis by pol eta is likely to be predominantly error-free, since the probability of correct insertion and extension by pol eta was 1000-2000-fold greater than the probability of incorrect insertion and extension. Our results also indicated that for pol eta the frequency of misincorporation is the same across from the 3'G and the 5'G of the platinum-GG adducts for both cisplatin and oxaliplatin adducts. On the other hand, pol beta is more likely to misinsert at the 3'G of the adducts and misinsertion occurs at higher frequency for oxaliplatin-GG than for cisplatin-GG adducts.     

phi 29 DNA polymerase residue Leu384, highly conserved in motif B of eukaryotic type DNA replicases,is involved in nucleotide insertion fidelity

Replicative DNA polymerases achieve insertion fidelity by geometric selection of a complementary nucleotide followed by induced fit: movement of the fingers subdomain toward the active site to enclose the incoming and templating nucleotides generating a binding pocket for the nascent base pair. Several residues of motif B of DNA polymerases from families A and B, localized in the fingers subdomain, have been described to be involved in template/primer binding and dNTP selection. Here we complete the analysis of this motif, which has the consensus "KLX2NSXYG" in DNA polymerases from family B, characterized by mutational analysis of conserved leucine, Leu384 of phi 29 DNA polymerase. Mutation of Leu384 into Arg resulted in a phi 29 DNA polymerase with reduced nucleotide insertion fidelity during DNA-primed polymerization and protein-primed initiation reactions. However, the mutation did not alter the intrinsic affinity for the different dNTPs, as shown in the template-independent terminal protein-deoxynucleotidylation reaction. We conclude that Leu384 of phi 29 DNA polymerase plays an important role in positioning the templating nucleotide at the polymerization active site and in controlling nucleotide insertion fidelity. This agrees with the localization of the corresponding residue in the closed ternary complexes of family A and family B DNA polymerases, contributing to form the binding pocket for the nascent base pair. As an additional effect, mutant polymerase L384R was strongly reduced in DNA binding, resulting in reduced processivity during polymerization.     

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.     

Subtle but variable conformational rearrangements in the replication cycle of Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) may accommodate lesion bypass

The possible conformational changes of DNA polymerase IV (Dpo4) before and after the nucleotidyl-transfer reaction are investigated at the atomic level by dynamics simulations to gain insight into the mechanism of low-fidelity polymerases and identify slow and possibly critical steps. The absence of significant conformational changes in Dpo4 before chemistry when the incoming nucleotide is removed supports the notion that the "induced-fit" mechanism employed to interpret fidelity in some replicative and repair DNA polymerases does not exist in Dpo4. However, significant correlated movements in the little finger and finger domains, as well as DNA sliding and subtle catalytic-residue rearrangements, occur after the chemical reaction when both active-site metal ions are released. Subsequently, Dpo4's little finger grips the DNA through two arginine residues and pushes it forward. These metal ion correlated movements may define subtle, and possibly characteristic, conformational adjustments that operate in some Y-family polymerase members in lieu of the prominent subdomain motions required for catalytic cycling in other DNA polymerases like polymerase beta. Such subtle changes do not easily provide a tight fit for correct incoming substrates as in higher-fidelity polymerases, but introduce in low-fidelity polymerases different fidelity checks as well as the variable conformational-mobility potential required to bypass different lesions.     

Efficiency of correct nucleotide insertion governs DNA polymerase fidelity

DNA polymerase fidelity or specificity expresses the ability of a polymerase to select a correct nucleoside triphosphate (dNTP) from a pool of structurally similar molecules. Fidelity is quantified from the ratio of specificity constants (catalytic efficiencies) for alternate substrates (i.e. correct and incorrect dNTPs). An analysis of the efficiency of dNTP (correct and incorrect) insertion for a low fidelity mutant of DNA polymerase beta (R283A) and exonuclease-deficient DNA polymerases from five families derived from a variety of biological sources reveals that a strong correlation exists between the ability to synthesize DNA and the probability that the polymerase will make a mistake (i.e. base substitution error). Unexpectedly, this analysis indicates that the difference between low and high fidelity DNA polymerases is related to the efficiency of correct, but not incorrect, nucleotide insertion. In contrast to the loss of fidelity observed with the catalytically inefficient R283A mutant, the fidelity of another inefficient mutant of DNA polymerase beta (G274P) is not altered. Thus, although all natural low fidelity DNA polymerases are inefficient, not every inefficient DNA polymerase has low fidelity. Low fidelity polymerases appear to be an evolutionary solution to how to replicate damaged DNA or DNA repair intermediates without burdening the genome with excessive polymerase-initiated errors.     

Magnesium-cationic dummy atom molecules enhance representation of DNA polymerase beta in molecular dynamics simulations: improved accuracy in studies of structural features and mutational effects

Human DNA polymerase beta (pol beta) fills gaps in DNA as part of base excision DNA repair. Due to its small size it is a convenient model enzyme for other DNA polymerases. Its active site contains two Mg(2+) ions, of which one binds an incoming dNTP and one catalyzes its condensation with the DNA primer strand. Simulating such binuclear metalloenzymes accurately but computationally efficiently is a challenging task. Here, we present a magnesium-cationic dummy atom approach that can easily be implemented in molecular mechanical force fields such as the ENZYMIX or the AMBER force fields. All properties investigated here, namely, structure and energetics of both Michaelis complexes and transition state (TS) complexes were represented more accurately using the magnesium-cationic dummy atom model than using the traditional one-atom representation for Mg(2+) ions. The improved agreement between calculated free energies of binding of TS models to different pol beta variants and the experimentally determined activation free energies indicates that this model will be useful in studying mutational effects on catalytic efficiency and fidelity of DNA polymerases. The model should also have broad applicability to the modeling of other magnesium-containing proteins.     

DNA structure and polymerase fidelity.

The accuracy of DNA replication results from both the intrinsic DNA polymerase fidelity and the DNA sequence. Although the recent structural studies on polymerases have brought new insights on polymerase fidelity, the role of DNA sequence and structure is less well understood. Here, the analysis of the crystal structures of hotspots for polymerase slippage including (CA)n and (A)n tracts in different intermolecular contexts reveals that, in the B-form, these sequences share common structural alterations which may explain the high rate of replication errors. In particular, a two-faced "Janus-like" structure with shifted base-pairs in the major groove but an apparent normal geometry in the minor groove constitutes a molecular decoy specifically suitable to mislead the polymerases. A model of the rat polymerase beta bound to this structure suggests that an altered conformation of the nascent template-primer duplex can interfere with correct nucleotide incorporation by affecting the geometry of the active site and breaking the rules of base-pairing, while at the same time escaping enzymatic mechanisms of error discrimination which scan for the correct geometry of the minor groove.In contrast, by showing that the A-form greatly attenuates the sequence-dependent structural alterations in hotspots, this study suggests that the A-conformation of the nascent template-primer duplex at the vicinity of the polymerase active site will contribute to fidelity. The A-form may play the role of a structural buffer which preserves the correct geometry of the active site for all sequences. The detailed comparison of the conformation of the nascent template-primer duplex in the available crystal structures of DNA polymerase-DNA complexes shows that polymerase beta, the least accurate enzyme, is unique in binding to a B-DNA duplex even close to its active site. This model leads to several predictions which are discussed in the light of published experimental data.     

Mechanism of nucleotide incorporation in DNA polymerase beta

DNA polymerases play a central role in the mechanisms of DNA replication and repair. Here, we report mechanisms of the beta-polymerase catalyzed phosphoryl transfer reactions corresponding to correct and incorrect nucleotide incorporations in the DNA. Based on energy minimizations, molecular dynamics simulations, and free energy calculations of solvated ternary complexes of pol beta and by employing a mixed quantum mechanics molecular mechanics Hamiltonian, we have uncovered the identities of transient intermediates in the phosphoryl transfer pathways. Our study has revealed that an intriguing Grotthuss hopping mechanism of proton transfer involving water and three conserved aspartate residues in pol beta's active site mediates the phosphoryl transfer in the correct as well as misincorporation of nucleotides. The significance of this catalytic step in serving as a kinetic check point of polymerase fidelity may be unique to DNA polymerase beta, and is discussed in relation to other known mechanisms of DNA polymerases.