RNA aptamers selected against DNA polymerase beta inhibit the polymerase activities of DNA polymerases beta and kappa

DNA polymerase β (polβ), a member of the X family of DNA polymerases, is the major polymerase in the base excision repair pathway. Using in vitro selection, we obtained RNA aptamers for polβ from a variable pool of 8 × 10¹² individual RNA sequences containing 30 random nucleotides. A total of 60 individual clones selected after seven rounds were screened for the ability to inhibit polβ activity. All of the inhibitory aptamers analyzed have a predicted tri-lobed structure. Gel mobility shift assays demonstrate that the aptamers can displace the DNA substrate from the polβ active site. Inhibition by the aptamers is not polymerase specific; inhibitors of polβ also inhibited DNA polymerase κ, a Y-family DNA polymerase. However, the RNA aptamers did not inhibit the Klenow fragment of DNA polymerase I and only had a minor effect on RB69 DNA polymerase activity. Polβ and κ, despite sharing little sequence similarity and belonging to different DNA polymerase families, have similarly open active sites and relatively few interactions with their DNA substrates. This may allow the aptamers to bind and inhibit polymerase activity. RNA aptamers with inhibitory properties may be useful in modulating DNA polymerase actvity in cells.     

Inhibition of bacteriophage-Q beta ribonucleic acid polymerase by guanosine triphosphate analogues.

Sixteen compounds related to GTP were evaluated as inhibitors of bacteriophage-Q beta poly(C)-dependent poly(G) polymerase. Non-phosphorylated compounds, including guanine, guanosine and deoxyguanosine, were inactive. Phosphorylated compounds gave significant inhibition at millimolar concentrations. For nucleotides the feature important for inhibition was the 5'-phosphate chain. Four triphosphates, XTP, ITP, 7-methyl-GTP and 2'-O-methyl-GTP, gave 50% inhibition of both the poly(C)- and poly(U2,C)-dependent reactions at concentrations from 0.1 to 5 mM. XTP was 10-fold more potent an inhibitor of the reaction with poly(U2,C) as template. None of these four compounds was able to substitute for GTP as substrate to a significant extent. The most active compound, 2'-O-methyl-GTP, was a competitive inhibitor (Ki = 0.4 mM) of GTP in the poly(C)-dependent reaction.     

Recognition of template-primer and gapped DNA substrates by the human DNA polymerase beta

Interactions between human DNA polymerase beta and the template-primer, as well as gapped DNA substrates, have been studied using quantitative fluorescence titration and analytical ultracentrifugation techniques. In solution, human pol beta binds template-primer DNA substrates with a stoichiometry much higher than predicted on the basis of the crystallographic structure of the polymerase-DNA complex. The obtained stoichiometries can be understood in the context of the polymerase affinity for the dsDNA and the two ssDNA binding modes, the (pol beta)(16) and (pol beta)(5) binding modes, which differ by the number of nucleotide residues occluded by the protein in the complex. The analysis of polymerase binding to different template-primer substrates has been performed using the statistical thermodynamic model which accounts for the existence of different ssDNA binding modes and has allowed us to extract intrinsic spectroscopic and binding parameters. The data reveal that the small 8 kDa domain of the enzyme can engage the dsDNA in interactions, downstream from the primer, in both (pol beta)(16) and (pol beta)(5) binding modes. The affinity, as well as the stoichiometry of human pol beta binding to the gapped DNAs is not affected by the decreasing size of the ssDNA gap, indicating that the enzyme recognizes the ssDNA gaps of different sizes with very similar efficiency. On the basis of the obtained results we propose a plausible model for the gapped DNA recognition by human pol beta. The enzyme binds the ss/dsDNA junction of the gap, using its 31 kDa domain, with slight preference over the dsDNA. Binding only to the junction, but not to the dsDNA, induces an allosteric conformational transition of the enzyme and the entire enzyme-DNA complex which results in binding of the 8 kDa domain with the dsDNA. This, in turn, leads to the significant amplification of the enzyme affinity for the gap over the surrounding dsDNA, independent of the gap size. The presence of the 5'-terminal phosphate, downstream from the primer, has little effect on the affinity, but profoundly affects the ssDNA conformation in the complex. The significance of these results for the mechanistic model of the functioning of human pol beta is discussed.     

Synthesis of non-nucleoside triphosphate analogues, a new type of substrates for terminal deoxynucleotidyl transferase

A series of non-nucleoside triphosphate analogues were synthesized. In place of the nucleoside fragment, substituents bearing aromatic groups were introduced; the triphosphate component was replaced at alpha, beta, or gamma-positions by phosphonates. Alpha-[2-N-(9-Fluorenylmethoxycarbonyl)aminoethylphosphonyl]-beta,gamma-difluoromethylenediphosphonate (IIc) revealed the best substrate properties toward terminal deoxynucleotidyl transferase.     

DNA polymerases beta and lambda, and their roles in the DNA replication and repair

One of the key stages of life of a cell is genome duplication. The main enzymes which lead this process are DNA-dependent DNA polymerases. At the moment, 19 DNA polymerases with striking properties are listed in the eukaryotic cells. Mitochondrial DNA polymerase gamma from A family and most of the nuclear enzymes from B family are high fidelity DNA polymerases which are participate in genome DNA replication process as well as in DNA repair. Among the other 1 5 proteins, the D N A polymerases belonging to the X and Y families have a special place. They participate in a different repair processes such as base excision repair and non-homologous end joining. Moreover, some of them play a specific role in the replication of the damaged DNA templates. This process is referred as translesion synthesis or TLS. The DNA polymerases beta and lambda members of X family are enclosed in polyfunctional enzymes, and their properties and functions will be discussed in this review.     

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.     

Utilization in vitro of deoxyuridine triphosphate in DNA synthesis by DNA polymerases alpha and beta from calf thymus.

DNA polymerases alpha and beta (EC 2.7.7.7.) from calf thymus could utilize dUTP as a substrate for DNA synthesis as well as DNA polymerase I of Escherichia coli. Deoxyuridylate was incorporated into DNA by replacing deoxythymidylate and supported the further elongation of DNA chains on activated DNA or on the intiated homopolymers, poly(dA) . (dT)10 and poly(rA) . (dT)10. The rate of the incorporation of deoxyuridylate into DNA varied from 50 to 160% of that of deoxythymidylate, depending on the nature of the template primers and the species of DNA polymerase used. The apparent Km values for dUTP were very similar to those for dTTP. Uracil DNA-glycosylase excised efficiently the uracil residues in products of DNA polymerase reactions with either activated calf thymus DNA or initiated homopolymers.     

Correct and incorrect nucleotide incorporation pathways in DNA polymerase beta

Tracking the structural and energetic changes in the pathways of DNA replication and repair is central to the understanding of these important processes. Here we report favorable mechanisms of the polymerase-catalyzed phosphoryl transfer reactions corresponding to correct and incorrect nucleotide incorporations in the DNA by using a novel protocol involving energy minimizations, dynamics simulations, quasi-harmonic free energy calculations, and mixed quantum mechanics/molecular mechanics dynamics simulations. Though the pathway proposed may not be unique and invites variations, geometric and energetic arguments support the series of transient intermediates in the phosphoryl transfer pathways uncovered here for both the G:C and G:A systems involving a Grotthuss hopping mechanism of proton transfer between water molecules and the three conserved aspartate residues in pol beta's active-site. In the G:C system, the rate-limiting step is the initial proton hop with a free energy of activation of at least 17 kcal/mol, which corresponds closely to measured k(pol) values. Fidelity discrimination in pol beta can be explained by a significant loss of stability of the closed ternary complex of the enzyme in the G:A system and much higher activation energy of the initial step of nucleophilic attack, namely deprotonation of terminal DNA primer O3'H group. Thus, subtle differences in the enzyme active-site between matched and mismatched base pairs generate significant differences in catalytic performance.     

Nucleotide binding interactions modulate dNTP selectivity and facilitate 8-oxo-dGTP incorporation by DNA polymerase lambda

8-Oxo-7,8,-dihydro-2′-deoxyguanosine triphosphate (8-oxo-dGTP) is a major product of oxidative damage in the nucleotide pool. It is capable of mispairing with adenosine (dA), resulting in futile, mutagenic cycles of base excision repair. Therefore, it is critical that DNA polymerases discriminate against 8-oxo-dGTP at the insertion step. Because of its roles in oxidative DNA damage repair and non-homologous end joining, DNA polymerase lambda (Pol λ) may frequently encounter 8-oxo-dGTP. Here, we have studied the mechanisms of 8-oxo-dGMP incorporation and discrimination by Pol λ. We have solved high resolution crystal structures showing how Pol λ accommodates 8-oxo-dGTP in its active site. The structures indicate that when mispaired with dA, the oxidized nucleotide assumes the mutagenic syn-conformation, and is stabilized by multiple interactions. Steady-state kinetics reveal that two residues lining the dNTP binding pocket, Ala⁵¹⁰ and Asn⁵¹³, play differential roles in dNTP selectivity. Specifically, Ala⁵¹⁰ and Asn⁵¹³ facilitate incorporation of 8-oxo-dGMP opposite dA and dC, respectively. These residues also modulate the balance between purine and pyrimidine incorporation. Our results shed light on the mechanisms controlling 8-oxo-dGMP incorporation in Pol λ and on the importance of interactions with the incoming dNTP to determine selectivity in family X DNA polymerases.     

Erroneous incorporation of oxidized DNA precursors by Y-family DNA polymerases

Deranged oxidative metabolism is a property of many tumour cells. Oxidation of the deoxynucleotide triphosphate (dNTP) pool, as well as DNA, is a major cause of genome instability. Here, we report that two Y-family DNA polymerases of the archaeon Sulfolobus solfataricus strains P1 and P2 incorporate oxidized dNTPs into nascent DNA in an erroneous manner: the polymerases exclusively incorporate 8-OH-dGTP opposite adenine in the template, and incorporate 2-OH-dATP opposite guanine more efficiently than opposite thymine. The rate of extension of the nascent DNA chain following on from these incorporated analogues is only slightly reduced. These DNA polymerases have been shown to bypass a variety of DNA lesions. Thus, our results suggest that the Y-family DNA polymerases promote mutagenesis through the erroneous incorporation of oxidized dNTPs during DNA synthesis, in addition to facilitating translesion DNA synthesis. We also report that human DNA polymerase η, a human Y-family DNA polymerase, incorporates the oxidized dNTPs in a similar erroneous manner.     

Deployment of DNA polymerases beta and lambda in single-nucleotide and multinucleotide pathways of mammalian base excision DNA repair

There exist two major base excision DNA repair (BER) pathways, namely single-nucleotide or “short-patch” (SP-BER), and “long-patch” BER (LP-BER). Both pathways appear to be involved in the repair of small base lesions such as uracil, abasic sites and oxidized bases. In addition to DNA polymerase β (Polβ) as the main BER enzyme for repair synthesis, there is evidence for a minor role for DNA polymerase lambda (Polλ) in BER. In this study we explore the potential contribution of Polλ to both SP- and LP-BER in cell-free extracts. We measured BER activity in extracts of mouse embryonic fibroblasts using substrates with either a single uracil or the chemically stable abasic site analog tetrahydrofuran residue. The addition of purified Polλ complemented the pronounced BER deficiency of POLB-null cell extracts as efficiently as did Polβ itself. We have developed a new approach for determining the relative contributions of SP- and LP-BER pathways, exploiting mass-labeled nucleotides to distinguish single- and multinucleotide repair patches. Using this method, we found that uracil repair in wild-type and in Polβ-deficient cell extracts supplemented with Polλ was ∼80% SP-BER. The results show that recombinant Polλ can contribute to both SP- and LP-BER. However, endogenous Polλ, which is present at a level ˜50% that of Polβ in mouse embryonic fibroblasts, appears to make little contribution to BER in extracts. Thus Polλ in cells appears to be under some constraint, perhaps sequestered in a complex with other proteins, or post-translationally modified in a way that limits its ability to participate effectively in BER.     

8-oxodGTP incorporation by DNA polymerase beta is modified by active-site residue Asn279

To understand how the active site of a DNA polymerase might modulate the coding of 8-oxo-7,8-dihydrodeoxyguanine (8-oxodG), we performed steady-state kinetic analyses using wild-type DNA polymerase beta (pol beta) and two active-site mutants. We compared the coding of these polymerases by calculating the ratio of efficiencies for incorporation of dATP and dCTP opposite 8-oxodG and for incorporation of 8-oxodGTP opposite dA and dC. For wild-type pol beta, there is a 2:1 preference for incorporation of dCTP over dATP opposite 8-oxodG using a 5'-phosphorylated 4-base gap substrate. Mutation of either Asn279 or Arg283 to alanine has almost no effect on the ratio. 8-OxodGTP is preferentially incorporated opposite a template dA (24:1) by wild-type pol beta; mutation of Asn279 to alanine results dramatic change whereby there is preferential incorporation of 8-oxodGTP opposite dC (14:1). This suggests that interactions of 8-oxodGTP with Asn279 in the polymerase active site may alter the conformation of 8-oxodGTP and therefore alter its misincorporation.     

Mismatched and matched dNTP incorporation by DNA polymerase beta proceed via analogous kinetic pathways

While matched nucleotide incorporation by DNA polymerase beta (Pol beta) has been well-studied, a true understanding of polymerase fidelity requires comparison of both matched and mismatched dNTP incorporation pathways. Here we examine the mechanism of misincorporation for wild-type (WT) Pol beta and an error-prone I260Q variant using stopped-flow fluorescence assays and steady-state fluorescence spectroscopy. In stopped-flow, a biphasic fluorescence trace is observed for both enzymes during mismatched dNTP incorporation. The fluorescence transitions are in the same direction as that observed for matched dNTP, albeit with lower amplitude. Assignments of the fast and slow fluorescence phases are designated to the same mechanistic steps previously determined for matched dNTP incorporation. For both WT and I260Q mismatched dNTP incorporation, the rate of the fast phase, reflecting subdomain closing, is comparable to that induced by correct dNTP. Pre-steady-state kinetic evaluation reveals that both enzymes display similar correct dNTP insertion profiles, and the lower fidelity intrinsic to the I260Q mutant results from enhanced efficiency of mismatched incorporation. Notably, in comparison to WT, I260Q demonstrates enhanced intensity of fluorescence emission upon mismatched ternary complex formation. Both kinetic and steady-state fluorescence data suggest that relaxed discrimination against incorrect dNTP by I260Q is a consequence of a loss in ability to destabilize the mismatched ternary complex. Overall, our results provide first direct evidence that mismatched and matched dNTP incorporations proceed via analogous kinetic pathways, and support our standing hypothesis that the fidelity of Pol beta originates from destabilization of the mismatched closed ternary complex and chemical transition state.     

Interplay between DNA polymerases beta and lambda in repair of oxidation DNA damage in chicken DT40 cells

DNA polymerase lambda (Pol lambda) is a DNA polymerase beta (Pol beta)-like enzyme with both DNA synthetic and 5'-deoxyribose-5'-phosphate lyase domains. Recent biochemical studies implicated Pol lambda as a backup enzyme to Pol beta in the mammalian base excision repair (BER) pathway. To examine the interrelationship between Pol lambda and Pol beta in BER of DNA damage in living cells, we disrupted the genes for both enzymes either singly or in combination in the chicken DT40 cell line and then characterized BER phenotypes. Disruption of the genes for both polymerases caused hypersensitivity to H(2)O(2)-induced cytotoxicity, whereas the effect of disruption of either polymerase alone was only modest. Similarly, BER capacity in cells after H(2)O(2) exposure was lower in Pol beta(-/-)/Pol lambda(-/-) cells than in Pol beta(-/-), wild-type, and Pol lambda(-/-) cells, which were equivalent. These results suggest that these polymerases can complement for one another in counteracting oxidative DNA damage. Similar results were obtained in assays for in vitro BER capacity using cell extracts. With MMS-induced cytotoxicity, there was no significant effect on either survival or BER capacity from Pol lambda gene disruption. A strong hypersensitivity and reduction in BER capacity was observed for Pol beta(-/-)/Pol lambda(-/-) and Pol beta(-/-) cells, suggesting that Pol beta had a dominant role in counteracting alkylation DNA damage in this cell system.     

Comparison of functional properties of mammalian DNA polymerase lambda and DNA polymerase beta in reactions of DNA synthesis related to DNA repair

DNA polymerase lambda (Pol lambda) is a novel enzyme of the family X of DNA polymerases. Pol lambda has some properties in common with DNA polymerase beta (Pol beta). The substrate properties of Pol lambda were compared to Pol beta using DNAs mimicking short-patch (SP) and long-patch (LP) base excision repair (BER) intermediates as well as recessed template primers. In the present work, the influence of several BER proteins such as flap-endonuclease-1 (FEN1), PCNA, and apurinic/apyrimidinic endonuclease-1 (APE1) on the activity of Pol lambda was investigated. Pol lambda is unable to catalyze strand displacement synthesis using nicked DNA, although this enzyme efficiently incorporates a dNMP into a one-nucleotide gap. FEN1 and PCNA stimulate the strand displacement activity of Pol lambda. FEN1 processes nicked DNA, thus removing a barrier to Pol lambda DNA synthesis. It results in a one-nucleotide gapped DNA molecule that is a favorite substrate of Pol lambda. Photocrosslinking and functional assay show that Pol lambda is less efficient than Pol beta in binding to nicked DNA. APE1 has no influence on the strand displacement activity of Pol lambda though it stimulates strand displacement synthesis catalyzed with Pol beta. It is suggested that Pol lambda plays a role in the SP BER rather than contributes to the LP BER pathway.     

Synthesis and incorporation of pyrrole carboxamide nucleoside triphosphates by DNA polymerases

We have synthesised and examined the enzymatic incorporation properties of the 5'-triphosphates of 2'-deoxyribosyl pyrrole 3-monocarboxamide (dMTP) and 2'-deoxyribosyl pyrrole 3,4-dicarboxamide (dDTP). These analogues we had hoped would behave as ambivalent base analogues in that they can present two alternative hydrogen-bonding faces either by rotation about the carboxamide group or about the glycosidic bond. The two pyrrole derivatives, dMTP and dDTP, exhibit a preference for incorporation with Klenow polymerase. They are preferentially incorporated as either A or C.     

Terminating substrates of DNA polymerases: synthesis and functional study

In order to study the mechanisms of DNA biosynthesis a number of modified nucleoside - substrates of DNA polymerases was synthesized. The absence of hydroxyl at 3'-position of ribose results in terminating properties of DNA biosynthesis of these analogues. A single step synthesis of triphosphates and alpha-thiotriphosphates of natural and 3'-modified 2'-deoxynucleosides is described.     

Energetics and specificity of Rat DNA polymerase beta interactions with template-primer and gapped DNA substrates

Interactions between rat polymerase beta (pol beta) and the template-primer, as well as gapped DNAs, were studied using the quantitative fluorescence titration technique. Stoichiometries of rat pol beta complexes with DNA substrates are much higher than stoichiometries predicted by the structures of co-crystals. The data can be understood in the context of the two single-stranded (ss)DNA-binding modes of the enzyme, the (pol beta)(16) and (pol beta)(5) binding modes, which differ by the number of nucleotides occluded by the protein. The 8-kDa domain of the enzyme engages the double-stranded (ds)DNA downstream from the primer, while the 31-kDa domain has similar affinity for the ss-ds DNA junction and the dsDNA. The affinity of rat pol beta for the gapped DNA is not affected by the size of the gap. The results indicate a plausible model for recognition of the gapped DNA by rat pol beta. The enzyme binds the ss-ds DNA junction of the gap using the 31-kDa domain. This binding induces an allosteric transition, resulting in the association of the 8-kDa domain with the dsDNA, leading to an amplification of the affinity for the gap. The 5' terminal phosphate, downstream from the primer, has little effect on the affinity, but affects the ssDNA conformation of the gap.