The I260Q variant of DNA polymerase beta extends mispaired primer termini due to its increased affinity for deoxynucleotide triphosphate substrates

DNA polymerase beta plays a key role in base excision repair. We have previously shown that the hydrophobic hinge region of polymerase beta, which is distant from its active site, plays a critical role in the fidelity of DNA synthesis by this enzyme. The I260Q hinge variant of polymerase beta misincorporates nucleotides with a significantly higher catalytic efficiency than the wild-type enzyme. In the study described here, we show that I260Q extends mispaired primer termini. The kinetic basis for extension of mispairs is defective discrimination by I260Q at the level of ground-state binding of the dNTP substrate. Our results suggest that the hydrophobic hinge region influences the geometry of the dNTP binding pocket exclusively. Because the DNA forms part of the binding pocket, our data are also consistent with the interpretation that the mispaired primer terminus affects the geometry of the dNTP binding pocket such that the I260Q variant has a higher affinity for the incoming dNTP than wild-type polymerase beta.     

Variants of DNA polymerase Beta extend mispaired DNA due to increased affinity for nucleotide substrate

DNA polymerase beta offers an attractive system to study the biochemical mechanism of polymerase-dependent mutagenesis. Variants of DNA polymerase beta, Y265F and Y265W, were analyzed for misincorporation efficiency and mispair extension ability, relative to wild-type DNA polymerase beta. Our data show that the fidelity of the mutant polymerases is similar to wild-type enzyme on a one-nucleotide gapped DNA substrate. In contrast, with a six-nucleotide gapped DNA, the mutant proteins are slightly more accurate than the wild-type enzyme. The mutagenic potential of Y265F and Y265W is more pronounced when encountering a mispaired DNA substrate. Here, both variants can extend a G:G mispair quite efficiently, and Y265F can also extend a T:G mispair. The kinetic basis of the increased mispair extension efficiency is due to an improved ability to bind to the incoming nucleotide. Y265W extends the G:G mispair even with an incorrect nucleotide substrate. Overall, our results demonstrate that the Y265 hinge residue is important for stabilizing the architecture of the nucleotide binding pocket of DNA polymerase beta, and that alterations of this residue can have significant impacts upon the fidelity of DNA synthesis.     

Prostate-cancer-associated I260M variant of DNA polymerase beta is a sequence-specific mutator

Studies show that 30% of 189 tumors sequenced to date express variants of the polymerase beta (pol beta) protein that are not present in normal tissue. This raises the possibility that variants of pol beta might be linked to the etiology of cancer. Here, we characterize the I260M prostate-cancer-associated variant of pol beta. Ile260 is a key residue of the hydrophobic hinge that is important for the closing of the polymerase. In this study, we demonstrate that the I260M variant is a sequence context-dependent mutator polymerase. Specifically, I260M is a mutator for misalignment-mediated errors in dipyrimidine sequences. I260M is also a low-fidelity polymerase with regard to the induction of transversions within specific sequence contexts. Our results suggest that the hinge influences the geometry of the DNA within the polymerase active site that is important for accurate DNA synthesis. Importantly, characterization of the I260M variant shows that it has a functional phenotype that could be linked to the etiology or malignant progression of human cancer.     

Hinge residue Ile260 of DNA polymerase beta is important for enzyme activity and fidelity

DNA polymerases ensure efficient insertion of the correct dNTP into the DNA substrate. They have evolved mechanisms for discriminating among very similar dNTP substrates. DNA polymerase beta is a repair polymerase that provides a model system for a direct study of insertion fidelity. In this study, we examined the role of hinge residue Ile260 of the rat Polbeta on enzyme activity and accuracy. We changed residue I260 to every other amino acid residue and used genetic screens to assess the activity and fidelity of the resulting mutants. The I260D, -E, -K, -N, and -R mutants are significantly less active than wild-type Polbeta. Interestingly, I260H and I260Q are active but exhibit mutator activity. This suggests that the nonpolar nature of residue 260 is important for maintaining the activity and fidelity of Polbeta. We employ molecular modeling as an aid in explaining the observed phenotypes and propose a mechanism whereby the positioning of the DNA substrate in the enzyme and within the surface of the hinge may be a key player in forming an optimal active site for phosphodiester bond formation between Watson-Crick base pairs.     

Fluorescence Resonance Energy Transfer Studies of DNA Polymerase β: THE CRITICAL ROLE OF FINGERS DOMAIN MOVEMENTS AND A NOVEL NON-COVALENT STEP DURING NUCLEOTIDE SELECTION*

During DNA repair, DNA polymerase β (Pol β) is a highly dynamic enzyme that is able to select the correct nucleotide opposite a templating base from a pool of four different deoxynucleoside triphosphates (dNTPs). To gain insight into nucleotide selection, we use a fluorescence resonance energy transfer (FRET)-based system to monitor movement of the Pol β fingers domain during catalysis in the presence of either correct or incorrect dNTPs. By labeling the fingers domain with ((((2-iodoacetyl)amino)ethyl)amino)naphthalene-1-sulfonic acid (IAEDANS) and the DNA substrate with Dabcyl, we are able to observe rapid fingers closing in the presence of correct dNTPs as the IAEDANS comes into contact with a Dabcyl-labeled, one-base gapped DNA. Our findings show that not only do the fingers close after binding to the correct dNTP, but that there is a second conformational change associated with a non-covalent step not previously reported for Pol β. Further analyses suggest that this conformational change corresponds to the binding of the catalytic metal into the polymerase active site. FRET studies with incorrect dNTP result in no changes in fluorescence, indicating that the fingers do not close in the presence of incorrect dNTP. Together, our results show that nucleotide selection initially occurs in an open fingers conformation and that the catalytic pathways of correct and incorrect dNTPs differ from each other. Overall, this study provides new insight into the mechanism of substrate choice by a polymerase that plays a critical role in maintaining genome stability.     

Loop II of DNA polymerase beta is important for discrimination during substrate binding

Loop II of DNA polymerase beta (pol β) consists of 14 amino acid residues and is highly flexible and solvent exposed. Previous research from our laboratory has shown that this loop is important for polymerase activity and fidelity. In the study presented here, we demonstrate that a shortened five amino acid residue loop compromises the fidelity of pol β. This five-residue loop, termed ENEYP, induces one base frameshift errors and A–C transversions within a specific sequence context. We demonstrate that ENEYP misincorporates dGTP opposite template A at higher efficiencies than wild-type pol β. The kinetic basis for misincorporation is a defect in discrimination of the correct from incorrect dNTP substrate at the level of ground-state binding. Our results are consistent with the idea that loop II of pol β functions to maintain accurate DNA synthesis by a direct or indirect influence on the nucleotide binding pocket.     

The E249K mutator mutant of DNA polymerase beta extends mispaired termini

The DNA polymerase beta mutant enzyme, which is altered from glutamic acid to lysine at position 249, exhibits a mutator phenotype in primer extension assays and in the herpes simplex virus-thymidine kinase (HSV-tk) forward mutation assay. The basis for this loss of accuracy was investigated by measurement of misincorporation fidelity in single turnover conditions. For the four misincorporation reactions investigated, the fidelity of the E249K mutant was not significantly different from wild type, implying that the mutator phenotype was not caused by a general inability to distinguish between correct and incorrect bases during the incorporation reaction. However, the discrimination between correct and incorrect substrates by the E249K enzyme occurred less during the conformational change and chemical steps and more during the initial binding step, compared with pol beta wild type. This implies that the E249K mutation alters the kinetic mechanism of nucleotide discrimination without reducing misincorporation fidelity. In a missing base primer extension assay, we observed that the mutant enzyme produced mispairs and extended them. This indicates that the altered fidelity of E249K could be due to loss of discrimination against mispaired primer termini. This was supported by the finding that the E249K enzyme extended a G:A mispair 8-fold more efficiently than wild type and a C:T mispair 4-fold more efficiently. These results demonstrate that an enhanced ability to extend mispairs can produce a mutator phenotype and that the Glu-249 side chain of DNA polymerase beta is critical for mispair extension fidelity.     

Involvement of phenylalanine 272 of DNA polymerase beta in discriminating between correct and incorrect deoxynucleoside triphosphates

DNA polymerase beta is a small monomeric polymerase that participates in base excision repair and meiosis [Sobol, R., et al. (1996) Nature 379, 183-186; Plug, A., et al. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 1327-1331]. A DNA polymerase beta mutator mutant, F272L, was identified by an in vivo genetic screen [Washington, S., et al. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 1321-1326]. Residue 272 is located within the deoxynucleoside triphosphate (dNTP) binding pocket of DNA polymerase beta according to the known DNA polymerase beta crystal structures [Pelletier, H., et al. (1994) Science 264, 1891-1893; Sawaya, M., et al. (1997) Biochemistry 36, 11205-11215]. The F272L mutant produces errors at a frequency 10-fold higher than that of wild type in vivo and in the in vitro HSV-tk gap-filling assay. F272L shows an increase in the frequency of both base substitution mutations and frameshift mutations. Single-enzyme turnover studies of misincorporation by wild type and F272L DNA polymerase beta demonstrate that there is a 4-fold decrease in fidelity of the mutant as compared to that of the wild type enzyme for a G:A mismatch. The decreased fidelity is due primarily to decreased discrimination between the correct and incorrect dNTP during ground-state binding. These results suggest that the phenylalanine 272 residue is critical for maintaining fidelity during the binding of the dNTP.     

A DNA polymerase beta mutator mutant with reduced nucleotide discrimination and increased protein stability

DNA polymerase beta (pol beta) offers a simple system to examine the role of polymerase structure in the fidelity of DNA synthesis. In this study, the M282L variant of pol beta (M282Lbeta) was identified using an in vivo genetic screen. Met282, which does not contact the DNA template or the incoming deoxynucleoside triphosphate (dNTP) substrate, is located on alpha-helix N of pol beta. This mutant enzyme demonstrates increased mutagenesis in both in vivo and in vitro assays. M282Lbeta has a 7.5-fold higher mutation frequency than wild-type pol beta; M282Lbeta commits a variety of base substitution and frameshift errors. Transient-state kinetic methods were used to investigate the mechanism of intrinsic mutator activity of M282Lbeta. Results show an 11-fold decrease in dNTP substrate discrimination at the level of ground-state binding. However, during the protein conformational change and/or phosphodiester bond formation, the nucleotide discrimination is improved. X-ray crystallography was utilized to gain insights into the structural basis of the decreased DNA synthesis fidelity. Most of the structural changes are localized to site 282 and the surrounding region in the C-terminal part of the 31-kDa domain. Repositioning of mostly hydrophobic amino acid residues in the core of the C-terminal portion generates a protein with enhanced stability. The combination of structural and equilibrium unfolding data suggests that the mechanism of nucleotide discrimination is possibly affected by the compacting of the hydrophobic core around residue Leu282. Subsequent movement of an adjacent surface residue, Arg283, produces a slight increase in volume of the pocket that may accommodate the incoming correct base pair. The structural changes of M282Lbeta ultimately lead to an overall reduction in polymerase fidelity.     

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.     

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.     

Site-specific labeling of T7 DNA polymerase with a conformationally sensitive fluorophore and its use in detecting single-nucleotide polymorphisms

Like most enzymes, DNA polymerases undergo a large conformational change on the binding of a correct nucleotide. To determine how the conformational change contributes to substrate specificity, we labeled the T7 DNA polymerase with a conformationally sensitive fluorophore at a position that provides a signal coincident with structural changes following nucleotide binding and distinguishes correct base pairs from incorrect ones by the sign of the fluorescence change. Here we describe methods to document that only one site on the polymerase was labeled with the fluorophore based on mass spectral analysis of tryptic peptides. In addition, we show by equilibrium titrations of opposing signals that mismatches and correct bases compete for the same site. This analysis forms an essential basis for characterization of a fluorescently labeled enzyme intended for mechanistic studies. Finally, we show that the labeled enzyme can be used to identify single-nucleotide mutations in a procedure that could be automated.     

Identification of small molecule synthetic inhibitors of DNA polymerase beta by NMR chemical shift mapping

DNA polymerase beta (beta-pol) plays a central role in repair of damaged DNA bases by base excision repair (BER) pathways. A predominant phenotype of beta-pol null mouse fibroblasts is hypersensitivity to the DNA-methylating agent methyl methanesulfonate. Residues in the 8-kDa domain of beta-pol that seem to interact with a known natural product beta-pol inhibitor, koetjapic acid, were identified by NMR chemical shift mapping. The data implicate the binding pocket as the hydrophobic cleft between helix-2 and helix-4, which provides the DNA binding and deoxyribose phosphate lyase activities of the enzyme. Nine structurally related synthetic compounds, containing aromatic or other hydrophobic groups in combination with two carboxylate groups, were then tested. They were found to bind to the same or a very similar region on the surface of the enzyme. The ability of these compounds to potentiate methyl methanesulfonate cytotoxicity, an indicator of cellular BER capacity, in wild-type and beta-pol null mouse fibroblasts, was next ascertained. The most active and beta-pol-specific of these agents, pamoic acid, was further characterized and found to be an inhibitor of the deoxyribose phosphate lyase and DNA polymerase activities of purified beta-pol on a BER substrate. Our results illustrate that NMR-based mapping techniques can be used in the design of small molecule enzyme inhibitors including those with potential use in a clinical setting.     

Structural design of a eukaryotic DNA repair polymerase: DNA polymerase beta

DNA polymerase beta, the smallest eukaryotic DNA polymerase, is designed to synthesize DNA in short DNA gaps during DNA repair. It is composed of two specialized domains that contribute essential enzymatic activities to base excision repair (BER). Its amino-terminal domain possesses a lyase activity necessary to remove the 5'-deoxyribose phosphate (dRP) intermediate generated during BER. Removal of the dRP moiety is often the rate-limiting step during BER. Failure to remove this group may initiate alternate BER pathways. The larger polymerase domain has nucleotidyl transferase activity. This domain has a modular organization with sub-domains that bind duplex DNA, catalytic metals, and the correct nucleoside triphosphate in a template-dependent manner. X-ray crystal structures of DNA polymerase beta, with and without bound substrates, has inferred that domain, sub-domain, and substrate conformational changes occur upon ligand binding. Many of these conformational changes are distinct from those observed in structures of other DNA polymerases. This review will examine the structural aspects of DNA polymerase beta that facilitate its role in BER.     

Pre-steady-state kinetic studies of the fidelity of Sulfolobus solfataricus P2 DNA polymerase IV

Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) is a thermostable archaeal enzyme and a member of the error-prone and lesion-bypass Y-family. In this paper, for the first time, the fidelity of a Y-family polymerase, Dpo4, was determined using pre-steady-state kinetic analysis of the incorporation of a single nucleotide into an undamaged DNA substrate 21/41-mer at 37 degrees C. We assessed single-turnover (with Dpo4 in molar excess over DNA) saturation kinetics for all 16 possible nucleotide incorporations. The fidelity of Dpo4 was estimated to be in the range of 10(-3)-10(-4). Interestingly, the ground-state binding affinity of correct nucleotides (70-230 microM) is 10-50-fold weaker than those of replicative DNA polymerases. Such a low affinity is consistent with the lack of interactions between Dpo4 and the bound nucleotides as revealed in the crystal structure of Dpo4, DNA, and a matched nucleotide. The affinity of incorrect nucleotides for Dpo4 is approximately 2-10-fold weaker than that of correct nucleotides. Intriguingly, the mismatched dCTP has an affinity similar to that of the matched nucleotides when it is incorporated against a pyrimidine template base flanked by a 5'-template guanine. The incoming dCTP likely skips the first available template base and base pairs with the 5'-template guanine, as observed in the crystal structure of Dpo4, DNA, and a mismatched nucleotide. The mismatch incorporation rates, regardless of the 5'-template base, were approximately 2-3 orders of magnitude slower than the incorporation rates for matched nucleotides, which is the predominant contribution to the fidelity of Dpo4.     

Conformational dynamics of DNA polymerase probed with a novel fluorescent DNA base analogue

DNA polymerases discriminate between correct and incorrect nucleotide substrates during a "nonchemical" step that precedes phosphodiester bond formation in the enzymatic cycle of nucleotide incorporation. Despite the importance of this process in polymerase fidelity, the precise nature of the molecular events involved remains unknown. Here we report a fluorescence resonance energy transfer (FRET) system that monitors conformational changes of a polymerase-DNA complex during selection and binding of nucleotide substrates. This system utilizes the fluorescent base analogue 1,3-diaza-2-oxophenothiazine (tC) as the FRET donor and Alexa-555 (A555) as the acceptor. The tC donor was incorporated within a model DNA primer/template in place of a normal base, adjacent to the primer 3' terminus, while the A555 acceptor was attached to an engineered cysteine residue (C751) located in the fingers subdomain of the Klenow fragment (KF) polymerase. The FRET efficiency increased significantly following binding of a correct nucleotide substrate to the KF-DNA complex, showing that the fingers had closed over the active site. Fluorescence anisotropy titrations utilizing tC as a reporter indicated that the DNA was more tightly bound by the polymerase under these conditions, consistent with the formation of a closed ternary complex. The rate of the nucleotide-induced conformational transition, measured in stopped-flow FRET experiments, closely matched the rate of correct nucleotide incorporation, measured in rapid quench-flow experiments, indicating that the conformational change was the rate-limiting step in the overall cycle of nucleotide incorporation for the labeled KF-DNA system. Taken together, these results indicate that the FRET system can be used to probe enzyme conformational changes that are linked to the biochemical function of DNA polymerase.     

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.     

Pre-steady-state kinetic studies of the fidelity and mechanism of polymerization catalyzed by truncated human DNA polymerase lambda

DNA polymerase lambda (Pollambda), a member of the X-family DNA polymerases, possesses an N-terminal BRCT domain, a proline-rich domain, and a C-terminal polymerase beta-like domain (tPollambda). In this paper, we determined a minimal kinetic mechanism and the fidelity of tPollambda using pre-steady-state kinetic analysis of the incorporation of a single nucleotide into a one-nucleotide gapped DNA substrate, 21-19/41-mer (primer-primer/template). Our kinetic studies revealed an incoming nucleotide bound to the enzyme.DNA binary complex at a rate constant of 1.55 x 10(8) M(-1) s(-1) to form a ground-state ternary complex while the nucleotide dissociated from this complex at a rate constant of 300 s(-1). Since DNA dissociation from tPollambda (0.8 s(-1)) was less than 3-fold slower than polymerization, we measured saturation kinetics for all 16 possible nucleotide incorporations under single turnover conditions to eliminate the complication resulting from multiple turnovers. The fidelity of tPollambda was estimated to be in the range of 10(-2)-10(-4) and was sequence-dependent. Surprisingly, the ground-state binding affinity of correct (1.1-2.4 microM) and incorrect nucleotides (1.4-8.4 microM) was very similar while correct nucleotides (3-6 s(-1)) were incorporated much faster than incorrect nucleotides (0.001-0.2 s(-1)). Interestingly, the misincorporation of dGTP opposite a template base thymine (0.2 s(-1)) was more rapid than all other misincorporations, leading to the lowest fidelity (3.2 x 10(-2)) among all mismatched base pairs. Additionally, tPollambda was found to possess weak strand-displacement activity during polymerization. These biochemical properties suggest that Pollambda likely fills short-patched DNA gaps in base excision repair pathways and participates in mammalian nonhomologous end-joining pathways to repair double-stranded DNA breaks.