Analysis of non-template-directed nucleotide addition and template switching by DNA polymerase

DNA polymerases use an uninterrupted template strand to direct synthesis of DNA. However, some DNA polymerases can synthesize DNA across two discontinuous templates by binding and juxtaposing them, resulting in synthesis across the junction. Primer/template duplexes with 3' overhangs are especially efficient substrates, suggesting that DNA polymerases use the overhangs as regions of microhomology for template synapsis. The formation of these overhangs may be the result of non-template-directed nucleotide addition by DNA polymerases. To examine the relative magnitude and mechanism of template switching, we studied the in vitro enzyme kinetics of template switching and non-template-directed nucleotide addition by the 3'-5' exonuclease-deficient large fragment of Escherichia coli DNA polymerase I. Non-template-directed nucleotide addition and template switching were compared to that of standard primer extension. We found that non-template-directed nucleotide addition and template switching showed similar rates and were approximately 100-fold slower than normal template-directed DNA synthesis. Furthermore, non-template-directed nucleotide addition showed a 10-fold preference for adding dAMP to the ends of DNA over that of the other three nucleotides. For template switching, kinetic analysis revealed that the two template substrates acted as a random bireactant system with mixed-type inhibition of substrate binding by one substrate over the other. These data are the first to establish the binding kinetics of two discontinuous DNA substrates to a single DNA polymerase. Our results suggest that although the activities are relatively weak, non-template-directed nucleotide addition and template switching allow DNA polymerases to overcome breaks in the template strand in an error-prone manner.     

A primer-dependent polymerase function of pseudomonas aeruginosa ATP-dependent DNA ligase (LigD)

Pseudomonas aeruginosa encodes two putative DNA ligases: a classical NAD(+)-dependent DNA ligase (LigA) plus an ATP-dependent DNA ligase (LigD). LigD exemplifies a family of bacterial proteins that consist of a ligase domain fused to flanking domains that resemble nucleases and/or polymerases. Here we purify LigD and show that it possesses an intrinsic polymerase function resident within an autonomous C-terminal polymerase domain, LigD-(533-840), that flanks an autonomous DNA ligase domain, LigD-(188-527). Native LigD and the polymerase domain are both monomeric proteins. The polymerase activity is manifest in three ways: (i) non-templated nucleotide addition to a blunt-ended duplex DNA primer; (ii) non-templated addition to a single-stranded DNA primer; and (iii) templated extension of a 5'-tailed duplex DNA primer-template. The divalent cation cofactor requirement for non-templated and templated polymerase activity is satisfied by manganese or cobalt. rNTPs are preferred over dNTPs as substrates for non-templated blunt-end addition, which typically entails the incorporation of only 1 or 2 nucleotides at the primer terminus. Templated dNMP addition to a 5'-tailed substrate is efficient with respect to dNTP utilization; the primer is elongated to the end of the template strand and is then further extended with a non-templated nucleotide. The polymerase activity is abolished by alanine substitution for two aspartates (Asp-669 and Asp-671) within the putative metal-binding site. We speculate that polymerase activity is relevant to LigD function in nonhomologous end-joining.     

Effectiveness of complex-formation of nucleotides with human DNA polymerase alpha from data of enzyme modification by reactive nucleotide analogs

The modification of the human placenta DNA polymerase alpha by the imidazolides of dNMP was investigated. The modification was shown to occur only in the simultaneous presence of the template and the primer. This process, however, doesn't depend on the complementary interaction of the nucleotide base with the template. The Kd values of the complexes between the different nucleotides and DNA polymerase alpha were estimated. The affinity of Im-dTMP was determined from the dependence of the Kapp of the enzyme inactivation rate on the reagent concentration. The Kd values for dNMP, dNDP, dNTP were estimated using the protective effect of these nucleotides under the enzyme modification by Im-dTMP. The comparison of the interaction efficiency between the polymerase and dNMP, dNDP, dNTP (complementary or non-complementary to the template) allow to conclude that the nucleotide discrimination occurs on the dNTP level, i. e. dNMP and dNDP upon forming the complex with the enzyme, don't interact complementarily with the template. The additional contacts between the enzyme and the nucleotide terminal phosphate were supposed to form only for the complementary dNTP. The studies allowed to put forward a hypothetical model of the template complementary dNTP binding to the polymerases. The role of the hydrophobic interaction of the nucleotides with the enzyme as well as the possible influence of the nucleotide gamma-phosphate group on the template--dNTP complement formation. The Watson-Crick bound formation of the nucleotide with the template was supposed to be followed by the additional conformational rearrangement of the nucleotide triphosphate chain. The latter process leads to the formation of additional contacts between the enzyme and the nucleotide gamma-phosphate.     

Simple, efficient protocol for enzymatic synthesis of uniformly 13C, 15N-labeled DNA for heteronuclear NMR studies.

The use of uniformly 13C,15N-labeled RNA has greatly facilitated structural studies of RNA oligonucleotides by NMR. Application of similar methodologies for the study of DNA has been limited, primarily due to the lack of adequate methods for sample preparation. Methods for both chemical and enzymatic synthesis of DNA oligonucleotides uniformly labeled with 13C and/or 15N have been published, but have not yet been widely used. We have developed a modified procedure for preparing uniformly 13C,15N-labeled DNA based on enzymatic synthesis using Taq DNA polymerase. The highly efficient protocol results in quantitative polymerization of the template and approximately 80% incorporation of the labeled dNTPs. Procedures for avoiding non-templated addition of nucleotides or for their removal are given. The method has been used to synthesize several DNA oligonucleotides, including two complementary 15 base strands, a 32 base DNA oligonucleotide that folds to form an intramolecular triplex and a 12 base oligonucleotide that dimerizes and folds to form a quadruplex. Heteronuclear NMR spectra of the samples illustrate the quality of the labeled DNA obtained by these procedures.     

Kinetic analysis of base substitution mutagenesis by transient misalignment of DNA and by miscoding

We measured the insertion fidelity of DNA polymerases alpha and beta and yeast DNA polymerase I at a template site that was previously observed to yield a high frequency of T----G transversions when copied by DNA polymerase beta but not by the other two polymerases. The results provide direct biochemical evidence that base substitution errors by DNA polymerase beta can result from a dislocation mechanism governed by DNA template-primer misalignment. In contrast to DNA polymerase beta, neither Drosophila DNA polymerase alpha nor yeast DNA polymerase I appear to misinsert nucleotides by a dislocation mechanism in either the genetic or kinetic fidelity assays. Dislocation errors by DNA polymerase beta are characterized primarily by a substantial reduction in the apparent Km for inserting a "correct," but ultimately errant, nucleotide compared to the apparent Km governing direct misinsertion. For synthesis by DNA polymerase beta, dislocation results in a 35-fold increase in dCMP incorporation opposite template T (T----G transversion) and a 20-35-fold increase in dTMP incorporation opposite T (T----A transversion); these results are consistent with parallel genetic fidelity measurements. DNA polymerase beta also produces base substitution errors by direct misinsertion. Here nucleotide insertion fidelity results from substantial differences in both Km and Vmax for correct versus incorrect substrates and is influenced strongly by local base sequence.     

Real-time single-molecule studies of the motions of DNA polymerase fingers illuminate DNA synthesis mechanisms

DNA polymerases maintain genomic integrity by copying DNA with high fidelity. A conformational change important for fidelity is the motion of the polymerase fingers subdomain from an open to a closed conformation upon binding of a complementary nucleotide. We previously employed intra-protein single-molecule FRET on diffusing molecules to observe fingers conformations in polymerase–DNA complexes. Here, we used the same FRET ruler on surface-immobilized complexes to observe fingers-opening and closing of individual polymerase molecules in real time. Our results revealed the presence of intrinsic dynamics in the binary complex, characterized by slow fingers-closing and fast fingers-opening. When binary complexes were incubated with increasing concentrations of complementary nucleotide, the fingers-closing rate increased, strongly supporting an induced-fit model for nucleotide recognition. Meanwhile, the opening rate in ternary complexes with complementary nucleotide was 6 s⁻¹, much slower than either fingers closing or the rate-limiting step in the forward direction; this rate balance ensures that, after nucleotide binding and fingers-closing, nucleotide incorporation is overwhelmingly likely to occur. Our results for ternary complexes with a non-complementary dNTP confirmed the presence of a state corresponding to partially closed fingers and suggested a radically different rate balance regarding fingers transitions, which allows polymerase to achieve high fidelity.     

Effect of oxidatively damaged DNA on the active site preorganization during nucleotide incorporation in a high fidelity polymerase from Bacillus stearothermophilus

We study the effect of the oxidative lesion 8-oxoguanine (8oxoG) on the preorganization of the active site for DNA replication in the closed (active) state of the Bacillus fragment (BF), a Klenow analog from Bacillus stearothermophilus. Our molecular dynamics and free energy simulations of explicitly solvated model ternary complexes of BF bound to correct dCTP/incorrect dATP opposite guanine (G) and 8oxoG bases in DNA suggest that the lesion introduces structural and energetic changes at the catalytic site to favor dATP insertion. Despite the formation of a stable Watson-Crick pairing in the 8oxoG:dCTP system, the catalytic geometry is severely distorted to possibly slow down catalysis. Indeed, our calculated free energy landscapes associated with active site preorganization suggest additional barriers to assemble an efficient catalytic site, which need to be overcome during dCTP incorporation opposite 8oxoG relative to that opposite undamaged G. In contrast, the catalytic geometry for the Hoogsteen pairing in the 8oxoG:dATP system is highly organized and poised for efficient nucleotide incorporation via the "two-metal-ion" catalyzed phosphoryl transfer mechanism. However, the free energy calculations suggest that the catalytic geometry during dATP incorporation opposite 8oxoG is considerably less plastic than that during dCTP incorporation opposite G despite a very similar, well organized catalytic site for both systems. A correlation analysis of the dynamics trajectories suggests the presence of significant coupling between motions of the polymerase fingers and the primary distance for nucleophilic attack (i.e., between the terminal primer O3' and the dNTP P(alpha.) atoms) during correct dCTP incorporation opposite undamaged G. This coupling is shown to be disrupted during nucleotide incorporation by the polymerase with oxidatively damaged DNA/dNTP substrates. We also suggest that the lesion affects DNA interactions with key polymerase residues, thereby affecting the enzymes ability to discriminate against non-complementary DNA/dNTP substrates. Taken together, our results provide a unified structural, energetic, and dynamic platform to rationalize experimentally observed relative nucleotide incorporation rates for correct dCTP/incorrect dATP insertion opposite an undamaged/oxidatively damaged template G by BF.     

Using 2-aminopurine fluorescence to detect base unstacking in the template strand during nucleotide incorporation by the bacteriophage T4 DNA polymerase

The fluorescence of the base analogue 2-aminopurine (2AP) was used to detect physical changes in the template strand during nucleotide incorporation by the bacteriophage T4 DNA polymerase. Fluorescent enzyme-DNA complexes were formed with 2AP placed in the template strand opposite the primer terminus (the n position) and placed one template position 5' to the primer terminus (the n + 1 position). The fluorescence enhancement for 2AP at the n position was shown to be due to formation of the editing complex, which indicates that the 2AP-T terminal base pair is recognized primarily as a mismatch. 2AP fluorescence at the n + 1 position, however, was a reporter for DNA interactions in the polymerase active center that induce intrastrand base unstacking. T4 DNA polymerase produced base unstacking at the n + 1 position following formation of the phosphodiester bond. Thus, the increase in fluorescence intensity for 2AP at the n + 1 position could be used to measure the nucleotide incorporation rate in primer extension reactions in which 2AP was placed initially at the n + 2 position. Primer extension occurred at the rate of about 314 s(-1). The amount of base unstacking at the template n + 1 position was sensitive to the local DNA sequence. More base unstacking was detected for DNA substrates with an A-T base pair at the primer terminus compared to C-G or G-C base pairs. Since proofreading is also increased by A-T base pairs compared to G-C base pairs at the primer terminus, we propose that base unstacking may provide an opportunity for the DNA polymerase to reexamine the primer terminus.     

DNA synthesis with methylated poly(dC-dG) templates. Evidence for a competitive nature to miscoding by O(6)-methylguanine.

The alternating copolymer poly(dC-dG) has been methylated with either dimethyl sulphate or N-methyl-N-nitrosourea and the levels of the various methylation products determined. In addition to the 3-methylcytosine, 3-methylguanine and 7-methylguanine (produced by both agents) reaction with N-methyl-N-nitrosourea also yielded easily detectable amounts of O(6)-methylguanine and phosphotriesters. These methylated polymers were then used as templates in an in vitro assay with Escherichia coli DNA polymerase I measuring the incorporation of complementary (dCMP and dGMP) and noncomplementary (dAMP and dTMP) nucleotides. When the dimethyl sulphate-methylated polymer was used as template there was virtually no detectable incorporation of non-complementary nucleotides indicating that no miscoding could be attributed to the presence of 3-methylcytosine, 3-methylguanine or 7-methylguanine. However, when the N-methyl-N-nitrosourea-methylated polymer was used as template there was a specific incorporation of dTMP but not of dAMP. The amount of dTMP incorporated was always less than the level of O(6)-methylguanine in the template and was found to vary with the relative concentrations of the deoxynucleoside 5'-triphosphates in the assay. As the amount of dCTP present in the assay was decreased the wrong incorporation of dTMP increased and approached the level that would have been expected for a one-to-one miscoding by O(6)-methylguanine as the concentration of dCTP approached zero. The results indicate that O(6)-methylguanine is capable of miscoding with a DNA polymerase but the miscoding is competitive with the normal incorporation of dCMP: when the 5'-triphosphate precursors are present in equal amounts approximately one O(6)-methylguanine in three miscodes leading to the incorporation of dTMP.     

Structural basis for a novel mechanism of DNA bridging and alignment in eukaryotic DSB DNA repair

Eukaryotic DNA polymerase mu of the PolX family can promote the association of the two 3′‐protruding ends of a DNA double‐strand break (DSB) being repaired (DNA synapsis) even in the absence of the core non‐homologous end‐joining (NHEJ) machinery. Here, we show that terminal deoxynucleotidyltransferase (TdT), a closely related PolX involved in V(D)J recombination, has the same property. We solved its crystal structure with an annealed DNA synapsis containing one micro‐homology (MH) base pair and one nascent base pair. This structure reveals how the N‐terminal domain and Loop 1 of Tdt cooperate for bridging the two DNA ends, providing a templating base in trans and limiting the MH search region to only two base pairs. A network of ordered water molecules is proposed to assist the incorporation of any nucleotide independently of the in trans templating base. These data are consistent with a recent model that explains the statistics of sequences synthesized in vivo by Tdt based solely on this dinucleotide step. Site‐directed mutagenesis and functional tests suggest that this structural model is also valid for Pol mu during NHEJ.     

Effect of double-strand break DNA sequence on the PARP-1 NHEJ pathway

Efficient repair of DNA double-strand breaks (DSBs) is critical for the maintenance of genomic integrity. In mammalian cells, DSBs are preferentially repaired by non-homologous end-joining (NHEJ). We have previously described a new DSBs microhomology end-joining pathway depending on PARP-1 and the XRCC1/DNA ligase III complex. In this study we analysed, with recombinant proteins and protein extracts, the effect of DSB end sequences: (i) on the DSB synapsis activity; (ii) on the end-joining activity. We report that PARP-1 DSB synapsis activity is independent of the DSB sequence and could be detected with non-complementary DSBs. We demonstrate also that the efficiency of DSBs repair by PARP-1 NHEJ is strongly dependent on the presence of G:C base pairs at microhomology termini. These results highlight a new role of the PARP-1 protein on the synapsis of DSBs and could explain why the PARP-1 NHEJ pathway is strongly dependent on the DSBs microhomology sequence.     

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.     

Model for forward polymerization and switching transition between polymerase and exonuclease sites by DNA polymerase molecular motors

Based on the available crystal structure a model is presented for the polymerization activity and switching transition between polymerase and exonuclease sites of a DNA polymerase molecular motor. Using the model, the fast polymerization rate for correctly base-paired DNA and much reduced polymerization rate after an incorporation of a mismatched base can be well explained. The dependences of the polymerization rate and exonuclease rate on mechanical tension acting on the DNA template are studied. The switching rates between the two sites are analyzed. All the results show good quantitative agreement with the available experimental results.     

Snapshots of a Y-family DNA polymerase in replication: substrate-induced conformational transitions and implications for fidelity of Dpo4

Y-family DNA polymerases catalyze translesion DNA synthesis over damaged DNA. Each Y-family polymerase has a polymerase core consisting of a palm, finger and thumb domain in addition to a fourth domain known as a little finger domain. It is unclear how each domain moves during nucleotide incorporation and what type of conformational changes corresponds to the rate-limiting step previously reported in kinetic studies. Here, we present three crystal structures of the prototype Y-family polymerase: apo-Dpo4 at 1.9 Å resolution, Dpo4-DNA binary complex and Dpo4-DNA-dTMP ternary complex at 2.2 Å resolution. Dpo4 undergoes dramatic conformational changes from the apo to the binary structures with a 131° rotation of the little finger domain relative to the polymerase core upon DNA binding. This DNA-induced conformational change is verified in solution by our tryptophan fluorescence studies. In contrast, the polymerase core retains the same conformation in all three conformationally distinct states. Particularly, the finger domain which is responsible for checking base pairing between the template base and an incoming nucleotide retains a rigid conformation. The inflexibility of the polymerase core likely contributes to the low fidelity of Dpo4, in addition to its loose and solvent-accessible active site. Interestingly, while the binary and ternary complexes of Dpo4 retain an identical global conformation, the aromatic side chains of two conserved tyrosines at the nucleotide-binding site change orientations between the binary and ternary structures. Such local conformational changes may correspond to the rate-limiting step in the mechanism of nucleotide incorporation. Together, the global and local conformational transitions observed in our study provide a structural basis for the distinct kinetic steps of a catalytic cycle of DNA polymerization performed by a Y-family polymerase.     

Avian myeloblastosis virus DNA polymerase. Kinetic studies on the incorporation of noncomplementary nucleotides.

The high error rate characteristic of DNA polymerases from RNA tumor viruses has permitted measurements on the simultaneous incorporation of complementary and noncomplementary nucleotides during DNA synthesis. For example, avian myeloblastosis virus DNA polymerase incorporates 1 molecule of dCMP for approximately 500 molecules of dTMP polymerized using polyriboadenylic acid as a template. The parallel incorporation of complementary and noncomplementary nucleotides afer gel filtration of avian myeloblastosis virus DNA polymerase indicates that the observed fidelity is catalyzed by the polymerase itself. Nearest neighbor analysis of the product indicates that noncomplementary nucleotides are incorporated as single base substitutions. The incorporation of the noncomplementary dCMP is not reduced by a 20-fold greater amount of the complementary nucleotide, dTTP. Conversely, the concentration of the noncomplementary nucleotides does not effect the rate of incorporation of the complementary nucleotide. A similar lack of competition between complementary dGTP and noncomplementary dATP is exhibited using poly(rC)-oligo(dG) as a template-primer. Furthermore, there was no detectable competition between the different noncomplementary nucleotides. Possible explanations for this lack of competition are considered.     

Recognition and binding of template-primers containing defined abasic sites by Drosophila DNA polymerase alpha holoenzyme

Human DNA polymerase alpha holoenzyme follows an ordered sequential terreactant mechanism of substrate recognition and binding (Wong, S. W., Paborsky, L. R., Fisher, P. A., Wang, T. S.-F., and Korn, D. (1986) J. Biol. Chem. 261, 7958-7968). We confirmed this mechanism for the DNA polymerase alpha holoenzyme purified from Drosophila melanogaster embryos and studied the interaction of Drosophila pol alpha with synthetic oligonucleotide template-primers containing modified tetrahydrofuran moieties as model abasic lesions chemically engineered at a number of defined sites. Abasic lesions in the template had relatively little effect on the polymerase incorporation reaction at sites proximal to the lesion. However, incorporation opposite an abasic site was undetectable relative to that which occurred opposite a normal template nucleotide. Moreover, abasic residues in the primer region of the template-primer construct as far as 4 base pairs removed from the 3'-primer terminus prevented detectable nucleotide incorporation relative to that seen on an unmodified template-primer. Primer-region lesions had qualitatively similar effects whether they were located on the primer strand itself or on the complementary template strand. Data from polymerase incorporation experiments were corroborated by competitive binding assays performed under steady state reaction conditions. Results of these experiments suggested that polymerase binding to synthetic oligonucleotide template-primers was essentially unaffected by lesions located at sites that did not block incorporation. Lesions that did block incorporation apparently did so by abrogating template-primer binding. These observations have implications for understanding the mechanisms whereby DNA polymerase alpha recognizes noninformational template sites in vivo and prevents DNA synthesis from proceeding past these points.     

Spectroscopic analysis of polymerization and exonuclease proofreading by a high-fidelity DNA polymerase during translesion DNA synthesis

High fidelity DNA polymerases maintain genomic fidelity through a series of kinetic steps that include nucleotide binding, conformational changes, phosphoryl transfer, polymerase translocation, and nucleotide excision. Developing a comprehensive understanding of how these steps are coordinated during correct and pro-mutagenic DNA synthesis has been hindered due to lack of spectroscopic nucleotides that function as efficient polymerase substrates. This report describes the application of a non-natural nucleotide designated 5-naphthyl-indole-2′-deoxyribose triphosphate which behaves as a fluorogenic substrate to monitor nucleotide incorporation and excision during the replication of normal DNA versus two distinct DNA lesions (cyclobutane thymine dimer and an abasic site). Transient fluorescence and rapid-chemical quench experiments demonstrate that the rate constants for nucleotide incorporation vary as a function of DNA lesion. These differences indicate that the non-natural nucleotide can function as a spectroscopic probe to distinguish between normal versus translesion DNA synthesis. Studies using wild-type DNA polymerase reveal the presence of a fluorescence recovery phase that corresponds to the formation of a pre-excision complex that precedes hydrolytic excision of the non-natural nucleotide. Rate constants for the formation of this pre-excision complex are dependent upon the DNA lesion, and this suggests that the mechanism of exonuclease proofreading is regulated by the nature of the formed mispair. Finally, spectroscopic evidence confirms that exonuclease proofreading competes with polymerase translocation. Collectively, this work provides the first demonstration for a non-natural nucleotide that functions as a spectroscopic probe to study the coordinated efforts of polymerization and exonuclease proofreading during correct and translesion DNA synthesis.