Discrimination against the cytosine analog tC by Escherichia coli DNA polymerase IV DinB

The cytosine analog 1,3-diaza-2-oxophenothiazine (tC) is a fluorescent nucleotide that forms Watson-Crick base pairs with dG. The Klenow fragment of DNA polymerase I (an A-family polymerase) can efficiently bypass tC on the template strand and incorporate deoxyribose-triphosphate-tC into the growing primer terminus. Y-family DNA polymerases are known for their ability to accommodate bulky lesions and modified bases and to replicate beyond such nonstandard DNA structures in a process known as translesion synthesis. We probed the ability of the Escherichia coli Y-family DNA polymerase DinB (Pol IV) to copy DNA containing tC and to incorporate tC into a growing DNA strand. DinB selectively adds dGTP across from tC in template DNA but cannot extend beyond the newly formed G:tC base pair. However, we find that DinB incorporates the tC deoxyribonucleotide triphosphate opposite template G and extends from tC. Therefore, DinB displays asymmetry in terms of its ability to discriminate against the modification of the DNA template compared to the incoming nucleotide. In addition, our finding that DinB (a lesion-bypass DNA polymerase) specifically discriminates against tC in the template strand may suggest that DinB discriminates against template modifications in the major groove of DNA.     

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.     

Fluorescent properties of DNA base analogue tC upon incorporation into DNA--negligible influence of neighbouring bases on fluorescence quantum yield

The quantum yield of the fluorescent tricyclic cytosine analogue, 1,3-diaza-2-oxophenothiazine, tC, is high and virtually unaffected by incorporation into both single- and double-stranded DNA irrespective of neighbouring bases (0.17–0.24 and 0.16–0.21, respectively) and the corresponding fluorescence decay curves are all mono-exponential, properties that are unmatched by any base analogue so far. The fluorescence lifetimes increase when going from tC free in solution (3.2 ns) to single- and double-stranded DNA (on average 5.7 and 6.3 ns, respectively). The mono-exponential decays further support previous NMR results where it was found that tC has a well-defined position and geometry within the DNA helix. Furthermore, we find that the oxidation potential of tC is 0.4 V lower than for deoxyguanosine, the natural base with the lowest oxidation potential. This suggests that tC may be of interest in charge transfer studies in DNA as an electron hole acceptor. We also present a novel synthetic route to the phosphoramidite form of tC. The results presented here together with previous work show that tC is a very good C-analogue that induces minimal perturbation to the native structure of DNA. This makes tC unique as a fluorescent base analogue and is thus highly interesting in a range of applications for studying e.g. structure, dynamics and kinetics in nucleic acid systems.     

Effect of transition metal ions on the fluorescence and Taq-catalyzed polymerase chain reaction of tricyclic cytidine analogs

The cytosine analogs 1,3-diaza-2-oxophenothiazine (tC) and 1,3-diaza-2-oxophenoxazine (tCo) stand out among fluorescent bases due to their unquenched fluorescence emission in double-stranded DNA. Recently, we reported a method for the generation of densely tCo-labeled DNA by polymerase chain reaction (PCR) that relied on the use of the extremely thermostable Deep Vent polymerase. We have now developed a protocol that employs the more commonly used Taq polymerase. Supplementing the PCR with Mn²⁺ or Co²⁺ ions dramatically increased the amount of tCo triphosphate (dtCoTP) incorporated and, thus, enhanced the brightness of the PCR products. The resulting PCR products could be easily detected in gels based on their intrinsic fluorescence. The Mn²⁺ ions modulate the PCR by improving the bypass of template tCo and the overall catalytic efficiency. In contrast to the lower fidelity during tCo bypass, Mn²⁺ improved the ability of Taq polymerase to distinguish between dtCoTP and dTTP when copying a template dA. Interestingly, Mn²⁺ ions hardly affect the fluorescence emission of tC(o), whereas the coordination of Co²⁺ ions with the phosphate groups of DNA and nucleotides statically quenches tC(o) fluorescence with small reciprocal Stern–Vollmer constants of 10–300 μM.     

Synthesis and polymerase incorporation of 5'-amino-2',5'-dideoxy-5'-N-triphosphate nucleotides

Owing to the markedly increased reactivity of amino functional groups versus hydroxyls, the 5′-amino-5′-deoxy nucleoside and nucleotide analogs have proven widely useful in biological, pharmaceutical and genomic applications. However, synthetic procedures leading to these analogs have not been fully explored, which may possibly have limited the scope of their utility. Here we describe the synthesis of the 5′-amino-2′,5′-dideoxy analogs of adenosine, cytidine, guanosine, inosine and uridine from their respective naturally occurring nucleosides via the reduction of 5′-azido-2′,5′-dideoxy intermediates using the Staudinger reaction, and the high yield conversion of these modified nucleosides and 5′-amino-5′-deoxythymidine to the corresponding 5′-N-triphosphates through reaction with trisodium trimetaphosphate in the presence of tris(hydroxymethyl)aminomethane (Tris). We also show that each of these nucleotide analogs can be efficiently incorporated into DNA by the Klenow fragment of Escherichia coli DNA polymerase I when individually substituted for its naturally occurring counterpart. Mild acid treatment of the resulting DNA generates polynucleotide fragments that arise from specific cleavage at each modified nucleotide, providing a sequence ladder for each base. Because the ladders are generated after the extension, the corresponding products may be manipulated by enzymatic and/or purification processes. The potential utility of this extension–cleavage procedure in genomic sequence analysis is discussed.     

The properties of steric gate mutants reveal different constraints within the active sites of Y-family and A-family DNA polymerases

Y-family (lesion-bypass) DNA polymerases show the same overall structural features seen in other members of the polymerase superfamily, yet their active sites are more open, with fewer contacts to the DNA and nucleotide substrates. This raises the question of whether analogous active-site side chains play equivalent roles in the bypass polymerases and their classical DNA polymerase counterparts. In Klenow fragment, an A-family DNA polymerase, the steric gate side chain (Glu710) not only prevents ribonucleotide incorporation but also plays an important role in discrimination against purine-pyrimidine mispairs. In this work we show that the steric gate (Phe12) of the Y-family polymerase Dbh plays a very minor role in fidelity, despite its analogous role in sugar selection. Using ribonucleotide discrimination to report on the positioning of a mispaired dNTP, we found that the pyrimidine of a Pu-dPyTP nascent mispair occupies a similar position to that of a correctly paired dNTP in the Dbh active site, whereas in Klenow fragment the mispaired dNTP sits higher in the active site pocket. If purine-pyrimidine mispairs adopt the expected wobble geometry, the difference between the two polymerases can be attributed to the binding of the templating base, with the looser binding site of Dbh permitting a variety of template conformations with only minimal adjustment at the incoming dNTP. In Klenow fragment the templating base is more rigidly held, so that changes in base pair geometry would affect the dNTP position, allowing the Glu710 side chain to serve as a sensor of nascent mispairs.     

Incoming nucleotide binds to Klenow ternary complex leading to stable physical sequestration of preceding dNTP on DNA

Klenow–DNA complex is known to undergo a rate-limiting, protein conformational transition from an ‘open’ to ‘closed’ state, upon binding of the ‘correct’ dNTP at the active site. In the ‘closed’ state, Mg²⁺ mediates a rapid chemical step involving nucleophilic displacement of pyrophosphate by the 3′ hydroxyl of the primer terminus. The enzyme returns to the ‘open’ state upon the release of PPi and translocation permits the next round of reaction. To determine whether Klenow can translocate to the next site on the addition of the next dNTP, without the preceding chemical step, we studied the ternary complex (Klenow–DNA–dNTP) in the absence of Mg²⁺. While the ternary complex is proficient in chemical addition of dNTPs in Mg²⁺, as revealed by primer extensions, the same in Mg²⁺-deficient conditions lead to non-covalent (physical) sequestration of first two ‘correct’ dNTPs in the ternary complex. Moreover, the second dNTP traps the first one in the DNA-helix of the ternary complex. Such a dNTP–DNA complex is found to be stable even after the dissociation of Klenow. This reveals the novel state of the dNTP–DNA complex where the complementary base is stacked in a DNA-helix non-covalently, without the phosphodiester linkage. Further, shuttling of the DNA between the polymerase and the exonuclease site mediates the release of such a DNA complex. Interestingly, Klenow in such a Mg²⁺-deficient ternary complex exhibits a ‘closed’ conformation.     

Role of base stacking and sequence context in the inhibition of yeast DNA polymerase eta by pyrene nucleotide

The Y family DNA polymerase yeast pol eta inserts pyrene deoxyribose monophosphate (dPMP) in preference to A opposite an abasic site, the 3'-T of a thymine dimer, and a normal T with almost equal efficiency. In contrast, pol A family polymerases such as Klenow fragment and T7 DNA polymerase only insert dPMP efficiently opposite an abasic site and the 3'-T of a thymine dimer but not opposite undamaged DNA. Pyrene nucleotide is also an efficient chain-terminating inhibitor of DNA synthesis by pol eta but not by Klenow fragment or T7 DNA polymerase. To better understand the origin of the efficiency and sequence specificity of dPMP insertion by pol eta, the kinetics of dPMP insertion opposite various templates have been determined. In one sequence context, the efficiency of dPMP insertion increases 4.6-fold opposite G < A < T < C, suggesting that the templating nucleotide modulates dPMP insertion efficiency by having to destack prior to dPTP binding. The efficiency of insertion of dPMP opposite T in the same sequence context increases 7-fold for primers terminating in G < A < C < T and is similar to that observed for nontemplated blunt-end extension, suggesting that stacking interactions between the pyrene and the primer terminus are also important. On heterogeneous templates, the average selectivity for dPMP insertion relative to the complementary dNMP decreases in the order of dAMP > dGMP > dTMP > dCMP, from a high of 5.8 when dAMP is to be inserted following a T to a low of 0.5 when dCMP is to be inserted following a C. The relative preference for dPMP insertion at a given site can be largely explained by the energetic cost of destacking the templating base and stacking of pyrene nucleotide relative to that of stacking and base pairing the complementary nucleotide. Thus, pyrene nucleotide represents a novel class of nucleotide-based chain-terminating DNA synthesis inhibitors whose base portion consists of a hydrophobic, non-hydrogen bonding, base-pair mimic.     

Conformational Dynamics of DNA Repair by Escherichia coli Endonuclease III

Escherichia coli endonuclease III (Endo III or Nth) is a DNA glycosylase with a broad substrate specificity for oxidized or reduced pyrimidine bases. Endo III possesses two types of activities: N-glycosylase (hydrolysis of the N-glycosidic bond) and AP lyase (elimination of the 3′-phosphate of the AP-site). We report a pre-steady-state kinetic analysis of structural rearrangements of the DNA substrates and uncleavable ligands during their interaction with Endo III. Oligonucleotide duplexes containing 5,6-dihydrouracil, a natural abasic site, its tetrahydrofuran analog, and undamaged duplexes carried fluorescent DNA base analogs 2-aminopurine and 1,3-diaza-2-oxophenoxazine as environment-sensitive reporter groups. The results suggest that Endo III induces several fast sequential conformational changes in DNA during binding, lesion recognition, and adjustment to a catalytically competent conformation. A comparison of two fluorophores allowed us to distinguish between the events occurring in the damaged and undamaged DNA strand. Combining our data with the available structures of Endo III, we conclude that this glycosylase uses a multistep mechanism of damage recognition, which likely involves Gln⁴¹ and Leu⁸¹ as DNA lesion sensors.     

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

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

DNA polymerase catalysis in the absence of Watson-Crick hydrogen bonds: analysis by single-turnover kinetics

We report the first pre-steady-state kinetic studies of DNA replication in the absence of hydrogen bonds. We have used nonpolar nucleotide analogues that mimic the shape of a Watson-Crick base pair to investigate the kinetic consequences of a lack of hydrogen bonds in the polymerase reaction catalyzed by the Klenow fragment of DNA polymerase I from Escherichia coli. With a thymine isostere lacking hydrogen-bonding ability in the nascent pair, the efficiency (k(pol)/Kd) of the polymerase reaction is decreased by 30-fold, affecting the ground state (Kd) and transition state (k(pol)) approximately equally. When both thymine and adenine analogues in the nascent pair lack hydrogen-bonding ability, the efficiency of the polymerase reaction is decreased by about 1000-fold, with most of the decrease attributable to the transition state. Reactions using nonpolar analogues at the primer-terminal base pair demonstrated the requirement for a hydrogen bond between the polymerase and the minor groove of the primer-terminal base. The R668A mutation of Klenow fragment abolished this requirement, identifying R668 as the probable hydrogen-bond donor. Detailed examination of the kinetic data suggested that Klenow fragment has an extremely low tolerance of even minor deviations of the analogue base pairs from ideal Watson-Crick geometry. Consistent with this idea, some analogue pairings were better tolerated by Klenow fragment mutants having more spacious active sites. In contrast, the Y-family polymerase Dbh was much less sensitive to changes in base pair dimensions and more dependent upon hydrogen bonding between base-paired partners.     

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.     

DNA substrate structural requirements for the exonuclease and polymerase activities of procaryotic and phage DNA polymerases

A DNA duplex covalently cross-linked between specific bases has been prepared. This and similar duplexes are substrates for the polymerase and exonuclease activities of the Klenow fragment of Escherichia coli DNA polymerase I and T4 and T7 DNA polymerases. The action of Klenow fragment on these duplexes indicates that the polymerase site does not require that the DNA duplex undergo strand separation for activity, whereas the exonuclease site requires that at least four base pairs of the primer strand must melt out for the exonucleolytic removal of nucleotides from the primer terminus. The exonucleolytic action of T4 and T7 DNA polymerases requires that only two and three bases respectively melt out for excision of nucleotides from the primer terminus. Klenow fragment and T4 DNA polymerase are able to polymerize onto duplexes incapable of strand separation, whereas T7 DNA polymerase seems to require that the primer terminus be at least three bases from the cross-linked base pair. A DNA duplex with a biotin covalently linked to a specific base has been prepared. In the presence of the biotin binding protein avidin, the exonucleolytic activity of Klenow fragment requires that the primer terminus be at least 15 base pairs downstream from the base with the biotin-avidin complex. On the other hand, the polymerase activity of Klenow fragment required that the primer terminus be at least six base pairs downstream from the base with the biotin-avidin complex. These results suggest that the polymerase and exonuclease sites of Klenow are physically separate in solution and exhibit different substrate structural requirements for activity.     

Interaction of Escherichia coli DNA polymerase I with azidoDNA and fluorescent DNA probes: identification of protein-DNA contacts

The synthesis of an azidoDNA duplex and its use to photolabel DNA polymerases have been previously described (Gibson & Benkovic, 1987). We now present detailed experiments utilizing this azidoDNA photoprobe as a substrate for Escherichia coli DNA polymerase I (Klenow fragment) and the photoaffinity labeling of the protein. The azidoDNA duplex is an efficient substrate for both the polymerase and 3'----5' exonuclease activities of the enzyme. However, the hydrolytic degradation of the azido-bearing base is dramatically impaired. On the basis of the ability of these duplexes to photolabel the enzyme, we have determined that the protein contacts between five and seven bases of duplex DNA. Incubation of azidoDNA with the Klenow fragment in the presence of magnesium results in the in situ formation of a template-primer with the azido-bearing base bound at the polymerase catalytic site of the enzyme. Photolysis of this complex followed by proteolytic digestion and isolation of DNA-labeled peptides results in the identification of a single residue modified by the photoreactive DNA substrate. We identify Tyr766 as the modified amino acid and thus localize the catalytic site for polymerization in the protein. A mansyl-labeled DNA duplex has been prepared as a fluorescent probe of protein structure. This has been utilized to determine the location of the primer terminus when bound to the Klenow fragment. When the duplex contains five unpaired bases in the primer strand of the duplex, the primer terminus resides predominantly at the exonuclease catalytic site of the enzyme. Removal of the mismatched bases by the exonuclease activity of the enzyme yields a binary complex with the primer terminus now bound predominantly at the polymerase active site. Data are presented which suggest that the rate-limiting step in the exonuclease activity of the enzyme is translocation of the primer terminus from polymerase to exonuclease catalytic sites.     

Insights into the Conformation of Aminofluorene-Deoxyguanine Adduct in a DNA Polymerase Active Site

The active site conformation of the mutagenic fluoroaminofluorene-deoxyguanine adduct (dG-FAF, N-(2′-deoxyguanosin-8-yl)-7-fluoro-2-aminofluorene) has been investigated in the presence of Klenow fragment of Escherichia coli DNA polymerase I (Kfexo⁻) and DNA polymerase β (pol β) using ¹⁹F NMR, insertion assay, and surface plasmon resonance. In a single nucleotide gap, the dG-FAF adduct adopts both a major-groove- oriented and base-displaced stacked conformation, and this heterogeneity is retained upon binding pol β. The addition of a non-hydrolysable 2′-deoxycytosine-5′-[(α,β)-methyleno]triphosphate (dCMPcPP) nucleotide analog to the binary complex results in an increase of the major groove conformation of the adduct at the expense of the stacked conformation. Similar results were obtained with the addition of an incorrect dAMPcPP analog but with formation of the minor groove binding conformer. In contrast, dG-FAF adduct at the replication fork for the Kfexo⁻ complex adopts a mix of the major and minor groove conformers with minimal effect upon the addition of non-hydrolysable nucleotides. For pol β, the insertion of dCTP was preferred opposite the dG-FAF adduct in a single nucleotide gap assay consistent with ¹⁹F NMR data. Surface plasmon resonance binding kinetics revealed that pol β binds tightly with DNA in the presence of correct dCTP, but the adduct weakens binding with no nucleotide specificity. These results provide molecular insights into the DNA binding characteristics of FAF in the active site of DNA polymerases and the role of DNA structure and sequence on its coding potential.     

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

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

In vitro synthesis of uniform poly(dG)-poly(dC) by Klenow exo- fragment of polymerase I

In this paper, we describe a production procedure of the one-to-one double helical complex of poly(dG)–poly(dC), characterized by a well-defined length (up to 10 kb) and narrow size distribution of molecules. Direct evidence of strands slippage during poly(dG)–poly(dC) synthesis by Klenow exo⁻ fragment of polymerase I is obtained by fluorescence resonance energy transfer (FRET). We show that the polymer extension results in an increase in the separation distance between fluorescent dyes attached to 5′ ends of the strands in time and, as a result, losing communication between the dyes via FRET. Analysis of the products of the early steps of the synthesis by high-performance liquid chromatography and mass spectroscopy suggest that only one nucleotide is added to each of the strand composing poly(dG)–poly(dC) in the elementary step of the polymer extension. We show that proper pairing of a base at the 3′ end of the primer strand with a base in sequence of the template strand is required for initiation of the synthesis. If the 3′ end nucleotide in either poly(dG) or poly(dC) strand is substituted for A, the polymer does not grow. Introduction of the T-nucleotide into the complementary strand to permit pairing with A-nucleotide results in the restoration of the synthesis. The data reported here correspond with a slippage model of replication, which includes the formation of loops on the 3′ ends of both strands composing poly(dG)–poly(dC) and their migration over long-molecular distances (μm) to 5′ ends of the strands.     

Methylglyoxal, an endogenous aldehyde, crosslinks DNA polymerase and the substrate DNA

Methylglyoxal, a known endogenous and environmental mutagen, is a reactive α-ketoaldehyde that can modify both DNA and proteins. To investigate the possibility that methylglyoxal induces a crosslink between DNA and DNA polymerase, we treated a ‘primed template’ DNA and the exonuclease-deficient Klenow fragment (KF^exo–) of DNA polymerase I with methylglyoxal in vitro. When the reaction mixtures were analyzed by SDS–PAGE, we found that methylglyoxal induced a DNA–KF^exo– crosslink. The specific binding complex of KF^exo– and ‘primed template’ DNA was necessary for formation of the DNA–KF^exo– crosslink. Methylglyoxal reacted with guanine residues in the single-stranded portion of the template DNA. When 2′-deoxyguanosine was incubated with Nα-acetyllysine or N-acetylcysteine in the presence of methylglyoxal, a crosslinked product was formed. No other amino acid derivatives tested could generate a crosslinked product. These results suggest that methylglyoxal crosslinks a guanine residue of the substrate DNA and lysine and cysteine residues near the binding site of the DNA polymerase during DNA synthesis and that DNA replication is severely inhibited by the methylglyoxal-induced DNA–DNA polymerase crosslink.