Mechanism of DNA cleavage and substrate recognition by a bovine apurinic endonuclease

The location of the phosphodiester bond cleaved by homogeneous Mg2+-dependent apurinic endodeoxyribonuclease (EC 3.1.25.2; APE) of bovine calf thymus has been determined by using a 21-mer oligonucleotide containing a single central apurinic site as a substrate. A single product of cleavage consistent with cleavage of the oligonucleotide 5' to the apurinic site, and leaving a 3' hydroxyl group, was identified. This enzyme is, therefore, a class II apurinic endonuclease. The substrate specificities of this enzyme have been determined by using a variety of natural and synthetic DNAs or oligonucleotides containing base-free sites. Calf thymus APE has an absolute requirement for a double-stranded DNA and requires an abasic site as a substrate. The presence of a base fragment such as a urea residue, an alkoxyamine group attached to the C'-1 position of the abasic site, or reduction of the C'-1 aldehyde abolishes the APE activity of this enzyme. Synthetic abasic sites containing either ethylene glycol, propanediol, or tetrahydrofuran interphosphate linkages are excellent substrates for bovine APE. These results indicate that APE has no absolute requirement for either ring-opened or ring-closed deoxyribose moieties in its recognition of DNA-cleavage substrates. The enzyme may interact with the pocket in duplex DNA that results from the base loss or with the altered conformations of the phosphodiester backbone that result from the abasic site.     

Effect of lesions on the dynamics of DNA on the picosecond and nanosecond timescales using a polarity sensitive probe

This paper explores the effects of structural modifications on the fast dynamics of DNA and the ability of time-resolved Stokes shift spectroscopy to measure those changes. The time-resolved Stokes shift of a synthetic coumarin base-pair replacement within an oligomer is measured between 40 ps and 40 ns. Comparisons are made between 17mers without modification, with a deleted base near the coumarin and with the coumarin placed near the end of the oligomer. The deletion of a next-to-nearest-neighbor base pair does not change the subnanosecond dynamics, but does cause an additional motion with a time constant of ~20 ns. A candidate for this motion is the flipping of the abasic sugar out of the helix and the concomitant intrusion of water into the interior of the helix. A nearby chain end causes little change in the dynamics after 1 ns but leads to a reduction in the amplitude of the dynamics between 40 ps and 1 ns. We suggest that at the chain end, where DNA on one side of the probe has been replaced by water, the charge- stabilizing dynamics have the same overall amplitude, but that much of the relaxation occurs before the start of the measurement time window.     

Interaction of a spin-labeled adenine-acridine conjugate with a DNA duplex containing an abasic site model

The abasic site is a common lesion in DNA that is also formed as an intermediate in the base excision repair of damaged bases. We have previously reported the adenine-acridine conjugate 1 that was designed to bind to the abasic site and interfere with the repair process. High-field NMR had shown that 1 forms specific complexes with a DNA duplex containing an apurinic abasic site model. We report here the dynamics of the interaction of the nitroxide-labeled analogue 3 of the conjugate 1 with the same apurinic oligonucleotide and with the parent unmodified duplex. Identical study of the labeled acridine subunit 5 used as a reference is also reported. In the presence of the apurinic duplex and depending on the concentrations and drug ratios, three species are observed: the radical "free in solution", the "intercalation" complex characterized by its similarity to that observed in the presence of the parent unmodified duplex, and the "abasic-site-specific" complex which is the sole species visible at low drug ratios. The experimental data reinforced by molecular modeling of the complex and theoretical calculation of correlation times suggest (i) the most immobilized form corresponds to that observed by NMR and (ii) complexation of the drug is little or not modified by the spin-label. We also show that the abasic site constitutes a binding site for the propylaminoacridine intercalator 5.     

Manganese substantially alters the dynamics of translesion DNA synthesis

The effect of metal ion substitution on the dynamics of translesion DNA synthesis catalyzed by the bacteriophage T4 DNA polymerase was quantitatively evaluated through steady-state and transient kinetic techniques. Substitution of Mn(2+) for Mg(2+) enhances the steady-state rate of dNMP misinsertion opposite an abasic site by 11-34-fold. At the molecular level, the enhancement in translesion DNA synthesis reflects a substantial increase in the rate of the conformational change preceding phosphoryl transfer for all dNTPs that were tested. This is best illustrated by the biphasic pre-steady-state time course of dAMP insertion opposite an abasic site which indicates that a step after chemistry is rate-limiting for steady-state enzyme turnover. Furthermore, the k(pol) value of 40 s(-1) measured under single-turnover reaction conditions is 20-fold greater than the k(cat) value of 2 s(-1) measured for steady-state enzyme turnover. Finally, the low elemental effect ( approximately 2.4-fold reduction in k(pol)) measured by substituting the alpha-thiotriphosphate analogue for dATP further argues that chemistry is not rate-limiting. In contrast to the biphasic insertion of dAMP, pre-steady-state time courses for the insertion of dCMP, dGMP, or dTMP opposite an abasic site were linear. Nearly identical k(pol) values ( approximately 1 s(-1)) were measured for the insertion of dCMP, dGMP, and dTMP opposite the abasic site using single-turnover conditions. However, the large elemental effects of 27 and 70 measured by substituting the alpha-thiotriphosphate analogues for dCTP and dGTP, respectively, suggest that phosphoryl transfer may be the rate-limiting step for their insertion opposite the abasic site. Various models are discussed in an attempt to explain the effect of metal ion substitution on the dynamics of translesion DNA replication.     

Pre-steady-state fluorescence analysis of damaged DNA transfer from human DNA glycosylases to AP endonuclease APE1

Background

DNA glycosylases remove the modified, damaged or mismatched bases from the DNA by hydrolyzing the N-glycosidic bonds. Some enzymes can further catalyze the incision of a resulting abasic (apurinic/apyrimidinic, AP) site through β- or β,δ-elimination mechanisms. In most cases, the incision reaction of the AP-site is catalyzed by special enzymes called AP-endonucleases.

Methods

Here, we report the kinetic analysis of the mechanisms of modified DNA transfer from some DNA glycosylases to the AP endonuclease, APE1. The modified DNA contained the tetrahydrofurane residue (F), the analogue of the AP-site. DNA glycosylases AAG, OGG1, NEIL1, MBD4^cat and UNG from different structural superfamilies were used.

Results

We found that all DNA glycosylases may utilise direct protein–protein interactions in the transient ternary complex for the transfer of the AP-containing DNA strand to APE1.

Conclusions

We hypothesize a fast “flip-flop” exchange mechanism of damaged and undamaged DNA strands within this complex for monofunctional DNA glycosylases like MBD4^cat, AAG and UNG. Bifunctional DNA glycosylase NEIL1 creates tightly specific complex with DNA containing F-site thereby efficiently competing with APE1. Whereas APE1 fast displaces other bifunctional DNA glycosylase OGG1 on F-site thereby induces its shifts to undamaged DNA regions.

General significance

Kinetic analysis of the transfer of DNA between human DNA glycosylases and APE1 allows us to elucidate the critical step in the base excision repair pathway.     

NMR studies of abasic sites in DNA duplexes: deoxyadenosine stacks into the helix opposite acyclic lesions

Proton and phosphorus NMR studies are reported for two complementary nonanucleotide duplexes containing acyclic abasic sites. The first duplex, d(C-A-T-G-A-G-T-A-C).d(G-T-A-C-P-C-A-T-G), contains an acyclic propanyl moiety, P, located opposite a deoxyadenosine at the center of the helix (designated APP 9-mer duplex). The second duplex, d(C-A-T-G-A-G-T-A-C).d(G-T-A-C-E-C-A-T-G), contains a similarly located acyclic ethanyl moiety, E (designated APE 9-mer duplex). The ethanyl moiety is one carbon shorter than the natural carbon-phosphodiester backbone of a single nucleotide unit of DNA. The majority of the exchangeable and nonexchangeable base and sugar protons in both the APP 9-mer and APE 9-mer duplexes, including those at the abasic site, have been assigned by recording and analyzing two-dimensional phase-sensitive NOESY data sets in H2O and D2O solution between -5 and 5 degrees C. These spectroscopic observations establish that A5 inserts into the helix opposite the abasic site (P14 and E14) and stacks between the flanking G4.C15 and G6.C13 Watson-Crick base pairs in both the APP 9-mer and APE 9-mer duplexes. The helix is right-handed at and adjacent to the abasic site, and all glycosidic torsion angles are anti in both 9-mer duplexes. Proton NMR parameters for the APP 9-mer and APE 9-mer duplexes are similar to those reported previously for the APF 9-mer duplex (F = furan) in which a cyclic analogue of deoxyribose was embedded in an otherwise identical DNA sequence [Kalnik, M. W., Chang, C. N., Grollman, A. P., & Patel, D. J. (1988) Biochemistry 27, 924-931]. These proton NMR experiments demonstrate that the structures at abasic sites are very similar whether the five-membered ring is open or closed or whether the phosphodiester backbone is shortened by one carbon atom. Phosphorus spectra of the APP 9-mer and APE 9-mer duplexes (5 degrees C) indicate that the backbone conformation is similarly perturbed at three phosphodiester backbone torsion angles. These same torsion angles are also distorted in the APF 9-mer but assume a different conformation than those in the APP 9-mer and APE 9-mer duplexes.     

Processing of the abasic sites clustered with the benzo[a]pyrene adducts by the base excision repair enzymes

The major enzyme in eukaryotic cells that catalyzes the cleavage of apurinic/apyrimidinic (AP or abasic) sites is AP endonuclease 1 (APE1) that cleaves the phosphodiester bond on the 5′-side of AP sites. We found that the efficiency of AP site cleavage by APE1 was affected by the benzo[a]pyrenyl-DNA adduct (BPDE-dG) in the opposite strand. AP sites directly opposite of the modified dG or shifted toward the 5′ direction were hydrolyzed by APE1 with an efficiency moderately lower than the AP site in the control DNA duplex, whereas AP sites shifted toward the 3′ direction were hydrolyzed significantly less efficiently. For all DNA structures except DNA with the AP site shifted by 3 nucleotides in the 3′ direction (AP₊₃-BP-DNA), hydrolysis was more efficient in the case of (+)-trans-BPDE-dG. Using molecular dynamic simulation, we have shown that in the complex of APE1 with the AP₊₃-BP-DNA, the BP residue is located within the DNA bend induced by APE1 and contacts the amino acids in the enzyme catalytic center and the catalytic metal ion. The geometry of the APE1 active site is perturbed more significantly by the trans-isomer of BPDE-dG that intercalates into the APE1-DNA complex near the cleaved phosphodiester bond. The ability of DNA polymerases β (Polβ), λ and ι to catalyze gap-filling synthesis in cooperation with APE1 was also analyzed. Polβ was shown to inhibit the 3′ → 5′ exonuclease activity of APE1 when both enzymes were added simultaneously and to insert the correct nucleotide into the gap arising after AP site hydrolysis. Therefore, further evidence for the functional cooperation of APE1 and Polβ in base excision repair was obtained.     

Conformational dynamics of abasic DNA upon interactions with AP endonuclease 1 revealed by stopped-flow fluorescence analysis

Apurinic/apyrimidinic (AP) sites are abundant DNA lesions arising from exposure to UV light, ionizing radiation, alkylating agents, and oxygen radicals. In human cells, AP endonuclease 1 (APE1) recognizes this mutagenic lesion and initiates its repair via a specific incision of the phosphodiester backbone 5' to the AP site. We have investigated a detailed mechanism of APE1 functioning using fluorescently labeled DNA substrates. A fluorescent adenine analogue, 2-aminopurine, was introduced into DNA substrates adjacent to the abasic site to serve as an on-site reporter of conformational transitions in DNA during the catalytic cycle. Application of a pre-steady-state stopped-flow technique allows us to observe changes in the fluorescence intensity corresponding to different stages of the process in real time. We also detected an intrinsic Trp fluorescence of the enzyme during interactions with 2-aPu-containing substrates. Our data have revealed a conformational flexibility of the abasic DNA being processed by APE1. Quantitative analysis of fluorescent traces has yielded a minimal kinetic scheme and appropriate rate constants consisting of four steps. The results obtained from stopped-flow data have shown a substantial influence of the 2-aPu base location on completion of certain reaction steps. Using detailed molecular dynamics simulations of the DNA substrates, we have attributed structural distortions of AP-DNA to realization of specific binding, effective locking, and incision of the damaged DNA. The findings allowed us to accurately discern the step that corresponds to insertion of specific APE1 amino acid residues into the abasic DNA void in the course of stabilization of the precatalytic complex.     

Nuclear magnetic resonance structural studies and molecular modeling of duplex DNA containing normal and 4'-oxidized abasic sites

A 4'-oxidized abasic site (X) has been synthesized in a defined duplex DNA sequence, 5'-d(CCAAAGXACCGGG)-3'/3'-d(GGTTTCATGGCCC)-5' (1). Its structure has been determined by two-dimensional NMR methods, molecular modeling, and molecular dynamics simulations. 1 is globally B-form with the base (A) opposite X intrahelical and well-stacked. Only the alpha anomer of X is observed, and the abasic site deoxyribose is largely intrahelical. These results are compared with a normal abasic site (Y) in the same sequence context (2). Y is composed of a 60:40 mixture of alpha and beta anomers (2alpha and 2beta). In both 2alpha and 2beta, the base (A) opposite Y is intrahelical and well-stacked and the abasic site deoxyribose is predominantly extrahelical, consistent with the reported structures of the normal abasic site in a similar sequence context [Hoehn, S. T., Turner, C. J., and Stubbe, J. (2001) Nucleic Acids Res. 29, 3413-3423]. Molecular dynamics simulations reveal that the normal abasic site appears to be conformationally more flexible than the 4'-oxidized abasic site. The importance of the structure and flexibility of the abasic site in the recognition by the DNA repair enzyme Ape1 is discussed.     

Mechanism of interaction between human 8-oxoguanine-DNA glycosylase and AP endonuclease

Human 8-oxoguanine-DNA glycosylase (OGG1) is the main human base excision protein that removes a mutagenic lesion 8-oxoguanine (8-oxoG) from DNA. Since OGG1 has DNA glycosylase and weak abasic site (AP) lyase activities and is characterized by slow product release, turnover of the enzyme acting alone is low. Recently it was shown that human AP endonuclease (APE1) enhances the activity of OGG1. This enhancement was proposed to be passive, resulting from APE1 binding to or cleavage of AP sites after OGG1 dissociation. Here we present evidence that APE1 could actively displace OGG1 from its product, directly increasing the turnover of OGG1. We have observed that APE1 forms an electrophoretically detectable complex with OGG1 cross-linked to DNA by sodium borohydride. Using oligonucleotide substrates with a single 8-oxoG residue located in their 5'-terminal, central or 3'-terminal part, we have demonstrated that OGG1 activity does not increase only for the first of these three substrates, indicating that APE1 interacts with the DNA stretch 5' to the bound OGG1 molecule. In kinetic experiments, APE1 enhanced the product release constant but not the rate constant of base excision by OGG1. Moreover, OGG1 bound to a tetrahydrofuran analog of an abasic site stimulated the activity of APE1 on this substrate. Using a concatemeric DNA substrate, we have shown that APE1 likely displaces OGG1 in a processive mode, with OGG1 remaining on DNA but sliding away in search for a new lesion. Altogether, our data support a model in which APE1 specifically recognizes an OGG1/DNA complex, distorts a stretch of DNA 5' to the OGG1 molecule, and actively displaces the glycosylase from the lesion.     

DNA oligonucleotides with A, T, G or C opposite an abasic site: structure and dynamics

Abasic sites are common DNA lesions resulting from spontaneous depurination and excision of damaged nucleobases by DNA repair enzymes. However, the influence of the local sequence context on the structure of the abasic site and ultimately, its recognition and repair, remains elusive. In the present study, duplex DNAs with three different bases (G, C or T) opposite an abasic site have been synthesized in the same sequence context (5′-CCA AAG₆ XA₈C CGG G-3′, where X denotes the abasic site) and characterized by 2D NMR spectroscopy. Studies on a duplex DNA with an A opposite the abasic site in the same sequence has recently been reported [Chen,J., Dupradeau,F.-Y., Case,D.A., Turner,C.J. and Stubbe,J. (2007) Nuclear magnetic resonance structural studies and molecular modeling of duplex DNA containing normal and 4′-oxidized abasic sites. Biochemistry, 46, 3096–3107]. Molecular modeling based on NMR-derived distance and dihedral angle restraints and molecular dynamics calculations have been applied to determine structural models and conformational flexibility of each duplex. The results indicate that all four duplexes adopt an overall B-form conformation with each unpaired base stacked between adjacent bases intrahelically. The conformation around the abasic site is more perturbed when the base opposite to the lesion is a pyrimidine (C or T) than a purine (G or A). In both the former cases, the neighboring base pairs (G6-C21 and A8-T19) are closer to each other than those in B-form DNA. Molecular dynamics simulations reveal that transient H-bond interactions between the unpaired pyrimidine (C20 or T20) and the base 3′ to the abasic site play an important role in perturbing the local conformation. These results provide structural insight into the dynamics of abasic sites that are intrinsically modulated by the bases opposite the abasic site.     

Thermodynamic, kinetic and structural basis for recognition and repair of abasic sites in DNA by apurinic/apyrimidinic endonuclease from human placenta

X-ray analysis of enzyme–DNA interactions is very informative in revealing molecular contacts, but provides neither quantitative estimates of the relative importance of these contacts nor information on the relative contributions of specific and nonspecific interactions to the total affinity of enzymes for specific DNA. A stepwise increase in the ligand complexity approach is used to estimate the relative contributions of virtually every nucleotide unit of synthetic DNA containing abasic sites to its affinity for apurinic/apyrimidinic endonuclease (APE1) from human placenta. It was found that APE1 interacts with 9–10 nt units or base pairs of single-stranded and double-stranded ribooligonucleotides and deoxyribooligonucleotides of different lengths and sequences, mainly through weak additive contacts with internucleotide phosphate groups. Such nonspecific interactions of APE1 with nearly every nucleotide within its DNA-binding cleft provides up to seven orders of magnitude (ΔG° ~ −8.7 to −9.0 kcal/mol) of the enzyme affinity for any DNA substrate. In contrast, interactions with the abasic site together with other specific APE1–DNA interactions provide only one order of magnitude (ΔG° ~ −1.1 to −1.5 kcal/mol) of the total affinity of APE1 for specific DNA. We conclude that the enzyme's specificity for abasic sites in DNA is mostly due to a great increase (six to seven orders of magnitude) in the reaction rate with specific DNA, with formation of the Michaelis complex contributing to the substrate preference only marginally.     

AP endonuclease and poly(ADP-ribose) polymerase-1 interact with the same base excision repair intermediate

Base excision repair (BER) is a defense system that protects cells from deleterious effects secondary to modified or missing DNA bases. BER is known to involve apurinic/apyrimidinic endonuclease (APE) and DNA polymerase ss (ss-pol) among other enzymes, and recent studies have suggested that poly(ADP-ribose) polymerase-1 (PARP-1) also plays a role by virtue of its binding to BER intermediates. The main role of APE is cleavage of the DNA backbone at abasic sites, and the enzyme also can catalyze 3'- to 5'-exonuclease activity at the cleaved abasic site. Photocross-linking studies with mouse embryonic fibroblast (MEF) cell extracts described here indicated that APE and PARP-1 interact with the same APE-cleaved abasic site BER intermediate. The model BER intermediate used includes a synthetic abasic site sugar, i.e. tetrahydrofuran (THF), in place of the natural deoxyribose. APE cross-linked efficiently with this intermediate, but not with a molecule lacking the 5'-THF phosphate group, and the same property was demonstrated for PARP-1. The addition of purified APE to the MEF extract reduced the amount of PARP-1 cross-linked to the BER intermediate, suggesting that APE can compete with PARP-1. APE and PARP-1 were antagonists of each other in in vitro BER related reactions on this model BER intermediate. These results suggest that PARP-1 and APE can interact with the same BER intermediate and that competition between these two proteins may influence their respective BER related functions.     

Mutagenic properties of a unique abasic site in mammalian cells

The mutagenic properties of a true unique abasic site located opposite a guanine residue were studied. An oligonucleotide containing a chemically-produced abasic site was inserted into a shuttle vector able to replicate both in simian cells and in bacteria. Plasmid DNA was rescued from simian cells and screened in bacteria by differential hybridization with a labelled oligonucleotide probe. Mutations were easily detected and sequenced. Results showed that opposite a guanine the abasic site was error free repaired or replicated by mammalian cells with an efficiency of 99%. Point mutations occurred at a frequency of approximately 1% in control host cells and at more than 3% in UV-pre-irradiated host cells. Adenine, cytosine or thymine were found to have been inserted opposite the abasic site. No preferential insertion for a particular base was observed in contrast to that reported in bacteria.     

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.     

Enhancing the "A-rule" of translesion DNA synthesis: promutagenic DNA synthesis using modified nucleoside triphosphates

Abasic sites are mutagenic DNA lesions formed as a consequence of inappropriate modifications to the functional groups present on purines and pyrimidines. In this paper we quantify the ability of the high-fidelity bacteriophage T4 DNA polymerase to incorporate various promutagenic alkylated nucleotides opposite and beyond this class of non-instructional DNA lesions. Kinetic analyses reveal that modified nucleotides such as N6-methyl-dATP and O6-methyl-dGTP are incorporated opposite an abasic site far more effectively than their unmodified counterparts. The enhanced incorporation is caused by a 10-fold increase in kpol values that correlates with an increase in hydrophobicity as well as changes in the tautomeric form of the nucleobase to resemble adenine. These biophysical features lead to enhanced base-stacking properties that also contribute toward their ability to be easily extended when paired opposite the non-instructional DNA lesion. Surprisingly, misincorporation opposite templating DNA is not enhanced by the increased base-stacking properties of most modified purines. The dichotomy in promutagenic DNA synthesis catalyzed by a high-fidelity polymerase indicates that the dynamics for misreplicating a miscoding versus a non-instructional DNA lesion are different. The collective data set is used to propose models accounting for synergistic enhancements in mutagenesis and the potential to develop treatment-related malignancies as a consequence of utilizing DNA-damaging agents as chemotherapeutic agents.     

Oligonucleotides with bistranded abasic sites interfere with substrate binding and catalysis by human apurinic/apyrimidinic endonuclease.

Apurinic/apyrimidinic endonuclease (AP endo) is a key enzyme in oxidative damage DNA repair. The enzyme, which repairs abasic sites, makes a single nick 5' to the phosphodeoxyribose, leaving a free 3'-hydroxyl. We recently described single turnover kinetics for human recombinant AP endo acting on an oligonucleotide with a single abasic site. We hypothesized that the structural changes induced by the presence of a second abasic site might provide insight into how AP endo recognizes the first abasic site. Here we performed steady state and single turnover experiments using bistranded abasic site substrates, with the second site located on the complementary strand to the one being followed and either opposite to the first or displaced in the 5' direction. All sites on the complementary strand were within half a helical turn of the first. The catalytic efficiency was reduced 80 to 96% and the Kd for substrate binding and dissociation was elevated 40- to 125-fold. The smaller changes occurred when the second site was opposite the first site or displaced by four nucleotides. In addition, if the second abasic site was directly across the helix or displaced by 1 or 3 nucleotides from the first abasic site, cleavage of the first abasic site was subject to apparent substrate inhibition, which did not occur if the second abasic site was displaced by four nucleotides from the first. While a substrate containing a nick without a phosphodeoxyribose on the contralateral strand abasic site did not inhibit nicking of the first strand, a substrate with a nicked abasic site on the contralateral strand was an even stronger inhibitor of enzyme action than an oligonucleotide containing the corresponding abasic site on each strand. Consequently, the inhibitory effect of the second abasic site is probably the result of prior cleavage of the abasic site on the contralateral strand with resulting distortions to the DNA helix that interfere with enzyme binding and/or cleavage.     

The abasic site as a challenge to DNA polymerase. A nuclear magnetic resonance study of G, C and T opposite a model abasic site

An abasic site in DNA creates a strong block to DNA polymerase and is a mutagenic base lesion. In this study, we present structural and dynamic properties of duplex oligodeoxynucleotides containing G, C and T opposite a model abasic site studied by one and two-dimensional nuclear magnetic resonance spectroscopy. We have demonstrated that A opposite the abasic site was positioned within the helix as if paired with T, and that the A residue melted co-operatively with the surrounding helix. We report here that G opposite the abasic site is also observed to be predominantly intrahelical in a normal anti conformation at low temperature. With increasing temperature, the mobility of the G residue increases rapidly and apparently is in a "melted state" well before denaturation of the helix. At low temperature, two species are found for T opposite the abasic site; one, intrahelical, one extrahelical. These species are in slow exchange with one another on a proton nuclear magnetic resonance time-scale. The two species then move into fast exchange with increasing temperature and the proportion of the extra-helical form increases. When C is positioned opposite the abasic site, both the C residue and the abasic sugar are extrahelical, the helix collapses, and the adjacent G.C base-pairs stack over one another. On the basis of these observations, we propose a model that explains why the abasic site acts to block DNA replication. Further, we suggest an explanation for the observed polymerase preference for base selection at abasic sites.