The use of hairpin DNA duplexes as HIV-1 fusion inhibitors: synthesis, characterization, and activity evaluation.

Discovery of new drugs for the treatment of AIDS that possess unique structures associated with novel mechanisms of action are of great importance due the rapidity with which drug-resistant HIV-1 strains evolve. Recently we reported on a novel class of DNA duplex-based HIV-1 fusion inhibitors modified with hydrophobic groups. The present study describes a new category of hairpin fusion inhibitor DNA duplexes bearing a 3 nucleotide loop located at either the hydrophobic or hydrophilic end. The new loop structures were designed to link 2 separate duplex-forming oligodeoxynucleotides (ODNs) to make helix-assembly easier and more thermally stable resulting in a more compact form of DNA duplex based HIV-1 fusion inhibitors. A series of new hairpin duplexes were tested for anti-HIV-1 cell-cell membrane fusion activity. In addition, Tm, CD, fluorescent resonance energy transfer assays, and molecular modeling analyses were carried out to define their structural activity relationships and possible mechanisms of action.

Sequence-specific base pair mimics are efficient topoisomerase IB inhibitors.

Topoisomerase IB controls DNA topology by cleaving DNA transiently. This property is used by inhibitors, such as camptothecin, that stabilize, by inhibiting the religation step, the cleavage complex, in which the enzyme is covalently attached to the 3'-phosphate of the cleaved DNA strand. These drugs are used in clinics as antitumor agents. Because three-dimensional structural studies have shown that camptothecin derivatives act as base pair mimics and intercalate between two base pairs in the ternary DNA-topoisomerase-inhibitor complex, we hypothesized that base pairs mimics could act like campthotecin and inhibit the religation reaction after the formation of the topoisomerase I-DNA cleavage complex. We show here that three base pair mimics, nucleobases analogues of the aminophenyl-thiazole family, once targeted specifically to a DNA sequence were potent topoisomerase IB inhibitors. The targeting was achieved through covalent linkage to a sequence-specific DNA ligand, a triplex-forming oligonucleotide, and was necessary to position and keep the nucleobase analogue in the cleavage complex. In the absence of triplex formation, only a weak binding to the DNA and topoisomerase I-mediated DNA cleavage was observed. The three compounds were equally active once conjugated, implying that the intercalation of the nucleobase upon triplex formation is the essential feature for the inhibition activity.

Structural basis of the RNase H1 activity on stereo regular borano phosphonate DNA/RNA hybrids.

Numerous DNA chemistries for improving oligodeoxynucleotide (ODN)-based RNA targeting have been explored. The majority of the modifications render the ODN/RNA target insensitive to RNase H1. Borano phosphonate ODN's are among the few modifications that are tolerated by RNase H1. To understand the effect of the stereochemistry of the BH(3) modification on the nucleic acid structure and RNase H1 enzyme activity, we have investigated two DNA/RNA hybrids containing either a R(P) or S(P) BH(3) modification by nuclear magnetic resonance (NMR) spectroscopy. T(M) studies show that the stabilities of R(P) and S(P) modified DNA/RNA hybrids are essentially identical (313.8 K) and similar to that of an unmodified control (312.9 K). The similarity is also reflected in the imino proton spectra. To characterize such similar structures, we used a large number of NMR restraints (including dipolar couplings and backbone torsion angles) to determine structural features that were important for RNase H1 activity. The final NMR structures exhibit excellent agreement with the data (total R(x) values of <6%) with helical properties between those of an A and B helix. Subtle backbone variations are observed in the DNA near the modification, while the RNA strands are relatively unperturbed. In the case of the S(P) modification, for which more perturbations are recorded, a slightly narrower minor groove is also obtained. Unique NOE base contacts localize the S(P) BH(3) group in the major groove while the R(P) BH(3) group points away from the DNA. However, this creates a potential clash of the R(P) BH(3) groups with important RNase H1 residues in a complex, while the S(P) BH(3) groups could be tolerated. We therefore predict that on the basis of our NMR structures a fully R(P) BH(3) DNA/RNA hybrid would not be a substrate for RNase H1.

Base pairing configuration and stability of an oligonucleotide duplex containing a 5-chlorouracil-adenine base pair.

Inflammation-mediated reactive molecules can damage DNA by oxidation and chlorination. The biological consequences of this damage are as yet incompletely understood. In this paper, we have constructed oligonucleotides containing 5-chlorouracil (ClU), one of the known inflammation damage products. The thermodynamic stability, base pairing configuration, and duplex conformation of oligonucleotides containing ClU paired opposite adenine have been examined. NMR spectra reveal that the ClU-A base pair adopts a geometry similar to that of the T-A base pair, and the ClU-A base pair-containing duplex adopts a normal B-form conformation. The line width of the imino proton of the ClU residue is substantially greater than that of the corresponding T imino proton; however, this difference is not attributed to a reduced thermal or thermodynamic stability or to an increased level of proton exchange with solvent. While the NMR studies reveal an increased level of chemical exchange for the ClU imino proton of the ClU-A base pair, the ClU residue is not a target for removal by the Escherichia coli mispaired uracil glycosylase, which senses damage-related helix instability. The results of this study are consistent with previous reports indicating that the DNA of replicating cells can tolerate substantial substitution with ClU. The fraudulent, pseudo-Watson-Crick ClU-A base pair is sufficiently stable to avoid glycosylase removal and, therefore, might constitute a persistent form of cellular DNA damage.

Conformational heterogeneity and quasi-static self-quenching in DNA containing a fluorescent guanine analogue, 3MI or 6MI.

Two different microenvironments in the DNA sequence 5'-act aGa gat ccc tca gac cct ttt agt cag tGt gga-3' (in both single- and double-stranded forms) are explored using two similar fluorescent nucleoside analogues, 3MI and 6MI. Each probe was evaluated in two environments, one strand with the probe flanked by thymines (PTRT) and the other by adenines (PTRA) with positions indicated by G's in the sequence. Both time-resolved anisotropies and lifetimes of the probes depend upon local interactions, and these are altered by duplex formation. Integrals of lifetime curves compared with quantum yields reveal that each probe displays a "dark" component (below detection limits, with a lifetime of <70 ps). For 6MI in PTRA, this QSSQ "quasi-static self-quenching" or "dark" component represents approximately half the molecules, whether in single- or double-stranded form. In PTRT, 6MI displays an unusual increase in the quantum yield upon formation of the double strand (from 0.107 to 0.189) apparently the result of escape from QSSQ which simultaneously declines from 66 to 33%. This is also accompanied by doubling of steady-state anisotropy. Only 6MI in the PTRT duplex displays a rotational correlation time of >7 ns. In other words, the DS 6MI PTRA environment fails to constrain local motion and QSSQ remains the same as in the single strand; in contrast, the flanking T duplex environment restricts local motion and halves QSSQ. We collected both steady-state and time-resolved fluorescence quenching titrations of 3MI and 6MI in solution with the mononucleotides AMP, CMP, GMP, and TMP. The dynamic quenching rank of the free probes (quenching constant, kq: T > A > G > C) is totally different from that of incorporated probes. We hypothesize the production of weak 3MI.C or 6MI.C complexes that are somehow rendered less subject to dynamic quenching by collision with subsequent C molecules.

A rare nucleotide base tautomer in the structure of an asymmetric DNA junction.

The single-crystal structure of a DNA Holliday junction assembled from four unique sequences shows a structure that conforms to the general features of models derived from similar constructs in solution. The structure is a compact stacked-X form junction with two sets of stacked B-DNA-type arms that coaxially stack to form semicontinuous duplexes interrupted only by the crossing of the junction. These semicontinuous helices are related by a right-handed rotation angle of 56.5 degrees, which is nearly identical to the 60 degree angle in the solution model but differs from the more shallow value of approximately 40 degrees for previous crystal structures of symmetric junctions that self-assemble from single identical inverted-repeat sequences. This supports the model in which the unique set of intramolecular interactions at the trinucleotide core of the crossing strands, which are not present in the current asymmetric junction, affects both the stability and geometry of the symmetric junctions. An unexpected result, however, is that a highly wobbled A.T base pair, which is ascribed here to a rare enol tautomer form of the thymine, was observed at the end of a CCCC/GGGG sequence within the stacked B-DNA arms of this 1.9 A resolution structure. We suggest that the junction itself is not responsible for this unusual conformation but served as a vehicle for the study of this CG-rich sequence as a B-DNA duplex, mimicking the form that would be present in a replication complex. The existence of this unusual base lends credence to and defines a sequence context for the "rare tautomer hypothesis" as a mechanism for inducing transition mutations during DNA replication.

Synthesis and base pairing properties of DNA-RNA heteroduplex containing 5-hydroxyuridine.

5-Hydroxyuridine (5-OHU) is a major lesion of uridine and cytosine produced in RNA by various chemical oxidants. To elucidate its biochemical and biophysical effects on RNA replication, the site-specifically modified oligoribonucleotides containing 5-OHU were synthesized with C5-hydroxy-5'-O-DMTr-2'-TBDMS-uridine phosphoramidite using automated solid phase synthesis. The base-pairing properties of nucleotides opposite 5-OHU in 24 mer oligoribonulcleotides with dNTP were studied using three reverse transcriptases (Super-Script(TM)II-, AMV-, MMLV-RT) in cDNA synthesis. Adenine as well as guanine was incorporated preferentially by all reverse transcriptases. In the UV-melting temperature experiment, the results from the relative stabilities of the base pairs were A : 5-OHU > G : 5-OHU > T : 5-OHU approximately C : 5-OHU. Circular Dichroism (CD) studies showed that DNA-RNA containing 5-OHU heteroduplexes exhibit a similar conformation between the A-type RNA and B-type DNA. These results suggest that 5-OHU from oxidative damage was mainly influenced by adenine mismatch.

Photoaffinity labeling reveals nuclear proteins that uniquely recognize cisplatin-DNA interstrand cross-links.

The DNA-binding inorganic compound cisplatin is one of the most successful anticancer drugs. The detailed mechanism by which cells recognize and process cisplatin-DNA damage is of great interest. Although the family of proteins that bind cisplatin 1,2- and 1,3-intrastrand cross-links has been identified, much less is known about cellular protein interactions with cisplatin interstrand cross-links (ICLs). In order to address this question, a photoreactive analogue of cisplatin, PtBP(6), was used to construct a DNA duplex containing a site-specific platinum ICL. This DNA probe was characterized and used in photo-cross-linking experiments to separate and identify nuclear proteins that bind to the ICL by peptide mass fingerprint analysis. Several such proteins were discovered, including PARP-1, hMutSbeta, DNA ligase III, XRCC1, and PNK. The photo-cross-linking approach was independently validated by an electrophoretic mobility shift assay demonstrating hMutSbeta binding to a cisplatin ICL. Proteins that recognize the platinum ICL were also identified in cisplatin-resistant cells, cells halted at various phases of the cell cycle, and in different carcinoma cells. Nuclear proteins that bind to the platinum ICL differ from those binding to intrastrand cross-links, indicating different mechanisms for disruption of cellular functions.

Kinetic hybrid i-motifs: intercepting DNA with RNA to form a DNA(2)-RNA(2) i-motif.

We have constructed and characterized a long-lived hybrid DNA(2)-RNA(2) i-motif that is kinetically formed by mixing equivalent amount of C-rich RNA (R) and C-rich DNA (D). Circular dichroism shows that these hybrids are distinct from their parent DNA(4) or RNA(4) i-motif. pH dependent CD and UV thermal melting experiments showed that the complexes were maximally stable at pH 4.5, the pK(a) of cytosine, consistent with the complex being held by CH(+)-C base pairs. Fluorescence studies confirmed their tetrameric nature and established the relative strand polarities of the RNA and DNA strands in the complex. These showed that in a hybrid D(2)R(2) i-motif two DNA strands occupy one narrow groove and the two RNA strands occupy the other. This suggests that even the sugar-sugar interactions are highly specific. Interestingly, this hybrid slowly disproportionates into DNA(4) i-motifs and ssRNA which would be valuable to study intermediates in DNA(4) i-motif formation.

Pyrene aromatic arrays on RNA duplexes as helical templates.

RNA oligomers having multiple (2 to 4) pyrenylmethyl substituents at the 2'-O-sugar residues were synthesized. UV-melting studies showed that the pyrene-modified RNAs could form duplexes with complementary RNA sequences without loss of thermal stability. Absorption, fluorescence, and circular dichroism (CD) spectra revealed that the incorporated pyrenes projected toward the outside of A-form RNA duplexes and assembled in helical aromatic arrays along the minor grooves of the RNA duplexes. Results of computer simulations agreed with the assembled structures of the pyrenes. The helical pyrene arrays exhibited remarkably strong excimer fluorescence, which was dependent on the sequence contexts of RNA duplexes.

Formation of bimetallic Ag-Au nanowires by metallization of artificial DNA duplexes.

Uniform bimetallic nanowires, tunable in size, have been grown on artificial DNA templates via a two-step metallization process. Alkyne-modified cytosines were incorporated into 900-base-pair polymerase-chain-reaction fragments. The alkyne modifications serve as addressable metal-binding sites after conversion to a sugar triazole derivative via click chemistry. Reaction of the Tollens reagent with these sugar-coated DNA duplexes generates Ag0 metallization centers around the sugar modification sites of the DNA. After a subsequent enhancement step using gold, nanowires < or = 10 nm in diameter with a homogeneous surface profile were obtained. Furthermore, the advantage of this two-step procedure lies in the high selectivity of the process, due to the exact spatial control of modified DNA base incorporation and hence the confinement of metallization centers at addressable sites. Besides experiments on a membrane as a proof for the selectivity of the method, atomic force microscopy (AFM) studies of the wires produced on Si-SiO2 surfaces are discussed. Furthermore, we demonstrate time-dependent metallization experiments, monitored by AFM.

Stepwise binding and bending of DNA by Escherichia coli integration host factor.

Integration host factor (IHF) is a prokaryotic protein required for the integration of lambda phage DNA into its host genome. An x-ray crystal structure of the complex shows that IHF binds to the minor groove of DNA and bends the double helix by 160 degrees [Rice PA, Yang S, Mizuuchi K, Nash HA (1996) Cell 87:1295-1306]. We sought to dissect the complex formation process into its component binding and bending reaction steps, using stopped-flow fluorimetry to observe changes in resonance energy transfer between DNA-bound dyes, which in turn reflect distance changes upon bending. Different DNA substrates that are likely to increase or decrease the DNA bending rate were studied, including one with a nick in a critical kink position, and a substrate with longer DNA ends to increase hydrodynamic friction during bending. Kinetic experiments were carried out under pseudofirst-order conditions, in which the protein concentration is in substantial excess over DNA. At lower concentrations, the reaction rate rises linearly with protein concentration, implying rate limitation by the bimolecular reaction step. At high concentrations the rate reaches a plateau value, which strongly depends on temperature and the nature of the DNA substrate. We ascribe this reaction limit to the DNA bending rate and propose that complex formation is sequential at high concentration: IHF binds rapidly to DNA, followed by slower DNA bending. Our observations on the bending step kinetics are in agreement with results using the temperature-jump kinetic method.

Improved delivery in cell culture of radiolabeled antisense DNAs by duplex formation.

PURPOSE: Delivery remains an unresolved problem in applications requiring intravenous administration of DNAs. Recently improved antisense translation interruption in cells was reported for an antisense (AS) oligomer as a duplex compared to singlet AS oligomer presumably because of improved delivery. The unstable phosphodiester backbone of the sense (S) oligomer and its shorter chain length apparently encouraged intracellular dissociation and release of the AS oligomer. We have investigated the mechanism involved to evaluate whether the approach may be useful for antisense radionuclide imaging. PROCEDURES: Duplexes were formed between an AS phosphorothioate DNA against the mdr1 mRNA and the uniform phoshorothioate or uniform phosphodiester sense (S) DNAs with either four or six mismatches. RESULTS: Accumulations in KB-G2 (Pgp++) cells of radiolabeled AS DNA as duplex accumulated threefold higher compared to singlet. Accumulation was still antisense as shown by reduced accumulations with the radiolabel on the S DNA. However, the DNA backbone had no clear influence on accumulations. CONCLUSIONS: Targeting of mRNAs with radiolabeled AS DNAs may be improved in cell culture if duplexed with an S DNA engineered for low hybridization affinity to encourage dissociation in the presence of the target mRNA.

High resolution characterization of formamidopyrimidine-DNA glycosylase interaction with its substrate by chemical cross-linking and mass spectrometry using substrate analogs.

Escherichia coli formamidopyrimidine-DNA glycosylase (Fpg) and human 8-oxoguanine-DNA glycosylase (hOgg1) initiate the base excision repair pathway for 7,8-dihydro-8-oxoguanine (8-oxoG) residues present in DNA. Recent structural and biochemical studies of Fpg-DNA and hOgg1-DNA complexes point to the existence of extensive interactions between phosphate groups and amino acids. However, the role of these contacts and their physiological relevance remains unclear. In the present study, we combined chemical cross-linking and electrospray ionization mass spectrometry (ESI/MS/MS) approaches to identify interacting residues in the Fpg-DNA and hOgg1-DNA complexes. The active centers of Fpg and hOgg1 were cross-linked with a series of reactive oligonucleotide duplexes containing both a single 8-oxoG residue and an O-ethyl-substituted pyrophosphate internucleotide (SPI) group at different positions in duplex DNA. The cross-linking efficiency reached 50% for Fpg and 30% for hOgg1. We have identified seven phosphate groups on both strands of the DNA duplex specifically interacting with nucleophilic amino acids in Fpg, and eight in hOgg1. MS/MS analysis of the purified proteolytic fragments suggests that lysine 56 of Fpg and lysine 249 of hOgg1 cross-link to the phosphate located 3' to the 8-oxoG residue. Site-specific mutagenesis analysis of Fpg binding to DNA substrate confirms the conclusions of our approach. Our results are consistent with crystallographic data on the Fpg-DNA complex and provide new data on the hOgg1-DNA interaction. The approach developed in this work provides a useful tool to study pro- and eukaryotic homologues of Fpg as well as other repair enzymes.

Structure, flexibility, and repair of two different orientations of the same alkyl interstrand DNA cross-link.

Interstrand DNA cross-links are the principal cytotoxic lesions produced by chemotherapeutic bifunctional alkylating agents. Using an N(4)C-ethyl-N(4)C interstrand DNA cross-link to mimic this class of clinically important cancer chemotherapeutic agents, we have characterized the repair, structure, and flexibility of DNA that contains this cross-link in two different orientations. Plasmid DNAs in which the cytosines of single CpG or GpC steps are covalently linked were efficiently processed by repair proficient and homologous recombination deficient strains of Escherichia coli. Repair in a nucleotide excision repair (NER) deficient strain was less efficient overall and displayed a 4-fold difference between the two cross-link orientations. Both the structure and flexibility of DNA containing these cross-links were examined using a combination of (1)H NMR, restrained molecular dynamics simulations, and atomic force microscopy (AFM). The NMR structure of a decamer containing a CpG interstrand cross-link shows the cross-link easily accommodated within the duplex with no disruption of hydrogen bonding and only minor perturbations of helical parameters. In contrast, disruptions caused by the GpC cross-link produced considerable conformational flexibility that precluded structure determination by NMR. AFM imaging of cross-link-containing plasmid DNA showed that the increased flexibility observed in the GpC cross-link persists when it is embedded into much larger DNA fragments. These differences may account for the different repair efficiencies seen in NER deficient cells.

Activation of camptothecin derivatives by conjugation to triple helix-forming oligonucleotides.

Topoisomerase I (topo I) is a ubiquitous DNA-cleaving enzyme and an important therapeutic target in cancer chemotherapy. Camptothecins (CPTs) reversibly trap topo I in covalent complex with DNA but exhibit limited sequence preference. The utilization of conjugates such as triplex-forming oligonucleotides (TFOs) to target a medicinal agent (like CPT) to a specific genetic sequence and orientation within the DNA has been accomplished successfully. In this study, different attachment points of the TFO to CPT (including positions 7, 9, 10, and 12) were investigated and our findings confirmed and extended previous conclusions. Interestingly, the conjugates induced specific DNA cleavage by topo I at the triplex site even when poorly active or inactive CPT derivatives were used. This suggests that the positioning of the drug in the cleavage complex by the sequence-specific DNA ligand is able to stabilize the ternary complex, even when important interactions between topo I and CPT are disrupted. Finally, certain TFO-CPT conjugates were able to induce sequence-specific DNA cleavage with the topo I mutants R364H and N722S that are resistant to camptothecin. The TFO-CPT conjugates are thus valuable tools to study the interactions involved in the formation of the ternary complex and also to enlarge the family of compounds that poison topo I. The fact that an inactive CPT analogue can act as a topo I poison when appropriately coupled to a TFO provides a new perspective at the level of drug design.

Distance and affinity dependence of triplex-induced recombination.

Triplex-forming oligonucleotides (TFOs) have the potential to serve as gene therapeutic agents on the basis of their ability to mediate site-specific genome modification via induced recombination. However, high-affinity triplex formation is limited to polypurine/polypyrimidine sites in duplex DNA. Because of this sequence restriction, careful analysis is needed to identify suitable TFO target sites within or near genes of interest. We report here an examination of two key parameters which influence the efficiency of TFO-induced recombination: (1) binding affinity of the TFO for the target site and (2) the distance between the target site and the mutation to be corrected. To test the influence of binding affinity, we compared induced recombination in human cell-free extracts by a series of G-rich oligonucleotides with an identical base composition and an increasing number of mismatches in the third strand binding code. As the number of mismatches increased and, therefore, binding affinity decreased, induced recombination frequency also dropped. There was an apparent threshold at an equilibrium dissociation constant (K(d)) of 1 x 10(-)(7) M. In addition, TFO chemical modification with N,N-diethylethylenediamine (DEED) internucleoside linkages to confer improved binding was found to yield increased levels of induced recombination. To test the ability of triplex formation to induce recombination at a distance, episomal targets with informative reporter genes were constructed to contain polypurine TFO target sites at varying distances from the mutations to be corrected. TFO-induced recombination in mammalian cells between a plasmid vector and a donor oligonucleotide was detected at distances ranging from 24 to 750 bp. Together, these results indicate that TFO-induced recombination requires high-affinity binding but can affect sites hundreds of base pairs away from the position of triplex formation.

Impact of the C1' configuration of abasic sites on DNA duplex structure.

Naturally occurring abasic sites in DNA exist as an equilibrium mixture of the aldehyde, the hydrated aldehyde, and the hemiacetal forms (dominant). The influence of the configuration of the C1' hydroxyl group of the hemiacetal form on duplex structure and abasic site repair has been examined using novel carbocyclic analogues. Both the alpha- and beta-forms of this novel abasic site were introduced into oligomeric DNA using the standard DMT-phosphoramidite approach in an automated solid-phase synthesizer. Solution structures of the d(CGTACXCATGC).d(GCATGAGTACG) duplex (where X is the alpha- or beta-anomer of the carbocyclic abasic site analogue) were determined by NMR spectroscopy and restrained molecular dynamics simulations. The structures were only minimally perturbed by the presence of either anomer of the abasic site. All residues adopted an anti conformation, and Watson-Crick alignments were observed on all base pairs of the duplexes. At the lesion site, the abasic residues and their partner adenines showed increased dynamic behavior but adopted intrahelical positions in the final refined structures. Incision of duplexes having the alpha- or beta-anomer of the carbocyclic abasic site by human AP endonuclease showed that the enzyme recognizes both configurations of the lesion and nicks the DNA backbone with similar efficiency. Our results challenge the suggestion that Ape1 is stereoselective and imply a plasticity at the active site of the enzyme for accommodating either anomer of the lesion.

Recognition of an unnatural difluorophenyl nucleotide by uracil DNA glycosylase.

The DNA repair enzyme uracil DNA glycosylase (UDG) utilizes base flipping to recognize and remove unwanted uracil bases from the genome but does not react with its structural congener, thymine, which differs by a single methyl group. Two factors that determine whether an enzyme flips a base from the duplex are its shape and hydrogen bonding properties. To probe the role of these factors in uracil recognition by UDG, we have synthesized a DNA duplex that contains a single difluorophenyl (F) nucleotide analogue that is an excellent isostere of uracil but possesses no hydrogen bond donor or acceptor groups. By using binding affinity measurements, solution (19)F NMR, and solid state (31)P[(19)F] rotational-echo double-resonance (REDOR) NMR measurements, we establish that UDG partially unstacks F from the duplex. However, due to the lack of hydrogen bonding groups that are required to support an open-to-closed conformational transition in UDG, F cannot stably dock in the UDG active site. We propose that F attains a metastable unstacked state that mimics a previously detected intermediate on the uracil-flipping pathway and suggest structural models of the metastable state that are consistent with the REDOR NMR measurements.

In vitro replication and repair of DNA containing a C2'-oxidized abasic site.

Abasic lesions are unable to form Watson-Crick hydrogen bonds with nucleotides. Nonetheless, polymerase and repair enzymes distinguish between various oxidized abasic lesions, as well as from nonoxidized abasic sites (AP). The C2-AP lesion is produced when DNA is exposed to gamma-radiolysis. Its effects on polymerases and repair enzymes are unknown. A recently reported method for the chemical synthesis of oligonucleotides containing C2-AP at a defined site was utilized for studying the activity of Klenow exo(-) and repair enzymes on templates containing the lesion. The C2-AP lesion has a similar effect on Klenow exo(-) as do AP and C4-AP sites. Deoxyadenosine is preferentially incorporated opposite C2-AP, but extension of the primer past the lesion is strongly blocked. C2-AP is incised less efficiently by exonuclease III and endonuclease IV than are other abasic lesions. Furthermore, although a Schiff base between C2-AP and endonuclease III can be chemically trapped, the location of the 3'-phosphate alpha with respect to the aldehyde prevents beta-elimination associated with the lyase activity of type I base excision repair enzymes. The interactions of the C2'-oxidized abasic site with Klenow exo(-) and repair enzymes suggest that the lesion will be mutagenic and that it will be removed by strand displacement synthesis and flap endonuclease processing via a long patch repair mechanism.