Bistranded oxidized purine damage clusters: induced in DNA by long-wavelength ultraviolet (290-400 nm) radiation?

Bistranded clustered DNA damages involving oxidized bases, abasic sites, and strand breaks are produced by ionizing radiation and radiomimetic drugs, but it was not known whether they can be formed by other agents, e.g., nonionizing radiation. UV radiation produces clusters of cyclobutyl pyrimidine dimers, photoproducts that occur individually in high yield. Since long-wavelength UV (290-400 nm) radiation induces oxidized bases, abasic sites, and strand breaks at low yields, we tested whether it also produces clusters containing these lesions. We exposed supercoiled pUC18 DNA to UV radiation with wavelengths of >290 nm (UVB plus UVA radiation), and assessed the induction of bistranded clustered oxidized purine and abasic clusters, as recognized by Escherichia coli Fpg protein and E. coli Nfo protein (endonuclease IV), respectively, as well as double-strand breaks. These three classes of bistranded clusters were detected, albeit at very low yields (37 Fpg-OxyPurine clusters Gbp(-1) kJ(-1) m(2), 8.1 double-strand breaks Gbp(-1) kJ(-1) m(2), and 3.4 Nfo-abasic clusters Gbp(-1) kJ(-1) m(2)). Thus, these bistranded OxyPurine clusters, abasic clusters, and double-strand breaks are not uniquely induced by ionizing radiation and radiomimetic drugs, but their level of production by UVB and UVA radiation is negligible compared to the levels of frequent photoproducts such as pyrimidine dimers.     

Synthesis and evaluation of RNA transesterification efficiency using stereospecific serinol-terpyridine conjugates

Six novel artificial ribonucleases were synthesized employing a stereochemically pure abasic serinol backbone residue for attachment of the RNA transesterification agent copper(II) terpyridine. These stereochemically pure abasic residues were synthesized as phosphoramidite building blocks from the parent L-serine and D-serine starting building blocks and incorporated into oligonucleotides via solid-phase DNA synthesis. These artificial ribonucleases were constructed to determine if the stereochemistry of the alpha carbon of an abasic serinol residue has influence over RNA transesterification through selective placement of a pendant transesterification agent in either the major or minor groove. The novel artificial ribonucleases and previously synthesized artificial ribonucleases were challenged with a 28-mer and 159-mer RNA substrate. It was determined that the stereochemistry of the carbon atom derived from the alpha-carbon of serine did not influence the extent of cleavage in these studies using copper(II) terpyridine conjugated artificial ribonucleases.     

The chemical stability of abasic RNA compared to abasic DNA

We describe the synthesis of an abasic RNA phosphoramidite carrying a photocleavable 1-(2-nitrophenyl)ethyl (NPE) group at the anomeric center and a triisopropylsilyloxymethyl (TOM) group as 2′-O-protecting group together with the analogous DNA and the 2′-OMe RNA abasic building blocks. These units were incorporated into RNA-, 2′-OMe-RNA- and DNA for the purpose of studying their chemical stabilities towards backbone cleavage in a comparative way. Stability measurements were performed under basic conditions (0.1 M NaOH) and in the presence of aniline (pH 4.6) at 37°C. The kinetics and mechanisms of strand cleavage were followed by High pressure liquid chromotography and ESI-MS. Under basic conditions, strand cleavage at abasic RNA sites can occur via β,δ-elimination and 2′,3′-cyclophosphate formation. We found that β,δ-elimination was 154-fold slower compared to the same mechanism in abasic DNA. Overall strand cleavage of abasic RNA (including cyclophosphate formation) was still 16.8 times slower compared to abasic DNA. In the presence of aniline at pH 4.6, where only β,δ-elimination contributes to strand cleavage, a 15-fold reduced cleavage rate at the RNA abasic site was observed. Thus abasic RNA is significantly more stable than abasic DNA. The higher stability of abasic RNA is discussed in the context of its potential biological role.     

Evidence for a second function for Saccharomyces cerevisiae Rev1p

The function of the Saccharomyces cerevisiae REV1 gene is required for translesion replication and mutagenesis induced by a wide variety of DNA-damaging agents. We showed previously that Rev1p possesses a deoxycytidyl transferase activity, which incorporates dCMP opposite abasic sites in the DNA template, and that dCMP insertion is the major event during bypass of an abasic site in vivo. However, we now find that Rev1p function is needed for the bypass of a T-T (6-4) UV photoproduct, a process in which dCMP incorporation occurs only very rarely, indicating that Rev1p possesses a second function. In addition, we find that Rev1p function is, as expected, required for bypass of an abasic site. However, replication past this lesion was also much reduced in the G-193R rev1-1 mutant, which we find retains substantial levels of deoxycytidyl transferase activity. This mutant is, therefore, presumably deficient principally in the second, at present poorly defined, function. The bypass of an abasic site and T-T (6-4) lesion also depended on REV3 function, but neither it nor REV1 was required for replication past the T-T dimer; bypass of this lesion presumably depends on another enzyme.     

Plant DNA-damage repair/toleration 100 protein repairs UV-B-induced DNA damage

We report the characterization of VvDRT100-L, a grape DNA-damage repair/toleration 100 protein. VvDRT100-L has nine leucine-rich repeats and belongs to the plant DRT100 protein family. VvDRT100-L is expressed abundantly in green organs of grapevines, including tendrils, leaves, and green berry skins. The overexpression of VvDRT100-L in Arabidopsis plants decreased the number of abasic sites and the frequency of DNA single-strand breaks in the DNA damaged by UV-B irradiation, whereas UV-B irradiation markedly increased the number of abasic sites and the frequency of DNA single-strand breaks in T-DNA insertion mutant drt100 plants. VvDRT100-L-overexpressing plants remained viable and noticeably healthy under lethal UV doses, suggesting that VvDRT100-L may enhance UV tolerance in plant. Taken together, we concluded that VvDRT100-L might play an important role in the repair and toleration of UV-B-induced DNA damage. These findings would help us better understand how plants acquire UV stress acclimation, tolerance and DNA repair.     

Two glycosylase/abasic lyases from Neisseria mucosa that initiate DNA repair at sites of UV-induced photoproducts

Diverse organisms ranging from Escherichia coli to humans contain a variety of DNA repair proteins that function in the removal of damage caused by shortwave UV light. This study reports the identification, purification, and biochemical characterization of two DNA glycosylases with associated abasic lyase activity from Neisseria mucosa. These enzymes, pyrimidine dimer glycosylase I and II (Nmu-pdg I and Nmu-pdg II), were purified 30,000- and 10,000-fold, respectively. SDS-polyacrylamide gel electrophoresis analysis indicated that Nmu-pdg I is approximately 30 kDa, whereas Nmu-pdg II is approximately 19 kDa. The N-terminal amino acid sequence of Nmu-pdg II exhibits 64 and 66% identity with E. coli and Hemophilus parainfluenzae endonuclease III, respectively. Both Nmu-pdg I and Nmu-pdg II were found to have broad substrate specificities, as evidenced by their ability to incise DNA containing many types of UV and some types of oxidative damage. Consistent with other glycosylase/abasic lyases, the existence of a covalent enzyme-DNA complex could be demonstrated for both Nmu-pdg I and II when reactions were carried out in the presence of sodium borohydride. These data indicate the involvement of an amino group in the catalytic reaction mechanism of both enzymes.     

Damage recognition by UV damage endonuclease from Schizosaccharomyces pombe

UV damage endonuclease (UVDE) from Schizosaccharomyces pombe initiates repair of UV lesions and abasic sites by nicking the DNA 5′ to the damaged site. In this paper we show that in addition UVDE incises DNA containing a single-strand nick or gap, but that the enzymatic activity on these substrates as well as on abasic sites strongly depends on the presence of a neighbouring pyrimidine residue. This indicates that, although UVDE may have been derived from an ancestral AP endonuclease its major substrate is a UV lesion and not an AP site. We propose that UVDE rotates two nucleotides into a pocket of the protein in order to bring the scissile bond close to the active site and that purine bases are excluded from this pocket. We also show that in the DNA complex residue Tyr-358 of UVDE penetrates the DNA helix causing unstacking of two residues opposite the lesion, thereby stabilizing the protein–DNA interaction, most likely by promoting bending of the DNA. In the absence of Tyr-358 the enzyme exhibits an increased catalytic activity on UV-induced lesions, but only at a lower pH of 6.5. At physiological conditions (pH 7.5) the mutant protein completely looses its catalytic activity although it can still bind to the DNA. We propose that in addition to stabilizing the bend in the DNA the hydrophobic side chain of Tyr-358 shields the active site from exposure to the solvent.     

Cleavage of single- and double-stranded DNAs containing an abasic residue by Escherichia coli exonuclease III (AP endonuclease VI).

The Escherichia coli exonuclease III (AP endonuclease VI) is a DNA-repair enzyme that hydrolyzes the phosphodiester bond 5' to an abasic site in DNA. To study how the enzyme recognizes the abasic site, we used oligonucleotides containing a synthetic abasic site at any desired position in the sequence. We prepared oligonucleotides containing an abasic residue such as 2'-deoxyribosylformamide, 2'-deoxyribose, 1',2'-dideoxy ribofuranose or propanediol. Duplex oligonucleotides containing an abasic residue used in this study were cleaved on the 5' side of the abasic site by exonuclease III in spite of the varieties of the bases opposite and adjacent to the abasic site. In addition, we observed that the enzyme cleaved single-stranded oligonucleotides containing an abasic site on the 5' side of the abasic site. These findings suggest that the enzyme may principally recognize the DNA-pocket formed at an abasic site. The indole ring of the tryptophan 212 residue of the exonuclease III is probably intercalated to the abasic site. The tryptophan in the vicinity of the catalytic site is conserved in the type II AP endonuclease from various organisms.     

New structural and mechanistic insight into the A-rule and the instructional and non-instructional behavior of DNA photoproducts and other lesions

The A-rule in mutagenesis was originally proposed to explain the preponderance of X-->T mutations observed for abasic sites and UV damaged sites. It was deduced that when a polymerase was faced with a non-instructional lesion, typified by an abasic site, it would preferentially incorporate an A. In the absence of any other compelling explanation, any lesion causing an X-->T mutation has often been classified as non-instructional to account for its apparent lack of instructional ability. The A-rule and the classification of lesions as non-instructional were formulated before the active sites of any polymerases or the mechanism by which they synthesized DNA were known. Since then, much structural and kinetic data on DNA polymerases has emerged to suggest mechanistic explanations for the A-rule and the instructive and non-instructive behavior of lesions such as cis-syn dimers. Polymerases involved in the replication of undamaged DNA have highly constrained active sites that evolved to only accommodate the templating base and the complementary nucleotide and as a result are relatively intolerant of modifications that alter the size and shape of the nascent base pair. On the other hand, DNA damage bypass polymerases have much more open and less constrained active sites, which are much more tolerant of modifications. An otherwise instructional lesion would become non-instructional if it were unable to fit into the active site, and thereby behave transiently like an abasic site, leading to the insertion of whichever nucleotide is favored by the polymerase, generally an A. In this review, what is known about the active sites and mechanisms of replicative and DNA damage bypass polymerases will be discussed with regard to the A-rule and non-instructive behavior of lesions, typified by dipyrimidine photoproducts.     

Effects of the presence of an aldehydic abasic site on the thermal stability and rates of helix opening and closing of duplex DNA.

The presence of an abasic site in duplex DNA lowers the thermodynamic stability, as monitored by the optical melting temperature, and decreases the rate of imino proton exchange with water, by about an order of magnitude, as monitored by direct measurement of both the exchange lifetimes and the imino proton T1S. The exchange lifetimes of the imino protons with water as a function of base catalyst concentration were analyzed to determine the origin of the effect of the abasic site on imino exchange lifetimes. Analysis of the results showed that the helix opening rate is not significantly changed by the presence of an abasic site. The differences in exchange lifetimes are attributed to a faster helix closing rate in the presence of an abasic site. The faster rate of helix closing may be an important contribution to the stability of abasic sites in duplex DNA to base-catalyzed elimination reaction. It is noted that duplex DNAs containing analogues of the aldehydic abasic site apparently do not exhibit these exchange lifetime effects.     

Is a thymine dimer replicated via a transient abasic site intermediate? A comparative study using non-natural nucleotides

UV light causes the formation of thymine dimers that can be misreplicated to induce mutagenesis and carcinogenesis. This report describes the use of a series of non-natural indolyl nucleotides in probing the ability of the high-fidelity bacteriophage T4 DNA polymerase to replicate this class of DNA lesion. Kinetic data reveal that indolyl analogues containing large pi-electron surface areas are incorporated opposite the thymine dimer almost as effectively as an abasic site, a noninstructional lesion. However, there are notable differences in the kinetic parameters for each DNA lesion that indicate distinct mechanisms for their replication. For example, the rate constants for incorporation opposite a thymine dimer are considerably slower than those measured opposite an abasic site. In addition, the magnitude of these rate constants depends equally upon contributions from pi-electron density and the overall size of the analogue. In contrast, binding of a nucleotide opposite a thymine dimer is directly correlated with the overall pi-electron surface area of the incoming dXTP. In addition to defining the kinetics of polymerization, we also provide the first reported characterization of the enzymatic removal of natural and non-natural nucleotides paired opposite a thymine dimer through exonuclease degradation or pyrophosphorolysis activity. Surprisingly, the exonuclease activity of the bacteriophage enzyme is activated by a thymine dimer but not by an abasic site. This dichotomy suggests that the polymerase can "sense" bulky lesions to partition the damaged DNA into the exonuclease domain. The data for both nucleotide incorporation and excision are used to propose models accounting for polymerase "switching" during translesion DNA synthesis.     

Improved measurement of dibenzo[a,l]pyrene-induced abasic sites by the aldehyde-reactive probe assay

Dibenzo[a,l]pyrene (DB[a,l]P) induces abundant amounts of depurinating adducts that spontaneously dissociate to form abasic sites in DNA. However, several previous studies that used the aldehyde-reactive probe (ARP) assay, could not verify abasic site formation by DB[a,l]P. Therefore, we examined whether a modification of the ARP assay would allow greater quantification of abasic sites. A previous study indicated that the abasic site quantification is improved by letting ARP trap the nascent abasic sites in cells, before extracting DNA for the assay. To test whether the addition of ARP to the DB[a,l]P-DNA adduct-forming reaction would improve abasic site quantification, we treated calf thymus DNA (0.625 mg/mL) with DB[a,l]P (80 microM) and 3-methylcholanthrene-treated rat liver microsomes with or without ARP (3 mM). The inclusion of ARP in the adduct-forming reaction resulted in significantly greater detection of abasic sites (62 lesions/10(6) bp versus 3.7 lesions/10(6) bp). DB[a,l]P also induces DNA strand breaks. The strand breaks may occur at abasic sites and by other mechanisms, such as oxidative damage. ARP/O-methoxyamine-abasic site conjugates are refractory to strand breakage, however, ARP or O-methoxyamine (3-10 mM) could only partially protect DB[a,l]P-induced DNA degradation, presumably by protecting the abasic sites, but not the other strand breaks. These results suggest that if DNA strand breakages occur at the abasic sites or at bases flanking them, and the fragments are lost during DNA extraction, abasic site estimation could be compromised. To obtain an independent line of evidence for abasic site formation in DB[a,l]P-treated cells, mouse Mbeta16 fibroblasts were treated with DB[a,l]P and O-methoxyamine. O-Methoxyamine is known to potentiate cytotoxicity of abasic site-inducing chemicals by forming abasic site conjugates, which partially inhibits their repair. O-Methoxyamine was found to increase DB[a,l]P cytotoxicity in these cells, supporting the idea that DB[a,l]P formed abasic sites. In summary, the inclusion of ARP in the DB[a,l]P-DNA adduct-forming reaction traps and protects the nascent abasic sites, allowing an improved quantification of abasic sites.     

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.     

Dynamics of translesion DNA synthesis catalyzed by the bacteriophage T4 exonuclease-deficient DNA polymerase

The mechanism and dynamics of translesion DNA synthesis were evaluated using primer/templates containing a tetrahydrofuran moiety designed to mimic an abasic site. Steady-state kinetic analysis reveals that the T4 DNA polymerase preferentially incorporates dATP across from the abasic site with 100-fold higher efficiency than the other nucleoside triphosphates. Under steady-state conditions, the catalytic efficiency of dATP incorporation across from an abasic site is only 220-fold lower than that across from T. Surprisingly, misincorporation across from T is favored 4-6-fold versus replication across an abasic site, suggesting that the dynamics of the polymerization cycle are differentially affected by formation of aberrant base pairs as opposed to the lack of base-pairing capabilities afforded by the abasic site. Linear pre-steady-state time courses were obtained for the incorporation of any dNTP across from an abasic site, indicating that chemistry or a step prior to chemistry is rate-limiting for the polymerization cycle. Low elemental effects (<3) measured by substituting the alpha-thiotriphosphate analogues for dATP, dCTP, and dGTP indicate that chemistry is not solely rate-limiting. Single-turnover experiments yield kpol/Kd values that are essentially identical to kcat/Km values and provide further evidence that the conformational change preceding chemistry is rate-limiting. Extension beyond an A:abasic mispair is approximately 20-fold and 100-fold faster than extension beyond a G:abasic mispair or C:abasic mispair, respectively. Extension from the G:abasic or A:abasic site mispair generates significant elemental effects (between 5 and 20) and suggests that chemistry is at least partially rate-limiting for extension beyond either mispair.     

Quantification of DNA strand breaks and abasic sites by oxime derivatization and accelerator mass spectrometry: application to gamma-radiation and peroxynitrite

We report a highly sensitive method to quantify abasic sites and deoxyribose oxidation products arising in damaged DNA. The method exploits the reaction of aldehyde- and ketone-containing deoxyribose oxidation products and abasic sites with [(14)C]methoxyamine to form stable oxime derivatives, as originally described by Talpaert-Borle and Liuzzi [Reaction of apurinic/apyrimidinic sites with [(14)C]methoxyamine. A method for the quantitative assay of AP sites in DNA, Biochim. Biophys. Acta 740 (1983) 410-416]. The sensitivity of the method was dramatically improved by the application of accelerator mass spectrometry to quantify the (14)C, with a limit of detection of 1 lesion in 10(6) nucleotides in 1 microg of DNA. The method was validated using DNA containing a defined quantity of abasic sites, with a >0.95 correlation between the quantities of abasic sites and those of methoxyamine labels. The original applications of this and similar oxyamine derivatization methods have assumed that abasic sites are the only aldehyde-containing DNA damage products. However, deoxyribose oxidation produces strand breaks and abasic sites containing a variety of degradation products with aldehyde and ketone moieties. To assess the utility of methoxyamine labeling for quantifying strand breaks and abasic sites, the method was applied to plasmid DNA treated with gamma-radiation and peroxynitrite. For gamma-radiation, there was a 0.99 correlation between the quantity of methoxyamine labels and the quantity of strand breaks and abasic sites determined by a plasmid nicking assay; the abasic sites comprised less than 10% of the radiation-induced DNA damage. Studies with peroxynitrite demonstrate that the method, in conjunction with DNA repair enzymes that remove damaged bases to produce aldehydic sugar residues or abasic sites, is also applicable to quantifying nucleobase lesions in addition to strand break products. Compared to other abasic site quantification techniques, the modified method offers the advantage of providing a straightforward and direct measurement of aldehyde- and ketone-containing strand breaks and abasic sites, with the potential for direct labeling in cells prior to DNA isolation.     

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.     

Base excision repair intermediates as topoisomerase II poisons

Abasic sites are the most commonly formed DNA lesions in the cell and are produced by numerous endogenous and environmental insults. In addition, they are generated by the initial step of base excision repair (BER). When located within a topoisomerase II DNA cleavage site, "intact" abasic sites act as topoisomerase II poisons and dramatically stimulate enzyme-mediated DNA scission. However, most abasic sites in cells are not intact. They exist as processed BER intermediates that contain DNA strand breaks proximal to the damaged residue. When strand breaks are located within a topoisomerase II DNA cleavage site, they create suicide substrates that are not religated readily by the enzyme and can generate permanent double-stranded DNA breaks. Consequently, the effects of processed abasic sites on DNA cleavage by human topoisomerase IIalpha were examined. Unlike substrates with intact abasic sites, model BER intermediates containing 5'- or 3'-nicked abasic sites or deoxyribosephosphate flaps were suicide substrates. Furthermore, abasic sites flanked by 5'- or 3'-nicks were potent topoisomerase II poisons, enhancing DNA scission approximately 10-fold compared with corresponding nicked oligonucleotides that lacked abasic sites. These findings suggest that topoisomerase II is able to convert processed BER intermediates to permanent double-stranded DNA breaks.     

Abasic sites from cytosine as termination signals for DNA synthesis.

DNA with abasic sites has been prepared by deamination of cytosine followed by treatment of the product with uracil N-glycosylase. Termination in vitro on such templates does not occur until treatment with uracil N-glycosylase. DNA terminated one base before abasic sites created from C's has been used as a template in "second stage" reactions. With enzymes devoid or deficient in 3' greater than 5' exonuclease activity purines, particularly adenine, are preferentially added opposite the putative abasic site. 2-Aminopurine behaves more like adenine than like guanine in these experiments. Polymerase beta preferentially incorporates A opposite abasic sites produced from T, and G opposite abasic sites produced from C. We have eliminated an obvious artefact (e.g. strand switching) which might account for this observation.     

Specificity of the dRP/AP lyase of Ku promotes nonhomologous end joining (NHEJ) fidelity at damaged ends

Nonhomologous end joining (NHEJ) is essential for efficient repair of chromosome breaks. However, the NHEJ ligation step is often obstructed by break-associated nucleotide damage, including base loss (abasic site or 5'-dRP/AP sites). Ku, a 5'-dRP/AP lyase, can excise such damage at ends in preparation for the ligation step. We show here that this activity is greatest if the abasic site is within a short 5' overhang, when this activity is necessary and sufficient to prepare such termini for ligation. In contrast, Ku is less active near 3' strand termini, where excision would leave a ligation-blocking α,β-unsaturated aldehyde. The Ku AP lyase activity is also strongly suppressed by as little as two paired bases 5' of the abasic site. Importantly, in vitro end joining experiments show that abasic sites significantly embedded in double-stranded DNA do not block the NHEJ ligation step. Suppression of the excision activity of Ku in this context therefore is not essential for ligation and further helps NHEJ retain terminal sequence in junctions. We show that the DNA between the 5' terminus and the abasic site can also be retained in junctions formed by cellular NHEJ, indicating that these sites are at least partly resistant to other abasic site-cleaving activities as well. High levels of the 5'-dRP/AP lyase activity of Ku are thus restricted to substrates where excision of an abasic site is required for ligation, a degree of specificity that promotes more accurate joining.