Active-site determination of a pyrimidine dimer glycosylase

One mechanism for the repair of UV-induced DNA damage is the base excision repair pathway. The initial step in this pathway and the specificity for the type of damage that is to be repaired reside in DNA glycosylase/abasic (AP) lyases. Cleavage of the glycosyl bond of the 5' pyrimidine of a cyclobutane pyrimidine dimer is hypothesized to occur through the destabilization of the glycosyl bond by protonation of the base or sugar with a concomitant nucleophilic attack on C1' of the deoxyribose moiety. Based on mechanistic biochemical information from several glycosylase/AP lyases and the structural information on the bacteriophage T4 pyrimidine dimer glycosylase (T4-pdg), the catalytic mechanism has been investigated for the Chlorella virus pyrimidine dimer glycosylase (cv-pdg). As predicted from modeling studies and reaction mechanisms, the primary amine that initiates the nucleophilic displacement reaction could be trapped as a covalent imine intermediate and its identity determined by sequential Edman degradation. The primary amine was identified as the alpha-amino group on the N-terminal Thr2. Site-directed mutagenesis was subsequently used to confirm the conclusions that the alpha-amino group of cv-pdg is the active-site nucleophile.     

Purification and characterization of a novel UV lesion-specific DNA glycosylase/AP lyase from Bacillus sphaericus

The purification and characterization of a pyrimidine dimer-specific glycosylase/AP lyase from Bacillus sphaericus (Bsp-pdg) are reported. Bsp-pdg is highly specific for DNA containing the cis-syn cyclobutane pyrimidine dimer, displaying no detectable activity on oligonucleotides with trans-syn I, trans-syn II, (6-4), or Dewar photoproducts. Like other glycosylase/AP lyases that sequentially cleave the N--glycosyl bond of the 5' pyrimidine of a cyclobutane pyrimidine dimer, and the phosphodiester backbone, this enzyme appears to utilize a primary amine as the attacking nucleophile. The formation of a covalent enzyme-DNA imino intermediate is evidenced by the ability to trap this protein-DNA complex by reduction with sodium borohydride. Also consistent with its AP lyase activity, Bsp-pdg was shown to incise an AP site-containing oligonucleotide, yielding beta- and delta-elimination products. N-terminal amino acid sequence analysis of this 26 kDa protein revealed little amino acid homology to any previously reported protein. This is the first report of a glycosylase/AP lyase enzyme from Bacillus sphaericus that is specific for cis-syn pyrimidine dimers.     

Modulation of the processive abasic site lyase activity of a pyrimidine dimer glycosylase

The repair of cis-syn cyclobutane pyrimidine dimers (CPDs) can be initiated via the base excision repair (BER) pathway, utilizing pyrimidine dimer-specific DNA glycosylase/lyase enzymes (pdgs). However, prior to incision at lesion sites, these enzymes bind to non-damaged DNAs through charge-charge interactions. Following initial binding to DNA containing multiple lesions, the enzyme incises at most of these sites prior to dissociation. If a subset of these lesions are in close proximity, clustered breaks may be produced that could lead to decreased cell viability or increased mutagenesis. Based on the co-crystal structures of bacteriophage T4-pdg and homology modeling of a related enzyme from Paramecium bursaria Chlorella virus-1, the structure-function basis for the processive incision activity for both enzymes was investigated using site-directed mutagenesis. An assay was developed that quantitatively measured the rates of incision by these enzymes at clustered apurinic/apyrimidinic (AP) sites. Mathematical modeling of random (distributive) versus processive incisions predicted major differences in the rate and extent of the accumulation of singly nicked DNAs between these two mechanisms. Comparisons of these models with biochemical nicking data revealed significant changes in the damage search mechanisms between wild-type pdgs and most of the mutant enzymes. Several conserved arginine residues were shown to be critical for the processivity of the incision activity, without interfering with catalysis at AP sites. Comparable results were measured for incision at clustered CPD sites in plasmid DNAs. These data reveal that pdgs can be rationally engineered to retain full catalytic activity, while dramatically altering mechanisms of target site location.     

Structure of T4 pyrimidine dimer glycosylase in a reduced imine covalent complex with abasic site-containing DNA

The base excision repair (BER) pathway for ultraviolet light (UV)-induced cyclobutane pyrimidine dimers is initiated by DNA glycosylases that also possess abasic (AP) site lyase activity. The prototypical enzyme known to catalyze these reactions is the T4 pyrimidine dimer glycosylase (T4-Pdg). The fundamental chemical reactions and the critical amino acids that lead to both glycosyl and phosphodiester bond scission are known. Catalysis proceeds via a protonated imine covalent intermediate between the alpha-amino group of the N-terminal threonine residue and the C1' of the deoxyribose sugar of the 5' pyrimidine at the dimer site. This covalent complex can be trapped as an irreversible, reduced cross-linked DNA-protein complex by incubation with a strong reducing agent. This active site trapping reaction is equally efficient on DNA substrates containing pyrimidine dimers or AP sites. Herein, we report the co-crystal structure of T4-Pdg as a reduced covalent complex with an AP site-containing duplex oligodeoxynucleotide. This high-resolution structure reveals essential precatalytic and catalytic features, including flipping of the nucleotide opposite the AP site, a sharp kink (approximately 66 degrees ) in the DNA at the dimer site and the covalent bond linking the enzyme to the DNA. Superposition of this structure with a previously published co-crystal structure of a catalytically incompetent mutant of T4-Pdg with cyclobutane dimer-containing DNA reveals new insights into the structural requirements and the mechanisms involved in DNA bending, nucleotide flipping and catalytic reaction.     

The reaction mechanism of DNA glycosylase/AP lyases at abasic sites

DNA glycosylase and glycosylase/abasic (AP) lyases are the enzymes responsible for initiating the base excision repair pathway by recognizing the damaged target base and catalyzing the breakage of the base-sugar glycosyl bond. The subset of glycosylases that have an associated AP lyase activity also catalyze DNA strand breakage at the resulting or preexisting AP site via a beta-elimination reaction, proceeding from an enzyme-DNA imino intermediate. Two distinct mechanisms have been proposed for the formation of this intermediate. These mechanisms essentially differ in the nature of the first bond broken and the timing of the opening of the deoxyribose ring. The data presented here demonstrate that the combined rate of sugar ring opening and reduction of the sugar is significantly slower than the rate of formation of a T4-pyrimidine dimer glycosylase (T4-pdg)-DNA intermediate. Using a methyl-deoxyribofuranose AP-site analogue that is incapable of undergoing sugar ring opening, it was demonstrated that the T4-pdg reaction can initiate at the ring-closed form, albeit at a drastically reduced rate. T4-pdg preferentially cleaved the beta-anomer of the methyl-deoxyribofuranose AP site analogue. This is consistent with a mechanism in which the methoxy group is backside-displaced by the amino group from the alpha-face of the deoxyribofuranose ring. In addition, studies examining rates of sugar-aldehyde reduction and the sodium borohydride concentration dependence of the rate of formation of the covalent imine intermediate suggest that the reduction of the intermediate is rate-limiting in the reaction.     

The interaction of T4 endonuclease V E23Q mutant with thymine dimer- and tetrahydrofuran-containing DNA.

The interaction between endonuclease V, the cyclobutane pyrimidine dimer-specific N-glycosylase/abasic lyase from bacteriophage T4, and DNA was investigated by DNase I footprinting methods. The catalytically inactive mutant E23Q was found to interact with a smaller region of DNA at the abasic site analog, tetrahydrofuran, than at a thymine dimer site. Like the wild-type enzyme, the mutant contacted the DNA substrates primarily on the strand opposite the damage. The various complexes examined by footprinting techniques represent distinct points along the catalytic pathway of endonuclease V: before catalysis at a dimer, after N-glycosylase action but before abasic lyase action, and before catalysis at an abasic site. The differences between the footprints of the mutant and wild-type enzymes on both DNA substrates likely represent subtly different conformations within these complexes.     

Comparison of the cleavage of pyrimidine dimers by the bacteriophage T4 and Micrococcus luteus UV-specific endonucleases

A comparison was made of the activity of the UV-specific endonucleases of bacteriophage T4 (T4 endonuclease V) and of Micrococcus luteus on ultravilet light-irradiated DNA substrates of defined sequence. The two enzymes cleave DNA at the site of pyrimidine dimers with the same frequency. The products of the cleavage reaction are the same, suggesting that the scission of DNA by T4 endonuclease V occurs via the combined actin of a pyrimidine dimer specific DNA glycosylase and an apyrimidinic-apurinic (AP) endonuclease as was recently shown for the M. luteus enzyme. The pyrimidine dimer DNA-glycosylase activity of both enzymes is more active on double-stranded DNA than it is on single-stranded DNA.     

Selective inhibition by methoxyamine of the apurinic/apyrimidinic endonuclease activity associated with pyrimidine dimer-DNA glycosylases from Micrococcus luteus and bacteriophage T4

The UV endonucleases [endodeoxyribonuclease (pyrimidine dimer), EC 3.1.25.1] from Micrococcus luteus and bacteriophage T4 possess two catalytic activities specific for the site of cyclobutane pyrimidine dimers in UV-irradiated DNA: a DNA glycosylase that cleaves the 5'-glycosyl bond of the dimerized pyrimidines and an apurinic/apyrimidinic (AP) endonuclease that thereupon incises the phosphodiester bond 3' to the resulting apyrimidinic site. We have explored the potential use of methoxyamine, a chemical that reacts at neutral pH with AP sites in DNA, as a selective inhibitor of the AP endonuclease activities residing in the M. luteus and T4 enzymes. The presence of 50 mM methoxyamine during incubation of UV- (4 kJ/m2, 254 nm) treated, [3H]thymine-labeled poly(dA).poly(dT) with either enzyme preparation was found to protect completely the irradiated copolymer from endonucleolytic attack at dimer sites, as assayed by yield of acid-soluble radioactivity. In contrast, the dimer-DNA glycosylase activity of each enzyme remained fully functional, as monitored retrospectively by release of free thymine after either photochemical- (5 kJ/m2, 254 nm) or photoenzymic- (Escherichia coli photolyase plus visible light) induced reversal of pyrimidine dimers in the UV-damaged substrate. Our data demonstrate that the inhibition of the strand-incision reaction arises because of chemical modification of the AP sites and is not due to inactivation of the enzyme by methoxyamine. Our results, combined with earlier findings for 5'-acting AP endonucleases, strongly suggest that methoxyamine is a highly specific inhibitor of virtually all AP endonucleases, irrespective of their modes of action, and may therefore prove useful in a wide variety of DNA repair studies.     

Characterization of a wide range base-damage-endonuclease activity of mammalian rpS3

Mammalian rpS3, a ribosomal protein S3 with a DNA repair endonuclease activity, nicks heavily UV-irradiated DNA and DNA containing AP sites. RpS3 calls for a novel endonucleolytic activity on AP sites generated from pyrimidine dimers by T4 pyrimidine dimer glycosylase activity. This study revealed that rpS3 cleaves the lesions including AP sites, thymine glycols, and other UV damaged lesions such as pyrimidine dimers. This enzyme does not have a glycosylase activity as predicted from its amino acid sequence. However, it has an endonuclease activity on DNA containing thymine glycol, which is exactly overlapped with UV-irradiated or AP DNAs, indicating that rpS3 cleaves phosphodiester bonds of DNAs containing altered bases with broad specificity acting as a base-damage-endonuclease. RpS3 cleaves supercoiled UV damaged DNA more efficiently than the relaxed counterpart, and the endonuclease activity of rpS3 was inhibited by MgCl2 on AP DNA but not on UV-irradiated DNA.     

Determination of active site residues in Escherichia coli endonuclease VIII.

Endonuclease VIII from Escherichia coli is a DNA glycosylase/lyase that removes oxidatively damaged bases. EndoVIII is a functional homologue of endonuclease III, but a sequence homologue of formamidopyrimidine-DNA glycosylase (Fpg). Using multiple sequence alignments, we have identified six target residues in endoVIII that may be involved in the enzyme's glycosylase and/or lyase functions: the N-terminal proline, and five acidic residues that are completely conserved in the endoVIII-Fpg proteins. To investigate the contribution of these residues, site-directed mutagenesis was used to create seven mutants: P2T, E3D, E3Q, E6Q, D129N, D160N, and E174Q. Each mutant was assayed both for lyase activity on abasic (AP) sites and for glycosylase/lyase activity on 5-hydroxyuracil, thymine glycol, and gamma-irradiated DNA with multiple lesions. The P2T mutant did not have lyase or glycosylase/lyase activity but could efficiently form Schiff base intermediates on AP sites. E6Q, D129N, and D160N behaved essentially as endoVIII in all assays. E3D, E3Q, and E174Q retained significant AP lyase activity but had severely diminished or abolished glycosylase/lyase activities on the DNA lesions tested. These studies provide detailed predictions concerning the active site of endoVIII.     

Investigations of pyrimidine dimer glycosylases--a paradigm for DNA base excision repair enzymology

The most prevalent forms of cancer in humans are the non-melanoma skin cancers, with over a million new cases diagnosed in the United States annually. The portions of the body where these cancers arise are almost exclusively on the most heavily sun-exposed tissues. It is now well established that exposure to ultraviolet light (UV) causes not only damage to DNA that subsequently generates mutations and a transformed phenotype, but also UV-induced immunosuppression. Human cells have only one mechanism to remove the UV-induced dipyrimidine DNA photoproducts: nucleotide excision repair (NER). However, simpler organisms such as bacteria, bacteriophages and some eukaryotic viruses contain up to three distinct mechanisms to initiate the repair of UV-induced dipyrimidine adducts: NER, base excision repair (BER) and photoreversal. This review will focus on the biology and the mechanisms of DNA glycosylase/AP lyases that initiate BER of cis-syn cyclobutane pyrimidine dimers. One of these enzymes, the T4 pyrimidine dimer glycosylase (T4-pdg), formerly known as T4 endonuclease V has served as a model in the study of this entire class of enzymes. It was the first DNA repair enzyme: (1) for which a biologically significant processive nicking activity was demonstrated; (2) to have its active site determined, (3) to have its crystal structure solved, (4) to be shown to carry out nucleotide flipping, and (5) to be used in human clinical trials for disease prevention.     

Antigen structural requirements for recognition by a cyclobutane thymine dimer-specific monoclonal antibody.

A monoclonal antibody (TDM-2) specific to a UV-induced cyclobutane pyrimidine dimer (T[cis-syn]T) has previously been established; however,the immunization had used UV-irradiated calf-thymus DNA containing a heterogeneous mixture of photoproduct sites. We investigated here the structural requirements of antigen recognition by the antibody using chemically synthesized antigen analogs. TDM-2 bound with cis-syn,but not trans-syn thymine dimer,and could bind strongly with four nucleotide analogs in which the cis-syn pyrimidine dimer was located in the center. Antigen analogs containing abasic linkers at the 5'- or 3'-side of the cis-syn cyclobutane pyrimidine dimer were synthesized and tested for binding to TDM-2. The results indicated that TDM-2 recognizes not only the cyclobutane ring but also both the 5'- and 3'-side nucleosides of the cyclobutane dimer. Furthermore,it was proved that either the 5'- or 3'-side phosphate group at a cyclobutane dimer site was absolutely required for the affinity to TDM-2. The antibody showed a strong binding to single stranded DNA but indicated little binding to double stranded DNA.     

U-U and T-T cyclobutane dimers have different mutational properties.

We have examined the mutagenic properties in E. coli of single stranded vectors containing a uniquely placed cis-syn or trans-syn uracil-uracil cyclobutane dimer in the sequence 5' GCAAGUUGGAG 3', and compared these with the properties of the corresponding T-T dimers in the same sequence context. The frequencies with which U-U and T-T photoproducts were bypassed were similar in SOS induced cells, and each induced similar frequencies of mutations. However, although both U-U and T-T cis-syn dimers showed a preference for misincorporation in about 5-7% of the replication products, with T or G being incorporated in place of A, the ratios of these events differed, being > 4:1 for T-T cis-syn, but only 2:1 for U-U cis-syn. A shift towards G insertion opposite dimerized uracil was also found with the trans-syn dimers, but the difference was greater; T and G were misincorporated opposite the U-U trans-syn dimer in a ratio of 1:2, compared with 4:1 for its T-T counterpart. In addition, the U-U dimer induced only nucleotide substitutions, unlike the T-T photoproduct which induced single nucleotide deletions as well as substitutions. We conclude that even relatively minor differences in photoproduct structure, such as the presence of a methyl group at C-5, can alter mutational properties, and that such properties cannot depend only on the attributes of the DNA polymerase. Neither the efficiency of bypass, the error frequency nor the mutation spectrum of either U-U isomer is influenced by DNA uracil glycosylase. In vitro, the U-U cis-syn dimer is a substrate for DNA photolyase, but not for the glycosylase.     

Structure/function analysis of the Ala116-->Lys121 region of endonuclease V by random targeted mutagenesis.

Endonuclease V is the product of the denV gene of bacteriophage T4 and is responsible for the recognition and repair of pyrimidine dimers due to UV irradiation of DNA. This is accomplished by a two-step mechanism involving incision at the site of the lesion followed by cleavage of the phosphate backbone. In order to better understand this molecule, and to validate our new mutagenesis procedure, we have constructed a series of random mutations within the region Ala116-->Lys121 using a random targeted mutagenesis procedure developed for this study. The results presented here suggest an important role for this region in the stabilization of the thymine dimer-containing substrate. These mutants also confirm a direct correlation between survival and both DNA binding and pyrimidine dimer-DNA glycosylase activity. No such correlation exists between survival and AP lyase activity. The results are consistent with the recently published X-ray crystal structure.     

Excision of 5'-terminal deoxyribose phosphate from damaged DNA is catalyzed by the Fpg protein of Escherichia coli.

Homogeneous Fpg protein of Escherichia coli has DNA glycosylase activity which excises some purine bases with damaged imidazole rings, and an activity excising deoxyribose (dR) from DNA at abasic (AP) sites leaving a gap bordered by 5'- and 3'-phosphoryl groups. In addition to these two reported activities, we show that the Fpg protein also catalyzes the excision of 5'-terminal deoxyribose phosphate (dRp) from DNA, which is the principal product formed by the incision of AP endonucleases at abasic sites. Moreover, the rate of the Fpg protein catalysis for the 2,6-diamino-4-hydroxy-5-formamidopyrimidine-DNA glycosylase activity is slower than the activities excising dR from abasic sites and dRp from abasic sites preincised by endonucleases. The product released by the Fpg protein in the excision of 5'-terminal dRp from an abasic site preincised by an AP endonuclease is a single base-free unsaturated dRp, suggesting that the excision results from beta-elimination. The release of 5'-terminal dRp by crude extracts of E. coli from wild type and fpg-mutant strains shows that the Fpg protein is one of the major EDTA-resistant activities catalyzing this reaction.     

Excision repair of pyrimidine dimers from simian virus 40 minichromosomes in vitro

The ability of DNA repair enzymes to carry out excision repair of pyrimidine dimers in SV40 minichromosomes irradiated with 16 to 64 J/m2 of UV light was examined. Half of the dimers were substrate for the DNA glycosylase activity of phage T4 UV endonuclease immediately after irradiation, but this limit decreased to 27% after 2 h at 0 degrees C. Moreover, the apyrimidinic (AP) endonuclease activity of the enzyme did not incise all of the AP sites created by glycosylase activity, although all AP sites were substrate for HeLa AP endonuclease II. The initial rate of the glycosylase was 40% that upon DNA. After incision by the T4 enzyme, excision was mediated by HeLa DNase V (acting with an exonuclease present in the chromatin preparation). Under physiological salt conditions, excision did not proceed appreciably beyond the damaged nucleotides in DNA or chromatin. With chromatin, about 70% of the accessible dimers were removed, but at a rate slower than for DNA. Finally, HeLa DNA polymerase beta was able to fill the short gaps created after dimer excision, and these patches were sealed by T4 DNA ligase. Overall, roughly 30% of the sites incised by the endonuclease were ultimately sealed by the ligase. The resistance of some sites was due to interference with the ligase by the chromatin structure, as only 30-40% of the nicks created in chromatin by pancreatic DNase could be sealed by T4 or HeLa DNA ligases. The overall excision repair process did not detectably disrupt the chromatin structure, since the repair label was recovered in Form I DNA present in 75 S condensed minichromosomes. Although other factors might stimulate the rate of this repair process, it appears that the enzymes utilized could carry out excision repair of chromatin to a limit near that observed at the initial rate in mammalian cells in vivo.     

Activities involved in base excision repair of bacteriophage T4 and lambda DNA in vivo

Summary The in vivo excision repair functions of Escherichia coli exonuclease III and 3-methyladenine DNA glycosylase I, and bacteriophage T4 pyrimidine dimer-DNA glycosylase were investigated. Following exposure of bacteriophage T4 or lambda to methyl methanesulfonate or ultraviolet irradiation, survival was determined by plating on E. coli have various genetic backgrounds. Although exonuclease III was shown to participate in base excision repair initiated by 3-methyladenine DNA glcosylase I, it had no detectable role in base excision repair initiated by the T4 pyrimidine dimer-DNA glycosylase. Despite its 3 apurinic/apyrimidinic endonuclease activity in vitro, T4 pyrimidine dimer-DNA glycosylase, even in large quantities, did not complement mutants defective in exonuclease III in the repair of apurinic sites generated by 3-methyladenine DNA glycosylase I in vivo.     

Site-directed mutagenesis of the T4 endonuclease V gene: the role of arginine-3 in the target search

Endonuclease V, a pyrimidine dimer specific endonuclease in T4 bacteriophage, is able to scan DNA, recognize pyrimidine dimer photoproducts produced by exposure to ultraviolet light, and effectively incise DNA through a two-step mechanism at the damaged bases. The interaction of endonuclease V with nontarget DNA is thought to occur via electrostatic interactions between basic amino acids and the acidic phosphate DNA backbone. Arginine-3 was chosen as a potential candidate for involvement in this protein-nontarget DNA interaction and was extensively mutated to assess its role. The mutations include changes to Asp, Glu, Leu, and Lys and deleting it from the enzyme. Deletion of Arg-3 resulted in an enzyme that retained marginal levels of AP specificity, but no other detectable activity. Charge reversal to Glu-3 and Asp-3 results in proteins that exhibit AP-specific nicking and low levels of dimer-specific nicking. These enzymes are incapable of affecting cellular survival of repair-deficient Escherichia coli after irradiation. Mutations of Arg-3 to Lys-3 or Leu-3 also are unable to complement repair-deficient E. coli. However, these two proteins do exhibit a substantial level of in vitro dimer- and AP-specific nicking. The mechanism by which the Leu-3 and Lys-3 mutant enzymes locate pyrimidine dimers within a population of heavily irradiated plasmid DNA molecules appears to be significantly different from that for the wild-type enzyme. The wild-type endonuclease V processively incises all dimers on an individual plasmid prior to dissociation from that plasmid and subsequent reassociation with other plasmids, yet neither of these mutants exhibits any of the characteristics of this processive nicking activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Utilization of DNA photolyase, pyrimidine dimer endonucleases, and alkali hydrolysis in the analysis of aberrant ABC excinuclease incisions adjacent to UV-induced DNA photoproducts.

ABC excinuclease of Escherichia coli removes 6-4 photoproducts and pyrimidine dimers from DNA by making two single strand incisions, one 8 phosphodiester bonds 5' and another 4 or 5 phosphodiester bonds 3' to the lesion. We describe in this communication a method, which utilizes DNA photolyase from E. coli, pyrimidine dimer endonucleases from M. luteus and bacteriophage T4, and alkali hydrolysis, for analyzing the ABC excinuclease incision pattern corresponding to each of these photoproducts in a DNA fragment. On occasion, ABC excinuclease does not incise DNA exclusively 8 phosphodiester bonds 5' or 4 or 5 phosphodiester bonds 3' to the photoproduct. Both the nature of the adduct (6-4 photoproduct or pyrimidine dimer) and the sequence of neighboring nucleotides influence the incision pattern of ABC excinuclease. We show directly that photolyase stimulates the removal of pyrimidine dimers (but not 6-4 photoproducts) by the excinuclease. Also, photolyase does not repair CC pyrimidine dimers efficiently while it does repair TT or TC pyrimidine dimers.     

Selective inhibition by harmane of the apurinic apyrimidinic endonuclease activity of phage T4-induced UV endonuclease.

1-Methyl-9H-pyrido-[3,4-b]indole (harmane) inhibits the apurinic/apyrimidinic (AP) endonuclease activity of the UV endonuclease induced by phage T4, whereas it stimulates the pyrimidine dimer-DNA glycosylase activity of that enzyme. E. coli endonuclease IV, E. coli endonuclease VI (the AP endonuclease activity associated with E. coli exonuclease III), and E. coli uracil-DNA glycosylase were not inhibited by harmane. Human fibroblast AP endonucleases I and II also were only slightly inhibited. Therefore, harmane is neither a general inhibitor of AP endonucleases, nor a general inhibitor of Class I AP endonucleases which incise DNA on the 3'-side of AP sites. However, E. coli endonuclease III and its associated dihydroxythymine-DNA glycosylase activity were both inhibited by harmane. This observation suggests that harmane may inhibit only AP endonucleases which have associated glycosylase activities.