Different effects on human topoisomerase I by minor groove and intercalated deoxyguanosine adducts derived from two polycyclic aromatic hydrocarbon diol epoxides at or near a normal cleavage site

Topoisomerase I (top1) relieves supercoiling in DNA by forming transient covalent cleavage complexes. These cleavage complexes can accumulate in the presence of damaged DNA or anticancer drugs that either intercalate or lie in the minor groove. Recently we reported that covalent diol epoxide (DE) adducts of benzo[a]pyrene (BaP) at the exocyclic amino group of G(+1) block cleavage at a preferred cleavage site ( approximately CTT-G(+1)G(+2)A approximately ) and cause accumulation of cleavage products at remote sites. In the present study, we have found that the 10S G(+2) adduct of BaP DE, which lies toward the scissile bond in the minor groove, blocks normal cleavage, whereas the 10R isomer, which orients away from this bond, allows normal cleavage but blocks religation. In contrast to BaP, the pair of benzo[c] phenanthrene (BcPh) DE adducts at G(+2), which intercalate from the minor groove either between G(+1)/G(+2) or between G(+2)/A, allow normal cleavage but block religation. Both intercalated BcPh DE adducts at G(+1) suppress normal cleavage, as do both groove bound BaP DE adducts at this position. These studies demonstrate that these DE adducts provide a novel set of tools to study DNA topoisomerases and emphasize the importance of contacts between the minor groove and top1's catalytic site.     

Site-specific DNA transesterification by vaccinia topoisomerase: effects of benzo[alpha]pyrene-dA, 8-oxoguanine, 8-oxoadenine and 2-aminopurine modifications

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C+5C+4C+3T+2T+1p downward arrow N-1 in duplex DNA. Here we study the effects of base modifications on the rate and extent of single-turnover DNA transesterification. Chiral trans opened C-10 R and S adducts of benzo[a]pyrene (BP) 7,8-diol 9,10-epoxide were introduced at single N6-deoxyadenosine (dA) positions within the 3'-G+5G+4G+3A+2A+1T-1A-2 sequence of the nonscissile DNA strand. The R and S BPdA adducts intercalate from the major groove on the 5' and 3' sides of the modified base, respectively, and perturb local base stacking. We found that R and S BPdA modifications at +1A reduced the transesterification rate by a factor of 700-1000 without affecting the yield of the covalent topoisomerase-DNA complex. BPdA modifications at +2A reduced the extent of transesterification and elicited rate decrements of 200- and 7000-fold for the S and R diastereomers, respectively. In contrast, BPdA adducts at the -2 position had no effect on the extent of the reaction and relatively little impact on the rate of cleavage. A more subtle probe of major groove contacts entailed substituting each of the purines of the nonscissile strand with its 8-oxo analog. The +3 oxoG modification slowed transesterification 35-fold, whereas other 8-oxo modifications were benign. 8-Oxo substitutions at the -1 position in the scissile strand slowed single-turnover cleavage by a factor of six but had an even greater slowing effect on religation, which resulted in an increase in the cleavage equilibrium constant. 2-Aminopurine at positions +3, +4, or +5 in the nonscissile strand had no effect on transesterification per se but had synergistic effects when combined with 8-oxoA at position -1 in the scissile strand. These findings illuminate the functional interface of vaccinia topoisomerase with the DNA major groove.     

Chemical and traditional mutagenesis of vaccinia DNA topoisomerase provides insights to cleavage site recognition and transesterification chemistry

Vaccinia DNA topoisomerase IB (TopIB) relaxes supercoils by forming and resealing a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate. Here we gained new insights to the TopIB mechanism through "chemical mutagenesis." Meta-substituted analogs of Tyr(274) were introduced by in vitro translation in the presence of a chemically misacylated tRNA. We report that a meta-OH reduced the rate of DNA cleavage 130-fold without affecting the rate of religation. By contrast, meta-OCH(3) and NO(2) groups elicited only a 6-fold decrement in cleavage rate. We propose that the meta-OH uniquely suppresses deprotonation of the para-OH nucleophile during the cleavage step. Assembly of the vaccinia TopIB active site is triggered by protein contacts with a specific DNA sequence 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrowN (where downward arrow denotes the cleavage site). A signature alpha-helix of the poxvirus TopIB ((132)GKMKYLKENETVG(144)) engages the target site in the major groove and thereby recruits catalytic residue Arg(130) to the active site. The effects of 11 missense mutations at Tyr(136) highlight the importance of van der Waals interactions with the 3'-G(+4)pG(+3)p dinucleotide of the nonscissile strand for DNA cleavage and supercoil relaxation. Asn(140) and Thr(142) donate hydrogen bonds to the pro-(S(p))-oxygen of the G(+3)pA(+2) phosphodiester of the nonscissile strand. Lys(133) and Lys(135) interact with purine nucleobases in the major groove. Whereas none of these side chains is essential per se, an N140A/T142A double mutation reduces the rate of supercoil relaxation and DNA cleavage by 120- and 30-fold, respectively, and a K133A/K135A double mutation slows relaxation and cleavage by 120- and 35-fold, respectively. These results underscore functional redundancy at the TopIB-DNA interface.     

Benzo[a]pyrene-dG adduct interference illuminates the interface of vaccinia topoisomerase with the DNA minor groove

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a pentapyrimidine target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow in duplex DNA. The enzyme engages the target site within a C-shaped protein clamp. Here we mapped the interface of topoisomerase with the DNA minor groove by introducing chiral C-10 R and S 7,8-diol 9,10-epoxide adducts of benzo[a]pyrene (BP) at single N(2)-deoxyguanosine (dG) positions within the nonscissile DNA strand. These trans opened BPdG adducts fit into the minor groove without perturbing helix conformation or base pairing, and the R and S diastereomers are oriented in opposite directions within the minor groove. We measured the effects of the BPdG adducts on the rate and extent of single-turnover DNA transesterification. We observed a sharp margin of interference effects, whereby +5 and -2 BPdG modifications were well tolerated but +4, +3, and -1 BPdG adducts were severely deleterious. Stereoselective effects at the -1 nucleoside (the R isomer interfered, whereas the S isomer did not) delineated at high resolution the downstream border of the minor groove interface. BPdG inhibition of transesterification is likely caused by steric exclusion of constituents of the topoisomerase from the minor groove. We also applied the BPdG interference method to probe the interactions of exonuclease III with the minor groove. DNAs containing these BPdG adducts were protected from digestion by exonuclease III, which was consistently arrested at positions 2-4 nucleotides prior to the BP-modified guanosine.     

Individual nucleotide bases, not base pairs, are critical for triggering site-specific DNA cleavage by vaccinia topoisomerase

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow N(-1) in duplex DNA. Here we study the effects of abasic lesions at individual positions of the scissile and nonscissile strands on the rate of single-turnover DNA transesterification and the cleavage-religation equilibrium. The rate of DNA incision was reduced by factors of 350, 250, 60, and 10 when abasic sites replaced the -1N, +1T, +2T, and +4C bases of the scissile strand, but abasic lesions at +5C and +3C had little or no effect. Abasic lesions in the nonscissile strand in lieu of +4G, +3G, +2A, and +1A reduced the rate of cleavage by factors of 130, 150, 10, and 5, whereas abasic lesions at +5G and -1N had no effect. The striking positional asymmetry of abasic interference on the scissile and nonscissile strands highlights the importance of individual bases, not base pairs, in promoting DNA cleavage. The rate of single-turnover DNA religation by the covalent topoisomerase-DNA complex was insensitive to abasic sites within the CCCTT sequence of the scissile strand, but an abasic lesion at the 5'-OH nucleoside (-1N) of the attacking DNA strand slowed the rate of religation by a factor of 600. Nonscissile strand abasic lesions at +1A and -1N slowed the rate of religation by factors of approximately 140 and 20, respectively, and strongly skewed the cleavage-religation equilibrium toward the covalent complex. Thus, abasic lesions immediately flanking the cleavage site act as topoisomerase poisons.     

Exocyclic DNA lesions stimulate DNA cleavage mediated by human topoisomerase II alpha in vitro and in cultured cells

DNA adducts are mutagenic and clastogenic. Because of their harmful nature, lesions are recognized by many proteins involved in DNA repair. However, mounting evidence suggests that lesions also are recognized by proteins with no obvious role in repair processes. One such protein is topoisomerase II, an essential enzyme that removes knots and tangles from the DNA. Because topoisomerase II generates a protein-linked double-stranded DNA break during its catalytic cycle, it has the potential to fragment the genome. Previous studies indicate that abasic sites and other lesions that distort the double helix stimulate topoisomerase II-mediated DNA cleavage. Therefore, to further explore interactions between DNA lesions and the enzyme, the effects of exocyclic adducts on DNA cleavage mediated by human topoisomerase IIalpha were determined. When located within the four-base overhang of a topoisomerase II cleavage site (at the +2 or +3 position 3' relative to the scissile bond), 3,N(4)-ethenodeoxycytidine, 3,N(4)-etheno-2'-ribocytidine, 1,N(2)-ethenodeoxyguanosine, pyrimido[1,2-a]purin-10(3H)-one deoxyribose (M(1)dG), and 1,N(2)-propanodeoxyguanosine increased DNA scission approximately 5-17-fold. Enhanced cleavage did not result from an increased affinity of topoisomerase IIalpha for adducted DNA or a decreased rate of religation. Therefore, it is concluded that these exocyclic lesions act by accelerating the forward rate of enzyme-mediated DNA scission. Finally, treatment of cultured human cells with 2-chloroacetaldehyde, a reactive metabolite of vinyl chloride that generates etheno adducts, increased cellular levels of DNA cleavage by topoisomerase IIalpha. This finding suggests that type II topoisomerases interact with exocyclic DNA lesions in physiological systems.     

Benzo[c]phenanthrene adducts and nogalamycin inhibit DNA transesterification by vaccinia topoisomerase

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow N(-1) in duplex DNA. Here we study the effects of position-specific DNA intercalators on the rate and extent of single-turnover DNA transesterification. Chiral C-1 R and S trans-opened 3,4-diol 1,2-epoxide adducts of benzo[c]phenanthrene (BcPh) were introduced at single N2-deoxyguanosine and N6-deoxyadenosine positions within the 3'-G(+5)G(+4)G(+3)A(+2)A(+1)T(-1)A(-2) sequence of the nonscissile DNA strand. Transesterification was unaffected by BcPh intercalation between the +6 and +5 base pairs, slowed 4-fold by intercalation between the +5 and +4 base pairs, and virtually abolished by BcPh intercalation between the +4 and +3 base pairs and the +3 and +2 base pairs. Intercalation between the +2 and +1 base pairs by the +2R BcPh dA adduct abolished transesterification, whereas the overlapping +1S BcPh dA adduct slowed the rate of transesterification by a factor of 2700, with little effect upon the extent of the reaction. Intercalation at the scissile phosphodiester (between the +1 and -1 base pairs) slowed transesterification by a factor of 450. BcPh intercalation between the -1 and -2 base pairs slowed cleavage by two orders of magnitude, but intercalation between the -2 and -3 base pairs had little effect. The anthracycline drug nogalamycin, a non-covalent intercalator with preference for 5'-TG dinucleotides, inhibited the single-turnover DNA cleavage reaction of vaccinia topoisomerase with an IC50 of 0.7 microM. Nogalamycin was most effective when the drug was pre-incubated with DNA and when the cleavage target site was 5'-CCCTT/G instead of 5'-CCCTT/A. These findings demarcate upstream and downstream boundaries of the functional interface of vaccinia topoisomerase with its DNA target site.     

Solution structure of the (+)-cis-anti-benzo[a]pyrene-dA ([BP]dA) adduct opposite dT in a DNA duplex.

Minor adducts, derived from the covalent binding of anti-benzo[a]pyrene-7,8-dihydroxy-9,10-epoxide to cellular DNA, may play an important role in generating mutations and initiating cancer. We have applied a combined NMR-computational approach including intensity based refinement to determine the solution structure of the minor (+)-cis-anti-[BP]dA adduct positioned opposite dT in the d(C1-T2-C3-T4-C5-[BP]A6-C7-T8-T9-C10-C11). (d(G12-G13-A14-A15-G16-T17-G18-A19-G20+ ++-A21-G22) 11-mer duplex. The BP ring system is intercalated toward the 5'-side of the [BP]dA6 lesion site without disrupting the flanking Watson-Crick dC5.dG18 and [BP]dA6.dT17 base pairs. This structure of the (+)-cis-anti-[BP]dA.dT 11-mer duplex, containing a bay region benzo[a]pyrenyl [BP]dA adduct, is compared with the corresponding structure of the (+)-trans-anti-[BPh]dA.dT 11-mer duplex (Cosman et al., Biochemistry 32, 12488-12497, 1993), which contains a fjord region benzo[c]phenanthrenyl [BPh]dA adduct with the same R stereochemistry at the linkage site. The carcinogen intercalates toward the 5'-direction of the modified strand in both duplexes (the adduct is embedded within the same sequence context) with the buckling of the Watson-Crick [BP]dA6.dT17 base pair more pronounced in the (+)-cis-anti-[BP]dA.dT 11-mer duplex compared to its Watson-Crick [BPh]dA.dT17 base pair in the (+)-trans-anti-[BPh]dA.dT 11-mer duplex. The available structural studies of covalent polycyclic aromatic hydrocarbon (PAH) carcinogen-DNA adducts point toward the emergence of a general theme where distinct alignments are adopted by PAH adducts covalently linked to the N(6) of adenine when compared to the N(2) of guanine in DNA duplexes. The [BPh]dA and [BP]dA N(6)-adenine adducts intercalate their polycyclic aromatic rings into the helix without disruption of their modified base pairs. This may reflect the potential flexibility associated with the positioning of the covalent tether and the benzylic ring of the carcinogen in the sterically spacious major groove. By contrast, such an intercalation without modified base pair disruption option appears not to be available to [BP]dG N(2)-guanine adducts where the covalent tether and the benzylic ring are positioned in the more sterically crowded minor groove. In the case of [BP]dG adducts, the benzopyrenyl ring is either positioned in the minor groove without base pair disruption, or if intercalated into the helix, requires disruption of the modified base pair and displacement of the bases out of the helix.     

Effects of antineoplastic drugs on the post-strand-passage DNA cleavage/religation equilibrium of topoisomerase II.

The post-strand-passage DNA cleavage/religation equilibrium of Drosophila melanogaster topoisomerase II was examined. This was accomplished by including adenyl-5'-yl imidodiphosphate, a nonhydrolyzable ATP analogue which supports strand passage but not enzyme turnover, in assays. Levels of post-strand-passage enzyme-mediated DNA breakage were 3-5 times higher than those generated by topoisomerase II prior to the strand-passage event. This finding correlated with a decrease in the apparent first-order rate of topoisomerase II mediated DNA religation in the post-strand-passage cleavage complex. Since previous studies demonstrated that antineoplastic drugs stabilize the pre-strand-passage cleavage complex of topoisomerase II by impairing the enzyme's ability to religate cleaved DNA [Osheroff, N. (1989) Biochemistry 28, 6157-6160; Robinson, M.J., & Osheroff, N. (1990) Biochemistry 29, 2511-2515], the effects of 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA) and etoposide on the enzyme's post-strand-passage DNA cleavage complex were characterized. Both drugs stimulated the ability of topoisomerase II to break double-stranded DNA after strand passage. As determined by two independent assay systems, m-AMSA and etoposide stabilized the enzyme's post-strand-passage DNA cleavage complex primarily by inhibiting DNA religation. These results strongly suggest that both the pre- and post-strand-passage DNA cleavage complexes of topoisomerase II serve as physiological targets for these structurally disparate antineoplastic drugs.     

19F NMR studies of vaccinia type IB topoisomerase. Conformational dynamics of the bound DNA substrate.

The site-specific DNA cleavage and religation activities of the vaccinia virus type IB topoisomerase at (C/T)CCTT(+1)X(-1) sites in duplex DNA have allowed detailed investigations of the chemical and conformational steps on the reaction pathway of this enzyme (see accompanying article (Kwon, K., and Stivers, J. T. (2002) J. Biol. Chem. 277, 345-352)). To extend these studies to the DNA substrate, we have performed 19F NMR experiments using substrates in which the +1 T has been replaced with the NMR-sensitive thymidine base analogue 5-fluoro-2'-deoxyuridine (5-F-dUrd). Substitution of 5-F-dUrd has little effect on the binding affinity of topoisomerase I for DNA, results in small changes in the cleavage and religation rate constants, and produces a net 3-fold decrease in the cleavage equilibrium constant as compared with the CCCTT consensus DNA. One-dimensional 19F NMR experiments show that the +1 5-F-dUrd is in a dynamic equilibrium between a stacked and unstacked state in both the noncovalent complex and the covalent phosphotyrosine complex. These NMR observations are supported by the selective sensitivity of the +1 T and +1 5-F-dUrd to KMnO4 oxidation. A role for localized DNA distortion in the topoisomerase I mechanism is suggested.     

Effect of antineoplastic agents on the DNA cleavage/religation reaction of eukaryotic topoisomerase II: inhibition of DNA religation by etoposide

Beyond its essential physiological functions, topoisomerase II is the primary cellular target for a number of clinically relevant antineoplastic drugs. Although the chemotherapeutic efficacies of these drugs correlate with their abilities to stabilize the covalent topoisomerase II-DNA cleavage complex, their molecular mechanism of action has yet to be described. In order to characterize the drug-induced stabilization of this enzyme-DNA complex, the effect of etoposide on the DNA cleavage/religation reaction of Drosophila melanogaster topoisomerase II was studied. Under the conditions employed, etoposide increased levels of enzyme-mediated double-stranded DNA cleavage 5-6-fold and single-stranded cleavage approximately 4-fold. Maximal stimulation was observed at 80-100 microM etoposide with 50% of the maximal effect at approximately 15 microM drug. By employing a topoisomerase II mediated DNA religation assay [Osheroff, N. & Zechiedrich, E.L. (1987) Biochemistry 26, 4303-4309], etoposide was found to stabilize the enzyme-DNA cleavage complex (at least in part) by inhibiting the enzyme's ability to religate cleaved DNA. Moreover, in order for the drug to affect religation, it has to be present at the time of DNA cleavage.     

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.     

New technique for uncoupling the cleavage and religation reactions of eukaryotic topoisomerase I. The mode of action of camptothecin at a specific recognition site.

A new technique for uncoupling the cleavage and religation half-reactions of topoisomerase I at a specific site has been developed. The technique takes advantage of a suicidal DNA substrate to attain enzyme-mediated cleavage without concomitant religation. Efficient religation can be achieved, subsequently, by addition of an oligonucleotide capable of hybridising to the non-cleaved strand of the suicide DNA substrate. The technique was used to study the effect of different compounds on the half-reactions of topoisomerase I. It was shown that topoisomerase I-mediated cleavage was inhibited by NaCl concentrations higher than 200 mM, while the religation reaction seemed unaffected by concentrations as high as 3 M-NaCl. The divalent cations Mg2+, Ca2+ and Mn2+ were found to enhance the cleavage but not the religation reaction of topoisomerase I, whereas Cu2+ and Zn2+ inhibited both reactions. Furthermore, the effect of the anti-neoplastic agent, camptothecin, on the half-reactions of topoisomerase I was investigated. It was found that the drug did not affect the cleavage reaction of topoisomerase I at the studied site, while the religation reaction of the enzyme was inhibited. Camptothecin was found to stabilise the enzyme-DNA cleavage complex even when the drug was added after complex formation.     

Double-stranded DNA cleavage/religation reaction of eukaryotic topoisomerase II: evidence for a nicked DNA intermediate

The DNA cleavage reaction of eukaryotic topoisomerase II produces nicked DNA along with linear nucleic acid products. Therefore, relationships between the enzyme's DNA nicking and double-stranded cleavage reactions were determined. This was accomplished by altering the pH at which assays were performed. At pH 5.0 Drosophila melanogaster topoisomerase II generated predominantly (greater than 90%) single-stranded breaks in duplex DNA. With increasing pH, less single-stranded and more double-stranded cleavage was observed, regardless of the buffer or the divalent cation employed. As has been shown for double-stranded DNA cleavage, topoisomerase II was covalently bound to nicked DNA products, and enzyme-mediated single-stranded cleavage was salt reversible. Moreover, sites of single-stranded DNA breaks were identical with those mapped for double-stranded breaks. To further characterize the enzyme's cleavage mechanism, electron microscopy studies were performed. These experiments revealed that separate polypeptide chains were complexed with both ends of linear DNA molecules generated during cleavage reactions. Finally, by use of a novel religation assay [Osheroff, N., & Zechiedrich, E. L. (1987) Biochemistry 26, 4303-4309], it was shown that nicked DNA is an obligatory kinetic intermediate in the topoisomerase II mediated reunion of double-stranded breaks. Under the conditions employed, the apparent first-order rate constant for the religation of the first break was approximately 6-fold faster than that for the religation of the second break. The above results indicate that topoisomerase II carries out double-stranded DNA cleavage/religation by making two sequential single-stranded breaks in the nucleic acid backbone, each of which is mediated by a separate subunit of the homodimeric enzyme.     

Effect of casein kinase II-mediated phosphorylation on the catalytic cycle of topoisomerase II. Regulation of enzyme activity by enhancement of ATP hydrolysis.

The catalytic activity of topoisomerase II is stimulated approximately 2-3-fold following phosphorylation by casein kinase II (Ackerman, P., Glover, C. V. C., and Osheroff, N. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 3164-3168). In order to delineate the mechanism by which the activity of the enzyme is enhanced, the effects of casein kinase II-mediated phosphorylation on the individual steps of the catalytic cycle of Drosophila topoisomerase II were characterized. Phosphorylation did not affect reaction steps that preceded hydrolysis of the enzyme's high energy ATP cofactor. This included enzyme-DNA binding, pre-strand passage DNA cleavage/religation, the double-stranded DNA passage event, and post-strand passage DNA cleavage/religation. In contrast, the rate of topoisomerase II-mediated ATP hydrolysis was stimulated 2.7-fold following phosphorylation by casein kinase II. Since ATP hydrolysis is a prerequisite for enzyme turnover, it is concluded that phosphorylation modulates the overall catalytic activity of topoisomerase II by stimulating the enzyme's ATPase activity.     

Molecular topology of polycyclic aromatic carcinogens determines DNA adduct conformation: a link to tumorigenic activity

We report below on the solution structures of stereoisomeric "fjord" region trans-anti-benzo[c]phenanthrene-N2-guanine (designated (BPh)G) adducts positioned opposite cytosine within the (C-(BPh)G-C).(G-C-G) sequence context. We observe intercalation of the phenanthrenyl ring with stereoisomer-dependent directionality, without disruption of the modified (BPh)G.C base-pair. Intercalation occurs to the 5' side of the modified strand for the 1S stereoisomeric adduct and to the 3' side for the 1R stereoisomeric adduct, with the S and R-trans-isomers related to one another by inversion in a mirror plane at all four chiral carbon atoms on the benzylic ring. Intercalation of the fjord region BPh ring into the helix without disruption of the modified base-pair is achieved through buckling of the (BPh)G.C base-pair, displacement of the linkage bond from the plane of the (BPh)G base, adaptation of a chair pucker by the BPh benzylic ring and the propeller-like deviation from planarity of the BPh phenanthrenyl ring. It is noteworthy that intercalation without base-pair disruption occurs from the minor groove side for S and R-trans-anti BPh-N2-guanine adducts opposite C, in contrast to our previous demonstration of intercalation without modified base-pair disruption from the major groove side for S and R-trans-anti BPh-N6-adenine adducts opposite T. Further, these results on fjord region 1S and 1R-trans-anti (BPh)G adducts positioned opposite C are in striking contrast to earlier research with "bay" region benzo[a]pyrene-N2-guanine (designated (BP)G) adducts positioned opposite cytosine, where 10S and 10R-trans-anti stereoisomers were positioned with opposite directionality in the minor groove without modified base-pair disruption. They also are in contrast to the 10S and 10R-cis-anti stereoisomers of (BP)G adducts opposite C, where the pyrenyl ring is intercalated into the helix with directionality, but the modified base and its partner on the opposite strand are displaced out of the helix. These results are especially significant given the known greater tumorigenic potential of fjord region compared to bay region polycyclic aromatic hydrocarbons. The tumorigenic potential has been linked to repair efficiency such that bay region adducts can be readily repaired while their fjord region counterparts are refractory to repair. Our structural results propose a link between DNA adduct conformation and repair-dependent mutagenic activity, which could ultimately translate into structure-dependent differences in tumorigenic activities. We propose that the fjord region minor groove-linked BPh-N2-guanine and major groove-linked BPh-N6-adenine adducts are refractory to repair based on our observations that the phenanthrenyl ring intercalates into the helix without modified base-pair disruption. The helix is therefore minimally perturbed and the phenanthrenyl ring is not available for recognition by the repair machinery. By contrast, the bay region BP-N2-G adducts are susceptible to repair, since the repair machinery can recognize either the pyrenyl ring positioned in the minor groove for the trans-anti groove-aligned stereoisomers, or the disrupted modified base-pair for the cis-anti base-displaced intercalated stereoisomers.     

Nonpolar nucleobase analogs illuminate requirements for site-specific DNA cleavage by vaccinia topoisomerase

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a specific target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow N(-1) in duplex DNA. Here we study the effects of nonpolar pyrimidine isosteres difluorotoluene (F) and monofluorotoluene (D) and the nonpolar purine analog indole at individual positions of the scissile and nonscissile strands on the rate of single-turnover DNA transesterification and the cleavage-religation equilibrium. Comparison of the effects of nonpolar base substitution to the effects of abasic lesions reported previously allowed us to surmise the relative contributions of base-stacking and polar edge interactions to the DNA transesterification reactions. For example, the deleterious effects of eliminating the +2T base on the scissile strand were rectified by introducing the nonpolar F isostere, whereas the requirement for the +1T base was not elided by F substitution. We impute a role for +1T in recruiting the catalytic residue Lys-167 to the active site. Topoisomerase is especially sensitive to suppression of DNA cleavage upon elimination of the +4G and +3G bases of the nonscissile strand. Indole provided little or no gain of function relative to abasic lesions. Inosine substitutions for +4G and +3G had no effect on transesterification rate, implying that the guanine exocyclic amine is not a critical determinant of DNA cleavage. Prior studies of 2-aminopurine and 7-deazaguanine effects had shown that the O6 and N7 of guanine were also not critical. These findings suggest that either the topoisomerase makes functionally redundant contacts with polar atoms (likely via Tyr-136, a residue important for precleavage active site assembly) or that it relies on contacts to N1 or N3 of the purine ring. The cleavage-religation equilibrium is strongly skewed toward trapping of the covalent intermediate by elimination of the +1A base of the nonscissile strand; the reaction equilibrium is restored by +1 indole, signifying that base stacking flanking the nick is critical for the religation step. Our findings highlight base isosteres as valuable tools for the analysis of proteins that act on DNA in a site-specific manner.     

Studies of the topoisomerase II-mediated cleavage and religation reactions by use of a suicidal double-stranded DNA substrate.

The cleavage and religation reactions of eukaryotic topoisomerase II were studied by use of a 5'-recessed DNA substrate containing a strong recognition sequence for the enzyme. Cleavage of the DNA substrate was suicidal, that is the enzyme was unable to religate the cleaved DNA due to a release of DNA 5' to the cleavage position. With this substrate cleavage products accumulated with time in the absence of protein-denaturing agents, and the cleavage reaction was not reversible with salt. The suicide cleavage complexes contained a kinetically competent topoisomerase II enzyme as determined by the enzyme's ability to perform intermolecular ligation of the cleaved DNA to a free 3'-hydroxyl end on another DNA strand. The efficiency of the religation reaction depended on the ability of the religation substrate to base pair to the DNA in the cleaved enzyme-DNA complex. Higher levels of religation were obtained with dinucleotides than with long DNA substrates. Mononucleotides also were efficiently religated, indicating an ability of the enzyme to mediate religation without making contacts to a long stretch of nucleotides 5' to the cleavage position.     

Inhibition of type IA topoisomerase by a monoclonal antibody through perturbation of DNA cleavage-religation equilibrium

Type IA DNA topoisomerases, typically found in bacteria, are essential enzymes that catalyse the DNA relaxation of negative supercoils. DNA gyrase is the only type II topoisomerase that can carry out the opposite reaction (i.e. the introduction of the DNA supercoils). A number of diverse molecules target DNA gyrase. However, inhibitors that arrest the activity of bacterial topoisomerase I at low concentrations remain to be identified. Towards this end, as a proof of principle, monoclonal antibodies that inhibit Mycobacterium smegmatis topoisomerase I have been characterized and the specific inhibition of Mycobacterium smegmatis topoisomerase I by a monoclonal antibody, 2F3G4, at a nanomolar concentration is described. The enzyme-bound monoclonal antibody stimulated the first transesterification reaction leading to enhanced DNA cleavage, without significantly altering the religation activity of the enzyme. The stimulated DNA cleavage resulted in perturbation of the cleavage-religation equilibrium, increasing single-strand nicks and protein-DNA covalent adducts. Monoclonal antibodies with such a mechanism of inhibition can serve as invaluable tools for probing the structure and mechanism of the enzyme, as well as in the design of novel inhibitors that arrest enzyme activity.