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.     

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.     

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.     

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.     

Site-specific DNA transesterification by vaccinia topoisomerase: role of specific phosphates and nucleosides

Vaccinia topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a pentapyrimidine target site 5'-CCCTTp downward arrow in duplex DNA. Here we present experiments that illuminate the contributions of specific nucleosides and phosphates to site affinity and transesterification. We find that the -1 phosphate and -2 nucleoside on the scissile strand (5'-CCCTTp / NpN) enhance the rate of transesterification by factors of 40 and 25, respectively, whereas the DNA segment downstream of the -2 nucleotide makes no significant kinetic contribution. Placement of a 5'-phosphate/3'-OH nick at position +2, +3, +4, or +5 within the CCCTT element results in a 5-10-fold reduction in the affinity of topoisomerase binding to DNA. A nick at the +2 phosphate also slows the rate of transesterification by approximately 500-fold. This finding, together with earlier studies of the effects of position-specific base and sugar modifications, points to the +2 Tp nucleotide as being the most critical element of the CCCTT target site other than the scissile phosphate itself. On the noncleaved strand, the segment downstream of the 3'-GGGAA element contributes minimally to the rate of transesterification provided that the substrate is otherwise fully base-paired within the 5'-CCCTT target site. By studying the effects of single nucleotide gaps and missing phosphate nicks within the 3'-GGGAA sequence, we find that the +1 and +2 adenosine nucleosides enhance the rate of transesterification by 20- and 1,000-fold respectively and that the +5 phosphate (3'-GpGGAA) is also important for cleavage. Cumulative functional analyses of the vaccinia topoisomerase-DNA interface are discussed in light of newly available structures for the vaccinia and human type IB enzymes.     

Intercalating polycyclic aromatic hydrocarbon-DNA adducts poison DNA religation by Vaccinia topoisomerase and act as roadblocks to digestion by exonuclease III

Polycyclic aromatic hydrocarbon (PAH)-DNA adducts pervert the execution or fidelity of enzymatic DNA transactions and cause mutations and cancer. Here, we examine the effects of intercalating PAH-DNA adducts on the religation reaction of vaccinia DNA topoisomerase, a prototypal type IB topoisomerase (TopIB), and the 3' end-resection reaction of Escherichia coli exonuclease III (ExoIII), a DNA repair enzyme. Vaccinia TopIB forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p / N(-1) in duplex DNA. The rate of the forward cleavage reaction is suppressed to varying degrees by benzo[a]pyrene (BP) or benzo[c]phenanthrene (BPh) adducts at purine bases within the 3'-G(+5)G(+4)G(+3)A(+2)A(+1)T(-1)A(-2) sequence of the nonscissile strand. We report that BP adducts at the +1 and -2 N6-deoxyadenosine (dA) positions flanking the scissile phosphodiester slow the rate of DNA religation to a greater degree than they do the cleavage rate. By increasing the cleavage equilibrium constant > or = 10-fold, the BPdA adducts, which are intercalated via the major groove, act as TopIB poisons. With respect to ExoIII, we find that (i) single BPdA adducts act as durable roadblocks to ExoIII digestion, which is halted at sites 1 and 2 nucleotides prior to the modified base; (ii) single BPhdA adducts, which also intercalate via the major groove, elicit a transient pause prior to the lesion, which is eventually resected; and (iii) BPh adducts at N2-deoxyguanosine, which intercalate via the minor groove, are durable impediments to ExoIII digestion. These results highlight the sensitivity of repair outcomes to the structure of the PAH ring system and whether intercalation occurs via the major or minor groove.     

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.     

Preferential, cooperative binding of DNA topoisomerase II to scaffold-associated regions.

DNA elements termed scaffold-associated regions (SARs) are AT-rich stretches of several hundred base pairs which are known to bind specifically to nuclear or metaphase scaffolds and are proposed to specify the base of chromatin loops. SARs contain sequences homologous to the DNA topoisomerase II cleavage consensus and this enzyme is known to be the major structural component of the mitotic chromosome scaffold. We find that purified topoisomerase II preferentially binds and aggregates SAR-containing DNA. This interaction is highly cooperative and, with increasing concentrations of topoisomerase II, the protein titrates quantitatively first SAR-containing DNA and then non-SAR DNA. About one topoisomerase II dimer is bound per 200 bp of DNA. SARs exhibit a Circe effect; they promote in cis topoisomerase II-mediated double-strand cleavage in SAR-containing DNA fragments. The AT-rich SARs contain several oligo(dA).oligo(dT) tracts which determine their protein-binding specificity. Distamycin, which is known to interact highly selectively with runs of A.T base pairs, abolishes the specific interaction of SARs with topoisomerase II, and the homopolymer oligo(dA).oligo(dT) is, above a critical length of 240 bp, a highly specific artificial SAR. These results support the notion of an involvement of SARs and topoisomerase II in chromosome structure.     

Site-specific interaction of vaccinia virus topoisomerase I with duplex DNA. Minimal DNA substrate for strand cleavage in vitro.

Purified vaccinia virus DNA topoisomerase I forms a cleavable complex with duplex DNA at a conserved sequence element 5'(C/T)CCTTdecreases in the incised DNA strand. DNase I footprint studies show that vaccinia topoisomerase protects the region around the site of covalent adduct formation from nuclease digestion. On the cleaved DNA strand, the protected region extends from +13 to -13 (+1 being the site of cleavage). On the noncleaved strand, the protected region extends from +13 to -9. Similar nuclease protection is observed for a mutant topoisomerase (containing a Tyr ---- Phe substitution at the active site amino acid 274) that is catalytically inert and does not form the covalent intermediate. Thus, vaccinia topoisomerase is a specific DNA binding protein independent of its competence in transesterification. By studying the cleavage of a series of 12-mer DNA duplexes in which the position of the CCCTTdecreases motif within the substrate is systematically phased, the "minimal" substrate for cleavage has been defined; cleavage requires six nucleotides upstream of the cleavage site and two nucleotides downstream of the site. An analysis of the cleavage of oligomer substrates mutated singly in the CCCTT sequence reveals a hierarchy of mutational effects based on position within the pentamer motif and the nature of the sequence alteration.     

Effect of phosphorothioate substitutions on DNA cleavage by Escherichia coli DNA topoisomerase I

To evaluate the structural influence of the DNA phosphate backbone on the activity of Escherichia coli DNA topoisomerase I, modified forms of oligonucleotide dA(7) were synthesized with a chiral phosphorothioate replacing the non-bridging oxygens at each position along the backbone. A deoxy-iodo-uracil replaced the 5'-base to crosslink the oligonucleotides by ultraviolet (UV) and assess binding affinity. At the scissile phosphate there was little effect on the cleavage rate. At the +1 phosphate, the rectus phosphorus (Rp)-thio-substitution reduced the rate of cleavage by a factor of 10. At the +3 and -2 positions from the scissile bond, the Rp-isomer was cleaved at a faster rate than the sinister phosphorus (Sp)-isomer. The results demonstrate the importance of backbone contacts between DNA substrate and E. coli topoisomerase I.     

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.     

Base mutation analysis of topoisomerase II-idarubicin-DNA ternary complex formation. Evidence for enzyme subunit cooperativity in DNA cleavage.

Antitumor drugs, such as anthracyclines, interfere with mammalian DNA topoisomerase II by forming a ternary complex, DNA-drug-enzyme, in which DNA strands are cleaved and covalently linked to the enzyme. In this work, a synthetic 36-bp DNA oligomer derived from SV40 and mutated variants were used to determine the effects of base mutations on DNA cleavage levels produced by murine topoisomerase II with and without idarubicin. Although site competition could affect cleavage levels, mutation effects were rather similar among several cleavage sites. The major sequence determinants of topoisomerase II DNA cleavage without drugs are up to five base pairs apart from the strand cut, suggesting that DNA protein contacts involving these bases are particularly critical for DNA site recognition. Cleavage sites with adenines at positions -1 were detected without idarubicin only under conditions favouring enzyme binding to DNA, showing that these sites are low affinity sites for topoisomerase II DNA cleavage and/or binding. Moreover, the results indicated that the sequence 5'-(A)TA/(A)-3' (the slash indicates the cleaved bond, parenthesis indicate conditioned preference) from -3 to +1 positions constitutes the complete base sequence preferred by anthracyclines. An important finding was that mutations that improve the fit to the above consensus on one strand can also increase cleavage on the opposite strand, suggesting that a drug molecule may effectively interact with one enzyme subunit only and trap the whole dimeric enzyme. These findings documented that DNA recognition by topoisomerase II may occur at one or the other strand, and not necessarily at both of them, and that the two subunits can act cooperatively to cleave a double helix.     

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.     

Effect of 2'-5' phosphodiesters on DNA transesterification by vaccinia topoisomerase

Vaccinia topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a pentapyrimidine target site 5'-CCCTTp downward arrow in duplex DNA. By introducing single 2'-5' phosphodiesters in lieu of a standard 3'-5' phosphodiester linkage, we illuminate the contributions of phosphodiester connectivity to DNA transesterification. We find that the DNA cleavage reaction was slowed by more than six orders of magnitude when a 2'-5' linkage was present at the scissile phosphodiester (CCCTT(2')p downward arrow(5')A). Thus, vaccinia topoisomerase is unable to form a DNA-(2'-phosphotyrosyl)-enzyme intermediate. We hypothesize that the altered geometry of the 2'-5' phosphodiester limits the ability of the tyrosine nucleophile to attain a requisite, presumably apical orientation with respect to the 5'-OH leaving group. A 2'-5' phosphodiester located to the 3' side of the cleavage site (CCCTTp downward arrowN(2')p(5')N) reduced the rate of transesterification by a factor of 500. In contrast, 2'-5' phosphodiesters at four other sites in the scissile strand (TpCGCCCTpT downward arrowATpTpC) and five positions in the nonscissile strand (3'-GGGpApApTpApA) had no effect on transesterification rate. The DNAs containing 2'-5' phosphodiesters were protected from digestion by exonuclease III. We found that exonuclease III was consistently arrested at positions 1 and 2 nucleotides prior to the encounter of its active site with the modified 2'-5' phosphodiester and that the 2'-5' linkage itself was poorly hydrolyzed by exonuclease III.     

Inhibition of Werner syndrome helicase activity by benzo[c]phenanthrene diol epoxide dA adducts in DNA is both strand-and stereoisomer-dependent

Helicases are among the first enzymes to encounter DNA damage during DNA processing within the cell and thus are likely to be targets for the adverse effects of DNA lesions induced by environmental chemicals. Here we examined the effect of cis- and trans-opened 3,4-diol 1,2-epoxide (DE) DNA adducts of benzo[c]phenanthrene (BcPh) at N6 of adenine on helicase activity. These adducts are derived from the highly tumorigenic (-)-(1R,2S,3S,4R)-DE as well as its less carcinogenic (+)-(1S,2R,3R,4S)-DE enantiomer in both of which the benzylic 4-hydroxyl group and epoxide oxygen are trans. The hydrocarbon portions of these adducts intercalate into DNA on the 3' or the 5' side of the adducted deoxyadenosine for the 1S- and 1R-adducts, respectively. These adducts inhibited the human Werner (WRN) syndrome helicase activity in a strand-specific and stereospecific manner. In the strand along which WRN translocates, cis-opened adducts were significantly more effective inhibitors than trans-opened isomers, indicating that WRN unwinding is sensitive to adduct stereochemistry. WRN helicase activity was also inhibited but to a lesser extent by cis-opened BcPh DE adducts in the displaced strand independent of their direction of intercalation, whereas inhibition by the trans-opened stereoisomers in the displaced strand depended on their orientation, such that only adducts oriented toward the advancing helicase inhibited WRN activity. A BcPh DE adduct positioned in the helicase-translocating strand did not sequester WRN, nor affect the rate of ATP hydrolysis relative to an unadducted control. Although the Bloom (BLM) syndrome helicase was also inhibited by a cis-opened adduct in a strand-specific manner, this helicase was not as severely affected as WRN. Because BcPh DEs form substantial amounts of deoxyadenosine adducts at dA, their adverse effects on helicases could contribute to genetic damage and cell transformation induced by these DEs. Thus, the unwinding activity of RecQ helicases is sensitive to the strand, orientation, and stereochemistry of intercalated polycyclic aromatic hydrocarbon adducts.     

Characterization of mimivirus DNA topoisomerase IB suggests horizontal gene transfer between eukaryal viruses and bacteria

Mimivirus, a parasite of Acanthamoeba polyphaga, is the largest DNA virus known; it encodes dozens of proteins with imputed functions in nucleic acid transactions. Here we produced, purified, and characterized mimivirus DNA topoisomerase IB (TopIB), which we find to be a structural and functional homolog of poxvirus TopIB and the poxvirus-like topoisomerases discovered recently in bacteria. Arginine, histidine, and tyrosine side chains responsible for TopIB transesterification are conserved and essential in mimivirus TopIB. Moreover, mimivirus TopIB is capable of incising duplex DNA at the 5'-CCCTT cleavage site recognized by all poxvirus topoisomerases. Based on the available data, mimivirus TopIB appears functionally more akin to poxvirus TopIB than bacterial TopIB, despite its greater primary structure similarity to the bacterial TopIB group. We speculate that the ancestral bacterial/viral TopIB was disseminated by horizontal gene transfer within amoebae, which are permissive hosts for either intracellular growth or persistence of many present-day bacterial species that have a type IB topoisomerase.     

Interactions of molecules with nucleic acids. VII. Intercalation and T.A specificity of daunomycin in DNA

Intercalation complexes of daunomicin(+1) with tetramer duplexes in DNA are studied with the theoretically determined intercalation sites (I, ?0.4), (II, ?0.4), and (III, ?1.4). These sites occur with base pairs separated by 6.76 Å for helical angles of 26°, 22°, and 8° about the intercalation site. Site I is preferred, and this is in agreement with experimental unwinding angles. Optimum binding positions and conformations are established, and these are in agreement with experimental results from crystal structures. A systematic procedure is devised to study base-pair and base-sequence specificity, which results in the demonstration that the most stable sequences are mainly ↑BP₁, T·A, DAUN, A·T, BP₄↓ and ↑BP₁, T·A, DAUN, G·C, BP₄↓, i.e., with the TpA and CpG (pyrimidine)p(purine) sequences about the intercalation site. These 32 possible sequences are found among the 40 most stable complexes. These theoretical calculations of intercalation complexes with daunomicin(+1) provide the first example in which a drug specifically selects the base pair T·A and prefers it in a particular sequence about the intercalation site. This specificity is in agreement with some experimental results. Problems associated with the interpretation of specificity are discussed in terms of the base, base-pair, and base-sequence resulting from the DNA site and the DNA–drug interactions. T·A specificity is rationalized by noting that the 2′deoxyribo-5′-monophosphate backbone attached to A is slightly more negative than that on the other nucleotides. Hence, a preference exists for binding to the protonated daunosamine (+1) groups. Stereographic projections of daunomycinone and daunomycin(+1) in a bond model and in a space-filling model with steric contours illustrate the results.     

Methylene blue photosensitised strand cleavage of DNA: effects of dye binding and oxygen.

It is shown that methylene blue (MB+) photosensitises DNA in either aerated or deaerated solutions, causing direct cleavage of phosphodiester bonds and rendering additional bonds labile to alkali. Evidence from unwinding and fluorimetric studies indicates that MB+ binds to DNA in at least 2 ways. Intercalation, which optimally induces helical unwinding of 24 degrees +/- 2 degrees per MB+, is markedly reduced upon neutralisation by Mg2+ of the DNA phosphates, while significant non-intercalative binding persists as shown by substantial fluorescence quenching at Mg2+ concentrations where there is little unwinding. MB+ induces photolysis at both low and high Mg2+ concentration - intercalation is apparently not required for photolysis. The quantum yield for strand breakage varies from 1-3 X 10(-7) under different conditions and is oxygen enhanced. The DNA cleavage is guanine specific. The 3' termini of the primary MB+-induced DNA photoproducts, unlike those generated by chemical sequencing retain an alkali labile adduct on the terminal phosphate.     

Binding and photocleavage of cationic porphyrin-phenylpiperazine hybrids to DNA

The binding properties of cationic porphyrin-phenylpiperazine hybrids to calf thymus (CT) DNA were investigated by using absorption, fluorescence and circular dichroism (CD) spectra, and the apparent affinity binding constants (K(app)) of the porphyrins for CT DNA were determined by using a competition method with ethidium bromide (EB). Intercalation of porphyrin into CT DNA occurred when two phenylpiperazines were introduced at cis position onto the periphery of cationic porphyrin. The photocleavages of pBR322 plasmid DNA by the porphyrins were consistent with the values of K(app). With [porphyrin]/[DNA base pairs] ratio increased, the binding mode tended to be outside binding, and the cleavage abilities of the porphyrins varied. In the presence of sodium azide, a quencher of 1O2, the cleavage of DNA by the porphyrin of intercalation was less inhibited.     

Molecular determinants of site-specific inhibition of human DNA topoisomerase I by fagaronine and ethoxidine. Relation to DNA binding

DNA topoisomerase (top) I inhibition activity of the natural alkaloid fagaronine (NSC157995) and its new synthetic derivative ethoxidine (12-ethoxy-benzo[c]phenanthridine) has been correlated with their molecular interactions and sequence specificity within the DNA complexes. Flow linear dichroism shows that ethoxidine exhibits the same inhibition of DNA relaxation as fagaronine at the 10-fold lower concentration. The patterns of DNA cleavage by top I show linear enhancement of CPT-dependent sites at the 0.016-50 microM concentrations of fagaronine, whereas ethoxidine suppress both top I-specific and CPT-dependent sites. Suppression of top I-mediated cleavage by ethoxidine is found to be specific for the sites, including strand cut between A and T. Fagaronine and ethoxidine are DNA major groove intercalators. Ethoxidine intercalates DNA in A-T sequences and its 12-ethoxy-moiety (absent in fagaronine) extends into the DNA minor groove. These findings may explain specificity of suppression by ethoxidine of the strong top I cleavage sites with the A(+1), T(-1) immediately adjacent to the strand cut. Fagaronine does not show any sequence specificity of DNA intercalation, but its highly electronegative oxygen of hydroxy group (absent in ethoxidine) is shown to be an acceptor of the hydrogen bond with the NH(2) group of G base of DNA. Ability of fagaronine to stabilize top I-mediated ternary complex is proposed to be determined by interaction of its hydroxy group with the guanine at position (+1) of the DNA cleavage site and of quaternary nitrogen interaction with top I. The model proposed provides a guidance for screening new top I-targeted drugs in terms of identification of molecular determinants responsible for their top I inhibition effects.