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.     

Efficient, Mg(2+)-dependent photochemical DNA cleavage by the antitumor quinobenzoxazine (S)-A-62176

The quinobenzoxazines, a group of structural analogues of the antibacterial fluoroquinolones, are topoisomerase II inhibitors that have demonstrated promising anticancer activity in mice. It has been proposed that the quinobenzoxazines form a 2:2 drug-Mg(2+) self-assembly complex on DNA. The quinobenzoxazine (S)-A-62176 is photochemically unstable and undergoes a DNA-accelerated photochemical reaction to afford a highly fluorescent photoproduct. Here we report that the irradiation of both supercoiled DNA and DNA oligonucleotides in the presence of (S)-A-62176 results in photochemical cleavage of the DNA. The (S)-A-62176-mediated DNA photocleavage reaction requires Mg(2+). Photochemical cleavage of supercoiled DNA by (S)-A-62176 is much more efficient that the DNA photocleavage reactions of the fluoroquinolones norfloxacin, ciprofloxacin, and enoxacin. The photocleavage of supercoiled DNA by (S)-A-62176 is unaffected by the presence of SOD, catalase, or other reactive oxygen scavengers, but is inhibited by deoxygenation. The photochemical cleavage of supercoiled DNA is also inhibited by 1 mM KI. Photochemical cleavage of DNA oligonucleotides by (S)-A-62176 occurs most extensively at DNA sites bound by drug, as determined by DNase I footprinting, and especially at certain G and T residues. The nature of the DNA photoproducts, and inhibition studies, indicate that the photocleavage reaction occurs by a free radical mechanism initiated by abstraction of the 4'- and 1'-hydrogens from the DNA minor groove. These results lend further support for the proposed DNA binding model for the quinobenzoxazine 2:2 drug-Mg(2+) complex and serve to define the position of this complex on the minor groove of DNA.     

Analysis of bisdioxopiperazine dexrazoxane binding to human DNA topoisomerase II alpha: decreased binding as a mechanism of drug resistance

Topoisomerase II is an ATP-operated clamp that effects topological changes by capturing a double stranded DNA segment and transporting it through another DNA molecule. Despite the extensive use of topoisomerase II-targeted drugs in cancer chemotherapy and the impact of drug resistance on the efficacy of treatment, much remains unknown concerning the interactions between these agents and topoisomerase II. To identify the interaction of the bisdioxopiperazine dexrazoxane (ICRF-187) with topoisomerase II, we developed a rapid gel-filtration assay and characterized the binding of ((3)H)-dexrazoxane to human topoisomerase II alpha. Dexrazoxane binds to human topoisomerase II alpha in the presence of DNA and ATP with an apparent K(d) of 23 microM and a stoichiometry of 1 drug molecule per enzyme dimer. Various N-terminal single amino acid substitutions in human topoisomerase II alpha that were previously shown to confer specific bisdioxopiperazine resistance either totally abolished drug binding or resulted in less efficient binding. The effect of the various mutations on drug binding correlated well with their effect on drug resistance in vivo and in vitro. Interestingly, an altered active site tyrosine mutant of human topoisomerase II alpha, which is incapable of carrying out DNA strand passage, was unable to bind dexrazoxane, which agrees with the drug's proposed mechanism of action late in the topoisomerase II catalytic cycle. The direct correlation between the level of drug binding and dexrazoxane resistance is consistent with a decreased drug binding mechanism of action for these dexrazoxane resistance conferring mutations.     

Intercalative antitumor drugs interfere with the breakage-reunion reaction of mammalian DNA topoisomerase II

Many intercalative antitumor drugs have been shown to induce reversible protein-linked DNA breaks in cultured mammalian cells. Using purified mammalian DNA topoisomerase II, we have demonstrated that the antitumor drugs ellipticine and 2-methyl-9-hydroxyellipticine (2-Me-9-OH-E+) can produce reversible protein-linked DNA breaks in vitro. 2-Me-9-OH-E+ which is more cytotoxic toward L1210 cells and more active against experimental tumors than ellipticine is also more effective in stimulating DNA cleavage in vitro. Similar to the effect of 4'-(9-acridinylamino)-methanesulfon-m-anisidide (m-AMSA) on topoisomerase II in vitro, the mechanism of DNA breakage induced by ellipticines is most likely due to the drug stabilization of a cleavable complex formed between topoisomerase II and DNA. Protein denaturant treatment of the cleavable complex results in DNA breakage and covalent linking of one topoisomerase II subunit to each 5'-end of the cleaved DNA. Cleavage sites on pBR322 DNA produced by ellipticine or 2-Me-9-OH-E+ treatment mapped at the same positions. However, many of these cleavage sites are distinctly different from those produced by the antitumor drug m-AMSA which also targets at topoisomerase II. Our results thus suggest that although mammalian DNA topoisomerase II may be a common target of these antitumor drugs, drug-DNA-topoisomerase interactions for different antitumor drugs may be different.     

Inhibition of topoisomerase II catalytic activity by two ruthenium compounds: a ligand-dependent mode of action

The ability of two structurally different ruthenium complexes to interfere with the catalytic activity of topoisomerase II was studied to elucidate their molecular mechanism of action and relative antineoplastic activity. The first complex, [RuCl2(C6H6)(dmso)], could completely inhibit DNA relaxation activity of topoisomerase II and form a drug-induced cleavage complex. This strongly suggests that the drug interferes with topoisomerase II activity by cleavage complex formation. The bi-directional binding of [RuCl2(C6H6)(dmso)] to DNA and topoisomerase II was verified by immunoprecipitation experiments which confirmed the presence of DNA and ruthenium in the cleavage complex. The second complex, Ruthenium Salicylaldoxime, could not inhibit topoisomerase II relaxation activity appreciably and also could not induce cleavage complex formation, though its DNA-binding characteristics and antiproliferation activity were almost comparable to those of [RuCl2(C6H6)(dmso)]. The results suggest that the difference in ligands and their orientation around a metal atom may be responsible for topoisomerase II poisoning by the first complex and not by the second. A probable mechanism is proposed for [RuCl2(C6H6)(dmso)], where the ruthenium atom interacts with DNA and ligands of the metal atom form cross-links with topoisomerase II. This may facilitate the formation of a drug-induced cleavage complex.     

Zinc (II) coordination in Escherichia coli DNA topoisomerase I is required for cleavable complex formation with DNA.

Escherichia coli DNA topoisomerase I catalyzes relaxation of negatively supercoiled DNA. The reaction proceeds through a covalent intermediate, the cleavable complex, in which the DNA is cleaved and the enzyme is linked to the DNA via a phosphotyrosine linkage. Each molecule of E. coli DNA topoisomerase I has been shown to have three tightly bound zinc(II) ions required for relaxation activity (Tse-Dinh, Y.-C., and Beran-Steed, R.K. (1988) J. Biol. Chem. 263, 15857-15859). It is shown here that Cd(II) could replace Zn(II) in reconstitution of active enzyme from apoprotein. The role of metal was analyzed by studying the partial reactions. The apoenzyme was deficient in sodium dodecyl sulfate-induced cleavage of supercoiled PM2 phage DNA. Formation of covalent complex with linear single-stranded DNA was also reduced in the absence of metal. However, the cleavage of small oligonucleotide was not affected, and the apoenzyme could religate the covalently bound oligonucleotide to another DNA molecule. Assay of noncovalent complex formation by retention of 5'-labeled DNA on filters showed that the apoenzyme was not inhibited in noncovalent binding to DNA. It is proposed that zinc(II) coordination in E. coli DNA topoisomerase I is required for the transition of the noncovalent complex with DNA to the cleavable state.     

Substituents on etoposide that interact with human topoisomerase IIalpha in the binary enzyme-drug complex: contributions to etoposide binding and activity

Etoposide is a widely prescribed anticancer agent that stabilizes topoisomerase II-mediated DNA strand breaks. The drug contains a polycyclic ring system (rings A-D), a glycosidic moiety at C4, and a pendant ring (E-ring) at C1. A recent study that focused on yeast topoisomerase II demonstrated that the H15 geminal protons of the etoposide A-ring, the H5 and H8 protons of the B-ring, and the H2', H6', 3'-methoxyl, and 5'-methoxyl protons of the E-ring contact topoisomerase II in the binary enzyme-drug complex [ Wilstermann et al. (2007) Biochemistry 46, 8217-8225 ]. No interactions with the C4 sugar were observed. The present study used DNA cleavage assays, saturation transfer difference [ (1)H] NMR spectroscopy, and enzyme-drug binding studies to further define interactions between etoposide and human topoisomerase IIalpha. Etoposide and three derivatives that lacked the C4 sugar were analyzed. Except for the sugar, 4'-demethyl epipodophyllotoxin is identical to etoposide, epipodophyllotoxin contains a 4'-methoxyl group on the E-ring, and 6,7- O, O-demethylenepipodophyllotoxin replaces the A-ring with a diol. Results suggest that etoposide-topoisomerase IIalpha binding is driven by interactions with the A- and B-rings and potentially by stacking interactions with the E-ring. We propose that the E-ring pocket on the enzyme is confined, because the addition of bulk to this ring adversely affects drug function. The A- and E-rings do not appear to contact DNA in the enzyme-drug-DNA complex. Conversely, the sugar moiety subtly alters DNA interactions. The identification of etoposide substituents that contact topoisomerase IIalpha in the binary complex has predictive value for drug behavior in the enzyme-etoposide-DNA complex.     

Contributions of the D-Ring to the activity of etoposide against human topoisomerase IIα: potential interactions with DNA in the ternary enzyme--drug--DNA complex

Etoposide is a widely prescribed anticancer drug that stabilizes covalent topoisomerase II-cleaved DNA complexes. The drug contains a polycyclic ring system (rings A-D), a glycosidic moiety at C4, and a pendant ring (E-ring) at C1. Interactions between human topoisomerase IIα and etoposide in the binary enzyme--drug complex appear to be mediated by substituents on the A-, B-, and E-rings of etoposide. These protein--drug contacts in the binary complex have predictive value for the actions of etoposide within the ternary topoisomerase IIα--drug--DNA complex. Although the D-ring of etoposide does not appear to contact topoisomerase IIα in the binary complex, etoposide derivatives with modified D-rings display reduced cytotoxicity against murine leukemia cells [Meresse, P., et al. (2003) Bioorg. Med. Chem. Lett. 13, 4107]. This finding suggests that alterations in the D-ring may affect etoposide activity toward topoisomerase IIα in the ternary enzyme--drug--DNA complex. Therefore, to address the potential contributions of the D-ring to the activity of etoposide, we characterized drug derivatives in which the C13 carbonyl was moved to the C11 position (retroetoposide and retroDEPT) or the D-ring was opened (D-ring diol). All of the D-ring alterations decreased the ability of etoposide to enhance DNA cleavage mediated by human topoisomerase IIα in vitro and in cultured cells. They also weakened etoposide binding in the ternary enzyme--drug--DNA complex and altered sites of enzyme-mediated DNA cleavage. On the basis of these findings, we propose that the D-ring of etoposide has important interactions with DNA in the ternary topoisomerase II cleavage complex.     

Evidence for a common mechanism of action for antitumor and antibacterial agents that inhibit type II DNA topoisomerases

Numerous antitumor and antibacterial agents inhibit type II DNA topoisomerases, yielding, in each case, a complex of enzyme covalently bound to cleaved DNA. We are investigating the mechanism of inhibitor action by using the type II DNA topoisomerase of bacteriophage T4 as a model. The T4 topoisomerase is the target of antitumor agent 4'-(9-acridinylamino)-methanesulfon-m-anisidide (m-AMSA) in T4-infected Escherichia coli. Two m-AMSA-resistant phage strains were previously isolated, one with a point mutation in topoisomerase subunit gene 39 and the other with a point mutation in topoisomerase subunit gene 52. We report here that the wild-type T4 topoisomerase is inhibited by six additional antitumor agents that also inhibit the mammalian type II topoisomerase: ellipticine, 9-OH-ellipticine, 2-me-9-OH-ellipticinium acetate, mitoxantrone diacetate, teniposide, and etoposide. Further, one or both of the m-AMSA-resistance mutations alters the enzyme sensitivity to each of these agents, conferring either cross-resistance or enhanced sensitivity. Finally, the gene 39 mutation confers on T4 topoisomerase a DNA gyrase-like sensitivity to the gyrase inhibitor oxolinic acid, thus establishing a direct link between the mechanism of action of the anti-bacterial quinolones and that of the antitumor agents. These results strongly suggest that diverse inhibitors of type II topoisomerases share a common binding site and a common mechanism of action, both of which are apparently conserved in the evolution of the type II DNA topoisomerases. Alterations in DNA cleavage site specificity caused by either the inhibitors or the m-AMSA-resistance mutations favor the proposal that the inhibitor binding site is composed of both protein and DNA.     

Stabilization of the topoisomerase II-DNA cleavage complex by antineoplastic drugs: inhibition of enzyme-mediated DNA religation by 4'-(9-acridinylamino)methanesulfon-m-anisidide

In order to elucidate the mechanism by which the intercalative antineoplastic drug 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA) stabilizes the covalent topoisomerase II-DNA cleavage complex, the effect of the drug on the DNA cleavage/religation reaction of the type II enzyme from Drosophila melanogaster was examined. At a concentration of 60 microM, m-AMSA enhanced topoisomerase II mediated double-stranded DNA breakage approximately 5-fold. Drug-induced stabilization of the enzyme-DNA cleavage complex was readily reversed by the addition of EDTA or salt. When a DNA religation assay was utilized, m-AMSA was found to inhibit the topoisomerase II mediated rejoining of cleaved DNA approximately 3.5-fold. This result is similar to that previously reported for the effects of etoposide on the activity of the Drosophila enzyme [Osheroff, N. (1989) Biochemistry 28, 6157-6160]. Thus, it appears that structurally disparate classes of topoisomerase II targeted antineoplastic drugs stabilize the enzyme's DNA cleavage complex primarily by interfering with the ability of topoisomerase II to religate DNA.     

New insight for fluoroquinophenoxazine derivatives as possibly new potent topoisomerase I inhibitor

Fluoroquinolones, represented by ciproxacin and norfloxacin, are well-known clinical antimicrobial agents, and their phenyl ring expanded quinophenoxazines are reported as possible antitumor active compounds. These quinophenoxazines are known to inhibit DNA topoisomerase II essential for cell replication cycle. But there were no reports for topoisomerase I inhibition study for these compounds. In this report, we have prepared a few quinophenoxazine analogues and tested their topoisomerases I and II inhibitory activities and cytotoxicity. From the result, we found that quinophenoxazine analogues possessed strong topoisomerase I inhibitory capacity as well as topoisomerase II inhibition. Among the compounds prepared, A-62176 analogues showed strong topoisomerases I and II inhibitory activities. Interestingly, compound 8 missing the 3-aminopyrrolidine moiety at C2 position has similar potent inhibitory capacity against topoisomerases I and II at higher concentrations (20 and 10 microM, respectively). But compound 8 inhibited topoisomerase I function more selectively at lower concentration, 2 microM. Our observation might strongly implicate that fluoroquinophenoxazines can be developed as efficient topoisomerase I inhibitor with the elaborate modification.     

A two-drug model for etoposide action against human topoisomerase IIalpha

The widely used anticancer drug etoposide kills cells by increasing levels of topoisomerase II-mediated DNA breaks. While it is known that the drug acts by inhibiting the ability of topoisomerase II to ligate cleaved DNA molecules, the precise mechanism by which it accomplishes this action is not well understood. Because there are two scissile bonds per enzyme-mediated double-stranded DNA break, it has been assumed that there are two sites for etoposide in every cleavage complex. However, it is not known whether the action of etoposide at only one scissile bond is sufficient to stabilize a double-stranded DNA break or whether both drug sites need to be occupied. An oligonucleotide system was utilized to address this important issue. Results of DNA cleavage and ligation assays support a two-drug model for the action of etoposide against human topoisomerase IIalpha. This model postulates that drug interactions at both scissile bonds are required in order to increase enzyme-mediated double-stranded DNA breaks. Etoposide actions at either of the two scissile bonds appear to be independent of one another, with each individual drug molecule stabilizing a strand-specific nick rather than a double-stranded DNA break. This finding suggests (at least in the presence of drug) that there is little or no communication between the two promoter active sites of topoisomerase II. The two-drug model has implications for cancer chemotherapy, the cellular processing of etoposide-stabilized enzyme-DNA cleavage complexes, and the catalytic mechanism of eukaryotic topoisomerase II.     

Amsacrine as a topoisomerase II poison: importance of drug-DNA interactions

Amsacrine (m-AMSA) is an anticancer agent that displays activity against refractory acute leukemias as well as Hodgkin's and non-Hodgkin's lymphomas. The drug is comprised of an intercalative acridine moiety coupled to a 4'-amino-methanesulfon-m-anisidide headgroup. m-AMSA is historically significant in that it was the first drug demonstrated to function as a topoisomerase II poison. Although m-AMSA was designed as a DNA binding agent, the ability to intercalate does not appear to be the sole determinant of drug activity. Therefore, to more fully analyze structure-function relationships and the role of DNA binding in the action of m-AMSA, we analyzed a series of derivatives for the ability to enhance DNA cleavage mediated by human topoisomerase IIα and topoisomerase IIβ and to intercalate DNA. Results indicate that the 3'-methoxy (m-AMSA) positively affects drug function, potentially by restricting the rotation of the headgroup in a favorable orientation. Shifting the methoxy to the 2'-position (o-AMSA), which abrogates drug function, appears to increase the degree of rotational freedom of the headgroup and may impair interactions of the 1'-substituent or other portions of the headgroup within the ternary complex. Finally, the nonintercalative m-AMSA headgroup enhanced enzyme-mediated DNA cleavage when it was detached from the acridine moiety, albeit with 100-fold lower affinity. Taken together, our results suggest that much of the activity and specificity of m-AMSA as a topoisomerase II poison is embodied in the headgroup, while DNA intercalation is used primarily to increase the affinity of m-AMSA for the topoisomerase II-DNA cleavage complex.     

Topoisomerase II is a cellular target for antiproliferative cobalt salicylaldoxime complex.

Topoisomerase II is a cellular target for a number of clinically relevant antitumor drugs. To elucidate the possible cellular target for the antiproliferation activity of cobalt salicylaldoxime (CoSAL), which inhibits 50% of leukemic cell proliferation at a concentration of 60 microM, DNA binding studies and studies of the action of this complex on topoisomerase II catalytic activities were carried out. The results from DNA binding studies show that CoSAL binds DNA strongly with a stoichiometric ratio of two drug molecules for five nucleotide bases and shows a mode of interaction similar to that of DNA groove binding agents. The results from topoisomerase II inhibition studies show that the complex inhibits the relaxation activity of topoisomerase II in a dose-dependent manner and poisons its activity through cleavage complex formation. To see if the hydroxyl group present on imine nitrogen is involved in topoisomerase II poisoning, we synthesized an analogue of CoSAL in which the hydroxyl group was replaced with semicarbazone. This complex too binds DNA with an affinity similar to that of CoSAL, but with a small difference in the mode of interaction; however, it marginally inhibits leukemic cell proliferation and does not inhibit topoisomerase II activity, which suggests the involvement of a hydroxyl group. An immunoprecipitation assay was conducted which showed that the cleavage complex formed in the presence of CoSAL contained 75% of the complex, while the other complex shows only 7. 65%. Cyclic voltametric spectra of the complexes in the presence of DNA show that they do not oxidize DNA. These results suggest that CoSAL shows a bidirectional mode of interaction with enzyme and DNA and inhibits topoisomerase II activity by forming a drug-mediated cleavage complex. Our data strongly suggest that topoisomerase II may be one of the cellular targets for antiproliferation activity of CoSAL.     

Stimulation of topoisomerase II mediated DNA cleavage at specific sequence elements by the 2-nitroimidazole Ro 15-0216

The effect of the 2-nitroimidazole Ro 15-0216 upon the interaction between purified topoisomerase II and its DNA substrate was investigated. The cleavage reaction in the presence of this DNA-nonintercalative drug took place with the hallmarks of a regular topoisomerase II mediated cleavage reaction, including covalent linkage of the enzyme to the cleaved DNA. In the presence of Ro 15-0216, topoisomerase II mediated cleavage was extensively stimulated at major cleavage sites of which only one existed in the 4363 base pair pBR322 molecule. The sites stimulated by Ro 15-0216 shared a pronounced sequence homology, indicating that a specific nucleotide sequence is crucial for the action of this drug. The effect of Ro 15-0216 thus differs from that of the clinically important topoisomerase II targeted agents such as mAMSA, VM26, and VP16, which enhance enzyme-mediated cleavage at a multiple number of sites. In contrast to the previous described drugs, Ro 15-0216 did not exert any inhibitory effect on the enzyme's catalytic activity. This observation might be ascribed to the low stability of the cleavage complexes formed in the presence of Ro 15-0216 as compared to the stability of the ones formed in the presence of traditional topoisomerase II targeted drugs.     

Human DNA topoisomerase IIbeta binds and cleaves four-way junction DNA in vitro.

We have used gel retardation analysis to show that human DNA topoisomerase IIbeta can bind a 40 bp linear duplex containing a single DNA topoisomerase IIbeta cleavage site. Furthermore, we demonstrate for the first time that human DNA topoisomerase IIbeta binds to four-way junction DNA. This supports previous suggestions that topoisomerase II may be targeted to supercoiled DNA through the recognition of DNA cruciforms, helix-helix crossovers and hairpins. DNA topoisomerase IIbeta had a 4-fold higher affinity for the four-way junction than for the linear duplex, as demonstrated by protein titration and competition analysis. Furthermore, the DNA topoisomerase IIbeta:four-way junction complex was significantly more salt stable than the complex with linear DNA. The four-way junction contained potential topoisomerase IIbeta cleavage sites straddling the points of strand exchange, and indeed, topoisomerase IIbeta was able to cleave three of these four predicted sites. This indicates that topoiso-merase IIbeta can bind to the centre of the junction. Topoisomerase II has to bind both the transported and the gated DNA helices prior to strand passage, and it is possible that both helices are provided by the four-way junction in this case. The stable complex of DNA topoisomerase IIbeta with four-way junction DNA may provide an ideal substrate for further studies into the mechanism of substrate recognition and binding by DNA topoisomerase II.     

Eukaryotic topoisomerase II cleavage of parallel stranded DNA tetraplexes.

A guanine-rich single-stranded DNA from the human immunoglobulin switch region was shown by Sen and Gilbert [Nature, (1988) 334, 364-366] to be able to self-associate to form a stable four-stranded parallel DNA structure. Topoisomerase II did not cleave the single-stranded DNA molecule. Surprisingly, the enzyme did cleave the same DNA sequence when it was annealed into the four-stranded structure. The two cleavage sites observed were the same as those found when this DNA molecule was paired with a complementary molecule to create a normal B-DNA duplex. These cleavages were shown to be protein-linked and reversible by the addition of salt, suggesting a normal topoisomerase II reaction mechanism. In addition, an eight-stranded DNA molecule created by the association of a complementary oligonucleotide with the four-stranded structure was also cleaved by topoisomerase II despite being resistant to restriction endonuclease digestion. These results suggest that a single strand of DNA may possess the sequence information to direct topoisomerase II to a binding site, but the site must be base paired in a proper manner to do so. This demonstration of the ability of a four-stranded DNA molecule to be a substrate for an enzyme further suggests that these DNA structures may be present in cells.     

Identification of the breakage-reunion subunit of T4 DNA topoisomerase

The antitumor drug 4'-(9-acridinylamino)methanesulfon-m-anisidide which stimulates the cleavable complex formation between mammalian DNA topoisomerase II and DNA also stimulates the cleavable complex formation between bacteriophage T4-induced DNA topoisomerase and DNA. In the presence of 4'-(9-acridinylamino)methanesulfon-m-anisidide, T4 DNA topoisomerase and DNA form a "cleavable complex" which is characterized by its sensitivity to protein-denaturant treatment. Upon protein-denaturant treatment, the phosphodiester bond of DNA is cleaved, and the gene 52 protein subunit of the topoisomerase becomes covalently linked to the 5'-end of the broken DNA. The covalent protein-DNA linkage has been determined by both paper electrophoresis and thin layer chromatography to be tyrosyl phosphate.     

Mode of action of topoisomerase II-targeting agents at a specific DNA sequence. Uncoupling the DNA binding, cleavage and religation events.

Methods of uncoupling the DNA binding, cleavage and religation reactions of topoisomerase II were employed to investigate the influence of topoisomerase II-directed drugs on the individual steps in the enzyme's catalytic cycle. A special DNA substrate containing a major topoisomerase II interaction site, which can be cleaved by the enzyme in the absence of any concomitant religation, was used to examine the effect of topoisomerase II-directed agents upon the DNA cleavage reaction. The experiment demonstrated that the topoisomerase II targeting agent Ro 15-0216 stimulates the DNA cleavage reaction extensively, whereas the traditional topoisomerase II inhibitor, mAMSA, has only a minor effect on this reaction. Topoisomerase II trapped in the cleavage complexes can religate to the 3' hydroxyl end of another DNA strand. Using this religation assay, it was demonstrated that the major effect of mAMSA is an inhibition of the enzyme's religation reaction, whereas Ro 15-0216 has no effect on this reaction. Recently, considerable attention has been given to drugs preventing topoisomerase II from introducing DNA cleavages. In the present paper the initial non-covalent DNA binding reaction of topoisomerase II was investigated under conditions excluding enzyme-mediated DNA cleavage. This demonstrated that the anthracycline, aclarubicin, prevents topoisomerase II from performing its initial non-covalent DNA binding reaction and thereby abolishes the DNA cleavage reaction of the enzyme. The results presented here demonstrate that profound differences exist in the mode of action of different agents targeting topoisomerase II, and that the enzyme can be affected by such agents at both its DNA binding, cleavage and religation subreactions.     

Nuclease protection by Drosophila DNA topoisomerase II. Enzyme/DNA contacts at the strong topoisomerase II cleavage sites

A DNA consensus sequence for topoisomerase II cleavage sites was derived previously based on a statistical analysis of the nucleotide sequences around 16 sites that can be efficiently cleaved by Drosophila topoisomerase II (Sander, M., and Hsieh, T. (1985) Nucleic Acids Res. 13, 1057-1072). A synthetic 21-mer DNA sequence containing this cleavage consensus sequence was cloned into a plasmid vector, and DNA topoisomerase II can cleave this sequence at the position predicted by the cleavage consensus sequence. DNase I footprint analysis showed that topoisomerase II can protect a region of approximately 25 nucleotides in both strands of the duplex DNA, with the cleavage site located near the center of the protected region. Similar correlation between the DNase I footprints and strong topoisomerase II cleavage sites has been observed in the intergenic region of the divergent HSP70 genes. This analysis therefore suggests that the strong DNA cleavage sites of Drosophila topoisomerase II likely correspond to specific DNA-binding sites of this enzyme. Furthermore, the extent of DNA contacts made by this enzyme suggests that eucaryotic topoisomerase II, in contrast to bacterial DNA bacterial DNA gyrase, cannot form a complex with extensive DNA wrapping around the enzyme. The absence of DNA wrapping is probably the mechanistic basis for the lack of DNA supercoiling action for eucaryotic topoisomerase II.