Relationship between sensitivity to 4′-(9-acridinylamino)methanesulfon-m-anisidide and DNA topoisomerase II in a cold-sensitive cell-cycle mutant of a murine mastocytoma cell line

The cold-sensitive (proliferating at 39.5°C, reversibly arrested in GI-phase at 33°C) cell-cycle mutant 21-Fb of the murine mastocytoma cell line P815 was used to study the effect of amsacrine on non-cycling cells. The sensitivity of arrested 21-Fb cells decreased less than 2-fold in cell survival experiments when compared to proliferating cells. In contrast, DNA breakage and stimulation of protein-DNA complex formation in intact or lysed cells was reduced approx. 10-fold in arrested cells and DNA topoisomerase II activity in arrested cells was only 5% of the activity in proliferating cells. Thus, there was no correlation between cell survival and DNA damage or DNA topoisomerase II activity in drug-treated cells.     

Effects of the DNA intercalators 4'-(9-acridinylamino)methanesulfon-m-anisidide and 2-methyl-9-hydroxyellipticinium on topoisomerase II mediated DNA strand cleavage and strand passage

DNA topoisomerase II is believed to be the enzyme that produces the protein-associated DNA strand breaks observed in mammalian cell nuclei treated with various intercalating agents. Two intercalators--4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA, amsacrine) and 2-methyl-9-hydroxyellipticinium (2-Me-9-OH-E+)--differ in their effects on protein-associated double-strand breaks in isolated nuclei. m-AMSA stimulates their production at all concentrations, whereas 2-Me-9-OH-E+ stimulates at low concentrations and inhibits at high concentrations. We have reproduced these differential effects in experiments carried out in vitro with purified L1210 DNA topoisomerase II, and we have found that concentrations of 2-Me-9-OH-E+ above 5 microM prevent the trapping of DNA-topoisomerase II cleavable complexes irrespective of the presence of m-AMSA. It also stimulated topoisomerase II mediated DNA strand passage, again with or without inhibitory amounts of m-AMSA (this result suggests that extensive intercalation by 2-Me-9-OH-E+ destabilized the cleavable complexes). From these data, it is concluded that intercalator-induced protein-associated DNA strand breaks observed in intact eukaryotic cells and isolated nuclei are generated by DNA topoisomerase II and that intercalators can affect mammalian DNA topoisomerase II in more than one way. They can trap cleavable complexes and inhibit DNA topoisomerase II mediated DNA relaxation (m-AMSA and low concentrations of 2-Me-9-OH-E+) or destabilize cleavable complexes and stimulate DNA relaxation (high concentrations of 2-Me-9-OH-E+).     

Induction of mammalian DNA topoisomerase I and II mediated DNA cleavage by saintopin, a new antitumor agent from fungus.

Saintopin is an antitumor antibiotic recently discovered in mechanistically oriented screening using purified calf thymus DNA topoisomerases. Saintopin induced topoisomerase I mediated DNA cleavage comparable to that of camptothecin, and topoisomerase II mediated DNA cleavage equipotent to those of 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA) or 4'-demethylepipodophyllotoxin 9-(4,6-O-ethylidene-beta-D-glucopyranoside) (VP-16). Treatment of a reaction mixture containing saintopin and topoisomerase I or II with either elevated temperature (65 degrees C) or higher salt concentration (0.5 M NaCl) resulted in a substantial reduction in DNA cleavage, suggesting that the topoisomerase I and II mediated DNA cleavage induced by saintopin is through the mechanism of stabilizing the reversible enzyme-DNA "cleavable complex". Consistent with the cleavable complex formation with both topoisomerases, saintopin inhibited catalytic activities of both topoisomerase I and topoisomerase II. The DNA cleavage intensity pattern induced by saintopin with topoisomerase I was different from that by camptothecin. A difference in cleavage pattern was also detected between saintopin and m-AMSA or VP-16 in topoisomerase II mediated DNA cleavage. DNA unwinding assay using T4 DNA ligase showed that saintopin is a weak DNA intercalator like m-AMSA. Thus, saintopin represents a new class of antitumor agent that can induce both mammalian DNA topoisomerase I and mammalian DNA topisomerase II mediated DNA cleavage.     

In vivo mapping of DNA topoisomerase II-specific cleavage sites on SV40 chromatin

The antitumor drug, m-AMSA (4'-(9-acridinylamino)-methanesulfon-m-anisidide), is known to interfere with the breakage-reunion reaction of mammalian DNA topoisomerase II by blocking the enzyme-DNA complex in its putative cleavable state. Treatment of SV40 virus infected monkey cells with m-AMSA resulted in both single- and double-stranded breaks on SV40 viral chromatin. These strand breaks are unusual because they are covalently associated with protein. Immunoprecipitation results suggest that the covalently linked protein is DNA topoisomerase II. These results are consistent with the proposal that the drug action in vivo involves the stabilization of a cleavable complex between topoisomerase II and DNA in chromatin. Mapping of these double-stranded breaks on SV40 viral DNA revealed multiple topoisomerase II cleavage sites. A major topoisomerase II cleavage site was preferentially induced during late infection and was mapped in the DNAase I hypersensitive region of SV40 chromatin.     

Induction of mammalian DNA topoisomerase I mediated DNA cleavage by antitumor indolocarbazole derivatives.

DNA topoisomerases have been shown to be important therapeutic targets in cancer chemotherapy. We found that KT6006 and KT6528, synthetic antitumor derivatives of indolocarbazole antibiotic K252a, were potent inducers of a cleavable complex with topoisomerase I. In DNA cleavage assay using purified calf thymus DNA topoisomerase I and supercoiled pBR322 DNA, KT6006 induced topoisomerase I mediated DNA cleavage in a dose-dependent manner at drug concentrations up to 50 microM, while DNA cleavage induced by KT6528 was saturated at 5 microM. The maximal amount of nicked DNA produced by KT6006 was more than 50% of substrate DNA, which was comparable to that of camptothecin. Heat treatment (65 degrees C) of the reaction mixture containing these compounds and topoisomerase I resulted in a substantial reduction in DNA cleavage, suggesting that topoisomerase I mediated DNA cleavage induced by KT6006 and KT6528 is through the mechanism of stabilizing the reversible enzyme-DNA "cleavable complex". Both KT6006 and KT6528 did not induce topoisomerase II mediated DNA cleavage in vitro. KT6006 and KT6528 were found to induce nearly identical topoisomerase I mediated DNA cleavage patterns, which was distinctly different from that with camptothecin. In contrast to the similarity between KT6006 and KT6528 in their structures and the nature of their cleavable complex with topoisomerase I, these drugs have different properties with respect to their interaction with DNA: KT6006 is a very weak intercalator whereas KT6528 is a strong intercalator with potentials comparable to that of adriamycin. These results indicate that KT6006 and KT6528 represent a new distinct class of mammalian DNA topoisomerase I active antitumor drugs.     

Topoisomerase II from Chlorella virus PBCV-1 has an exceptionally high DNA cleavage activity

Chlorella virus PBCV-1 topoisomerase II is the only functional type II enzyme known to be encoded by a virus that infects eukaryotic cells. However, it has not been established whether the protein is expressed following viral infection or whether the enzyme has any catalytic features that distinguish it from cellular type II topoisomerases. Therefore, the present study characterized the physiological expression of PBCV-1 topoisomerase II and individual reaction steps catalyzed by the enzyme. Results indicate that the topoisomerase II gene is widely distributed among Chlorella viruses and that the protein is expressed 60-90 min after viral infection of algal cells. Furthermore, the enzyme has an extremely high DNA cleavage activity that sets it apart from all known eukaryotic type II topoisomerases. Levels of DNA scission generated by the viral enzyme are approximately 30 times greater than those observed with human topoisomerase IIalpha. The high levels of cleavage are not due to inordinately tight enzyme-DNA binding or to impaired DNA religation. Thus, they most likely reflect an elevated forward rate of scission. The robust DNA cleavage activity of PBCV-1 topoisomerase II provides a unique tool for studying the catalytic functions of type II topoisomerases.     

Isolation of intercalator-dependent protein-linked DNA strand cleavage activity from cell nuclei and identification as topoisomerase II

DNA intercalating agents such as 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA) have previously been found to induce in mammalian cells the formation of protein-associated DNA single- and double-strand breaks. In the current work, an activity characterized by the production of DNA-protein links associated with DNA strand breaks and by stimulation by m-AMSA was isolated from L1210 cell nuclei and was shown to be due to topoisomerase II. Nuclei were extracted with 0.35 M NaCl, and the extract was fractionated by gel filtration, DNA-cellulose chromatography, and glycerol gradient centrifugation. A rapid filter binding assay was devised to monitor the fractionation procedure on the basis of DNA-protein linking activity. The active DNA-cellulose fraction contained both topoisomerase I and topoisomerase II whereas the glycerol gradient purified material contained only topoisomerase II activity. The properties of the active material were studied at both stages of purification. m-AMSA enhanced the formation of complexes between purified topoisomerase II and SV40 DNA in which the DNA sustained a single- or double-strand cut and the enzyme was covalently linked to the 5' terminus of the DNA. This action was further enhanced by ATP, as well as by nonhydrolyzable ATP analogues. m-AMSA inhibited the topoisomerization and catenation reactions of topoisomerase II, probably because of trapping of the enzyme-DNA complexes. The activity showed a dependence on the type of DNA intercalators used, analogous to what was previously observed in intact cells. m-AMSA had no effect on topoisomerase I.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification of GidA protein,a novel topoisomerase II inhibitor produced by Streptomyces flavoviridis

The presence of topoisomerase II inhibition activities in the intracellular extract of Streptomyces flavoviridis was investigated. One active compound inhibiting relaxation activity of topoisomerase II was determined to be a protein. This active principle was purified to homogeneity by gel filtration followed by ion exchange chromatography. The apparent molecular mass was 42 kDa as determined by SDS-PAGE. MALDI TOF peptide mass fingerprinting analysis confirmed this topoisomerase II inhibitor, as glucose-inhibited division protein A (GidA) by MOWSE score of 72. The effects of purified GidA protein on DNA relaxation and decatenation by topoisomerase II were investigated. It inhibited topoisomerase II activity and acted as a topoisomerase poison that significantly stabilized the covalent DNA-topoisomerase II reaction intermediate “cleavable complex”, as observed with etoposide. Collectively, these findings indicate that GidA is a potent inhibitor of topoisomerase II enzyme, which can be exploited for rational drug design in human carcinomas.     

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.     

The p53 tumor suppressor stimulates the catalytic activity of human topoisomerase IIalpha by enhancing the rate of ATP hydrolysis

DNA topoisomerase II is an essential nuclear enzyme for proliferation of eukaryotic cells and plays important roles in many aspects of DNA processes. In this report, we have demonstrated that the catalytic activity of topoisomerase IIalpha, as measured by decatenation of kinetoplast DNA and by relaxation of negatively supercoiled DNA, was stimulated approximately 2-3-fold by the tumor suppressor p53 protein. In order to determine the mechanism by which p53 activates the enzyme, the effects of p53 on the topoisomerase IIalpha-mediated DNA cleavage/religation equilibrium were assessed using the prototypical topoisomerase II poison, etoposide. p53 had no effect on the ability of the enzyme to make double-stranded DNA break and religate linear DNA, indicating that the stimulation of the enzyme catalytic activity by p53 was not due to alteration in the formation of covalent cleavable complexes formed between topoisomerase IIalpha and DNA. The effects of p53 on the catalytic inhibition of topoisomerase IIalpha were examined using a specific catalytic inhibitor, ICRF-193, which blocks the ATP hydrolysis step of the enzyme catalytic cycle. Clearly manifested in decatenation and relaxation assays, p53 reduced the catalytic inhibition of topoisomerase IIalpha by ICRF-193. ATP hydrolysis assays revealed that the ATPase activity of topoisomerase IIalpha was specifically enhanced by p53. Immunoprecipitation experiments revealed that p53 physically interacts with topoisomerase IIalpha to form molecular complexes without a double-stranded DNA intermediary in vitro. To investigate whether p53 stimulates the catalytic activity of topoisomerase II in vivo, we expressed wild-type and mutant p53 in Saos-2 osteosarcoma cells lacking functional p53. Wild-type, but not mutant, p53 stimulated topoisomerase II activity in nuclear extract from these transfected cells. Our data propose a new role for p53 to modulate the catalytic activity of topoisomerase IIalpha. Taken together, we suggest that the p53-mediated response of the cell cycle to DNA damage may involve activation of topoisomerase IIalpha.     

Two independent amsacrine-resistant human myeloid leukemia cell lines share an identical point mutation in the 170 kDa form of human topoisomerase II.

Cloning and sequencing of cDNA segments of human TOP2 gene encoding the 170 kDa form of human DNA topoisomerase II show that Arg486 of the enzyme has been mutated to a lysine in the enzyme from two human leukemia cell lines HL-60/AMSA and KBM-3/AMSA, which were independently selected for resistance to the antitumor drug amsacrine (4'-[9-acridinylamino]-methanesulfon-m-anisidide, mAMSA). Sequence identity comparisons between eukaryotic DNA topoisomerase II and bacterial gyrase (bacterial DNA topoisomerase II) indicate that the position of the common mutation observed in mAMSA-resistant human TOP2 corresponds to that of the point mutation nal-31 in the Escherichia coli gyrase B gene, which confers resistance to nalidixic acid. Because mAMSA and nalidixic acid are known to act on their respective targets by a common mechanism of trapping the covalent enzyme-DNA intermediates, these results provide strong evidence that the 170 kDa form of human DNA topoisomerase II is a major cellular target of mAMSA, and that Arg486 of this enzyme is involved in mAMSA-mediated trapping of the covalent enzyme-DNA complex.     

Incomplete reversion of double stranded DNA cleavage mediated by Drosophila topoisomerase II: formation of single stranded DNA cleavage complex in the presence of an anti-tumor drug VM26.

Anti-tumor drug VM26 greatly stimulates topoisomerase II mediated DNA cleavage by stabilizing the cleavable complex. Addition of a strong detergent such as SDS to the cleavable complex induces the double stranded DNA cleavage. We demonstrate here that heat treatment can reverse the double stranded DNA cleavage; however, topoisomerase II remains bound to DNA even in the presence of SDS. This reversed complex has been shown to contain single strand DNA breaks with topoisomerase II covalently linked to the nicked DNA. Chelation of Mg++ by EDTA and the addition of salt to a high concentration also reverse the double strand DNA cleavage, and like heat reversion, topoisomerase II remains bound to DNA through single strand DNA break. The reversion complex can be analyzed and isolated by CsCl density gradient centrifugation. We have detected multiple discrete bands from such a gradient, corresponding to protein/DNA complexes with 1, 2, 3, ..... topoisomerase II molecules bound per DNA molecule. Analysis of topoisomerase II/DNA complexes isolated from the CsCl gradient indicates that there are single stranded DNA breaks associated with the CsCl stable complexes. Therefore, topoisomerase II/DNA complex formed in the presence of VM26 cannot be completely reversed to yield free DNA and enzyme. We discuss the possible significance of this finding to the mechanism of action of VM26 in the topoisomerase II reactions.     

The SUMO pathway is required for selective degradation of DNA topoisomerase IIbeta induced by a catalytic inhibitor ICRF-193(1)

DNA topoisomerase I and II have been shown to be modified with a ubiquitin-like protein SUMO in response to their specific inhibitors called 'poisons'. These drugs also damage DNA by stabilizing the enzyme-DNA cleavable complex and induce a degradation of the enzymes through the 26S proteasome system. A plausible link between sumoylation and degradation has not yet been elucidated. We demonstrate here that topoisomerase IIbeta, but not its isoform IIalpha, is selectively degraded through proteasome by exposure to the catalytic inhibitor ICRF-193 which does not damage DNA. The beta isoform immunoprecipitated from ICRF-treated cells was modified by multiple modifiers, SUMO-2/3, SUMO-1, and polyubiquitin. When the SUMO conjugating enzyme Ubc9 was conditionally knocked out, the ICRF-induced degradation of topoisomerase IIbeta did not occur, suggesting that the SUMO modification pathway is essential for the degradation.     

Irreversible trapping of the DNA-topoisomerase I covalent complex. Affinity labeling of the camptothecin binding site

Camptothecin (CPT) binds reversibly to, and thereby stabilizes, the cleavable complex formed between DNA and topoisomerase I. The nature of the interaction of CPT with the DNA-topoisomerase I binary complex was studied by the use of two affinity labeling reagents structurally related to camptothecin: 10-bromoacetamidomethylcamptothecin (BrCPT) and 7-methyl-10-bromoacetamidomethylcamptothecin (BrCPTMe). These compounds have been shown to trap the DNA-topoisomerase I complex irreversibly. Although cleavage of DNA plasmid mediated by topoisomerase I and camptothecin was reduced significantly by treatment with high salt or excess competitor DNA, enzyme-mediated DNA cleavage stabilized by BrCTPMe persisted for at least 4 h after similar treatment. The production of irreversible topoisomerase I-DNA cleavage was time-dependent, suggesting that BrCPTMe first bound noncovalently to the enzyme-DNA complex and, in a second slower step, alkylated the enzyme or DNA in a manner that prevented DNA ligation. The formation of a covalent linkage was supported by experiments that employed [3H]BrCPT, which was shown to label topoisomerase I within the enzyme-DNA complex. [3H]BrCPT labeling of topoisomerase I was enhanced greatly by the presence of DNA; very little labeling of isolated topoisomerase I or isolated DNA occurred. Even in the presence of DNA, [3H]BrCPT labeling of topoisomerase I was inhibited by camptothecin, suggesting that both CPT and BrCPT bound to the same site on the DNA-topoisomerase I binary complex. These studies provide further evidence that a binding site for camptothecin is created as the DNA-topoisomerase I complex is formed and suggest that the A-ring of camptothecin is proximate to an enzyme residue.     

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

Many intercalative antitumor drugs have been shown to cleave DNA indirectly through their specific effect on the stabilization of a cleavable complex formed between mammalian DNA topoisomerase II and DNA (Nelson, E.M., Tewey, K.M., and Liu, L.F. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 1361-1365). Antitumor epipodophyllotoxins (VP-16 and VM-26) which do not intercalate DNA can similarly induce protein-linked DNA breaks in cultured mammalian cells. In vitro studies using purified mammalian DNA topoisomerase II show that epipodophyllotoxins interfere with the breakage-reunion reaction of mammalian DNA topoisomerase II by stabilizing a cleavable complex. Treatment of this stabilized cleavable complex with protein denaturants results in DNA strand breaks and the covalent linking of a topoisomerase subunit to the 5'-end of the broken DNA. Furthermore, epipodophyllotoxins also inhibit the strand-passing activity of mammalian DNA topoisomerase II, presumably as a result of drug-enzyme interaction. The agreement between the in vivo and in vitro studies suggests that mammalian DNA topoisomerase II is a drug target in vivo. The similarity between the effect of epipodophyllotoxins on mammalian DNA topoisomerase II and the effect of nalidixic acid on Escherichia coli DNA gyrase suggests that the cytotoxic action of epipodophyllotoxins may be analogous to the bactericidal action of nalidixic acid.     

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.     

Purification and characterization of an altered topoisomerase II from a drug-resistant Chinese hamster ovary cell line

The cytotoxicity and DNA damage induced by the epipodophyllotoxins and several intercalating agents appear to be mediated by DNA topoisomerase II. We have purified topoisomerase II to homogeneity both from an epipodophyllotoxin-resistant Chinese hamster ovary cell line, VpmR-5, and from the wild-type parental cell line. Immunoblots demonstrate similar topoisomerase II content in these two cell lines. The purified enzymes are dissimilar in that DNA cleavage by VpmR-5 topoisomerase II is not stimulated by VP-16 or m-AMSA. Furthermore, the VpmR-5 enzyme is unstable at 37 degrees C. Thus, the drug resistance of VpmR-5 cells appears to result from the presence of an altered topoisomerase II in these cells. Purified topoisomerase II from VPMR-5 and wild-type cells has the same monomeric molecular mass as well as equivalent catalytic activity with respect to decatenation of kinetoplast DNA. Etoposide (VP-16) inhibits the activity of both enzymes. Noncovalent DNA-enzyme complex formation, assayed by nitrocellulose filter binding, is also similar, as is protection from salt dissociation of this complex by ATP and VP-16. The data suggest a model in which the drug-resistant cell line, VpmR-5, has religation activity which is less affected by drug than that of the wild-type cells. Drug effect on DNA religation and catalytic activity are dissociated mechanistically. In addition, under certain circumstances, the "cleavable complex" observed following denaturation of a drug-stabilized DNA-enzyme complex may not adequately reflect the nature of the antecedent lesion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of Hsp90 acts synergistically with topoisomerase II poisons to increase the apoptotic killing of cells due to an increase in topoisomerase II mediated DNA damage

Topoisomerase II plays a crucial role during chromosome condensation and segregation in mitosis and meiosis and is a highly attractive target for chemotherapeutic agents. We have identified previously topoisomerase II and heat shock protein 90 (Hsp90) as part of a complex. In this paper we demonstrate that drug combinations targeting these two enzymes cause a synergistic increase in apoptosis. The objective of our study was to identify the mode of cell killing and the mechanism behind the increase in topoisomerase II mediated DNA damage. Importantly we demonstrate that Hsp90 inhibition results in an increased topoiosmerase II activity but not degradation of topoisomerase II and it is this, in the presence of a topoisomerase II poison that causes the increase in cell death. Our results suggest a novel mechanism of action where the inhibition of Hsp90 disrupts the Hsp90–topoisomerase II interaction leading to an increase in and activation of unbound topoisomerase II, which, in the presence of a topoisomerase II poison leads to the formation of an increased number of cleavable complexes ultimately resulting in rise in DNA damage and a subsequent increase cell death.     

Amiloride intercalates into DNA and inhibits DNA topoisomerase II

Amiloride is capable of inhibiting DNA synthesis in mammalian cells in culture. Recent evidence indicates that the enzyme, DNA topoisomerase II, is probably required for DNA synthesis to occur in situ. In experiments to determine the mechanism of inhibition of DNA synthesis by amiloride, we observed that amiloride inhibited both the catalytic activity of purified DNA topoisomerase II in vitro and DNA topoisomerase II-dependent cell functions in vivo. Many compounds capable of inhibiting DNA topoisomerase II are DNA intercalators. Thus, we performed studies to determine if and how amiloride bound to DNA. Results indicated that amiloride 1) shifted the thermal denaturation profile of DNA, 2) increased the viscosity of linear DNA, and 3) unwound circular DNA, all behavior consistent with a DNA intercalation mechanism. Furthermore, quantitative and qualitative measurements of amiloride fluorescence indicated that amiloride (a) bound reversibly to purified DNA under conditions of physiologic ionic strength, and (b) bound to purified nuclei in a highly cooperative manner. Lastly, amiloride did not promote the cleavage of DNA in the presence of DNA topoisomerase II, indicating that the mechanism by which amiloride inhibited DNA topoisomerase II was not through the stabilization of a "cleavable complex" formed between DNA topoisomerase II, DNA, and amiloride. The ability of amiloride to intercalate with DNA and inhibit topoisomerase II is consistent with the proposed planar, hydrogen-bonded, tricyclic nature of amiloride's most stable conformation. Thus, DNA and DNA topoisomerase II must be considered as new cellular targets of amiloride action.