Inhibition of Zn(II) Binding Type IA Topoisomerases by Organomercury Compounds and Hg(II)

Type IA topoisomerase activities are essential for resolving DNA topological barriers via an enzyme-mediated transient single strand DNA break. Accumulation of topoisomerase DNA cleavage product can lead to cell death or genomic rearrangement. Many antibacterial and anticancer drugs act as topoisomerase poison inhibitors that form stabilized ternary complexes with the topoisomerase covalent intermediate, so it is desirable to identify such inhibitors for type IA topoisomerases. Here we report that organomercury compounds were identified during a fluorescence based screening of the NIH diversity set of small molecules for topoisomerase inhibitors that can increase the DNA cleavage product of Yersinia pestis topoisomerase I. Inhibition of relaxation activity and accumulation of DNA cleavage product were confirmed for these organomercury compounds in gel based assays of Escherichia coli topoisomerase I. Hg(II), but not As(III), could also target the cysteines that form the multiple Zn(II) binding tetra-cysteine motifs found in the C-terminal domains of these bacterial topoisomerase I for relaxation activity inhibition. Mycobacterium tuberculosis topoisomerase I activity is not sensitive to Hg(II) or the organomercury compounds due to the absence of the Zn(II) binding cysteines. It is significant that the type IA topoisomerases with Zn(II) binding domains can still cleave DNA when interfered by Hg(II) or organomercury compounds. The Zn(II) binding domains found in human Top3α and Top3β may be potential targets of toxic metals and organometallic complexes, with potential consequence on genomic stability and development.     

Induction of sister chromatid exchanges by inhibitors of topoisomerases

To investigate the role of topoisomerases in the production of sister chromatid exchanges, the effects of inhibitors of type I and II topoisomerases on baseline and mutagen-induced sister chromatid exchanges were compared. V79 cells were treated with VM-26 and m-AMSA, known inhibitors of type II topoisomerase, or with camptothecin, the only known inhibitor of type I topoisomerase. We observed that inhibitors of both type I and II topoisomerases induced high levels of sister chromatid exchanges at 10^–6 M, and that the dose-response curves of these drugs were very similar. A clear heterogeneity in the distribution patterns of exchanges induced by inhibitors of topoisomerases was observed. We believe that this heterogeneity in response to these compounds is due to variation in sensitivity within the cell cycle. We also studied interactions of these agents with mitomycin-C and with PUVA (8-methoxypsoralen + UVA), both cross-linking agents and potent sister chromatid exchange inducers, and with x-rays, an agent that induces high levels of DNA strand breaks. No significant change in exchange levels was observed in interactions between topoisomerase inhibition and the levels induced by the agents studied. We conclude that double-strand break prevalence, known to be increased through inhibition of type II topoisomerase, is not the primary mechanism for induction of sister chromatid exchanges. We further conclude that acute inhibition of type I and type II topoisomerases does not influence substantially the induction of exchanges by other agents.Abbreviations MMC mitomycin C - 8-MOP 8-methoxypsoralen - SCE sister chromatid exchange - SFM serum-free medium     

Topoisomerase II plays an essential role as a swivelase in the late stage of SV40 chromosome replication in vitro.

The effects of topoisomerases I and II on the replication of SV40 DNA were examined using an in vitro replication system of purified proteins that constitutes the monopolymerase system. In the presence of the two topoisomerases, two distinct nascent DNAs were formed. One product arising from the replication of the leading template strand was approximately half the size of the template DNA, whereas the other product derived from the lagging template strand consisted of short DNAs. These products were synthesized from both SV40 naked DNA and SV40 chromosomes. For the replication of SV40 naked DNA, either topoisomerase I or II maintained replication fork movement and supported complete leading strand synthesis. When SV40 chromosomes were replicated with the same proteins, reactions containing only topoisomerase I produced shorter leading strands. However, mature size DNA products accumulated in reactions supplemented with topoisomerase II, as well as in reactions containing only topoisomerase II. In the presence of crude extracts of HeLa cells, VP-16, a specific inhibitor of topoisomerase II, blocked elongation of the nascent DNA during the replication of SV40 chromosomes. These results indicate that topoisomerase II plays a crucial role as a swivelase in the late stage of SV40 chromosome replication in vitro.     

Novel DNA Topoisomerase IIα Inhibitors from Combined Ligand- and Structure-Based Virtual Screening

DNA topoisomerases are enzymes responsible for the relaxation of DNA torsional strain, as well as for the untangling of DNA duplexes after replication, and are important cancer drug targets. One class of topoisomerase inhibitors, “poisons”, binds to the transient enzyme-DNA complex which occurs during the mechanism of action, and inhibits the religation of DNA. This ultimately leads to the accumulation of DNA double strand breaks and cell death. Different types of topoisomerases occur in human cells and several poisons of topoisomerase I and II are widely used clinically. However, their use is compromised by a variety of side effects. Recent studies confirm that the inhibition of the α-isoform of topoisomerase II is responsible for the cytotoxic effect, whereas the inhibition of the β-isoform leads to development of adverse drug reactions. Thus, the discovery of agents selective for topoisomerase IIα is an important strategy for the development of topoisomerase II poisons with improved clinical profiles. Here, we present a computer-aided drug design study leading to the identification of structurally novel topoisomerase IIα poisons. The study combines ligand- and structure-based drug design methods including pharmacophore models, homology modelling, docking, and virtual screening of the National Cancer Institute compound database. From the 8 compounds identified from the computational work, 6 were tested for their capacity to poison topoisomerase II in vitro: 4 showed selective inhibitory activity for the α- over the β-isoform and 3 of these exhibited cytotoxic activity. Thus, our study confirms the applicability of computer-aided methods for the discovery of novel topoisomerase II poisons, and presents compounds which could be investigated further as selective topoisomerase IIα inhibitors.     

Relaxation of supercoiled phosphorothioate DNA by mammalian topoisomerases is inhibited in a base-specific manner

The nucleotide preferences of calf thymus topoisomerases I and II for recognition of supercoiled DNA have been assessed by the relaxation and cleavage of DNA containing base-specific phosphorothioate substitutions in one strand. The type I enzyme is inhibited to varying degrees by all modified DNAs, but most effectively (by approximately 60%) if deoxyguanosine 5'-O-(1-thiomonophosphate) (dGMP alpha S) is incorporated into negatively supercoiled DNA. A DNA in which all internucleotide linkages of one strand are phosphorothionate is relaxed, most probably via the unsubstituted strand. The type II enzyme is inhibited when deoxyadenosine 5'-O-(1-thiomonophosphate) (dAMP alpha S) or deoxyribosylthymine 5'-O-(1-thiomonophosphate) is incorporated into the DNA substrate, and the course of the relaxation reaction changes from a distributive mode to a predominantly processive mode. A fully substituted DNA is very poorly relaxed by the type II enzyme, illustrating the strict commitment of the enzyme to relaxation via double-strand cleavage. The sense of supercoiling does not affect the inhibition profile of either enzyme. DNA strand breaks introduced by type II topoisomerase in a normal control DNA or deoxycytidine 5'-O-(1-thiomonophosphate)-substituted DNA on treatment with sodium dodecyl sulfate at low ionic strength are prevented by pretreatment with 0.2 M NaCl. In contrast, breaks in DNA having either dAMP alpha S or all four phosphorothioate nucleotides incorporated in one strand are prevented only with higher NaCl concentrations. Thus indicating activity at the phosphorothioate linkage 5' to dA but not 5' to dC. We conclude that topoisomerase II activity occurs preferentially at sites possessing dAMP or dTMP, and that dGMP is involved in DNA recognition by topoisomerase I.     

Inhibition of replicon initiation in human cells following stabilization of topoisomerase-DNA cleavable complexes.

Diploid human fibroblast strains were treated for 10 min with inhibitors of type I and type II DNA topoisomerases, and after removal of the inhibitors, the rate of initiation of DNA synthesis at replicon origins was determined. By alkaline elution chromatography, 4'-(9-acridinylamino)methanesulfon-m-anisidide (amsacrine), an inhibitor of DNA topoisomerase II, was shown to produce DNA strand breaks. These strand breaks are thought to reflect drug-induced stabilization of topoisomerase-DNA cleavable complexes. Removal of the drug led to a rapid resealing of the strand breaks by dissociation of the complexes. Velocity sedimentation analysis was used to quantify the effects of amsacrine treatment on DNA replication. It was demonstrated that transient exposure to low concentrations of amsacrine inhibited replicon initiation but did not substantially affect DNA chainelongation within operating replicons. Maximal inhibition of replicon initiation occurred 20 to 30 min after drug treatment, and the initiation rate recovered 30 to 90 min later. Ataxia telangiectasia cells displayed normal levels of amsacrine-induced DNA strand breaks during stabilization of cleavable complexes but failed to downregulate replicon initiation after exposure to the topoisomerase inhibitor. Thus, inhibition of replicon initiation in response to DNA damage appears to be an active process which requires a gene product which is defective or missing in ataxia telangiectasia cells. In normal human fibroblasts, the inhibition of DNA topoisomerase I by camptothecin produced reversible DNA strand breaks. Transient exposure to this drug also inhibited replicon initiation. These results suggest that the cellular response pathway which downregulates replicon initiation following genotoxic damage may respond to perturbations of chromatin structure which accompany stabilization of topoisomerase-DNA cleavable complexes.     

Reprint of “The mechanism of negative DNA supercoiling: A cascade of DNA-induced conformational changes prepares gyrase for strand passage”

DNA topoisomerases inter-convert different DNA topoisomers in the cell. They catalyze the introduction or relaxation of DNA supercoils, as well as catenation and decatenation. Members of the type I topoisomerase family cleave a single strand of their double-stranded DNA substrate, whereas enzymes of the type II family cleave both DNA strands. Bacterial DNA gyrase, a type II topoisomerase, catalyzes the introduction of negative supercoils into DNA in an ATP-dependent reaction. Gyrase is not present in humans, and constitutes an attractive drug target for the treatment of bacterial and parasite infections. DNA supercoiling by gyrase is believed to occur by a strand passage mechanism, in which one segment of the double-stranded DNA substrate is passed through a (transient) break in a second segment. This mechanism requires the coordinated opening and closing of three protein interfaces, so-called gates, to ensure the directionality of strand passage toward negative supercoiling.Single molecule fluorescence resonance energy transfer experiments are ideally suited to investigate conformational changes during the catalytic cycle of DNA topoisomerases. In this review, we summarize the current knowledge on the cascade of DNA- and nucleotide-induced conformational changes in gyrase that lead to strand passage and negative supercoiling of DNA. We discuss how these conformational changes couple ATP hydrolysis to DNA supercoiling in gyrase, and how the common mechanistic principle of coordinated gate opening and closing is modulated to allow for the catalysis of different reactions by different type II topoisomerases.     

The mechanism of negative DNA supercoiling: A cascade of DNA-induced conformational changes prepares gyrase for strand passage

DNA topoisomerases inter-convert different DNA topoisomers in the cell. They catalyze the introduction or relaxation of DNA supercoils, as well as catenation and decatenation. Members of the type I topoisomerase family cleave a single strand of their double-stranded DNA substrate, whereas enzymes of the type II family cleave both DNA strands. Bacterial DNA gyrase, a type II topoisomerase, catalyzes the introduction of negative supercoils into DNA in an ATP-dependent reaction. Gyrase is not present in humans, and constitutes an attractive drug target for the treatment of bacterial and parasite infections. DNA supercoiling by gyrase is believed to occur by a strand passage mechanism, in which one segment of the double-stranded DNA substrate is passed through a (transient) break in a second segment. This mechanism requires the coordinated opening and closing of three protein interfaces, so-called gates, to ensure the directionality of strand passage toward negative supercoiling.Single molecule fluorescence resonance energy transfer experiments are ideally suited to investigate conformational changes during the catalytic cycle of DNA topoisomerases. In this review, we summarize the current knowledge on the cascade of DNA- and nucleotide-induced conformational changes in gyrase that lead to strand passage and negative supercoiling of DNA. We discuss how these conformational changes couple ATP hydrolysis to DNA supercoiling in gyrase, and how the common mechanistic principle of coordinated gate opening and closing is modulated to allow for the catalysis of different reactions by different type II topoisomerases.     

Structure of the topoisomerase VI-B subunit: implications for type II topoisomerase mechanism and evolution

Type IIA and type IIB topoisomerases each possess the ability to pass one DNA duplex through another in an ATP-dependent manner. The role of ATP in the strand passage reaction is poorly understood, particularly for the type IIB (topoisomerase VI) family. We have solved the structure of the ATP-binding subunit of topoisomerase VI (topoVI-B) in two states: an unliganded monomer and a nucleotide-bound dimer. We find that topoVI-B is highly structurally homologous to the entire 40-43 kDa ATPase region of type IIA topoisomerases and MutL proteins. Nucleotide binding to topoVI-B leads to dimerization of the protein and causes dramatic conformational changes within each protomer. Our data demonstrate that type IIA and type IIB topoisomerases have descended from a common ancestor and reveal how ATP turnover generates structural signals in the reactions of both type II topoisomerase families. When combined with the structure of the A subunit to create a picture of the intact topoisomerase VI holoenzyme, the ATP-driven motions of topoVI-B reveal a simple mechanism for strand passage by the type IIB topoisomerases.     

Strand specificity of the topoisomerase II mediated double-stranded DNA cleavage reaction

The strand specificity of topoisomerase II mediated DNA cleavage was analyzed at the nucleotide level by characterizing the enzyme's interaction with a strong DNA recognition site. This site was isolated from the promoter region of the extrachromosomal rRNA genes of Tetrahymena thermophila and was recognized by type II topoisomerases from a variety of phylogenetically diverse eukaryotic organisms, including Drosophila, Tetrahymena, and calf thymus. When incubated with this site, topoisomerase II was found to introduce single-stranded breaks (i.e., nicks) in addition to double-stranded breaks in the nucleic acid backbone. Although the nucleotide position of cleavage on both the noncoding and coding strands of the rDNA remained unchanged, the relative ratios of single- and double-stranded DNA breaks could be varied by altering reaction conditions. Under all conditions which promoted topoisomerase II mediated DNA nicking, the enzyme displayed a 3-10-fold specificity for cleavage at the noncoding strand of its recognition site. To determine whether this specificity of topoisomerase II was due to a faster forward rate of cleavage of the noncoding strand or a slower rate of its religation, a DNA religation assay was performed. Results indicated that both the noncoding and coding strands were religated by the enzyme at approximately the same rate. Therefore, the DNA strand preference of topoisomerase II appears to be embodied in the enzyme's forward cleavage reaction.     

An insight into the active site of a type I DNA topoisomerase from the kinetoplastid protozoan Leishmania donovani

DNA topoisomerases are ubiquitous enzymes that govern the topological interconversions of DNA thereby playing a key role in many aspects of nucleic acid metabolism. Recently determined crystal structures of topoisomerase fragments, representing nearly all the known subclasses, have been solved. The type IB enzymes are structurally distinct from other known topoisomerases but are similar to a class of enzymes referred to as tyrosine recombinases. A putative topoisomerase I open reading frame from the kinetoplastid Leishmania donovani was reported which shared a substantial degree of homology with type IB topoisomerases but having a variable C-terminus. Here we present a molecular model of the above parasite gene product, using the human topoisomerase I crystal structure in complex with a 22 bp oligonucleotide as a template. Our studies indicate that the overall structure of the parasite protein is similar to the human enzyme; however, major differences occur in the C-terminal loop, which harbors a serine in place of the usual catalytic tyrosine. Most other structural themes common to type IB topoisomerases, including secondary structural folds, hinged clamps that open and close to bind DNA, nucleophilic attack on the scissile DNA strand and formation of a ternary complex with the topoisomerase I inhibitor camptothecin could be visualized in our homology model. The validity of serine acting as the nucleophile in the case of the parasite protein model was corroborated with our biochemical mapping of the active site with topoisomerase I enzyme purified from L.donovani promastigotes.     

Helicase-appended Topoisomerases: New Insight into the Mechanism of Directional Strand Transfer

DNA strand passage through an enzyme-mediated gate is a key step in the catalytic cycle of topoisomerases to produce topological transformations in DNA. In most of the reactions catalyzed by topoisomerases, strand passage is not directional; thus, the enzyme simply provides a transient DNA gate through which DNA transport is allowed and thereby resolves the topological entanglement. When studied in isolation, the type IA topoisomerase family appears to conform to this rule. Interestingly, type IA enzymes can carry out directional strand transport as well. We examined here the biochemical mechanism for directional strand passage of two type IA topoisomerases: reverse gyrase and a protein complex of topoisomerase IIIα and Bloom helicase. These enzymes are able to generate vectorial strand transport independent of the supercoiling energy stored in the DNA molecule. Reverse gyrase is able to anneal single strands, thereby increasing linkage number of a DNA molecule. However, topoisomerase IIIα and Bloom helicase can dissolve DNA conjoined with a double Holliday junction, thus reducing DNA linkage. We propose here that the helicase or helicase-like component plays a determinant role in the directionality of strand transport. There is thus a common biochemical ground for the directional strand passage for the type IA topoisomerases.     

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.     

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.     

The geometry of DNA supercoils modulates topoisomerase-mediated DNA cleavage and enzyme response to anticancer drugs

Collisions with DNA tracking systems are critical for the conversion of transient topoisomerase-DNA cleavage complexes to permanent strand breaks. Since DNA is overwound ahead of tracking systems, cleavage complexes most likely to produce permanent strand breaks should be formed between topoisomerases and positively supercoiled molecules. Therefore, the ability of human topoisomerase IIalpha and IIbeta and topoisomerase I to cleave positively supercoiled DNA was assessed in the absence or presence of anticancer drugs. Topoisomerase IIalpha and IIbeta maintained approximately 4-fold lower levels of cleavage complexes with positively rather than negatively supercoiled DNA. Topoisomerase IIalpha also displayed lower levels of cleavage with overwound substrates in the presence of nonintercalative drugs. Decreased drug efficacy was due primarily to a drop in baseline (i.e., nondrug) cleavage, rather than an altered interaction with the enzyme-DNA complex. Similar results were seen for topoisomerase IIbeta, but the effects of DNA geometry on drug-induced scission were somewhat less pronounced. With both topoisomerase IIalpha and IIbeta, intercalative drugs displayed greater relative cleavage enhancement with positively supercoiled DNA. This appeared to result from negative effects of high concentrations of intercalative agents on underwound DNA. In contrast to the type II enzymes, topoisomerase I maintained approximately 3-fold higher levels of cleavage complexes with positively supercoiled substrates and displayed an even more dramatic increase in the presence of camptothecin. These findings suggest that the geometry of DNA supercoils has a profound influence on topoisomerase-mediated DNA scission and that topoisomerase I may be an intrinsically more lethal target for anticancer drugs than either topoisomerase IIalpha or IIbeta.     

DNA topoisomerase activities in Chinese hamster radiosensitive mutants after X-ray treatment

In the last years the attractive hypothesis of a possible involvement of mammalian topoisomerases in DNA repair has been proposed, given their molecular mechanism of action. So far, using asynchronous cultures a lot of controversial results have been reported, without taking into account the frequently dramatic fluctuations of topoisomerase activities depending upon the cell cycle stage and proliferation rate (mainly for topoisomerase II). We have addressed this question making use of G1 synchronous cultures of the Chinese hamster radiosensitive mutants xrs 5 (defective in DNA double strand breaks rejoining) and irs 2 (which shows radioresistant DNA synthesis), as well as their parental lines CHO K1 and V79 respectively, which show a normal radiosensitivity. Cells were irradiated with 5 Gy of X-rays and the activities of topoisomerases I and II in nuclear extracts were studied for comparison with non-irradiated controls in both the mutants and parental cell lines. Our results clearly show a modulation of the topoisomerase activities after irradiation, that varies depending upon the mutation that the different lines bear. While this hypothesis needs further testing, an interesting idea is that DNA topoisomerases might be involved in the cellular response to radiation damage, either through a direct participation in the repair mechanisms or in a preparative step to allow repair to proceed.     

Iridoids as DNA topoisomerase I poisons

The discovery of new topoisomerase I inhibitors is necessary since most of the antitumor drugs are targeted against type II and only a very few can specifically affect type I. Topoisomerase poisons generate toxic DNA damage by stabilization of the covalent DNA-topoisomerase cleavage complex and some have therapeutic efficacy in human cancer. Two iridoids, aucubin and geniposide, have shown antitumoral activities, but their activity against topoisomerase enzymes has not been tested. Here it was found that both compounds are able to stabilize covalent attachments of the topoisomerase I subunits to DNA at sites of DNA strand breaks, generating cleavage complexes intermediates so being active as poisons of topoisomerase I, but not topoisomerase II. This result points to DNA damage induced by topoisomerase I poisoning as one of the possible mechanisms by which these two iridoids have shown antitumoral activity, increasing interest in their possible use in cancer chemoprevention and therapy.     

Iridoids as DNA topoisomerase I poisons

The discovery of new topoisomerase I inhibitors is necessary since most of the antitumor drugs are targeted against type II and only a very few can specifically affect type I. Topoisomerase poisons generate toxic DNA damage by stabilization of the covalent DNA-topoisomerase cleavage complex and some have therapeutic efficacy in human cancer. Two iridoids, aucubin and geniposide, have shown antitumoral activities, but their activity against topoisomerase enzymes has not been tested. Here it was found that both compounds are able to stabilize covalent attachments of the topoisomerase I subunits to DNA at sites of DNA strand breaks, generating cleavage complexes intermediates so being active as poisons of topoisomerase I, but not topoisomerase II. This result points to DNA damage induced by topoisomerase I poisoning as one of the possible mechanisms by which these two iridoids have shown antitumoral activity, increasing interest in their possible use in cancer chemoprevention and therapy.     

Conformational changes in E. coli DNA topoisomerase I.

DNA topoisomerases are the enzymes responsible for maintaining the topological states of DNA. In order to change the topology of DNA, topoisomerases pass one or two DNA strands through transient single or double strand breaks in the DNA phosphodiester backbone. It has been proposed that both type IA and type II enzymes change conformation dramatically during the reaction cycle in order to accomplish these transformations. In the case of Escherichia coli DNA topoisomerase I, it has been suggested that a 30 kDa fragment moves away from the rest of the protein to create an entrance into the central hole in the protein. Structures of the 30 kDa fragment reveal that indeed this fragment can change conformation significantly. The fragment is composed of two domains, and while the domains themselves remain largely unchanged, their relative arrangement can change dramatically.