Putative identification of functional interactions between DNA intercalating agents and topoisomerase II using the V79 in vitro micronucleus assay

Clastogenicity is frequently observed following treatment of mammalian cells with new chemical entities. This clastogenicity, unless proven otherwise, is assumed to result from the imperfect repair of DNA lesions produced from covalent chemical/DNA interaction. However, clastogenicity can also arise via other mechanisms such as non-covalent chemical intercalation into DNA resulting in poisoning of cellular DNA topoisomerase II (topo II) and stabilization of DNA double strand breaks. We have recently reported modifications to the V79 in vitro micronucleus assay which allow an indirect evaluation of both the intercalative and topoisomerase-interactive activities of chemical agents. In the present studies we have used these modified assays to further assess the validity of this approach in an evaluation of a number of intercalating and non-intercalating polycyclic compounds. It is shown that intercalating agents may be catalytic topo II inhibitors (e.g. chloroquine (CHL), tacrine (TAC), 9-aminoacridine (9AA), ethidium bromide (EB)) or topo II poisons (e.g. proflavine (PROF), auramine O (AUR) and curcumin (CURC)). Still other intercalators are shown to lack detectable topo II-interactions, (e.g. imipramine (IMP), quinacrine (QUIN), 2-aminoanthracene (AA), iminostilbene (IMN) and promethazine (PHE)). It is concluded that (1) the clastogenicity of three agents, PROF (a typical DNA intercalating agent), and AUR and CURC (both structurally atypical intercalating agents, with unknown clastogenic mechanisms), may be due to topo II poisoning; (2) other intercalating agents may either act as catalytic topo II inhibitors or exhibit no functional topo II interaction; (3) The use of these cell-based approaches may provide a logical first step in determining if unexpected clastogenicity associated with test article exposure is due to a topo II interaction.     

靶向共价键药物的研究进展

药物与靶标的结合是启动药理作用的本源,共价键药物是以共享电子的方式来实现与靶标的结合,其中大多为抗感染、抗肿瘤以及心脑血管、神经系统和代谢类药物。简介共价键药物与非共价键药物的区别以及既往的重磅级共价键药物与靶标的结合特点,分类综述靶向共价键药物的理性设计及与靶标的结合反应。     

An ecofriendly synthesis and DNA binding interaction study of some pyrazolo [1,5-a]pyrimidines derivatives

The DNA molecule is a target for plethora of anticancer and antiviral drugs that forms covalent and non-covalent adducts with major or minor groove of DNA. In present study we synthesized series of novel Pyrazolo [1,5-a]pyrimidine derivatives. The newly synthesized compounds were characterized by elemental analysis, IR, ¹H NMR, and mass spectral data. The selected compounds were studied for interaction with Calf thymus DNA (CT-DNA) using electronic spectra, viscosity measurement and thermal denaturation studies. Further, molecular interactions were revealed for compound IIIa and IVa by computational methodologies. The preferred mode of ligand binding with double helical DNA as well as preferable DNA groove were explored by molecular docking in different DNA models.     

Genotoxicity profiles of common alkyl halides and esters with alkylating activity

Drug synthesis and/or formulation can generate genotoxic impurities. For instance, strong acid/alcohol interactions during the process of drug salt formation produce alkylating agents such as alkyl halides and alkyl esters of alkyl sulfonic acids. The genotoxicity of a few classic alkylating agents such as methyl and ethyl methanesulfonate have been previously well characterized, whereas the majority of compounds from this class have only been tested in the Salmonella reversion assay. Therefore, the goal of this study was to investigate clastogenicity and DEL recombination profiles of 22 halogenated alkanes and alkylesters of sulfuric and alkane-, aryl-sulfonic acids using a battery of cellular and molecular assays. The in-vitro micronucleus assay in CHO cells was used to measure clastogenicity and the deletion recombination (DEL) assay in S. cerevisiae provided a measure of DNA deletions. We also examined the compounds' reactivity towards 4-(p-nitrobenzyl)pyridine (NBP), a surrogate molecule for biological ring nitrogens. Methylating agents were most potent in all three assays and the alkyl chlorides evaluated in our study were negative in all three assays. Also, a strong correlation was found between the MN, DEL and NBP assays. In summary, this study contributes to a better understanding of the genotoxic properties of common alkyl halides and alkyl esters with alkylating activity and might provide guidance for managing risk of genotoxic process-related impurities of drug substances and products.     

Binding mode of chemically activated semiquinone free radicals from quinone anticancer agents to DNA

Chemical reduction of the highly active quinone-containing antitumor drugs, adriamycin and daunorubicin formed the same partially reduced free radical previously reported [9] by microsomal activation. In vitro incubation of the chemically activated free radical intermediates with DNA resulted in covalent binding of these drugs to DNA. The adriamycin semiquinone radical has a greater affinity for DNA and covalent complexes up to one adriamycin per 12 nucleotides were obtained. The daunorubicin semiquinone radical, on the other hand, showed a lesser binding affinity and gave rise to complexes in which one drug molecule was covalently bound per 135 nucleotides. The stronger covalent binding of adriamycin to DNA may account for more severe DNA damage induced by this drug.     

Comparative reactivity analysis of small-molecule thiol surrogates

Targeted covalent inhibitors represent an increasingly popular approach to modulate challenging drug targets. Since covalent and non-covalent interactions are both contributing to the affinity of these compounds, evaluation of their reactivity is a key-step to find feasible warheads. There are well-established HPLC- and NMR-based kinetic assays to tackle this task, however, they use a variety of cysteine-surrogates including cysteamine, cysteine or acetyl-cysteine and GSH. The diverse nature of the thiol sources often makes the results incomparable that prevents compiling a comprehensive knowledge base for the design of covalent inhibitors. To evaluate kinetic measurements from different sources we performed a comparative analysis of the different thiol surrogates against a designed set of electrophilic fragments equipped with a range of warheads. Our study included seven different thiol models and 13 warheads resulting in a reactivity matrix analysed thoroughly. We found that the reactivity profile might be significantly different for various thiol models. Comparing the different warheads, we concluded that – in addition to its human relevance - glutathione (GSH) provided the best estimate of reactivity with highest number of true positives identified.     

Calf thymus DNA binding/bonding properties of CC-1065 and analogs as related to their biological activities and toxicities.

CC-1065 is a potent natural antitumor antibiotic that binds non-covalently and covalently (N-3 adenine adduct) in the minor groove of B-form DNA. Synthetic analogs of CC-1065 do not exhibit the delayed death toxicity of CC-1065 and are efficacious anticancer agents, some of them curative in murine tumor models. In an attempt to understand the different biological properties of CC-1065 and analogs, we have determined the following quantities for CC-1065, enantiomeric CC-1065, and three biologically active analogs and their enantiomers: the calf thymus DNA (CT-DNA) induced molar ellipticity of the adduct (or how rigidly the adduct is held in the right-hand conformation of the minor groove); the stability of the adduct with respect to long incubation times and to digestion by snake venom phosphodiesterase I (SVPD); the stabilizing effect on the CT-DNA helix of the covalently and non-covalently bound species with respect to thermal melting; and the CT-DNA binding/bonding (non-covalent/covalent) profiles at a low molar ratio of nucleotide to drug. The major observations from these studies are as follows: (i) molecules which show large DNA interaction parameters, stable adducts, and significant non-covalent binding exhibit delayed death toxicity; (ii) molecules which show intermediate DNA interaction parameters and stable adducts, but do not show significant non-covalent binding, do not exhibit delayed death toxicity and are biologically active; (iii) molecules which show small DNA interaction parameters and unstable DNA adducts are biologically inactive. The results suggest that a window exists in the affinity for the minor groove of DNA wherein an analog may possess the correct balance of toxicity and activity to make a useful anticancer agent. Outside of this window, the analog causes delayed deaths or has no significant biological activity.     

Covalent and non-covalent interactions of betaig-h3 with collagen VI. Beta ig-h3 is covalently attached to the amino-terminal region of collagen VI in tissue microfibrils

Transforming growth factor-beta induced gene-h3 (betaig-h3) was found to co-purify with collagen VI microfibrils, extracted from developing fetal ligament, after equilibrium density gradient centrifugation under both nondenaturing and denaturing conditions. Analysis of the collagen VI fraction from the non-denaturing gradient by gel electrophoresis under non-reducing conditions revealed the present of a single high molecular weight band that immunostained for both collagen VI and betaig-h3. When the fraction was analyzed under reducing conditions, collagen VI alpha chains and betaig-h3 were the only species evident. The results indicated that betaig-h3 is associated with collagen VI in tissues by reducible covalent bonding, presumably disulfide bridges. Rotary shadowing and immunogold staining of the collagen VI microfibrils and isolated tetramers indicated that betaig-h3 was specifically and periodically associated with the double-beaded region of many of the microfibrils and that this covalent binding site was located in or near the amino-terminal globular domain of the collagen VI molecule. Using solid phase and co-immunoprecipitation assays, recombinant betaig-h3 was found to bind both native and pepsin-treated collagen VI but not individual pepsin-collagen VI alpha chains. Blocking experiments indicated that the major in vitro betaig-h3 binding site was located in the pepsin-resistant region of collagen VI. In contrast to the tissue situation, the in vitro interaction had the characteristics of a reversible non-covalent interaction, and the Kd was measured as 1.63 x 10(-8) m. Rotary shadowing of immunogold-labeled complexes of recombinant betaig-h3 and pepsin-collagen VI indicated that the in vitro betaig-h3 binding site was located close to the amino-terminal end of the collagen VI triple helix. The evidence indicates that collagen VI may contain distinct covalent and non-covalent binding sites for betaig-h3, although the possibility that both interactions use the same binding region is discussed. Overall the study supports the concept that betaig-h3 is extensively associated with collagen VI in some tissues and that it plays an important modulating role in collagen VI microfibril function.     

DNA conformational changes and cleavage by ruthenium(II) nitrofurylsemicarbazone complexes

Metal complexes that establish interactions with DNA are being studied not only because of their potential use as therapeutic agents but also as tools for biochemistry and molecular biology. Searching for drugs with anti-trypanosome activity, we previously synthesized a series of ruthenium mixed ligand dimethyl sulfoxide complexes of the type [Ru(II)Cl(2)(DMSO)(2)L], where L is 5-nitrofurylsemicarbazone derivatives and DMSO is dimethyl sulfoxide. Though they present the ability to bind DNA, no activity against parasites in cell culture was observed. Considering their potential application as molecular tools we further analyzed the interactions with DNA through an electrophoretic approach. Non covalent withdrawal of superhelicity and a rapid nicking activity upon covalent interaction was observed. Inhibition of both effects was observed in the presence of distamycin suggesting the involvement of the DNA minor groove in the interaction with the nitrofurylsemicarbazone ruthenium complexes. In addition cleavage inhibition by dimethyl sulfoxide suggests an oxidative mechanism of action.     

The importance of intercalation in the covalent binding of benzo(a)pyrene diol epoxide to DNA

The primary mode of non-covalent interaction of the strong carcinogen, benzo(a)pyrene diol epoxide, with DNA is through intercalation. It has variously been suggested that intercalative complexes may be prerequisite for either covalent binding or DNA-catalysed hydrolysis of the epoxide or both. Geacintov [Geacintov, N. E. (1986). Carcinogenesis 7, 589.] has recently argued that intercalation is important in covalent binding and presented theoretical constructs consistent with this proposal. A more general theoretical model is presented here which includes the possibilities that either catalysis of hydrolysis or covalent binding of benzo(a)pyrene diol epoxide DNA can occur (a) in an intercalation complex, or (b) without formation of a detectable, physically bound complex. It is shown that a variety of possible mechanisms formulated under this general theory lead to equations for overall reaction rates and covalent binding fractions which are all of the same form with respect to DNA concentration dependence. A consequence of this is that experimental studies of the dependence of hydrolysis rates and covalent binding fractions on DNA concentration do not distinguish between the various possible mechanisms. These findings are discussed in relation to the interactions of benzo(a)pyrene diol epoxide with chromatin in cells.     

A Network Inference Method for Large-Scale Unsupervised Identification of Novel Drug-Drug Interactions

Characterizing interactions between drugs is important to avoid potentially harmful combinations, to reduce off-target effects of treatments and to fight antibiotic resistant pathogens, among others. Here we present a network inference algorithm to predict uncharacterized drug-drug interactions. Our algorithm takes, as its only input, sets of previously reported interactions, and does not require any pharmacological or biochemical information about the drugs, their targets or their mechanisms of action. Because the models we use are abstract, our approach can deal with adverse interactions, synergistic/antagonistic/suppressing interactions, or any other type of drug interaction. We show that our method is able to accurately predict interactions, both in exhaustive pairwise interaction data between small sets of drugs, and in large-scale databases. We also demonstrate that our algorithm can be used efficiently to discover interactions of new drugs as part of the drug discovery process.     

Small ubiquitin-related modifier (SUMO) binding determines substrate recognition and paralog-selective SUMO modification

Small ubiquitin-related modifiers (SUMOs) regulate diverse cellular processes through their covalent attachment to target proteins. Vertebrates express three SUMO paralogs: SUMO-1, SUMO-2, and SUMO-3 (SUMO-2 and SUMO-3 are approximately 96% identical and referred to as SUMO-2/3). SUMO-1 and SUMO-2/3 are conjugated, at least in part, to unique subsets of proteins and thus regulate distinct cellular pathways. However, how different proteins are selectively modified by SUMO-1 and SUMO-2/3 is unknown. We demonstrate that BLM, the RecQ DNA helicase mutated in Bloom syndrome, is preferentially modified by SUMO-2/3 both in vitro and in vivo. Our findings indicate that non-covalent interactions between SUMO and BLM are required for modification at non-consensus sites and that preferential SUMO-2/3 modification is determined by preferential SUMO-2/3 binding. We also present evidence that sumoylation of a C-terminal fragment of HIPK2 is dependent on SUMO binding, indicating that non-covalent interactions between SUMO and target proteins provide a general mechanism for SUMO substrate selection and possible paralog-selective modification.     

Alterations in linker flexibility suppress DNA topoisomerase I mutant-induced cell lethality

Eukaryotic DNA topoisomerase I (Top1p) catalyzes changes in DNA topology via the formation of a covalent enzyme-DNA intermediate, which is reversibly stabilized by the anticancer agent camptothecin (CPT). Crystallographic studies of the 70-kDa C terminus of human Top1p bound to duplex DNA describe a monomeric protein clamp circumscribing the DNA helix. The structures, which lack the N-terminal domain, comprise the conserved clamp, an extended linker domain, and the conserved C-terminal active site Tyr domain. CPT bound to the covalent Top1p-DNA complex limits linker flexibility, allowing structural determination of this domain. We previously reported that mutation of Ala(653) to Pro in the linker increases the rate of enzyme-catalyzed DNA religation, thereby rendering Top1A653Pp resistant to CPT (Fiorani, P., Bruselles, A., Falconi, M., Chillemi, G., Desideri, A., and Benedetti P. (2003) J. Biol. Chem. 278, 43268-43275). Molecular dynamics studies suggested mutation-induced increases in linker flexibility alter Top1p catalyzed DNA religation. To address the functional consequences of linker flexibility on enzyme catalysis and drug sensitivity, we investigated the interactions of the A653P linker mutation with a self-poisoning T718A mutation within the active site of Top1p. The A653P mutation suppressed the lethal phenotype of Top1T718Ap in yeast, yet did not restore enzyme sensitivity to CPT. However, the specific activity of the double mutant was decreased in vivo and in vitro, consistent with a decrease in DNA binding. These findings support a model where changes in the flexibility or orientation of the linker alter the geometry of the active site and thereby the kinetics of DNA cleavage/religation catalyzed by Top1p.     

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.     

Mutation Induced Conformational Changes in Genomic DNA from Cancerous K562 Cells Influence Drug-DNA Binding Modes

Normal human genomic DNA (N-DNA) and mutated DNA (M-DNA) from K562 leukemic cells show different thermodynamic properties and binding affinities on interaction with anticancer drugs; adriamycin (ADR) and daunomycin (DNM). Isothermal calorimetric thermograms representing titration of ADR/DNM with N-DNA and M-DNA on analysis best fitted with sequential model of four and three events respectively. From Raman spectroscopy it has been identified that M-DNA is partially transformed to A form owing to mutations and N-DNA on binding of drugs too undergoes transition to A form of DNA. A correlation of thermodynamic contribution and structural data reveal the presence of different binding events in drug and DNA interactions. These events are assumed to be representative of minor groove complexation, reorientation of the drug in the complex, DNA deformation to accommodate the drugs and finally intercalation. Dynamic light scattering and zeta potential data also support differences in structure and mode of binding of N and M DNA. This study highlights that mutations can manifest structural changes in DNA, which may influence the binding efficacy of the drugs. New generation of drugs can be designed which recognize the difference in DNA structure in the cancerous cells instead of their biochemical manifestation.     

Base specific interaction of reductively activated nitroimidazoles with DNA

To exert biological activity, nitroimidazole drugs require reductive activation in vivo. Nucleic acids are susceptible to the activated drug in vitro and are presumably the major target in vivo. We carried out electrolytical reduction of several 5-nitroimidazoles at a controlled potential either in the presence or prior to the addition of DNA. Using a nucleotide sequence specific test to analyse cleavage products, specific interaction of the reduced nitroimidazole intermediate(s) towards the guanine residues is prominent. Since the strand scission depends on subsequent piperidine treatment, it can be concluded that the primary interaction between the activated drug and guanine is a covalent modification weakening the glycosidic bond.     

Cisplatin resistance and mechanism in a viral test system: SV40 isolates that resist inhibition by the antitumor drug have lost regulatory DNA

Isolates of SV40 that have enhanced ability to survive inhibition by the antitumor drug cisplatin were selected by serial drug challenge in vivo. These mutant viruses have acquired specific deletions within the repeated regulatory motif (GGGCGG)6 or GC box. This DNA element was shown previously to be a strong target of drug attack by cisplatin and other anticancer drugs in vitro and is an important viral and cellular DNA control sequence. Thus, drug resistance in this viral test system is dependent on the loss of important target DNA sequences. The results also indicate that drug efficacy may be related to the ability of certain anticancer drugs to attack regulatory DNA sequences containing strings of guanosines.     

Regulation of catalysis by the smallpox virus topoisomerase

The poxvirus type IB topoisomerases catalyze relaxation of supercoiled DNA by cleaving and rejoining DNA strands via a pathway involving a covalent phosphotyrosine intermediate. Recently we determined structures of the smallpox virus topoisomerase bound to DNA in covalent and non-covalent DNA complexes using x-ray crystallography. Here we analyzed the effects of twenty-two amino acid substitutions on the topoisomerase activity in vitro in assays of DNA relaxation, single cycle cleavage, and equilibrium cleavage-religation. Alanine substitutions at 14 positions impaired topoisomerase function, marking a channel of functionally important contacts along the protein-DNA interface. Unexpectedly, alanine substitutions at two positions (D168A and E124A) accelerated the forward rate of cleavage. These findings and further analysis indicate that Asp(168) is a key regulator of the active site that maintains an optimal balance among the DNA cleavage, religation, and product release steps. Finally, we report that high level expression of the D168A topoisomerase in Escherichia coli, but not other alanine-substituted enzymes, prevented cell growth. These findings help elucidate the amino acid side chains involved in DNA binding and catalysis and provide guidance for designing topoisomerase poisons for use as smallpox antivirals.     

DNA contacts stimulate catalysis by a poxvirus topoisomerase

Eukaryotic type 1B topoisomerases act by forming covalent enzyme-DNA intermediates that transiently nick DNA and thereby release DNA supercoils. Here we present a study of the topoisomerase encoded by the pathogenic poxvirus molluscum contagiosum. Our studies of DNA sites favored for catalysis reveal a larger recognition site than the 5'-(T/C)CCTT-3' sequence previously identified for poxvirus topoisomerases. Separate assays of initial DNA binding and covalent complex formation revealed that different DNA sequences were important for each reaction step. The location of the protein-DNA contacts was mapped by analyzing mutant sites and inosine-substituted DNAs. Some of the bases flanking the 5'-(T/C)CCTT-3' sequence were selectively important for covalent complex formation but not initial DNA binding. Interactions important for catalysis were probed with 5'-bridging phosphorothiolates at the site of strand cleavage, which permitted covalent complex formation but prevented subsequent religation. Kinetic studies revealed that the flanking sequences that promoted recovery of covalent complexes increased initial cleavage instead of inhibiting resealing of the nicked intermediate. These data 1) indicate that previously unidentified DNA contacts can accelerate a step between initial binding and covalent complex formation and 2) help specify models for conformational changes promoting catalysis.