DNA minor groove binding agents interfere with topoisomerase II mediated lesions induced by epipodophyllotoxin derivative VM-26 and acridine derivative m-AMSA in nuclei from L1210 cells

This study demonstrated that agents capable of interacting with the minor groove in nuclear DNA interfere with topoisomerase II mediated effects of antitumor drugs such as VM-26 and m-AMSA. Distamycin, Hoechst 33258, and DAPI were used as agents capable of AT-specific binding in the minor groove of DNA while producing no profound long-range distortion of DNA structure. In intact nuclei from L1210 cells, these minor groove binders inhibited the induction of topoisomerase II mediated DNA damage (DNA-protein cross-links and DNA double-strand breaks) by VM-26 and m-AMSA. The inhibitory effects of distamycin reflected prevention of formation of new lesions but not reversal of preexisting damage. The minor groove binders did not differentiate between lesions induced by an intercalator, m-AMSA, or by a DNA-nonbinding drug, VM-26. All three groove binders inhibited DNA breaks more strongly than DNA-protein cross-links. The inhibitory potency correlated with the size of minor groove binders and the size of their DNA-binding sites: distamycin (5 bp) greater than Hoechst 33258 (4 bp) greater than DAPI (3 bp). The results showed that DNA minor groove binders are a new type of modulators of the action of topoisomerase II targeted drugs.     

DNA binding properties of minor groove binders and their influence on the topoisomerase II cleavage reaction

We present titrations of the human δβ-globin gene region with DNA minor groove binders netropsin, bisnetropsin, distamycin, chromomycin and four bis-quaternary ammonium compounds in the presence of calf thymus topoisomerase II and DNase I. With increasing ligand concentration, stimulation and inhibition of enzyme activity were detected and quantitatively evaluated. Additionally we show a second type of stimulation, the appearance of strong new topoisomerase II cleavage sites at high ligand concentrations. The specific binding sites of the minor groove binders of the DNA sequence and their microscopic binding constants were determined from DNase I footprints. A binding mechanism for minor groove binders is proposed in order to explain these results especially when ligand concentration is increased. © 1998 John Wiley & Sons, Ltd.     

Modelling topoisomerase I inhibition by minor groove binders

Topoisomerase inhibition is an extremely useful target for anticancer and antimicrobial drugs, and an undesirable side effect of some drugs targeting other proteins. Published modelling studies are sparse, and have used small data sets with relatively low molecular diversity. Given the important role of minor groove binding in the mechanism of topoisomerase I inhibition, we have conducted the first 3D QSAR study of topoisomerase I inhibition of a large, diverse set of minor groove binders using the minor groove binding conformation as the alignment template. The highly significant QSAR models resulting from this alignment identify the roles played by molecular features, most importantly the hydrogen bond donor properties.     

Netropsin and bis-netropsin analogs as inhibitors of the catalytic activity of mammalian DNA topoisomerase II and topoisomerase cleavable complexes.

This study examined the ability of netropsin and related minor groove binders to interfere with the actions of DNA topoisomerases II and I. We evaluated a series of netropsin dimers linked with flexible aliphatic chains of different lengths. These agents are potentially able to occupy longer stretches of DNA than the parental drug as a result of bidentate binding. Both netropsin and its dimers were found: (i) to inhibit the catalytic activity of isolated topoisomerase II and (ii) to interfere with the stabilization of the cleavable complexes of topoisomerase II and I in nuclei. Dimers with linkers consisting of 0-4 and 6-9 methylene groups (n) were far more inhibitory than netropsin against isolated enzyme and in the nuclear system. The compound with n = 5 was less active than netropsin in both assays while the dimer with n = 10 inhibited only the isolated enzyme. The comparison of dimers with fixed linker length (n = 2) but varying number of N-methylpyrrole residues (from 1 to 3) revealed that the inhibitory properties were enhanced with increasing number of N-methylpyrrole units. For dimers with varying linker length, drug ability to inhibit catalytic activity of isolated topoisomerase II was positively correlated with calf thymus DNA association constants. In contrast, no such correlation existed in nuclei. However, the inhibitory effects in the nuclear system were correlated with the association constants for poly(dAdT). The results indicate that bidentate binding can significantly enhance anti-topoisomerase activity of netropsin related dimeric minor groove binders. However, other factors such as the length of the linker, the number of pyrrole moieties and the nature of the target (isolated enzyme/DNA versus chromatin in nuclei) also contribute to these activities.     

Towards more specific O6-methylguanine-DNA methyltransferase (MGMT) inactivators

Searching for a novel family of inactivators of the human DNA repair protein O(6)-methylguanine-DNA methyltransferase (MGMT) which is known to bind to the DNA minor groove, we have computationally modelled and synthesised two series of 2-amino-6-aryloxy-5-nitropyrimidines with morpholino or aminodiaryl substituents (potential minor groove binders) at the 4-position. Synthesis of these compounds was achieved by successive substitution of each of the two Cl atoms of 2-amino-4,6-dichloro-5-nitropyrimidine by the corresponding amino and aryloxy derivatives. Biochemical evaluation of these compounds as MGMT inactivators showed poor activities, but in general the 4-bromothenyloxy derivatives showed better inactivation than the benzyloxy versions. DNA binding assessment was not possible due to insolubility problems.     

Potent inhibition of werner and bloom helicases by DNA minor groove binding drugs

Maintenance of genomic integrity is vital to all organisms. A number of human genetic disorders, including Werner Syndrome, Bloom Syndrome and Rothmund–Thomson Syndrome, exhibit genomic instability with some phenotypic characteristics of premature aging and cancer predisposition. Presumably the aberrant cellular and clinical phenotypes in these disorders arise from defects in important DNA metabolic pathways such as replication, recombination or repair. These syndromes are all characterized by defects in a member of the RecQ family of DNA helicases. To obtain a better understanding of how these enzymes function in DNA metabolic pathways that directly influence chromosomal integrity, we have examined the effects of non-covalent DNA modifications on the catalytic activities of purified Werner (WRN) and Bloom (BLM) DNA helicases. A panel of DNA-binding ligands displaying unique properties for interacting with double helical DNA was tested for their effects on the unwinding activity of WRN and BLM helicases on a partial duplex DNA substrate. The levels of inhibition by a number of these compounds were distinct from previously reported values for viral, prokaryotic and eukaryotic helicases. The results demonstrate that BLM and WRN proteins exhibit similar sensitivity profiles to these DNA-binding ligands and are most potently inhibited by the structurally related minor groove binders distamycin A and netropsin (K_i ≤1 µM). The distinct inhibition of WRN and BLM helicases by the minor groove binders suggest that these helicases unwind double-stranded DNA by a related mechanism.     

Minor groove deformability of DNA: a molecular dynamics free energy simulation study

The conformational deformability of nucleic acids can influence their function and recognition by proteins. A class of DNA binding proteins including the TATA box binding protein binds to the DNA minor groove, resulting in an opening of the minor groove and DNA bending toward the major groove. Explicit solvent molecular dynamics simulations in combination with the umbrella sampling approach have been performed to investigate the molecular mechanism of DNA minor groove deformations and the indirect energetic contribution to protein binding. As a reaction coordinate, the distance between backbone segments on opposite strands was used. The resulting deformed structures showed close agreement with experimental DNA structures in complex with minor groove-binding proteins. The calculated free energy of minor groove deformation was approximately 4-6 kcal mol(-1) in the case of a central TATATA sequence. A smaller equilibrium minor groove width and more restricted minor groove mobility was found for the central AAATTT and also a significantly ( approximately 2 times) larger free energy change for opening the minor groove. The helical parameter analysis of trajectories indicates that an easier partial unstacking of a central TA versus AT basepair step is a likely reason for the larger groove flexibility of the central TATATA case.     

Design,synthesis and biological evaluation of a novel series of anthrapyrazoles linked with netropsin-like oligopyrrole carboxamides as anticancer agents

Anticancer drugs that bind to DNA and inhibit DNA-processing enzymes represent an important class of anticancer drugs. Combilexin molecules, which combine DNA minor groove binding and intercalating functionalities, have the potential for increased DNA binding affinity and increased selectivity due to their dual mode of DNA binding. This study describes the synthesis of DNA minor groove binder netropsin analogs containing either one or two N-methylpyrrole carboxamide groups linked to DNA-intercalating anthrapyrazoles. Those hybrid molecules which had both two N-methylpyrrole groups and terminal (dimethylamino)alkyl side chains displayed submicromolar cytotoxicity towards K562 human leukemia cells. The combilexins were also evaluated for DNA binding by measuring the increase in DNA melting temperature, for DNA topoisomerase IIα-mediated double strand cleavage of DNA, for inhibition of DNA topoisomerase IIα decatenation activity, and for inhibition of DNA topoisomerase I relaxation of DNA. Several of the compounds stabilized the DNA–topoisomerase IIα covalent complex indicating that they acted as topoisomerase IIα poisons. Some of the combilexins had higher affinity for DNA than their parent anthrapyrazoles. In conclusion, a novel group of compounds combining DNA intercalating anthrapyrazole groups and minor groove binding netropsin analogs have been designed, synthesized and biologically evaluated as possible novel anticancer agents.     

Insights into substrate binding and catalytic mechanism of human tyrosyl-DNA phosphodiesterase (Tdp1) from vanadate and tungstate-inhibited structures

Tyrosyl-DNA phosphodiesterase (Tdp1) is a DNA repair enzyme that catalyzes the hydrolysis of a phosphodiester bond between a tyrosine residue and a DNA 3'-phosphate. The only known example of such a linkage in eukaryotic cells occurs normally as a transient link between a type IB topoisomerase and DNA. Thus human Tdp1 is thought to be responsible for repairing lesions that occur when topoisomerase I becomes stalled on the DNA in the cell. Tdp1 has also been shown to remove glycolate from single-stranded DNA containing a 3'-phosphoglycolate, suggesting a role for Tdp1 in repair of free-radical mediated DNA double-strand breaks. We report the three-dimensional structures of human Tdp1 bound to the phosphate transition state analogs vanadate and tungstate. Each structure shows the inhibitor covalently bound to His263, confirming that this residue is the nucleophile in the first step of the catalytic reaction. Vanadate in the Tdp1-vanadate structure has a trigonal bipyramidal geometry that mimics the transition state for hydrolysis of a phosphodiester bond, while Tdp1-tungstate displays unusual octahedral coordination. The presence of low-occupancy tungstate molecules along the narrow groove of the substrate binding cleft is suggestive evidence that this groove binds ssDNA. In both cases, glycerol from the cryoprotectant solution became liganded to the vanadate or tungstate inhibitor molecules in a bidentate 1,2-diol fashion. These structural models allow predictions to be made regarding the specific binding mode of the substrate and the mechanism of catalysis.     

Comparison of effects of fostriecin, novobiocin, and camptothecin, inhibitors of DNA topoisomerases, on DNA replication and repair in human cells.

Fostriecin causes a delayed inhibition of replicative DNA synthesis in human cells, consistent with a role for DNA topoisomerase II (its target enzyme) at a late stage in replication. Fostriecin does not inhibit UV-induced excision repair. The less specific inhibitor novobiocin blocks repair in permeabilised cells given a low dose of UV, presumably through a mechanism other than the inhibition of topoisomerase II. Its effect cannot be accounted for by a depletion of the ATP required for incision. Camptothecin, an inhibitor of DNA topoisomerase I, blocks replicative DNA synthesis immediately but incompletely, suggesting a participation of topoisomerase I at the replication fork, but it, too, has no influence on DNA repair. We thus find no evidence for involvement of either topoisomerase I or II in the response of cells to UV damage.     

Benzo[a]pyrene-dG adduct interference illuminates the interface of vaccinia topoisomerase with the DNA minor groove

Vaccinia DNA topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a pentapyrimidine target site 5'-C(+5)C(+4)C(+3)T(+2)T(+1)p downward arrow in duplex DNA. The enzyme engages the target site within a C-shaped protein clamp. Here we mapped the interface of topoisomerase with the DNA minor groove by introducing chiral C-10 R and S 7,8-diol 9,10-epoxide adducts of benzo[a]pyrene (BP) at single N(2)-deoxyguanosine (dG) positions within the nonscissile DNA strand. These trans opened BPdG adducts fit into the minor groove without perturbing helix conformation or base pairing, and the R and S diastereomers are oriented in opposite directions within the minor groove. We measured the effects of the BPdG adducts on the rate and extent of single-turnover DNA transesterification. We observed a sharp margin of interference effects, whereby +5 and -2 BPdG modifications were well tolerated but +4, +3, and -1 BPdG adducts were severely deleterious. Stereoselective effects at the -1 nucleoside (the R isomer interfered, whereas the S isomer did not) delineated at high resolution the downstream border of the minor groove interface. BPdG inhibition of transesterification is likely caused by steric exclusion of constituents of the topoisomerase from the minor groove. We also applied the BPdG interference method to probe the interactions of exonuclease III with the minor groove. DNAs containing these BPdG adducts were protected from digestion by exonuclease III, which was consistently arrested at positions 2-4 nucleotides prior to the BP-modified guanosine.     

Evidence for participation of a multiprotein complex in yeast DNA replication in vitro

Fractions containing a high molecular weight form (Mr approximately equal to 2 X 10(6] of the activity that replicates in vitro both the 2-micron yeast DNA plasmid and the chromosomal autonomously replicating sequence ars 1 can be prepared from cells of the budding yeast Saccharomyces. Protein complexes from the fractions associate in vitro with the replication origins of these DNA elements, as determined by electron microscopy. In the present study, the high molecular weight replicative fraction has been characterized in further detail. The DNA synthetic activity in the high molecular weight fraction was bound to the DNA and could be isolated with it. This binding of the replicating activity to the DNA was greatly reduced in the absence of the 2-micron origins of replication. Association of the protein complexes with DNA depended on the amount of replicating activity added, was sensitive to 0.2 M KCl, and exhibited a requirement for rATP and deoxyribonucleoside triphosphates. It was not blocked, however, by the DNA polymerase inhibitor aphidicolin or by the RNA polymerase inhibitor alpha-amanitin. The lack of inhibition by aphidicolin suggests that the deoxyribonucleoside triphosphates may function as cofactors in the binding of protein complexes to DNA or as substrates for a polymerizing activity such as a primase. Binding of the protein complexes as well as actual DNA replication were heat sensitive in the high molecular weight fraction prepared from the temperature-sensitive mutant of the cell division cycle cdc 8. This suggests that the cdc 8 gene product is present in a replicative protein complex and strengthens the conclusion that the presence of the protein complexes on the DNA is associated with replication. Using independent enzyme assays, several other possible replication proteins (including DNA polymerase I, DNA ligase, DNA primase, and DNA topoisomerase II) have been identified directly in the high molecular weight replicative fraction. All of these results provide support for the idea that a protein complex (or replisome ) is involved in the replication of both the extrachromosomal 2-micron DNA and chromosomal DNA in yeast.     

Interaction of DNA topoisomerase 1 with DNA intermediates and proteins of base excision repair

The interaction of human recombinant DNA topoisomerase 1 (Top1) with linear and circular DNA structures containing a nick or short gap but lacking a specific Top1 recognition site was studied. The effect of key excision repair proteins on formation of the Top1 covalent adduct with the DNA repair intermediates was shown. Partial inhibition of the Top1-DNA-adduct formation upon addition of poly(ADP-ribose) polymerase 1 in the absence of NAD⁺ was shown, whereas in the presence of NAD⁺ formation of a high molecular weight product, most likely corresponding to poly(ADP)-ribosylated Top1-DNA adduct, was observed. The data show that the key base excision repair proteins can influence formation of suicide Top1-DNA adducts. Top1 was identified by immunoprecipitation in the bovine testis nuclear extract as the protein forming the main modification product with nick-containing DNA.     

RRM proteins interacting with the cap region of topoisomerase I

RNA recognition motif (RRM) domains bind both nucleic acids and proteins. Several proteins that contain two closely spaced RRM domains were previously found in protein complexes formed by the cap region of human topoisomerase I, a nuclear enzyme responsible for DNA relaxation or phosphorylation of SR splicing proteins. To obtain molecular insight into specific interactions between the RRM proteins and the cap region of topo I we examined their binary interactions using the yeast two-hybrid system. The interactions were established for hnRNP A1, p54(nrb) and SF2/ASF, but not for hnRNP L or HuR. To identify the amino acid pattern responsible for binding, experimental mutagenesis was employed and computational modelling of these processes was carried out. These studies revealed that two RRM domains and six residues of the consensus sequence are required for the binding to the cap region. On the basis of the above data, a structural model for the hnRNP A1-topoisomerase I complex was proposed. The main component of the hnRNP A1 binding site is a hydrophobic pocket on the beta-surface of the first RRM domain, similar to that described for Y14 protein interacting with Mago. We demonstrated that the interaction between RRM domains and the cap region was important for the kinase reaction catalyzed by topoisomerase I. Together with the previously described inhibitory effect of RRM domains of SF2/ASF on DNA cleavage, the above suggests that the binding of RRM proteins could regulate the activity of topoisomerase I.     

Interaction between the N-terminus of human topoisomerase I and SV40 large T antigen.

We have attempted to identify human topoisomerase I-binding proteins in order to gain information regarding the cellular roles of this protein and the cytotoxic mechanisms of the anticancer drug camptothecin, which specifically targets topoisomerase I. In the course of this work we identified an interaction between the N-terminus of human topoisomerase I and the SV40 T antigen that is detectable in vitro using both affinity chromatography and co-immunoprecipitation. Additional results indicate that this interaction does not require intermediary DNA or stoichiometric quantities of other proteins. Furthermore, the interaction is detectable in vivo using a yeast two-hybrid assay. Two binding sites for T antigen are apparent on the topoisomerase I protein: one consisting of amino acids 1-139, the other present in the 383-765 region of the protein. Interestingly, nucleolin, which binds the 166-210 region of topoisomerase I, is able to bind an N-terminal fragment of topoisomerase I concurrently with T antigen. Taken together with our prior identification of nucleolin as a topoisomerase I-binding protein, the current results suggest that helicase-binding is a major role of the N-terminus of human topoisomerase I and that the resultant helicase-topoisomerase complex may function as a eukaryotic gyrase.     

Identification of a topoisomerase I mutant,scsA1, as an extragenic suppressor of a mutation in scaA(NBS1), the apparent homolog of human nibrin in Aspergillus nidulans

The Mre11-Rad50-Nbs1 protein complex has emerged as a central player in the human cellular DNA damage response, and recent observations suggest that these proteins are at least partially responsible for the linking of DNA damage detection to DNA repair and cell cycle checkpoint functions. Mutations in scaA(NBS1), which encodes the apparent homolog of human nibrin in Aspergillus nidulans, inhibit growth in the presence of the antitopoisomerase I drug camptothecin. This article describes the selection and characterization of extragenic suppressors of the scaA1 mutation, with the aim of identifying other proteins that interfere with the pathway or complex in which the ScaA would normally be involved. Fifteen extragenic suppressors of the scaA1 mutation were isolated. The topoisomerase I gene can complement one of these suppressors. Synergistic interaction between the scaA(NBS1) and scsA(TOP1) genes in the presence of DNA-damaging agents was observed. Overexpression of topoisomerase I in the scaA1 mutant causes increased sensitivity to DNA-damaging agents. The scsA(TOP1) and the scaA(NBS1) gene products could functionally interact in pathways that either monitor or repair DNA double-strand breaks.