Site-specific binding constants for actinomycin D on DNA determined from footprinting studies

[Cu(o-phthalate)(phenanthroline)] Exhibits Unique Superoxide-Mediated NCI-60 Chemotherapeutic Action through Genomic DNA Damage and Mitochondrial Dysfunction

The in cellulo catalytic production of reactive oxygen species (ROS) by copper(II) and iron(II) complexes is now recognized as a major mechanistic model in the design of effective cytotoxins of human cancer. The developmental complex, [Cu(o-phthalate)(1,10-phenanthroline)] (Cu-Ph), was recently reported as an intracellular ROS-active cytotoxic agent that induces double strand breaks in the genome of human cancer cells. In this work, we report the broad-spectrum action of Cu-Ph within the National Cancer Institute's (NCI) Developmental Therapeutics Program (DTP), 60 human cancer cell line screen. The activity profile is compared to established clinical agents-via the COMPARE algorithm-and reveals a novel mode of action to existing metal-based therapeutics. In this study, we identify the mechanistic activity of Cu-Ph through a series of molecular biological studies that are compared directly to the clinical DNA intercalator and topoisomerase II poison doxorubicin. The presence of ROS-specific scavengers was employed for in vitro and intracellular evaluation of prevailing radical species responsible for DNA oxidation with superoxide identified as playing a critical role in this mechanism. The ROS targeting properties of Cu-Ph on mitochondrial membrane potential were investigated, which showed that it had comparable activity to the uncoupling ionophore, carbonyl cyanide m-chlorophenyl hydrazine. The induction and origins of apoptotic activation were probed through detection of Annexin V and the activation of initiator (8,9) and executioner caspases (3/7) and were structurally visualized using confocal microscopy. Results here confirm a unique radical-induced mechanistic profile with intracellular hallmarks of damage to both genomic DNA and mitochondria.

Extracting physical chemistry from mechanics: a new approach to investigate DNA interactions with drugs and proteins in single molecule experiments

In this review we focus on the idea of establishing connections between the mechanical properties of DNA–ligand complexes and the physical chemistry of DNA–ligand interactions.

Differential disruption of EWS-FLI1 binding by DNA-binding agents

Fusion of the EWS gene to FLI1 produces a fusion oncoprotein that drives an aberrant gene expression program responsible for the development of Ewing sarcoma. We used a homogenous proximity assay to screen for compounds that disrupt the binding of EWS-FLI1 to its cognate DNA targets. A number of DNA-binding chemotherapeutic agents were found to non-specifically disrupt protein binding to DNA. In contrast, actinomycin D was found to preferentially disrupt EWS-FLI1 binding by comparison to p53 binding to their respective cognate DNA targets in vitro. In cell-based assays, low concentrations of actinomycin D preferentially blocked EWS-FLI1 binding to chromatin, and disrupted EWS-FLI1-mediated gene expression. Higher concentrations of actinomycin D globally repressed transcription. These results demonstrate that actinomycin D preferentially disrupts EWS-FLI1 binding to DNA at selected concentrations. Although the window between this preferential effect and global suppression is too narrow to exploit in a therapeutic manner, these results suggest that base-preferences may be exploited to find DNA-binding compounds that preferentially disrupt subclasses of transcription factors.

DNase I footprinting

Footprinting is a method for determining the sequence selectivity of DNA-binding compounds in which ligands protect DNA from cleavage at their binding sites. Footprinting templates are typically 50-200 base pairs long, and DNase I is the most commonly used nuclease for these experiments. This chapter describes the preparation and labelling of suitable DNA footprinting substrates, the footprinting experiment itself, and the way in which these data can be used to estimate the dissociation constant of the interaction.

Design and synthesis of 4-substituted indolo[3,2-e][1,2,3]triazolo[1,5-a]pyrimidine derivatives with antitumor activity

New derivatives of the indolo[3,2- e][1,2,3]triazolo[1,5- a]pyrimidine system, substituted in the 4 position, were designed as novel antitumor agents because of their theoretical capability to form stable complexes with DNA fragments. The calculated free energies of binding were found in the range -12.76 --> -39.68 Kcal/mol. The docking studies revealed a common binding mode with the chromophore intercalated between GC base pairs, whereas the side chain lies along the minor groove. Compounds, selected on the basis of the docking studies and suitably synthesized, showed antiproliferative activity against each type of tumor cell line investigated, generally in the low micromolar range. The more active derivatives were shown to be 1eJ and 1eL, endowed with significant antiproliferative activity against the renal and CNS subpanels, respectively. A mechanism of action closely related to the DNA-interacting drugs can be supposed, although, alternative mechanisms, similar to those of the anthracyclines, can also operate.

Study of interactions between actinomycin D and oligonucleotides by microchip electrophoresis and ESI-MS

In the present study, the interactions between actinomycin D (ActD) and single stranded DNA (ssDNA) 5'-CGTAACCAACTGCAACGT-3' and a duplex stranded DNA (dsDNA) with this sequence were investigated by microchip-based non-gel sieving electrophoresis and electrospray ionization mass spectrometry (ESI-MS). The ssDNA was designed according to the conserved regions of open reading frame 1b (replicase 1B) following the Tor 2 SARS genome sequence of 15611-15593. The binding constants of the interactions between ActD and ssDNA/dsDNA were (8.3+/-0.32)x10(6)M(-1) (ssDNA) and (2.8+/-0.02)x10(5)M(-1) (dsDNA), respectively, calculated from microchip electrophoresis via Scatchard plot. The binding stoichiometries were 1:1 (single/1ActD molecule) and 1:2 (duplex/2ActD molecules) calculated from microchip electrophoresis, and the results were further verified by ESI-MS. The results obtained by these two methods indicated that ActD bound much more tightly to ssDNA used in this work than dsDNA. Furthermore, this is shown that the microchip-based non-gel sieving electrophoresis method is a rapid, highly sensitive and convenient method for the studies of interactions between DNA and small molecule drugs.

Fluorescent intercalator displacement analyses of DNA binding by the peptide-derived natural products netropsin, actinomycin, and bleomycin

The response of the high-throughput fluorescent intercalator displacement (HT-FID) assay reported recently by Boger et al. to peptide-based DNA binding intercalators and metal complexes was examined through the study of actinomycin and Co(III).bleomycin-B2. Along with a validation of netropsin that illustrated the good laboratory-to-laboratory reproducibility of the assay, our examination of actinomycin revealed results for a four base pair cassette library of DNA hairpins that paralleled the known DNA site-selectivity of this agent and also indicated the involvement of the flanking sequences of the hairpin oligonucleotide. In addition, for Co(III).bleomycin-B2 the established cleavage site-selectivity for 5'-GT and 5'-GC sites was correlated to drug-DNA association in this binding-only assay; our results also suggest a tetranucleotide site-selectivity for metallobleomycin involving cross-strand, 'back-to-back' 5'-GT and 5'-GC sites such as 5'-ACGT and 5'-ACGC.

Single-strand DNA binding of actinomycin D with a chromophore 2-amino to 2-hydroxyl substitution

A modified actinomycin D was prepared with a hydroxyl group that replaced the amino group at the chromophore 2-position, a substitution known to strongly reduce affinity for double-stranded DNA. Interactions of the modified drug on single-stranded DNAs of the defined sequence were investigated. Competition assays showed that 2-hydroxyactinomycin D has low affinity for two oligonucleotides that have high affinities (K(a) = 5-10 x 10(6) M(-1) oligomer) for 7-aminoactinomycin D and actinomycin D. Primer extension inhibition assays performed on several single-stranded DNA templates totaling around 1000 nt in length detected a single high affinity site for 2-hydroxyactinomycin D, while many high affinity binding sites of unmodified actinomycin D were found on the same templates. The sequence selectivity of 2-hydroxyactinomycin D binding is unusually high and approximates the selectivity of restriction endonucleases. Binding appears to require a complex structure, including residues well removed from the polymerase pause site.

Actinomycin D induces high-level resistance to thymidine analogs in replication of human immunodeficiency virus type 1 by interfering with host cell thymidine kinase expression

Actinomycin D (ActD) is a transcription inhibitor and has been used in the treatment of certain forms of cancer. ActD has been reported to be a potential inhibitor of human immunodeficiency virus type 1 (HIV-1) replication due to its ability to inhibit reverse transcription. In contrast to what was expected, low concentrations of ActD (1 to 10 nM) upregulated HIV-1 replication 8- to 10-fold in MT-2 cells and had no effect on HIV-2 replication or on HIV-1 replication in MT-4, Jurkat, or peripheral blood mononuclear cells. The upregulation of HIV-1 replication was associated with an increase in HIV-1 transcription and a decrease in CD4 and CXCR4 expression. To further evaluate the effects of ActD on emergence of drug resistance in HIV-1 replication, a series of drug resistance assays were performed. Of interest, treatment of MT-2 cells with ActD also led to a high level of resistance to thymidine analogs (>1,000-fold increase in resistance to zidovudine and >250-fold to stavudine) but not to other nucleoside reverse transcriptases (RT), nonnucleoside RT, or protease inhibitors. This resistance appeared to be due to a suppression of host cell thymidine kinase-1 (TK-1) expression. These results indicate that ActD leads to a novel form of thymidine analog resistance by suppressing host cell TK-1 expression. These results suggest that administration of combination drugs to HIV-1-infected patients may induce resistance to antiretroviral compounds via a modification of cellular factors.

Drug-RNA footprinting

RNase I and RNase T1 can be used to obtain high-quality footprinting information for paromomycin binding to a 176-mer RNA from the packaging region of HIV-1 (LAI). Controls and scanning procedures are necessary for quantitation of autoradiographic data, so that footprinting plots showing cutting behavior as a function of drug concentration can be used to identify binding sites and regions of altered structure on the 176-mer. From the RNase I footprinting results the primary paromomycin binding sites on the 176-mer are on the main stem and on the stem of SL1, but noncontiguous sequences may be involved in the same binding event. Strong enhancements in cleavage with added drug are also observed, indicating drug-induced structural changes. Drug binding may cause linker regions between stem-loops of the 176-mer to change structure, possibly providing a site or sites for additional drug binding. Because drug binding changes the structure of the packaging region, which may alter its function, paromomycin analogs with enhanced specificity for HIV psi RNA have potential as a new class of agent for treating AIDS.

Actinomycin D binds strongly to d(CGACGACG) and d(CGTCGTCG)

Earlier calorimetric studies had indicated that despite the absence of a GpC sequence, the self-complementary octamer d(CGTCGACG) binds strongly to actinomycin D (ACTD) with high cooperativity and a 2:1 drug/duplex ratio. A subsequent optical spectral study with related oligomers led us to suggest that ACTD may likely stack at the G. C basepairs of the duplex termini. New findings are reported herein to indicate that despite the lack of complete self-complementarity, oligomers of d(CGXCGXCG) [X = A or T] motif exhibit unusually strong ACTD affinities with binding constants of roughly 2 x 10(7) M(-1) and binding densities of 1 drug molecule per strand. The ACTD binding affinity for the corresponding heteroduplex obtained by annealing these two oligomers is, however, considerably reduced. Although spectroscopic results with related oligomers obtained by removing, replacing, or appending bases at the termini appear to be consistent with the end-stacking model, capillary electrophoretic (CE) evidence provides additional insights into the binding mode. CE experiments with the self-complementary oligomers d(CGAGCTCG) and d(CGTCGACG) revealed contrasting migration patterns in the presence of ACTD, with mobility retardation and acceleration exhibited by the GpC- and non-GpC-containing octamers, respectively, whereas the X/X-mismatched d(CGXCGXCG) experienced retardation. These results, along with those of related oligomers, suggest that ACTD may in fact stack at the duplex stem end of a monomeric hairpin or at the 3'-end of dG as a single strand. The seemingly cooperative ACTD binding and the curved Scatchard plot for the self-complementary d(CGTCGACG) may thus be attributed to the drug-induced duplex denaturation resulting from strong binding to single strands of d(CGXCGYCG) motif. Detailed structural information on the ACTD-DNA complexes, however, must await further NMR investigations.

Water regulation of actinomycin-D binding to DNA: the interplay among drug affinity, DNA long-range conformation, and hydration

Actinomycin-D (actD) binds to natural DNA at two different classes of binding sites, weak and strong. The affinity for these sites is highly dependent on DNA sequence and solution conditions, and the interaction appears to be purely entropic driven. Although the entropic character of this reaction has been attributed to the release of water molecules upon drug to DNA complex formation, the mechanism by which hydration regulates actD binding and discrimination between different classes of binding sites on natural DNA is still unknown. In this work, we investigate the role of hydration on this reaction using the osmotic stress method. We show that the decrease of solution water activity, due to the addition of sucrose, glycerol, ethylene glycol, and betaine, favors drug binding to the strong binding sites on DNA by increasing both the apparent binding affinity delta G, and the number of DNA base pairs apparently occupied by the bound drug nbp/actD. These binding parameters vary linearly with the logarithm of the molar fraction of water in solution log(chi w), which indicates the contribution of water binding to the energetic of the reaction. It is demonstrated that the hydration change measured upon binding increases proportionally to the apparent size of the binding site nbp/actD. This indicates that nbp/actD, measured from the Scatchard plot, is a measure of the size of the DNA molecule changing conformation due to ligand binding. We also find that the contribution of DNA deformation, gauged by nbp/actD, to the total free energy of binding delta G, is given by delta G = delta Glocal + nbp/actD x delta GDNA, where delta Glocal = -8020 +/- 51 cal/mol of actD bound and delta GDNA = -24.1 +/- 1.7 cal/mol of base pair at 25 degrees C. We interpret delta Glocal as the energetic contribution due to the direct interactions of actD with the actual tetranucleotide binding site, and nbp/actD x delta GDNA as that due to the change in conformation, induced by binding, of nbp/actD DNA base pairs flanking the local site. This interpretation is supported by the agreement found between the value of delta GDNA and the torsional free energy change measured independently. We conclude suggesting an allosteric model for ligand binding to DNA, such that the increase in binding affinity is achieved by increasing the relaxation of the unfavorable free energy of binding storage at the local site through a larger number of DNA base pairs. The new aspect on this model is that the "size" of the complex is not fixed but determined by solutions conditions, such as water activity, which modulate the energetic barrier to change helix conformation. These results may suggest that long-range allosteric transitions of duplex DNA are involved in the inhibition of RNA synthesis by actD, and more generally, in the regulation of transcription.

A survey of the sequence-specific interaction of damaging agents with DNA: emphasis on antitumor agents

This article reviews the literature concerning the sequence specificity of DNA-damaging agents. DNA-damaging agents are widely used in cancer chemotherapy. It is important to understand fully the determinants of DNA sequence specificity so that more effective DNA-damaging agents can be developed as antitumor drugs. There are five main methods of DNA sequence specificity analysis: cleavage of end-labeled fragments, linear amplification with Taq DNA polymerase, ligation-mediated polymerase chain reaction (PCR), single-strand ligation PCR, and footprinting. The DNA sequence specificity in purified DNA and in intact mammalian cells is reviewed for several classes of DNA-damaging agent. These include agents that form covalent adducts with DNA, free radical generators, topoisomerase inhibitors, intercalators and minor groove binders, enzymes, and electromagnetic radiation. The main sites of adduct formation are at the N-7 of guanine in the major groove of DNA and the N-3 of adenine in the minor groove, whereas free radical generators abstract hydrogen from the deoxyribose sugar and topoisomerase inhibitors cause enzyme-DNA cross-links to form. Several issues involved in the determination of the DNA sequence specificity are discussed. The future directions of the field, with respect to cancer chemotherapy, are also examined.

Actinomycin D inhibits human immunodeficiency virus type 1 minus-strand transfer in in vitro and endogenous reverse transcriptase assays

In this report we demonstrate that human immunodeficiency virus type 1 (HIV-1) minus-strand transfer, assayed in vitro and in endogenous reactions, is greatly inhibited by actinomycin D. Previously we showed that HIV-1 nucleocapsid (NC) protein (a nucleic acid chaperone catalyzing nucleic acid rearrangements which lead to more thermodynamically stable conformations) dramatically stimulates HIV-1 minus-strand transfer by preventing TAR-dependent self-priming from minus-strand strong-stop DNA [(-) SSDNA]. Despite this potent activity, the addition of NC to in vitro reactions with actinomycin D results in only a modest increase in the 50% inhibitory concentration (IC50) for the drug. PCR analysis of HIV-1 endogenous reactions indicates that minus-strand transfer is inhibited by the drug with an IC50 similar to that observed when NC is present in the in vitro system. Taken together, these results demonstrate that NC cannot overcome the inhibitory effect of actinomycin D on minus-strand transfer. Other experiments reveal that at actinomycin D concentrations which severely curtail minus-strand transfer, neither the synthesis of (-) SSDNA nor RNase H degradation of donor RNA is affected; however, the annealing of (-) SSDNA to acceptor RNA is significantly reduced. Thus, inhibition of the annealing reaction is responsible for actinomycin D-mediated inhibition of strand transfer. Since NC (but not reverse transcriptase) is required for efficient annealing, we conclude that actinomycin D inhibits minus-strand transfer by blocking the nucleic acid chaperone activity of NC. Our findings also suggest that actinomycin D, already approved for treatment of certain tumors, might be useful in combination therapy for AIDS.

Use of capillary electrophoresis in the study of ligand-DNA interactions

Free solution capillary electrophoresis (FSCE) has been used to separate two non-self-complementary 12mer oligonucleotide duplexes: d(AAATTATATTAT).d(ATAA-TATAATTT) and d(GGGCCGCGCCGC).d(GCGGCGCGGCCC). Titration of mixtures of the two oligonucleotides with model intercalators (ethidium bromide andactinomycin D) and minor groove binders (netropsin, Hoechst 33258 and distamycin) has shown the suitability of FSCE as a method to study the sequence selectivity of DNA binding agents. Binding data have shown cooperativity of binding for netropsin and Hoechst 33258 and have provided ligand:DNA binding ratios for all five compounds. Cooperativity of netropsin binding to a 12mer with two potential sites has been demonstrated for the first time. Ligands binding in the minor groove caused changes in migration time and peak shape which were significantly different from those caused by intercalators.

Footprinting of echinomycin and actinomycin D on DNA molecules asymmetrically substituted with inosine and/or 2,6-diaminopurine

In order to clarify the role of the purine 2-amino group in the recognition of DNA by small molecules we have examined the binding of actinomycin D and echinomycin to artificial DNA molecules asymmetrically substituted with inosine and/or 2,6-diaminopurine (DAP) in one of the complementary strands. These DNAs, prepared by a method based upon PCR, present various potential sites for antibiotic binding, including several containing only a single purine 2-amino group in different configurations. The results show unambiguously that the presence of two 2-amino groups is mandatory for binding of actinomycin D to double-stranded DNA. In the case of echinomycin only one purine 2-amino group is required for remarkably strong binding to the asymmetric TpDAP.TpA dinucleotide step, but the CpDAP.TpI step (which also contains only a single purine-2 amino group) does not afford a binding site. Evidently, removing a 2-amino group (G-->I substitution) is dominant over adding one (A-->DAP substitution). No sequences containing just a single guanine residue are acceptable. The possibility is raised that replacing guanosine with inosine may do more than remove a group endowed with hydrogen bonding capability and interfere with ligand binding in other ways. The new methodology developed to construct asymmetrically substituted DNA substrates for this work provides a novel strategy that should be generally applicable for studying ligand-DNA interactions, beyond the specific interest in drug binding to DNA, and may help to elucidate how proteins and oligonucleotides recognize their target sites.

Altered cleavage of DNA sequences by bleomycin and its deglycosylated derivative in the presence of actinomycin

The antitumour antibiotics bleomycin and actinomycin are commonly used therapeutically in combination. One causes metal ion- and oxygen-dependent oxidative damage to DNA, while the other acts at the level of DNA via intercalation of its phenoxazone chromophore and probable inhibition of topoisomerases. Both drugs bind and/or cleave DNA primarily at guanine-containing sequences, which could lead to mutual interference. Using three different restriction fragments we show that binding of actinomycin to DNA causes major alterations in the sequence specificity of bleomycin.Fe-mediated cleavage, including the appearance of new cleavage sites and the suppression of others. The subtle sequence-dependence of the interference is illustrated by the different effects of actinomycin on DNA cleavage by the deglycobleomycin.Fe complex. Actinomycin sharply decreases the extent of cleavage at GpC sites by both bleomycin and deglycobleomycin whereas cleavage at GpT sites is much less affected, while novel cleavage sites are generated at GpA, ApT and, to a lesser extent, TpT steps. A dramatic increase in bleomycin.Fe cutting at GpA is barely detectable with deglycobleomycin.Fe, confirming that the carbohydrate moiety of bleomycin is important for DNA recognition. The results contribute to a better understanding of how two individually well-characterized small molecules interact simultaneoulsy with specific sequences in DNA and as such assist clarification of the principles governing drug-DNA recognition.

Structure-affinity relationships for the binding of actinomycin D to DNA

Molecular models of the complexes between actinomycin D and 14 different DNA hexamers were built based on the X-ray crystal structure of the actinomycin-d(GAAGCTTC)2 complex. The DNA sequences included the canonical GpC binding step flanked by different base pairs, nonclassical binding sites such as GpG and GpT, and sites containing 2,6-diamino-purine. A good correlation was found between the intermolecular interaction energies calculated for the refined complexes and the relative preferences of actinomycin binding to standard and modified DNA. A detailed energy decomposition into van der Waals and electrostatic components for the interactions between the DNA base pairs and either the chromophore or the peptidic part of the antibiotic was performed for each complex. The resulting energy matrix was then subjected to principal component analysis, which showed that actinomycin D discriminates among different DNA sequences by an interplay of hydrogen bonding and stacking interactions. The structure-affinity relationships for this important antitumor drug are thus rationalized and may be used to advantage in design of novel sequence-specific DNA-binding agents.

Quantitative nucleic acids footprinting: thermodynamic and kinetic approaches

Quantitative footprinting techniques allow a detailed analysis of the thermodynamic forces that characterize nucleic acid-ligand interactions and ligand-induced changes in nucleic acid structure by separately resolving the intrinsic and cooperative Gibbs free energy changes describing the reactions being investigated. A new implementation of the quantitative footprinting technique is the application of stopped-flow techniques to the study of kinetic reactions.

Sequence-specific actinomycin D binding to single-stranded DNA inhibits HIV reverse transcriptase and other polymerases

Primer extension assays using recombinant templates constructed to contain all 256 possible base quartets in a minimum length sequence were used to examine binding of the anticancer drug actinomycin D to single-stranded DNA. Single-stranded templates were generated by digestion of linearized plasmid with the double-strand-specific T7 gene 6 exonuclease. Actinomycin D formed high-affinity, kinetically stable complexes that paused primer elongation at specific sites by HIV-1 reverse transcriptase, Sequenase (modified T4 DNA polymerase), the Klenow fragment of Escherichia coli DNA polymerase, and Vent (exo-) DNA polymerase. Pauses occurred most commonly near G+C-rich nucleotide clusters, including GpC steps, the preferred sites of double-stranded DNA binding. Complexes were stable for several minutes at temperatures over 50 degrees C as determined by their abilities to pause Vent polymerase at elevated temperatures. Significant variations were noted in pause patterns of different polymerases, demonstrating differential responses of polymerases to a bound actinomycin. Covalent adducts formed on template DNA by a photoaffinity analog of actinomycin D completely stopped primer extension. These results support the possibility that actinomycin D inhibits transcription elongation by complexing single-stranded DNA in the open transcription complex. Single-stranded DNA binding by actinomycin D or analogs may also provide routes for combating HIV or other viruses which replicate through single-stranded intermediates.

Photoaffinity approaches to determining the sequence selectivities of DNA-small molecule interactions: actinomycin D and ethidium

The DNA photoaffinity ligands, 7-azidoactinomycin D and 8-azidoethidium, form DNA adducts that cause chain cleavage upon treatment with piperidine. Chemical DNA sequencing techniques were used to detect covalent binding. The relative preferences for modifications of all possible sites defined by a base pair step (e.g. GC) were determined within all quartet contexts such as (IGCJ). These preferences are described in terms of 'effective site occupations', which express the ability of a ligand to covalently modify some base in the binding site. Ideally, the effective site occupations measured for photoaffinity agents can also be related to site-specific, non-covalent association constants of the ligand. The sites most reactive with 7-azidoactinomycin D were those preferred for non-covalent binding of unsubstituted actinomycin D. GC sites were most reactive, but next-nearest neighbors exerted significant influences on reactivity. GC sites in 5'-(pyrimidine)GC(purine)-3' contexts, particularly TGCA, were most reactive, while reactivity was strongly suppressed for GC sites with a 5'-flanking G, or a 3'-flanking C. High reactivities were also observed for bases in the first (5') GG steps in TGGT, TGGG and TGGGT sequences recently shown to bind actinomycin D with high affinity. Pyrimidine-3',5'-purine steps and GG steps flanked by a T were most preferred by 8-azidoethidium, in agreement with the behavior of unsubstituted ethidium. The good correspondence between expected and observed covalent binding preferences of these two azide analogs demonstrates that photoaffinity labeling can identify highly preferred sites of non-covalent DNA binding by small molecules.

Transferring the purine 2-amino group from guanines to adenines in DNA changes the sequence-specific binding of antibiotics

The proposition that the 2-amino group of guanine plays a critical role in determining how antibiotics recognise their binding sites in DNA has been tested by relocating it, using tyrT DNA derivative molecules substituted with inosine plus 2,6-diaminopurine (DAP). Irrespective of their mode of interaction with DNA, such GC-specific antibiotics as actinomycin, echinomycin, mithramycin and chromomycin find new binding sites associated with DAP-containing sequences and are excluded from former canonical sites containing I.C base pairs. The converse is found to be the case for a group of normally AT-selective ligands which bind in the minor groove of the helix, such as netropsin: their preferred sites become shifted to IC-rich clusters. Thus the binding sites of all these antibiotics strictly follow the placement of the purine 2-amino group, which accordingly must serve as both a positive and negative effector. The footprinting profile of the 'threading' intercalator nogalamycin is potentiated in DAP plus inosine-substituted DNA but otherwise remains much the same as seen with natural DNA. The interaction of echinomycin with sites containing the TpDAP step in doubly substituted DNA appears much stronger than its interaction with CpG-containing sites in natural DNA.

Actinomycin D stimulates the transcription of rRNA minigenes transfected into mouse cells. Implications for the in vivo hypersensitivity of rRNA gene transcription

The in vivo hypersensitivity of eukaryotic rRNA gene transcription to actinomycin D has long been known, but this effect could not be reproduced in model systems and its molecular mechanisms remain uncertain. We studied the action of actinomycin D using mouse rRNA minigenes (with RNA polymerase I promoter and terminator signals), carrying truncated mouse or human rDNA inserts, which are faithfully transcribed upon transient transfection into mouse cells. Low concentrations (0.01-0.08 micrograms/ml) of actinomycin D caused within 1-2 h a 2-7-fold stimulation of the transcription of rRNA minigenes which is inversely related to the size of the rDNA transcript. With transcripts longer than 3 kb the effect was reversed and at 4 kb a practically complete inhibition of the formation of full-length transcripts was observed, accompanied, however, by an enhanced accumulation of unfinished rDNA transcripts. The dependence of actinomycin D action on transcript length was also observed with lacZ gene segments of different size inserted into the mouse rRNA minigenes. The transcription initiation of endogenous rRNA genes was also stimulated by the low doses of actinomycin D as indicated by the enhanced synthesis of unfinished rDNA transcripts (spanning mainly the 5' external transcribed spacer), whereas the synthesis of full-length transcripts was abolished. Removal of actinomycin D from the medium caused within 8-24 h a dramatic increase of the transcription from all rRNA minigenes tested. This stimulation was also inversely related to the size of the transcripts and varied from twofold to fivefold for the 3-4-kb transcripts to about 50-80-fold for the basic minigene transcript (395 nucleotides). The amount of endogenous aborted rDNA transcripts was also markedly increased, but the synthesis of full-length transcripts was not restored even 24 h after removal of the drug. The present results reproduce in a model cellular system the in vivo hypersensitivity of rRNA gene transcription to actinomycin D and reveal that the major factor involved is the size of the rRNA gene transcript. This effect requires only the basic rRNA gene promoter and terminator signals and does not depend on the G + C content of the RNA polymerase I transcripts. We suggest that at low concentrations, the intercalation of actinomycin D changes the conformation of DNA in the promoter region in a manner that stimulates the transcription of both endogenous and transfected rRNA genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Daunomycin modifies the sequence-selective recognition of DNA by actinomycin

The antitumour antibiotic actinomycin D normally binds to DNA by intercalation at sequences containing the CpG step, but in the presence of daunomycin it has been reported to interact with poly(dA-dT). This observation has neither been confirmed nor explained. Here we have used a photoreactive 7-azido derivative of actinomycin to study the effect of daunomycin on its binding to three DNA fragments. Daunomycin did indeed alter the binding of actinomycin to the DNA, such that the antibiotic was displaced from its primary GpC sites onto secondary sites in the DNA, though not to AT regions especially. These findings suggest a possible scientific explanation for the increased toxicity seen during combination chemotherapy with these two drugs.

Quantitative footprinting analysis

This review outlines the steps for obtaining relative binding constants for drugs from footprinting data. After correcting the autoradiographic spot intensities for differing amounts of radioactive DNA loaded into the lanes of a sequencing gel, footprinting plots, showing individual spot intensities as a function of drug concentration, are constructed. The initial relative slopes of footprinting plots are proportional to the binding constant of the drug for its DNA site. Slopes of plots outside of drug binding sites can be used to identify locations of altered DNA structure. It illustrates the power of quantitative footprinting analysis by analyzing the binding of the antiviral agent netropsin to a 139-base pair restriction fragment in the presence of the antitumor agent actinomycin D. While two netropsin binding regions are unaffected by actinomycin D a third region experiences enhanced binding in the presence of the antitumor agent.

Drug-DNA sequence-dependent interactions analysed by electric linear dichroism

The interactions between 20 drugs and a variety of synthetic DNA polymers and natural DNAs were studied by electric linear dichroism (ELD). All compounds tested, including several clinically used antitumour agents, are thought to exert their biological activities mainly by virtue of their abilities to bind to DNA. The selected drugs include intercalating agents with fused and unfused aromatic structures and several groove binders. To examine the role of base composition and base sequence in the binding of these drugs to DNA, ELD experiments were carried out with natural DNAs of widely differing base composition as well as with polynucleotides containing defined alternating and non-alternating repeating sequences, poly(dA).poly(dT), poly(dA-dT).poly(dA-dT),poly(dG).poly(dC) and poly(dG-dC).poly(dG-dC). Among intercalating agents, actinomycin D was found to be by far the most GC-selective. GC selectivity was also observed with an amsacrine-4-carboxamide derivative and to a lesser extent with methylene blue. In contrast, the binding of amsacrine and 9-aminoacridine was practically unaffected by varying the GC content of the DNAs. Ethidium bromide, proflavine, mitoxantrone, daunomycin and an ellipticine derivative were found to bind best to alternating purine-pyrimidine sequences regardless of their nature. ELD measurements provided evidence for non-specific intercalation of amiloride. A significant AT selectivity was observed with hycanthone and lucanthone. The triphenyl methane dye methyl green was found to exhibit positive and negative dichroism signals at AT and GC sites, respectively, showing that the mode of binding of a drug can change markedly with the DNA base composition. Among minor groove binders, the N-methylpyrrole carboxamide-containing antibiotics netropsin and distamycin bound to DNA with very pronounced AT specificity, as expected. More interestingly the dye Hoechst 33258, berenil and a thiazole-containing lexitropsin elicited negative reduced dichroism in the presence of GC-rich DNA which is totally inconsistent with a groove binding process. We postulate that these three drugs share with the trypanocide 4',6-diamidino-2-phenylindole (DAPI) the property of intercalating at GC-rich sites and binding to the minor groove of DNA at other sites. Replacement of guanines by inosines (i.e., removal of the protruding exocyclic C-2 amino group of guanine) restored minor groove binding of DAPI, Hoechst 33258 and berenil. Thus there are several cases where the mode of binding to DNA is directly dependent on the base composition of the polymer. Consequently the ELD technique appears uniquely valuable as a means of investigating the possibility of sequence-dependent recognition of DNA by drugs.