Sequence selective binding of ditrisarubicin B to DNA: comparison with daunomycin

DNase I footprinting has been used to examine the sequence selective binding of ditrisarubicin B, novel anthracycline antibiotic, to DNA. At 37°C no footprinting pattern is observed, the drug protects all sites from enzymic cleavage with equal efficiency. At 4°C a footprinting pattern is induced with low drug concentrations which is different from that produced by daunomycin. The best binding sites contain the dinucleotide step GpT (ApC) and are located in regions of alternating purines and pyrimidines.     

Quantitative footprinting analysis using a DNA-cleaving metalloporphyrin complex

The results of quantitative footprinting studies involving the antiviral agent netropsin and a DNA-cleaving cationic metalloporphyrin complex are presented. An analysis of the footprinting autoradiographic spot intensities using a model previously applied to footprinting studies involving the enzyme DNase I [Ward, B., Rehfuss, R., Goodisman, J., & Dabrowiak, J. C. (1988) Biochemistry 27, 1198-1205] led to very low values for netropsin binding constants on a restriction fragment from pBR-322 DNA. In this work, we show that, because the porphyrin binds with high specificity to DNA, it does not report site loading information in the same manner as does DNase I. We elucidate a model involving binding equilibria for individual sites and include competitive binding of drug and porphyrin for the same site. The free porphyrin and free drug concentrations are determined by binding equilibria with the carrier (calf thymus DNA) which is present in excess and acts as a buffer for both. Given free porphyrin and free netropsin concentrations for each total drug concentration in a series of footprinting experiments, one can calculate autoradiographic spot intensities in terms of the binding constants of netropsin to the various sites on the 139 base pair restriction fragment. The best values of these binding constants are determined by minimizing the sum of the squared differences between calculated and experimental footprinting autoradiographic spot intensities. Although the determined netropsin binding constants are insensitive to the value assumed for the porphyrin binding constant toward its highest affinity sites, the best mean-square deviation between observed and calculated values, D, depends on the choice of (average) drug binding constant to carrier DNA, Kd.(ABSTRACT TRUNCATED AT 250 WORDS)     

Footprinting reveals that nogalamycin and actinomycin shuffle between DNA binding sites.

The hypothesis that sequence-selective DNA-binding antibiotics locate their preferred binding sites by a process involving migration from nonspecific sites has been tested by footprinting with DNAase I. Footprinting patterns on the tyrT DNA fragment produced by nogalamycin and actinomycin change with time after mixing the antibiotic with the DNA. Sites of protection as well as enhanced cleavage are seen to develop in a fashion which is both temperature and concentration-dependent. At certain sites cutting is transiently enhanced, then blocked. Limited evidence for slow reaction with echinomycin and mithramycin is presented, but the kinetics of footprinting with daunomycin and distamycin appear instantaneous. The feasibility of adducing direct evidence for shuffling by footprinting seems to be governed by slow dissociation of the antibiotic-DNA complex. It may also be dependent upon the mode of binding, be it intercalative or non-intercalative in character.     

Specific protection of DNA by distamycin A, netropsin and bis-netropsins against the action of DNAse I

Interaction of netropsin, distamycin A and a number of bis-netropsins with DNA fragments of definite nucleotide sequence was studied by footprinting technique. The nuclease protection experiments were made at fixed DNA concentration and varying ligand concentrations. The affinity of ligand for a DNA site was estimated from measurements of ligand concentration that causes 50% protection of the DNA site. Distribution pattern of the protected and unprotected regions along the DNA fragment was compared with the theoretically expected arrangement of the ligand along the same DNA. The comparison led us to the following conclusions: 1. Footprinting experiments show that at high levels of binding the arrangement of netropsin molecules along the DNA corresponds closely to the distribution pattern expected from theoretical calculations based on the known geometry of netropsin--DNA complex. However, the observed differences in the affinity of netropsin for various DNA sequences is markedly greater than that expected from theoretical calculations. 2. Netropsin exhibits a greater selectivity of binding than that expected for a ligand with three specific reaction centers associated with the antibiotic amide groups. It binds preferentially to DNA regions containing four or more successive AT pairs. Among 13 putative binding sites for netropsin with four or more successive AT pairs there are 11 strong binding sites and two weaker sites which are occupied at 2 D/P less than or equal to 1/9 and 2 D/P = 1/4, respectively. 3. The extent of specificity manifested by distamycin A is comparable to that shown by netropsin although the molecule of distamycin A contains four rather than three amide groups. At high levels of binding distamycin A occupies the same binding sites on DNA as netropsin does. 4. The binding specificity of bis-netropsins is greater than that of netropsin. Bis-netropsins can bind to DNA in such a way that the two netropsin-like fragments are implicated in specific interaction with DNA base pairs. However, the apparent affinity of bis-netropsins estimated from footprinting experiments is comparable with that of netropsin for the same DNA region. 5. At high levels of binding bis-netropsins and distamycin A (but not netropsin) can occupy any potential site on DNA irrespectively of the DNA sequence. 6. Complex formation with netropsin increases sensitivity to DNase I at certain DNA sites along with the protection effect observed at neighboring sites.     

Characterizing the DNA contacts and cooperative binding of F plasmid TraM to its cognate sites at oriT

TraM is a DNA binding protein required for conjugative transfer of the self-transmissible IncF group of plasmids, including F, R1, and R100. F TraM binds to three sites in F oriT: two high affinity binding sites, sbmA and sbmB, which are direct repeats of nearly identical sequence involved in the autoregulation of the traM gene; and a lower affinity site, sbmC, an inverted repeat important for transfer, which is situated nearest to the nic site where transfer originates. TraM bound cooperatively to its binding sites at oriT; the presence of sbmA and sbmB increased the affinity for sbmC 10-fold. Bending of oriT DNA by TraM was minimal, suggesting that TraM, a tetramer, was able to loop the DNA when bound to sbmA and sbmB simultaneously. Hydroxyl radical footprinting of DNA of sbmA and sbmC revealed that TraM contacted the DNA within a region previously delineated by DNase I footprinting. TraM protected the CT bases within the sequence CTAG, which occurred at 12-base intervals on the top and bottom strand of sbmA, most consistently with other protected bases. The footprint on sbmC revealed that the predicted inverted repeats were protected by TraM with a pattern that began at the center of the repeats and radiated outward at 11-12 base intervals toward the 5'-ends of either strand. At high protein concentrations, this pattern extended beyond the footprint defined by DNase I, suggesting that the DNA was wrapped around the protein forming a nucleosome-like structure, which could aid in preparing the DNA for transfer.     

Influence of cationic triphenylmethane dyes upon DNA polymerization and product hydrolysis by Escherichia coli polymerase I.

The cationic triphenylmethane dyes crystal violet, methyl green, and malachite green inhibited DNA synthesis catalyzed by Escherichia coli B polymerase I (polymerase I). Lower concentrations of the dyes inhibited DNA replication as a direct function of the proportion of AT to GC in the DNA of Clostridium perfringens, Escherichia coli, and Micrococcus lysodeikticus. When the intercalant proflavin was employed, the GC-rich micrococcal DNA was most severely inhibited. In addition, both the triphenylmethanes and proflavin inhibited product hydrolysis catalyzed by polymerase I.     

Footprinting studies of DNA-sequence recognition by nogalamycin.

We have studied the DNA sequence binding preference of the antitumour antibiotic nogalamycin by DNase-I footprinting using a variety of DNA fragments. The DNA fragments were obtained by cloning synthetic oligonucleotides into longer DNA fragments and were designed to contain isolated ligand-binding sites surrounded by repetitive sequences such as (A)n.(T)n and (AT)n. Within regions of (A)n.(T)n, clear footprints are observed with low concentrations of nogalamycin (< 5 microM), with apparent binding affinities for tetranucleotide sequences which decrease in the order TGCA > AGCT = ACGT > TCGA. In contrast, within regions of (AT)n, the ligand binds best to AGCT; binding to TCGA and TGCA is no stronger than to alternating AT. Within (ATT)n, the preference is for ACGT > TCGA. Although each of these binding sites contains all four base pairs, there is no apparent consensus sequence, suggesting that the selectivity is affected by local DNA dynamic and structural effects. At higher drug concentrations (> 25 microM), nogalamycin prevents DNAse-I cleavage of (AT)n but shows no interaction with regions of (AC)n.(GT)n. Regions of (A)n.(T)n, which are poorly cut by DNase I, show enhanced rates of cleavage in the presence of low concentrations of nogalamycin, but are protected from cleavage at higher concentrations. We suggest that this arises because drug binding to adjacent regions distorts the DNA to a structure which is more readily cut by the enzyme and which is better able to bind further ligand molecules.     

Interaction of minor groove binding ligands with long AT tracts.

We have used quantitative DNase I footprinting to examine the ability of distamycin and Hoechst 33258 to discriminate between different arrangements of AT residues, using synthetic DNA fragments containing multiple blocks of (A/T)6or (A/T)10in identical sequence environments. Previous studies have shown that these ligands bind less well to (A/T)4sites containing TpA steps. We find that in (A/T)6tracts distamycin shows little discrimination between the various sites, binding approximately 2-fold stronger to TAATTA than (TA)3, T3A3and GAATTC. In contrast, Hoechst 33258 binds approximately 20-fold more tightly to GAATTC and TAATTA than T3A3and (TA)3. Hydroxyl radical footprinting reveals that both ligands bind in similar locations at the centre of each AT tract. At (A/T)10sites distamycin binds with similar affinity to T5A5, (TA)5and AATT, though bands in the centre of (TA)5are protected at approximately 50-fold lower concentration than those towards the edges. Hoechst 33258 shows a similar pattern of preference, with strong binding to AATT, T5A5and the centre of (TA)5. Hydroxyl radical footprinting reveals that at low concentrations both ligands bind at the centre of (TA)5and A5T5, while at higher concentrations ligand molecules bind to each end of the (A/T)10tracts. At T5A5two ligand molecules bind at either end of the site, even at the lowest ligand concentration, consistent with the suggestion that these compounds avoid the TpA step. Similar DNase I footprinting experiments with a DNA fragment containing T n (n = 3-6) tracts reveals that both ligands bind in the order T3< T4 << T5 = T6.     

Footprinting: a method for determining the sequence selectivity, affinity and kinetics of DNA-binding ligands

Footprinting is a simple method for assessing the sequence selectivity of DNA-binding ligands. The method is based on the ability of the ligand to protect DNA from cleavage at its binding site. This review describes the use of DNase I and hydroxyl radicals, the most commonly used footprinting probes, in footprinting experiments. The success of a footprinting experiment depends on using an appropriate DNA substrate and we describe how these can best be chosen or designed. Although footprinting was originally developed for assessing a ligand's sequence selectivity, it can also be employed to estimate the binding strength (quantitative footprinting) and to assess the association and dissociation rate constants for slow binding reactions.     

Quantitative footprinting analysis

This review outlines the steps for obtaining relative 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 sites. Slopes of plots outside the 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 netrospin to a 139-base pair restriction fragment in the presence of the antitumor agent actinomycin D. While two netrospin binding regions are unaffected by actinomycin D a third region experiences enhanced binding in the presence of the antitumor agent.     

Methyl green-pyronin Y staining of nucleic acids: studies on the effects of staining time,dye composition and diffusion rates

Since the introduction of the methyl green-pyronin Y procedure as a differential histological stain more than 100 years ago, the method has become a histochemical procedure for differential demonstration of DNA and RNA. Numerous variants of the procedure have been suggested, and a number of hypotheses have been put forward concerning kinetics and binding mechanisms. Using both filter paper models containing DNA, RNA or heparin and histological sections, we have attempted to evaluate the kinetics of staining and the role of staining time for methyl green and pyronin Y by applying the dyes individually, simultaneously and sequentially. The results are presented as color charts approximating the observed staining patterns using a computerized palette. Our results indicate unequivocally that the differential staining is not time-dependent, but that it is dictated by the relative concentrations of methyl green and pyronin Y and by the pH of the staining solution.     

Methyl green-pyronin Y staining of nucleic acids: studies on the effects of staining time, dye composition and diffusion rates

Since the introduction of the methyl green-pyronin Y procedure as a differential histological stain more than 100 years ago, the method has become a histochemical procedure for differential demonstration of DNA and RNA. Numerous variants of the procedure have been suggested, and a number of hypotheses have been put forward concerning kinetics and binding mechanisms. Using both filter paper models containing DNA, RNA or heparin and histological sections, we have attempted to evaluate the kinetics of staining and the role of staining time for methyl green and pyronin Y by applying the dyes individually, simultaneously and sequentially. The results are presented as color charts approximating the observed staining patterns using a computerized palette. Our results indicate unequivocally that the differential staining is not time-dependent, but that it is dictated by the relative concentrations of methyl green and pyronin Y and by the pH of the staining solution.     

Fluorescent complexes of DNA with DAPI 4′,6-diamidine-2-phenyl indole.2HCl or DCI 4′,6-dicarboxyamide-2-phenyl indole

4',6-Dioarboxyamide-2-phenyl indole (DCI), a non-ionic structural analogue of 4',6-diamidine-2-phenyl indole.2HCl (DAPI), was synthesized in order to verify the hypothesis of intercalation of both dyes into the DNA double helix.The influence of pH, viscosity, and different concentrations of SDS (sodium dodecylsulphate) or NaCl on the optical and fluorescent properties and the changes in thermal transition of both dye complexes with DNA confirm the affinity of the dyes to the double helix as well as their stabilizing influence on the secondary DNA structure.The results of binding studies, carried out by fluorescent methods have shown that the dyes are strongly bound to DNA, though the number of binding sites is small. According to the experimental data, the fluorescent properties of DAPI and DCI complexes with DNA are connected with the intercalating binding mechanism of these dyes. On the other hand, the eventual ionic or hydrogen bonds of dyes outside the DNA helix do not change noticeably their fluorescent properties.     

Methidiumpropyl-EDTA.Fe(II) and DNase I footprinting report different small molecule binding site sizes on DNA.

DNase I and MPE.Fe (II) footprinting both employ partial cleavage of ligand-protected DNA restriction fragments and Maxam-Gilbert sequencing gel methods of analysis. One method utilizes the enzyme, DNase I, as the DNA cleaving agent while the other employs the synthetic molecule, methidium-propyl-EDTA (MPE). For actinomycin D, chromomycin A3 and distamycin A, DNase I footprinting reports larger binding site sizes than MPE.Fe (II). DNase I footprinting appears more sensitive for weakly bound sites. MPE.Fe (II) footprinting appears more accurate in determining the actual size and location of the binding sites for small molecules on DNA, especially in cases where several small molecules are closely spaced on the DNA. MPE.Fe (II) and DNase I report the same sequence and binding site size for lac repressor protein on operator DNA.     

High resolution hydroxyl radical footprinting of the binding of mithramycin and related antibiotics to DNA.

The preferred binding sites for mithramycin on three different DNA fragments have been determined by hydroxyl radical footprinting. Sequences which appear as one long protected region using DNAase I as a footprinting probe are resolved into several discrete binding domains. Each drug molecule protects three bases from radical attack, though adjacent regions show attenuated cleavage. Mithramycin and the other related compounds induce similar footprinting patterns and appear to recognise GC rich regions with a preference for those containing the dinucleotide step GpG. The ability of each such site to bind the drug depends on the sequence environment in which it is located. The data are consistent with mithramycin binding to the DNA minor groove.     

Interaction of echinomycin with An.Tn. and (AT)n regions flanking its CG binding site.

We have prepared DNA fragments containing the sequences A15CGT15, T15CGA15 and T(AT)8CG(AT)15 cloned within the SmaI site of the pUC19 polylinker. These have been used as substrates in footprinting experiments with DNase I and diethylpyrocarbonate probing the effects of echinomycin, binding to the central CG, on the structure of the surrounding sequences. No clear DNase I footprints are seen with T15CGA15 though alterations in the nuclease susceptibility of surrounding regions suggest that the ligand is binding, albeit weakly at this site. All the other fragments show the expected footprints around the CG site. Regions of An and Tn are rendered much more reactive to DNase I and adenines on the 3'-side of the CG become hyperreactive to diethylpyrocarbonate. Regions of alternating AT show unusual changes in the presence of the ligand. At low concentrations (5 microM) cleavage of TpA is enhanced, whereas at higher concentrations a cleavage pattern with a four base pair repeat is evident. A similar pattern is seen with micrococcal nuclease. Modification by diethylpyrocarbonate is strongest at alternate adenines which are staggered in the 5'-direction across the two strands. We interpret these changes by suggesting secondary drug binding within regions of alternating AT, possibly to the dinucleotide ApT. DNase I footprinting experiments performed at 4 degrees C revealed neither enhancements nor footprints for flanking regions of homopolymeric A and T suggesting that the conformational changes are necessary consequence of drug binding.     

Preferential binding to DNA sequences of peptides related to a novel XPRK motif

Two dodecapeptide amines: (WPRK)(3)NH(2)[WR-12] and (YPRK)(3)NH(2)[YR-12], and a 30-mer polypeptide amide (SP-30) were synthesized by solid-phase peptide methodology. DNase I footprinting studies on a 117-mer DNA showed that WR-12 and YR-12 bind selectively to DNA sequences in a manner similar to SP-30 which has a repeating SPK(R)K sequence. The most distinctive blockages seen with all three peptides occur at positions 26-30, 21-24 and 38-45 around sequences 5'-GAATT-3', 5'-TAAT-3' and 5'-AAAACGAC-3', respectively. However, it appears that YR-12 is better able to extend its recognition site to include CG pairs than is SP-30. At low concentrations YR-12 was able to induce enhanced rates of DNase I cleavage at regions surrounding some of its binding sites. To obtain further quantitative data supplementary to the footprinting work, equilibrium binding experiments were performed in which the binding of the two peptides to six decanucleotide duplexes was compared. Scatchard analyses indicated that WR-12 may be more selective for oligomers containing runs of consecutive purines or pyrimidines. On the other hand, YR-12 binds better to d(CTTAGACGTC)- d(GACGTCTAAG) than to the other oligomer duplexes, denoting selectivity for evenly distributed C/G and A/T sequences.     

Interactions of heteroaromatic compounds with nucleic acids. A - T-specific non-intercalating DNA ligands.

In the present paper we report the results of a study on the base specificity and affinity of eight dyes potentially able to interact with DNA. These compounds include four triphenylmethane dyes used in histochemistry, auramine, "Hoechst 33258" and two acridines substituted with t-butyl groups. They were selected with regard to their inability to intercalate between the base pairs of helical polynucleotides due to structural limitations. Hydrodynamic studies performed with the DNA complexes of crystal violet and Hoechst 33258 confirmed our assumptions that compounds of this type bind to the outside of DNA. The main results from DNA binding studies indicate that the triphenylmethane dyes except p-fuchsin are bound with high preference to two adjacent A - T pairs while Hoechst 33258 seems to need three A - T pairs as the binding site. Model studies with synthetic polynucleotides revealed that not only a sequence of A - T pairs, but also their structural arrangement in a helix, is crucial for the high affinities observed for most of the ligands when interacting with natural DNA. Methyl green and Hoechst 33258 can be used for increasing the resolution power of cesium chloride density gradients for DNAs with different (A + T) content.     

Caffeine interaction with fluorescent calcium indicator dyes.

We report that caffeine, in millimolar concentrations, interacts strongly with four common calcium indicator dyes: mag-fura-2, magnesium green, fura-2, and fluo-3. Fluorescence intensities are either noticeably enhanced (mag-fura-2, fura-2) or diminished (magnesium green, fluo-3). The caffeine-induced changes in the fluorescence spectra are clearly distinct from those of metal ion binding at the indicator chelation sites. Binding affinities for calcium of either mag-fura-2 or magnesium green increased only slightly in the presence of caffeine. Caffeine also alters the fluorescence intensities of two other fluorescent dyes lacking a chelation site, fluorescein and sulforhodamine 101, implicating the fluorophore itself as the interaction site for caffeine. In the absence of caffeine, variation of solution hydrophobicity by means of water/dioxane mixtures yielded results similar to those for caffeine. These observations suggest that hydrophobic substances, in general, can alter dye fluorescence in a dye-specific manner. For the particular case of caffeine, and perhaps other commonly used pharmacological agents, the dye interactions can seriously distort fluorescence measurements of intracellular ion concentrations with metal indicator dyes.     

Distamycin inhibition of topoisomerase I-DNA interaction: a mechanistic analysis.

Inhibition of eukaryotic DNA topoisomerase I by the minor groove binding ligand, distamycin A, was investigated. Low concentrations of the ligand selectively prevented catalytic action at a high affinity topoisomerase I binding sequence. A restriction enzyme protection assay indicated that the catalytic cycle was blocked at the binding step. Distamycin binding sites on DNA were localized by hydroxyl radical footprinting. A strongly preferred site mapped to a homopolymeric (dA).(dT)-tract partially included in the essential topoisomerase I binding region. Mutational elimination of the stable helix curvature associated with this ligand binding site demonstrated that (i) the intrinsic bend was unessential for efficient binding of topoisomerase I, and (ii) distamycin inhibition did not occur by deformation of a stable band. Alternative modes of inhibition are discussed.