Binding of ethidium to the nucleosome core particle. 2. Internal and external binding modes

We have previously reported that the binding of ethidium bromide to the nucleosome core particle results in a stepwise dissociation of the structure which involves the initial release of one copy each of H2A and H2B (McMurray & van Holde, 1986). In this report, we have examined the absorbance and fluorescence properties of intercalated and outside bound forms of ethidium bromide. From these properties, we have measured the extent of external, electrostatic binding of the dye versus internal, intercalation binding to the core particle, free from contribution by linker DNA. We have established that dissociation is induced by the intercalation mode of binding to DNA within the core particle DNA, and not by binding to the histones or by nonintercalative binding to DNA. The covalent binding of [3H]-8-azidoethidium to the core particle clearly shows that less than 1.0 adduct is formed per histone octamer over a wide range of input ratios. Simultaneously, analyses of steady-state fluorescence enhancement and fluorescence lifetime data from bound ethidium complexes demonstrate extensive intercalation binding. Combined analyses from steady-state fluorescence intensity with equilibrium dialysis or fluorescence lifetime data revealed that dissociation began when approximately 14 ethidium molecules are bound by intercalation to each core particle and less than 1.0 nonintercalated ion pair was formed per core particle.     

Influence of the amino substituents in the interaction of ethidium bromide with DNA

A key step in the rational design of new DNA binding agents is to obtain a complete thermodynamic characterization of small molecule-DNA interactions. Ethidium bromide has served as a classic DNA intercalator for more than four decades. This work focuses on delineating the influence(s) of the 3- and 8-amino substituents of ethidium on the energetic contributions and concomitant fluorescent properties upon DNA complex formation. Binding affinities decrease by an order of magnitude upon the removal of either the 3- or 8-amino substituent, with a further order-of-magnitude decrease in the absence of both amino groups. The thermodynamic binding mechanism changes from enthalpy-driven for the parent ethidium to entropy-driven when both amino groups are removed. Upon DNA binding, fluorescence enhancement is observed in the presence of either or both of the amino groups, likely because of more efficient fluorescence quenching through solvent interactions of free amino groups than when buried within the intercalation site. The des-amino ethidium analog exhibits fluorescence quenching upon binding, consistent with less efficient quenching of the chromophore through interactions with solvent than within the intercalation site. Determination of the quantum efficiencies suggests distinct differences in the environments of the 3- and 8-amino substituents within the DNA binding site.     

Pressure-jump study of the kinetics of ethidium bromide binding to DNA

Pressure-jump chemical relaxation has been used to investigate the kinetics of ethidium bromide binding to the synthetic double-stranded polymers poly[d(G-C)] and poly[d(A-T)] in 0.1 M NaCl, 10 mM tris(hydroxymethyl)aminomethane hydrochloride, and 1 mM ethylenediaminetetraacetic acid, pH 7.2, at 24 degrees C. The progress of the reaction was followed by monitoring the fluorescence of the intercalated ethidium at wavelengths greater than 610 nm upon excitation at 545 nm. The concentration of DNA was varied from 1 to 45 microM and the ethidium bromide concentration from 0.5 to 25 microM. The data for both polymers were consistent with a single-step bimolecular association of ethidium bromide with a DNA binding site. The necessity of a proper definition of the ethidium bromide binding site is discussed: it is shown that an account of the statistically excluded binding phenomenon must be included in any adequate representation of the kinetic data. For poly[d(A-T)], the bimolecular association rate constant is k1 = 17 X 10(6) M-1 s-1, and the dissociation rate constant is k-1 = 10 s-1; in the case of poly[d(G-C)], k1 = 13 X 10(6) M-1 s-1, and k-1 = 30 s-1. From the analysis of the kinetic amplitudes, the molar volume change, delta V0, of the intercalation was calculated. In the case of poly[d(A-T)], delta V0 = -15 mL/mol, and for poly[d(G-C)], delta V0 = -9 mL/mol; that is, for both polymers, intercalation is favored as the pressure is increased.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fluorescence Polarization Studies of the Binding of BMS 181176 to DNA

Abstract

The DNA binding of BMS 181176, an antitumor antibiotic derivative of rebeccamycin was characterized by DNA unwinding assays, as well as by fluorescence emission and polarization spectroscopic techniques. Unwinding and rewinding of supercoiled DNA was interpreted in terms of intercalation of BMS 181176 into DNA BMS 181176 shows an enhanced fluorescence emission upon binding to the AT sequence and no enhancement upon binding to the GC sequence. BMS 181176 appears to be a weaker binder to poly(dAdT).poly(dAdT) compared to doxorubicin and ethidium bromide. When bound to DNA, the rotational motion of BMS 181176 is substantially decreased as evident from the increase in fluorescence polarization. BMS 181176 exhibits a range of binding strengths depending on the DNA This is demonstrated by the Acridine Orange displacement assay using fluorescence polarization.     

Binding of platinum(II) intercalation reagents to deoxyribnonucleic acid. Dependence on base-pair composition, nature of the intercalator, and ionic strength.

The DNA binding of three platinum(II) intercalation reagents has been studied and found to depend upon base composition, the nature of the intercalator, and the ionic strength of the solvent medium. In 0.2 M NaCl, binding data for calf thymus DNA show the association constants to be approximately 10(4) M-1. The binding constants decrease in the order [(o-phen)Pt(en)]2+ greater than or equal to [(terpy)Pt(HET)]+ greater than [(bipy)Pt(en)]2+. The number of available intercalation sites for the doubly charged intercalators is only 70% of the number expected from the nearest-neighbor exclusion model. Binding of [(o-phen)Pt(en)]2+ and [(terpy)Pt(HET)]+ to various DNAs depends linearly on G.C content. Both reagents exhibit essentially the same degree of G.C specificity. Intercalative binding is a function of ionic strength. Increasing the salt concentration minimizes the importance of metallointercalator charge, and extrapolation to 1 M salt reveals the intercalative abilities, as reflected in binding constants, to be equivalent for [(terpy)Pt(HET)]+ and [o-phen)Pt(en)]2+ and about 1 order of magnitude less than that of ethidium.     

DNA Bifunctional intercalators. 2. Fluorescence properties and DNA binding interaction of an ethidium homodimer and an acridine ethidium heterodimer

An ethidium homodimer and acridine ethidium heterodimer have been synthesized (Gaugain, B., Barbet, J., Oberlin, R., Roques, B. P., & Le Pecq, J. B. (1978) Biochemistry 17 (preceding paper in this issue)). The binding of these molecules to DNA has been studied. We show that these dimers intercalate only one of their chromophores in DNA. At high salt concentration (Na+ greater than 1 M) only a single type of DNA-binding site exists. Binding affinity constants can then be measured directly using the Mc Ghee & Von Hippel treatment (Mc Ghee, J. D., & Von Hippel, P. H. (1974) J. Mol. Biol. 86, 469). In these conditions the dimers cover four base pairs when bound to DNA. Binding affinities have been deduced from competition experiments in 0.2 M Na+ and are in agreement with the extrapolated values determined from direct DNA-binding measurements at high ionic strength. As expected, the intrinsic binding constant of these dimers is considerably larger than the affinity of the monomer (ethidium dimer K = 2 X 10(8) M-1; ethidium bromide K = 1.5 X 10(5) M-1 in 0.2 M Na+). The fluorescence properties of these molecules have also been studied. The efficiency of the energy transfer from the acridine to the phenanthridinium chromophore, in the acridine ethidium heterodimer when bound to DNA, depends on the square of the AT base pair content. The large increase of fluorescence on binding to DNA combined with a high affinity constant for nucleic acid fluorescent probes. In particular, such molecules can be used in competition experiments to determine the DNA binding constant of ligands of high binding affinity such as bifunctional intercalators.     

DNA intercalation by quinacrine and methylene blue: a comparative binding and thermodynamic characterization study

There is compelling evidence that cellular DNA is the target of many anticancer agents. Consequently, elucidation of the molecular nature governing the interaction of small molecules to DNA is paramount to the progression of rational drug design strategies. In this study, we have compared the binding and thermodynamic aspects of two known DNA-binding agents, quinacrine (QNA) and methylene blue (MB), with calf thymus (CT) DNA. The study revealed noncooperative binding phenomena for both the drugs to DNA with an affinity one order higher for QNA compared to MB as observed from diverse techniques, but both bindings obeyed neighbor exclusion principle. The data of the salt dependence of QNA and MB from the plot of log K versus log [Na+] revealed a slope of 1.06 and 0.93 consistent with the values predicted by theories for the binding of monovalent cations, and have been analyzed for contributions from polyelectrolytic and nonpolyelectrolytic forces. The binding of both drugs was further characterized by strong stabilization of DNA against thermal strand separation in both optical melting and differential scanning calorimetry studies. The binding data analyzed from the thermal denaturation and from isothermal titration calorimetry (ITC) were in close proximity to those obtained from spectral titration data. ITC results revealed the binding to be exothermic and favored by both negative enthalpy and positive entropy changes. The heat capacity changes obtained from temperature dependence of enthalpy indicated -146 and -78 cal/(mol.K), respectively, for the binding of QNA and MB to CT DNA. Circular dichroism study further characterized the structural changes on DNA upon intercalation of these molecules. Molecular aspects of interaction of these molecules to DNA are discussed.     

抗菌肽BuforinⅡ衍生物与大肠杆菌基因组DNA的作用机制

【目的】研究抗菌肽BuforinⅡ的衍生物BF2-A/B与大肠杆菌基因组DNA的作用机制。【方法】琼脂糖电泳检测肽对DNA的断裂作用,凝胶阻滞实验研究肽与DNA的结合作用,圆二色谱考察结合肽后DNA结构的变化,荧光光谱分析肽与溴化乙锭竞争性嵌入DNA以及磷酸根对肽与DNA相互作用的影响。【结果】BF2-A/B不断裂基因组DNA而是结合DNA,使DNA双螺旋结构变得松散,削弱碱基对间的堆积作用,并取代EB,使EB-DNA复合体系荧光减弱。而PO43-的加入减弱了肽对DNA-EB荧光的淬灭作用。【结论】衍生肽与DNA的结合方式是先靠静电引力吸附到DNA磷酸基团上,随即插入双螺旋沟槽,嵌入碱基对间。BF2-B有更多的正电荷,更强的插入沟槽和嵌入碱基对的能力,使得其结合DNA的能力比BF2-A强。     

The interaction of plant alkaloids with DNA. II. Berberinium chloride.

The interaction of berberinium chloride with DNA has been investigated using spectrophotometry, viscometric titrations with sonicated and closed circular superhelical DNA, and flow polarized fluorescence. The binding results for berberinium were found to fit the neighbor exclusion model. The two viscometric titrations and flow polarized fluorescence results exclusion model. The two viscometric titrations and flow polarized fluorescence results also indicated that berberinium binds to DNA by intercalation. Titration of sonicated DNA with berberinium produced viscosity increases which were less than those obtained with quinacrine and the titration of superhelical DNA indicated a significantly smaller unwinding angle for intercalation of berberinium than for quinacrine. These results can be interpreted in terms of a model in which (i) berberinium is partially intercalated into the double helix, or (ii) the alkaloid is more completely intercalated into the double helix, but causes bending of the helix due to the slight nonplanarity of the berberinium ring system, or (iii) a combination of (i) and (22).     

A helicase assay based on the displacement of fluorescent, nucleic acid-binding ligands.

We have developed a new helicase assay that overcomes many limitations of other assays used to measure this activity. This continuous, kinetic assay is based on the displacement of fluorescent dyes from dsDNA upon DNA unwinding. These ligands exhibit significant fluorescence enhancement when bound to duplex nucleic acids and serve as the reporter molecules of DNA unwinding. We evaluated the potential of several dyes [acridine orange, ethidium bromide, ethidium homodimer, bis-benzimide (DAPI), Hoechst 33258 and thiazole orange] to function as suitable reporter molecules and demonstrate that the latter three dyes can be used to monitor the helicase activity of Escherichia coli RecBCD enzyme. Both the binding stoichiometry of RecBCD enzyme for the ends of duplex DNA and the apparent rate of unwinding are not significantly perturbed by two of these dyes. The effects of temperature and salt concentration on the rate of unwinding were also examined. We propose that this dye displacement assay can be readily adapted for use with other DNA helicases, with RNA helicases, and with other enzymes that act on nucleic acids.     

DNA binding properties of the marine sponge pigment fascaplysin

Association of fascaplysin with double-stranded calf thymus DNA was investigated by means of isothermal titration calorimetry, absorption spectroscopy, and circular dichroism. The UV spectroscopic data could be well interpreted in terms of a two-site model for the binding of fascaplysin to DNA revealing affinity constants of K1 = 2.5 x 10(6) M(-1) and K2 = 7.5 x 10(4) M(-1) (base pairs of DNA). Based on the typical change observed in the absorption and circular dichroism spectra, intercalation of fascaplysin is regarded as the major binding mode. The calorimetric titration curves showed an exothermic reaction which was exhausted at a 2:1 base pair/drug; ratio. This finding is in agreement with an intercalation model comprising nearest neighbor exclusion. In addition, significantly weaker non-intercalative DNA interactions can be observed at high drug concentration. By comparison of all these data with the binding behavior of known intercalating agents, it is concluded that fascaplysin intercalates into DNA.     

Interaction of noncompetitive inhibitors with the acetylcholine receptor. The site specificity and spectroscopic properties of ethidium binding

The spectroscopic properties and specificity of binding of a fluorescent quaternary amine, ethidium, with acetylcholine receptor-enriched membranes from Torpedo californica have been examined. Competition binding with [3H]phencyclidine in the presence of carbamylcholine showed that ethidium binds with high affinity to a noncompetitive inhibitor site (KD = 3.6 X 10(-7) M). However, in the presence of alpha-toxin, ethidium's affinity is substantially lower (KD approximately 1 X 10(-3) M). Ethidium was also found to enhance [3H]acetylcholine binding with a KD characteristic of ethidium binding to a high-affinity noncompetitive inhibitor site. These findings indicate that ethidium binds to an allosteric site which is regulated by agonist binding and can convert the agonist sites from low to high affinity. Fluorescence titrations of ethidium in the presence of carbamylcholine yielded a similar KD (2.5 X 10(-7) M) and showed an ethidium stoichiometry of one site/acetylcholine receptor monomer. Ethidium was completely displaced by noncompetitive inhibitors such as phencyclidine, histrionicotoxin, and dibucaine. The enhanced fluorescence lifetime of the bound species showed that the increased fluorescence intensity reflects a 13-fold increase in quantum yield for the complex compared to ethidium in buffer. Fractional dissociation of ethidium with phencyclidine produced a double-exponential fluorescence decay rate with lifetime components characteristic of ethidium free in solution and bound to the receptor. These data argue that the alterations in ethidium fluorescence elicited by other ligands is due to a change in the fraction of specifically bound ethidium rather than a change in quantum yield of a pre-existing ethidium-acetylcholine receptor complex. The extent of polarization indicates that bound ethidium is strongly immobilized. The magnitude of the quantum yield enhancement and the shifts of excitation and emission maxima of bound ethidium suggest that its binding site is within a hydrophobic domain with limited accessibility to the aqueous phase.     

Relaxation of chromatin structure induced by ethidium binding. Involvement of the intercalation process

In this paper we study the effects of the binding of ethidium on the structure of chromatin, using micrococcal nuclease as a structural probe. This binding induces two structural changes of chromatin either isolated or in the nuclei. (a) An unfolding of the overall structure which results in an activation of the rate of degradation by the nuclease. (b) A disorganisation of the core particle structure which has the effect of unwrapping the DNA from the histone core, this disruption can go on so far as to leave only 90 base pairs. By comparing the bindings of ethidium and tetramethylethidium, we conclude that the first type of structural change is due to an electrostatic effect and does not depend upon intercalation. On the other hand, the second one is due to the intercalation process and to the change of topological constraints on the DNA that such a process involves.     

Fluorescence correlation spectroscopy and photobleaching recovery of multiple binding reactions. II. FPR and FCS measurements at low and high DNA concentrations

The preceding paper develops the theory for the interpretation of fluorescence photobleaching recovery (FPR) measurements of multiple binding of a ligand to a multivalent substrate molecule. Based on a reasonable assumption about the mechanism of the photobleaching process, this analysis shows that the observed behavior of a multivalent system should be practically identical to that of a univalent binding system. This is in contrast to the expected and observed behavior of fluorescence correlation spectroscopy (FCS) measurments. Experimental FPR measurements of multivalent binding of ethidium bromide to DNA confirm these conclusions. The FCS and FPR measurements also reveal an apparently enhanced diffusion of ethidium at high DNA concentration. This enhancement might result from direct transfer of ethidium among DNA molecules.     

Structure of the complex between lac repressor headpiece and operator DNA from measurements of the orientation relaxation and the electric dichroism.

The complex between lac repressor headpiece and short rodlike DNA fragments containing the lac operator sequence is characterised by measurements of the rotation diffusion. Using the method of electric dichroism we measure the rotation relaxation and determine changes in the length of the DNA upon ligand binding with high accuracy. According to these measurements any change in the length of the operator DNA upon binding of the first two headpiece molecules remains below 1A; the electric dichroism also remains virtually unchanged. At high degrees of (unspecific) binding we observe an increase in the rotation relaxation time, which is attributed to an increase of the apparent mean radius of the complex. As a control of our procedure for the determination of length changes we use the intercalation of ethidium bromide and arrive at an increase of the DNA length per bound ethidium of 3.2A (at 3.4A rise per base pair). The results obtained for the headpiece operator complex are not consistent with models assuming large changes of the DNA structure or intercalation of tyrosine residues.     

Spectroscopic properties of oligonucleotides excised from the anticodon region of phenylalanine tRNA from yeast

Ultraviolet absorption and static fluorescence properties of hexanucleotide (Gm-A-A-Y-A-ψp) and a dodecanucleotide (A-Cm-U-Gm-A-A-Y-A-ψ-m⁵C-U-Gp) excised from the anticodon region of phenylalanine tRNA from yeast have been studied with respect to temperature, pH, ionic strength, and Mg²⁺ concentration. At low temperature these oligomers have a largely stacked structure. Only the melting data of the dodecanucleotide in absence of Mg²⁺ fit a two-state model. From the different melting behavior of the oligonucleotides after excision of base Y, a rodlike structure of the hexanucleotide produced by stacking interactions can be concluded. The Y fluorescence increase produced by Mg²⁺ has been used to evaluate the binding equilibria between Mg²⁺ and the oligonucleotides. One strong binding site per oligonucleotide and a greater number of weak binding sites have been found. The fluorescence of the free base Y is not influenced by Mg²⁺. The dodecanucleotide enhances the ethidium fluorescence to the same extent as tRNA^Phe and produces comparable shifts in the excitation and emission spectra. Therefore a double helical structure for this oligomer under the assay conditions is suggested. Only weak binding of ethidium to the hexanucleotide is observed, indicating that intercalation of the dye into its structure is not favored. The data show the decisive role of the nucleobase Y in maintaining a rigid stacked structure of the anticodon nucleotides. This structure is stabilized by high ionic strength, Mg²⁺, and ethidium.     

Interaction of ellipticine and an indolo[2,3b]-quinoxaline derivative with DNA and synthetic polynucleotides

The non-covalent DNA interaction of the anticancer drug ellipticine (Scheme I, 1a) as well as an indolo[2,3-b]-quinoxaline derivative (Scheme I, 3b) with a dimethylaminoethyl side chain has been studied by light absorption, linear dichroism (LD) and fluorescence. Compound 3b (Scheme I) has antitumorigenic as well as antiviral activity. Both compounds bind to DNA or synthetic polynucleotides such as poly(dA-dT).(dA-dT) and poly(dG-dC).(dG-dC) by intercalation. In contrast to ellipticine, compound 3b (Scheme I) exhibits a significant binding specificity for alternating AT sequences. Its fluorescence is strongly enhanced in AT sequences and quenched in GC sequences. Fluorescence titrations evaluated as Scatchard plots show that both ellipticine and compound 3b (Scheme I) bind to the nucleic acids according to a non-cooperative neighbor exclusion model.     

Characterization of ciprofloxacin binding to the linear single- and double-stranded DNA

The binding of ciprofloxacin to natural and synthetic polymeric DNAs was investigated at different solvent conditions using a combination of spectroscopic and hydrodynamic techniques. In 10 mM cacodylate buffer (pH 7.0) containing 108.6 mM Na(+), no sequence preferences in the interaction of ciprofloxacin with DNA was detected, while in 2 mM cacodylate buffer (pH 7.0) containing only 1.7 mM Na(+), a significant binding of ciprofloxacin to natural and synthetic linear double-stranded DNA was observed. At low ionic strength of solution, ciprofloxacin binding to DNA duplex containing alternating AT base pairs is accompanied by the largest enhancement in thermal stability (e.g. DeltaT(m) approximately 10 degrees C for poly[d(AT)].poly[d(AT)]), and the most pronounced red shift in the position of the maximum of the fluorescence emission spectrum (lambda(max)). Similar red shift in the position of lambda(max) is also observed for ciprofloxacin binding to dodecameric duplex containing five successive alternating AT base pairs in the row. On the other hand, ciprofloxacin binding to poly[d(GC)].poly[d(GC)], calf thymus DNA and dodecameric duplex containing a mixed sequence is accompanied by the largest fluorescence intensity quenching. Addition of NaCl does not completely displace ciprofloxacin bound to DNA, indicating the binding is not entirely electrostatic in origin. The intrinsic viscosity data suggest some degree of ciprofloxacin intercalation into duplex.     

Synthesis, characterization, and DNA binding studies of some mixed-ligand platinum(II) complexes of 1,10-phenanthroline and amino acids

A series of complexes of the type [Pt(phen)(AA)]+ (where AA is the anion of glycine, L-alanine, L-leucine, L-phenylalanine, L-tyrosine, or L-tryptophan) has been synthesized. These complexes have been characterized by electronic absorption, infrared, and 1H NMR spectroscopy. The interaction of these complexes with calf thymus DNA has been studied using fluorescence spectroscopy. They inhibit the intercalation of ethidium bromide in DNA by intercalative binding at low concentrations and show nonintercalative binding at higher concentrations.