Pulse fluorimetry study in polarized light of DNA-ethidium bromide complexes

In previous works, a quantitative analysis of the fluorescence anisotropy decay, based on a comparison of the experimental measurements with a Monte Carlo simulation of the excitation energy migration, has been shown to provide the value of the unwinding angle of the DNA helix, induced by an ethidium bromide (E.B.) molecule intercalation. In the present work some of the characteristics of the model used in the computation are reexamined: namely the influence of the direction of the E.B. electronic moment, and the influence of the dye distribution along the DNA helix are studied. The computations are compared with experimental results obtained with new experiments performed with calf thymus and micrococcus lysodeikticus DNA-E.B. complexes. It is found that the difference in base composition of these DNA does not influence the fluorescence properties of their E.B. complexes. Our study confirms the validity of the dye distribution obtained with the single adjacent excluded site principle. Reasonable values of the unwinding angle are obtained by assuming that the transition moment direction lies along the great axis of the E.B. molecule. The value of this unwinding angle is compared with other values proposed in the literature.     

Energy migration in the poly(ra-rU)-ethidium complex. determination of the unwinding angle of the polyribonucleic helix

The polarized fluorescence of the ethidium bromide (EB)-poly(rA-rU) complex has been studied by pulse fluorometry. As expected for a polynucleotide snowing one single kind of intercalation site, the decay of the whole emission is a single exponential (time constant 27 ns). The anisotropy decay is analysed as follows: (1) A brownian contribution having two correlation times, one of which characterizes local motions and the other a macromolecular motion. (2) A contribution due to transfers between EB molecules fixed to the same polynucleotide molecule, is analysed by a method analogous to the method used in previous work on EB-DNA complexes. That method consists in choosing a molecular model of the complex depending on geometrical parameters, and in simulating the energy migration on that model with a Monte Carlo calculation. Poly(rA-rU) is assumed here to adopt the structure A of RNA. Intercalated EB molecules modify the anale between two consecutive base pairs by δ. The angular position of the EB transition moment is defined by an angle φ. One finds that the angle φ is situated between 0° and 30°, which corresponds to a whole intercalation of the chroniophore as opposed to the semi-intercalation which has been proposed for certain dyes. The angle δ is negative; therefore there is an unwinding of the polyribonucleotide helix. Its absolute value is about 38°, sensibly greater than The value previously found for EB-DNA complexes.     

The use of fluorescence anisotropy decay of poly d(A-T) ethidium bromide complex to estimate the unwinding angle of the double helix.

We measured the fluorescence decay under polarized light, of ethidium bromide bound to the poly d(A-T) isolated from Cancer Pagurus. The decay of the whole fluorescence is a single exponential function revealing a good homogeneity of the binding sites. The anisotropy decay due to energy transfers between the ethidium bromide molecules bound to a same poly d(A-T) molecule has been analysed, with a Monte Carlo calculation. We found the dye unwinds the poly d(A-T) duplex by an angle of 17 degrees plus or minus 2 degrees. This result is in agreement with the value previously found in the case of calf thymus DNA-ethidium bromide complex, although the base compositions of the two nucleic acids are different.     

Fluorescence anisotropy decay of ethidium bound to chromatin

The fluorescence anisotropy decays of the chromatin ethidium complexes have been measured in solutions in which the dye was bound to the high affinity sites of the nucleosome DNA. Energy transfers between chromatin-bound ethidium molecules cause an increase of the anisotropy decay rate for much smaller values of the concentration ratio of dye to nucleotide than in the case of nacked DNA-ethidium complexes. This result implies that the high affinity sites are clustered on a short nucleosomal DNA segment. Quantitative analysis of the experimental data by computer simulations of the energy transfer process, shows that these sites are gathered on a single nucleosomal DNA segment, 28 base pairs long. Such a segment probably belongs to the nucleosome “linker”, contributing about half of it.     

Fluorescence anisotropy decay due to rotational brownian motion of ethidium intercalated in double strand DNA

The transient fluorescence of solutions of ethidium bromide . DNA complexes has been measured by pulse fluorimetry at different temperatures and in solvents containing various amounts of sucrose. The molar ratio of ethidium to nucleotides was low. Under these conditions the anisotropy decay was due to the Brownian motion of ethidium molecules intercalated in the double strand DNA molecules. This anisotropy decay could be described by a sum of 3 exponential terms, with correlation times 01, 02, 03 which were linear functions of the ratio of the solvent viscosity to the absolute temperature (n/T). The amplitude of the exponential term characterized by the shortest correlation time (01) has been found to depend on temperature while the ratio of the amplitude of the two other terms (characterized by 02 and 03) was independent of temperature. These results were interpreted as follows: 01 corresponds to a fast motion of the dye in its site. 02 and 03 describe a tortional motion of the ethidium bromide. DNA complex, involving several nucleotide pairs.     

Study of the DNA/ethidium bromide interactions on mica surface by atomic force microscope: influence of the surface friction

The influence of mica surface on DNA/ethidium bromide interactions is investigated by atomic force microscopy (AFM). We describe the diffusion mechanism of a DNA molecule on a mica surface by using a simple analytical model. It appears that the DNA diffusion on a mica surface is limited by the surface friction due to the counterion correlations between the divalent counterions condensed on both mica and DNA surfaces. We also study the structural changes of linear DNA adsorbed on mica upon ethidium bromide binding by AFM. It turns out that linear DNA molecules adsorbed on a mica surface are unable to relieve the topological constraint upon ethidium bromide binding. In particular, strongly adsorbed molecules tend to be highly entangled, while loosely bound DNA molecules appear more extended with very few crossovers. Adsorbed DNA molecules cannot move freely on the surface because of the surface friction. Therefore, the topological constraint increases due to the ethidium bromide binding. Moreover, we show that ethidium bromide has a lower affinity for strongly bound molecules due to the topological constraint induced by the surface friction.     

Studies of the Fluorophore Sempervirene and its Complexes with DNA

Evidence that the fluorophore sempervirene binds to nucleic acids is presented. The complexes were studied by fluorescence intensity, spectra, decay lifetime, and polarization methods. Both fluorescent and nonfluorescent complexes are formed. The sempervirene is rigidly fixed to DNA. If ethidium bromide and sempervirene are bound to DNA, energy can be transferred from sempervirene to ethidium. Sempervirene is taken up by mammalian cells and appears in the cytoplasm. This unusual new probe should be useful in molecular and cellular investigations.     

The degree of unwinding of the DNA helix by ethidium. I. Titration of twisted PM2 DNA molecules in alkaline cesium chloride density gradients

A series of covalently closed bacteriophage PM2 DNA samples with varying degrees of superhelicity were prepared in vitro. The amount of bound ethidium per DNA nueleotide needed for the removal of all superhelical turns, v_c⁰, was determined for each sample by a number of methods. In order to evaluate the unwinding angle for the binding of one ethidium molecule to a DNA double helix, the pH dependence of the buoyant densities in CsCI of these samples was examined. A new calibration relating the change in buoyant density of a DNA to the fraction of bases titrated has been obtained, by measuring the buoyant densities of a number of catenanes (interlocked rings) containing both single-stranded and double-stranded λ DNA rings, at a pH such that the single-stranded DNA is fully titrated while the double-stranded DNA is not titrated. This calibration was used to obtain the pH dependence of the fraction of DNA bases titrated for the phage PM2 DNAs with differing extents of supercoiling. A simple theoretical analysis shows that in a restricted pH range close to pH_m, the melting pH of the DNA in the absence of the topological constraint associated with covalently closed double-stranded DNAs, the difference in the fraction of bases titrated at a certain pH between two covalently closed DNAs with different degrees of superhelicity is directly proportional to the difference in the v_c⁰ values of the DNAs. The unwinding angle per bound ethidium molecule can be obtained from the proportionality constant. In this way, it is not necessary to know precisely the actual pH value for either DNA, pH_e, at which the DNA is titrated to the extent that it contains no superhelical turns. The conclusion of the theoretical analysis and the experimental results is that the binding of an ethidium molecule to a double-stranded DNA unwinds the DNA helix by an angle φ_e = 26 °. The uncertainty in this value is estimated to be less than 10%. The new value for φ_e is approximately a factor of two larger than the value 12 °, which has been in use in the past decade. In the earlier alkaline titration results for polyoma DNA (Vinograd et al., 1968), which had been interpreted as supporting the 12 ° value, the calculation of φ_e was critically dependent on knowing pH_e. It is believed that pH_e was underestimated in the earlier work, resulting in a low φ_e value. Since the previous value φ_e = 12 ° has been widely used in the determination of the number of superhelical turns for many DNAs, and in measurements on the angular alterations of the DNA helix by the binding of a variety of small and large molecules and by solvent and temperature changes, the new value φ_e = 26 ° requires proportional adjustments of many previous results.     

Fluorescence anisotropy decay of ethidium bound to nucleosome core particles. 2. The torsional motion of the DNA is highly constrained and sensitive to pH

The effects of pH on the torsional flexibility of DNA bound to nucleosome core particles were investigated by using time-resolved fluorescence anisotropy decays of intercalated ethidium. The decays were collected by using time-resolved single-photon counting and were fit to a model developed by J. M. Schurr [(1984) Chem. Phys. 84, 71-96] with a nonlinear least-squares-fitting algorithm developed for this purpose. As the torsional flexibility of DNA is affected by the presence of an intercalating dye, the decays were studied at different ethidium bromide to core particle binding ratios. Because we see large increases in DNA flexibility and in the rotational diffusion coefficient at binding ratios of 0.6 ethidium/core particle and above, we conclude that, under these conditions, the DNA begins to detach from the protein. At lower binding ratios, we observe only small changes in the anisotropy decay. The torsional parameters obtained are a function of N, the number of base pairs of DNA between points of attachment to the histone core. Only if N is greater than 30 base pairs is the torsional rigidity of DNA on a nucleosome core particle higher than that for DNA free in solution. Also, for reasonable values of N (less than 30), the friction felt by the DNA on a core particle is much higher than that felt by free DNA. This indicates that the region of the DNA to which the ethidium binds is highly constrained in its motions. pH changes nearly neutrality at moderate ionic strengths (100 mM) have a substantial effect on the fluorescence anisotropy decays, particularly at early times. These analyses indicated that the observed change on increasing pH can be attributed either to a loosening of the contacts between the DNA and the histone core (increasing N) or to a substantial relaxing of the torsional rigidity of the DNA.     

Effect of ligand binding on the buoyant density of DNA in Nycodenz gradients.

The effect of ligand binding upon the buoyant density of DNA in Nycodenz gradients has been studied using DNAs of differing base compositions. The effect of both intercalating ligands (ethidium bromide and proflavin) and non-intercalating ligands (distamycin A, DAPI and netropsin) has been studied. The binding of intercalating ligands to DNA has essentially no effect on the buoyant density of DNA in Nycodenz gradients. The non-intercalating ligands were found to increase the buoyant density of DNA in a base specific manner. The increase in buoyant density can be interpreted in terms of disruption of the hydration shell of the DNA molecule caused by the binding of the ligand along the minor groove of the DNA helix.     

Intercalation of ethidium bromide into a triple-stranded oligonucleotide.

We have examined the ability of a cationic planar chromophore, ethidium bromide, to intercalate into a short, defined triple helix. Using UV absorption, fluorescence spectroscopy and a gel retardation assay we demonstrate that ethidium bromide is able to bind to a triple helix with a lower affinity than to the corresponding duplex. Energy transfer from base triplets to ethidium shows that ethidium is intercalated into the triple helix. The spectroscopic characteristics of ethidium intercalated into a triplex are similar to those observed for intercalation into duplex DNA.     

A reexamination of the problem of resonance energy transfer between DNA intercalated chromophores using bisintercalating compounds.

The rate of energy transfer between DNA intercalated ethidium cations calculated by Paoletti and Le Pecq1 using the Forster theory differs from the measured one by a factor of twenty two, if the proper geometrical factors are taken into account. By changing some of the parameters used in the calculation, the discrepancy can be reduced but not eliminated. This led us to the study of other systems where experimental and calculated results can be more directly compared. The apparent rate of energy transfer between ethidium and one of its non fluorescent analogues and between various pairs of intercalated chromophores has been studied. The fluorescence anisotropy decay of acridine dimers in glycerol or bisintercalated in DNA has been measured. These studies show that the Forster theory of energy transfer does not apply to the case of identical chromophores when they are relatively close to each other.     

A photochemical method to map ethidium bromide binding sites on DNA: application to a bent DNA fragment

It is shown that, when irradiated in the visible, ethidium bromide (EB) engages in direct photochemistry with its DNA binding site. At the photochemical end point, an average of one single-strand break is produced per bound EB molecule in a reaction which also bleaches the dye chromophore. Using high-resolution electrophoresis, we have mapped the distribution of EB photocleavage sites on DNA, at one-base resolution. It is argued that because the photocleavage is stoichiometric, the resulting pattern is similar to, if not identical with, the local distribution of EB binding affinity. When interpreted in the context of the extensive thermodynamic and structural data which are available for EB, a binding distribution of that kind can be used to infer details of DNA structure variation within the underlying helix. As a first application of the method, we have used EB to probe the structure of a 265 bp fragment of DNA, which had been described as being bent as the result of a periodic array of oligo(A) segments [Kitchin et al. (1986) J. Biol. Chem. 261, 11302]. The EB mapping data provide evidence that the oligo(A) elements in this fragment assume a local secondary structure which is different than that assumed by isolated ApA nearest neighbors and that the ends of the oligo(A) elements comprise a junctional domain with EB binding properties which differ from those of the oligo(A) element or of random-sequence DNA.     

Rotational dynamics of curved DNA fragments studied by fluorescence polarization anisotropy

The rotational dynamics of short DNA fragments with or without intrinsic curvature were studied using time-resolved phase fluorimetry of intercalated ethidium with detection of the anisotropy. Parameters determined were the spinning diffusion coefficient of the DNA fragments about the long axis and the zero-time ethidium fluorescence anisotropy. We find a significant decrease in the spinning diffusion coefficient for all curved fragments compared to the straight controls. This decrease is likewise evident in rotational diffusion coefficients computed from DNA structures obtained by a curvature prediction program for these sequences. Using a hinged-cylinder model, we can identify the change in rotational diffusion coefficient with a permanent bend of 13-16 degrees per helix turn for the sequences studied. Moreover, for some of the curved fragments an increased flexibility has to be assumed in addition to the permanent bend in order to explain the data.     

Studies on amikhellin: I. Intercalative binding to double-stranded DNA

The present paper reports that amikhellin, a drug so far used as a coronary vasodilator, binds to double-stranded DNA by an intercalation process which does not depend upon DNA base composition. The binding to DNA was established by spectrophotometry, ultracentrifugation and competition with ethidium bromide. The parameters of the binding equilibrium were calculated by these two latter methods. Evidence for intercalation was obtained from the observation by viscosimetric experiments of the length increase of sonicated calf thymus DNA and of the untwisting of circular PM2 DNA. The unwinding angle was measured to be 6° per bound drug molecule.     

Theoretical Study of Ethidium Intercalation in Triple-Stranded DNA and at Triplex-Duplex Junctions

Abstract

The contribution of different factors in the interaction of ethidium intercalated into various sequences of a triple helix, or in the region of the junction between the double- and triple-stranded DNA has been studied by energy minimization. It is found that in the total energy of the ethidium - triple helix complexes, a particular electrostatic contribution emerges due to the presence of protonated cytosines in the triple helix. This parameter is determinant in the sequence-specificity of ethidium binding to the triple helix. The preferred intercalation sites of ethidium in the triple helix are proposed. The interaction of ethidium at the triplex-duplex junction, and its effects are also discussed. This study is aimed at searching for new drugs specific for the triple helix, or for the triplex-duplex junctions.     

Theoretical study of ethidium intercalation in triple-stranded DNA and at triplex-duplex junctions.

The contribution of different factors in the interaction of ethidium intercalated into various sequences of a triple helix, or in the region of the junction between the double- and triple-stranded DNA has been studied by energy minimization. It is found that in the total energy of the ethidium- triple helix complexes, a particular electrostatic contribution emerges due to the presence of protonated cytosines in the triple helix. This parameters is determinant in the sequence-specificity of ethidium binding to the triple helix. The preferred intercalation sites of ethidium in the triple helix are proposed. The interaction of ethidium at the triplex-duplex junction, and its effects are also discussed. This study is aimed at searching for new drugs specific for the triple helix, or for the triplex-duplex junctions.     

1H NMR study of an ethidium dimer poly(dA-dT) complex: evidence of a transition between bis and monointercalation

Comparative 1H NMR and optical studies of the interaction between poly(dA-dT), ethidium bromide (Et) and ethidium dimer (Et2) in 0.7 M NaCl are reported as a function of the temperature. Denaturation of the complexes followed at both polynucleotide and drug levels leads to a biphasic melting process for poly(dA-dT) complexed with ethidium dimer (t1/2 = 75 degrees C; 93 degrees C) but a monophasic one in poly(dA-dT): ethidium bromide complex (t1/2 = 74 degrees C). In both cases drug signals exhibit monophasic thermal dependence (Et = 81 degrees C; Et2 = 95 degrees C). Evidence is presented showing that the ethidium dimer bisintercalates into poly(dA-dT) in high salt, based on the observation that i) dimer and monomer ring protons exhibit similar upfield shifts upon DNA binding, ii) upfield shifts of DNA sugar protons are twice as large with the dimer than with ethidium bromide. Comparison between native DNA fraction and bound drug fraction indicates that ethidium covers, n = 2.5-3 base pairs. The dimer bisintercalates and covers, n = 5.7 base pairs when the helix fraction is high but as the number of available sites decreases the binding mode changes and the drug monointercalates (n = 2.9).