Connection of ethidium bromide with single-stranded DNA

The interaction of ethidium bromide with single-stranded synthetic and natural polynucleotides at high temperatures (t = 70 degrees C) and low pH values (pH 3.0) was studied. The isotherms of adsorption of ethidium bromide on single-stranded DNA were obtained. Two modes of binding of single-stranded DNA, strong and weak, were revealed. The values of the corresponding constants of interaction of this ligand and the number of bases per one binding site were determined.     

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.     

Interaction of ethidium bromide with DNA. Optical and electrooptical study

The binding of ethidium bromide to DNA has been studied by various optical methods. From fluorescence polarization studies, and film, electric linear dichroism, and circular dichroism spectra, we propose assignments of the absorption bands of the dye, which are discussed in connection with wave-mechanical calculations recently reported. The optical activity induced in the dye absorption bands upon binding to DNA was attributed to various origins depending on the electronic transition considered. The visible absorption band displayed a circular dichroism due to the asymmetry of the binding site and independent of the amount of binding. The transition identified at 378 nm from the circular dichroism and electric dichroism observations was thought to be due to a magnetic-dipole transition. It remained constant with increasing amounts of dye bound. The main ultraviolet band showed circular dichroism characteristics corresponding to exciton interactions between dye molecules bound to neighboring sites. The electric dichroism observed for the strongly bound dye molecules indicated that the phenanthridinium ring of ethidium bromide was probably not perfectly parallel to the DNA base planes. When the amount of dye bound to DNA exceeded the maximum amount compatible with the exclusion of adjacent binding sites, the electric dichroism decreased owing to the appearance of externally bound dye molecules with no contribution to the dichroism. Sonicated DNA was used to study the lengthening of the DNA molecule upon complexation. Although the viscosity of the complexes increased with the amount of binding, the rotational diffusion coefficient measured by the electric birefringence relaxation was not detectably affected. The absence of variation in the electric birefringence with the binding indicated that the DNA base stacking remained unaltered.     

Interaction of the dye ethidium bromide with DNA containing guanine repeats.

DNA containing one or more copies of the motifs repeated in telomere sequences has unusual conformational properties. The isolated sequence from the protozoan Oxytricha, dT4G4 has the potential to form tetramers in the presence of sodium or potassium ions. We report here that these tetramers bind ethidium tightly, with an interaction that fulfills several criteria for an intercalative mechanism in the G sequence. By contrast, the 4-fold tandem repeat of this subunit, d(T4G4)4, does not interact specifically with ethidium in the presence of Na+. This difference might have a simple structural basis: the tetramer of dT4G4 forms a stack of four G-quartets in the presence of Na+ or K+, whereas the constraint imposed by the T4 "tethers" in the repeat d(T4G4)4 allows only two layers to form in the presence of Na+. In the presence of sufficient K+, the latter can partially form a four-layer G-quartet structure, which interacts with ethidium. This idea is supported by analysis of a "relaxed" sequence, dT4G4(T7G4)3, which allows formation of four G-quartets and binds ethidium in the presence of Na+ as well as K+. Ethidium (and intercalators generally) should thus be able to retard or inhibit the action of telomerase in the presence of K+.     

Study of complexes of ethidium bromide with DNA by differential pulse voltammetry

The interaction of ethidium bromide with calf thymus DNA was investigated by the method of differential pulse voltammetry. It was found that ethidium bromide binds with DNA in several ways. Corresponding values of the constants and the number of binding sites were determined. The intercalation, semi-intercalation, and electrostatic mechanisms of interaction were shown. The results obtained are in good agreement with the data obtained by spectroscopic (absorption and fluorimetric) methods.     

Molecular mechanical calculations on the interaction of ethidium cation with double-helical DNA

Molecular mechanical calculations were done on complexes of ethidium cation with various base-paired deoxydinucleoside monophosphates [(ApT)₂, (TpA)₂, (A₂ · T₂), (GpC)₂, (CpG)₂, and (G₂ · C₂)] and deoxyhexanucleoside pentaphosphates [(ATATAT)₂, (TATATA)₂, (A₆ · T₆), (GCGCGC)₂, (CGCGCG)₂, and G₆ · C₆]. Relative binding energies, sequence preferences, and conformational aspects of the intercalation complexes were studied. The most detailed models used (an all-atom force field) gave results in good agreement with previous calculations and experimental work. Less-sophisticated models did not perform as well.     

Interaction of ethidium bromide with DNA as studied by kinetic spectrophotometry.

The interaction of ethidium bromide (EB) with DNA has been investigated using the pulse radiolysis technique. In particular, the absolute rate constant for the reaction of hydrated electrons, generated by single pulses of high-energy electrons, with EB is shown to drop dramatically in the presence of DNA. This drop in diffusion-limited reactivity results from the interaction of EB with DNA, effectively immobilising it, thus lowering the reaction cross-section or probability. Analysis of the resulting kinetic spectrophotometric data shows that they are consistent with a reversible interaction of EB with DNA as described by the law of mass action. The Scatchard-type plots obtained are linear, and give quantitative information on the extent and degree of association, comparable with that obtained by more conventional methods. The potential of the pulse radiolysis technique for studying different types of interactions between small molecules and various biopolymers has been demonstrated.     

Renaturation of DNA in the presence of ethidium bromide

The rate of renaturation of T2 DNA has been studied as a fuction of ethidium bound per nucleotide of denatured DNA. The Binding constants and number of binding sites for ethidium have been determined by spectral titration for denatured DNA at 55, 65, and 75°C and for native DNA at 65°C in 0.4M Na⁺. The rate of renaturation of T2 DNA was found to be independentof ethidium binding up to 0.03 moles per mole of nucleotide. Above 0.03 moles, the rate drops off precipitously approaching zero at 0.08 and 0.06 moles bound ethidium per nucleotide at 65°C respectively. A study was also made of the use of bound ethidium fluorescence as a probe for monitoring DNA renaturation reactions.     

Photolytic binding of the monoazido analog of ethidium to yeast mitochondrial DNA: competition by ethidium.

The [14C]-labeled monoazido analog of ethidium, 3-amino-8-azido-5-ethyl-6-phenylphenanthridinium chloride, when mixed with yeast cells and photolyzed, produced covalent adducts with both nuclear and mitochondrial DNA via the light-generated nitrene. The binding efficiency was about 12 times higher in mitochondrial than nuclear DNA. Moreover, the parent ethidium bromide at a 5-fold excess was an effective competitor for the binding of the monoazide analog with mitochondrial DNA, but not with nuclear DNA.     

Thermodynamic analysis of complex formation of ethidium bromide with DNA in water solutions

A thermodynamic analysis of two types of binding of ethidium bromide with DNA: intercalation and binding to the outer surface of a biopolymer has been performed by spectrophotometry. It has been shown that the dominant contribution to the energy of external binding of the ligand to DNA is made by hydrophobic interactions, which lead to less negative values of enthalpy and entropy and more severe negative changes in the heat capacity of complex formation as compared with the intercalation type of binding.     

CD of ethidium bromide complexes with normal and electrophoretically anomalous DNA restriction fragments

The equilibrium binding of ethidium bromide (EB) to two small 147 base-pair (bp) DNA restriction fragments, which exhibit different mobilities in polyacrylamide gels, was investigated by CD. Two larger DNA restriction fragments and calf thymus DNA were also studied for comparison. Difference spectra were calculated by subtracting the spectrum of the pure DNA from the spectra of its DNA–EB complexes. The D/P ratios ranged from 0.03 to 1.0. The difference CD spectra of all fragments are characterized by bands with maxima near 310, 275, and 207 nm, and minima near 290, 253, 225, and 190 nm. The band near 310 nm, which has a shoulder at about 335 nm, has zero intensity at D/P ≤ 0.05, and rises to a plateau value, different for each fragment, at D/P ? 0.3 for large fragments (≥ 1400 bp), and D/P ～ 0.7 for the two small 147 bp fragments. The minimum near 290 nm is markedly blue shifted with increasing D/P, the wavelength of the extremum corresponding approximately to the wavelength of the uv absorption maximum of the DNA–EB complex. The negative amplitude of this band at D/P = 1.0 depends on the molecular weight of the DNA. The difference CD maximum near 275 nm is positive at low D/P ratios, increases and goes through a maximum at D/P = 0.06–0.1, and then becomes increasingly negative with increasing D/P. The amplitude of the negative ellipticity per added dye is constant at high D/P ratios, suggesting that the transition can be attributed to outside-bound EB molecules. The ellipticities at 310, 290, and 253 nm increase in absolute magnitude with increasing D/P at approximately the same rate, suggesting that all three bands are associated with the same optical and/or conformational transition. For the two small 147 bp fragments the fractional increases in amplitude of these bands parallel the fractional increase in length of the DNA upon binding EB, determined by electric birefringence measurements. The titration of the restriction fragments with EB was also followed by optical absorption. Two end points are observed, the first at a D/P ratio of ～ 0.1, reflecting the transition between intercalated and outside-bound dye molecules, and the second at D/P ? 1.0, the equivalence point of the titration.     

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.     

Covalent binding of ethidium azide analogs to Salmonella DNA in vivo: competition by ethidium bromide.

The photoreactive analogs of ethidium bromide (ethidium mono- and diazide) have been developed as drug probes to determine the actual molecular details of ethidium bromide interactions with DNA. In an effort to demonstrate that the analogs in fact mimic the parent ethidium, competition experiments were designed using ³H thymidine-labeled DNA in intact $\text{Salmonella}$ TA1538, which is reverted by the azide analogs. ¹⁴C-labeled ethidium azide analogs were used in combination with the non-labeled ethidium bromide. The results presented here demonstrate that the parent ethidium competes with the azide analogs as a DNA intercalating drug using CsCl density gradient ultracentrifugation.     

Interacalation of ethidium ion into DNA and RNA oligonucleotides

The thermodynamics of ethidium ion binding to the double strands formed by the ribooligonucleotides rCA₅G + rCU₅G and the analogous deoxyribo-oligonucleotides dCA₅G + dCT₅G were determined by monitoring the absorbance versus temperature at 260 and 283 nm at several concentrations of oligonucleotides and ethidium bromide. A maximum of three ethidium ions bind to the oligonucleotides, which is consistent with intercalation and nearest-neighbor exclusion. For the ribo-oligonucleotide the binding mechanism is complex. Either two sites (assumed to be the intercalation sites at the two ends of the oligonucleotide) bind more strongly by a factor of 140 than the third site, or all sites are identical, but there is strong anticooperativity on binding (cooperativity parameter, 0.1). In sharp contrast, the binding to the same sequence (with thymine substituted for uracil) in the deoxyribo-oligonucleotide showed all sites equivalent and no cooperativity. For the ribo-oligonucleotides the enthalpy for ethidium binding is ?14 kcal/mol. The equilibrium constants at 25°C depend on the model; either K = 6 × 10⁵M^?1 for the two strong sites (4 × 10³M^?1 for the weak site) or K = 2.5 × 10⁵M^?1 for the intrinsic constant of the anticooperative model. For the equivalent deoxyribo-oligonucleotide the enthalpy of binding is -9 kcal/mol and the equilibrium constant at 25°C is a factor of 10 smaller (K = 2.5 × 10⁴M^?1).