Improved electrophoretic separation of supercoiled and relaxed DNA in the presence of ethidium bromide.

Supercoiled and relaxed DNA were resolved electrophoretically in the presence of 0.5 micrograms/ml ethidium bromide. Under these conditions the Gaussian distributions of topological isomers of both supercoiled and relaxed DNA migrated as discrete bands. The separation of these DNAs was optimized by varying the concentration of electrode buffer. Electrophoresis in the presence of 160 mM Tris-acetate, pH 8.3, 4 mM EDTA resulted in a 20-fold increase in the separation of relaxed and supercoiled DNA relative to electrophoresis in 40 mM Tris-acetate, pH 8.3, 1 mM EDTA.     

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.     

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.     

Reversible tenfod reduction in mitochondrial DNA content of human cells treated with ethidium bromide

Summary Cells of the human line VA₂-B in suspension culture have been treated with very low concentrations of ethidium bromide for the purpose of reducing the amount of mitochondrial DNA (mit-DNA) per cell. Cells maintained in the presence of 5 ng/ml ethidium bromide grew at a normal rate for three days; thereafter, their doubling time gradually increased to a stable value of about 60 h. In these cells, the rate of ³H thymidine incorporation into mit-DNA decreased very rapidly to 60% of the normal, and remained thereafter at this level, while the amount of mit-DNA per cell stabilized around a level of 70–80% of the control. In cells long-term treated with 5 ng/ml ethidium bromide, the rate of mitochondrial protein synthesis was about 35% of the normal, and the cytochrome c oxidase activity about 50% of the control. Cells treated with 20 ng/ml of the drug underwent 3–4 cell doublings at control rates, then gradually stopped growing, and eventually died. In these cells, the rate of incorporation of ³H thymidine into mit-DNA was reduced to 50% of the control value after 10 min treatment with ethidium bromide, and became barely detectable after three cell doublings. At this time, the cells had on the average less than 10% of the control amount of mit-DNA, the rate of mitochondrial protein synthesis was reduced to 3% of the normal, and the specific activities of cytochrome c oxidase and rutamycin-sensitive ATPase were less than 20% of the control values. In spite of these marked changes, the cells exhibited only a 20–30% loss in cell viability, as estimated by cloning efficiency, after three days of exposure to the drug. Cells treated with ethidium bromide at 20 ng/ml for three days, and then transferred to drug-free medium, recovered a near-to-normal growth rate and cloning efficiency and a near-to-normal rate of synthesis and amount of mit-DNA in about five days.     

A yeast mitochondrial deoxyribonuclease stimulated by ethidium bromide

Several DNase activities, with different substrate and pH requirements, have been identified in yeast mitochondria. One of them is active on double stranded DNA at neutral pH and stimulated by Ethidium Bromide and other DNA intercalating drugs. This activity could be responsible for the yeast mitochondrial DNA degradation induced during mutagenesis by Ethidium Bromide.     

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.     

Absence of ethidium bromide induced nicking and degradation of mitochondrial DNA in mouse L-cells.

The in vivo effects of ethidium bromide on the integrity of mitochondrial DNA have been studied in a mouse L-cell system in which this DNA may be nearly exclusively radiolabelled. This allows the detection of mitochondrial DNA in the presence of contaminating nuclear DNA and eliminates the need for extensive purification of mitochondria or the use of deoxyribonuclease. The mitochondrial DNA in treated cells rapidly attains a high negative superhelix density and is not substantially nickel or degraded over the course of several days.     

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+.     

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.     

Retention of cytoplasmic killer determinants in yeast cells after removal of mitochondrial DNA by ethidium bromide

Summary The killer character in yeast shows cytoplasmic inheritance. Killer cells were treated with ethidium bromide and their DNA subsequently examined by caesium chloride density gradient centrifugation. Under conditions in which more than 94% of detectable mitochondrial DNA is lost, more than 99% of the cells retain the killer phenotype. It is concluded that the killer genetic determinants are unlikely to be part of the mitochondrial genome.     

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.     

Nuclear and mitochondrial alterations in amebae exposed to ethidium bromide

Cultures of Amoeba proteus were exposed to ethidium bromide at concentrations ranging between 5 and 100 μg/ml for periods of up to 1 week. Samples of treated and control cells were prepared at intervals for electron microscopy. The main ultrastructural alterations were in nucleoli and in mitochondria. The nucleoli of treated cells increased in density and became spherical with more sharply defined margins than those of normal amebae. Many nucleoli contained electron-lucent regions or nucleolar vacuoles of varying size. The chromatin was unusually condensed in some amebae. Mitochondria developed a central electron-lucent region and accumulated a dense material in the matrix. Some cristae were abnormally dilated. The nuclear alterations occurred at least as early as the mitochondrial changes and were present even in cells exposed to the lower concentrations of inhibitor, in which mitochondrial changes were minimal.