Ethidium bromide enhancement of frameshift mutagenesis caused by photoactivatable ethidium analogs.

Ethidium azide analogs (3-amino-8-azido-ethidium monoazide and ethidium diazide) have been developed as photosensitive probes in order to analyze directly the reversible in vivo interactions of ethidium bromide. Our preliminary observations [11], relating the mutagenic potential of the monoazide analog of ethidium, have been extended and refined, using the highly purified ethidium azide analogs [5]. A number of physical-chemical studies indicate that the monoazide analog interaction with nucleic acids, prior to photolysis, resembles remarkably the interaction of the parent ethidium (unpublished). It was anticipated, therefore, that competition by ethidium for the ethidium monoazide mutagenic sites in Salmonella TA1538 would be observed when these drugs were used in combination. Previous results in fact showed a decreased production of frameshift mutants when ethidium bromide was added to the ethidium monoazide in the Ames assay [1]. However, more extensive investigations, reported here, have shown that this apparent competition was the result of neglecting the toxic effects of ethidium monoazide and its enhanced toxocity in the presence of ethidium bromide. Conversely, an enhancement of the azide mutagenesis and toxicity for both the mono- and diazide analogs was seen when ethidium bromide was used in combination with these analogs.     

Intracellular binding of ethidium studied by photoaffinity labeling in vivo.

The azide analog of 14C-labeled ethidium bromide was mixed with yeast cells and when photolyzed by visible light, formed covalent complexes with all yeast cell organelles. The 14C counts were found in DNA, RNA and protein of yeast subcellular fractions, illustrating the complexity of binding of a drug which appears highly specific in its actions.     

Intracellular binding of ethidium studied by photoaffinity labeling in vivo

The azide analog of ¹⁴C-labeled ethidium bromide was mixed with yeast cells and when photolyzed by visible light, formed covalent complexes with all yeast cell organelles. The ¹⁴C counts were found in DNA, RNA and protein of yeast subcellular fractions, illustrating the complexity of binding of a drug which appears highly specific in its actions.     

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.     

Production of frameshift mutations in salmonella by a light sensitive azide analog of ethidium

Frameshift mutations have been produced in specific repair-negative Salmonella tester strains by photoaffinity labeling technique using ethidium azide. Reversions requiring a +1 addition or a ?2 deletion were especially sensitive. Mutagenesis was reduced by the simultaneous addition of non-mutagenic ethidium bromide, and was prevented by photolysis of the azide prior to culture addition. Identical tester strains active in DNA excision repair were not mutagenized by the azide. These results are consistent with the interpretation that photolysis of the bound ethidium analog converts the drug from its noncovalent mode of binding (presumably intercalation) to a covalent complex with consequent production of frameshift mutations. Such photoaffinity labeling by drugs which bind to DNA not only confirms the importance of covalent drug attachment for frameshift mutagenesis, but also provides powerful techniques for studying the molecular details of a variety of genetic mechanisms.     

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.     

Energetic aspects of spore germination in filamentous fungi

The antifungal activity of substances interfering with the function and biogenesis of mitochondria was studied. Strict anaerobiosis, cyanide, azide, oligomycin, bongkrekic acid and ethidium bromide were found to prevent spore germination ofAspergillus niger andPenicillium italicum in liquid germination medium. The effect of azide, oligomycin and ethidium bromide was fungicidal. Cyanide and azide completely inhibited the incorporation of¹⁴C-leucine and¹⁴C-uracil into germinating conidia ofA. niger. Oligomycin and ethidium bromide reduced the extent of incorporation of both precursors in the first few hours of conidial germination and at later stages stopped it completely. The inhibition of both spore germination and macromolecules synthesis during the germination ofA. niger conidia were in relation to the specific inhibitory effect of the agents on respiratory activity of dormant conidia and mycelial cells. The results indicate that both the function of mitochondrial genetic and protein synthesizing systems and the function of oxidative phosphorylation are essential for normal spore germination and fungal growth.     

Petite induction in Saccharomyces cerevisiae by ethidium analogs. Action on mitochondrial genome

Petite induction of ethidium analogs was examined in both resting and growing yeast cells. All of the analogs used in these experiments were active in dividing cells of Saccharomyces cerevisiae; only the parent ethidium bromide was mutagenic under resting conditions. Incorporation of adenine into mitochondrial DNA appeared to be prevented completely by ethidium and partially inhibited by other analogs. Treatment of growing cells with analogs affected fragmentation of pre-existing DNA as seen by the loss of a mitochondrial antibiotic resistance marker. The rates of elimination of the marker were different; ethidium generated greater loss than the monoamino analogs (3-amino and 8-amino-); and the deaminated analog was least effective. However, in resting yeast the marker was partially eliminated only with treatment of the parent ethidium. The degradation of the mitochondrial DNA by exposure to ethidium compounds was confirmed by agarose gel electrophoresis. Electrophoretic patterns of the mitochondrial DNA treated with each of the analogs under growing conditions and only with ethidium under resting conditions showed degradation of the mitochondrial DNA.     

Monoazido analog of ethidium as a chromatin probe: Binding to DNA

Two photoaffinity analogs of ethidium, 8-azido-3-amino, and 3-azido-8-amino-5-ethyl-6-phenylphenanthridinium chloride, have been used to probe the structure of mammalian chromatin and its interactions with the ethidium moiety. The monoazido analogs were established as suitable probes by comparing their interactions with chromatin and pure DNA prepared from chromatin to those of the parent ethidium bromide. Scatchard analysis of the binding data determined from spectrophotometric titrations showed that the analogs interacted with both nucleic acids in a manner similar to the parent compound. The effect of chromatin proteins on the interaction of the ethidium moiety with intact chromatin was investigated directly. By exposing the noncovalent complex to visible light, the monoazido analog was attached covalently in its interaction sites within chromatin, and the amount of drug bound covalently to DNA was determined for both protein-free DNA and chromatin. Using saturating concentrations of drug, DNA within intact chromatin was found to be associated with only half as much drug as DNA extracted from its protein prior to drug exposure. The distribution of drug bound within chromatin was determined following the attachment of the monoazido analog (by photoactivation) to chromatin that had undergone limited nuclease digestion. Several distinct populations isolated by size fractionation and quantitative measurements revealed that (1) both the core particles and the spacer-containing particles contained bound drug, reflecting high-affinity binding sites; and (2) chromatin particles containing 150 DNA base pairs (putatively nucleosome core structures) contained less total bound drug at high drug concentrations than those particles having intact spacer DNA.     

Rapid purification of Ti plasmids from Agrobacterium by ethidium bromide treatment and phenol extraction

An efficient method is described for the purification of Ti plasmid DNA from Agro-bacterium. The procedure is based on the relative binding capacity of ethidium bromide to supercoiled plasmid DNA and linear DNA and on the high solubility of ethidium bromide in phenol. Following treatment with ethidium bromide, more than 87% of linear chromosomal DNA and most of the RNA was present in the phenol phase, while 91% of Ti plasmid DNA was recovered from the aqueous phase. The Ti plasmid DNA was sufficiently pure for restriction endonuclease analysis and cloning. The procedure is simple, fast and provides eight times higher yield than the standard isopycnic ultracentrifugation method.     

Interaction of 2‐Chloro‐N10‐Substituted Phenoxazine with DNA and Effect on DNA Melting

Five N¹⁰‐substituted phenoxazines having different R groups and –Cl substitution at C‐2 were found to bind to calf –thymus DNA and plasmid DNA with high affinity as seen from by UV and CD spectroscopy. The effect of phenoxazines on DNA were studied using DNA‐ethidium bromide complexes. Upon addition of phenoxazines, the ethidium bromide dissociated from the complex with DNA. The binding of phenoxazines to plasmid _PUC18 reduced ethidium bromide binding as seen from the agarose gel electrophoresis. Butyl, and propyl substituted phenoxazines were able to release more ethidium bromide compared with that of acetyl substitution. Addition of phenoxazines also enhanced melting temperature of DNA.     

Interaction of 2-chloro-N10-substituted phenoxazine with DNA and effect on DNA melting

Five N10-substituted phenoxazines having different R groups and -Cl substitution at C-2 were found to bind to calf -thymus DNA and plasmid DNA with high affinity as seen from by UV and CD spectroscopy. The effect of phenoxazines on DNA were studied using DNA-ethidium bromide complexes. Upon addition of phenoxazines, the ethidium bromide dissociated from the complex with DNA. The binding of phenoxazines to plasmid PUC18 reduced ethidium bromide binding as seen from the agarose gel electrophoresis. Butyl, and propyl substituted phenoxazines were able to release more ethidium bromide compared with that of acetyl substitution. Addition of phenoxazines also enhanced melting temperature of DNA.     

Circular dichroism studies of ethidium bromide binding to the isolated nucleolus.

Circular dichroism in the 300-360 nm region and fluorescence induced by intercaltating binding of ethidum bromide to both DNA and RNA components were studied in isolated HeLa nucleoli. Both DNA and RNA compoents contribute to the induced dichroic elliticity. Digestion of nucleoli by RNase or DNase shows that most of the induced ellipticity comes from the DNA component. In nucleoli with an RNA/DNA = 0.8/1.0 the RNA component gives only 20% of the total ellipticity when measured at an ethidium bromide/DNA = 0.25. Spectro-fluorometric titration shows that ethidium bromide intercalates mostly into DNA in nucleoli. Both circular dichroism and fluorescence studies indicate that both DNA and RNA components in isolated nucleoli are less accessible to intercalating binding by ethidium bromide when compared to purified nucleolar DNA, DNA in chromatin or purified ribosomal RNA. Circular dichroic measurements of intercalating binding of ethidium bromide to to nucleoli may be used to study changes in nucleoli under different physiological or pathological conditions.     

Selective inhibition of restriction endonuclease cleavage by DNA intercalators

The preferred dye binding sites and the microenvironment of known nucleotide sequences within mitochondrial and plasmid pBR322 DNA was probed in a gross fashion with restriction endonucleases. The intercalating dyes, ethidium bromide and propidium iodide, do not inhibit a given restriction endonuclease equally at all of the restriction sites within a DNA molecule. The selective inhibition may be explained, in part, by the potential B to Z conformation transition of DNA flanking the restriction site and by preferred dye binding sites. Propidium iodide was found to be a more potent inhibitor than ethidium bromide and the inhibition is independent of the type of cut made by the enzyme.     

Destruction of ethidium bromide in solution by ozonolysis

Ethidium bromide can be rapidly destroyed in aqueous solutions or in isoamyl alcohol by ozonolysis in the presence of H2O2 to give a mixture of organic acids. In a variety of buffers commonly used in recombinant DNA technology destruction of ethidium bromide was more than 99.9%. The yellow reaction mixture after ozonolysis was shown to be nonmutagenic. This method may be used in laboratories for the disposal of ethidium bromide wastes.     

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.     

Detection of A + T-rich DNA in gels by differential fluorescence

The fluorochrome Hoechst 33258 preferentially forms complexes with A + T-rich duplex DNA, whereas ethidium bromide binds nucleic acids independent of base composition. Both compounds can be conveniently used to visualize DNA fractionated by gel electrophoresis. Determination of fluorescence emission from Hoechst 33258-stained restriction fragments normalized to fluorescence derived from the same sample after ethidium bromide staining provides a measure of emission due to A + T content, and allows easy identification of A + T-rich restriction fragments. To demonstrate the utility of this procedure, an A + T map of bacteriophage lambda DNA was constructed and found to be comparable to similar maps derived by alternate techniques. Analysis of recombinant plasmid DNAs with established nucleotide sequences demonstrated that the A + T content of individual restriction fragments could be estimated to within an accuracy of 5%.     

Isolation of viral RNA using cesium chloride-ethidium bromide equilibrium sedimentation

The effect of ethidium bromide (EB) on the buoyant density of reovirus RNA during equilibrium sedimentation has been investigated. The addition of the dye ethidium bromide was found to reduce the buoyant density of reovirus RNA in a Cs₂SO₄ gradient by a value of 0.13 to 0.15 g/cc, and provided a separation limit of 0.10 g/cc relative to the ? of marker DNA. Ethidium bromide was found also to reduce the ? of reovirus RNA to allow this RNA to band on a CsCl gradient. The separation factor between DNA and RNA on a CsCl-EB gradient was found to be 0.23 g/cc, indicating this type of gradient to be highly effective for separating the two types of polynucleotides.     

Isolation and cell cycle analysis of temperature-sensitive mutants from chinese hamster cells

HeLa cell mitochondria were allowed to incorporate ³H-thymidine in a cell free system and the effect of ethidium bromide, cytosine arabinoside and cytosine arabinoside triphosphate on the labeling of mitochondrial DNA was studied. The labeled products, isolated by sedimentation velocity in CsCl-ethidium bromide two-step gradients, showed similar sedimentation profiles as in vivo labeled mtDNA. Cytosine arabinoside triphosphate and ethidium bromide strongly inhibited the labeling of mitochondrial DNA, whereas cytosine arabinoside appeared to be much less effective. Tritiated deoxycytidine was found to be incorporated by isolated mitochondria, whereas cytosine arabinoside was shown to enter the mitochondrial acid-soluble pool but not to be incorporated in acid-insoluble form. These results are in agreement with the previously reported findings of in vivo experiments.     

Dye titrations of covalently closed supercoiled DNA analyzed by agarose gel electrophoresis.

We have developed a rapid electrophoretic technique for performing ethidium bromide dye titrations in cylindrical 0.7% agarose gels. The technique was used to analyze the extent of supercoiling in circular covalently closed SV40, Co1E1, and pSC101 DNA. We have estimated the superhelical densities of SV40, Co1E1, and pSC101 DNA to be ?0.050, ?0.078, and ?0.085 respectively. The results obtained for native SV40 DNA correlate well with previously published values for the superhelical density of this DNA when these values are corrected to reflect a 26° duplex unwinding angle for ethidium bromide. Ethidium bromide concentrations sufficient to partially relax a supercoiled DNA allow the DNA to be resolved into a series of discrete bands in agarose gels. The distribution of bands represents a natural heterogeneity in the superhelical densities of the DNA molecules in the population.