Synthesis, separation and characterization of the mono- and diazide analogs of ethidium bromide

Bifunctional cross-linking approaches for mass spectrometry-based investigation of nucleic acids and protein-nucleic acid assemblies

With the goal of expanding the very limited toolkit of cross-linking agents available for nucleic acids and their protein complexes, we evaluated the merits of a wide range of bifunctional agents that may be capable of reacting with the functional groups characteristic of these types of biopolymers. The survey specifically focused on the ability of test reagents to produce desirable inter-molecular conjugates, which could reveal the identity of interacting components and the position of mutual contacts, while also considering a series of practical criteria for their utilization as viable nucleic acid probes. The survey employed models consisting of DNA, RNA, and corresponding protein complexes to mimic as close as possible typical applications. Denaturing polyacrylamide gel electrophoresis (PAGE) and mass spectrometric (MS) analyses were implemented in concert to monitor the formation of the desired conjugates. In particular, the former was used as a rapid and inexpensive tool for the efficient evaluation of cross-linker activity under a broad range of experimental conditions. The latter was applied after preliminary rounds of reaction optimization to enable full-fledged product characterization and, more significantly, differentiation between mono-functional and intra- versus inter-molecular conjugates. This information provided the feedback necessary to further optimize reaction conditions and explain possible outcomes. Among the reagents tested in the study, platinum complexes and nitrogen mustards manifested the most favorable characteristics for practical cross-linking applications, whereas other compounds provided inferior yields, or produced rather unstable conjugates that did not survive the selected analytical conditions. The observed outcomes will help guide the selection of the most appropriate cross-linking reagent for a specific task, whereas the experimental conditions described here will provide an excellent starting point for approaching these types of applications. As a whole, the results of the survey clearly emphasize that finding a universal reagent, which may afford excellent performance with all types of nucleic acid substrates, will require extending the exploration beyond the traditional chemistries employed to modify the constitutive functional groups of these vital biopolymers.

Covalent attachment of ethidium to DNA results in enhanced topoisomerase II-mediated DNA cleavage

The classic DNA intercalator, ethidium, was used to probe the effects of (i) intercalation and (ii) covalent modification of the DNA on the catalytic activity of topoisomerase II. Ethidium bromide, which binds reversibly to DNA via intercalation, does not stimulate topoisomerase II-mediated DNA cleavage at concentrations up to 100 microM, indicating that the intercalative binding of this molecule to DNA is not sufficient to alter the activity of the enzyme. In contrast, covalent attachment of the photoreactive ethidium analog to DNA resulted in marked enhancement of topoisomerase II-mediated single- and double-stranded DNA cleavage. This increase in DNA cleavage was observed at very low drug binding densities (<1 drug per 10-80 base pairs) which correspond to nanomolar concentrations, as compared with other topoisomerase II poisons such as etoposide or m-AMSA which require micromolar concentrations to elicit comparable DNA cleavage levels. Over the past decade, topoisomerase II has been an important target for a variety of clinically relevant anticancer agents due to the abilities of these agents to convert this enzyme to a cellular toxin resulting in an increase in the levels of enzyme-mediated DNA breaks. Modification of DNA by covalently attaching a DNA-targeting intercalating agent (i.e., ethidium bromide) resulted in a marked shift of the cleavage/religation equilibrium of the enzyme toward the cleaved state "poison" topoisomerase II as observed by the enhancement in single- and double-stranded cleavage; thus, key insight was gained into the mechanism(s) through which DNA binding agents may influence the catalytic properties of topoisomerase II. These data demonstrate that conversion of a reversible ethidium-DNA complex to an irreversible adduct results in the transformation of an ineffective intercalating drug into a potent topoisomerase II-targeted agent. Finally, they provide support for the recently proposed "positional poisoning model" for the actions of DNA lesions and anticancer drugs on the type II enzyme.

Photoaffinity approaches to determining the sequence selectivities of DNA-small molecule interactions: actinomycin D and ethidium

The DNA photoaffinity ligands, 7-azidoactinomycin D and 8-azidoethidium, form DNA adducts that cause chain cleavage upon treatment with piperidine. Chemical DNA sequencing techniques were used to detect covalent binding. The relative preferences for modifications of all possible sites defined by a base pair step (e.g. GC) were determined within all quartet contexts such as (IGCJ). These preferences are described in terms of 'effective site occupations', which express the ability of a ligand to covalently modify some base in the binding site. Ideally, the effective site occupations measured for photoaffinity agents can also be related to site-specific, non-covalent association constants of the ligand. The sites most reactive with 7-azidoactinomycin D were those preferred for non-covalent binding of unsubstituted actinomycin D. GC sites were most reactive, but next-nearest neighbors exerted significant influences on reactivity. GC sites in 5'-(pyrimidine)GC(purine)-3' contexts, particularly TGCA, were most reactive, while reactivity was strongly suppressed for GC sites with a 5'-flanking G, or a 3'-flanking C. High reactivities were also observed for bases in the first (5') GG steps in TGGT, TGGG and TGGGT sequences recently shown to bind actinomycin D with high affinity. Pyrimidine-3',5'-purine steps and GG steps flanked by a T were most preferred by 8-azidoethidium, in agreement with the behavior of unsubstituted ethidium. The good correspondence between expected and observed covalent binding preferences of these two azide analogs demonstrates that photoaffinity labeling can identify highly preferred sites of non-covalent DNA binding by small molecules.

Use of drug-specific antibodies to identify ethidium adducts produced in Trypanosoma brucei by photoaffinity labeling

A photoreactive azido analog of the trypanocide ethidium bromide, 3-amino-8-azido-5-ethyl-6-phenylphenanthridinium chloride, attached covalently to calf thymus DNA (CT DNA) by photoaffinity labeling, was used to generate antibodies for the drug analog. The specificity of the antiserum was tested using enzyme-linked immunoadsorbant assays (ELISA) against immobilized antigen (photoaffinity labeled DNA) and by both the avidin-biotin peroxidase reaction and indirect immunofluorescence performed on smears of drug treated trypanosomes. The reaction of the antiserum with the covalently bound drug adduct was diminished effectively by prior incubation with an excess of ethidium monoazide, ethidium diazide, and ethidium bromide, and to a lesser extent by the DNA-ethidium complex, the diazide-DNA or RNA adduct, and the monoazide-RNA adduct. DNA which had been photoaffinity labeled with either the propidium or the acridine moiety did not react. The antiserum recognition of DNA photoaffinity labeled with ethidium monoazide was based on the substituted phenanthridinium ring system of the parent ethidium, as evidenced by competition binding studies involving the free monoazido analog (EA1), the diazido analog (EA2), and the parent compound, ethidium bromide (EB). This approach and the sensitivity it provides should prove useful for identifying the distribution and fate of covalently bound drugs resulting from antiparasitic drug treatment, and for studying their roles in antiparasitic action.

Inhibition of the B to Z transition in poly(dGdC).poly(dGdC) by covalent attachment of ethidium: equilibrium studies

The effects of covalent modification of poly(dGdC).poly(dGdC) and poly(dGm5dC).poly(dGm5dC) by ethidium monoazide (a photoreactive analogue of ethidium) on the salt-induced B to Z transition are examined. Earlier studies have shown ethidium monoazide to bind DNA (in the absence of light) in a manner identical to that of the parent ethidium bromide. Photolysis of the ethidium monoazide-DNA complex with visible light results in the covalent attachment of the photoreactive analogue to the DNA. This ability to form a covalent adduct was utilized to probe the effects of an intercalating irreversibly bound adduct on the salt-induced B to Z transition of the poly(dGdC).poly(dGdC) and poly(dGm5dC).poly(dGm5dC) polynucleotides. In the absence of drug, the salt-induced transition from the B to Z structure occurs in a highly cooperative manner. In contrast, this cooperativity is diminished as the concentration of covalently attached drug is increased. The degree of inhibition of the B to Z transition is quantitated as a function of the concentration of covalently attached drug. At a concentration of one drug bound per four base pairs for poly(dGdC).poly(dGdC) and seven base pairs for poly(dGm5dC).poly(dGm5dC), total inhibition of this transition is achieved. Lower concentrations of bound drug were effective in the partial inhibition of this transition. The effects of the covalently bound intercalator on the energetics of the B to Z transition were determined and demonstrated that the adduct is effective in locking the alternating copolymer in a right-handed conformation under high salt conditions.

Inhibition of the B to Z transition in poly(dGdC).poly(dGdC) by covalent attachment of ethidium: kinetic studies

The photoaffinity analogue ethidium monoazide was used to prepare samples of poly(dGdC).poly(dGdC) containing covalently attached ethidium. The effects of both noncovalently and covalently bound ethidium on the kinetics of the NaCl-induced B to Z transition in poly(dGdC).poly(dGdC) was examined using absorbance and fluorescence spectroscopy to monitor the reaction. Covalently and noncovalently attached ethidium were equal in the extent to which they reduce the rate of the B to Z transition. By using fluorescence to selectively monitor the fate of noncovalently bound ethidium over the course of the transition, we found that ethidium completely dissociates as the reaction proceeds, but at a rate that lags behind the conversion of the polymer to the Z form. These experiments provide evidence for the redistribution of noncovalently bound ethidium over the course of the B to Z transition, leading to the development of biphasic reaction kinetics. The observed kinetics suggest that the primary effect of both covalently and noncovalently bound ethidium is on the nucleation step of the B to Z transition. The reduction in the rate of the B to Z transition by noncovalently or covalently bound ethidium may be quantitatively explained as resulting from the reduced probability of finding a drug-free length of helix long enough for nucleation to occur. As necessary ancillary experiments, the defined length deoxyoligonucleotides (dGdC)4, (dGdC)5, and (dGdC)6 were synthesized and used in kinetic experiments designed to determine the nucleation length of the B to Z transition, which was found to be 6 bp. The activation energy of the B to Z transition was demonstrated to be independent of the amount of covalently bound ethidium and was found to be 21.2 +/- 1.1 kcal mol-1. Covalent attachment of ethidium was observed to increase the rate of the reverse Z to B transition, presumably by locking regions of the polymer into a right-handed conformation and thereby providing nucleation sites from which the Z to B conversion may propagate.

A fluorescence photobleaching study of the microsecond reorientational motions of DNA

We have conducted a polarized fluorescence photobleaching recovery (FPR) study of the rotational dynamics of ethidium azide labeled DNA. Polarized photobleaching experiments provide data on microsecond and millisecond molecular reorientation that complement the information available from nanosecond fluorescence depolarization studies. In polarized FPR experiments an anisotropic angular concentration of fluorophore is created by bleaching dye molecules in a preferred orientation with a short, intense pulse of polarized light. The sample is then weakly illuminated, and the temporal variation in the emitted fluorescence is monitored. The fluorescence signal will systematically change as molecules undergo post-bleach reorientation and the angular distribution of dye tends toward isotropy. We have observed that the time dependence of our microsecond FPR curves is also determined in part by nonrotational phenomena. To isolate the reorientational recovery we conduct our FPR experiments in two modes (called parallel and perpendicular) that differ only in the polarization of the bleaching light. A quotient function, R(t), is constructed from the data obtained in these two modes; the variation with time of this new quantity is governed solely by processes that are sensitive to the polarization of the incident light (e.g., molecular rotation). It is found experimentally that R(t) remains constant, as expected, for rotationally restricted DNA systems despite a temporal recovery in the parallel and perpendicular FPR curves. We also follow the dynamics of solutions of phage lambda DNA as revealed in the temporal dependence of R(t). This DNA system rotationally relaxes after approximately 100 microseconds and the dye/DNA complex reorients substantially during the 10-microseconds bleach period. Our FPR data are interpreted in terms of dynamic models of DNA motion.

Alkali lability and rapid initiation of excision repair following photoaffinity damage by ethidium azide

DNA damage and repair provoked by ethidium azide (EA) photoaffinity labeling in mouse leukemia cells was studied by measuring sedimentation properties of nucleoids in neutral sucrose gradients, and it was found that the strand opening step was faster than that which followed damage of cells by ultraviolet (UV) light. The two insults were compared at levels of damage which gave the same overall rates of repair synthesis in intact cells and which required the same length of time to complete repair, as judged by the restoration of supercoiling of the isolated nucleoids. In the case of UV, single-strand breaks in DNA were detectable at 30 min, maximum at 2 h, and the superhelical properties restored at 21 h. With photoaffinity labeling, single-strand breaks were prominent immediately, even when photolabeling of cells was done on ice, but restoration of DNA supercoiling still required 21 h. Photolabeling of isolated nucleoids or isolated viral DNA with EA failed to introduce DNA strand breaks. However, it was discovered that photoaffinity labeling of DNA with EA resulted in alkali labile sites shown by single strand breaks produced on alkaline sucrose sedimentation or by alkali exposure followed by sedimentation on neutral formamide gradients. These results suggest that the drug attachment sites should be identifiable by the location of such single strand breaks.

Production of frameshift mutations in Salmonella by phenanthridinium derivatives: enzymatic activation and photoaffinity labeling

The effect of metabolic activation on the mutagenic potential of some phenanthridinium compounds was examined in Salmonella typhimurium strains TA1538 and TA1978 . All of the compounds tested were mutagenic in TA1538, a DNA excision-repair-deficient strain, when metabolizing enzymes were included in the assay. Reversions were not detected when these compounds were examined under the same conditions in TA1978 , the isogenic strain of TA1538 proficient in DNA repair. The mutagenic activity of an azido analog of propidium iodide was also examined using photoactivation and enzymatic activation, and with both conditions, reversions were observed in TA1538 but not in TA1978 . Furthermore, the ranking of mutagenic activity of propidium azide relative to ethidium azide analogs was comparable for both types of activation. The evidence from several studies suggests that the structural requirements for mutagenic activity for this series of phenanthridinium compounds appear to be the same whether mutagenesis is induced via photoactivation or metabolic activation. The interaction with DNA resulting in covalent alteration of the DNA is implicated as the mutagenic mechanism whether the active species is generated by metabolic- or photo-activation.

Single-cell partition analysis--a direct fluorescence technique for examining ligand-macromolecule interactions

Single-cell partition analysis is described as a novel technique for examining ligand-macromolecule interactions. This procedure is a combination of the classical fluorescence titration technique and phase-partition techniques and allows three separate methods for calculating and comparing both free and bound drug concentrations. The value of this technique is demonstrated by the comparison of the binding properties of the potent antitumor antibiotic adriamycin and ethidium bromide to nucleic acids. Binding isotherms of both drugs were obtained at low r (concentration of bound drug per base pair) values, showing strikingly different results, thus allowing insight to be gained into the cooperative binding of these drugs to DNA.

Comparative binding of ethidium and three azido analogs to dinucleotides: affinity and intercalation geometry. A 1H NMR and visible spectroscopy study

Geometrical and thermodynamic information has been obtained from theoretical analysis of both visible and 1H-NMR spectroscopic binding isotherms of ethidium and three photoactivable derivatives (8-azido-ethidium, 3-azido-ethidium and 3,8-diazido-ethidium) to self-complementary ribodinucleosides. The following results have been obtained. 1. Interaction with pyrimidine(3-5')purine sequences is well accounted for by multicomponent equilibria involving self-association of the dyes in oligomers, formation of 1:1 and 2:1 (nucleoside:dye) complexes. This model provided evidence for intercalation of all dyes, though with weaker affinity in the case of diazido-ethidium (2 X 10(6) M-2 vs 6 X 10(7) M-2). Moreover 3-azido-ethidium was shown to intercalate into cytidylyl(3'-5')guanosine (CpG) with its phenyl group lying in the major groove of the minihelix. This geometry is inverted with respect to that of all other compounds. It should be emphasized that visible and 1H-NMR techniques independently provided similar results (intercalation, affinity constants) therefore supporting this stepwise model. 2. Interaction of all dyes with purine(3'-5')pyrimidine sequences is not intercalative, even at low temperature (4 degrees C), but is well described by self-association of the dyes and formation of 1:1 (nucleoside:dye) complexes. Regarding the reversible DNA intercalation process, these studies show that 8-azido-ethidium is the only photoactivatable derivative which behaves exactly as ethidium. Therefore 8-azido-ethidium can be used as a covalent probe to investigate the DNA-related cytotoxic effects of ethidium.

Torsional motion and elasticity of the deoxyribonucleic acid double helix and its nucleosomal complexes

Torsional thermal oscillations of the DNA double helix within the electron paramagnetic resonance (EPR) time scale (10(-10)-10(-3) s) as indicated by a rigid, intercalating probe are much smaller in the spacer segment between nucleosomes in chromatin than in long, free DNA molecules. Still smaller DNA oscillation is indicated in intact nuclei and yet smaller if the nuclei have been treated with glutaraldehyde. The values of EPR measurements are not affected by the loading density of probe. If the probe were capable of substantial oscillations or movement different from that of the helix, those oscillations would be expected to dominate the spectra when movement of the helix is restrained. We conclude that the correlation time for torsional movement of free DNA inferred from EPR spectra is characteristic of the double helix and that there is no significant independent motion of the probe. The correlation time for the DNA double helix in molecules longer than approximately 500 base pairs is close to 30 ns, corresponding to an elastic constant of 1.5 X 10(-19) ergs cm for deformation by twisting. The motions observed in chromatin are consistent with a model in which spheres of 50-60-A radius are connected by simple elastic rods with the length of spacer DNA and the same elastic constant. The spin-labeled ethidium probe has been characterized in detail by nuclear magnetic resonance, infrared, fluorescence, and visible light spectroscopy. The binding equilibria are consistent with the hypothesis that strongly immobilized probe molecules are preferentially bound to spacer DNA.

Comparison of petite induction in yeast by acridines, ethidium and their photoaffinity probes

The production of petite mutations by different acridine analogs was studied in Saccharomyces cerevisiae. Compounds with amino substituents at the 2 and 3 positions of the acridine nucleus and methylation at position 10 were effective for petite induction in growing cells but not in resting cells, while those with chloro, nitro and methoxy substituents were not effective in either resting or growing cells. Photosensitive azido derivatives of the acridines were tested to evaluate the role of covalent drug attachment for mutagenesis in resting cells. Photolysis of resting cells with 9-axido, 3-azido-6-amino-, 9-azido-10-methyl-, or 3-azido-6-amino-10-methyl-acridine was highly toxic. 3-Azido-6-amino-acridine, and especially 3-azido-10-methyl-, and 3-azido-6-amino-10-methyl-acridine, were effective petite inducers in resting cells. Thus, the photosensitive (azido) group at position 9 produced only cell killing while the azido group at position 3 and/or 6 led to effective petite induction in resting cells. In contrast, petite induction was observed only for growing cells, for dark control experiments with these compounds or with the monoazide precursor compounds.

Azido analogs of acridine: photoaffinity probes for frameshift mutagenesis in Salmonella typhimurium

In order to identify a photoaffinity probe for 9-aminoacridine frameshift mutagenesis, 20 azido analogs of acridine were synthesized and tested in Ames' Salmonella tester strains, TA1535, TA1537, TA1538 and their corresponding excision-repair-coefficient strains TA1975, TA1977 and TA1978, to determine their mutagenicity and toxicity relative to 9-aminoacridine. The substituent-mutagenicity patterns observed for these compounds agree very well with those obtained previously for non-azidoacridines. The results presented here show that the 2-azido-analog of 9-aminoacridine demonstrates biological activity similar to 9-aminoacridine prior to photolytic activation. With light activation, however, the 9-amino-2-azido derivative becomes more effective at producing frameshift mutations characteristic of 9-aminoacridine. Furthermore, this photolytic enhancement of mutagenesis appears to be due to the repairable lesion suggesting that covalent attachment of the drug occurs.

Induction of petite "mutants" in an ethidium-resistant strain of Saccharomyces cerevisiae by photoaffinity labeling. Distinction between early and late steps

A strain of Saccharomyces cerevisiae (MH41-7B/011) was resistant to petite induction by ethidium bromide at 30 degrees, but was sensitive to induction by photolabeling with ethidium monoazide. These results suggested a defect in the mutant in metabolic activation of ethidium to account for its resistance. Synchronized cultures of both the mutant and the normal parent strains showed a substantial reduction in petite response to photolabeling in stationary phase cells which could not be accounted for by changes in cell penetration of the drug. The use of photolabeling with normal and mutant cells suggested that petite induction can be divided into early and late steps.

Binding of ethidium monoazide to the chromatin in human lymphocytes

The azide analog of [14C]ethidium bromide was mixed with lymphocytes and photolyzed with visible light. The distribution of azide in the chromatin fraction was found to be 55% in DNA, 28% in protein and 16% in RNA. Label in the DNA portion was found to be almost exclusively in the region digestible with micrococcal nuclease. The parent compound, ethidium bromide, competed with azide for binding sites, illustrating that the azide analog mimics the action of ethidium bromide.

Structure-function characterization for ethidium photoaffinity labels as mutagens in Salmonella

The development of photoaffinity probes to characterize the binding process and subsequent biological activity of a drug has recently been emphasized by the synthesis of two ethidium azide analogs. The initial finding showed that one of the azido analogs, the 8-azido-3-amino derivative, was at least 40-fold more mutagenic and toxic in Salmonella tester strain TA1538 than the other analog, the 3.8-diazido derivative. These observations suggested the need to examine the structural requirements of ethidium photoaffinity labels for frameshift mutagenic activity in Salmonella. Thus, the isomer of the monoazide, the 3-azido-8-amino derivative, and two deaminated monoazide derivatives were synthesized and all of the ethidium analogs were screened in two Salmonella frameshift tester strains, TA1537 and TA1538, and in their excision-repair positive isogenic strains. The results presented in this paper demonstrate that two substituents are needed to produce significant mutagenicity and toxicity by the compound. One substituent, usually the amino group, is required for mutagenic activity, perhaps by orienting the phenanthridinium ring into its mutagenic configuration. The other substituent, the azido group, is required for covalent attachment, a requisite for mutagenic activity. Thus, photoaffinity labeling has provided a means of comparing structure with mutagenic activity for ethidium compounds.

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.

Deletion of mitochondrial genetic markers in yeast by ethidium and the photoaffinity probe, ethidium azide

Induction of petite (cytoplasmic-respiration-deficient, rho-,rho-) mutations in yeast and deletion of mitochondrial drug-resistance genetic markers were compared after after treatment with ethidium and the corresponding photoaffinity probe, ethidium azide. Deletion of mitochondrial drug-resistance markers for chloramphenicol, erythromycin and oligomycin in these petite mutants was observed during prolonged treatment times with ethidium and with ethidium azide in the dark. A similar loss of drug-resistance markers was also observed in petites produced by photolytic treatment with the azide analogue, although the rate of loss appeared to be somewhat less. These results confirmed the usefulness of photoaffinity labeling with ethidium monoazide for studies of mitochondrial mutations.

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.

Spectroscopic properties of ethidium monoazide: a fluorescent photoaffinity label for nucleic acids

The non-covalent binding of ethidium monoazide to nucleic acids is entirely analogous to that of ethidium (binding constant approximately 2-3 X 10(5) M). The ethidium monoazide can be photochemically covalently linked to nucleic acids in high yield, up to 75%, by long wavelength light. The fluorescence of ethidium monoazide and ethidium crosslinked to nucleic acids show the same environmental sensitivity as does the fluorescence of ethidium. These properties of ethidium monoazide indicate its use as a fluorescent photoaffinity label for nucleic acids. Ethidium diazide can be photochemically linked to nucleic acids but appears to have properties substantially different from those of ethidium.

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.

Induction of respiratory deficient mutants in Saccharomyces cerevisiae by mono- and diazido analogs of ethidium

Mono- and diazido analogs of ethidium when photolyzed with yeast cells were highly effective in inducing respiratory deficient (RD) mutants. The monoazide was more mutagenic, though slightly less photosensitive, and under the concentrations and conditions used, both required photolysis to be significantly mutagenic. Ethidium bromide (EB) competed with either its mono- or diazide analog for RD induction when applied before, but not after, the photolysis step. This suggested that the initial mutagenic binding sites for azides were identical with those of EB. There was no self-rescue or recovery in azide mutagenesis in contrast to EB. Furthermore, recovery from azide mutagenesis could not be provoked by EB. This confirmed a simple competition between binding of EB and its azide analogs to account for the prevention by EB of the azide induced mutations.