Lerena W. Yielding

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.

Induction of cytoplasmically inherited respiration-deficient (‘petite’) mutants by photodynamic action of acridine compounds

All acridines used (acriflavine, proflavine, acridine orange and 3-azido-10-methylacridinium chloride) produced killing in yeast cells when activated with visible light. Acriflavine, proflavine and 3-azido-10-methylacridinium chloride, but not acridine orange, produced petite and sectored colonies. Both cell killing and petite induction by light activation of acriflavine resulted apparently from photodynamic action mediated by singlet oxygen (1O2) since the effect were prevented by either sodium azide or anaerobiosis. The biological effects of 3-azido-10-methylacridinium chloride, which was developed as a potential photoaffinity probe for studying the binding and biological effects of acridines, appeared to be due to a photodynamic action analogous to that of acriflavine. Sodium azide or anaerobiosis prevented the light-activated effects of 3-azido-10-methylacridinium chloride despite the fact that the initial chemical breakdown of the azido derivative induced by light was not affected. Cells suspended in D2O demonstrated an enhanced response to 3-azido-10-methylacridinium chloride with irradiation. These results indicate that singlet oxygen mediates the light-activated biological effects of both acriflavine and 3-azido-10-methylacridinium chloride.

Structure-function characterization of phenanthridinium compounds as mutagens in Salmonella

The mutagenic activity of some phenanthridinium compounds was examined by using Salmonella typhimurium strain TA98. Microsomal enzyme activation of the compounds was necessary for the detection of frameshift mutagenesis. Amino and/or azido functions at both R3 and R8 were structural requisites for significant mutagenic activity, although mutagenicity was severely reduced for the diazido analog. When an azido or amino group was substituted by hydrogen at either R3 or R8, mutagenic activities were minimal, and the deaminated compound (3,8-dihydro derivative) was not mutagenic. Propidium was only slightly more mutagenic than the monoamino and monoazido analogs. Relationships between mutagenic activity and chemical structure of phenanthridinium compounds are discussed.

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.

PETITE INDUCTION IN YEAST, Saccharomyces cerevisiae, BY PHOTOACTIVATION OF 3-A-ZIDO-6-A-MINO-10-M-ETHYLACRIDINIUM CHLORIDE

Abstract— The photoinduction of petite colonies and cell toxicity in non‐growing yeast, Saccharomyces cerevisiae, by 3‐a‐zido‐6‐a‐mino‐10‐m‐ethylacridinium chloride (AAMAC) has been examined. The results presented here indicate that mitochondrial DNA damage in resting yeast which occurs following irradiation of AAMAC‐treated cells for short time periods is probably mediated through a covalent adduct between AAMAC and DNA. Furthermore, the photoreaction which contributes to biological activity is dependent on the presence of oxygen. Pre‐irradiated AAMAC, which no longer exhibited the short‐term photo‐induction of biological effects showed a second biological activity. In this case longer irradiation times, e.g. 30 min, were required to induce petites for resting yeast. Again there was a strong dependence on the presence of oxygen. These results suggest that both processes may be effected through oxygen intermediates (photodynamic processes).

Histochemical applications of two phenanthridinium compounds.

The fluorescent compounds ethidium monoazide and ethidium bromide were found to react intensely with nucleic acids of fixed, paraffin embedded tissues of rat and mouse. For routine staining, 10(-5) M solutions of ethidium bromide and its monoazide analogue were virtually identical in their reactions. Fresh frozen sections of the tissues reacted in the same manner as fixed, paraffin embedded samples. Fluorescence of DNA and RNA in rat pancreas could be selectively abolished by taking advantage of the greater sensitivity of RNA to acid hydrolysis. Hydrolysis in aqueous solutions (1 N HCl at 55-60 C) abolished RNA fluorescence in 5 min, whereas 20 min or longer were required to destroy DNA fluorescence. DNA fluorescence was selectively abolished by 3 hr in 0.1 N HCl in anhydrous methanol while the RNA remained unaffected. Rat pancreas stained with the 10(-5) M ethidium compounds below pH 5.0 showed reduced RNA fluorescence, but the DNA continued to fluoresce brightly at pH 0.6. Reducing the pH of the staining solution to pH 1.0, therefore, was an additional method of selectively abolishing RNA fluorescence. Ethidium solutions in 5.0 M NaCl at pH 5.0 had little effect on DNA or RNA fluorescence. This new method of examining nucleic acids in fixed tissue samples opens new approaches to the histochemistry of these substances. The method also offers new possibilities for the study of mutagenic drug-DNA interactions.