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

Mutagenic activities of azido analogues of amsacrine and other 9-anilinoacridines in Salmonella typhimurium and their enhancement by photoirradiation

Analogues of amsacrine and other 9-anilinoacridines, bearing azide groups at various positions, were tested for their mutagenic activity in five strains of Salmonella typhimurium, both before and after photoirradiation. Azido substitution at the 2- or 3-position of the acridine or the 1'-position of the aniline led to compounds which were active frameshift mutagens, as detected in strain TA1537. Photoirradiation enhanced both the mutagenicity and the cytotoxicity of the azido compounds. Analogues bearing two azido groups at either the 2,6- or 3,6-positions were less strongly mutagenic in the dark, and light activation led to a toxic but only weakly mutagenic product. The effects of photoirradiation were decreased by aniline ring substitution, and were essentially eliminated by additional methyl substitution in the acridine ring. Comparison of events in TA1537 and TA98 suggested that photoirradiation of the 2- or 3-azido compounds gave a product which was capable of forming covalent bonds with DNA. The azide-containing analogues readily formed single strand DNA breaks on irradiation in the presence of DNA, but the efficiency of this reaction varied considerably.

Photo-enhancement of the mutagenicity of 9-anilinoacridine derivatives related to the antitumour agent amsacrine

The frameshift mutagenicity of the DNA intercalating drug proflavine is known to be enhanced by photoirradiation of bacterial cultures. To determine whether this phenomenon was also present in acridine-derived antitumour drugs, cultures of Salmonella typhimurium were exposed to the antileukaemia agent amsacrine and the experimental agent N-[2-(dimethylamino)ethyl]acridine-4-carboxamide dihydrochloride (acridine carboxamide) in the presence or absence of visible light. A small increase in mutagenicity was observed with amsacrine but not with acridine carboxamide. A series of analogues of amsacrine were then tested, and a striking relationship was found between the minimum drug concentration for mutagenicity and DNA binding affinity. In each case, photoirradiation was associated with a small increase in mutagenicity. Each of the compounds showing the photo-enhancement effect was capable of reversible one-electron oxidation. It is suggested that this oxidation occurs in bacteria, and that the DNA binding constant of the resulting acridine radical species will increase because of the extra positive charge. This increased DNA binding would be sufficient to explain the photo-enhancement of mutagenicity of these drugs.

Photodynamic mutagenic action of acridine compounds on yeast Saccharomyces cerevisiae

The photodynamically produced mutagenicity and toxicity of 8 acridine compounds were compared in Saccharomyces cerevisiae under resting and growing conditions. Without irradiation none of the acridines induced respiratory-deficient ('petite') colonies, indicative of mitochondrial DNA damage, in resting cells; and only acriflavine and proflavine induced 'petites' in growing cells. Also, without irradiation none of the acridines were significantly toxic or mutagenic for nuclear DNA under resting or growing conditions. However, with irradiation, acriflavine, proflavine, acridine yellow and rivanol became effective 'petite'-inducing mutagens and highly toxic for resting cells, while acriflavine, proflavine, and acridine orange became effective nuclear mutagens for resting cells. Acridine, quinacrine and 9-aminoacridine were not at all biologically effective with irradiation for resting cells. The results presented here indicate that singlet oxygen is generated by a photodynamic mechanism when acriflavine is irradiated, and further, that acridine, quinacrine and 9-aminoacridine are ineffective photosensitizers, because they are incapable of generating singlet oxygen with irradiation.