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.     

Effect of Deoxyribonucleic Acid Ligands on Deoxyribonucleases and Deoxyribonucleic Acid Polymerase I of Escherichia coli K-12

Endonuclease I, exonuclease I, and exonuclease II-deoxyribonucleic acid (DNA) polymerase I activities are not vital functions in Escherichia coli, although the latter two enzymes have been indirectly shown to be involved in DNA repair processes. Acridines such as acridine orange and proflavine interfere with repair in vivo, and we find that such compounds inhibit the in vitro activity of exonuclease I and DNA polymerase I but stimulate endonuclease I activity and hydrolysis of p-nitrophenyl thymidine-5′-phosphate by exonuclease II. Another acridine, 10-methylacridinium chloride, binds strongly to DNA but is relatively inert both in vivo and in vitro. These experiments suggest that acridines affect enzyme activity by interacting with the enzyme directly as well as with DNA. Resulting conformational changes in the DNA-dependent enzymes might explain why similar acridines which form similar DNA complexes have such a wide range of physiological effects. Differential sensitivity of exonuclease I and DNA polymerase I to acridine inhibition relative to other DNA-dependent enzymes may contribute to the acridine sensitivity of DNA repair.     

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-azido, 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.     

Factors influencing transduction of genetic determinants of penicillinase activity and pathogenicity in staphylococcus aureua. II. Antiphage activity of acridine derivatives]

Acridine dyes examined earlier (acrichine, acridine orange, proflavine and rivanol) and newly-synthesized preparations (acridines No. No. 37--40) were studied in the capacity of nonspecific agents influencing the lytic cycle in development of staphylococcus phages. Acrichine and acridine No. 37 failed to prevent lysis of the indicator staphylococcus cultures (strains 16/160 and 8325) by bacteriophages; proflavine, rivanol, acridines No. No. 39--40 produced a marked inhibitory effect; acridine orange and acridine No. 38 inhibited the staphylococcus lysis completely. Some preparations could be used to investigate the transduction phenomenon.     

Acridine Binding by Escherichia coli: pH Dependency and Strain Differences

Acridine dye binding by cells of Escherichia coli has been characterized in terms of a number of parameters. There is a temperature-dependent, readily reversible binding of acriflavine which occurs to a greater extent with acridine-sensitive mutants of E. coli K-12 than with wild-type E. coli B or K-12. There is an essentially irreversible internal binding of acriflavine which occurs when the cellular permeability barriers are destroyed or altered by heat-treatment, elevated pH, treatment with toluene or phenethyl alcohol, or infection with bacteriophage T2 or T4. Both the reversible and the irreversible binding of acridines occurs more effectively with the acridine dye acriflavine than with the related dye proflavine, and still less effectively with 9-aminoacridine and quinacrine. These properties of acridine binding can be correlated with various inhibitory effects of the dyes on the cells.     

The induction of chromosomal aberrations and SCE by visible light in combination with dyes. I. The effect of hypoxia during light exposure in unsynchronized Chinese hamster ovary cells, sensitized with acridines

A comparison has been made between the ability of different acridine compounds to act as sensitizers for visible light (400-700 nm) induced chromosomal aberrations and sister-chromatid exchanges (SCE) in unsynchronized Chinese hamster ovary (CHO) cells. Cells were treated for 20 min with acridines (0.1-5.0 microgram/ml), washed free of excess dye and subsequently exposed to visible light (2 x 40 W/8 W m-2) either in air or in nitrogen for 5-15 min. The 4 acridines tested, proved to be effective sensitizers for the induction of both chromosomal aberrations and SCE by visible light. The most pronounced effect was observed when the light exposure of the fluorochrome-pretreated cells was performed in air. Hypoxic conditions during light exposure reduced the effect dramatically, especially in the case of induced chromosomal aberrations. The order of efficiency for the induction of both chromosomal aberrations and SCE was acridine orange greater than acridine yellow greater than proflavine greater than 3,6-diamino-10-methylacridine. The results are discussed in terms of S-independent versus S-dependent mechanisms for inducing chromosomal alterations and the potential involvement of oxygen-derived free radicals in this process.     

The influence of acridine dyes and caffeine on recovery from ultraviolet damage in Eudorina elegans.

Caffeine and the acridine dyes, acridine orange and acriflavine, were used to examine the repair potential in Eudorina elegans following ultraviolet irradiation. Acridines blocked photoreactivation primarily as a result of absorption of photoreactivating wavelengths, but acridines did not influence dark survival. Therefore, an acridine-sensitive excision-resynthesis-repair process is absent in Eudorina. Caffeine decreased both dark and light survival, the latter only after relatively high doses of ultraviolet light were used for inactivation. The caffeine-sensitive repair process appears to function most actively when the organisms are engaged in DNA synthesis, indicating that a postreplication-repair system exists in Eudorina. However, the data suggest that a repair system not associated with the DNA synthetic phases may also exist.     

Production of extracellular plasmocoagulase in staphylococcus aureus exposed to 3,6-diaminoacridines]

A modified quantitative nephelometric method was used. It was shown that production of extracellular plasmocoagulase was depressed in the development of acridine-sensitive and acridine-resistant cultures of Staph. aureus in the fluid nutrient medium containing 3,6-diaminoacridines: acriflavine, proflavine, acridine yellow, acridine orange, acridine No. 40 and acridine No. 56; 3,6-diaminoacridines failed to lead to noncompetitive inhibition of staphylococcus plasmocoagulase. A disturbance of the regulation of the enzyme exit into the external environment can serve as the cause of depression of the extracellular plasmocoagulase production by Staph. aureus.     

Inhibition of Pyrimidine Dimer Formation in DNA by Cationic Molecules: Role of Energy Transfer

In addition to the acridine dyes, acridine orange and proflavine, we find that three other cationic molecules which bind to DNA-ethidium bromide, chloroquine, and methyl green-inhibit the production of cyclobutyl pyrimidine dimers by ultraviolet radiation. Intercalation is not necessary for dimer inhibition. The long range nature of the inhibition implies that energy transfer is responsible. The transfer is between the lowest excited singlet state of DNA and the acceptor singlet, and seems to involve the F?rster mechanism.     

Genetic effects of acridine compounds.

Acridines and a very large number of acridine derivatives are used in enormous quantities both in medicine and industry. The mutagenic action of these compounds has been demonstrated in a wide variety of organisms and is known to occur both in the dark as well as in the presence of light (photodynamic action). At the molecular level, acridines have been shown to cause frameshift mutations of both the addition and deletion types, a characteristic which has been of tremendous help in elucidating the nature of the genetic code. These and various other biological effects of acridines, such as inhibition of DNA repair, curing of plasmids and cell-growth inhibition, are examined in this review.     

Selective permeabilization of lipid membranes by photodynamic action via formation of hydrophobic defects or pre-pores

To gain insight into mechanisms of photodynamic modification of biological membranes, we studied an impact of visible light in combination with a photosensitizer on translocation of various substances across artificial (vesicular and planar) bilayer lipid membranes (BLMs). Along with induction of carboxyfluorescein leakage from liposomes, pronounced stimulation of lipid flip-flop between the two monolayers was found after photosensitization, both processes being prevented by the singlet oxygen quencher sodium azide. On the contrary, no enhancement of potassium chloride efflux from liposomes was detected by conductometry under these conditions. Illumination of planar BLMs in the presence of a photosensitizer led to a marked increase in membrane permeability to amphiphilic 2-n-octylmalonic acid, but practically no change in the permeability to ammonia, which agreed with selective character of the photosensitized leakage of fluorescent dyes from liposomes (Pashkovskaya et al., Langmuir, 2010). Thus, the effect on transbilayer movement of molecules elicited by the photodynamic treatment substantially depended on the kind of translocated species, in particular, on their lipophilicity. Based on similarity with results of previous electroporation studies, we hypothesized about photodynamic induction of "pre-pores" or "hydrophobic defects" permeable to amphiphilic compounds and less permeable to hydrophilic substances and inorganic ions.     

A theoretical study of acriflavin-DNA binding

A theoretical study of binding behaviour of acriflavin, a well-known mutagen, with DNA base pairs such as AT, GC, TA and CG has been performed using CNDO/2 method to compute net atomic charges and dipoles located at various centres in acriflavine as well as base pairs. Acriflavine-DNA base pair interactions have been evaluated using second order perturbation method with multicentered multipole approximation. Only minimum energy configurations have been reported. Results have been discussed with a view to obtain a comparative behaviour of other similar dyes like proflavine and acridine orange.     

Fluorescence decay and quantum yield characteristics of acridine orange and proflavine bound to DNA

Fluorescence properties (quantum yield, decay curve, lifetime and polarization) of acridine orange and proflavine bound to DNA were examined as a function of nucleotide to dye (P/D) ratio. First, mean fluoiescence lifetimes were determined by the phase-shift measurements. The lifetime and quantum yield of acridine orange increased in a parallel fashion with increasing P/D ratio. There was no parallel relation between the lifetime and quantum yield for proflavine; the lifetime showed a minimum around P/D = 10. Next, fluorescence decay curves were measured by the monophoton counting technique and analyzed with the aid of the method of moments and the Laplace transform method. The results showed that the fluorescence decay of bound acridine orange was exponential above P/D = 10. On the other hand, the decay of bound proflavine was exponential above P/D = 100, but markedly deviated from exponentiality with decreasing P/D ratio. The results of fluorescence polarization suggested that this phenomenon is the result of Förster energy transfer between proflavine molecules bound to the fluorescent site (AT pair) and bound to the quenching site (GC pair). Critical transfer distances were 26-4 and 37.0 Å, respectively, for bound proflavine and acridine orange.     

The effect on sister-chromatid exchanges of drugs and dyes by intercalation and photoactivation.

Intercalating dyes (acridine orange, proflavin and methylene blue) and drugs (chlorpromazine, promazine and chlorprothixene) were tested for their ability to induce sister-chromatid exchanges (SCEs) with and without photoactivation by visible light. Whereas in the dark all substances tested increased the frequency of SCEs, a superimposed effect of visible light on SCE formation was observed for the acridines proflavin and acridine orange, but not for the pheneothiazine derivatives methylene blue and chlorpromazine. These results are discussed in connection with the known mutagenic effects of these substances and with the factors that may be involved in SCE formation induced by intercalating molecules in the absence and presence of visible light.     

Possibilità d'impiego dell'arancio di acridina e dell'acriflavina nella ricerca istocliimica dei polisaccaridi insolubili della cellula vegetale

Abstract

Possible use of acridine orange and acriflavine in histochemistry staining of plant cell insoluble polysaccharides. – It is suggested to use acridine orange and acriflavine for staining insoluble polysaccharides in plant histochemistry. In fact the two dyes can give, under certain conditions, specific metachromatic effects. A discussion of the results and a comparison with those obtained by PAS follow.     

On the complex formation of acridine dyes with DNA. VII. Dependence of the binding on the dye structure

The binding constants for the complex formation of more than twenty ring nitrogen-and amino-substituted acridine derivatives with calf thymas DNA were measured by a fluorescence method. DNA quenches the fluorescence of the aminoacridine dyes so long as both amino hydrogens are not substituted. These dyes show an enhancement of their fluorescence intensity in the presence of DNA. Typical representatives of both are proflavine and acridine orange derivatives, respectively. A discussion of steric and electronic influences of various substituents attached to the ring nitrogen and amino groups on the binding led to the concept of different conformations for intercalated acridines without amino groups and the aminoacridines. The electrostatic binding site of the former seems to be the positively charged ring nitrogen, while the binding sites in the aminoacridines are so located that the amino groups are directed towards the negatively charged DNA phosphates.     

Extrinsic cotton effects of aminoacridines bound to DNA

The optical rotatory dispersion curves of the proflavine cation were measured in the spectral range 400–500 mμ. No optical activity was observed for the free cation but a large positive Cotton effect appeared in the presence of DNA. The effect of ionic strength, denaturation of the DNA, and the DNA/proflavine ratio were studied. The dependence of the magnitude of the Cotton effect on the DNA/proflavine ratio suggests that a nearest-neighbor interaction between bound proflavine molecules is necessary for optical activity. A simple statistical treatment was made which indicated that only a small number of proflavine molecules are required in close proximity for optical activity to occur. Denaturation of the DNA did not destroy the optical activity, which shows that long runs of DNA double helix are not necessary for optical activity of the ligand molecules. The optical rotatory dispersion curves of acridine orange which was bound to DNA were also measured. Two Cotton effects of opposite sense could be distinguished, the relative magnitudes of which depended on the DNA/acridine orange ratio and the state of denaturation of the DNA. The apparent differences from the proflavine-DNA system can to a large extent be explained in terms of the tendency of acridine orange to form aggregates.     

The mechanism of photodynamic inactivation ofStaphylococcus aureus by deuteroporphyrin

The mechanism ofStaphylococcus aureus inactivation by deuteroporphyrin (DT) and light was studied with singlet oxygen quenchers or hydroxyl radical scavengers. The light-activated DT (10 /ml) reduced the viability of the culture to less than 1%, whereas methionine, tryptophan, and 1,4-diazabicyclo-2,2,2-octane (DBCO) used as singlet oxygen quenchers provided almost 60% protection. Propylgallate, which is a hydroxyl free radical scavenger, also provided 60% protection. The presence of a singlet oxygen quencher and propylgallate provided almost complete protection from inactivation (96%). Photoinactivation in the absence of culture media (in saline) increased the killing rate and decreased the ability of the singlet oxygen quenchers to protect. In the same conditions damage from hydroxl free radicals was well protected by propyl gallate. The present results indicate thatS. aureus photoinactivation by DT and light is mediated by both singlet oxygen and hydroxyl free radicals.     

Stimulation of incorporation of nucleic acid precursors into HeLa cells caused by provaline

1. The effect of proflavine and other acridines on the incorporation of precursors into the nucleic acids of HeLa cells was examined. 2. Relatively low concentrations (50mum) of proflavine completely inhibited incorporation of precursors into DNA, but allowed a small extent of incorporation into RNA. 3. Acridine-resistant incorporation into RNA was unaffected by actinomycin D at 2mug./ml. and persisted even at high concentrations (500mum) of many acridines. 4. A few combinations of acridine and precursor, notably 250mum-proflavine and [(14)C]adenine, caused a stimulation of incorporation. 5. The proflavine-stimulated incorporation was into alkali-stable di- and tri-nucleotides. 6. It was concluded that the effect was due to the preferential inhibition of degradation of a fraction of RNA that normally turned over, thus allowing small radioactive oligonucleotides to accumulate in the cells.     

Staining Juxtaglomerular Granules with Basic Fluorescent Stains

Many basic fluorescent dyes stain juxtaglomerular granules to produce characteristic colors in ultraviolet light. The stain is applied to paraffin sections of tissues fixed in 2% calcium acetate-10% formalin or in phosphate-buffered 10% formalin. Procedure: Bring section to water, stain 0.5 min in Delafield hematoxylin, wash in tap water, stain 3 min in a 0.1% aqueous solution of basic fluorescent dye (auramine O, acriflavine, acridine orange, coriphosphine O, acridine yellow, phosphine E, thioflavine T, berberine sulfate, atebrine or rivanol) and differentiate 1 min in 0.1% acetate acid (or omit this step). After washing in tap water, air dry with or without subsequent mounting in a resin. Juxtaglomerular granules stain bright fluorescent yellow or orange against a dark background.