ON THE MECHANISM OF QUENCHING OF SINGLET OXYGEN IN SOLUTION

Abstract— Bimolecular rate constants for the quenching of singlet oxygen O*₂(¹Δ_g), have been obtained for several transition-metal complexes and for β-carotene. Laser photolysis experiments of aerated solutions, in which triplet anthracene is produced and quenched by oxygen, yielding singlet oxygen which then sensitizes absorption due to triplet carotene, firmly establishes diffusion-controlled energy transfer from singlet oxygen as the quenching mechanism in the case of β-carotene. The efficient quenching of singlet oxygen by two trans-planar Schiff-base Ni(II) complexes, which have low-lying triplet ligand-field states, most probably also occurs as a result of electronic energy transfer, since an analogous Pd(II) complex and ferrocene, which both have lowest-lying triplet states at higher energies than the O*₂(¹Δ_g), state, quench much less effectively.     

A NEW METHOD FOR THE DETECTION OF SINGLET OXYGEN IN AQUEOUS SOLUTIONS

Abstract— In experiments on the interception of reactive intermediates of strongly oxidizing character in dye (S) sensitized photooxidations using p -nitrosodimethylaniline (RNO) as a selective scavenger, it has been observed that some substrates (A) or ¹O₂ acceptors (like imidazole derivatives) induce the bleaching of RNO as followed spectrophotometrically at 440 nm. Since singlet oxygen (¹O₂) does not react chemically with RNO, this bleaching is a consequence of ¹O₂ capture by the imidazole ring which results in the formation of a trans-annular peroxide intermediate [¹O₂] capable of inducing the bleaching of RNO (-RNO). In the absence of RNO, [¹O₂] decomposes or rearranges into the final oxygenation product ¹O₂: ¹Δ_g Thus, the system imidazole plus RNO can be used as a sensitive and selective test for the presence of ¹O₂ in aqueous solutions. The method can also be applied in the presence of sensitizing dyes which, under visible irradiation, can partially bleach RNO even in the absence of imidazole derivatives. In such a case, the bleaching of RNO is strongly increased by the presence of imidazoles with a characteristic dependence on their concentration. The separation of the product of RNO bleaching by thin layer chromatography can serve as additional proof of the presence of ¹O₂ in the system. The imidazole plus RNO method has been applied to a number of sensitizing and non-sensitizing dyes.     

ON THE MECHANISM OF QUENCHING OF SINGLET OXYGEN BY AMINES-III. EVIDENCE FOR A CHARGE-TRANSFER-LIKE COMPLEX

Abstract— A series of amines were found to quench singlet oxygen in the order tertiary > secondary > primary, with a reasonable correlation between the log of their rate constant of quenching and their ionization potential. In addition, a Hammett rho plot gave a rho value of - 1.39 for the quenching of singlet oxygen by a series of substituted N, N-dimethylanilines, in good agreement with the results obtained by a different method. It was found that some of the amines (anilines) quenched the triplet state of the dye-sensitizer (Rose Bengal) used for the production of singlet oxygen. Corrections in the results were made in the calculations of rates of quenching of singlet oxygen to allow for the triplet-state quenching. No extensive quenching of the singlet state of the dye was observed at the concentrations of the amines necessary for singlet-oxygen quenching. In one case (N, N, N', N'-tetramethylphenylenediamine) there was no observable chemical reaction between singlet oxygen and the amine. It was concluded that singlet oxygen undergoes physical quenching by the amines via partial charge-transfer intermediates.     

PHOTOINACTIVATION OF SPINACH NITRATE REDUCTASE SENSITIZED BY FLAVIN MONONUCLEOTIDE. EVIDENCE FOR THE INVOLVEMENT OF SINGLET OXYGEN

Abstract All the activities of the nitrate reductase complex from spinach are irreversibly inactivated by irradiation of the enzyme with blue light in the presence of flavin mononucleotide. The photoinactivation requires oxygen and is prevented by ethylenediaminetetraacetic acid and by reduced nicotinamide adenine dinucleotide, but not by superoxide dismutase plus catalase. On the other hand, the inactivation is markedly enhanced in 77% deuterated water and it is suppressed by the singlet oxygen quenchers azide, histidine and tryptophan. All these results suggest that singlet oxygen generated by light absorption by flavin mononucleotide, rather than excited flavin mononucleotide or other oxygen species, is the primary agent involved in the photooxidative inactivation of the enzyme.     

DYE-SENSITIZED PHOTOLYSTS OF DISODIUM PHENYL PHOSPHATE IN AQUEOUS SOLUTION UNDER OXYGEN: INVOLVEMENT OF SINGLET OXYGEN

Abstract— The release of orthophosphate from oxygen-saturated aqueous solutions of disodium phenyl phosphate by near-UV and visible light was enhanced in the presence of the sensitizing dyes methylene blue, rose bengal and thionine. The reaction was accompanied by the bleaching of these dyes. In the absence of oxygen, under nitrogen, the photodecomposition was very much slower. In deuterium oxide as the solvent, the dye-sensitized photodecomposition was 9 times faster than in normal water. This result suggests that singlet oxygen is probably the reactive species in the dye-sensitized reaction.     

PHOTOOXIDATION OF EPINEPHRINE SENSITIZED BY METHYLENE BLUE—EVIDENCE FOR THE INVOLVEMENT OF SINGLET OXYGEN AND OF SUPEROXIDE

Abstract— The photooxidation of epinephrine, sensitized by methylene blue or by chlorophylls, excited with red light, involves the reduction of two molecules of oxygen to hydrogen peroxide per molecule of epinephrine oxidized to adrenochrome. The initial rates of these reactions are not affected by low concentrations of catalase. In 99 mol % D₂O, rates of methylene blue sensitized photooxidations are accelerated as much as 5.2 times over rates in ordinary water. Azide anion is a more effective inhibitor of this reaction in D₂O than in H₂O. Half maximal inhibitions are obtained by 1.3 mM azide in H₂O and by 0.1 mAf azide in D₂O. Isotope effects and azide sensitivities point to photooxidation of epinephrine in D₂O primarily by a singlet oxygen pathway; in H₂O, non-singlet oxygen pathways become more predominant. Superoxide dismutase (SOD) markedly inhibits rates of the photooxidations in H₂O and in D₂O; about 25% at 10^-9 M SOD, and 50% at 10^-6 M SOD in H₂O. In the photooxidation in H₂O, both by non-singlet and singlet oxygen mechanisms, the amount of superoxide produced is equivalent to the amount of O₂ consumed in the photooxidation of epinephrine; the superoxide thus formed participates in the oxidation of epinephrine.     

PHOTOBLEACHING OF MEROCYANINE 540: INVOLVEMENT OF SINGLET MOLECULAR OXYGEN

The purpose of this study was to assess the mechanism of merocyanine 540 (MC540) photobleaching in a liposomal system. Broad based visible irradiation of MC540 in unilamellar dilauroylphosphatidylcholine (DLPC) vesicles resulted in dye bleaching that was strictly O2 dependent. The rate of self-sensitized photobleaching was enhanced in D2O and inhibited by both azide and histidine, consistent with 1O2 intermediacy (Type II chemistry). Supportive evidence for this mechanism was obtained by using a Type II sensitizer, aluminum phthalocyanine tetrasulfonate (AlPcS lambda max = 678 nm). Irradiation of AlPcS and MC540 in DLPC with lambda greater than 630 nm (absorbed only by AlPcS) light resulted in rapid bleaching of MC540, which was stimulated by D2O and inhibited by azide. A rate constant of 10(7) M-1 s-1 was determined for the chemical quenching of 1O2 by MC540. The rate constant for physical quenching of 1O2 by MC540 was estimated to be ca 10(9) M-1 s-1.     

SINGLET OXYGEN YIELDS, OPTICAL PROPERTIES, AND PHOTOTOXICITY OF REDUCED DERIVATIVES OF THE PHOTOSENSITIZER CERCOSPORIN

Abstract— The perylenequinone cercosporin (CR) is a singlet oxygen generating photosensitizer produced by Cercospora spp which plays a critical role in parasitism of plants by these fungi. Several lines of evidence suggest that the defense mechanism of Cercospora spp towards this toxin is the generation of a cell surface reducing environment that leads to transient reduction of CR. In order to demonstrate that reduced CR is less toxic, several derivatives of CR were synthesized. Hexaacetyl-dihydrocercos-porin (HAC) was prepared by reductive acetylation of CR. Noranhydrocercosporin (NAC) resulted from dehydration of CR and tetramethyl-noranhydrodihydrocercosporin (TMNAC) was a product of reductive methylation of NAC. The perylenequinones, CR and NAC, absorb more light than their respective reduced derivatives, but are much less fluorescent; the relative fluorescence intensities of HAC, TMNAC, and dithionite-reduced CR were 80–160 times greater than that of CR and NAC. Also, CR and NAC were more efficient at generating singlet oxygen. As measured by time-resolved IR luminescence, the singlet oxygen quantum yields relative to CR (adjusted to 1.00) were 0.16, 0.19 and 0.73, respectively, for HAC, TMNAC, and NAC. Toxicity was measured by assaying for inhibition of growth of CR-sensitive fungi in constant light. The reduced derivatives were less toxic than their respective oxidized forms. None of the compounds showed significant growth inhibition in the dark with any of the fungi, or when assayed in the light with the CR-resistant fungus Cercospora kikuchii. A lipid peroxidation assay with methyl linolenate also showed that HAC was less active than CR. Thus, reduction of CR leads to greater fluorescence intensities, lower production of singlet oxygen and lower phototoxicity. These data support the hypothesis of transient cercosporin reduction as a mechanism of defense against cercosporin toxicity.     

INVOLVEMENT OF DRUG-DERIVED PEROXIDES IN THE PHOTOTOXICITY OF NAPROXEN and TIAPROFENIC ACID

Photodegradation of naproxen and tiaprofenic acid in aqueous buffered solutions leads to decarboxylated products with ethyl, 1-hydroxyethyl and/or acetyl side chains. The photomixtures obtained in the presence of oxygen were clearly more toxic to cultured hepatocytes than those obtained under anaerobic conditions. This effect was more noticeable in the case of naproxen. Based on the composition of the oxygenated photomixtures and the relative toxicity of the different photoproducts, it is possible to account for most of the observed toxicity in the case of tiaprofenic acid but not in the case of naproxen. This is explained as a result of the presence of drug-derived peroxidic species in the photomixtures and their contribution to the observed toxicity. Peroxides were determined by the peroxidase-catalyzed oxidation of dichlorodihydrofluorescein to its fluorescent analog. The amount of peroxides present in naproxen photomixtures was much higher than in the case of tiaprofenic acid. A dose-dependent depletion of intracellular glutathione was observed when hepatocytes were incubated with peroxide-containing naproxen photomixtures. This effect was prevented by the addition of catalase or jV-acetylcysteine to the culture medium.     

A TEST OF THE SINGLET OXYGEN MECHANISM OF CATIONIC DYE PHOTOSENSITIZATION OF MITOCHONDRIAL DAMAGE

Aromatic cationic dyes have a potential as photo-chemotherapeutic agents because they are selectively concentrated into the mitochondria of cancerous cells. The mechanism of cytophototoxicity has been proposed to be primarily due to dye sensitized photogeneration of highly toxic singlet oxygen (1O2) at the mitochondria. We tested this hypothesis by measuring the relative phototoxicity of a collection of aromatic cationic dyes towards respiring rat-liver mitochondria (RLM), upon addition of 514 nm laser light. Effectiveness of dye photosensitization towards destruction of RLM function was assayed by its effect on the RLM membrane potential. Three physical parameters of dye phototoxicity were independently measured and a relative phototoxicity calculated assuming adherence of mechanism to the 1O2 hypothesis. Quantum yields of dye sensitized 1O2 production were estimated, either from time-resolved luminescence measurements of photosensitized 1O2 formed, or by comparing rates of photobleaching of 1O2 trap; the relative partition of dye into mitochondrial lipid was determined gravimetrically; and the optical density of dye was determined in a lipid like Triton X-100 micellar environment. Under the assumption of the 1O2 hypothesis, these parameters were used to predict a relative phototoxicity which was compared with that observed. For 12 of the 14 dyes investigated, the observed and predicted phototoxicities were linearly correlated (r = 0.85) suggesting support of the 1O2 hypothesis. Carbocyanines DiOC2(3) and DiSC2(3) did not correlate and were found to be 10 and 1000 times more potent than predicted, suggesting an additional factor at play in their phototoxicity.     

THE ROLE OF SINGLET OXYGEN IN THE PHOTOOXIDATION OF POLYMERS

Abstract— This paper is a critical review of the singlet oxygen oxidation of polymers in solid state and in solution, referring in particular to polydienes, polystyrene and polyvinyl chloride). The singlet oxygenation of polydienes resulted in formation of allylic hydroperoxide groups with shifted double bonds, according to the "ene"-type process. The singlet oxygenation of polystyrene and polyvinyl chloride) occurs only when the new double bonds are formed in these polymers. During dye-photosensitized singlet oxygenation of polydienes in methanol-benzene solution, a very rapid decrease in the molecular weight was observed. For the chain-scission which occurs, not only singlet oxygen but several intermediates such as radicals, bi-radicals and cation-radicals which are formed during light fading of dyes are responsible. At the end of this paper a short review appears which has been focused on the quenching behavior of stabilizers, particularly interactions with singlet oxygen.     

CUTANEOUS PHOTOTOXICITY OF TETRACYCLINE ANTIBIOTICS: GENERATION OF FREE RADICALS and SINGLET OXYGEN DURING PHOTOLYSIS AS MEASURED BY SPIN-TRAPPING and THE PHOSPHORESCENCE OF SINGLET MOLECULAR OXYGEN

Chlortetracycline (CTC) generated an aryl radical in aqueous buffer (pH 7.4) during near UV irradiation, as evidenced by the formation of 2-methyl-2-nitrosopropane spin adducts. The radical was produced via dechlorination, a photoprocess not previously reported for tetracyclines. Demeclocyc-line (DEM), another chlorinated tetracycline, did not produce detectable aryl radicals. Relative ¹O₂ yields obtained by direct luminescence measurements at 1268 nm for five tetracyclines in alkaline ethanol (demeclocycline · tetracycline · chlortetracycline · doxycycline · minocycline) showed that DEM produced approximately three times as much singlet oxygen as CTC. This constitutes direct evidence that tetracyclines sensitize both Type I and Type II photoreactions.     

SINGLET OXYGEN INVOLVEMENT IN PHOTOHEMOLYSIS SENSITIZED BY MEROCYANINE-540 and ROSE BENGAL

Merocyanine-540 is currently in use in experimental protocols for the treatment of leukemia and neuroblastomas. The mechanism of cellular phototoxicity of this membrane binding sensitizer is unexplored. We have used sodium azide and deuterium oxide to examine the role of singlet oxygen in photomodification of cell membranes in a photohemolysis assay. The effects of these agents on the photomodification process were separated from the effects on the ion fluxes leading to lysis (lytic phase). Azide significantly inhibited photohemolysis sensitized by merocyanine-540 or rose bengal. The inhibition was equal for both sensitizers. Azide had no effect on the lytic phase. Deuterium oxide significantly potentiated lysis with both sensitizers to approximately the same degree. There was little effect of deuterium oxide when added after illumination. The results indicate that singlet oxygen plays a significant role in membrane photomodification sensitized by both rose bengal and merocyanine-540.     

单线态分子氧的产生和体外叶绿素α的结构状态

叶绿素α(Chl α)是光合作用光量子的接受器和光能最初传递体。早期研究表明,在光合器官中,Chlα长波主吸收带位于红区。1969年Krasnovsky指出,Chlα受光照射时有可过氧化还原反应。     

THE SINGLET OXYGEN REACTIVITY OF BILIVERDIN

Abstract— In 1, 1, 2-trichlorotrifluoroethane solution biliverdin physically quenches singlet oxygen at a rate of 8 × l0^sM-¹s^-1 and reacts chemically at 6 × 10 ⁵M-¹s^-1 to give a red product. In D, O solution the rate constants are PD dependent and range from 1.5–6 times 10¹⁰M-¹s^-1 for quenching and the chemical rate varies from 3–5 × 10⁸ M^-1 s^-1 to give colorless products.     

THE ROLE OF SINGLET OXYGEN IN PHOTOOXIDATION OF EXCITABLE CELL MEMBRANES

Abstract— Giant nerve axons from lobsters were photooxidized by visible light from a Xe arc using eosin Y, rose bengal and methylene blue as sensitizers. The degree of modification was assayed as the rate constant for block of sodium channels during illumination. Protection or enhancement of modification was tested for several reagents known to interact with singlet oxygen. Deuterium oxide enhanced the modification up to 57% while sodium azide protected up to 60%. β -Carotene, triethylamine and DABCO exerted no effect. From a consideration of the probable low polarity environment of the sensitization sites and diffusional restrictions on reagents it is concluded that intramembranously created singlet oxygen plays a significant role in membrane modification.     

THE ROLE OF SUPEROXIDE AND SINGLET OXYGEN IN LIPID PEROXIDATION

Abstract— An investigation into the mechanism of lipid peroxidation catalyzed by xanthine oxidase showed a dependence upon superoxide, singlet oxygen and adenosine 5'-diphosphate chelated iron (ADP-Fe³⁺). In the absence of ADP-Fe³⁺ or in the presence of superoxide dismutase there is complete inhibition of enzymatic peroxidation. Initiation of peroxidation likely occurs through an ADP-perferryl ion complex formed by ADP-Fe³⁺ and superoxide. Use of the singlet oxygen trapping agent 2,5-diphenylfuran showed that singlet oxygen does not participate in the initiation of peroxidation but rather in the propagation of peroxidation. The mechanisms of NADPH-cytochrome P450 reductase-catalyzed and ADP-Fe²⁺ catalyzed lipid peroxidation parallel that of xanthine oxidase in that initiation occurs through a superoxide dismutase-sensitive reaction and that singlet oxygen is present during propagation of lipid peroxidation.     

EVIDENCE FOR THE PRODUCTION OF SINGLET OXYGEN BY PHOTOEXCITED ACRIDINE ORANGE

Abstract In contrast to previous results obtained with the nitroxide radical detection technique, generation of the specific ¹O₂ oxidation product of cholesterol shows that photoexcited acridine orange produces singlet oxygen.     

THE HEMOLYSIS OF ERYTHROCYTES BY SINGLET OXYGEN GENERATED IN THE GAS PHASE

Many sensitizers cause photodynamic hemolysis of erythrocytes. As these sensitizers usually participate in Type I as well as Type II processes, the determination of the mechanism(s) of photosensitized hemolysis is always ambiguous. Here, human erythrocytes were proved to hemolyze upon treatment with singlet oxygen (1 delta g) generated with fluoranthene in the gas phase. These conditions rigorously exclude the participation of superoxide anion. The standard diagnostic tests for singlet oxygen (enhanced effect in D2O and protection by NaN3) gave the anticipated results when the erythrocytes were treated with 1O2 generated in the gas phase. When the erythrocytes were irradiated in a buffer solution containing fluoranthene, the results of the diagnostic tests depended on the sensitizer concentration.     

PHOTOLUMINESCENCE OF SINGLET OXYGEN IN PIGMENT SOLUTIONS

Luminescence of ¹O₂ (1270 nm) accompanying energy transfer to oxygen from photoexcited (triplet) molecules of sensitizers in air saturated solutions has been investigated. The luminescence was observed in CC1₄, CS₂ and freon with the use of porphyrins, chlorophylls, pheophytins and aromatic hydrocarbons as sensitizers. The lifetime and quantum yield of the luminescence depended on the nature of the solvents. pigments and their concentrations. The maximum values of these parameters were equal to 28 ± 5 ms and 5 ± 4 times 10^--⁵, respectively. The quantum yield of ¹O₂ generation by pigments has been measured and the results used for determining the quantum yields of intersystem crossing in the pigment molecules. The rate constants of ¹O₂ reaction with different substances have been determined with the aid of luminescence quenching. It has been shown that along with β-carotene. Chls, pheophytins, and some porphyrins are also very active quenchers of ¹O₂, The quenching effect depends on their molecular structure and on the presence and nature of the central metal atom. Quenching ¹O₂ by the pigments is due mainly to a “physical” mechanism (without destruction of the pigments). The destructive “chemical” quenching is by 1–4 orders of magnitude less effective and is accompanied with photochemiluminescence of the pigments. The experiments on ¹O₂ generation and quenching indicate that energy of triplet states of bacteriochlorophyll and bacteriopheophytin is somewhat higher than that of ¹Δ_g oxygen. The data demonstrate wide possibilities of the luminescence studied as a method for investigating ¹O₂ reactivity and photophysical properties of sensitizers.