PHOTOSENSITIZED INACTIVATION OF E. COLI CELLS IN TOLUIDINE BLUE-LIGHT SYSTEM

E. coli cells were inactivated with visible light in the presence of toluidine blue as a photo-sensitizer. This photodynamic effect was partially protected with α-tocopherol. Not only pH but the concentration of the buffer during irradiation also affected the survival. The addition of osmotic stabilizers such as KCI, glycerol and polyethyleneglycol to the buffer increased the survival. The difference in singlet oxygen production in these reaction mixtures could not be related to these features. Furthermore, the survival was also dependent upon both irradiation temperature and cultivation temperature of the cells. These results with E. coli cells support the notion that one of the primary targets of toluidine blue sensitized photodynamic inactivation is cytoplasmic membrane, although other factors than cytoplasmic membrane also influence the survival of the cells.     

PHOTOSENSITIZED CARCINOGEN DEGRADATION AND THE POSSIBLE ROLE OF SINGLET OXYGEN IN CARCINOGEN ACTIVATION

Abstract— Dye sensitized photo-oxidation of various chemical carcinogens including 2-acetylaminofluorene, benzo(a)pyrene, 9,10-dimethyl-1,2-benzanthracene and 4-nitroquinoline- N -oxide has been studied in the presence and absence of oxygen. Visible light from a filtered 150 W Xe arc was used for photolysis. and carcinogen destruction was monitored spectrophotometrically. The carcinogens were solubilized in aqueous solution within micelles of various lipid-like surfactants. Photosensitized destruction of carcinogens by several triplet sensitizers has been observed. Enhanced damage in the presence of oxygen is also found. These results are consistent with photochemical oxidative damage to carcinogens being produced in aerated solutions via the sensitizer triplet state, possibly involving singlet oxygen. These manifold reactions are catalysed by micelles which concentrate polycyclic hydrocarbons in the non-polar environment within the micelles where the exclusion of water probably increases reactive species lifetimes. This model photochemical system mimics the aerobic metabolic activation of chemical carcinogens, which in part is believed to be mediated by various forms of activated oxygen.     

SINGLET OXYGEN PRODUCTION BY SOME FUROCOUMARIN DERIVATIVES IN THE PRESENCE OF DNA: TIME RESOLVED LUMINESCENCE MEASUREMENTS

Abstract— The yield of singlet oxygen (¹Δ_g) from some furocoumarins in the presence of DNA has been measured using time resolved techniques. For both psoralen and 4'-aminomethyl-4,5',8-trimethylpsoralen, increasing DNA concentration leads to a decrease in the yield of singlet oxygen. In addition, there is a linear dependence between the yield of singlet oxygen and the observed triplet yield determined by laser flash photolysis. In view of this observation it seems unlikely that singlet oxygen production occurs from these two furocoumarins when they are complexed with DNA. Preliminary, albeit inconclusive, results for 8-methoxypsoralen are also presented.     

OXYGEN EFFECT IN THE PROTECTION OF E. COLI AGAINST U.V. INACTIVATION AND MUTAGENESIS BY ACRIDINE ORANGE*

Abstract— Protection by acridine orange against ultraviolet light effects in resting cells of E. coli B/r/1, try^- was studied with special reference to a possible oxygen effect. Dose-response relationships were described by the function S= 1–(1 - e-^kD)ⁿ where S is the surviving fraction and D is the u.v. dose in ergs/mm². For cells suspended in 5 × 10^--⁶M acridine orange (AO) in air, the radiation sensitivity k was reduced from 0.010 (ergs/mm²)^)-1 in the absence of the dye to 0.0053 (ergs/mm²)^-1 in the presence of the dye. Under anoxia at this AO concentration, k was further reduced to 0.0015 (ergs/mm²)^-1. The oxygen effect ratio, kO₂/k_N2, was 3.5 at this concentration of AO. Greater protection was observed in cells suspended in 2 × 10^--⁵M AO, the oxygen effect ratio was unchanged. No oxygen effect was detected in the u.v. response in the absence of the dye. The value of n was reduced from about 12 with no dye to about 5 at dye concentrations of 5 × 10^--⁶M AO or more when oxygen was present. Under anoxia, in the presence of AO, n was further reduced to about 1.3. Atebrin, an efficient u.v. protective agent but an inefficient photodynamic agent, had no oxygen effect for protection against u.v. inactivation. Acridine orange protected against u.v.-induced reversion to tryptophan indepence in E. coli WP2 to about the same extent as it did for inactivation. A similar oxygen effect was observed for both inactivation and mutagenesis.     

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.     

FURTHER IN VIVO STUDIES ON THE PARTICIPATION OF SINGLET OXYGEN IN THE PHOTODYNAMIC INACTIVATION AND INDUCTION OF GENETIC CHANGES IN SACCHAROMYCES CEREVISIAE

Abstract —In vivo participation of singlet excited oxygen (¹O₂, ¹Δ9) in the photodynamic inactivation and induction of genetic changes (gene conversion) in acridine orange-sensitized yeast cells was investigated by using N₃^-, an efficient ¹O₂ quencher, and D²O, a known agent for the enhancement of the lifetime of ¹O₂. The addition of N₃^- protected the cells from both photodynamic actions. From an analysis of the concentration-dependent protection, about 80% of the induction of the genetic change is explainable on the basis of ¹O₂ mechanism. The quantitative estimation of the N₃^- protection in the inactivation was not possible because of the sigmoidal nature of the inactivation curve. The replacement of H₂O with D₂O during illumination was effective in enhancing the photodynamic inactivation but almost completely ineffective for the gene conversion induction. The deuterium effect with the cell system was clearly not as large as would be expected from in vitro experiments. This, however, could be explained from the kinetic consideration that natural quenchers of ^lO₂ in the cell would mask the deuterium effect. By experiments with different cell stages it was demonstrated that these two modifying effects were dependent on the intracellular reaction environment. The conclusion is that ¹O₂ must be the major intermediate responsible for the photodynamic actions in acridine orangesensitized yeast cells.     

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.     

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。     

INHIBITION OF RESPIRATION AND LOSS OF MEMBRANE INTEGRITY BY SINGLET OXYGEN GENERATED BY A PHOTOSENSITIZED REACTION IN NEUROSPORA CRASSA CONIDIA

Abstract— It was found that killing of Neurospora crassa conidia by singlet molecular oxygen generated by a photosensitized reaction in the presence of toluidine blue O, accompanied inhibition of respiration and uptake of the photosensitizing dye by conidia. Both the inactivation of respiration and the uptake of toluidine blue O were stimulated by deuterium oxide and suppressed by azide. Mitochondria of irradiated conidia were swollen and showed matrix of low density under an electron microscope.
These results suggest that singlet molecular oxygen induces the inhibition of respiration and the loss of membrane integrity of Neurospora conidia.     

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.     

INVOLVEMENT OF SINGLET OXYGEN IN THE PHOTOTOXICITY MECHANISM FOR A METABOLITE OF PIROXICAM

It has been previously shown that a metabolite of piroxicam but not piroxicam itself causes phototoxicity to cells in vitro after exposure to UVA (320–400 nm) radiation. The phototoxicity mechanism for this metabolite, 2-methyl-4-oxo-2H-l,2-benzothiazine-l,l-dioxide (Compound I), was investigated. In vitro phototoxicity to human mononuclear cells was assayed using 0.5 m M Compound I and UVA radiation. The UVA fluence required for phototoxicity of Compound I was lower by a factor of 2-3 in D₂O buffer compared to H₂O buffer. Superoxide dismutase and mannitol, which remove O₂^- and OH", respectively, do not decrease the phototoxicity. The photodecomposition of Compound I was inhibited by sodium azide, enhanced by human serum albumin and unaffected by mannitol. Stable photoproducts of Compound I were not toxic to the cells. The quantum yield of singlet oxygen based on its emission at 1270 nm was 0.19 and 0.35 for Compound I and s2 ± 10^-3 and 10^-2 for piroxicam in D₂O and C₆H₆, respectively. While the extremely low quantum yield for singlet oxygen from piroxicam appears to account for its lack of phototoxicity, the phototoxicity mechanism for its metabolite, Compound I, most likely does involve singlet oxygen.     

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.     

PHOTOSENSITIZED FORMATION OF SINGLET OXYGEN BY CHLOROPHYLL a IN NEUTRAL AQUEOUS MICELLAR SOLUTIONS WITH TRITON X-100

Abstract— Singlet oxygen (^lO₂) formed in the photolysis of neutral aqueous micellar (with Triton X-100) solution of chlorophyll a (dissolved inside the micelle) is detected in the aqueous phase by a test using imidazole in the presence of p -nitrosodimethylaniline. The quantum yield of ^lO₂ diffusing out of the micelle into the aqueous phase is also determined [θ(^lO₂) ⋍ 0.70–0.85].     

ON THE ACRIDINE AND THIAZINE DYE SENSITIZED PHOTODYNAMIC INACTIVATION OF LYSOZYME—SINGLET OXYGEN SELF-QUENCHING BY THE SENSITIZERS

Abstract— The quantum yield of the photodynamic inactivation of lysozyme increases in the sequence acridine orange, methylene blue, proflavine and acriflavine (1:5:6:12). At least up to protein concentrations of 0.1 m M , singlet oxygen is exclusively responsible for the inactivation of the enzyme. For methylene blue, acriflavine and proflavine the quantum yields decrease considerably with increasing dye concentrations. From measurements in H₂O and D₂O buffer solutions it was concluded that in the case of methylene blue the effect is mainly caused by the quenching of singlet oxygen [rate constant (3–4) × 10⁸ M ⁻¹ s⁻¹]. For the acridine sensitizers both singlet oxygen and dye triplet quenching processes have to be taken into consideration. It has been found that all sensitizers act as competitive inhibitors of the enzymatic reaction of lysozyme. However, the dye-protein interaction near the active center cannot be responsible for the observed dye self-quenching effect.     

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.     

INACTIVATION OF THE ACCEPTOR SIDE AND DEGRADATION OF THE D1 PROTEIN OF PHOTOSYSTEM II BY SINGLET OXYGEN PHOTOGENERATED FROM THE OUTSIDE

Abstract— The possible association of photodynamic sensitization with photoinhibition damage to the photosystem II complex (PS II) has been investigated using isolated intact thylakoids from pea leaves. For this study singlet oxygen (¹O₂), photoproduced by endogenous chromophores that are independent of the function of PS II, was assumed to be the major reactive intermediate involved in the photoinhibition process. When thylakoid samples preincubated with rose bengal were subjected to exposure to relatively weak green light (500–600 nm) under aerobic conditions, PS II was severely damaged. The pattern of the rose bengal-sensitized inhibition of PS II was similar to that of high light-induced damage to PS II: (1) the secondary quinone (Q_B)-dependent electron transfer through PS II is inactivated much faster than the Q_B-independent electron flow, (2) PS II activity is lost prior to degradation of the D1 protein, (3) diuron, an herbicide that binds to the Q_B domain on the D1 protein, prevents D1 degradation, and (4) PS II is damaged to a greater extent by the deuteration of thylakoid suspensions but to a lesser extent by the presence of histidine. Furthermore, it was observed that destroying thylakoid Fe-S centers resulted in a marked reduction of high light-induced PS II damage. These results may suggest that the primary processes of photoinhibition are mediated by ¹O₂ and that Fe-S centers, which are located in some membrane components, but not in PS II, play an important role in photogenerating the activated oxygen immediately responsible for the initiation of photodamage to PS II.     

A LASER FLASH KINETIC SPECTROPHOTOMETRIC EXAMINATION OF THE DYNAMICS OF SINGLET OXYGEN IN UNILAMMELLAR VESICLES

Abstract— The kinetic properties of O₂(₁Δ_g) have been examined in unilamellar vesicle dispersions composed of didodecyldimethylammonium bromide, di- n -octadecyl phosphate and egg lecithin. Light absorbing sensitizers 2-acetonaphthone, methylene blue and a methylene blue derivative of enhanced water-solubility were used. The rate parameters for singlet oxygen were monitored by observing the time profile of the bleaching of the reactive substrates diphenylisobenzofuran and anthracene dipropionate. The natural lifetime of O₂(₁Δ_g) in D₂O-based suspensions was shown to be 46/JS in good agreement with that found earlier for D₂O alone and D₂O-based micelle systems. The bimolecular rate constants for reaction with diphenylisobenzofuran and dimethylindole (both lipid-bound) and histidine (water-bound) were also in close conformity with the values found earlier in micellar media. Kinetic spectrophotometry has been shown to be a useful technique for examining rate parameters in these heterogeneous media.     

ULTRAVIOLET INACTIVATION OF THE ABILITY OF E. COLI TO SUPPORT THE GROWTH OF PHAGE T7: AN ACTION SPECTRUM

Abstract— Ultraviolet (UV)-irradiated E. coli K-12 wild-type cells were sensitized by a post-irradiation treatment with 10^-2 M 2, 4-dinitrophenol (DNP). This effect was not seen in strains carrying a uvr mutation, suggesting that DN P interferes with the excision repair process. The polA strain was sensitized to the same extent as the wild-type strain, while the exrA strain was not affected by DNP treatment.
Recombination deficient strains ( recA, recB and recA recB ) were protected by DNP treatment after UV irradiation. This protection was abolished by the addition of a uvr mutation (i.e., in strains recA uvrB and recB uvrB ).
Alkaline sucrose gradient sedimentation studies showed that DNP treatment interfered with the rejoining of DNA single-strand breaks induced by the excision repair process. This interference was apparently specific for the exr gene-dependent branch of the uvr gene-dependent excision repair process, since the uvr and exr strains were not sensitized while the wild-type and polA strains were sensitized.     

IS SINGLET OXYGEN FORMATION DOMINANT IN TRIPLET QUENCHING PROCESSES? MEASUREMENT OF THE QUANTUM YIELD OF SINGLET OXYGEN FORMATION BY THE TIME-RESOLVED THERMAL LENS METHOD

The quantum yields of singlet oxygen formation (Ø_Δ) by the quenching of triplet states of organic sensitizers are measured at various concentrations of the sensitizers by using the time-resolved thermal lens method. Above a certain concentration, Ø_Δ is independent of the sensitizer concentration. Below the threshold, Ø_Δ gradually decreases as the concentration of the sensitizer decreases. The extrapolation of Ø_Δ to zero concentration indicates that singlet oxygen formation is not necessarily dominant in the quenching process even for the ³ππ* state in benzene.