O2>-DEPENDENT and -INDEPENDENT PHOTOOXIDATION OF QUERCETIN IN THE PRESENCE and ABSENCE OF RIBOFLAVIN and EFFECTS OF ASCORBATE ON THE PHOTOOXIDATION

Abstract— The self-sensitized photooxidation of quercetin was not suppressed by superoxide dismutase (SOD), but suppressed by ascorbate. During the suppression of quercetin photooxidation, ascorbate was oxidized. These results suggest the reduction of oxidized quercetin to quercetin by ascorbate. Quercetin photooxidation in the presence of both riboflavin and EDTA was suppressed by SOD by about 90%. The result suggests the participation of O₂^- in the photooxidation of quercetin. The participation of O₂^- in the quercetin oxidation was confirmed by a xanthine-xanthine oxidase system. Based on these results the physiological and pharmacological functions of quercetin are discussed.     

LASER PHOTOLYSIS STUDIES OF SUPEROXIDE ADDUCTS OF COBALT(II) AND ZINC(II) PORPHYRINS IN DIMETHYLFORMAMIDE

Abstract— Photochemistry of superoxide adducts of cobalt(II) and zinc(II) porphyrins has been studied by laser photolysis. It was found that the former in dimethlformamide photodissociates the superoxide anion radical, O₂^-, with the quantum yield of 0.5 ± 0.05 at the excitation wavelenths 355 and 532 nm, and the latter gives flurescence and the triple state without giving rise to the photodissociation of O₂^-     

PROOXIDANT and ANTIOXIDANT EFFECTS OF ASCORBATE ON PHOTOSENSITIZED PEROXIDATION OF LIPIDS IN ERYTHROCYTE MEMBRANES

Abstract— Continuous blue light irradiation of resealed erythrocyte ghosts at 37°C in the presence of uroporphyrin or protoporphyrin results in ¹O₂-mediated (azide inhibitable) lipid peroxidation and membrane lysis. Lipid peroxidation was assessed by thiobarbituric acid reactivity and by quantitation of total hydroperoxides, while lysis was measured in terms of trappedglucose–6-P release. Low concentrations of ascorbate, AH^- (e.g. 0.5 m M ). present at the start of irradiation, significantly enhanced the rates of lysis and peroxidation, whereas relatively high concentrations of AH^- (e.g. 15 m M ) inhibited both processes. By way of contrast. AH^- produced only a dose-dependent inhibition of the photoinactivation of lysozyme, added as an extramembranous target. No significant AH^-induced lipid peroxidation was observed in dark or light controls, plus porphyrin or minus porphyrin, respectively. Stimulation of peroxidation and lysis by low levels of AH^- was enhanced by added Fe(III), abolished by EDTA. but unaffected by catalase or superoxide dismutase. A plausible explanation for these results is as follows. At low concentrations of AH^- prooxidant activity is favored. Redox metal-mediated breakdown of photoperoxides occurs, which tends to amplify lipid peroxidation. Neither O₂^- nor H₂O₂ appears to be involved. At significantly high concentrations, AH^- acts predominantly as an antioxidant by intercepting ¹O₂ and/or sensitizer triplet, or by scavenging free radical intermediates of lipid peroxidation.     

BLUE LIGHT INDUCED, REVERSIBLE IN ACTIVATION OF THE TONOPLAST-TYPE H+-ATPase FROM CORN COLEOPTILES IN THE PRESENCE OF FLAVINS

Abstract— Irradiation (λ_max 447 nm; 58.5 W m^-2) of a microsomal membrane fraction of corn coleoptiles for 5 min in the presence of the in vivo concentration of riboflavin inactivates the tonoplast-type H⁺-ATPase. This inhibition is O₂-dependent, is enhanced in D₂O and suppressed by NaN₃, indicating participation of singlet molecular oxygen in the inactivating mechanism. Besides singlet oxygen, the superoxide anion (O₂^-) is generated during irradiation, which obviously has no effect on the H⁺-pumping activity. However, in the presence of superoxide dismutase (SOD), O₂^- is transformed into H₂O₂ which causes an additional strong inhibition of H⁺. ATPase activity. This inhibition can be increased by ethylenediaminetetraacetic acid (EDTA), which is known to be an electron donor of the excited flavin molecule. In contrast, catalase prevents the H₂O₂-mediated photoinactivation of the H⁺ -ATPase. The light dependent inactivation of H⁺-transport does not occur if reduced glutathion (GSH) is added prior to or after irradiation. These results indicate that the blue light mediated inhibition of the H⁺-ATPase is mediated by singlet oxygen and H₂O₂ which oxidize essential SH-groups of the enzyme into disulfides. Reduction of the formed disulfides by GSH restores the activity of the enzyme.     

THE ROLE OF O2- IN THE CHEMILUMINESCENCE OF LUMINOL*

Abstract— The chemiluminescence of luminol in buffered aqueous solutions is inhibited by superoxide dismutase. This occurs whether the luminescence is induced by ferricyanide, persulfate, hypochlorite, or by the action of xanthine oxidase on xanthine. Since superoxide dismutase inhibits reactions which involve O₂^-, we conclude that this radical is a constant factor in the chemiluminescence of luminol in aqueous solutions. The kinetics of light production are discussed in terms of hypothetical mechanisms that fit the available data. The strong luminescence of luminol in aprotic solvents or in aqueous systems containing relatively high concentrations of H₂O₂ could not be explored in this way, because superoxide dismutase is inactive under such conditions.     

ON THE GENERATION OF THE HYDROXYLATION AGENT FROM SUPEROXIDE RADICAL. CAN THE HABER–WEISS REACTION BE THE SOURCE OF OH RADICALS?

Abstract— In many biological systems, the role of O₂^- in hydroxylation and toxic processes was assumed to be due to the formation of OH radicals. The Haber-Weiss reaction (Haber and Weiss, 1934)—(H₂O₂+ O₂^-→ OH + OH^-+ O₂) was suggested as the origin of this activity.
In this study it is shown that this reaction pathway is too slow, and that OH is probably formed from the reaction of complexed superoxide with H₂O₂ or/and from the reduction of Fe(III), bound to biological compounds, by O₂^-; the reduced Fe(II) can then react with H₂O₂ as a Fenton reagent, to yield OH.
It is also shown that singlet oxygen cannot be formed in these biological systems neither from the dismutation of OJ nor from the reaction of O₂^- with OH. Singlet oxygen may be formed from the reduction of metal complexes by O₂^-.     

PHOTOFRAGMENTATION OF α-OXOCARBOXYLIC ACIDS IN AQUEOUS SOLUTION. AN EPR STUDY. FORMATION OF SEMIDIONE RADICALS BY DECARBOXYLATIVE SUBSTITUTION OF α-OXOCARBOXYLIC ACIDS BY ACYL RADICALS-I: GLYOXYLIC, PYRUVIC, α-OXOBUTYRIC, α-OXOGLUTARIC AND α-OXOISOCAPROlC ACIDS

Abstract— By means of in situ photolysis EPR of aqueous solutions of α-oxocarboxylic acids (RCO-CO₂H) at pH values above 5, semidione radical anions [RC(O^-)=C(O')R] and α-hydroxy-α-carboxy alkyl radicals [RC(OH)CO₂-] were detected. C0₂ was identified as a reaction product. On photolysis of mixtures of α-oxocarboxylic acids (RCOCO₂H and R'COCC₂H), "mixed" semidione radical anions [RC(O^->=C(O)R'] were observed in addition to RC(O^-)=C(O')R, R'C(O^-)=C(O')R', RC(OH)CO₂^- and R'C(OH)CO₂^-. The experimental results are explained in terms of photodecarboxylation (α-clea-vage) of electronically excited RCOCOJ to yield RCO and CO₂. The radicals RC(OH)CO₂^- are formed by reduction of RCOCO₂^- by CO₂^-. The semidione radicals are produced by addition of RCO to RCOCO₂^- followed by decarboxylation of the intermediate adduct. This mechanism was confirmed by generating acyl radicals independently and reacting them with α-oxocarboxylic acids. Selected product studies support the mechanism suggested.     

THE EFFECT OF IRON ON THE DISTRIBUTION OF SUPEROXIDE AND HYDROXYL RADICALS AS SEEN BY SPIN TRAPPING AND ON THE SUPEROXIDE DISMUTASE ASSAY

Abstract— Using the spin trap 5,5-dimethyl-1-pyrroline-1-oxide we have demonstrated the presence of OH in the xanthine-xanthine oxidase system when iron and/or iron-EDTA (ethylenediamine-tetraacetic acid) is present. With increasing iron (or iron-EDTA) concentration the intensity of the O₂^- spin adduct decreased while that of OH increased. However, use of diethylenetriaminepentaacetic acid (DETAPAC) as a metal chelator in the reaction mixture suppressed the OH spin adduct signal while maintaining the intensity of the signal from the O₂^- spin adduct.
Use of EDTA to eliminate the interfering effects of metal ions in the superoxide dismutase assay employing xanthine oxidase and nitroblue tetrazolium introduces an artifact from the iron present. The interference in the assay from metal ions, including iron, can be eliminated with use of DETAPAC as a metal chelator. Thus, it is possible to make comparisons of measured superoxide dismutase activities even when there are variations in the amount of iron present in the samples.     

RADIATION ACTIVATION OF CARCINOGENS AND THE ROLE OF OH AND O2-

Abstract— Radiation-induced covalent binding of labelled carcinogens to DNA has been investigated under a variety of conditions using ultrafiltration or millipore filtration of TCA precipitable complexes. High yields of carcinogen binding at high DNA concentrations are also observed for a variety of small molecules and are not carcinogen-specific. At high carcinogen concentrations, radiation-induced unstable electrophilic carcinogenic species are produced, and undergo free-radical reactions which simulate cellular redox reactions involved in metabolic carcinogen activation, leading to the formation of covalently bound carcinogen adducts to DNA as a potential target macromolecule. The yields of carcinogen-DNA adducts increase linearly with dose and depend upon carcinogen concentration. The results of scavenger studies indicate that the oxidising species O₂^- and OH are the principal activating species. Rate constants for the selective radiation-induced oxidation reactions of various chemical carcinogens with superoxide have been measured by a competition kinetic method using pulse radiolysis. The relatively long-lived superoxide radical reacts with carcinogens at a rate which is two orders of magnitude slower than the diffusion-controlled rate for the hydroxyl radical, thus allowing a measure of O₂^- specificity in the presence of competing reactants within the cell.     

DETERMINATION OF SINGLET OXYGEN RATE CONSTANTS IN AQUEOUS SOLUTIONS

Abstract— A very efficient quenching of singlet oxygen (¹O₂) by N₃^- ions has been applied to the determination of rate constants of reactions of ¹O₂ with various substrates (A). This determination has been made possible by choosing experimental conditions which give simple competition between N₃^- and A for ¹O₂ formed in the steady state irradiation of convenient sensitizing dye (S). The consumption of oxygen by the substrate, as followed with an oxygen analyzer, decreases in the presence of low concentrations of N₃^-. Using neutral air saturated aqueous solutions containing the dye phenosafranine + A and varying concentrations of N₃^-, the ¹O₂ rate constants for reactions with biological substrates and some radiation protective agents have been determined.     

POLYMER BOUND PYRROLE COMPOUNDS–VI. PHOTOPHYSICAL PROPERTIES OF MONOMERIC MODELS FOR POLYSTYRENE-BOUND PORPHYRINS

Abstract— Several porphyrin esters used as models for polystyrene-bound porphyrins have been prepared and their excited states have been studied by laser flash photolysis, IR phosphorescence of singlet molecular oxygen, O₂(¹Δ_g), and steady-state fluorescence. The photophysical properties of the porphyrin esters in solution are affected by the presence of nitro group(s) in the chain. In this case, an important decrease in φ_f, φ_T and φ_δ (to ca 0.7–0.4 of the value for the parent dimethyl ester) is observed. This is mainly due to intramolecular electron-transfer quenching [by the nitro group(s)] of the first excited singlet state of the porphyrin. The thermodynamic feasibility of this deactivation pathway has been confirmed polarographically. Quenching of the porphyrin triplet state and of O₂(¹Δ_g) by the nitro groups is negligible. The present conclusions explain also the results obtained previously for the photooxidation of bilirubin sensitized by the parent insoluble polystyrene-bound porphyrins. In that case the photooxidation rates were correlated directly with the quantum yield of O₂(¹Δ_g) production by the sensitizer. The consequences of these results for the use of polystyrene-bound porphyrins in sensitized photooxidation processes are discussed.     

THE QUENCHING OF SINGLET OXYGEN BY AMINO ACIDS AND PROTEINS

Abstract— The physical quenching of singlet molecular oxygen (¹Δ_g) by amino acids and proteins in D₂O solution has been measured by their inhibition of the rate of singlet oxygen oxidation of the bilirubin anion. Steady-state singlet oxygen concentrations are produced by irradiating the oxygenated solution with the 1–06 μm output of a Nd-YAG laser, which absorbs directly in the electronic transition ¹Δ_g+ 1 v →³Σ_g^-. The rate of quenching by most of the proteins studied is approximated by the sum of the quenching rates of their amino acids histidine, tryptophan and methionine, which implies that these amino acids in the protein structure are all about equally accessible to the singlet oxygen. The quenching constants differ from those obtained by the ruby-laser methylene-blue-photosensitized method of generating singlet oxygen, or from the results of steady-state methylene-blue-photosensitized oxidation, where singlet oxygen is assumed to be the main reactive species. The singlet oxygen quenching rates in D₂O, pD 8, are (10⁷ℒ mol^-1 s^-1): alanine 0–2, methionine 3, tryptophan 9, histidine 17, carbonic anhydrase 85, lysozyme 150, superoxide dismutase 260, aposuperoxide dismutase 250.     

DETECTION OF OXYGEN RADICALS IN BIOLOGICAL REACTIONS

Abstract— Recent data are presented on the mechanisms or selected assay procedures for superoxide anions (O₂^-) and hydroxyl radicals (OH). The systems discussed include the autoxidation of adrenalin to adrenochrome and other indole compounds, the oxidation of hydroxylamine to nitrite, the generation of ethylene from methional, and the scavenging of OH radicals by p -nitroso-dimethylaniline. The results are compared with other assay procedures to aid in the search for absolute and specific tests for these oxygen radicals. Particular emphasis is placed on the interrelation of 0₂^- OH and hydrogen peroxide.     

PHOTOVOLTAIC PROPERTIES OF MESO-TETRAARYLPORPHYRINS

Abstract— The photovoltaic properties of meso -tetraphenylporphyrin and its derivatives with various para -substituents, meso-tetrakis(2,4-dimethoxyphenyl)porphyrin and meso -tetrakis (2-fluorenyl)porphyrin have been investigated. The forward dark current-voltage characteristics of Al/porphyrin/Ag cells are attributed to the MIS Schottky barriers consisting of Al/Al₂O₃/porphyrin. The barrier parameters such as the apparent diffusion potential V ₀ the barrier width w₀ and the density of ionized impurity N are estimated by using the capacitor discharge method. The action spectra of photocurrents closely follow the optical absorption spectra of the porphyrin films. The photocurrents vary as i _pα I ^γ, where I is the incident light intensity, and the Sight exponents y range between 0.83 and 1.0. The sublinear difference from unity could be related to the exponential distribution of hole traps in films of the porphyrins. No obvious correlation between the photocurrent and the fluorescence quantum yields of the sublimed porphyrin films is found. The electron donating substituents such as OCH₃ and CH₃ strikingly increase the photocurrents. The photocurrent quantum yields correlate exponentially with the first ring oxidation potentials of the porphyrins and also with the substituent constants for the Hammett linear free-energy relationship. The current quantum yields estimated for the porphyrins studied, range in the order of 10^-4–10^-2 with power conversion efficiencies 10^-7–10^-3.     

EFFECTS OF QUENCHING AGENTS ON THE PHOTODYNAMICALLY-INDUCED CHEMOTACTIC RESPONSE OF THE COLORLESS FLAGELLATE Polytomella magna

Abstract In the presence of the photosensitizer riboflavin at high fluence rates a photoproduct, most probably H₂O₂, is formed which causes negative phototaxis in the colorless flagellate Polytomella magna . The aim of this study was to find out whether H₂O₂ is produced in a type I or II reaction. As has been shown, ¹O₂ quenchers either do not influence the photodynamic action of riboflavin (furfuryl ethanol, DPBF, l -histidine, crocetin) or show slight quenching effects only at very high concentrations ≧ 10⁻² M (DABCO, DMF, imidazole). D₂O is toxic to P. magna even in 1:1 and 1:2 mixtures with H₂O. On the other hand, the quenching effect of 1,4-benzoquinone, highly indicative for the type I pathway, is more than two orders of magnitude stronger than the one of the above mentioned ¹O₂ quenchers. The results suggest that H₂O₂ is produced in a type I reaction. Superoxide does not seem to be involved since superoxide dismutase does not diminish the photodynamic effect of riboflavin.     

LASER FLASH PHOTOKINETIC STUDIES OF ROSE BENGAL SENSITIZED PHOTODYNAMIC INTERACTIONS OF NUCLEOTIDES AND DNA

Abstract— Laser flash photolysis studies of the production of the triplet state of the xanthene dye, rose bengal (RB), have been carried out. The reactions of this state with oxygen to form singlet oxygen and the superoxide anion radical have been observed and yields measured. Quenching of RB(T₁) by oxygen leads to approximately 75% singlet oxygen and 20% superoxide. The reactivity of these species-RB(T₁), O₂(¹Δ_g) and O₂^-—with four nucleotides and DNA have been determined. Only guanine residues showed any noticeable reaction at neutral pH. At higher pH guanine rate constants increased. The consequences to biological photodynamic processes are discussed.     

INTERACTIONS OF ASCORBATE AND CHELATED IRON IN A METHYLVIOLOGEN-MEDIATED MEHLER REACTION

Abstract— –In the light, isolated spinach thylakoids consumed O₂ in the presence of methylviologen, and ascorbate was found to interact with this reaction in various ways. Chelating-resin was used to remove metal impurities from the assay medium. Ascorbate diminished the H₂0₂ pool in resin-untreated solutions, while in resin-treated solutions ascorbate had no effect on H₂O₂ concentrations. A Fenton catalyst (Fe-EDTA) increased O₂ uptake in the presence of ascorbate and decreased the amount of O₂ recovered by catalase. Ascorbate tripled the rate of the methylviologen-mediated Mehler reaction, and the O₂ consumed was liberated to 50% of its original concentration by catalase. Superoxide dismutase reversed the effects of ascorbate on the Mehler reaction rates. These results indicate that ascorbate can stimulate Mehler reactions indirectly by promoting a Fenton-type reaction as well as stimulating Mehler reactions directly by reducing 2O₂^- to 2H₂O₂. The promotion of a Fenton-type reaction by ascorbate appears to be the cause of H₂O₂ depletion in resin-untreated solutions.     

SELECTIVE TYPE I PHOTOOXIDATIONS IN MIXTURES OF PORPHYRINS AND ELECTROPHILIC NITROIMIDAZOLES

Abstract— Electrophilic compounds metronidazole (METRO) and misonidazole (MISO), considerably enhance the photooxidation quantum yield of Type I photodynamic substrates such as Trp, Tyr and Cys. For the latter, the quantum yield of photooxidation which can be much greater than one, suggests radical chain reactions. On the other hand, METRO and MISO inhibit ¹O₂ formation because they react at diffusion controlled rate (∼10⁹ M⁻¹ S⁻¹) with porphyrin triplets forming, porphyrin radical cations. As a result, the porphyrins are still able to photosensitize the destruction of Type I substrates even in the absence of O₂. These results are discussed with respect to the possibility of increasing the sensitivity of hypoxic cells to porphyrin photosensitization.     

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.     

CHEMILUMINESCENCE IN THE OXIDATION OF 6-HYDROXYDOPAMINE: EFFECTS OF LUCIGENIN, SCAVENGERS OF ACTIVE OXYGEN, METAL CHELATORS AND THE PRESENCE OF OXYGEN

Abstract— Maximum chemiluminescence in a system containing 6-hydroxydopamine (6-OHDA) and H₂O₂ required the addition of Fe²⁺:EDTA, oxygen, and lucigenin. In this system luminescence was strongly inhibited by catalase (91% inhibition) or 50 m M mannitol (83%), whereas superoxide dismutase or ascorbate did not significantly change the reaction rate. In the absence of lucigenin, 50 m M mannitol (78%), catalase (76%), or ascorbate (73%) inhibited strongly, while superoxide dismutase inhibited by 60%. Removing EDTA from the lucigenin-containing system caused a 79% decrease in luminescence, while the substitution of desferoxamine for EDTA decreased luminescence by 55%. In the presence of desferoxamine plus EDTA the luminescence increased by 30% in comparison with that seen with EDTA alone. Luminescence in the system containing 6-hydroxydopamine, H₂O₂, Fe²⁺:EDTA and lucigenin required the presence of oxygen (93% inhibition anaerobically), consistent with a mechanism involving reductive oxygenation of the lucigenin. It is concluded that luminescence in the presence of lucigenin involves a substantial contribution from H₂O₂ and Fe²⁺ mediated by a mannitol-sensitive intermediate (conceivably Fenton-derived hydroxyl radicals). In the absence of lucigenin, superoxide and an ascorbate-labile component are additional important participants in the process.