Enhancement of luminol-dependent chemiluminescence in an aqueous NaCl/H2O2 solution by argon

It was found that the bubbling of argon through NaCl/H2O2 aqueous solutions results in the development of intense sustained luminol-dependent chemiluminescence. Bubbling of nitrogen and air through similar solutions does not result in such effect. The relationship between argon-supported chemiluminescence and initial concentrations of NaCl and H2O2 is characterized by threshold effects. In NaCl/H2O2 solutions blown with argon, hypochlorite was found, indicating that argon intensifies the reaction of chloride oxidation with H2O2. It is suggested that the enhancement of this reaction in aqueous solutions saturated with argon is related to specific changes in the properties of water, which is a highly nonequilibrium system. Possible consequences of relatively high concentrations of argon in the atmosphere for the chemical processes that occur in aqueous systems and, in particular, living systems are discussed.     

Chemiluminescence study of active oxygen species produced by TiO2 photocatalytic reaction.

Two chemiluminescence approaches have been used for study of active oxygen species produced by the TiO2 photocatalytic reaction. One is based on flow injection analysis (FIA)-luminol chemiluminescence (CL); another is a time-resolved CL method. In the FIA-CL experiment, an UV-illuminated TiO2 suspension and water were passed into a mixing cell by two separate flow lines. Luminol solution was injected into the water flow line at different times. The injected luminol reacted with active oxygen species generated by the TiO2 photocatalytic reaction in a mixing coil and produced CL. It was found that the maximum CL was detected at the first injection of luminol. CL intensity decreased with time of injection. When the luminol was injected after 5 min, the CL intensity was almost unchanged. Addition of scavengers of active oxygen species indicated that the CL produced early in the 5 min was caused by O2- and H2O2, while CL after 5 min was only from H2O2. In the time-resolved CL, the third harmonic wavelength of Nd:YAG laser (355 nm) was used as a UV light source, and CL was detected by a PMT and recorded in a millisecond time scale using a digital oscilloscope. It was found that CL induced by the photocatalytic reaction increased with concentration of the TiO2 suspension. Scavengers of active oxygen species of *OH, O2- and H2O2 were added to study the involvement of the active oxygen species.     

Interaction of tert-butyl hydroperoxide with hypochlorite induces peroxyl radicals. A chemiluminescence study

The interaction of hypochlorite (HOCl/OCl-) with tert-butyl hydroperoxide ((CH3)3COOH) was investigated by chemiluminescence. It was shown that the addition of HOCl/OCl- to (CH3)3COOH induces a fast chemiluminescent flash. The intensity of this flash increases with the increase in both HOCl/OCl- and (CH3)3COOH concentration. The chemiluminescence is quenched in a concentration-dependent manner in the presence of free radical spin traps N-tert-butyl nitrone and alpha-(4-pyridyl-1-oxyl)-N-tert-butyl nitrone. This fact proves that free radicals take part in the interaction of HOCl/OCl- and (CH3)3COOH. Hypochlorite yielded a very similar chemiluminescence spectrum in its reaction with (CH3)3COOH as Ce4+. It differed considerably from the spectrum in the system H2O2 and HOCl/OCl-. It is well known that the interaction of Ce4+ and (CH3)3COOH produces peroxyl radicals. These results confirm the hyothesis that the interaction of HOCl/OCl- and (CH3)3COOH is mediated by peroxyl radicals. Thus, organic hydroperoxides always present in unsaturated lipids can induce lipid peroxidation processes in the reaction with HOCl/OCl-.     

Light generation with Fenton's reagent. Its relationship to granulocyte chemiluminescence.

A simple chemical system consisting of FeSO4 and H2O2 (Fenton's reagent) was shown to emit light (chemiluminescence). The addition of tryptophan to the reaction markedly enhanced light production. Very little chemiluminescence was observed when H2O2 was omitted from the reaction and when ferric, instead of ferrous, ions were used. Hydroxyl radical (OH.) and singlet oxygen (1 deltagO2) quenchers suppressed chemiluminescence of the FeSO4 + tryptophan + H2O2 system; and, deuterium oxide (2H2O) enhanced chemiluminescence of both FeSO4 reactions. These observations suggest that a radical chain reaction involving both OH. and 1 deltag O2 is responsible for the chemiluminescent reactions. Six iron-containing proteins, some of which are located within granulocytes, all emitted light in the presence of H2O2. Since iron and H2O2 are present in metabolically stimulated granulocytes, it is likely that chemiluminescent reactions similar to the ones demonstrated in this study account for part of the chemiluminescence of activated granulocytes.     

Co-oxidation of salicylate and cholesterol during the oxidation of metmyoglobin by H2O2

The reaction between metmyoglobin and H2O2 proceeds with oxidation of the hemo-protein iron to a higher valence state and consumption of the peroxide. This reaction is further associated with (a) O2 evolution; (b) hydroxylation of the aromatic compound salicylate to yield a set of dihydroxybenzoic acid derivatives (analyzed by HPLC with electrochemical detection); (c) autoxidation of cholesterol with formation of 3 beta-hydroxy-5-alpha-cholest-6-ene-5-hydroperoxide; and (d) formation of electronically excited states detected by low-level chemiluminescence. The heterolytic scission of the O-O bond of hydroperoxides by metmyoglobin causes the formation of an oxidizing equivalent capable of promoting peroxidation of linoleate and arachidonate (as indicated by the parallel formation of thiobarbituric acid-reactive material and an enhancement of chemiluminescence intensity). The identity of the oxidizing equivalent(s) is discussed in terms of the formation of a relatively stable higher state of oxidation of heme Fe (FeIV-OH or FeV = O) as well as on possible intermediate species derived during the decomposition of H2O2 by metmyoglobin, such as HO.and 1O2. These species might be involved either simultaneously or sequentially in the peroxidation of fatty acids as well as in the tissue damage associated with the formation of H2O2 in ischemic-reperfusion states.     

Kinetics of O2 evolution from H2O2 catalyzed by the oxygen-evolving complex: investigation of the S1-dependent reaction

The evolution of O2 from H2O2 catalyzed by the oxygen-evolving complex (OEC) in darkness was examined with photosystem II reaction center complex preparations from spinach. Flash illumination of dark-adapted reaction centers was used to make S0-enriched or S1-enriched complexes. The membranes catalyzed O2 evolution from H2O2 when preset to either the S0 or S1 state. However, only the S0-state reaction was inhibited by carbonyl cyanide m-chlorophenylhydrazone and dependent on chloride. These results indicate that (1) the S0-dependent and S1-dependent catalytic cycles can be separated by flash illumination, (2) the S0-dependent reaction involves the formation of the S2 state, and (3) the S1-dependent reaction does not involve the formation of the S2 or S3 states. A kinetic study of the S1-dependent reaction revealed a rapid equilibrium ordered mechanism in which (1) the binding of Ca(II) must precede the binding of H2O2 to the OEC and (2) the reaction of Ca(II) with the free enzyme is at thermodynamic equilibrium such that Ca(II) does not necessarily dissociate after each catalytic cycle.     

Chemiluminescence decrease of singlet oxygen in NaClO+H2O2 reaction in the presence of different anti-cataract drugs]

Singlet oxygen was produced in chemical reaction NaClO+ H2O2. Action of different well-known anti-cataract drugs on this reaction was studied. There is no doubt that the singlet oxygen chemiluminescence decreases in the presence of Catalin and Baineiting. Finnish Catachrom Ophthan, Vita iodurol (France) and Quinax (USA) have no such effect at all which may be a result of the interaction of these remedies with H2O2 and/or with NaClO.     

Detection of activated O2 species in vitro and in rat lungs by chemiluminescence

This study used chemiluminescence, an "on-line" photon-counting technique, to detect and characterize activated O2 species in vitro and in isolated rat lungs. The sensitivity and specificity of enhanced chemiluminescence for superoxide anion (O2-.) and hydrogen peroxide (H2O2) was evaluated in vitro. The effect of media conditions (such as O2 tension, albumin concentration, and sulfhydryl group availability) on luminescence was assessed in vitro. Xanthine-xanthine oxidase (X-XO) primarily produced superoxide anion in vitro. Enhanced chemiluminescence varied directly with the dose of luminescent probe used and the quantity of activated O2 species administered. The strength of the luminescent signal was also dependent on the concentration of albumin and O2 in the media. Lucigenin was more sensitive than luminol to the presence of O2-. and, unlike luminol, lucigenin did not alter radical production by XO. However, neither luminescent probe was specific for O2-., as both detected H2O2 and O2 in vitro. H2O2-induced chemiluminescence was inhibited by catalase but not superoxide dismutase (SOD), while X-XO-induced luminescence was inhibited by SOD but not catalase. SOD-inhibitable chemiluminescence was a sensitive and specific marker for O2-. production in vitro. Once the sensitivity-specificity of enhanced chemiluminescence was defined in vitro, this technique was used to explore the mechanism by which exogenous X-XO reduced hypoxic vasoconstriction in isolated rat lungs. The vascular paresis, caused by administration of X-XO to the rat lung, resulted from a brief burst of O2-. production rather than a sustained alteration of lung radical levels.     

Studies of the primary oxygen intermediate in the reaction of fully reduced cytochrome oxidase.

The formation and disappearance of a photosensitive species during the reaction of reduced cytochrome c oxidase (putatively a3II.O2), EC 1.9.3.1, has been followed by (a) mixing a3II.CO with O2 in a stopped flow apparatus; (b) initiating the oxygen-oxidase reaction by removing CO with a laser flash; (c) probing the reaction mixture for photosensitivity with a second laser flash. Photosensitivity appears in the reaction mixture after the first laser flash, reaches a maximum after 50-60 microseconds ([O2] greater than 100 microM), and disappears in a further 50-100 microseconds. The kinetics can be represented by the scheme [formula: see text]. In species B, O2 is associated with the protein, possibly CuB, but not with the heme. Species C is the photosensitive a3II.O2 complex, and in D, a3 iron has been oxidized. The formation of species C is responsible for the rapid phase of absorbance change in the oxidase-oxygen reaction. The rate of reaction with oxygen approaches the limit of 35,000 s-1 at high oxygen. Nitric oxide, however, reacts with FeII oxidase with a rate of 1 x 10(8) M-1 s-1, which is accurately maintained up to an observed rate of 10(5) s-1. In flash photolysis experiments, approximately half of the photodissociated nitric oxidase recombines in a biphasic geminate reaction with rates of 1 x 10(8) s-1 and 1 x 10(7) s-1.     

Characteristics of luminol chemiluminescence induced by the catalytic action of myeloperoxidase

The effects of pH, luminol myeloperoxidase and hydrogen peroxide concentrations on the intensity of luminol chemiluminescence induced by myeloperoxidase catalysis were investigated. It was found that the intensity of luminescence is proportional to the enzyme concentration (up to 8.10(-8) M) and reaches the saturation level at higher enzyme concentrations. The dependence of chemiluminescence intensity on [H2O2] is bell-shaped: at H2O2 concentrations above 1.10(-4) M the luminescence is inhibited with a maximum at neutral values of pH. Luminol at concentrations above 5.10(-5) M inhibits this process. It was demonstrated that the effects of singlet oxygen, superoxide and hydroxyl radicals on the chemiluminescence reaction are insignificant. Luminol oxidation in the course of the myeloperoxidase reaction is induced by hypochlorite.     

Chemiluminescence study on the peroxidation of linoleic acid initiated by the reaction of ferrous iron with hydrogen peroxide

Linoleic acid was used as a model system to study lipid peroxidation initiated by the reaction of ferrous iron with hydrogen peroxide. Low-level chemiluminescence of the peroxidation was measured with a high-sensitivity single-photon counter. It was found that the luminescence primarily comes from the dimol reaction of singlet oxygen and that the peak intensity of emission is a quadratic function of the concentration of either Fe2+ or H2O2, provided that the other Fenton reagent is in great excess. Under the same conditions, analysis on reaction kinetics shows a linear relationship between the maximal level of the initiator formed by the Fenton reaction and the initial concentration of Fe2+ or H2O2. This implies that the peak intensity of the chemiluminescence may be a good index of the maximal level of the initiator.     

Generation of excited species catalyzed by horseradish peroxidase or hemin in the presence of reduced glutathione and H2O2

Horseradish peroxidase (HRP) (EC 1.11.1.7) catalyzes the oxidation of reduced glutathione. This reaction is accompanied by light emission, which is attributed to the generation of singlet oxygen. The chemiluminescence is directly related to thiyl radical formation, as deduced from the correlation between the time course of HRP-compound II formation and light emission in the presence of different amounts of H2O2. Superoxide dismutase has an inhibitory effect on the chemiluminescence without affecting the HRP-compound II formation. This indicates the direct involvement of superoxide radicals in the production of photoemissive species. Replacement of HRP by hemin is also accompanied by chemiluminescence.     

Features of transformation of phosphates in Rhodobacter sphaeroides chromatophores

We have found the ATP production in the Rhodobacter sphaeroides chromatophores illuminated by single short light flash, that is under conditions when the proton gradient formed as a result of electron transport after the second flash, is absent. The ATP synthesis was accompanied by the H2O2 formation. Simultaneous formation of H2O2 is indicative of the oxidative activation of phosphate during the ATP synthesis, as in the model systems with isolated chlorophyll. These data provide a theoretical background to the fitting of illumination parameters in both laboratory and industrial photobioreactors with photosynthetic bacteria used in biotechnological processes.     

Chemiluminescence detection of H2O2 produced by human neutrophils during the respiratory burst

A sensitive luminol-dependent chemiluminescence assay for H2O2 was developed for the indirect determination of the transient changes in NADPH oxidase activity associated with the respiratory burst of human neutrophils. A relatively large, controlled amount of horseradish peroxidase was used in combination with added luminol to rapidly remove and simultaneously detect H2O2 as soon as it is formed, thus preventing its accumulation during burst activity and minimizing the effects of side reactions. Cell-derived myeloperoxidase and possibly catalase were inhibited with 90 microM sodium azide to maintain the total catalytic activity toward H2O2 at a constant level. Chemiluminescence measurements of the respiratory burst activity of human neutrophils stimulated with N-formyl-Met-Leu-Phe (fMLP) were in good agreement with measurements made using an established fluorometric assay based on similar principles (P. A. Hyslop and L. A. Sklar (1984) Anal. Biochem. 141, 280-286). In contrast to fluorometry, the chemiluminescence progress curves reflect the instantaneous rather than the integrated levels of H2O2 at any time and are thus a more direct measure of the activity of the NADPH oxidase. This advantage, as well as higher signal-to-noise ratios and greater inherent sensitivity, distinguishes chemiluminescence as a means of following burst activity. The onset of fMLP-stimulated H2O2 generation was detectable by chemiluminescence within 2 s of stimulation (as opposed to more than double this time by fluorometry), showing that high sensitivity is an important consideration in evaluating respiratory burst kinetics. In contrast to fMLP stimulation, longer and concentration-dependent onset times were observed when phorbol myristate acetate was used as a stimulus.     

The involvement of singlet oxygen in copper-phenanthroline/H2O2-induced DNA base damage: a chemiluminescent study

Copper in the presence of excess 1,10-phenanthroline, a reducing agent, and H2O2 causes DNA base damage as well as strand breakage. We have reported in previous work that a strong chemiluminescence was followed by DNA base damage in this system, which is characteristic of guanine. In the present work, the mechanism of the chemiluminescence was studied. Results show that the luminescence was inhibited by all three classes of reactive oxygen species (*OH, O2-, (1)O2) scavengers to different degrees. Singlet oxygen scavengers showed the most powerful inhibition while the other two classes of scavengers were relatively weaker. The emission intensity in D2O was 3-fold that in H2O. Comparing the effect of scavengers on the luminescence of DNA with that of dGMP, the ratio of inhibition was similar. On the other hand, DNA breakage analysis showed that inhibition by the singlet oxygen scavenger NaN3 of strand breakage was strong and comparable to that of the scavengers of the two oxygen radicals. The results suggest that singlet oxygen may be a major factor for the chemiluminescence of guanine, while DNA strand breakage may be caused by many active species.     

Characteristics of antioxidant properties of 20-hydroxyecdysone in low density lipoproteins by kinetic parameters of chemiluminescence

20-Hydroxyecdysone is capable to terminate the lipid free-radical oxidation in low density lipoprotein in vitro as displayed by the kinetic chemiluminescence parameters. In concentrations interval from 2 x 10(-6) mol/l up to 8 x 10(-6) mol/l it statistically reliably reduces maximum of the first flash intensity of the low density lipoprotein Fe(2+)-initiated chemiluminescence. It testifies about Fe(2+)-initiated lipid peroxide process decomposition in low density lipoprotein slowing down by 20-hydroxyecdysone. In concentration of 20-hydroxyecdysone 8 x 10(-6) mol/l the statistically reliable reduction of angle tangent of an ascending branch of the second flash of low density lipoprotein Fe(2+)-initiated chemiluminescence was found. This is a result of free-radical lipid oxidation rate reduction in the low density lipoprotein at the 20-hydroxyeodysone presence. The equations of the kinetic parameters linear dependences Fe(2+)-initiated chemiluminescence in low density lipoprotein on the concentration of 20-hydroxyeodysone and hydroquinone have been received. The correlation factors in the interval from 0.8980 up to 0.6789 have been calculated. Thus, the assumption has been forwarded that 20-hydroxyeodysone has antioxidizing properties. However, its antioxidizing activity in free radical lipid oxidation of is low density lipoprotein is as less as for hydroquinone.     

Electron acceptors of bacterial photosynthetic reaction centers. II. H+ binding coupled to secondary electron transfer in the quinone acceptor complex.

The photoreduction of ubiquinone in the electron acceptor complex (QIQII) of photosynthetic reaction centers from Rhodopseudomonas sphaeroides, R26, was studied in a series of short, saturating flashes. The specific involvement of H+ in the reduction was revealed by the pH dependence of the electron transfer events and by net H+ binding during the formation of ubiquinol, which requires two turnovers of the photochemical act. On the first flash QII receives an electron via QI to form a stable ubisemiquinone anion (QII-); the second flash generates QI-. At low pH the two semiquinones rapidly disproportionate with the uptake of 2 H+, to produce QIIH2. This yields out-of-phase binary oscillations for the formation of anionic semiquinone and for H+ uptake. Above pH 6 there is a progressive increase in H+ binding on the first flash and an equivalent decrease in binding on the second flash until, at about pH 9.5, the extent of H+ binding is the same on all flashes. The semiquinone oscillations, however, are undiminished up to pH 9. It is suggested that a non-chromophoric, acid-base group undergoes a pK shift in response to the appearance of the anionic semiquinone and that this group is the site of protonation on the first flash. The acid-base group, which may be in the reaction center protein, appears to be subsequently involved in the protonation events leading to fully reduced ubiquinol. The other proton in the two electron reduction of ubiquinone is always taken up on the second flash and is bound directly to QII-. At pH values above 8.0, it is rate limiting for the disproportionation and the kinetics, which are diffusion controlled, are properly responsive to the prevailing pH. Below pH 8, however, a further step in the reaction mechanism was shown to be rate limiting for both H+ binding electron transfer following the second flash.     

Generation of O2- and tyrosine cation-mediated chemiluminescence during the fertilization of sea urchin eggs

Sea urchin eggs emit light in the visible region during their fertilization. Judging from the chemiluminescence spectra, one of the excited species generated is considered to have originated from a tyrosine cation radical-mediated reaction. Chemiluminescence probes such as luminol or a cypridina luciferin analog (See text) are useful for detecting the ovoperoxidase +H2O2 reaction associated with membrane hardening and O2- generation, respectively, during fertilization of sea urchin eggs.     

Analysis of horseradish peroxidase-amplified chemiluminescence produced by human neutrophils reveals a role for the superoxide anion in the light emitting reaction

When polymorphonuclear leukocytes and soluble or particulate matter interact, the cells produce chemiluminescence, which is linked to activation of the oxidative metabolism of the cells. A luminol chemiluminescence assay in which the reaction mixture contains a relatively large amount of horseradish peroxidase combined with sodium azide has been proposed to quantitate H2O2 produced by human neutrophils during the respiratory burst (M.P. Wymann, V. von Tscharner, D. A. Deranleau, and M. Baggiolini (1987) Anal. Biochem. 165, 371-378). We found, when comparing the response to concanavalin A and a formylated peptide (formylmethionyl-leucyl-phenylalanine), that neutrophils produce H2O2 that is not detected as chemiluminescence by the horseradish peroxidase-azide-luminol system. Furthermore, the horseradish peroxidase-amplified chemiluminescence response obtained from granule-depleted neutrophil cytoplasts is inhibited by superoxide dismutase, an O2- scavanger. Based on these results, we question the specificity of the described technique for H2O2. The usefulness of the technique in the determining the extracellular and intracellular production of oxidative metabolites is discussed.     

Induction of active forms of oxygen by biotic elicitors in tomato cell cultures

The elicitor-induced generation of two oxygen species in tomato cell culture as well as their involvement into hypersensitive reaction was investigated. Generation of superoxide O2.- was measured by a lucigenin-related chemiluminescence. Accumulation of hydrogen peroxide H2O2 was measured by a fluorescent probe pyranin. Xylanase and chitosan were used as biotic elicitors with different mode of action. It was found that both O2.- and H2O2 had been accumulated in elicitor-treated tomato cells. The results obtained show that reactive oxidants are important signal transduction elements for activation of hypersensitive response in tomato cells.