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.     

PHOTOINACTIVATION OF A Chlamydomonas MUTANT(NL–11) IN THE PRESENCE OF METHIONINE: ROLES OF H2O2 and O-2

Abstract— A mutant of Chlamydomonas reinhardtii (NL–11) isolated from a wild type (137c+) was inactivated in the light in the presence of methionine at concentrations where the wild type was not inactivated. The inactivation was suppressed by either catalase or superoxide dismutase (SOD). Light-induced H₂O₂ formation and nitroblue tetrazolium (NBT) reduction inNL–11 were greater than those in the wild type. Methionine stimulated both the H₂O₂ formation and the NBT reduction inNL–11 as well as the wild type. The light-induced NBT reduction inNL–11 in the presence of methionine was partially suppressed by externally added SOD suggesting the participation of O^-₂. These results suggest that the hypersensitivity ofNL–11 to methionine in the light is due to stimulated formation of H₂O₂ and O^-₂.     

REGENERATION OF NAD+ AND NADP+ COFACTORS BY PHOTOSENSITIZED ELECTRON TRANSFER

Abstract The irradiation with visible light of photosensitizer dyes like methylene blue or N-methyl phenazonium methyl sulfate leads to the oxidation of reduced coenzymes such as pyridine nucleotides (NADH or NADPH). This photoredox reaction can be used to regenerate the oxidized form of these coenzymes in enzymatic reactions and total consumption of a substrate with catalytic amounts of enzyme, coenzyme and photosensitizer can be performed. The process has been studied on two common enzymatic reactions: ethanol oxidation by alcohol-NAD ⁺ -oxidoreductase and gluconate-6-phosphate oxidation by 6-phospho-D-gluconate-NADP⁺-2-oxidoreductase. In the first case, a turnover number of 1125 has been obtained for the photoregeneration of NAD ⁺ from NADH.     

Improved anti-inflammatory and pharmacokinetic properties for superoxide dismutase by chemical glycosidation with carboxymethylchitin

O-carboxymethylchitin (molecular weight = 1.07 x 10(5), degree of carboxymethylation = 80%, degree of N-acetylation = 91%) was chemically attached to superoxide dismutase by the formation of amide linkages through a carbodiimide catalyzed reaction. The glycosidated enzyme contained about 1.8 mole of polysaccharide per mole of protein and retained 57% of the initial catalytic activity. The anti-inflammatory activity of the enzyme was 2.4 times increased after conjugation with the polysaccharide. The modified superoxide dismutase preparation was remarkably more resistant to inactivation with H(2)O(2) and its plasma half-life time was prolonged from 4.8 min to 69 h.     

Cu, Zn Superoxide dismutase: distorted active site binds substrate without significant energetic cost

Copper, Zinc superoxide dismutase (CuZnSOD) catalyzes the dismutation of the toxic superoxide radical into molecular oxygen and hydrogen peroxide. Dismutation is achieved by reduction and re-oxidation of the active site copper ion, where the superoxide substrate binds. This enzyme is considered to be a perfect enzyme, as the catalytic rate is very high and diffusion controlled. The redox active copper ion is coordinated by four histidine residues in a distorted square planar geometry. Much has been written about the biological significance of the geometry distortion. It is sometimes considered that it should help to tune the redox potential of the copper ion in order to efficiently reduce the first superoxide molecule and oxidize the second one. In this work we present a series of high level theoretical calculations using realistic models, which demonstrate that the distorted geometry is fundamental for the catalytic efficiency of the enzyme by allowing substrate binding without extensive geometric reorganization of the copper complex, upon changing from four to five ligands. A lower limit for the reorganization energy is calculated here in 22 kcal/mol, which would slow down the reaction kinetics by more than 13 orders of magnitude, transforming a perfect enzyme into an inefficient one.     

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.     

Melanocyte-stimulating Properties of Secretory Phospholipase A2

Abstract— Phospholipase A₂ (PLA₂) catalyzes the release of free fatty acids from membrane phospholipids, and its products derived from these fatty acids, such as prostaglandins and leukotrienes, significantly up-regulate the key mela-nogenic enzyme, tyrosinase, in melanocytes. This has led to suggestions that PLA₂ itself triggers melanin synthesis in melanogenesis following UV irradiation or inflammation.
We have examined the effect of secretory PLA₂ (sPLA₂) on melanogenesis in cultured human melanocytes. Secretory PLA₂ stimulated DNA synthesis and melanin synthesis, and these phenomena were completely inhibited by treatment with a phospholipase inhibitor, p- bromophenacyl bromide, demonstrating that the catalytic activity of sPLA₂ is required for melanogenesis. Secretory PLA₂ also stimulated tyrosinase activity, increased the amount of tyrosinase-related protein-1 and up-regulated the expression of both mRNA. These findings suggest that sPLA₂ is an important mediator of UV-induced or postinflammatory pigmentation.     

Superoxide Dismutase Biosensors for Superoxide Radical Analysis

ABSTRACT

Some basic work has been performed on the development and optimisation of superoxide dismutase (SOD) biosensors for superoxide radical analysis. Initially we studied the possibility of obtaining a SOD biosensor using the Clark electrode as indicating sensor. However, the best results were obtained using as indicator a classical amperometric electrode for H₂O₂. In both cases the superoxide radical was generated in situ using the xanthine/xanthine oxidase (XOD) enzyme system, while the SOD was immobilised in kappa-carrageenan gel. The first application was realised by studying the effects in vitro on the superoxide radical of some molecules commonly accepted as radical scavengers.     

LIGHT-INDUCED FORMATION OF O-2˙ OXYGEN RADICALS IN SYSTEMS CONTAINING CHLOROPHYLL

It has been shown recently that photosystem 1 particles, photosystem 1 lipid vesicles and chlorophyll-a lipid vesicles show identical photochemical reactions in the presence of oxygen e.g. H⁺-and O₂-uptake (Van Ginkel, 1979). Therefore, spin-trapping experiments were done to identify the oxygen radicals formed. The spintrap phenyltertiarybutylnitrone (PBN) failed to yield information about oxygen radicals. With the spintrap 5,5-dimethyl-1-pyrroline-1-oxide (DMPO), however, we obtained a mixed spectrum of O^-_2˙ and OH·-adducts generated in chloroplasts, photosystem 1 particles or chlorophyll-a lipid vesicles. These data indicate that chlorophyll-a in an artificial membrane can also catalyze O^-_2˙-formation. Chlorophyll-a lipid vesicles catalyze light-induced formation of the Tiron-semiquinone free radical, which has been proposed as a specific O^-_2˙-probe (Greenstock and Miller, 1975). However, OH· scavengers strongly reduce the formation of this radical, whereas superoxide dismutase does not. Pulse-radiolysis measurements showed that the rate constant for the reaction of Tiron with OH· is 8.2 · 10⁹M^-1 s^-1, which is considerably higher than the published Tiron/O^-_2˙ rate constants. Therefore, Tiron is a better spin probe for OH· than for O^-_2˙. We suggest that light-induced H⁺-and O^-_2˙-uptake in membranes containing chlorophyll-a in the presence of ascorbate is caused mainly by the very rapid reaction of OH· with ascorbate.     

NADH Photosynthesis System with Affordable Electron Supply and Inhibited NADH Oxidation

Photosynthesis offers a green approach for the recycling of nicotinamide cofactors primarily NADH in bio-redox reactions. Herein, we report an NADH photosynthesis system where the oxidation of biomass derivatives is designed as an electron supply module (ESM) to afford electrons and superoxide dismutase/catalase (SOD/CAT) cascade catalysis is designed as a reactive oxygen species (ROS) elimination module (REM) to inhibit NADH degradation. Glucose as the electron donor guarantees the reaction sustainability accompanied with oxidative products of gluconic acid and formic acid. Meanwhile, enzyme cascades of SOD/CAT greatly eliminate ROS, leading to a ≈2.00-fold elevation of NADH yield (61.1 % vs. 30.7 %). The initial reaction rate and turnover frequency (TOF) increased by 2.50 times and 2.54 times, respectively, compared with those systems without REM. Our study establishes a novel and efficient platform for NADH photosynthesis coupled to biomass-to-chemical conversion.     

Oxidation of kojic acid catalyzed by manganese peroxidase from Ceriporiopsis subvermispora in the absence of hydrogen peroxide

We have previously reported the oxidation of kojic acid catalyzed by manganese peroxidase (MnP) from Ceriporiopsis subvermispora. This reaction is strictly dependent on Mn(II), although it does not require the addition of hydrogen peroxide. We have extended these studies because this reaction can be considered as a model system for the in situ generation of hydrogen peroxide in natural environments. We show here that oxidation of kojic acid with horseradish peroxidase (HRP) plus hydrogen peroxide or with manganic acetate rendered a product with identical chromatographic and spectral properties as the one obtained in the reaction catalyzed by MnP. The initial lag observed in the latter reaction decreased significantly upon UV irradiation of the substrate. On the other hand, ascorbic acid increased the lag and did not affect the yield of the reaction. The superoxide anion trapping agents glutathione, nitroblue tetrazolium, and superoxide dismutase markedly affected the reaction. In contrast, addition of the hydroxyl radical scavengers mannitol and salicylic acid had no effect. Based on these results, a mechanism for the MnP-catalyzed reaction is proposed.     

Interactions of water-soluble polymers with small molecules I: Poly(2-diethylaminoethyl methacrylate)-orange II and ethyl orange systems

The interactions between poly(2-diethylaminoethyl methacrylate) (PDEAEMA) and orange II (OII) or ethyl orange (EO) have been examined in detail by measuring the transmittance and the specific conductance of the solutions. The mechanisms of flocculation and deflocculation have been investigated by changing the intrinsic viscosity, the degree of neutralization and alkyl groups of PDEAEMA or by adding NaCl, urea or alcohols. The complexation of PDEAEMA with dyes is completed at the same mole ratio but is not dependent on the molecular weight of PDEAEMA. OII molecules bind with PDEAEMA by electrostatic interactions, followed by flocculation through hydrogen bondings between hydroxyl groups on OII molecules bound. EO molecules first interact with PDEAEMA electrostatically in the same ways as OII, but flocculation occurs by hydrophobic interactions between ethyl groups on EO molecules bound. By further addition of dyes to the complex, OII or EO molecules already bound can interact with free OII or EO molecules newly added through hydrogen/hydrophobic interaction between OII or EO molecules. Deflocculation occurs by the electrostatic repulsion between anions of dyes bound, such as (PDEAEMA-OII)-hydrogen bonding-(OII-anions) or (PDEAEMA-EO)-hydrophobic bonding-(EO-anions) newly formed.     

THE GENERATION OF HYDROXYL RADICALS IN BIOLOGIC SYSTEMS: TOXICOLOGICAL ASPECTS

Abstract— The formation of hydroxyl radicals in vitro was studied through their reaction with 2-keto-4-thiomethylbutyric acid to form ethylene gas. The autoxidation reaction of 6-aminodopamine served as a model source of hydroxyl radicals. Ethylene production was suppressed by catalase and by superoxide dismutase, indicating that both hydrogen peroxide and superoxide were involved in the reaction. Hydroxyl radical scavengers (thiourea > benzoate > ethanol) suppressed ethylene production in good agreement with their respective rate constants for reaction with hydroxyl radicals. Urea served as a negative control. Several substituted thiourea derivatives also suppressed ethylene production to a similar degree as thiourea itself. Biologic studies centered on several cytotoxic agents whose mechanisms of action are thought to involve hydroxyl radicals. These agents included alloxan, which destroys the beta cells of the pancreas, and 6-hydroxy- and 6-aminodopamine, which destroy sympathetic nerves. Damage to tissues in vivo was blocked to varying degrees by pretreatment of animals with hydroxyl radical scavengers such as ethanol or the thiourea derivatives. In addition, hydroxyl radical scavengers blocked the action of 5,7-dihydroxytryptamine, a neurotoxin whose effects on noradrenaline neurons were previously shown to be blocked by inhibitors of monoamine oxidase. The data indicate that these cell toxins produce their damaging actions on specific target cells through the intracellular generation of hydroxyl radicals.     

β-CD-Shiff碱铜(Ⅱ)配合物模拟酶催化光度法的研究

合成了Shiff碱2-羟基-1-萘醛缩-2-氨基噻唑(HNATS)及其铜配合物,发现配合物Cu(Ⅱ)-(HNATS)~2具有显著的过氧化物模拟酶活性,可催化H~2O~2氧化4-氨基安替比林与2,4-二氯苯酚偶联反应。研究了β-环糊精对模拟酶催化活性的影响,探讨了反应机理,考察了反应条件和共存物质的影响,建立了新的测定超氧阴离子自由基(O~2^-^.)的分光光度法,线性范围为0～5.0×10^-^4mol/L,检出限为5.0×10^-^6mol/L。方法用于测定人体血液中超氧化物歧化酶(SOD)活性,结果满意。     

QUENCHING OF PEROXIDIZED LUMINOL CHEMILUMINESCENCE BY REDUCED PYRIDINE NUCLEOTIDES

Abstract— Reduced pyridine nucleotides were observed to cause a delay as well as a diminution of light emission from peroxidized luminol at pH 6.5. Other reductants were found to have similar effects. Neither superoxide nor hydroxyl radical scavengers quenched chemiluminescence of luminol in the presence of horseradish peroxidase and H₂O₂. A scheme in which reductants such as NADH and NADPH prevent peroxidase from oxidizing luminol to aminophthalate is proposed. Moreover, it is concluded that neither O₂⁻nor OH' play a role in the peroxidation of luminol by horseradish peroxidase.     

Determination of superoxide dismutase and SOD-mimetic activities by a chemical system: Co2/H2O2/lucigenin

The bright chemiluminescence has been observed in the system: Co²⁺/hydrogen peroxide/lucigenin. The chemiluminescence intensity was directly proportional to either cobalt, hydrogen peroxide, or lucigenin concentrations. A procedure of determination of superoxide dismutase (SOD) activity by the chemiluminescence method in the cobalt–hydrogen peroxide–lucigenin system at pH 8.5 is suggested. A linear dependence was established between a relative chemiluminescence intensity and SOD concentration in the range of SOD concentrations between 0 and 4.5 nM, c _1/2 = 0.8 nM. The determination of SOD activity was performed in several tissue samples (rat plasma, erythrocyte hemolysate, and liver mitochondria). A technique of tissue sample preparation with the use of thermal inactivation of interfering proteins at 60 °C was used. The method was successfully applied for comparison of the efficiency of SOD mimetics.     

PHOTOLYSIS OF SUBSTITUTED NAPHTHALENES ON SiO2 AND Al2O3

Abstract— Photolysis of naphthalene on the surface of SiO₂ under an atmosphere of air produces phthalic acid as the only major photoproduct, accounting for 49%o of the consumed naphthalene. Photolysis on Al₂O₃ also produces phthalic acid, in 31% yield. Photolysis of 1 -methylnaphthalene on SiO₂ proceeds under similar conditions to produce 2-acetylbenzoic acid (35%) as the major photoproduct with the production of a small amount of I-naphthaldchyde (6%). 1-Cyanonaphthalene does not photooxidize under similar conditions. The presence of oxygen is necessary for the photodecomposition of naphthalene and 1-methylnaphthalene to proceed. Superoxide formed from the photolysis of naphthalene at the SiO₂/air interface is readily observed by electron paramagnetic resonance spectroscopy. In the absence of naphthalene no superoxide is observed. A mechanism involving electron transfer from the S₁ state of the naphthalene to O₂ is proposed on the basis of these observations and related literature precedent.     

Ultrasound effects on the antioxidative defense systems of Porphyridium cruentum

Ultrasound is a special physical stimulus that has a variety of biological effects. This study provides a first systemic investigation on the ultrasound-induced oxidation and protection actions of the antioxidant defense system in Porphyridium cruentum. The hydroxyl radical and superoxide anion radical scavenging ability of the cells and the electrolyte leakage of the cell membrane were examined. The change of glutathione and carotenoids produced with/without ultrasonic processing were measured; the enzyme activities of superoxide dismutase, catalase, and membrane bound ATPases (Na(+)/K(+)-ATPase, Ca(2+)/Mg(2+)-ATPase) were evaluated for either ultrasound-treated or untreated P. cruentum. The hydroxyl radical and superoxide anion radical scavenging ability of ultrasound-treated P. cruentum increase 49.8 and 76.0%, respectively, of which the electrolyte leakage and malonyldialdehyde accumulation are also found increased 48.6 and 48.0%, respectively, indicating a state of oxidative stress. A significant enhancement of the activities of superoxide dismutase by 53.5%, catalase, membrane bound ATPases (Na(+)/K(+)-ATPase, Ca(2+)/Mg(2+)-ATPase increased by 67.7 and 69.3%, respectively), and the increment of glutathione and carotenoids production are also observed. These results suggested that oxidative stress manifested by elevated reactive oxygen species levels and malonyldialdehyde contents might be resulted from the biophysical responses of P. cruentum to the physical stimuli, and most likely the enhanced antioxidation ability of the algal cells stimuli by ultrasonic comes from the enhancement of enzymatic and nonenzymatic preventive substances as observed in this work.     

Xanthine oxidase-assisted catalysis by dopamine β-hydroxylase: Mechanistic considerations on the role of superoxide anion

Dopamine β-monooxygenase catalyzes the transformation of dopamine into norepinephrine by inserting an O-atom on a benzylic C–H bond. The activation of O₂ occurs at a copper-containing active site in the presence of a reducer (ascorbate) that enables that copper ions be reduced to Cu(I) and reoxidized during catalysis. In the present paper, we establish that the xanthine/xanthine oxidase coupled system is a cofactor for this enzyme, and that hydroxylation of substrate tyramine is time-dependent. Using superoxide dismutase, we unambiguously prove that the species responsible for the hydroxylase activity is superoxide anion. The optimum pH for this activity is 6.8, a value about one pH unit higher than the physiological pH for the enzyme. Moreover, we propose a mechanism that takes into account all of our results, and describes putative interactions between the copper ions of the active site and superoxide anion.     

The Kinetics Behavior of the Reduction of Formaldehyde Catalyzed by Alcohol Dehydrogenase (ADH) and Partial Uncompetitive Substrate Inhibition by NADH

Alcohol dehydrogenase (ADH) catalyzes the final step in the biosynthesis of methanol from CO₂. Here, we report the steady-state kinetics for ADH, using a homogeneous enzyme preparation with formaldehyde as the substrate and nicotinamide adenine dinucleotide (NADH) as the cofactor. When changing NADH concentrations with the fixed concentrations of HCHO (more or less than NADH), kinetic studies revealed a particular zigzag phenomenon for the first time. Increasing formaldehyde concentration can weaken substrate inhibition and improve catalytic efficiency. The kinetic mechanism of ADH was analyzed using the secondary fitting method. The double reciprocal plots (1/v～1/[HCHO] and 1/[NADH]) strongly demonstrated that the substrate inhibition by NADH was uncompetitive versus formaldehyde and partial. In the direction of formaldehyde reduction, ADH has an ordered kinetic mechanism with formaldehyde adding to enzyme first and product methanol released last. The second reactant NADH can combine with the enzyme–methanol complex and then methanol dissociates from it at a slower rate than from enzyme–methanol. The reaction velocity depends on the relative rates of the alternative pathways. The addition of NADH also accelerates the releasing of methanol. As a result, substrate inhibition and activation occurred intermittently, and the zigzag double reciprocal plot (1/v～1/[NADH]) was obtained.