Mediatorless electrocatalytic reduction of hydrogen peroxide at graphite electrodes chemically modified with peroxidases

The electrocatalytic reduction of H₂O₂ was studied for carbonaceous electrodes modified with horse-radish peroxidase (HRP), microperoxidase (MP), and lactoperoxidase (LP). The carbonaceous electrodes were of three different graphites, carbon and glassy carbon. The peroxidase modified electrode was inserted as the working electrode in a flow through amperometric cell of the wall jet type and connected to a flow injection system. The effect of different pretreatments of the electrode surface prior to adsorption of the enzyme was investigated. Heating the electrodes in a muffle furnace at 700°C for 1.5 min was found to yield the highest currents. The electrocatalytic current for HRP-modified electrodes starts at about +600 mV vs. Ag/AgCl (pH 7.0) and reaches a maximum value at about −200 mV. For MP- and LP-modified electrodes the currents start at a lower potential (≈ 300 mV). For the best electrode material for HRP, straight calibration curves were obtained between 1 and 500 μM H₂O₂ at 0 mV. The mechanism for the electron transfer from the electrode to the adsorbed peroxidase is discussed. Deliberate modification of the electrode surface with quinoid type electroactive species was found to mediate the reaction. It is proposed that spontaneously occurring electrochemically active surface groups mediate the electron transfer to the adsorbed enzyme. However, a contribution to the observed current from a direct electron transfer cannot be ruled out.     

Cytochemical localization of hydrogen peroxide generating sites in the rat thyroid gland

Sites of H₂O₂ generation in lightly prefixed, intact thyroid follicles were studied by two cytochemical reactions: peroxidase-dependent DAB oxidation and cerium precipitation. In both cases reaction product accumulated on the apical surface of the follicle cell at the membrane-colloid interface. The former reaction was inhibited by the peroxidase inhibitor, aminotriazole; both reactions were blocked by the presence of catalase. NADH in the medium slightly increased the amount of cerium precipitation. The ferricyanide technique for oxidoreductase activity was also applied; reaction product again was associated with the apical surface. These results strongly imply that the follicle cells have a NADH oxidizing system generating H₂O₂ at the apical plasma membrane.     

Shift in the localization of sites of hydrogen peroxide production in brain mitochondria by mitochondrial stress

We have determined the underlying sites of H(2)O(2) generation by isolated rat brain mitochondria and how these can shift depending on the presence of respiratory substrates, electron transport chain modulators and exposure to stressors. H(2)O(2) production was determined using the fluorogenic Amplex red and peroxidase system. H(2)O(2) production was higher when succinate was used as a respiratory substrate than with another FAD-dependent substrate, alpha-glycerophosphate, or with the NAD-dependent substrates, glutamate/malate. Depolarization by the uncoupler p-trifluoromethoxyphenylhydrazone decreased H(2)O(2) production stimulated by all respiratory substrates. H(2)O(2) production supported by succinate during reverse transfer of electrons was decreased by inhibitors of complex I (rotenone and diphenyleneiodonium) whereas in glutamate/malate-oxidizing mitochondria diphenyleneiodonium decreased while rotenone increased H(2)O(2) generation. The complex III inhibitors antimycin and myxothiazol decreased succinate-induced H(2)O(2) production but stimulated H(2)O(2) production in glutamate/malate-oxidizing mitochondria. Antimycin and myxothiazol also increased H(2)O(2) production in mitochondria using alpha-glycerophosphate as a respiratory substrate. In substrate/inhibitor experiments maximal stimulation of H(2)O(2) production by complex I was observed with the alpha-glycerophosphate/antimycin combination. In addition, three forms of in vitro mitochondrial stress were studied: Ca(2+) overload, cold storage for more than 24 h and cytochrome c depletion. In each case we observed (i) a decrease in succinate-supported H(2)O(2) production by complex I and an increase in succinate-supported H(2)O(2) production by complex III, (ii) increased glutamate/malate-induced H(2)O(2) generation by complex I and (iii) increased alpha-glycerophosphate-supported H(2)O(2) generation by complex III. Our results suggest that all three forms of mitochondrial stress resulted in similar shifts in the localization of sites of H(2)O(2) generation and that, in both normal and stressed states, the level and location of H(2)O(2) production depend on the predominant energetic substrate.     

Indirect electrocatalytic determination of choline by monitoring hydrogen peroxide at the choline oxidase-prussian blue modified iron phosphate nanostructures

Choline, as a marker of cholinergic activity in brain tissue, is very important in biological and clinical analysis, especially in the clinical detection of the neurodegenerative disorders disease. This work presents an electrochemical approach for the detection of choline based on prussian blue modified iron phosphate nanostructures (PB-FePO(4)). The obtained nanostructures showed a good catalysis toward the electroreduction of H(2)O(2), and an amperometric choline biosensor was developed by immobilizing choline oxidase on the PB-FePO(4) nanostructures. The biosensor exhibited a rapid response (ca. 2s), low detection limit (0.4±0.05 μM), wide linear range (2 μM to 3.2 mM), high sensitivity (~75.2 μAm M(-1) cm(-2)), as well as good stability and repeatability. In addition, the common interfering species, such as ascorbic acid, uric acid and 4-acetamidophenol did not cause obvious interference due to the low detection potential (-0.05 V versus saturated calomel electrode). This nanostructure could be used as a promise platform for the construction of other oxidase-based biosensors.     

The interaction of oxymyoglobin with hydrogen peroxide: a kinetic anomaly at large excesses of hydrogen peroxide

The reaction of oxymyoglobin (MbO2) with H2O2 has been examined at pH 7.2 and 20(+/- 2) degrees C for reactant ratios of [H2O2]:[MbO2] greater than approximately 15:1. Under the conditions of large excesses of H2O2, the reaction is characterized by an increase in the rate of loss of MbO2 as [H2O2] is increased, for which a value of k(MbO2 + H2O2) approximately 3 M-1 s-1 is obtained. This kinetic behavior contrasts the saturation kinetics observed previously at lower values of [H2O2]. The change in kinetics at increasing excesses of H2O2 is accompanied by a progressive tendency toward the direct formation of ferrimyoglobin at the expense of ferrylmyoglobin formation. A mechanism is proposed in which an initially formed intermediate produces the ferryl derivative in competition with the formation of ferrimyoglobin through the interaction of further H2O2. Overall, the H2O2 is catalytically decomposed by the MbO2. This mechanism is integrated with that determined previously at low excesses of H2O2 into a complex general scheme that applies over the entire studied range of [H2O2]:[MbO2]. No evidence is obtained for the conversion of ferrylmyoglobin to oxymyoglobin by the large excesses of H2O2, regardless of whether the ferryl derivative is the product of the reaction of H2O2 with the oxy or ferri derivative of myoglobin.     

The interaction of oxymyoglobin with hydrogen peroxide: the formation of ferrylmyoglobin at moderate excesses of hydrogen peroxide

The reaction of oxymyoglobin with H2O2 has been examined at pH 7.2 and 20(+/-2) degrees over a range of [H2O2] up to an initial excess of 25:1. The reaction is characterized by a direct conversion of oxymyoglobin to ferrylmyoglobin without the intermediacy of the ferri derivative. The initial rate of loss of oxymyoglobin is first-order with respect to [oxymyoglobin], and exhibits saturation kinetics with increasing [H2O2]. In addition, the stoichiometric relationship between the reactants varies as [H2O2] increases. A complex non-Michaelis-Menten mechanism is proposed in which an intermediate, produced upon the initial interaction of the reactants, regenerates oxymyoglobin by reaction with further H2O2, in competition with the formation of the ferryl derivative. In this way, oxymyoglobin catalytically decomposes excess H2O2. Deoxygenated ferromyoglobin is substantially more reactive with H2O2 in producing the transient intermediate than the oxy analog. Some fundamental similarity is noted between the catalytic mechanism and that of catalase activity. From a detailed examination of the probable nature of the intermediate, conventional Fenton reactivity is rejected for the reaction of H2O2 with oxymyoglobin.     

Membrane transport of hydrogen peroxide

Hydrogen peroxide (H2O2) belongs to the reactive oxygen species (ROS), known as oxidants that can react with various cellular targets thereby causing cell damage or even cell death. On the other hand, recent work has demonstrated that H2O2 also functions as a signalling molecule controlling different essential processes in plants and mammals. Because of these opposing functions the cellular level of H2O2 is likely to be subjected to tight regulation via processes involved in production, distribution and removal. Substantial progress has been made exploring the formation and scavenging of H2O2, whereas little is known about how this signal molecule is transported from its site of origin to the place of action or detoxification. From work in yeast and bacteria it is clear that the diffusion of H2O2 across membranes is limited. We have now obtained direct evidence that selected aquaporin homologues from plants and mammals have the capacity to channel H2O2 across membranes. The main focus of this review is (i) to summarize the most recent evidence for a signalling role of H2O2 in various pathways in plants and mammals and (ii) to discuss the relevance of specific transport of H2O2.     

Membrane transport of hydrogen peroxide

Hydrogen peroxide (H₂O₂) belongs to the reactive oxygen species (ROS), known as oxidants that can react with various cellular targets thereby causing cell damage or even cell death. On the other hand, recent work has demonstrated that H₂O₂ also functions as a signalling molecule controlling different essential processes in plants and mammals. Because of these opposing functions the cellular level of H₂O₂ is likely to be subjected to tight regulation via processes involved in production, distribution and removal. Substantial progress has been made exploring the formation and scavenging of H₂O₂, whereas little is known about how this signal molecule is transported from its site of origin to the place of action or detoxification. From work in yeast and bacteria it is clear that the diffusion of H₂O₂ across membranes is limited. We have now obtained direct evidence that selected aquaporin homologues from plants and mammals have the capacity to channel H₂O₂ across membranes. The main focus of this review is (i) to summarize the most recent evidence for a signalling role of H₂O₂ in various pathways in plants and mammals and (ii) to discuss the relevance of specific transport of H₂O₂.     

Spectrofluorometric analysis of hydrogen peroxide

The pH of maximum fluorescence (above pH 7) and the optimal excitation and emission wavelengths (468 nm and 519 nm, respectively) were determined for 2′,7′-dichlorofluorescein (DCF). The stoichiometry after hydrolysis of the oxidation of the stable nonfluorescent compound 2′,7′-dichlorofluorescin diacetate (LDADCF) was determined and found to be 2 moles of DCF produced per mole of hydrogen peroxide used.     

Basal and hydrogen peroxide stimulated sites of phosphorylation in heterogeneous nuclear ribonucleoprotein C1/C2

Hydrogen peroxide (H2O2) is a recently recognized second messenger, which regulates mammalian cell proliferation and migration. The biochemical mechanisms by which mammalian cells sense and respond to low concentrations of H2O2 are poorly understood. Recently, heterogeneous nuclear ribonucleoprotein C1/C2 (hnRNP-C1/C2) was found to be rapidly phosphorylated in response to the application of low concentrations of H2O2 to human endothelial cells. Here, using tandem mass spectrometry, four sites of phosphorylation are identified in hnRNP-C1/C2, all of which are in the acidic C-terminal domain of the protein. Under resting conditions, the protein is phosphorylated at S247 and S286. In response to low concentrations of H2O2, there is increased phosphorylation at S240 and at one of the four contiguous serine residues from S225-S228. Studies using a recombinant acidic C-terminal domain of hnRNP-C overexpressed in Escherichia coli demonstrate that protein kinase CK2 phosphorylates hnRNP-C1/C2 at S247, while protein kinase A and several protein kinase C isoforms fail to phosphorylate the isolated domain. These findings demonstrate that the acidic C-terminal domain of hnRNP-C1/C2 serves as the site for both basal and stimulated phosphorylation, indicating that this domain may play an important role in the regulation of mRNA binding by hnRNP-C1/C2.     

Investigation of hydrogen peroxide formation in plants

A convenient and simple electrophoretic procedure was used to study the NAD(P)H-dependent generation of the hydrogen peroxide needed for the polymerization of coniferyl alcohol by peroxidases from the wood of Ailanthus glandulosa. The results showed that an NAD(P)H-dependent generation of hydrogen peroxide could be brought about by either: a FMN or riboflavin-dependent system; or a Mn²⁺ -dependent system. The most active system was the one incorporating Mn²⁺, followed closely by that incorporating riboflavin. In nature it appears that the method of hydrogen peroxide formation is determined by the amounts of cofactors present in the lignifying tissue. Because no quantitative data are available in the literature, further studies of the concentrations of these cofactors in the plant cell-wall are needed.     

Direct electrochemistry and electrocatalysis of hemoglobin on polypyrrole-Fe3O4/dodecyltrimethylammonium bromide-modified carbon paste electrode and its biosensing for hydrogen peroxide

Abstract

A novel hydrogen peroxide (H₂O₂) biosensor was successfully constructed, based on the immobilization of hemoglobin (Hb) on polypyrrole (PPy)-Fe₃O₄ and dodecyltrimethylammonium bromide (DTAB) composite ?lm-modified carbon paste electrodes (CPE). The PPy-Fe₃O₄ composites were synthesized in the suspension solution of Fe₃O₄ nanoparticles via in situ chemical oxidative polymerization under the direction of cationic surfactant cetyl trimethyl ammonium bromide. Spectroscopic and electrochemical examinations illustrated that the PPy-Fe₃O₄/DTAB composites were a biocompatible matrix for immobilizing Hb, which revealed high chemical stability and excellent biocompatibility. The thermodynamic, dynamic, and catalytic performance of the biosensor were analysed using cyclic voltammetry (CV). The results indicated that the PPy-Fe₃O₄/Hb/DTAB/CPE exhibited excellent electrocatalytic activity in the reduction of H₂O₂ with a high sensitivity (104 μA mM^{? 1}). The catalytic reduction currents of H₂O₂ were linearly related to H₂O₂ concentration in the range from 2.5 μM to 60 μM with a detection limit of 0.8 μM (S/N = 3). With such superior characteristics, this biosensor for H₂O₂ can be potentially applied in determination of other reactive oxygen species as well. These results indicated that PPy-Fe₃O₄/DTAB composites are a promising matrix for bioactive molecule immobilization.     

Non-oxygen-forming pathways of hydrogen peroxide degradation by bovine liver catalase at low hydrogen peroxide fluxes

Heme catalases are considered to degrade two molecules of H₂O₂ to two molecules of H₂O and one molecule of O₂ employing the catalatic cycle. We here studied the catalytic behaviour of bovine liver catalase at low fluxes of H₂O₂ (relative to catalase concentration), adjusted by H₂O₂-generating systems. At a ratio of a H₂O₂ flux (given in μM/min^- 1) to catalase concentration (given in μM) of 10 min^- 1 and above, H₂O₂ degradation occurred via the catalatic cycle. At lower ratios, however, H₂O₂ degradation proceeded with increasingly diminished production of O₂. At a ratio of 1 min^- 1, O₂ formation could no longer be observed, although the enzyme still degraded H₂O₂. These results strongly suggest that at low physiological H₂O₂ fluxes H₂O₂ is preferentially metabolised reductively to H₂O, without release of O₂. The pathways involved in the reductive metabolism of H₂O₂ are presumably those previously reported as inactivation and reactivation pathways. They start from compound I and are operative at low and high H₂O₂ fluxes but kinetically outcompete the reaction of compound I with H₂O₂ at low H₂O₂ production rates. In the absence of NADPH, the reducing equivalents for the reductive metabolism of H₂O₂ are most likely provided by the protein moiety of the enzyme. In the presence of NADPH, they are at least in part provided by the coenzyme.     

Doing the unexpected: proteins involved in hydrogen peroxide perception

A look back at the early literature on reactive oxygen species (ROS) gives the impression that these small inorganic molecules had a singular defined role, that of host defence in mammalian systems. However, it is now known that their roles also include a major part in cell signalling, in a broad range of organisms from mammals to plants. Similarly, a look back at papers on the proteins now thought to be involved in the perception of hydrogen peroxide (H(2)O(2)) will show that they too had defined functions assigned to them, completely independent to H(2)O(2) signalling. These proteins have disparate roles, in ethylene perception or even major metabolic pathways such as glycolysis. However, the chemistry of H(2)O(2) sensing dictates that the proteins have a commonality, with active thiol groups being potential ROS targets. The challenge now is to determine the full range of proteins which may partake in the role of H(2)O(2) perception, and to determine the mechanisms by which the signal is transmitted to the next players in the signal transduction pathways.     

Alteration of DNA by hydrogen peroxide

DNA is altered by the action of hydrogen peroxide, a ubiquitous body constituent. Formation of damaged species is established by changes in four characteristics of DNA: absorption in the ultraviolet, complexing with histone, adsorption by anion exchange resin and charcoal, binding of silver cations. Damaged species of DNA might lead to impaired function of the organism. Gamma globulin by complexing with DNA is a partial inhibitor of this attack by hydrogen peroxide.     

Oxidation of deuteroferrihaem by hydrogen peroxide

1. The oxidation of deuteroferrihaem by H(2)O(2) to bile pigment and CO was studied both by stopped-flow kinetic spectrophotometry and mass spectrometry, at 25 degrees C, I=0.1m. 2. Spectrophotometric studies imply that, at constant pH, the rate of bile pigment formation is first-order with respect to [H(2)O(2)] and also proportional to [deuteroferrihaem monomer]. The effect of pH on the apparent second-order rate constant suggests that acid-ionization of deuteroferrihaem monomer is important in the reaction mechanism. 3. The relative rates of formation of O(2) (from catalytic decomposition of H(2)O(2)) and CO (from oxidation of ferrihaem) have been measured by mass spectrometry. The results are in excellent agreement with those obtained by combining kinetic data for catalytic decomposition (Jones et al., 1973, preceding paper) with the spectrophotometric results for deuteroferrihaem oxidation.