Studies on the lactoperoxidase system: reaction kinetics and antibacterial activity using two methods for hydrogen peroxide generation.

Components of the lactoperoxidase system were measured during incubation in Isosensitest broth, with enzymatic (glucose oxidase, GO) or chemical (sodium carbonate peroxyhydrate, SCP) means to generate H2O2. When low levels of thiocyanate (SCN-) were used in the GO system, H2O2 was detected and lactoperoxidase (LP) was inactivated when SCN- was depleted. With 10-fold higher SCN-, LP remained active and H2O2 was not detectable. The oxidation product of the LP reaction, most likely hypothiocyanite, was present in low concentrations. When SCP was used for the immediate generation of H2O2 in a system employing low SCN-, half the LP activity was lost within minutes but thereafter it remained stable. Low concentrations of oxidation product were measured and H2O2 was not detected during the course of the experiment. At high SCN- levels, relatively high concentrations of oxidation product were produced immediately, with H2O2 undetectable. The results suggest that the final product of the LP reaction depends on the method of H2O2 generation and the relative proportions of the substrates. Antibacterial activity of the two LPS was tested against an enterotoxigenic strain of Escherichia coli. Both systems showed bactericidal activity within 4 h incubation at 37 degrees C.     

Interaction of lactoperoxidase with hydrogen peroxide. Formation of enzyme intermediates and generation of free radicals

Peroxidases belong to a group of enzymes which catalyze the oxidation of numerous organic and inorganic substrates by hydrogen peroxide. Most peroxidases, including lactoperoxidase (LPO), contain ferriprotoporphyrin IX as a prosthetic group. A characteristic feature of hemoprotein peroxidases is their ability to exist in various oxidation states. There are five known enzyme intermediates. In increasing order of their oxidative equivalents these are ferrous enzyme, ferric or native enzyme, Compound II, Compound I, and Compound III (sections 5, 7). They are readily distinguished from each other by their absorbance in the Soret region (380-450 nm) and visible range (450-650 nm). In the course of Compound III and Compound II conversion back to the native peroxidase, oxygen derived free radicals such as O2-, HO.2, and .OH are generated. Simultaneously the enzyme is irreversibly damaged. In the presence of an exogenous electron donor, such as iodide, the interconversion between the various oxidation states of the peroxidase is markedly affected. Compound II and/or Compound III formation is inhibited, depending on the H2O2 concentration. In addition, the enzyme is largely protected from irreversible inactivation. These effects of iodide are readily explained by 1) the two-electron oxidation of iodide to Iox by Compound I, which bypasses Compound II as an intermediate, and 2) the rapid oxidation of H2O2 to O2 by the oxidized species of iodide which prevents the generation of oxygen derived free radicals.     

Steady-state generation of hydrogen peroxide: kinetics and stability of alcohol oxidase immobilized on nanoporous alumina

Alcohol oxidase from Pichia pastoris was immobilized on nanoporous aluminium oxide membranes by silanization and activation by carbonyldiimidazole to create a flow-through enzyme reactor. Kinetic analysis of the hydrogen peroxide generation was carried out for a number of alcohols using a subsequent reaction with horseradish peroxidase and ABTS. The activity data for the immobilized enzyme showed a general similarity with literature data in solution, and the reactor could generate 80 mmol H₂O₂/h per litre reactor volume. Horseradish peroxidase was immobilized by the same technique to construct bienzymatic modular reactors. These were used in both single pass mode and circulating mode. Pulsed injections of methanol resulted in a linear relation between response and concentration, allowing quantitative concentration measurement. The immobilized alcohol oxidase retained 58 % of initial activity after 3 weeks of storage and repeated use.     

Pseudo-catalytic degradation of hydrogen peroxide in the lactoperoxidase/H2O2/iodide system

Non-stoichiometric (excessive) consumption of hydrogen peroxide (H2O2), which was observed in various lactoperoxidase-catalysed reactions, was tested in the lactoperoxidase/H2O2/iodide system. In preliminary experiments the suitability of the system was tested with special regard to the triiodide (I-3) absorption and the I2/I-3 equilibrium. Triiodide equilibrium concentrations evaluated theoretically and experimentally were compared after adding a known amount of iodine (I2) to solutions containing variable I- concentrations. A close fit of the two methods was only obtained if experiments were carried out in pure aqueous or 0.001 M H2SO4 medium. The presence of various anions, e.g. OH- and Cl-, led to a measurable decrease in I-3 and I2 equilibrium concentrations. These ions are able to displace competitively I- in forming association products with I+ and I2. When I+ and I2 were generated enzymatically by lactoperoxidase and hydrogen peroxide, additional interactions with H2O2 were observed. Depending on the enzyme and iodide concentrations, variable amounts of H2O2 disappeared nonproductively. Due to its ambivalent redox reactivity, part of the H2O2 is not reduced to H2O in the enzyme-catalysed generation of iodine, but undergoes oxidation to O2 by an oxidized iodine compound. This suggests a pseudo-catalytic side reaction which can competitively interfere with the I2/I-3 generation or (and) the iodination reaction.     

Reaction of ferrous lactoperoxidase with hydrogen peroxide and dioxygen: an anaerobic stopped-flow study

Lactoperoxidase (LPO) is found in mucosal surfaces and exocrine secretions including milk, tears, and saliva and has physiological significance in antimicrobial defense which involves (pseudo-)halide oxidation. LPO compound III (a ferrous-dioxygen complex) is known to be formed rapidly by an excess of hydrogen peroxide and could participate in the observed catalase-like activity of LPO. The present anaerobic stopped-flow kinetic analysis was performed in order to elucidate the catalytic mechanism of LPO and the kinetics of compound III formation by probing the reactivity of ferrous LPO with hydrogen peroxide and molecular oxygen. It is shown that ferrous LPO heterolytically cleaves hydrogen peroxide forming water and oxyferryl LPO (compound II). The two-electron oxidation reaction follows second-order kinetics with the apparent bimolecular rate constant being (7.2+/-0.3) x 10(4) M(-1) s(-1) at pH 7.0 and 25 degrees C. The H2O2-mediated conversion of compound II to compound III follows also second-order kinetics (220 M(-1) s(-1) at pH 7.0 and 25 degrees C). Alternatively, compound III is also formed by dioxygen binding to ferrous LPO at an apparent bimolecular rate constant of (1.8+/-0.2) x 10(5) M(-1) s(-1). Dioxygen binding is reversible and at pH 7.0 the dissociation constant (K(D)) of the oxyferrous form is 6 microM. The rate constant of dioxygen dissociation from compound III is higher than conversion of compound III to ferric LPO, which is not affected by the oxygen concentration and follows a biphasic kinetics. A reaction cycle including the redox intermediates compound II, compound III, and ferrous LPO is proposed, which explains the observed (pseudo-)catalase activity of LPO in the absence of one-electron donors. The relevance of these findings in LPO catalysis is discussed.     

An immobilized two-enzyme system for the activation of the lactoperoxidase antibacterial system in milk

Lactoperoxidase catalyzes the oxidation of thiocyanate by hydrogen peroxide and an intermediary product is formed with antibacterial properties. The components of this system, with the exception of hydrogen peroxide, are present in milk. H₂O₂ may be introduced by means of enzymatic, generation and thus make the system complete. A two-enzyme system consisting of β–galactosidase and glucose oxidase has been developed for this purpose. The coupled enzyme reaction is shown to work with high efficiency at the neutral pH of milk although the enzymes as such, particularly lactases suitable for immobilization, have optimal activities at much lower pH values. The results indicate that the lactoperoxidase system may in this way be employed to inactivate bacteria present in milk.     

Dendritic chain reaction: Responsive release of hydrogen peroxide upon generation and enzymatic oxidation of methanol

Signal amplification dramatically increases the sensitivity of diagnostic methods. Recently, we introduced a new technique for signal amplification that uses a distinctive dendritic chain reaction (DCR) to generate exponential evolution of a diagnostic signal. In this report, we demonstrate how the modular design of our DCR probe can be used to improve the detection sensitivity. We synthesized a new probe based on a methyl carbonate linkage, which has superior stability in aqueous media. Triggered release of methanol, which was oxidized by alcohol oxidase present in the solution, produced hydrogen peroxide that used as a reagent in the DCR amplification technique. The new probe exhibited higher sensitivity in detection of hydrogen peroxide than our previously reported probe.     

Studies on the generation of hydrogen peroxide during some non-enzymic reactions changing the hyaluronic acid molecule

The effect of catalase on non-enzymic-induced changes in the conformation of hyaluronic acid in a vitreous humour preparation was measured using viscometry. Ascorbate, heavy metal ions, riboflavin or EDTA all lowered the viscosity of hyaluronic acid solutions. These effects could be prevented by the addition of catalase. This suggested that H₂O₂ is produced by these compounds and that the resulting change in conformation of hyaluronic acid may be due to peroxyl and hydroxyl attack by the free radicals thus generated.     

Role of porins in sensitivity of Escherichia coli to antibacterial activity of the lactoperoxidase enzyme system

Lactoperoxidase is an enzyme that contributes to the antimicrobial defense in secretory fluids and that has attracted interest as a potential biopreservative for foods and other perishable products. Its antimicrobial activity is based on the formation of hypothiocyanate (OSCN-) from thiocyanate (SCN-), using H2O2 as an oxidant. To gain insight into the antibacterial mode of action of the lactoperoxidase enzyme system, we generated random transposon insertion mutations in Escherichia coli MG1655 and screened the resultant mutants for an altered tolerance of bacteriostatic concentrations of this enzyme system. Out of the ca. 5,000 mutants screened, 4 showed significantly increased tolerance, and 2 of these had an insertion, one in the waaQ gene and one in the waaO gene, whose products are involved in the synthesis of the core oligosaccharide moiety of lipopolysaccharides. Besides producing truncated lipopolysaccharides and displaying hypersensitivity to novobiocin and sodium dodecyl sulfate (SDS), these mutants were also shown by urea-SDS-polyacrylamide gel electrophoresis analysis to have reduced amounts of porins in their outer membranes. Moreover, they showed a reduced degradation of p-nitrophenyl phosphate and an increased resistance to ampicillin, two indications of a decrease in outer membrane permeability for small hydrophilic solutes. Additionally, ompC and ompF knockout mutants displayed levels of tolerance to the lactoperoxidase system similar to those displayed by the waa mutants. These results suggest that mutations which reduce the porin-mediated outer membrane permeability for small hydrophilic molecules lead to increased tolerance to the lactoperoxidase enzyme system because of a reduced uptake of OSCN-.     

Studies on the generation of hydrogen peroxide during some non-enzymic reactions changing the hyaluronic acid molecule.

The effect of catalase on non-enzymic-induced changes in the conformation of hyaluronic acid in a vitreous humour preparation was measured using viscometry. Ascorbate, heavy metal ions, riboflavin or EDTA all lowered the viscosity of hyaluronic acid solutions. These effects could be prevented by the addition of catalase. This suggested that H2 O2 is produced by these compounds and that the resulting change in conformation of hyaluronic acid may be due to peroxyl and hydroxyl attack by the free radicals thus generated.     

D-Penicillamine: analysis of the mechanism of copper-catalyzed hydrogen peroxide generation

Recent studies have suggested that the inhibition of lymphocyte mitogenesis by D-penicillamine in the presence of copper could be mediated by the formation and action of hydrogen peroxide. To explore this possibility further, we first sought evidence of H2O2 generation by D-penicillamine in a cell-free system by a) measurement of copper-catalyzed D-penicillamine oxidation and the requirement for oxygen in this process; b) direct measurement of H2O2 formation during D-penicillamine oxidation by the peroxidase-mediated oxidation of fluorescent scopoletin; and c) evaluation of the possible synthesis of O2- during D-penicillamine oxidation. The addition of copper to D-penicillamine in physiologic buffer catalyzed D-penicillamine oxidation in a dose-dependent fashion. D-penicillamine oxidation was accompanied by O2 consumption with a molar ratio of approximately 2:1, but did not occur under anaerobic conditions. Furthermore, D-penicillamine oxidation resulted in the formation of amounts of H2O2 stoichiometrically equivalent to oxygen consumption (i.e., 1:1). Copper-catalyzed D-penicillamine oxidation caused reduction of nitroblue tetrazolium in a reaction blocked by superoxide dismutase, suggesting the formation of O2-. Additional studies confirmed that D-penicillamine inhibited PHA-induced mitogenesis of lymphocytes in the presence of copper, and that catalase protected the cells from this action. Furthermore, when polymorphonuclear leukocytes were incubated with D-penicillamine plus copper, hexose monophosphate shunt activity increased up to threefold with abrogation of this stimulation by catalase. None of the effects of D-penicillamine plus copper on cells were diminished by hydroxyl radical scavengers mannitol or benzoate. These results are consistent with oxygen-dependent copper-catalyzed oxidation of D-penicillamine in aqueous solutions leading to the formation of O2- and H2O2. H2O2 produced by this reaction can inhibit lymphocyte mitogenesis and stimulate neutrophil hexose monophosphate shunt activity in vitro and may be relevant to the therapeutic effects of D-penicillamine in vivo.     

Copper-catalyzed DNA damage by ascorbate and hydrogen peroxide: kinetics and yield

Time profiles for degradation of DNA via reaction of H2O2 with the DNA-Cu+ complex were analyzed over a wide range of concentrations of the components. The yield of DNA damage per H2O2 molecule is 10 times lower than that obtained with gamma-radiolytically generated .OH radicals. The observations can be explained by a model in which H2O2 reacts, slowly on the one hand with DNA-Cu+ by formation of toxic .OH radicals immediately at the DNA and faster on the other hand with Cu+ in the bulk solution by formation of less toxic Cu(III) intermediates.     

Effect of lactoperoxidase on the antimicrobial effectiveness of the thiocyanate hydrogen peroxide combination in a quantitative suspension test

Background  

The positive antimicrobial effects of increasing concentrations of thiocyanate (SCN-) and H₂O₂ on the human peroxidase defence system are well known. However, little is known about the quantitative efficacy of the human peroxidase thiocyanate H₂O₂ system regarding Streptococcus mutans and sanguinis, as well as Candida albicans. The aim of this study was to evaluate the effect of the enzyme lactoperoxidase on the bactericidal and fungicidal effectiveness of a thiocyanate-H₂O₂ combination above the physiological saliva level. To evaluate the optimal effectiveness curve, the exposure times were restricted to 1, 3, 5, and 15 min.     

Population doubling time, phosphatase activity, and hydrogen peroxide generation in Jurkat cells.

Differences in growth characteristics, phosphatase activity, and hydrogen peroxide generation in two clones of a T-cell leukemic line are described in this communication. Wurzburg cells had significantly shorter population doubling times compared with the parental Jurkat cells (16.6 +/- 2.0 h and 20.7 +/- 2.2 h, respectively; mean +/- SD, p < .0001, n = 20). In addition, total phosphatase activity was significantly decreased (p < .006) and hydrogen peroxide production was significantly increased (p < .002) in Wurzburg cells compared to Jurkat cells. That the cell line with the faster growth rate should have these latter two properties is entirely consistent with the positive effects of increased kinase activity and hydrogen peroxide on proliferative cellular responses in T cells. As originally described, Wurzburg cells were distinguished from Jurkat cells by their lack of CD45, a membrane protein tyrosine phosphatase, and their positive response to hydrogen peroxide-stimulation of NF-kappaB activation. We propose that these two clones, with their distinguishing characteristics, can be used to advantage in experiments designed to study the effects of antioxidants on signaling pathways that control cell life and death.     

Observations on the cytolytic activity of lactoperoxidase using a continuous assay

A turbidometric assay that allows continuous monitoring of the cytolytic activity of toxic agents toward various target cells has been developed. This assay monitors the change in absorbance at 600 nm (due to light scattering) of a suspension of human red blood cells as a function of time. The rate of cell lysis, delta A600/delta t, can be expressed as the number of cells lysed per minute, which facilitates the determination of kinetic constants. Using this procedure we observed that the cytolytic activity exerted by various peroxidases in the presence of hydrogen peroxide and a halide ion proceeds in at least two stages. During the first stage no lysis occurs, but scanning electron microscopy showed that alterations in the target cell membrane take place. During the second stage the target cells lyse, resulting in a simultaneous release of metabolites and macromolecules. We conclude that the lytic action of peroxidases is directed toward the target cell membrane, which appears to acquire an increased rigidity and subsequently disintegrates.     

Endothelin-1 decreases endothelial NOS expression and activity through ETA receptor-mediated generation of hydrogen peroxide

Similar to infants born with persistent pulmonary hypertension of the newborn (PPHN), there is an increase in circulating endothelin-1 (ET-1) and decreased endothelial nitric oxide synthase (eNOS) gene expression in an ovine model of PPHN. These abnormalities lead to vasoconstriction and vascular remodeling. Our previous studies have demonstrated that reactive oxygen species (ROS) levels are elevated in the pulmonary arteries from PPHN lambs and that ET-1 increases ROS production in pulmonary arterial smooth muscle cells (PASMC) in culture. Thus the objective of this study was to determine whether there was a feedback mechanism between the ET-1-mediated increase in ROS in fetal PASMC (FPASMC) and a decrease in eNOS gene expression in fetal pulmonary arterial endothelial cells (FPAEC). Our results indicate that ET-1 increased H2O2 levels in FPASMC in an endothelin A receptor-dependent fashion. This was observed in both FPASMC monoculture and in cocultures of FPASMC and FPAEC. Conversely, ET-1 decreased H2O2 levels in FPAEC monoculture in an endothelin B receptor-dependent fashion. Furthermore, ET-1 decreased eNOS promoter activity by 40% in FPAEC in coculture with FPASMC. Promoter activity was restored in the presence of catalase. In FPAEC in monoculture treated with 0-100 microM H2O2, 12 microM had no effect on eNOS promoter activity, but it increased eNOS protein levels by 50%. However, at 100 microM, H2O2 decreased eNOS promoter activity and protein levels in FPAEC by 79 and 40%, respectively. These data suggest a role for smooth muscle cell-derived H2O2 in ET-1-mediated downregulation of eNOS expression in children born with PPHN.     

A study on the reaction of human erythrocytes with hydrogen peroxide

Membrane fluidity of human erythrocytes treated with H2O2 (1--20 mM) was studied using three kinds of fatty acid spin labels. A strongly immobilized signal appeared on exposure of erythrocytes to H2O2 but was not observed in either H2O2- or Fenton's reagent-treated ghosts or lipid vesicles prepared from H2O2-treated erythrocytes, indicating that the appearance of this signal necessitates the reaction of hemoglobin with H2O2 and is not due to lipid peroxidation. The ESR spectrum of maleimide-prelabeled erythrocytes showed an isotropic signal and the rotational correlation time (tau c) increased as the concentration of H2O2 was increased. Furthermore, maleimide labeling of H2O2-pretreated erythrocytes showed a strongly immobilized component, in addition to a weakly immobilized component. From the relative ratio of the signal intensity of hemoglobin and membrane proteins, it was found that label molecules bound predominantly to hemoglobin. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of H2O2-treated erythrocytes demonstrated globin aggregation. Therefore, the changes in the ESR signal observed on H2O2 treatment may be due to some change in hemoglobin, such as globin aggregation or its binding to the membranes. The ESR spectrum of H2O2-treated erythrocytes at -196 degrees C is characterized by signals of nonheme ferric iron type (g equal to 4.3), low spin ferric iron, and free radical type at g equal to 2.00. At higher H2O2 concentrations, the ESR lines due to low spin ferric iron became broad and their peak heights decreased, compared with that at g equal to 2.00 or 4.3. These results indicate that oxidative stress such as decrease of membrane fluidity, lipid peroxidation, and globin aggregation in H2O2-treated erythrocytes is dependent on the reaction of hemoglobin with H2O2.     

Biosensor for the monitoring of hydrogen peroxide using poly(vinyl alcohol) membrane system

Summary A biosensor system for continuous on-line monitoring of hydrogen peroxide concentration was developed employing catalase and a poly(vinyl alcohol)/poly(tetra fluoro ethylene) bilayer membrane system, Catalase was entrapped between poly(vinyl alcohol) membrane layer and poly(tetra fluoro ethylene) membrane layer outside of the galvanic type DO probe. Since poly(vinyl alcohol) membrane has non-porous, hydrophilic characteristics, the difference in hydrogen peroxide concentration between inside and outside of the membrane was therefore approximately 100 times. The developed hydrogen peroxide sensor has a wide linear range of hydrogen peroxide sensing more than 140 mM and favourable dynamic response characteristics. The sensor showed also good operational stability, rapid response time, and long life time.