Oxidant membrane injury by the neutrophil myeloperoxidase system. II. Injury by stimulated neutrophils and protection by lipid-soluble antioxidants

The stimulated human neutrophil can damage a variety of target cells, and in some models, a mechanism involving secretion of myeloperoxidase and H2O2 has been demonstrated. We explored the characteristics of this cell-cell interaction by using neutrophils and our recently described liposome model target cell system. Exposure of 51Cr-labeled liposomes to phorbol myristate acetate-stimulated human neutrophils resulted in release of 25 to 30% of the radioactivity. 51Cr release was abrogated by omission of the neutrophils, the phorbol ester or halide (iodide), replacement of the phorbol by an inactive congener, or addition of azide, cyanide, or catalase. Neutrophils from patients with hereditary absence of myeloperoxidase (MPO) or a failure of H2O2 formation (chronic granulomatous disease) did not cause liposome lysis unless purified MPO or a source of H2O2, respectively, was added. These data indicate that 51Cr release from liposomes is a consequence of the secretion of MPO and H2O2, which combine with extracellular halides to form a membrane lytic system. The influence of liposome composition on injury was then examined, with a focus on physiologically relevant lipid soluble antioxidants. Liposomes containing either alpha-tocopherol (0.33 to 1.67% of molar fraction of lipid) or beta-carotene (1.67% of molar fraction of lipid) were markedly resistant to lysis by the cellfree MPO-H2O2-chloride system. When the major structural lipid phosphatidyl choline was replaced by dipalmitoyl phosphatidyl choline, a synthetic phospholipid with no oxidizable double bonds, the resultant liposomes were totally resistant to lysis by the MPO-H2O2-chloride system. The addition of iodide to this system (i.e., both chloride and iodide present) changed the pattern of protection dramatically in that alpha-tocopherol and beta-carotene were no longer protective and the resistance of dipalmitoyl phosphatidyl choline liposomes was partial rather than complete. In contrast to iodide, the addition of bromide or thiocyanate did not have a major effect on the protection by antioxidants. Finally, we demonstrated protection by alpha-tocopherol or dipalmitoyl phosphatidyl choline against liposome lysis by phorbol-activated neutrophils. These studies illustrate the use of model phospholipid membranes in the characterization of oxygen-dependent cell-mediated cytotoxicity. Activated neutrophils lyse liposome targets through a MPO-dependent mechanism. Target properties, especially the content of lipid-soluble antioxidants, have a marked influence on susceptibility to lysis.(ABSTRACT TRUNCATED AT 400 WORDS)     

Peroxidative oxidation of halides catalysed by myeloperoxidase. Effect of fluoride on halide oxidation

It was found that all halides can compete with cyanide for binding with myeloperoxidase. The lower is the pH, the higher is the affinity of halides. The apparent dissociation constants (Kd) of myeloperoxidase-cyanide complex were determined in the presence of F-, Cl-, Br- and I- in the pH range of 4 to 7. In slightly acidic pH (4 - 6) fluoride and chloride exhibit a higher affinity towards the enzyme than bromide and iodide. Taking into account competition between cyanide and halides for binding with myeloperoxidase the dissociation constants of halide-myeloperoxidase complexes were calculated. All halides except fluoride can be oxidized by H2O2 in the presence of myeloperoxidase. However, since fluoride can bind with myeloperoxidase, it can competitively inhibit the oxidation of other halides. Fluoride was a competitive inhibitor with respect to other halides as well as to H2O2. Inhibition constants (Ki) for fluoride as a competitive inhibitor with respect to H2O2 increased from iodide oxidation through bromide to chloride oxidation.     

Oxidative inactivation of pneumolysin by the myeloperoxidase system and stimulated human neutrophils

Pneumolysin, a hemolytic toxin from Streptococcus pneumoniae, is a member of the group of thiol-activated, oxygen-labile cytolysins produced by various Gram-positive bacteria. The toxin activity of pneumolysin, as determined by lysis of 51Cr-labeled human erythrocytes, was destroyed on exposure to the neutrophil enzyme myeloperoxidase, hydrogen peroxide, and a halide (chloride or iodide). Detoxification required each component of the myeloperoxidase system and was prevented by the addition of agents that inhibit heme enzymes (azide, cyanide) or degrade H2O2 (catalase). Reagent H2O2 could be replaced by the peroxide-generating enzyme system glucose oxidase plus glucose. The entire myeloperoxidase system could be replaced by sodium hypochlorite at micromolar concentrations. Toxin inactivation was a function of time of exposure to the myeloperoxidase system (less than 1 min), the rate of formation of H2O2 (0.05 nmol/min), and the concentration of toxin employed. Toxin that had been inactivated by the myeloperoxidase system was reactivated on incubation with the reducing agent dithiothreitol. Pneumolysin was also inactivated when incubated with human neutrophils (10(5)) in the presence of a halide and phorbol myristate acetate, an activator of neutrophil secretion and oxygen metabolism. Toxin inactivation by stimulated neutrophils was blocked by azide, cyanide, or catalase, but not by superoxide dismutase. Neutrophils from patients with impaired oxygen metabolism (chronic granulomatous disease) or absent myeloperoxidase (hereditary deficiency) failed to inactivate the toxin unless they were supplied with an exogenous source of H2O2 or purified myeloperoxidase, respectively. Thus, inactivation of pneumolysin involved the secretion of myeloperoxidase and H2O2, which combined with extracellular halides to form agents (e.g., hypochlorite) capable of oxidizing the toxin. This example of oxidative inactivation of a cytolytic agent may serve as a model for phagocyte-mediated detoxification of microbial products.     

Cytotoxicity towards human endothelial cells, induced by neutrophil myeloperoxidase: protection by ceftazidime

We investigated the effects of the antibiotic ceftazidime (CAZ) on the cytolytic action of the neutrophil myeloperoxidase-hydrogen peroxide-chloride anion system (MPO/H(2)O(2)/Cl(-)). In this system, myeloperoxidase catalyses the conversion of H(2)O(2) and CI(-) to the cytotoxic agent HOCl. Stimulated neutrophils can release MPO into the extracellular environment and then may cause tissue injury through direct endothelial cells lysis. We showed that human umbilical vein endothelial cells (HUVEC) were capable of taking up active MPO. In presence of H(2)O(2) (10(-4) M), this uptake was accompanied by cell lysis. The cytolysis was estimated by the release of (51)Cr from HUVEC and expressed as an index of cytotoxicity (IC). Dose dependent protection was obtained for CAZ concentrations ranging from 10(-5) to 10(-3) M;this can be attributed to inactivation of HOCl by the drug. This protection is comparable to that obtained with methionine and histidine, both of which are known to neutralize HOCl. This protection by CAZ could also be attributed to inactivation of H(2)O(2), but when cytolysis was achieved with H(2)O(2) or O(2) (-) generating enzymatic systems, no protection by CAZ was observed. Moreover, the peroxidation activity of MPO (action on H(2)O(2)) was not affected by CAZ, while CAZ prevented the chlorination activity of MPO (chlorination of monochlorodimedon). So, we concluded that CAZ acts via HOCl inactivation. These antioxidant properties of CAZ may be clinically useful in pathological situations where excessive activation of neutrophils occurs, such as in sepsis.     

Influence of chloride on modification of unsaturated phosphatidylcholines by the myeloperoxidase/hydrogen peroxide/bromide system

The leukocyte enzyme myeloperoxidase (MPO) is capable of catalyzing the oxidation of chloride and bromide ions, at physiological concentrations of these substrates, by hydrogen peroxide, generating hypochlorous acid (HOCl) and hypobromous acid (HOBr), respectively. Our previous results showed that the hypohalous acids formed react with double bonds in phosphatidylcholines (PCs) to produce chloro- and bromohydrins. Lysophosphatidylcholine (lyso-PC) is additionally formed in PCs with two or more double bonds. This study was conducted to determine the effect physiological chloride concentration (140 mM) has on the formation of bromohydrins and lyso-PC from unsaturated PC upon treatment with the myeloperoxidase/hydrogen peroxide/bromide (MPO/H2O2/Br-) system using physiological bromide concentrations (20-100 microM). The composition of reaction products was analyzed by matrix-assisted laser desorption and ionization time-of-flight mass spectrometry (MALDI-TOF MS). With monounsaturated PC, we demonstrated that the rate and extent of mono-bromohydrin formation were higher in the samples with 140 mM chloride compared to those with no added chloride. Moreover, mono-bromohydrin came to be the major product and no mono-chlorohydrin was observed already at 60 microM bromide. We attributed these effects to the involvement of HOBr arising from the reaction of MPO-derived HOCl with bromide rather than to the exchange of bromide with chlorine atoms of chlorohydrins or direct formation of HOBr by MPO. The presence of chloride shifted the pH optimum for mono-bromohydrin formation (pH 5.0) toward neutral values, and a significant yield of mono-bromohydrin was detected at physiological pH values (7.0-7.4). For polyunsaturated PC, chloride enhanced also lyso-PC production, the effect being pronounced at bromide concentrations below 40 microM. The results indicate that at physiological levels of chloride and bromide, chloride promotes MPO-mediated formation of bromohydrins and lyso-PC in unsaturated phospholipids.     

Peroxidase-mediated toxicity to schistosomula of Schistosoma mansoni

Guinea pig eosinophil peroxidase (EPO) was capable of killing schistosomula of Schistosoma mansoni in vitro when combined with hydrogen peroxide and a halide. Killing was measured by 51Cr release, by microscopic evaluation of viability, and by reinfection experiments in mice. Parasite killing was dependent on each component of the EPO-H2O2-halide system, was completely inhibited by catalase and azide, and was partially inhibited by cyanide. The EPO-mediated system required 10(-4) M H2O2 and 10(-4) M iodide at pH 7.0, and the schistosomula were killed with exposure to this system of less than 30 min at 37 degrees C. At pH 6.0, the EPO-mediated system showed significant cidal activity with 10(-6) M iodide. Canine neutrophil peroxidase (myeloperoxidase [MPO]) was also able to kill schistosomula in vitro in the presence of 10(-4) M H2O2 and 10(-4) iodide at pH 7.0 and pH 6.0. Physiologic concentrations of chloride (0.1 M) could substitute for iodide at pH 7.0 and pH 6.0 as the halide cofactor; however, at pH 7.0, a higher concentration of enzyme was required. These findings with isolated enzyme systems are compatible with a role for peroxidase in the host defense against schistosomula.     

Down-regulation of human natural killer activity against tumors by the neutrophil myeloperoxidase system and hydrogen peroxide

There is growing evidence that natural killer (NK) cells play an important role in immune surveillance against tumors and certain infections. The coexistence of activated neutrophils with lymphocytes in tumor masses and inflammatory tissues suggests the possibility of interaction between secreted neutrophil products and nearby lymphocytes. We examined the susceptibility of lymphocyte NK activity to oxidative injury by the neutrophil myeloperoxidase (MPO) system and H2O2 with the use of a cellfree model system. Exposure of human mononuclear leukocytes (MNL) to MPO, an H2O2-generating system (glucose + glucose oxidase), and a halide (C1- or I-) resulted in marked suppression of MNL-NK activity, as measured by 51Cr release from K562 tumor targets (p less than 0.001). This suppression was dependent on the presence and activity of each system component and was blocked by azide and catalase, but not by heated catalase. In spite of the marked functional suppression of NK activity, MNL viability was more than 95% and target binding frequency was not affected. NK suppression was reversible after 24 hr in culture. The mechanism of suppression was dependent on the amount and rate of H2O2 delivered, and on MNL number. MPO was essential when H2O2 flux was low or when MNL numbers were high. As H2O2 flux increased or MNL numbers decreased, NK suppression gradually became MPO-independent and was mediated by H2O2 alone. The ability of the MPO system to compromise lymphocyte NK function may explain the in vitro inhibition of NK activity of mixed cell populations by the tumor promoter phorbol esters, because these agents are potent stimulants for neutrophil secretion of MPO and H2O2. This study may also provide a possible mechanism for the reported in situ NK activity suppression by adherent phagocytic cells during carcinogenesis in both humans and animals.     

Immunosuppression by activated human neutrophils. Dependence on the myeloperoxidase system

An in vitro model system was used to define the mechanism of interaction between human neutrophils and lymphocytes. Blood mononuclear leukocytes were exposed to purified neutrophils in the presence of a neutrophil-activating agent (phorbol ester, lectin, or opsonized particle). The treated mononuclear cells displayed a marked decrease in both natural killer activity and mitogen-dependent DNA synthesis, but no change in viability. This functional suppression was dependent on neutrophil number, stimulus concentration, and duration of exposure. Lymphocytes were protected by addition of catalase, but not superoxide dismutase. Neutrophils defective in oxidative metabolism (chronic granulomatous disease) failed to suppress lymphocyte function unless an H2O2-generating system, glucose oxidase plus glucose, was added. The patients' neutrophils provided a factor, possibly myeloperoxidase, which interacted with the glucose oxidase system. The immunosuppressive effect of normal neutrophils was diminished when chloride was omitted from the cultures and was enhanced when chloride was replaced by iodide. Myeloperoxidase-deficient neutrophils were partially defective in suppressing lymphocytes and this was corrected by addition of purified myeloperoxidase. Paradoxically, azide caused enhancement of suppression that depended on the neutrophil oxidative burst, but not on myeloperoxidase and was mediated at least in part by an effect of azide on the target mononuclear leukocytes. These data indicate that suppression of lymphocyte function by activated neutrophils is mediated by the secretion of myeloperoxidase and H2O2 that react with halides to form immunosuppressive products. Moreover, the mononuclear leukocytes contain an azide-sensitive factor, probably catalase, which provides partial protection against injury by neutrophil products. These dynamic interactions may be important local determinants of the immune response.     

Interaction of halides with the cyanide complex of myeloperoxidase: a model for substrate binding to compound I.

EPR spectra of the low-spin cyanide complex of myeloperoxidase have been measured in the absence and presence of halide substrates; chloride, bromide and iodide. Halide-dependent spectral changes are found at acidic pH. The electronic structure of the low-spin ferric iron in cyanide complex appears to be modulated by halide binding to a protonated amino acid in the distal heme cavity. These findings suggest halide substrates can interact with ferryl oxygen in compound I during enzyme catalysis to form hypohalous acid.     

Possible involvement of myeloperoxidase in lipid peroxidation.

1. Exposure of liposomes to the MPO-H2O2-Cl- system results in oxidation of lipids. Malondialdehyde and 4-hydroxynonenal are formed. 2. Oxidation of liposomes by stimulated rat neutrophils, assessed by malondialdehyde formation, is inhibited by KCN. This indicates involvement of MPO in the process. 3. The MPO-H2O2 system oxidizes mildly LDL but in the presence of chloride a propagation phase, with a rapid increase of conjugated diene formation, was observed.     

Inactivation of myocardial dihydrolipoamide dehydrogenase by myeloperoxidase systems: effect of halides, nitrite and thiol compounds

Dihydrolipoamide dehydrogenase (LADH) lipoamide reductase activity decreased whereas enzyme diaphorase activity increased after LADH treatment with myeloperoxidase (MPO) dependent systems (MPO/H₂O₂/halide, MPO/NADH/halide and MPO/H₂O₂/nitrite systems. LADH inactivation was a function of the composition of the inactivating system and the incubation time. Chloride, iodide, bromide, and the thiocyanate anions were effective complements of the MPO/H₂O₂ system. NaOCl inactivated LADH, thus supporting hypochlorous acid (HOCl) as putative agent of the MPO/H₂O₂/NaCl system. NaOCl and the MPO/H₂O₂/NaCl system oxidized LADH thiols and NaOCl also oxidized LADH methionine and tyrosine residues. LADH inactivation by the MPO/ NADH/halide systems was prevented by catalase and enhanced by superoxide dismutase, in close agreement with H₂O₂ production by the LADH/NADH system. Similar effects were obtained with lactoperoxidase and horseradish peroxidase suplemented systems. L-cysteine, N-acetylcysteine, penicillamine, N-(2-mercaptopropionylglycine), Captopril and taurine protected LADH against MPO systems and NaOCl. The effect of the MPO/H₂O₂/NaNO₂ system was prevented by MPO inhibitors (sodium azide, isoniazid, salicylhydroxamic acid) and also by L-cysteine, L-methionine, L-tryptophan, L-tyrosine, L-histidine and reduced glutathione. The summarized observations support the hypothesis that peroxidase-generated “reactive species” oxidize essential thiol groups at LADH catalytic site.     

Mechanism of reaction of myeloperoxidase with hydrogen peroxide and chloride ion.

The reaction of myeloperoxidase compound I (MPO-I) with chloride ion is widely assumed to produce the bacterial killing agent after phagocytosis. Two values of the rate constant for this important reaction have been published previously: 4.7 x 106 M-1.s-1 measured at 25 degrees C [Marquez, L.A. and Dunford, H.B. (1995) J. Biol. Chem. 270, 30434-30440], and 2.5 x 104 M-1.s-1 at 15 degrees C [Furtmüller, P.G., Burner, U. & Obinger, C. (1998) Biochemistry 37, 17923-17930]. The present paper is the result of a collaboration of the two groups to resolve the discrepancy in the rate constants. It was found that the rate constant for the reaction of compound I, generated from myeloperoxidase (MPO) and excess hydrogen peroxide with chloride, decreased with increasing chloride concentration. The rate constant published in 1995 was measured over a lower chloride concentration range; the 1998 rate constant at a higher range. Therefore the observed conversion of compound I to native enzyme in the presence of hydrogen peroxide and chloride ion cannot be attributed solely to the single elementary reaction MPO-I + Cl- --> MPO + HOCl. The simplest mechanism for the overall reaction which fit the experimental data is the following: MPO+H2O2 ⇄k-1k1 MPO-I+H2O MPO-I+Cl- ⇄k-2k2 MPO-I-Cl- MPO-I-Cl- -->k3 MPO+HOCl where MPO-I-Cl- is a chlorinating intermediate. We can now say that the 1995 rate constant is k2 and the corresponding reaction is rate-controlling at low [Cl-]. At high [Cl-], the reaction with rate constant k3 is rate controlling. The 1998 rate constant for high [Cl-] is a composite rate constant, approximated by k2k3/k-2. Values of k1 and k-1 are known from the literature. Results of this study yielded k2 = 2.2 x 106 M-1.s-1, k-2 = 1.9 x 105 s-1 and k3 = 5.2 x 104 s-1. Essentially identical results were obtained using human myeloperoxidase and beef spleen myeloperoxidase.     

Production of the superoxide adduct of myeloperoxidase (compound III) by stimulated human neutrophils and its reactivity with hydrogen peroxide and chloride.

Examination of the spectra of phagocytosing neutrophils and of myeloperoxidase present in the medium of neutrophils stimulated with phorbol myristate acetate has shown that superoxide generated by the cells converts both intravacuolar and exogenous myeloperoxidase into the superoxo-ferric or oxyferrous form (compound III or MPO2). A similar product was observed with myeloperoxidase in the presence of hypoxanthine, xanthine oxidase and Cl-. Both transformations were inhibited by superoxide dismutase. Thus it appears that myeloperoxidase in the neutrophil must function predominantly as this superoxide derivative. MPO2 autoxidized slowly (t 1/2 = 12 min at 25 degrees C) to the ferric enzyme. It did not react directly with H2O2 or Cl-, but did react with compound II (MP2+ X H2O2). MPO2 catalysed hypochlorite formation from H2O2 and Cl- at approximately the same rate as the ferric enzyme, and both reactions showed the same H2O2-dependence. This suggests that MPO2 can enter the main peroxidation pathway, possibly via its reaction with compound II. Both ferric myeloperoxidase and MPO2 showed catalase activity, in the presence or absence of Cl-, which predominated over chlorination at H2O2 concentrations above 200 microM. Thus, although the reaction of neutrophil myeloperoxidase with superoxide does not appear to impair its chlorinating ability, the H2O2 concentration in its environment will determine whether the enzyme acts primarily as a catalase or peroxidase.     

The interaction of 5,5-dimethyl-1-pyrroline-N-oxide with human myeloperoxidase and its potential impact on spin trapping of neutrophil-derived free radicals

Activation of human neutrophils leads to secretion of myeloperoxidase (MPO) with resulting generation of several oxidant species including OCl-. Spin trapping techniques employing 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) are being applied increasingly to the investigation of free radical production by in vitro and in vivo experimental systems which contain neutrophils. Because such knowledge is critical to the interpretation of these data, we examined the impact of MPO and MPO-derived oxidants on DMPO spin adduct formation and stability. Addition of increasing concentrations of OCl- to DMPO yielded a number of EPR-detectable products including DMPO-OH. However, the concentration of OCl- required was in excess of that expected under physiologic conditions. Addition of purified human MPO and H2O2 to DMPO yielded EPR spectra consisting of small DMPO-OH peaks. The addition of MPO and H2O2 to preformed DMPO-OH and DMPO-CH3 resulted in rapid destruction of these spin adducts. Thus MPO/H2O2 appeared to both generate and destroy DMPO spin adducts. Neutrophils stimulated with phorbol myristate acetate or opsonized zymosan generated large DMPO-OOH and DMPO-OH peaks as well as small DMPO-CH3 peaks. Addition of the MPO inhibitor azide to the reaction mixture had no effecting on resulting DMPO-OH or DMPO-CH3 peak amplitudes but increased that of DMPO-OOH. These data suggest that MPO-derived oxidants likely have little impact on the nature of EPR spectra resulting from DMPO spin trapping of free radical species following neutrophil stimulation. Because MPO oxidants did appear to react with DMPO the ability of DMPO to protect a biologic target from in vitro MPO injury was examined. DMPO (greater than 10 mM) significantly decreased MPO/H2O2/Cl- -mediated erythrocyte hemolysis as assessed by 51Cr release. The experimental and/or pharmacologic implications of this observation require further study.     

Hydrogen cyanide and cyanogen chloride formation by the myeloperoxidase-H2O2-Cl- system.

The chlorination of glycine by the myeloperoxidase-H2O2-Cl- system at acidic pH values yielded N-monochloroglycine and a mixture of HCN and ClCN. HCN was formed as a product of N-dichloroglycine decomposition and cyanogen chloride formation resulted from simultaneous chlorination of HCN by N-chloroglycine or directly by the myeloperoxidase-H2O2-Cl- system. HCN was readily chlorinated by the myeloperoxidase-H2O2Cl- system yielding cyanogen chloride. This dissociation constants of the myeloperoxidase-CN- complex were estimated as 2.5.10(-6)--1.15.10(-5) M within the pH range of 6.2 to 3.4, respectively. Chloride competed with cyanide for binding at the active site of myeloperoxidase. The lower the pH the more pronounced was the competitive effect of chloride. This accounted for chlorination by myeloperoxidase in the presence of CN-.     

Interaction of methyl-xanthines with myeloperoxidase. An anti-inflammatory mechanism.

1. Inhibition of myeloperoxidase (MPO)-catalyzed reactions by methyl-substituted xanthines has been investigated. 2. Except for theobromine and caffeine, all xanthines tested were potent inhibitors of the MPO-H2O2-Cl- system. 3. In contrast to methyl substitution in the 1 or 8 position of xanthine, substitution in the 3 or 7 position had a marked effect on the inhibition of MPO catalysis. 4. Two different inhibitory mechanisms were induced; scavenging of hypochlorous acid (HOCl) generated by the MPO system and accumulation of Compound II (ferryl MPO) which is inactive as a catalyst of Cl- oxidation.     

Spectroscopic, ligand binding, and enzymatic properties of the spleen green hemeprotein. A comparison with myeloperoxidase

The bovine spleen green hemeprotein, a peroxidase which exhibits spectrophotometric properties similar to those of granulocyte myeloperoxidase, was purified using an improved method. The ligand affinity of the ferric enzyme was spectroscopically determined using chloride and cyanide as exogenous ligands. The pH dependence of the apparent dissociation constant of the enzyme-chloride complex showed the presence of a proton dissociable group with a pKa value of 4 on the enzyme; chloride binds to the enzyme when this group is protonated with a dissociation constant of 60 microM. The cyanide affinity of the enzyme is also regulated by the group with a pKa value of 4, but in this case cyanide binds to the unprotonated enzyme with a dissociation constant of 0.6 microM; only the protonated, uncharged form of cyanide reacts with the enzyme. Cyanide binding was competitively inhibited by chloride, and chloride binding was also competitively inhibited by cyanide. The EPR spectrum of the resting enzyme exhibited a rhombic high spin signal at g = 6.65, 5.28, and 1.97 with a low spin signal at g = 2.55, 2.32, and 1.82. Upon formation of the chloride complex, the spectrum was replaced with a new high spin EPR signal with g-values of 6.81, 5.04, and 1.95. The cyanide complex showed a low spin EPR signal with g-values of 2.83, 2.25, and 1.66. Examination of the enzymatic activity of the spleen green hemeprotein by following the chlorination of monochlorodimedon has indicated that the enzyme has the same chlorinating activity as myeloperoxidase; the spleen green peroxidase can catalyze the formation of hypochlorous acid from hydrogen peroxide and chloride ion. Comparison of the present data with those of myeloperoxidase has led to the conclusion that the structure of the iron center and its vicinity in spleen green hemeprotein is very similar, if not identical, to that of myeloperoxidase. The spleen enzyme can thus be used as a model to study the active center, and its environment, in myeloperoxidase.     

Myeloperoxidase-Halide-Hydrogen Peroxide Antibacterial System

An antibacterial effect of myeloperoxidase, a halide, such as iodide, bromide, or chloride ion, and H(2)O(2) on Escherichia coli or Lactobacillus acidophilus is described. When L. acidophilus was employed, the addition of H(2)O(2) was not required; however, the protective effect of catalase suggested that, in this instance, H(2)O(2) was generated by the organisms. The antibacterial effect was largely prevented by preheating the myeloperoxidase at 80 C or greater for 10 min or by the addition of a number of inhibitors; it was most active at the most acid pH employed (5.0). Lactoperoxidase was considerably less effective than was myeloperoxidase when chloride was the halide employed. Myeloperoxidase, at high concentrations, exerted an antibacterial effect on L. acidophilus in the absence of added halide, which also was temperature- and catalase-sensitive. Peroxidase was extracted from intact guinea pig leukocytes by weak acid, and the extract with peroxidase activity had antibacterial properties which were similar, in many respects, to those of the purified preparation of myeloperoxidase. Under appropriate conditions, the antibacterial effect was increased by halides and by H(2)O(2) and was decreased by catalase, as well as by cyanide, azide, Tapazole, and thiosulfate. This suggests that, under the conditions employed, the antibacterial properties of a weak acid extract of guinea pig leukocytes is due, in part, to its peroxidase content, particularly if a halide is present in the reaction mixture. A heat-stable antibacterial agent or agents also appear to be present in the extract.     

Effect of dimethylthiourea on the neutrophil myeloperoxidase pathway

The sulfur-centered compound dimethylthiourea (DMTU) affords antioxidant protection in animal models of acute lung injury, an effect that has been attributed to its OH. scavenging properties. Although DMTU can also react with H2O2 in certain experimental systems, the effect of DMTU on the neutrophil myeloperoxidase (MPO) pathway has not been studied. DMTU (1-10 mM) completely blocked stable oxidants and hypochlorous acid formation by phorbol myristate acetate- and zymosan-stimulated neutrophils. DMTU also provided complete inhibition when incubated with cell-free supernatants after the formation of the MPO products. DMTU prevented the oxidative inactivation of alpha 1-antitrypsin by neutrophil-stable oxidants. Evidence that DMTU was oxidized by the MPO products was obtained by titration of oxidized DMTU with reduced glutathione. Surprisingly, supernatants from cells incubated with DMTU (10 mM) consumed two- to threefold higher amounts of reduced glutathione than supernatants from cells incubated with taurine (15 mM). Metabolic studies with stimulated neutrophils and experiments with the MPO enzyme system in a cell-free system suggested that DMTU acts by scavenging the products of the MPO pathway rather than by blocking H2O2 production in the intact cell. These findings demonstrate that DMTU blocks the neutrophil MPO pathway in addition to its known ability to scavenge other reactive O2 species. The capacity of DMTU to scavenge MPO products may explain some of its protective effects in acute lung injury.     

Influence of ceruloplasmin and lactoferrin on the chlorination activity of leukocyte myeloperoxidase assayed by chemiluminescence

We demonstrate that addition of H₂O₂ to a mixture of myeloperoxidase (MPO), chloride and luminol immediately evokes a short intense flash of chemiluminescence (CL). This flash is diminished in the absence of MPO or chloride, and in the complete system it is suppressed by an MPO inhibitor azide, hypochlorite scavengers taurine or methionine, or an MPO peroxidase-cycle substrate guaiacol. Hence, this CL is mostly due to the MPO halogenation function; a measure of this activity is provided by the integral CL. With three independent methods (CL, taurine chlorination, and peroxidase assay) it is shown that MPO activity is suppressed by ceruloplasmin (Cp). Lactoferrin has no effect either on MPO or on the MPO-Cp complex. It is also shown that peroxidase inhibition by Cp is the stronger the larger is the MPO substrate, which suggests steric hindrances to substrate binding in the MPO-Cp complex. Importantly, the conventional chlorination and peroxidase assays detect MPO inhibition by Cp only at a large excess of the latter, whereas the CL assay reveals it at stoichiometric ratios characteristic of the naturally occurring protein complexes.