A continuous, fluorescent, high-throughput assay for human dimethylarginine dimethylaminohydrolase-1

Inhibitors of human dimethylarginine dimethylaminohydrolase-1 (DDAH-1) are of therapeutic interest for controlling pathological nitric oxide production. Only a limited number of biologically useful inhibitors have been identified, so structurally diverse lead compounds are desired. In contrast with previous assays that do not possess adequate sensitivity for optimal screening, herein is reported a high-throughput assay that uses an alternative thiol-releasing substrate, S-methyl-L-thiocitrulline, and a thiol-reactive fluorophore, 7-diethylamino-3-(4'-maleimidylphenyl)-4-methylcoumarin, to enable continuous detection of product formation by DDAH-1. The assay is applied to query two commercial libraries totaling 4446 compounds, and two representative hits are described, including a known DDAH-1 inhibitor. This is the most sensitive DDAH-1 assay reported to date and enables screening of compound libraries using [S] = K (M) conditions while displaying Z' factors from 0.6 to 0.8. Therefore, this strategy now makes possible high-throughput screening for human DDAH-1 inhibitors in pursuit of molecular probes and drugs to control excessive nitric oxide production.     

Co-oxidation of luminol by hypochlorite and hydrogen peroxide implications for neutrophil chemiluminescence

Stimulated neutrophils produce several potent oxidants including H2O2, O2- and HOCl. Previous studies have revealed all of these compounds to be capable of oxidizing luminol, a reagent often used to indicate, by its chemiluminescence, the oxidative burst of neutrophils. Data presented in this paper indicate that H2O2 and HOCl spontaneously react at physiologic pH to produce luminol-dependent chemiluminescence 100 times the sum of the chemiluminescence of either reagent alone. This enhancement is due to a co-oxidation by HOCl and H2O2, or to a novel oxidant generated by the interaction of HOCl and H2O2. The HOCl scavenger, taurine, inhibits the chemiluminescence. Evidence is presented against the participation of hydroxyl radical, O2- or singlet oxygen in the oxidation of luminol by HOCl and H2O2. These findings have implications for potential anti-inflammatory compounds.     

Inhibition of phosphatidylserine synthesis in Jurkat T cells by hydrogen peroxide.

Incubation of Jurkat cells in the presence of H2O2 either directly added to the culture medium or generated with glucose oxidase, menadione or the couple xanthine/xanthine oxidase induced a marked decrease of phosphatidylserine synthesis in the absence of changes in the synthesis of phosphatidylcholine and phosphatidylethanolamine. Concentration dependent response curves indicated that H2O2 induced inhibition of phosphatidylserine synthesis with an IC(50)=5 microM while both induction of tyrosine phosphorylation of proteins and Ca(2+) signals were obtained with an EC(50)=300 microM. The tyrosine kinase and Ca(2+) independent mechanism was confirmed by comparing the H2O2-induced and the CD3-induced inhibition of phosphatidylserine synthesis using several Jurkat clones differing in the expression of cell surface receptors such as CD3/TCR and CD45 and protein tyrosine kinase such as p72syk, ZAP-70 and p56lck. While CD3-induced inhibition of phosphatidylserine synthesis necessitates protein tyrosine phosphorylation and Ca(2+) signals, H2O2 provoked its effect in all the clones studied independently of the presence or absence of the proteins previously shown to be key elements in T cell signal transduction. Conversely, the antioxidant molecule, butylated hydroxanisole, generates an increased PtdSer synthesis, suggesting that the synthesis of this phospholipid is regulated by the redox status of the cells.     

Inhibition of organic anion transport in endothelial cells by hydrogen peroxide.

ATP loss is a prominent feature of cellular injury induced by oxidants or ischemia. How reduction of cellular ATP levels contributes to lethal injury is still poorly understood. In this study we examined the ability of H2O2 to inhibit in a dose-dependent manner the extrusion of fluorescent organic anions from bovine pulmonary artery endothelial cells. Extrusion of fluorescent organic anions was inhibited by probenecid, suggesting an organic anion transporter was involved. In experiments in which ATP levels in endothelial cells were varied by treatment with different degrees of metabolic inhibition, it was determined that organic anion transport was ATP-dependent. H2O2-induced inhibition of organic anion transport correlated well with the oxidant's effect on cellular ATP levels. Thus H2O2-mediated inhibition of organic anion transport appears to be via depletion of ATP, a required substrate for the transport reaction. Inhibition of organic anion transport directly by probenecid or indirectly by metabolic inhibition with reduction of cellular ATP levels was correlated with similar reductions of short term viability. This supports the hypothesis that inhibition of organic anion transport after oxidant exposure or during ischemia results from depletion of ATP and may significantly contribute to cytotoxicity.     

Inactivation of human myeloperoxidase by hydrogen peroxide

Human myeloperoxidase (MPO) uses hydrogen peroxide generated by the oxidative burst of neutrophils to produce an array of antimicrobial oxidants. During this process MPO is irreversibly inactivated. This study focused on the unknown role of hydrogen peroxide in this process. When treated with low concentrations of H₂O₂ in the absence of reducing substrates, there was a rapid loss of up to 35% of its peroxidase activity. Inactivation is proposed to occur via oxidation reactions of Compound I with the prosthetic group or amino acid residues. At higher concentrations hydrogen peroxide acts as a suicide substrate with a rate constant of inactivation of 3.9 × 10⁻³ s⁻¹. Treatment of MPO with high H₂O₂ concentrations resulted in complete inactivation, Compound III formation, destruction of the heme groups, release of their iron, and detachment of the small polypeptide chain of MPO. Ten of the protein’s methionine residues were oxidized and the thermal stability of the protein decreased. Inactivation by high concentrations of H₂O₂ is proposed to occur via the generation of reactive oxidants when H₂O₂ reacts with Compound III. These mechanisms of inactivation may occur inside neutrophil phagosomes when reducing substrates for MPO become limiting and could be exploited when designing pharmacological inhibitors.     

Inhibition of succinate-linked respiration and complex II activity by hydrogen peroxide

Hydrogen peroxide produced from electron transport chain derived superoxide is a relatively mild oxidant, and as such, the majority of mitochondrial enzyme activities are impervious to physiological concentrations. Previous studies, however, have suggested that complex II (succinate dehydrogenase) is sensitive to H₂O₂-mediated inhibition. Nevertheless, the effects of H₂O₂ on succinate-linked respiration and complex II activity have not been examined in intact mitochondria. Results presented indicate that H₂O₂ inhibits succinate-linked state 3 mitochondrial respiration in a concentration dependent manner. H₂O₂ has no effect on complex II activity during state 2 respiration, but inhibits activity during state 3. It was found that conditions which prevent oxaloacetate accumulation during state 3 respiration, such as inclusion of rotenone, glutamate, or ATP, blunted the effect of H₂O₂ on succinate-linked respiration and complex II activity. It is concluded that H₂O₂ inhibits succinate-linked respiration indirectly by sustaining and enhancing oxaloacetate-mediated inactivation of complex II.     

Inhibition of immunoglobulin G-catalyzed hydrogen peroxide generation by dexamethasone and piroxicam

In the present study, we established a simple and physiologically acceptable in vitro assay system to measure H2O2 generated by human immunoglobulin G (IgG) and other proteins. In addition, the effects of various drugs were also tested in this method. We found that UV irradiation (280 nm) of the test solutions for 1 h at 37 degrees C produced suitable conditions to test the effects of these drugs. The test solution contained 100 microg/ml IgG in 50 mM phosphate buffer (pH 7.4), and 1% dimethylformamide (DMF), a solvent used to dissolve each drug. Phosphate anions were preferable for H2O2 generation. H2O2 concentration in the irradiated sample was determined by continuous photometric measurement of absorption (O.D.) at 340 nm for 600 sec. The decrease in O.D. was due to the oxidation of NADPH by H2O2 mediated by the glutathione redox cycle. H2O2 generation was expressed as O.D.(340 nm decrease/400 sec). IgG (100 microg/ml) generated 6-7 microM H2O2/h. With irradiation, most cytokines, proteins and enzymes failed to generate significant amounts of H2O2. The formation of H2O2 from H2O and UV light-induced singlet oxygen (1O2) was demonstrated by the inhibitory effects of 1O2 quenchers. Dexamethasone (IC50: 6 ng/ml = 1.4x10(-8) M) blocked H2O2 generation catalyzed by IgG. This action was not mediated by binding to the glucocorticoid receptor. Piroxicam (IC50: 20 ng/ml = 6.0 x 10(-6) M) and diclofenac.Na (IC50: 500 ng/ml = 1.6 x 10(-5) M), but not indomethacin, also blocked H2O2 generation. The mechanism underlying the inhibition of IgG-catalyzed H2O2 generation is not clear; however, the possibility exists that these drugs intercept, or interfere with, the approach of water molecules at the catalytic interface(s) of the IgG.     

Inhibition of human neutrophil IL-8 production by hydrogen peroxide and dysregulation in chronic granulomatous disease

The innate immune response to bacterial infections includes neutrophil chemotaxis and activation, but regulation of inflammation is less well understood. Formyl peptides, byproducts of bacterial metabolism as well as mitochondrial protein biosynthesis, induce neutrophil chemotaxis, the generation of reactive oxygen intermediates (ROI), and the production of the neutrophil chemoattractant, IL-8. Patients with chronic granulomatous disease (CGD) exhibit deficient generation of ROI and hydrogen peroxide and susceptibility to bacterial and fungal pathogens, with associated dysregulated inflammation and widespread granuloma formation. We show in this study that in CGD cells, fMLF induces a 2- to 4-fold increase in IL-8 production and a sustained IL-8 mRNA response compared with normal neutrophils. Moreover, normal neutrophils treated with catalase (H(2)O(2) scavenger) or diphenyleneiodonium chloride (NADPH oxidase inhibitor) exhibit IL-8 responses comparable to those of CGD neutrophils. Addition of hydrogen peroxide or an H(2)O(2)-generating system suppresses the sustained IL-8 mRNA and increased protein production observed in CGD neutrophils. These results indicate that effectors downstream of the activation of NADPH oxidase negatively regulate IL-8 mRNA in normal neutrophils, and their absence in CGD cells results in prolonged IL-8 mRNA elevation and enhanced IL-8 levels. ROI may play a critical role in regulating inflammation through this mechanism.     

Inhibition of porcine kidney betaine aldehyde dehydrogenase by hydrogen peroxide

Renal hyperosmotic conditions may produce reactive oxygen species, which could have a deleterious effect on the enzymes involved in osmoregulation. Hydrogen peroxide was used to provoke oxidative stress in the environment of betaine aldehyde dehydrogenase in vitro. Enzyme activity was reduced as hydrogen peroxide concentration was increased. Over 50% of the enzyme activity was lost at 100 μM hydrogen peroxide at two temperatures tested. At pH 8.0, under physiological ionic strength conditions, peroxide inhibited the enzyme. Initial velocity assays of betaine aldehyde dehydrogenase in the presence of hydrogen peroxide (0-200 μM) showed noncompetitive inhibition with respect to NAD(+) or to betaine aldehyde at saturating concentrations of the other substrate at pH 7.0 or 8.0. Inhibition data showed that apparent V(max) decreased 40% and 26% under betaine aldehyde and NAD(+) saturating concentrations at pH 8.0, while at pH 7.0 V(max) decreased 40% and 29% at betaine aldehyde and NAD(+) saturating concentrations. There was little change in apparent Km(NAD) at either pH, while Km(BA) increased at pH 7.0. K(i) values at pH 8 and 7 were calculated. Our results suggest that porcine kidney betaine aldehyde dehydrogenase could be inhibited by hydrogen peroxide in vivo, thus compromising the synthesis of glycine betaine.     

Fragmentation of human ceruloplasmin induced by hydrogen peroxide

We investigated the fragmentation of human ceruloplasmin induced by H2O2 to study its oxidative damage. When ceruloplasmin was incubated with H2O2, the frequency of the protein fragmentation increased in a proportion to the concentration of H2O2. It also increased in a time-dependent manner and was accompanied by gradual loss of the oxidase activity. Hydroxyl radical scavengers such as azide and mannitol inhibited the fragmentation of ceruloplasmin. The deoxyribose assay showed that hydroxyl radicals were generated in the reaction of ceruloplasmin with H2O2. Incubation of ceruloplasmin with H2O2 resulted in a time-dependent release of copper ions. The released copper ion may participate in a Fenton-like reaction to produce hydroxyl radical, which enhanced the fragmentation. The protection of the fragmentation by copper chelators such as diethylenetriaminepentaacetic acid and bathocuproine indicates a role for copper ion in the reaction. These results suggest that the fragmentation of ceruloplasmin induced by H2O2 is due to hydroxyl radicals formed by a copper-dependent Fenton-like reaction.     

Killing of schistosomes by elastase and hydrogen peroxide: implications for leukocyte-mediated schistosome killing

Activated leukocytes participate in immunity to infection by the parasitic blood fluke Schistosoma mansoni. They attach to the surface of schistosomes and secrete schistosomicidal substances. Cationic proteins, hydrolytic enzymes, and oxidants, produced by the leukocytes, have been implicated in the damage to the schistosomes. To examine the possible involvement of elastase in the killing of schistosomes by leukocytes, young and adult stages of S. mansoni were treated in vitro with pancreatic elastase (PE) and neutrophil elastase (NE). Schistosomula, lung-stage schistosomula (LSS), and adult worms (AW) have been found to be sensitive to both PE and NE. Male AW were more sensitive to PE than female AW. The enzymatic activity of elastase is essential for its toxic effect because heat-inactivation and specific elastase inhibitors prevented elastase-mediated schistosome killing. Thus, alpha1-antitrypsin and the chloromethyl ketone (CMK)-derived tetrapeptides Ala-Ala-Pro-Val-CMK and Ala-Ala-Pro-Ala-CMK but not Ala-Ala-Pro-Phe-CMK and Ala-Ala-Pro-Leu-CMK blocked PE caseinolytic and schistosomulicidal activities. As shown previously, schistosomes are also efficiently killed by hydrogen peroxide. LSS appear to be more resistant than AW and early-stage schistosomula to the lytic effects of hydrogen peroxide. Cotreatment experiments with both elastase and hydrogen peroxide indicated that they exert an additive toxic effect and that hydrogen peroxide sensitizes schistosomula to the toxic effect of elastase but not vice versa. These results demonstrate, for the first time, that elastases may be toxic molecules used by neutrophils, eosinophils, and macrophages to kill various developmental stages of S. mansoni.     

Inhibition of Chinese hamster ovary cell DNA synthesis by hydrogen peroxide

The DNA synthesis inhibitory effect of hydrogen peroxide has been examined under a number of experimental conditions. Results have indicated that the effect of the oxidant is more pronounced when the treatment is performed at 37 degrees C than at 4 degrees C and in low density as compared to high density cultures. In addition, similar levels of inhibition were achieved by measuring the incorporation of radiolabelled thymidine in the presence of, or following treatment with, the oxidant. Although early events seem to be responsible for the decreased rate of DNA synthesis, it would appear that hydrogen peroxide does not alter thymidine extracellularly and/or decrease the transport of the nucleoside across the plasma membrane, which may actually be slightly augmented. Thus, the previously illustrated results may represent an underestimate of the actual capacity of the oxidant to reduce DNA synthesis. This inference is further supported by the fact that the effect of hydrogen peroxide appears markedly enhanced in cells preloaded with the radiolabelled precursor. A temporal relationship seems to exist between the steady state level of DNA single strand breaks and the extent of DNA synthesis inhibition by hydrogen peroxide. The oxidant has no effect on DNA chain elongation. In conclusion, data presented in this paper suggest that early events, involving selective effects on replicon initiation, mediate the DNA synthesis inhibitory effect of hydrogen peroxide.     

Inactivation of calcineurin by hydrogen peroxide and phenylarsine oxide. Evidence for a dithiol-disulfide equilibrium and implications for redox regulation.

Calcineurin (CaN) is a Ca2+-and calmodulin (CaM)-dependent serine/threonine phosphatase containing a dinuclear Fe-Zn center in the active site. Recent studies have indicated that CaN is a possible candidate for redox regulation. The inactivation of bovine brain CaN and of the catalytic CaN A-subunit from Dictyostelium by the vicinal dithiol reagents phenylarsine oxide (PAO) and melarsen oxide (MEL) and by H2O2 was investigated. PAO and MEL inhibited CaN with an IC50 of 3-8 microM and the inactivation was reversed by 2, 3-dimercapto-1-propane sulfonic acid. The treatment of isolated CaN with hydrogen peroxide resulted in a concentration-dependent inactivation. Analysis of the free thiol content performed on the H2O2 inactivated enzyme demonstrated that only two or three of the 14 Cys residues in CaN are modified. The inactivation of CaN by H2O2 could be reversed with 1,4-dithiothreitol and with the dithiol oxidoreductase thioredoxin. We propose that a bridging of two closely spaced Cys residues in the catalytic CaN A-subunit by PAO/MEL or the oxidative formation of a disulfide bridge by H2O2 involving the same Cys residues causes the inactivation. Our data implicate a possible involvement of thioredoxin in the redox control of CaN activity under physiological conditions. The low temperature EPR spectrum of the native enzyme was consistent with a Fe3+-Zn2+ dinuclear centre. Upon H2O2-mediated inactivation of the enzyme no significant changes in the EPR spectrum were observed ruling out that Fe2+ is present in the active enzyme and that the dinuclear metal centre is the target for the oxidative inactivation of CaN.     

Inhibition of human T lymphocyte E rosette formation by neutrophils and hydrogen peroxide. Differential sensitivity between helper and suppressor T lymphocytes

Co-incubation of human mononuclear cells with small numbers of autologous polymorphonuclear leukocytes resulted in a ratio-dependent inhibition of T lymphocyte rosette formation with sheep erythrocytes (SRBC). Inhibition by polymorphonuclear leukocytes was reversed with catalase, implicating H2O2 or associated products as the suppressive agent(s). Exposing T lymphocytes directly to micromolar concentrations of H2O2 also inhibited subsequent rosette formation. Inhibition was dose-dependent between 40 and 320 microM H2O2 and was not due to cytotoxicity at those H2O2 concentrations. Kinetic studies demonstrated that after exposing T lymphocytes to H2O2 a proportion of cells appeared to be relatively resistant in that they retained their ability to form E rosettes. T cell phenotype analysis of these cells showed that, in contrast to untreated T cells, H2O2-treated T rosette-forming cells were almost exclusively of the helper/inducer phenotype. Analysis with the monoclonal antibody 4B4 revealed that H2O2-resistant T rosette-forming cells contained significantly fewer 4B4-positive cells than predicted for the T helper population, indicating that H2O2-resistant T cells might be a subset of helper/inducer T lymphocytes. The interaction between H2O2 and T cells was rapid but did not lead to loss of Leu-5b binding sites. Preliminary functional analysis indicates that interleukin 2 production and phytohemagglutinin-induced proliferation by the relatively H2O2-resistant T cells is similar to untreated T cells. In contrast, H2O2-treated T cells which lost their ability to form E rosettes produced undetectable levels of interleukin 2 and proliferated poorly in response to phytohemagglutinin. Finally, mononuclear cells pretreated with H2O2 and subsequently stimulated with mitogens demonstrated a preferential expansion of the T helper population with concomitant loss of T suppressors. Our results show that, although neutrophil-released H2O2 inhibits effective interactions between SRBC and T lymphocyte sheep erythrocyte receptors, there appears to be a population of T helper cells which is relatively resistant to H2O2 both in terms of SRBC rosette formation and response to mitogens. These data suggest that at sites of inflammation phagocyte-released H2O2 could exert immunoregulatory effects on T cells by altering T cell subset survival and allowing the function of a particular lymphocyte population to predominate.     

Inhibition of peroxidase and catalase activities and modulation of hydrogen peroxide level by inositol phosphoglycan-like compounds.

Inositol phosphoglycan-like compounds are produced by the hydrolysis of the membrane bound glycosyl phosphoinositides. Besides being short term mediators of insulin action, they inhibit peroxidases and catalase, increasing the concentration of cellular hydrogen peroxide. Although high concentrations of hydrogen peroxide are toxic, moderate increases of its basal level are signals for different metabolic pathways. The inhibitor, localized in the cytosol of the cell, acts on peroxidases and catalase of the same tissue (homologous action) and of other tissues or organisms (heterologous action). The inositol phosphoglycan-like compound inhibits peroxidases with different prosthetic groups, i.e. containing iron such as: thyroid peroxidase, lactoperoxidase, horseradish peroxidase, soy bean peroxidase; and containing selenium such as glutathione peroxidase and 2-cys peroxiredoxin with no prosthetic group. Besides peroxidases, the inositol phosphoglycan-like compound inhibits catalase, another heme enzyme. The inhibition kinetics demonstrates a noncompetitive effect. The site of action is not the prosthetic group, given that the inhibitor does not produce any effect on the peak in the Soret region in the presence or absence of hydrogen peroxide. In conclusion, the inositol phosphoglycan-like compound is the general inhibitor of peroxidases and catalase involved in the modulation of hydrogen peroxide level that acts in different metabolic pathways as a signal transducer.     

Mechanism of enzymatic and non-enzymatic tyrosine iodination. Inhibition by excess hydrogen peroxide and/or iodide

Non-enzymatic (I2-mediated) and lactoperoxidase-catalyzed iodination of tyrosine are inhibited by excess iodide (I-) and/or hydrogen peroxide (H2O2). This phenomenon is a consequence of the concentration-dependent dual role of I- and H2O2 in the iodinating system. I- and H2O2, in addition to their function as primary substrates of peroxidase, may act as alternative 'iodine acceptors' and therefore compete with tyrosine for the active iodinating agent, irrespective of whether this compound is an enzyme-associated iodinium cation (E X I delta +) or an equivalent oxidized iodine species (IOH, IC1, I2). The competitive reaction pathways resulting from excess I- and/or H2O2 in the iodination system are I2/I-3 generation and/or pseudo-catalatic degradation of H2O2, respectively. Our results also demonstrate that I2 (and alternative medium-dependent oxidized iodine species such as IOH and IC1) generated in the iodination system may play an important role as iodinating agent(s). They serve as a substitute for the enzyme-bound iodinium species (E X I delta +), if the prevailing I- concentration favours this pathway. The proposed mechanism of the various antagonistic and interactive reaction pathways is summarized in a scheme.     

Diffusion of extracellular hydrogen peroxide into intracellular compartments of human neutrophils. Studies utilizing the inactivation of myeloperoxidase by hydrogen peroxide and azide

It is well known that catalase is transformed to nitric oxide-Fe2+-catalase by hydrogen peroxide (H2O2) plus azide. In this report, we show that myeloperoxidase is also inactivated by H2O2 plus azide. Utilizing this system, we studied the presence and source of intracellular H2O2 generated by activated neutrophils. Stimulation of neutrophils with phorbol myristate acetate (PMA, 100 ng/ml) plus azide (5 mM) for 30 min completely inactivated intragranular myeloperoxidase and reduced cytosolic catalase to 35% of resting cells. This intracellular inactivation of heme enzymes did not occur in normal neutrophils incubated with either PMA or azide alone or in neutrophils from patients with chronic granulomatous disease (CDG) which cannot produce H2O2 in response to PMA. Incubation of neutrophils with azide and a H2O2 generating system (glucose-glucose oxidase) inactivated 41% of neutrophil myeloperoxidase. Glutathione-glutathione peroxidase (GSH-GSH peroxidase), an extracellular H2O2 scavenger, totally protected neutrophil myeloperoxidase from inactivation by azide plus glucose-glucose oxidase. In addition, when a mixture of normal and CGD cells was stimulated with PMA in the presence of azide, 90% of the myeloperoxidase in CGD neutrophils was inactivated. Therefore, H2O2 released extracellularly from activated neutrophils can diffuse into cells. In contrast, myeloperoxidase in normal polymorphonuclear leukocytes stimulated with PMA in the presence of azide and GSH-GSH peroxidase was 75% inactivated. Thus, the results indicate that a GSH-GSH peroxidase-insensitive pool of H2O2 is also generated, presumably at the plasma membrane, and this pool of H2O2 can undergo direct internal diffusion to inactivate myeloperoxidase.     

Inhibition of proteoglycan synthesis by hydrogen peroxide in cultured bovine articular cartilage

Oxygen-derived reactive species, generated enzymatically by the action of xanthine oxidase upon hypoxanthine, significantly inhibit proteoglycan synthesis by cultured bovine articular cartilage (Bates, E.J., Lowther, D.A. and Handley, C.J. (1984) Ann. Rheum. Dis. 43, 462-469). Here we extend these investigations and show, through the use of catalase and the specific iron chelator diethylenetriaminepentaacetic acid, that the active species involved is H2O2 and not the hydroxyl radical. Incubations of cartilage with H2O2 at concentrations of 1 X 10(-4) M and above are also inhibitory to proteoglycan synthesis. Subsequent recovery of the tissue is dependent upon the initial dose of xanthine oxidase or H2O2. Xanthine oxidase at 84 mU per incubation results in a prolonged inhibition of proteoglycan synthesis which is still apparent after 14 days in culture. Lower concentrations of xanthine oxidase (21-66 mU) are inhibitory to proteoglycan synthesis, but the tissue is able to synthesise proteoglycans at near normal rates after 3 days in culture. The inhibition of proteoglycan synthesis by 1 X 10(-4) M H2O2 is completely reversed after 5 days in culture, whereas 1 X 10(-3) M H2O2 results in a more prolonged inhibition. The synthesis of the proteoglycan core protein is inhibited, but the ability of the newly formed proteoglycans to aggregate with hyaluronic acid is unimpaired.