An electron spin resonance (ESR) study on the mechanism of ascorbyl radical production by metal-binding proteins

The mechanism of ascorbate oxidation by metal-binding proteins (ceruloplasmin, albumin and transferrin) was investigated in vitro and in isolated plasma by the measurement of the ascorbyl free radicals (AFR) by electron spin resonance (ESR). In plasma of 13 healthy volunteers, a spontaneous and variable pro-duction of AFR was detected, which was increased by a 10 M ascorbate overloading; however, this increase was not correlated to the intensity of the spontaneous AFR signal. The addition of Cu and ceruloplasmin to plasma increased the ESR signal, while the addition of transferrin decreased the signal intensity in a dose-dependent manner. In vitro, we demonstrated that ascorbate was oxidized by human serum albumin and by ceruloplasmin, and that this oxidase-like activity was lost by trypsin or heat treatment of these proteins. These two proteins positively interacted in the oxidation of ascorbate, since addition of crude albumin to a solution of ascorbate and ceruloplasmin increased the intensity of ESR signal in a dose-dependent manner. The treatment of albumin by a metal chelator (DDTC) abolished these positive inter-actions. The respective roles of copper and iron in ascorbate oxidation were studied and showed a dose-dependent effect of these ions on ascorbate oxidation. The role of iron was confirmed by the inhibiting effect of metal-free transferrin on iron-dependent ascorbate oxidation. Concerted actions between iron carrying albumin and copper carrying ceruloplasmin appear responsible for the production of AFR in vitro and in vivo. © Rapid Science 1998     

A kinetic study of the coupled iron-ceruloplasmin catalyzed oxidation of ascorbate in the presence of albumin

Ascorbate is catalytically oxidized by a coupled iron-ceruloplasmin system, the iron ions functioning as a red/ox cycling intermediate between ceruloplasmin and ascorbate. Serum albumin, an iron binding compound, was found to stimulate the ascorbate oxidation rate. It is proposed that ferrous ions react more rapidly with ceruloplasmin when they are bound to albumin. A K _m value of 39 m was estimated for Fe²⁺-albumin. Citrate and urate inhibit the iron-ceruloplasmin-dependent ascorbate oxidation by chelating ferric ions. In the presence of albumin only citrate reduced the oxidation rate, the observation suggesting the following order of iron binding ability: citrate > albumin > urate. Physiological aspects of the results have been discussed.     

Free radical mediated interaction of ascorbic acid and ascorbate/Cu(II) with viral and plasmid DNAs

Previous studies indicate that ascorbic acid, when combined with copper or iron cleaves several viral DNA. ln this study, we generated the ascorbate radical anion electrochemically in a simple chemical environment without the participation of a metal ion. This solution possesses viral DNA scission activity. Ohe absence of catalytic metal ions [Fe (III) and Cu(II)] in the incubation medium was evidenced by metal chelating agents such as desferrioxamine and EDTA. Ohe radical quenching at high EDTA concentration was attributed to ionic strength of EDTA rather than metal chelation. Ohe effects of antioxidants, radical scavangers, catalase, superoxide dismutase and some proteins on DNA cleavage have been tested. Cleavage may not arise directly from ascorbate free radical but the reaction of the radical form of ascorbate with oxygen may produce the actual reactive species. Aerobic oxidation of ascorbate itself strictly requires transition metal catalysts, however electrochemically produced ascorbyl radical avoided the kinetic barrier that prevented direct oxidation of ascorbic acid with oxygen and eliminated the need for the transition metal ion catalysts.     

In vitro lipid peroxidation of human serum catalyzed by cupric ion: antioxidant rather than prooxidant role of ascorbate.

The dual role of ascorbate as an antioxidant and a prooxidant has been clearly documented in the literature. Ascorbate acts as an antioxidant by protecting human serum from lipid peroxidation induced by azo dye-generated free radicals. On the other hand, ascorbate is readily oxidized in the presence of transition metal ions, (especially cupric ion) and accelerates lipid peroxidation in tissue homogenates by producing free radicals. Interestingly, we observed an antioxidant rather than an expected prooxidant role of ascorbate when human serum supplemented with 1.2mmol/L ascorbate underwent lipid peroxidations initiated by 2mmol/L copper sulfate. The antioxidant role of ascorbate was confirmed by studying the conventional thiobarbituric acid reactive substances (TBARS) as well as by observing the protective effect of ascorbate on the copper-induced peroxidation of unsaturated and polyunsaturated fatty acids. The antioxidation protection provided by ascorbate was comparable to that of equimolar alpha-tocopherol when incubated for 24h. However, lipid peroxidation products were lower in serum supplemented with alpha-tocopherol after 48h of incubation. This effect may be attributed to the binding of copper by plpha-tocopherol after serum proteins, thus preventing direct interaction between cupric ions and ascorbate. This proposed mechanism is based on the observation that the concentration of ascorbate decreased more slowly in serum than in phosphate buffer at physiological pH. Our results also indicate an outstanding anti-oxidant property of human serum due to the chelation of transition metal ions (even at high concentrations) by various serum proteins.     

The Role of Histidine Residues in the Non-Enzyme Covalent Attachment of Glucose and Ascorbic Acid to Protein

Copper ions have been suggested to play a role in the non-covalent glycosylation (glycation) of proteins via transition metal-catalysed oxidations. We have further investigated “autoxidative glycosylation” by comparison of the behaviour of dog and bovine serum albumin with respect to the oxidative reactions of glucose and ascorbate. The proteins possess similar numbers of total amino residues available for glucose attachment but dog serum albumin contains fewer histidine groups and also lacks a high affinity copper-binding site. We find that the higher copper-binding capacity of bovine serum albumin is reflected in a lower rate of ascorbate oxidation as well as less protein oxidative damage than is the case for dog serum albumin. We also observe that modification of bovine serum albumin histidine groups by diethylpyrocarbonate enhances ascorbate-mediated protein fluorophore formation.     

Binding of fatty acids facilitates oxidation of cysteine-34 and converts copper-albumin complexes from antioxidants to prooxidants

As a transition metal capable of undergoing one-electron oxidation-reduction conversions, copper (Cu) is essential for life and fulfills important catalytic functions. Paradoxically, the same redox properties of copper can make it extremely dangerous because it can catalyze production of free radical intermediates from molecular oxygen. Factors involved in regulation of redox activity of albumin-bound copper have not been well characterized. In the present study, effects of modification of the albumin cysteine-34 (Cys-34) and binding of nonesterified fatty acids on the redox-cycling activity of the complex of copper with human serum albumin (Cu/HSA) were studied. Because ascorbate is the most abundant natural reductant/scavenger of free radicals in blood plasma, the electron paramagnetic resonance assay of ascorbate radical formation was used as a method to monitor Cu/HSA redox-cycling activity. At Cu/HSA ratios below 1:1, the bound Cu was virtually redox inactive, as long as Cys-34 was in reduced state (Cu/HSA-SH). Alkylation, nitrosylation, or oxidation of Cu/HSA resulted in the appearance of redox-cycling activity. Experiments with ultrafiltration of Cu/HSA alkylated with N-ethylmaleimide (Cu/HSA-NEM) showed that at Cu/HSA-NEM ratios below 1:1, the ascorbate radicals were produced by Cu tightly bound to HSA rather than by Cu released in solution. The rate of ascorbate radical production in HSA-NEM and S-nitrosylated HSA (HSA-NO) was, however, more than one order of magnitude lower than that in a solution containing equivalent concentration of free copper ions. While Cu/HSA-SH was redox inactive, binding of oleic or linoleic acids induced Cu-dependent redox-cycling with maximal activity reached at a fatty acid to protein molar ratio of 3:1 for oleic acid and 2:1 for linoleic acid. Binding of fatty acids caused profound conformational changes and facilitated oxidation of the Cys-34 SH-group at essentially the same ratios as those that caused redox-cycling activity of Cu/HSA. We conclude that fatty acids regulate anti-/prooxidant properties of Cu-albumin via controlling redox status of Cys-34.     

Kinetic studies of copper-induced oxidation of urate, ascorbate and their mixtures

Urate and ascorbate are the major water-soluble low molecular weight antioxidants in serum. Much attention has been devoted to the effect of these antioxidants on lipoprotein peroxidation in vivo and on their effect on copper-induced peroxidation ex vivo. These studies revealed that urate inhibits ascorbate oxidation in vitro, whereas the effect of ascorbate on urate oxidation has not been systematically studied thus far. The present study addresses mechanistic aspects of the kinetics of copper-induced oxidation of both these antioxidants and their mutual effects in aqueous solutions. We found that: (i) ascorbate becomes oxidized much faster than urate. (ii) Urate inhibits the oxidation of ascorbate but, even in the presence of excess urate, ascorbate becomes oxidized much faster than urate. (iii) Ascorbate, as well as the products of its oxidation (and/or hydrolysis) inhibit the copper-induced oxidation of urate. All these results are consistent with the hypothesis that the rate of ascorbate oxidation is determined by the rate of reoxidation of reduced copper (Cu(I)) to Cu(II) by molecular oxygen, whereas the rate of urate oxidation is governed by the rate of oxidation of urate within a 2:1 urate/copper complex. We think that the mutual effects of urate and ascorbate on each other's oxidation are likely to enhance their inhibitory effect on lipid peroxidation in biologically relevant systems including membranes and lipoproteins.     

Protein aging by carboxymethylation of lysines generates sites for divalent metal and redox active copper binding: relevance to diseases of glycoxidative stress.

Aging and age-related diseases are associated with the production of reactive oxygen species which modify lipids, proteins and DNA. Here we hypothesized the glyco- and lipoxidation product N(epsilon)-(carboxymethyl)lysine (CML) in proteins should bind divalent and redox active transition metal binding. CML-rich poly-L-lysine and bovine serum albumin (BSA) were chemically prepared and found to bind non-dialyzable Cu(2+), Zn(2+) and Ca(2+). CML-BSA-copper complexes oxidized ascorbate and depolymerized protein in the presence of H(2)O(2). CML-rich tail tendons implanted for 25 days into the peritoneal cavity of diabetic rats had a 150% increase in copper content and oxidized ascorbate three times faster than controls. CML-rich proteins immunoprecipitated from serum of uremic patients oxidized four times more ascorbate than control and generated spin adducts of DMPO in the presence of H(2)O(2). The chelator DTPA suppressed ascorbate oxidation thereby implicating transition metals in the process. In aging and disease, CML accumulation may result in a deleterious vicious cycle since CML formation itself is catalyzed by lipoxidation and glycoxidation.     

Synergistic inhibition of low-density lipoprotein oxidation by rutin, gamma-terpinene, and ascorbic acid.

Low-density lipoprotein (LDL) oxidation may play a significant role in atherogenesis. Flavonoids are well-known for their excellent antioxidative capacity in various model systems, therefore we examined the behaviour of rutin, a quercetin-3-rutinosid, in the copper-mediated LDL oxidation. Rutin alone has been shown to protect LDL against oxidation. Furthermore we investigated the combination of rutin with a hydrophilic (ascorbate) and a lipophilic antioxidant (gamma-terpinene) in copper-mediated LDL oxidation. In both cases we found a synergistic effect on lag phase prolongation. To elucidate whether this effect mainly depends on the copper chelating ability of rutin we examined its reaction in more detail. Although inhibiting the oxidation of alpha-linolenic acid in the "rose bengal system" no direct influence of a copper-rutin-complex was determined. We conclude that a redox active copper-rutin-complex is still able to initiate the LDL oxidation but may prevent copper from a reaction at the binding sites of apoB-100. The synergistic effect in preventing LDL oxidation is due to this trapping of copper in a complex in the case of ascorbate. The synergistic action of rutin and gamma-terpinene can be explained by different distribution of rutin and gamma-terpinene in, and around the LDL-particle, respectively.     

Stabilization of ascorbate solution by chelating agents that block redox cycling of metal ions

Among the seven chelating agents tested, ethylenediamine di(o-hydroxyphenylacetic acid) and diethylenetriamine pentaacetic acid were found to almost completely inhibit ascorbate oxidation catalyzed by iron ions. The inhibition with the former chelator is due to the prevention of the reduction of Fe3+ by ascorbate, while the inhibition with the latter is caused by the strong inhibition of both this reductive reaction and the oxidation of Fe2+ by O2. These chelators almost completely inhibit ascorbate oxidation catalyzed by copper ions as well. These results indicate that the blocking of redox cycling of metal ions is important to prevent the oxidation of ascorbate.     

Ascorbate-induced high-affinity binding of copper to cytosolic proteins

Copper chaperones are necessary for intracellular trafficking of copper to target proteins. This is probably because the milieu inside the cell has a large capacity for sequestering this metal. By fluorometry using a fluorescent Cu(II) chelator and by centrifugal ultrafiltration, we have studied copper binding of the whole cytosolic proteins from mouse brain and liver, and found that their binding capacity and affinity for copper were markedly increased by ascorbate. Brain cytosolic protein bound, with high affinity, 63 nmol of copper/mg, more than half of which was redox-inactive, as indicated by its inability to catalyze oxidation of ascorbate. Most of the bound copper was in the Cu(I) state, coordinating to thiol groups of protein. Cytosolic protein competed for copper more strongly than GSH when compared at their relative concentrations in tissues. The results taken together suggest that protein thiols of cytosol can strongly sequester copper.     

The regeneration with ascorbate of Helix pomatia methaemocyanin mediated by hydrogen peroxide

The regeneration of the copper bands of H. pomatia haemocyanin proceeds much more slowly with an excess of ascorbate than with a slight excess of hydrogen peroxide. The regenerating agent with ascorbate is hydrogen perioxide, formed in its autoxidation at the air. This was concluded after regeneration experiments with ascorbate under strictly anaerobic conditions and at the air in the presence of catalase. The autoxidation of ascorbate was catalysed by Fe and Cu ions. In the presence of EDTA there is still metal catalysis, especially in slightly alkaline medium, due to the Fe(III)-EDTA complex. Addition of diethylenetriamine pentaacetate completely abolished the metal catalysis.     

Role of lipoprotein-copper complex in copper catalyzed-peroxidation of low-density lipoprotein.

The oxidative modification of low-density lipoprotein (LDL) is suggested to play an important role in the pathogenesis of atherosclerosis. The present study examined the role of the formation of LDL-copper (Cu) complex in the peroxidation of LDL. The amount of copper bound to LDL increased during incubation performed with increasing concentrations of CuSO4. More than 80% of the copper bound to the LDL particle was observed in the protein phase of LDL, suggesting that most of the copper ions formed complexes with the ligand-binding sites of apoprotein. The addition of histidine (1 mM), known to form a high affinity complex with copper, and EDTA (1 mM), a metal chelator, during the incubation of LDL with CuSO4 prevented the formation of both thiobarbituric acid-reactive substances (TBARS) and LDL-Cu complexes. EDTA inhibited the copper-catalyzed ascorbate oxidation whereas histidine had no effect, suggesting that the copper within the complex with histidine is available to catalyze the reaction, in contrast to EDTA. These observations indicate that the preventive effect of histidine on the copper-catalyzed peroxidation of LDL is not simply mediated by chelating free copper ions in aqueous phase. Evidence that copper bound to LDL particle still has a redox potential was provided by the observed increase in TBARS content during incubation of LDL-Cu complexes in the absence of free copper ions. The addition of either histidine or EDTA to LDL-Cu complexes inhibited the formation of TBARS by removing copper ions from the LDL forming the corresponding complexes. However, there still remained small amounts of copper in the LDL particles following the treatment of LDL-Cu complexes with histidine or EDTA. The copper ions remaining in the LDL particle lacked the ability to catalyze LDL peroxidation, suggesting that there may be two types of copper binding sites in LDL: tight-binding sites, from which the copper ions are not removed by chelation, and weak-binding sites, from which copper ions are easily removed by chelators. The formation of TBARS in the LDL preparation during incubation with CuSO4 was comparable to the incubation with FeSO4. In contrast, the formation of TBARS in the LDL-lipid micelles by CuSO4 was nearly eliminated even in the presence of ascorbate to promote metal-catalyzed lipid peroxidation, although a marked increase in TBARS content was observed in the LDL-lipid micelles with FeSO4, and with FeCl3 in the presence of ascorbate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Reactions of copper macrocycles with antioxidants and HOCl: potential for biological redox sensing

A series of simple copper N₂S₂ macrocycles were examined for their potential as biological redox sensors, following previous characterization of their redox potentials and crystal structures. The divalent species were reduced by glutathione or ascorbate at a biologically relevant pH in aqueous buffer. A less efficient reduction was also achieved by vitamin E in DMSO. Oxidation of the corresponding univalent copper species by sodium hypochlorite resulted in only partial (~65 %) recovery of the divalent form. This was concluded to be due to competition between metal oxidation and ligand oxidation, which is believed to contribute to macrocycle demetallation. Electrospray mass spectrometry confirmed that ligand oxidation had occurred. Moreover, the macrocyclic complexes could be demetallated by incubation with EDTA and bovine serum albumin, demonstrating that they would be inappropriate for use in biological systems. The susceptibility to oxidation and demetallation was hypothesized to be due to oxidation of the secondary amines. Consequently these were modified to incorporate additional oxygen donor atoms. This modification led to greater resistance to demetallation and ligand oxidation, providing a better platform for further development of copper macrocycles as redox sensors for use in biological systems.     

Inhibition of astrocyte glutamate uptake by reactive oxygen species: role of antioxidant enzymes.

BACKGROUND: The recent literature suggests that free radicals and reactive oxygen species may account for many pathologies, including those of the nervous system. MATERIALS AND METHODS: The influence of various reactive oxygen species on the rate of glutamate uptake by astrocytes was investigated on monolayers of primary cultures of mouse cortical astrocytes. RESULTS: Hydrogen peroxide and peroxynitrite inhibited glutamate uptake in a concentration-dependent manner. Addition of copper ions and ascorbate increased the potency and the efficacy of the hydrogen peroxide effect, supporting the potential neurotoxicity of the hydroxyl radical. The free radical scavenger dimethylthiourea effectively eliminated the inhibitory potential of a mixture containing hydrogen peroxide, copper sulphate, and ascorbate on the rate of glutamate transport into astrocytes. The inhibitory effect of hydrogen peroxide on glutamate uptake was not altered by the inhibition of glutathione peroxidase, whereas the inhibition of catalase by sodium azide clearly potentiated this effect. Superoxide and nitric oxide had no effect by themselves on the rate of glutamate uptake by astrocytes. The absence of an effect of nitric oxide is not due to an inability of astrocytes to respond to this substance, since the same cultures did respond to nitric oxide with a sustained increase in cytoplasmic free calcium. CONCLUSION: These results confirm that reactive oxygen species have a potential neurotoxicity by means of impairing glutamate transport into astrocytes, and they suggest that preventing the accumulation of hydrogen peroxide in the extracellular space of the brain, especially during conditions that favor hydroxyl radical formation, could be therapeutic.     

Copper modifies liver microsomal UDP-glucuronyltransferase activity through different and opposite mechanisms

Treatment of hepatic microsomes with Fe(3+)/ascorbate activates UDP-glucuronyltransferase (UGT), a phenomenon totally prevented and reversed by reducing agents. At microM concentrations, iron and copper ions catalyze the formation of ROS through Fenton and/or Haber-Weiss reactions. Unlike iron ions, indiscriminate binding of copper ions to thiol groups of proteins different from the specialized copper-binding proteins may occur. Thus, we hypothesize that incubation of hepatic microsomes with the Cu(2+)/ascorbate system will lead to both UGT oxidative activation and Cu(2+)-binding induced inhibition, simultaneously. We studied the effects of Cu(2+) alone and in the presence of ascorbate on rat liver microsomal UGT activity. Our results show that the effects of both copper alone and in the presence of ascorbate were copper ion concentration- and incubation time-dependent. At very low Cu(2+) (25nM), this ion did not modify UGT activity. In the presence of ascorbate, however, UGT activity was increased. At higher copper concentrations (10 and 50microM), this ion led to UGT activity inhibition. In the presence of ascorbate, 10microM Cu(2+) activated UGT at short incubation periods but inhibited this enzyme at longer incubation times; 50microM Cu(2+) only inhibited UGT activity. Thiol reducing agent 2,4-dithiothreitol prevented and reversed UGT activation while EDTA prevented both, UGT activation and inhibition. Our results are consistent with a model in which Cu(2+)-induced oxidation of UGT leads to the activation of the enzyme, while Cu(2+)-binding leads to its inhibition. We discuss physiological and pathological implications of these findings.     

Conversion of lysine to N(epsilon)-(carboxymethyl)lysine increases susceptibility of proteins to metal-catalyzed oxidation.

Metal-catalyzed oxidation (MCO) of proteins leads to the conversion of some amino acid residues to carbonyl derivatives, and may result in loss of protein function. It is well documented that reactions with oxidation products of sugars, lipids, and amino acids can lead to the conversion of some lysine residues of proteins to N(epsilon)-(carboxymethyl)lysine (CML) derivatives, and that this increases their metal binding capacity. Because post-translational modifications that enhance their metal binding capacity should also increase their susceptibility to MCO, we have investigated the effect of lysine carboxymethylation on the oxidation of bovine serum albumin (BSA) by the Fe(3+)/ascorbate system. Introduction of approximately 10 or more mol CML/mol BSA led to increased formation of carbonyls and of the specific oxidation products glutamic and adipic semialdehydes. These results support the view that the generation of CML derivatives on proteins may contribute to the oxidative damage that is associated with aging and a number of age-related diseases.     

Zinc(II) Protects Against Metal-Mediated Free Radical Induced Damage: Studies on Single and Double-Strand DNA Breakage

M13 DNA was used as a source for single and double-stranded DNA. Free radical-induced damage to single and double stranded DNA was caused by asorbateliron and ascorbate/copper oxidative systems. The degree of breakage was estimated by running samples on an agarose gel and staining with ethidium bromide, followed by photographic analysis. DflA breakage was dependent on time and concentration of iron or copper ions. Zincions protected against damage caused by iron/asorbate both to single-stranded and double-stranded DNA. In contrast, in the copper/ascorbate system zinc ions protected only against the double-stranded DNA (replicative form of M13) breakage, and not against copper-mediated single-stranded DNA breakages. It seemed to amplify the efficiency of breakage. The protection provided to the replicative form in the copper/ascorbate system is much less effective than the protection to DNA in the iron/ascorbate system. These results support the notion that redox-inactive metal ions, that compete for iron or copper binding sites, could provide protection against transition metal-mediated and free radical-induced damage.     

Zinc(II) Protects Against Metal-Mediated Free Radical Induced Damage: Studies on Single and Double-Strand DNA Breakage

M13 DNA was used as a source for single and double-stranded DNA. Free radical-induced damage to single and double stranded DNA was caused by asorbateliron and ascorbate/copper oxidative systems. The degree of breakage was estimated by running samples on an agarose gel and staining with ethidium bromide, followed by photographic analysis. DflA breakage was dependent on time and concentration of iron or copper ions. Zincions protected against damage caused by iron/asorbate both to single-stranded and double-stranded DNA. In contrast, in the copper/ascorbate system zinc ions protected only against the double-stranded DNA (replicative form of M13) breakage, and not against copper-mediated single-stranded DNA breakages. It seemed to amplify the efficiency of breakage. The protection provided to the replicative form in the copper/ascorbate system is much less effective than the protection to DNA in the iron/ascorbate system. These results support the notion that redox-inactive metal ions, that compete for iron or copper binding sites, could provide protection against transition metal-mediated and free radical-induced damage.     

Spectrophotometric analysis of the protective effect of ascorbate against spontaneous oxidation of tetrahydrobiopterin in aqueous solution: kinetic characteristics and potentiation by catalase of ascorbate action

Tetrahydrobiopterin (BH(4)) is oxidized by O(2) readily in aqueous solutions and physiological concentrations of ascorbate have been shown to inhibit this reaction. In order to gain insight into the mechanism of ascorbate effect, a spectrophotometric analysis was applied for the study of the time course of BH(4) oxidation in the presence of various concentrations of ascorbate and the effect of various temperatures on the apparent second-order rate constant of BH(4) oxidation (k(ox)) in the presence or absence of catalase. In 100 micromol/l concentration, ascorbate alone prolonged the half-life time of 36 micromol/l BH(4) 1.4-fold whereas in the presence of catalase 1.85-fold. In the presence of catalase ascorbate decreased the value of k(ox) to 51 +/- 0.67%, whereas in the absence of it only to 64 +/- 0.77% of control (P < 0.01). The extent of ascorbate effect was not dependent on temperature, at least between 22 and 37 degrees C, either in the presence or absence of catalase. In the absence of catalase the apparent Arrhenius activation energies: 57.02 +/- 0.09 kJ/mol (-ascorbate) and 56.77 +/- 2.21 kJ/mol (+ascorbate) whereas in the presence of catalase: 62.72 +/- 1.37 kJ/mol (-ascorbate) and 59.93 +/- 2.84 kJ/mol (+ascorbate, mean +/- S.E.M., n=3) were obtained. The study shows that catalase potentiates the BH(4)-stabilizing effect of ascorbate. It is concluded that removal of H(2)O(2) generated from BH(4) during oxidation by O(2) prevents a decrease of ascorbate concentration, and in the presence of ascorbate the pacemaker step in the overall reaction is the oxidation of BH(4) and not the reduction of the quinonoid BH(2) back to BH(4) by ascorbate.