Generation of free radicals from lipid hydroperoxides by Ni2+ in the presence of oligopeptides.

The generation of free radicals from lipid hydroperoxides by Ni2+ in the presence of several oligopeptides was investigated by electron spin resonance (ESR) utilizing 5,5-dimethyl-1-pyrroline N-oxide (DMPO) as a spin trap. Incubation of Ni2+ with cumene hydroperoxide or t-butyl hydroperoxide did not generate any detectable free radical. In the presence of glycylglycylhistidine (GlyGlyHis), however, Ni2+ generated cumene peroxyl (ROO.) radical from cumene hydroperoxide, with the free radical generation reaching its saturation level within about 3 min. The reaction was first order with respect to both cumene hydroperoxide and Ni2+. Similar results were obtained using t-butyl hydroperoxide, but the yield of t-butyl peroxyl radical generation was about 7-fold lower. Other histidine-containing oligopeptides such as beta-alanyl-L-histidine (carnosine), gamma-aminobutyryl-L-histidine (homocarnosine), and beta-alanyl-3-methyl-L-histidine (anserine) caused the generation of both cumene alkyl (R.) and cumene alkoxyl (RO.) radicals in the reaction of Ni2+ with cumene hydroperoxide. Similar results were obtained using t-butyl hydroperoxide. Glutathione also caused generation of R. and RO. radicals in the reaction of Ni2+ with cumene hydroperoxide but the yield was approximately 25-fold greater than that produced by the histidine-containing peptides, except GlyGlyHis. The ratio of DMPO/R. and DMPO/RO. produced with glutathione and cumene hydroperoxide was approximately 3:1. Essentially the same results were obtained using t-butyl hydroperoxide except that the ratio of DMPO/R. to DMPO/RO. was approximately 1:1. The free radical generation from cumene hydroperoxide reached its saturation level almost instantaneously while in the case of t-butyl hydroperoxide, the saturation level was reached in about 3 min. In the presence of oxidized glutathione, the Ni2+/cumene hydroperoxide system caused DMPO/.OH generation from DMPO without forming free hydroxyl radical. Since glutathione, carnosine, homocarnosine, and anserine are considered to be cellular antioxidants, the present work suggests that instead of protecting against oxidative damage, these oligopeptides may facilitate the Ni(2+)-mediated free radical generation and thus may participate in the mechanism(s) of Ni2+ toxicity and carcinogenicity.     

Nickel (II) Complexes of Histidyl-Peptides as Fenton-Reaction Catalysts

Addition of histidyl-peptides containing the glycyl-glycyl-L-histidyl sequence stimulated the catalysis of Ni(II) hydrogen peroxide reduction. Maximum bleaching of murexide or nitrosodimethylaniline was obtained with glycyl-glycyl-L-histidine. A decrease in the bleaching rates was observed upon addition of SOD or hydroxyl radical scavengers, showing that the hydrogen peroxide/Ni(II)/glycyl-glycyl-L-histidine system generated superoxide anions as well as hydroxyl radicals. In contrast, addition of glycyl-glycyl-L-histidine inhibited the Cu(II) hydrogen peroxide reduction.

When peptides or proteins were exposed to oxygen radicals produced by Ni(II)/glycyl-glycyl-L-histidine catalysis of hydrogen peroxide reduction, the observed effects were similar to those produced by oxygen radicals generated by water radiolysis or by Fe(II) or Cu(II) mediated Fenton-reactions: hydroxylation of phenylalanine, interchange of disulfides, destruction of tryptophans and dityrosine formation.     

Nickel (II) Complexes of Histidyl-Peptides as Fenton-Reaction Catalysts

Addition of histidyl-peptides containing the glycyl-glycyl-L-histidyl sequence stimulated the catalysis of Ni(II) hydrogen peroxide reduction. Maximum bleaching of murexide or nitrosodimethylaniline was obtained with glycyl-glycyl-L-histidine. A decrease in the bleaching rates was observed upon addition of SOD or hydroxyl radical scavengers, showing that the hydrogen peroxide/Ni(II)/glycyl-glycyl-L-histidine system generated superoxide anions as well as hydroxyl radicals. In contrast, addition of glycyl-glycyl-L-histidine inhibited the Cu(II) hydrogen peroxide reduction.

When peptides or proteins were exposed to oxygen radicals produced by Ni(II)/glycyl-glycyl-L-histidine catalysis of hydrogen peroxide reduction, the observed effects were similar to those produced by oxygen radicals generated by water radiolysis or by Fe(II) or Cu(II) mediated Fenton-reactions: hydroxylation of phenylalanine, interchange of disulfides, destruction of tryptophans and dityrosine formation.     

Hydroxyl radical and singlet oxygen production and DNA damage induced by carcinogenic metal compounds and hydrogen peroxide

Carcinogenic chromium(VI), iron(III) nitrilotriacetate, cobalt(II), and nickel(II) react with hydrogen peroxide leading to the production of active species including hydroxyl radical and singlet oxygen, which cause DNA damage.     

Diketopiperazine-mediated peptide formation in aqueous solution

Though diketopiperazines (DKP) are formed in most experiments concerning the prebiotic peptide formation, the molecules have not been paid attention in the studies of chemical evolution. We have found that triglycine, tetraglycine or pentaglycine are formed in aqueous solution of glycine anhydride (DKP) and glycine, diglycine or triglycine, respectively. A reaction of alanine with DKP resulted in the formation of glycylglycylalanine under the same conditions. These results indicate that the formation of the peptide bonds proceeds through the nucleophilic attack of an amino group of the amino acids or the oligoglycines on the DKP accompanied by the ring-opening.The formation of glycine anhydride, di-, tri- and tetraglycine was also observed in a mixed aqueous solution of urea and glycine in an open system to allow the evaporation of ammonia. A probable pathway is proposed for prebiotic peptide formation through diketopiperazine on the primitive Earth.     

The hydroxylation of phenylalanine and tyrosine: a comparison with salicylate and tryptophan.

The hydroxylation of phenylalanine by the Fenton reaction and gamma-radiolysis yields 2-hydroxy-, 3-hydroxy-, and 4-hydroxyphenylalanine (tyrosine), while the hydroxylation of tyrosine results in 2,3- and 3,4-dihydroxyphenylalanine (dopa). Yields are determined as a function of pH and the presence or absence of oxidants. During gamma-radiolysis and the Fenton reaction the same hydroxylated products are formed. The final product distribution depends on the rate of the oxidation of the hydroxyl radical adducts (hydroxycyclohexadiene radicals) relative to the competing dimerization reactions. The pH profiles for the hydroxylations of phenylalanine and tyrosine show a maximum at pH 5.5 and a minimum around pH 8. The lack of hydroxylated products around near pH 8 is due to the rapid oxidation of dopa to melanin. The relative abilities of iron chelates (HLFe(II) and HLFe(III) to promote hydroxyl radical formation from hydrogen peroxide are nitrilotriacetate (nta) greater than ethylenediaminediacetate (edda) much greater than hydroxyethylethylenediaminetriacetate greater than citrate greater than ethylenediaminetetraacetate greater than diethylenetriaminepentaacetate greater than adenosine 5'-triphosphate greater than pyrophosphate greater than adenosine 5'-diphosphate greater than adenosine 5'-monophosphate. The high activity of iron-nta and -edda chelates is explained by postulating the formation of a ternary Fe(III)-L-dopa complex in which dopa reduces Fe(III). The hydroxylations of phenylalanine and tyrosine are similar to that of salicylate (Z. Maskos, J. D. Rush, and W. H. Koppenol, 1990, Free Radical Biol. Med. 8, 153-162) and tryptophan (preceding paper) in that oxidants augment the formation of hydroxylated products by catalyzing the dismutation of hydroxyl radical adducts to the parent compound and a stable hydroxylated product. A comparison of salicylate and the amino acids tryptophan, phenylalanine, and tyrosine clearly shows that salicylate is the best indicator of hydroxyl radical production.     

A comparison of cobalt(II) and iron(II) hydroxyl and superoxide free radical formation

We have employed the electron spin resonance spin-trapping technique to study the reaction of Co(II) with hydrogen peroxide in a chemical system and in a microsomal system. In both cases, we employed the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO) and were able to detect the formation of DMPO/.OH and DMPO/.OOH. DMPO/.OOH was the predominant radical adduct formed in the chemical system, while the two adducts were of similar concentrations in the microsomal system. The formation of both of these adducts in either reaction system was inhibited by the addition of superoxide dismutase or catalase, and by chelating the cobalt with either ethylenediaminetetraacetic acid (EDTA) or diethylenetriaminepentaacetic acid (DTPA). The incorporation of the hydroxyl radical scavengers ethanol, formate, benzoate, or mannitol inhibited the formation of DMPO/.OH in both systems. We also repeated the study using Fe(II) in place of Co(II). In contrast to the Co(II) results, Fe(II) reacted with hydrogen peroxide to yield only DMPO/.OH, and this adduct formation was relatively insensitive to the presence of added superoxide dismutase. In addition, Fe(II)-mediated DMPO/.OH formation increased when the iron was chelated to either EDTA or DTPA rather than being inhibited as for Co(II). Thus, we propose that Co(II) does not react with hydrogen peroxide by the classical Fenton reaction at physiological pH values.     

Site-specific DNA damage induced by hydrazine in the presence of manganese and copper ions. The role of hydroxyl radical and hydrogen atom.

The mechanism of DNA damage by hydrazine in the presence of metal ions was investigated by DNA sequencing technique and ESR-spin trapping method. Hydrazine caused DNA damage in the presence of Mn(III), Mn(II), Cu(II), Co(II), and Fe(III). The order of inducing effect on hydrazine-dependent DNA damage (Mn(III) greater than Mn(II) approximately Cu(II) much greater than Co(II) approximately Fe(III)) was related to that of the accelerating effect on the O2 consumption rate of hydrazine autoxidation. DNA damage by hydrazine plus Mn(II) or Mn(III) was inhibited by hydroxyl radical scavengers and superoxide dismutase, but not by catalase. On the other hand, bathocuproine and catalase completely inhibited DNA damage by hydrazine plus Cu(II), whereas hydroxyl radical scavengers and superoxide dismutase did not. Hydrazine plus Mn(II) or Mn(III) caused cleavage at every nucleotide with a little weaker cleavage at adenine residues, whereas hydrazine plus Cu(II) induced piperidine-labile sites frequently at thymine residues, especially of the GTC sequence. ESR-spin trapping experiments showed that hydroxyl radical is generated during the Mn(III)-catalyzed autoxidation of hydrazine, whereas hydrogen atom adducts of spin trapping reagents are generated during Cu(II)-catalyzed autoxidation. The results suggest that hydrazine plus Mn(II) or Mn(III) generate hydroxyl free radical not via H2O2 and that this hydroxyl free radical causes DNA damage. A possibility that the hydrogen atom releasing compound participates in hydrazine plus Cu(II)-induced DNA damage is discussed.     

In vitro reactive oxygen species production by histatins and copper(I,II)

The ability of the histidine-rich peptides, histatin-5 (Hst-5) and histatin-8 (Hst-8), to support the generation of reactive oxygen species during the Cu-catalyzed oxidation of ascorbate and cysteine has been evaluated. High levels of hydrogen peroxide (70–580 mol/mol Cu/h) are produced by aqueous solutions containing Cu(II), Hst-8 or Hst-5, and a reductant, either ascorbate or cysteine, as determined by the postreaction Amplex Red assay. When the reactions are conducted in the presence of superoxide dismutase, the total hydrogen peroxide produced is decreased, more so in the presence of the peptides (up to 50%), suggesting the intermediacy of superoxide in these reactions. On the other hand, the presence of sodium azide or sodium formate, traps for hydroxyl radicals, has no appreciable effect on the total hydrogen peroxide production for the Cu–Hst systems. EPR spin-trapping studies using 5-(2,2-dimethyl-1,3-propoxy cyclophosphoryl)-5-methyl-1-pyrroline N-oxide (CYPMPO) in the cysteine–Cu(II) reactions reveal the formation of the CYPMPO–hydroperoxyl and CYPMPO–hydroxyl radical adducts in the presence of Hst-8, whereas only the latter was observed with Cu alone.     

Kinetic studies on spin trapping of superoxide and hydroxyl radicals generated in NADPH-cytochrome P-450 reductase-paraquat systems. Effect of iron chelates

Electron spin resonance (ESR) studies on spin trapping of superoxide and hydroxyl radicals by 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) were performed in NADPH-cytochrome P-450 reductase-paraquat systems at pH 7.4. Spin adduct concentrations were determined by comparing ESR spectra of the adducts with the ESR spectrum of a stable radical solution. Kinetic analysis in the presence of 100 microM desferrioxamine B (deferoxamine) showed that: 1) the oxidation of 1 mol of NADPH produces 2 mol of superoxide ions, all of which can be trapped by DMPO when extrapolated to infinite concentration; 2) the rate constant for the reaction of superoxide with DMPO was 1.2 M-1 s-1; 3) the superoxide spin adduct of DMPO (DMPO-OOH) decays with a half-life of 66 s and the maximum level of DMPO-OOH formed can be calculated by a simple steady state equation; and 4) 2.8% or less of the DMPO-OOH decay occurs through a reaction producing hydroxyl radicals. In the presence of 100 microM EDTA, 5 microM Fe(III) ions nearly completely inhibited the formation of the hydroxyl radical adduct of DMPO (DMPO-OH) as well as the formation of DMPO-OOH and, when 100 microM hydrogen peroxide was present, produced DMPO-OH exclusively. Fe(III)-EDTA is reduced by superoxide and the competition of superoxide and hydrogen peroxide in the reaction with Fe(II)-EDTA seems to be reflected in the amounts of DMPO-OOH and DMPO-OH detected. These effects of EDTA can be explained from known kinetic data including a rate constant of 6 x 10(4) M-1 s-1 for reduction of DMPO-OOH by Fe(II)-EDTA. The effect of diethylenetriamine pentaacetic acid (DETAPAC) on the formation of DMPO-OOH and DMPO-OH was between deferoxamine and EDTA, and about the same as that of endogenous chelator (phosphate).     

Superoxide dismutase activity and novel reactions with hydrogen peroxide of histidine-containing nickel(II)-oligopeptide complexes and nickel(II)-induced structural changes in synthetic DNA

At physiologic pH values, histidine-containing nickel(II) oligopeptides reduced the flux of superoxide anion (O₂) generated in the hypoxanthine/xanthine oxidase system. The postulated involvement of the Ni(III)/Ni(II) redox couple in this apparent dismutation receives indirect support from electron-spin resonance data. These complexes also catalyzed the disproportionation of hydrogen peroxide, a process which generates active intermediates capable of hydroxylating p-nitrophenol and oxidizing uric acid to allantoin. An oxene moiety, namely [Nio]²⁺, is postulated as the active species in these H₂O₂-dependent reactions. Spectral analysis showed that monovalent, divalent and trivalent ions induced cooperative conformational changes in synthetic polydeoxynucleotides. For the nickel(II) ion, resistance to DNase-I activity clearly showed that an alternating G-C sequence is required for the observed transitions. It is concluded that the ability of nickel(II) peptide complexes to participate in active oxygen biochemistry suggests a possible role for nickel as a chemical promoter of cancer, whereas the capacity of the nickel(II) ion to induce conformational changes in DNA could, in principle, affect gene expression. Of course, the validity of both hypotheses require that the observed reactions be verified as biologically significant.     

Partial molar volumes,expansibilities, and compressibilities of oligoglycines in aqueous solutions at 18–55°C

We have determined the partial molar volumes, expansibilities, and adiabatic compressibilities of glycine, diglycine, triglycine, tetraglycine, and pentaglycine over the temperature range 18–55°C. These data were analyzed and interpreted in terms of the hydration of these short oligoglycines and their constituent groups. From our results, we have estimated the contributions of the peptide group to the partial molar volume and the partial molar adiabatic compressibility of these oligoglycines. Based on these data, we propose that each of the polar atomic groups of the peptide bond forms approximately two hydrogen bonds with adjacent water molecules. Furthermore, the temperature dependence of the partial molar volume suggests that water that solvates the polar groups of a peptide linkage behaves more like a “normal” liquid than does bulk water, which exhibits its well-known anomalous liquid properties. © 1994 John Wiley & Sons, Inc.     

Damage to the oxygen-evolving complex by superoxide anion, hydrogen peroxide, and hydroxyl radical in photoinhibition of photosystem II

Under strong illumination of a photosystem II (PSII) membrane, endogenous superoxide anion, hydrogen peroxide, and hydroxyl radical were successively produced. These compounds then cooperatively resulted in a release of manganese from the oxygen-evolving complex (OEC) and an inhibition of oxygen evolution activity. The OEC inactivation was initiated by an acceptor-side generated superoxide anion, and hydrogen peroxide was most probably responsible for the transportation of reactive oxygen species (ROS) across the PSII membrane from the acceptor-side to the donor-side. Besides ROS being generated in the acceptor-side induced manganese loss; there may also be a ROS-independent manganese loss in the OEC of PSII. Both superoxide anion and hydroxyl radical located inside the PSII membrane were directly identified by a spin trapping-electron spin resonance (ESR) method in combination with a lipophilic spin trap, 5-(diethoxyphosphoryl)-5-phenethyl-1-pyrroline N-oxide (DEPPEPO). The endogenous hydrogen peroxide production was examined by oxidation of thiobenzamide.     

Hydroxyl radical is not a product of the reaction of xanthine oxidase and xanthine. The confounding problem of adventitious iron bound to xanthine oxidase

The reaction of xanthine and xanthine oxidase generates superoxide and hydrogen peroxide. In contrast to earlier works, recent spin trapping data (Kuppusamy, P., and Zweier, J.L. (1989) J. Biol. Chem. 264, 9880-9884) suggested that hydroxyl radical may also be a product of this reaction. Determining if hydroxyl radical results directly from the xanthine/xanthine oxidase reaction is important for 1) interpreting experimental data in which this reaction is used as a model of oxidant stress, and 2) understanding the pathogenesis of ischemia/reperfusion injury. Consequently, we evaluated the conditions required for hydroxyl radical generation during the oxidation of xanthine by xanthine oxidase. Following the addition of some, but not all, commercial preparations of xanthine oxidase to a mixture of xanthine, deferoxamine, and either 5,5-dimethyl-1-pyrroline-N-oxide or a combination of alpha-phenyl-N-tert-butyl-nitrone and dimethyl sulfoxide, hydroxyl radical-derived spin adducts were detected. With other preparations, no evidence of hydroxyl radical formation was noted. Xanthine oxidase preparations that generated hydroxyl radical had greater iron associated with them, suggesting that adventitious iron was a possible contributing factor. Consistent with this hypothesis, addition of H2O2, in the absence of xanthine, to "high iron" xanthine oxidase preparations generated hydroxyl radical. Substitution of a different iron chelator, diethylenetriaminepentaacetic acid for deferoxamine, or preincubation of high iron xanthine oxidase preparations with chelating resin, or overnight dialysis of the enzyme against deferoxamine decreased or eliminated hydroxyl radical generation without altering the rate of superoxide production. Therefore, hydroxyl radical does not appear to be a product of the oxidation of xanthine by xanthine oxidase. However, commercial xanthine oxidase preparations may contain adventitious iron bound to the enzyme, which can catalyze hydroxyl radical formation from hydrogen peroxide.     

Photosensitization by antitumor agents 3: spectroscopic evidence for superoxide and hydroxyl radical production by anthrapyrazole-sensitized oxidation of nadh

EPR and spin-trapping techniques were employed to study the oxidation of the dihydronicotinamide adenine dinucleotide (NADH) photosensitized by an anthrapyrazole-antitumor agent. The superoxide radical was detected as a DMPO adduct upon illumination of the system with visible light. Photoinduced generation of hydroxyl radicals is demonstrated by detection of DMPO adducts of OH scavengers, such as ethyl alcohol, sodium formate, and sodium azide. The dependence of the production of these spin adducts on the presence of catalase implies the involvement of hydrogen peroxide in that process. The production of hydrogen peroxide is demonstrated independently during oxygen consumption measurements with the Clark electrode technique.     

Abatement of Sorbed Crude Oil by Heterogeneous Fenton Process Using A Contaminated Soil Pre-Impregnated with Dissolved Fe(II) and Humic Acid

Dissolved Fe(II) and humic acid (HA) were pre-impregnated into contaminated soil to catalyze hydrogen peroxide to remove crude oil (CO). The effects of parameters such as initial Fe(II), HA and H₂O₂ concentrations on the oxidation of total petroleum hydrocarbon (TPH) were investigated using response surface methodology based on Box–Behnken design. The rate of hydrogen peroxide decomposition is decreased by pre-impregnating with dissolved Fe(II) + HA compared with only pre-impregnated Fe(II) and modified Fenton (MF). Oxygen evolution is the predominant route of hydrogen peroxide decomposition at natural pH. Unlike O₂ evolution, the kinetics of hydroxyl radical (OH^?) production are clearly uncoupled from H₂O₂ decay in these systems. The steady-state hydroxyl radical production rate is higher in the systems with pre-impregnated dissolved Fe(II) and HA, and more significance is the decrease in detectable TPH (70.84% removal efficiency) when soil is pre-impregnated with dissolved 25 mM Fe(II) + 0.7 mg/mL HA, and with the application of 700 mM H₂O₂, possibly due to hydrogen peroxide catalyzed by the iron of this complex (CO-HA–Fe(II)) producing hydroxyl radical in close proximity to the CO. Meanwhile, the removal efficiency of C₂₁–C₃₀ is up to 65.69%, which is 2.6 times higher than that of the MF (25.52%).     

The Effect of Myoglobin on the Stability of the Hydroxyl-Radical Adducts of 5, 5 Dimethyl-1-Pyrolline-N-Oxide (DMPO), 3, 3,5, 5 Tetramethyl-1-pyrolline-N-Oxide(TMPO) and 1-Alpha-Phenyl-Tert-Butyl Nitrone (PBN) in the Presence of Hydrogen Peroxide

The hydroxyl radical adducts of 5, 5 dimethyl-1-pyrolline-N-oxide (DMPO) and 3, 3,5, 5 tetramethyl-1-pyrolline-N-oxide (TMPO) formed in the presence of hydrogen peroxide and Fe are normally quite stable, but in the presence of 5-20 micromolar myoglobin their ESR signals decay rapidly. This decay probably reflects further oxidation of the adduct to nonparamgnetic products.

The ESR signal of the hydroxyl radical adduct of 1-alpha-phenyl-tert-butyl nitrone (PBN) formed under similar conditions is subject to non-heme dependent attenuation, possibly via hydroxyl radical scavenging, but not to heme dependent decay. Hydrogen peroxide readily converts myoglobin to its ferryl (Fe^IV) derivative, and this centre may be responsible for the oxidation of the DMPO and TMPO adducts. The different behaviour of PBN may be due to differences in susceptibility to ferrylmyoglobin mediated oxidation, or to steric differences controlling access to the heme pocket of myoglobin, and is relevant to the choice of spin trap for biological experiments aimed at detecting hydroxyl radicals in the presence of myoglobin or other heme proteins.     

Role of iron in adriamycin biochemistry

Adriamycin forms a chelate with Fe(III) that exhibits complex redox chemistry. The drug ligand is able to directly reduce the bound Fe(III) with the concomitant production of a one-electron oxidized drug radical. This Fe(II) can reduce oxygen to hydrogen peroxide and cleave the peroxide to yield the hydroxyl radical. In addition, the drug X Fe complex can catalyze the transfer of electrons from reduced glutathione to molecular oxygen to yield superoxide, hydrogen peroxide, and hydroxyl radicals. The adriamycin X Fe complex binds to DNA to form a ternary drug X Fe X DNA complex, which is also able to catalyze the thiol-dependent reduction of oxygen and the formation of hydroxyl radical from hydrogen peroxide. As a consequence of this chemistry, the adriamycin X Fe complex can cleave DNA on the addition of glutathione or hydrogen peroxide. Although less well defined, the adriamycin X Fe complex can bind to cell membranes and cause oxidative destruction of these membranes in the presence of thiols or hydrogen peroxide.     

Hydroxyl radical production by stimulated neutrophils reappraised

Release of active oxygen species during the human neutrophil respiratory burst is thought to be mandatory for effective defense against bacterial infections and may play an important role in damage to host tissues. Part of the critical bacterial and host tissue damage has been attributed to hydroxyl radicals produced from superoxide and hydrogen peroxide. Because of the short life time of the very reactive hydroxyl radical, direct study of hydroxyl radical production is not possible; therefore, indirect detection methods such as electron spin resonance (ESR) coupled with appropriate spin-trapping agents such as 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) have been used. Superoxide production during the oxidative burst has been unambiguously demonstrated. Recent reports claim that hydroxyl radicals are not made during neutrophil stimulation and offer as an explanation the presence of granular components that interfere with hydroxyl radical production. When using the spin-trap agent DMPO, absence of the relatively long-lived adducts DMPO-OH and DMPO-CH3 has been assumed to be prima facie evidence for lack of hydroxyl radical participation. We show that high superoxide flux produced during stimulation of human neutrophils rapidly destroys both DMPO-OH and DMPO-CH3. In accord with previous implications, our results provide an alternative explanation for the absence of .OH adduct in spin-trapping studies and corroborate results obtained using other methods that implicate hydroxyl radical production during neutrophil stimulation.     

Possible involvement of hydroxyl radical on the stimulation of tetrahydrobiopterin synthesis by hydrogen peroxide and peroxynitrite in vascular endothelial cells

We recently described that hydrogen peroxide (H2O2) stimulates the synthesis of tetrahydrobiopterin (BH4) through the induction of the rate-limiting enzyme GTP-cyclohydrolase I (GTPCH), and increases tetrahydrobiopterin content in vascular endothelial cells. Tetrahydrobiopterin is easily oxidized by peroxynitrite (ONOO-), but not by hydrogen peroxide. The aim of this study was to determine the effect of hydroxyl radical and peroxynitrite, which are both toxic biological oxidants, on tetrahydrobiopterin synthesis and the regulation of its content in vascular endothelial cells. In the cell-free assay system, tetrahydrobiopterin was rapidly oxidized by the hydroxyl radical and peroxynitrite, but not by hydrogen peroxide. However, the addition of not only hydrogen peroxide but also the hydroxyl radical and peroxynitrite to vascular endothelial cells transiently decreased tetrahydrobiopterin content, and then markedly increased its content. Interestingly, total biopterin content was also decreased by early treatment with oxidants. Moreover, oxidants induced the expression of GTP-cyclohydrolase I, and the increase of the tetrahydrobiopterin content was blocked by the treatment with GTP-cyclohydrolase I inhibitor. Both the hydrogen peroxide- and peroxynitrite-induced increases in tetrahydrobiopterin content and findings suggest that not only hydrogen peroxide but also the hydroxyl radical and peroxynitrite stimulates tetrahydrobiopterin synthesis through GTP-cyclohydrolase I expression, and that the hydroxyl radical plays a central role in the stimulation of tetrahydrobiopterin synthesis. Moreover, the transient decrease in BH4 to tetrahydrobiopterin.