Phenylbutazone radicals inactivate creatine kinase

Creatine kinase (CK) was used as a marker molecule to examine the side effect of damage to tissues by phenylbutazone (PB), an effective drug to treat rheumatic and arthritic diseases, with horseradish peroxidase and hydrogen peroxide (HRP-H₂O₂). PB inactivated CK during its interaction with HRP-H₂O₂, and inactivated CK in rat heart homogenate. PB carbon-centered radicals were formed during the interaction of PB with HRP-H₂O₂. The CK efficiently reduced electron spin responance signals of the PB carbon-centered radicals. The spin trap agent 2-methyl-2-nitrosopropane strongly prevented CK inactivation. These results show that CK was inactivated through interaction with PB carbon-centered radicals. Sulfhydryl groups and tryptophan residues in CK were lost during the interaction of PB with HRP-H₂O₂, suggesting that cysteine and tryptophan residues are oxidized by PB carbon-centered radicals. Other enzymes, including alcohol dehydrogenase, glyceraldehyde-3-phosphate dehydrogenase, but not lactate dehydrogenase, were also inactivated. Sulfhydryl enzymes seem to be sensitive to attack by PB carbon-centered radicals. Inhibition of SH enzymes may explain some of the deleterious effects induced by PB.     

Inactivation of creatine kinase during the interaction of mefenamic acid with horseradish peroxidase and hydrogen peroxide: participation by the mefenamic acid radical

Creatine kinase (CK) was used as a marker molecule to examine the side effects of damage to tissues by mefenamic acid, an effective drug to treat rheumatic and arthritic diseases, with horseradish peroxidase and hydrogen peroxide (HRP-H(2)O(2)). Mefenamic acid inactivated CK during its interaction with HRP-H(2)O(2). Also, diphenylamine and flufenamic acid caused a loss of CK activity, indicating the imino group, not substituent groups, in the phenyl rings have a crucial role in CK inactivation. Rapid change in mefenamic acid spectra was detected, suggesting that mefenamic acid is efficiently oxidized by HRP-H(2)O(2). Peroxidases oxidize xenobiotics to free radicals by a one-electron transfer. However, direct detection of mefenamic acid radicals by electron spin resonance (ESR) was unsuccessful. Reduced glutathione and 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) in the reaction mixture containing mefenamic acid with HRP-H(2)O(2) produced ESR signals consistent with a DMPO-glutathionyl radical adduct. These results suggest that inactivation of CK is probably caused through formation of mefenamic acid radicals. Sulfhydryl groups and tryptophan residues of CK were diminished by mefenamic acid with HRP-H(2)O(2). Other SH enzymes, including alcohol dehydrogenase and glyceraldehyde-3-phosphate dehydrogenase, were very sensitive to mefenamic acid with HRP-H(2)O(2). Inactivation of SH enzymes may explain some deleterious actions of mefenamic acid.     

Inactivation of mitochondrial succinate dehydrogenase by adriamycin activated by horseradish peroxidase and hydrogen peroxide

Although human cancers are widely treated with anthracycline drugs, these drugs have limited use because they are cardiotoxic. To clarify the cardiotoxic action of the anthracycline drug adriamycin (ADM), the inhibitory effect on succinate dehydrogenase (SDH) by ADM and other anthracyclines was examined by using pig heart submitochondrial particles. ADM rapidly inactivated mitochondrial SDH during its interaction with horseradish peroxidase (HRP) in the presence of H(2)O(2) (HRP-H(2)O(2)). Butylated hydroxytoluene, iron-chelators, superoxide dismutase, mannitol and dimethylsulfoxide did not block the inactivation of SDH, indicating that lipid-derived radicals, iron-oxygen complexes, superoxide and hydroxyl radicals do not participate in SDH inactivation. Reduced glutathione was extremely efficient in blocking the enzyme inactivation, suggesting that the SH group in enzyme is very sensible to ADM activated by HRP-H(2)O(2). Under anaerobic conditions, ADM with HRP-H(2)O(2) caused inactivation of SDH, indicating that oxidized ADM directly attack the enzyme, which loses its activity. Other mitochondrial enzymes, including NADH dehydrogenase, NADH oxidase and cytochrome c oxidase, were little sensitive to ADM with HRP-H(2)O(2). SDH was also sensitive to other anthracycline drugs except for aclarubicin. Mitochondrial creatine kinase (CK), which is attached to the outer face of the inner membrane of muscle mitochondria, was more sensitive to anthracyclines than SDH. SDH and CK were inactivated with loss of red color of anthracycline, indicating that oxidative activation of the B ring of anthracycline has a crucial role in inactivation of enzymes. Presumably, oxidative semiquinone or quinone produced from anthracyclines participates in the enzyme inactivation.     

Inactivation of alcohol dehydrogenase by piroxicam-derived radicals

Alcohol dehydrogenase (ADH) was used as a marker molecule to clarify the mechanism of gastric mucosal damage as a side effect of using piroxicam. Piroxicam inactivated ADH during interaction of ADH with horseradish peroxidase and H₂O₂ (HRP-H₂O₂). The ADH was more easily inactivated under aerobic than anaerobic conditions, indicating participation by oxygen. Superoxide dismutase, but not hydroxyl radical scavengers, inhibited inactivation of ADH, indicating participation by superoxide. Sulfhydryl (SH) groups in ADH were lost during incubation of piroxicam with HRP-H₂O₂. Adding reduced glutathione (GSH) efficiently blocked ADH inactivation. Other SH enzymes, including creatine kinase and glyceraldehyde-3-phosphate dehydrogenase, were also inactivated by piroxicam with HRP-H₂O₂. Thus SH groups in the enzymes seem vulnerable to piroxicam activated by HRP-H₂O₂. Spectral change in piroxicam was caused by HRP-H₂O₂. ESR signals of glutathionyl radicals occurred during incubation of piroxicam with HRP-H₂O₂ in the presence of GSH. Under anaerobic conditions, glutathionyl radical formation increased. Thus piroxicam free radicals interact with GSH to produce glutathionyl radicals. Piroxicam peroxyl radicals or superoxide, or both, seem to inactivate ADH. Superoxide may be produced through interaction of peroxyl radicals with H₂O₂. Thus superoxide dismutase may inhibit inactivation of ADH through reducing piroxicam peroxyl radicals or blocking interaction of SH groups with O₂^-, or both. Other oxicam derivatives, including isoxicam, tenoxicam and meloxicam, induced ADH inactivation in the presence of HRP-H₂O₂.     

Salicylic acid-induced inactivation of creatine kinase in the presence of lactoperoxidase and H2O2

To clarify one mechanism of aspirin-induced gastric mucosal damage, inactivation of creatine kinase (CK) by salicylic acid that is easily produced from aspirin in vivo was examined in the presence of lactoperoxidase (LPO) and H2O2 (LPO-H2O2). Salicylic acid inactivated CK (rabbit muscle) during its interaction with LPO-H2O2. CK activity in gastric mucosal homogenate decreased dependent on the concentration of salicylic acid in the presence of LPO-H2O2. Oxygen radical scavengers did not prevent the inactivation of CK. Direct detection of free radicals of salicylic acid by electron spin resonance was unsuccessful. However, glutathionyl radicals were formed during the interaction of salicylic acid with LPO-H2O2 in the presence of reduced glutathione and 5,5-dimethyl-1-pyrroline oxide as a spin trap agent. Among salicylic acid-related drugs, salsalate, but not aspirin and ethenzamide, inactivated CK, indicating the phenolic hydroxyl group is oxidized by LPO-H2O2. During oxidation of salicylic acid by LPO-H2O2, the sulfhydryl group in CK markedly decreased, and salicylic acid bound to CK. These results indicate that CK was inactivated through loss of the sulfhydryl group and binding of salicylic acid.     

Lipid peroxidation induced by phenylbutazone radicals

Lipid peroxidation was investigated to evaluate the deleterious effect on tissues by phenylbutazone (PB). PB induced lipid peroxidation of microsomes in the presence of horseradish peroxidase and hydrogen peroxide (HRP-H2O2). The lipid peroxidation was completely inhibited by catalase but not by superoxide dismutase. Mannitol and dimethylsulfoxide had no effect. These results indicated no paticipation of superoxide and hydroxyl radical in the lipid peroxidation. Reduced glutathione (GSH) efficiently inhibited the lipid peroxidation. PB radicals emitted electron spin resonance (ESR) signals during the reaction of PB with HRP-H2O2. Microsomes and arachidonic acid strongly diminished the ESR signals, indicating that PB radicals directly react with unsaturated lipids of microsomes to cause thiobarbituric acid reactive substances. GSH sharply diminished the ESR signals of PB radicals, suggesting that GSH scavenges PB radicals to inhibit lipid peroxidation. Also, 2-methyl-2-nitrosopropan strongly inhibited lipid peroxidation. R-Phycoerythrin, a peroxyl radical detector substance, was decomposed by PB with HRP-H2O2. These results suggest that lipid peroxidation of microsomes is induced by PB radicals or peroxyl radicals, or both.     

Inactivation of glycerol dehydrogenase of Klebsiella pneumoniae and the role of divalent cations.

Anaerobically induced NAD-linked glycerol dehydrogenase of Klebsiella pneumoniae for fermentative glycerol utilization was reported previously to be inactivated in the cell during oxidative metabolism. In vitro inactivation was observed in this study by incubating the purified enzyme in the presence of O2, Fe2+, and ascorbate or dihydroxyfumarate. It appears that O2 and the reducing agent formed H2O2 and that H2O2 reacted with Fe2+ to generate an activated species of oxygen which attacked the enzyme. The in vitro-oxidized enzyme, like the in vivo-inactivated enzyme, showed an increased Km for NAD (but not glycerol) and could no longer be activated by Mn2+ which increased the Vmax of the native enzyme but decreased its apparent affinity for NAD. Ethanol dehydrogenase and 1,3-propanediol oxidoreductase, two enzymes with anaerobic function, also lost activity when the cells were incubated aerobically with glucose. However, glucose 6-phosphate dehydrogenase (NADP-linked), isocitrate dehydrogenase, and malate dehydrogenase, expected to function both aerobically and anaerobically, were not inactivated. Thus, oxidative modification of proteins in vivo might provide a mechanism for regulating the activities of some anaerobic enzymes.     

Thiol oxidation induced by oxidative action of adriamycin

To clarify the mechanism of the cardiotoxic action of adriamycin (ADM), the participation of free radicals from ADM in cardiotoxicity was investigated through the protective action of glutathione (GSH) or by using electron spin resonance (ESR). Oxidation of ADM by horseradish peroxidase and H₂O₂ (HRP-H₂O₂) was blocked by GSH concentration dependently. Inactivation of creatine kinase (CK) induced during interaction of ADM with HRP-H₂O₂ was also protected by GSH. Other anthracycline antitumor drugs that have a p-hydroquinone structure in the B ring also inactivated CK, and GSH inhibited the inactivation of CK. These results suggest that ADM was activated through oxidation of the p-hydroquinone in the B ring by HRP-H₂O₂. Although ESR signals of the oxidative ADM B ring semiquinone were not detected, glutathionyl radicals were formed during the interaction of ADM with HRP-H₂O₂ in the presence of GSH. ADM may be oxidized to the ADM B ring semiquinone and then reacts with the SH group. However, ESR signals of ADM C ring semiquinone, which was reductively formed by xanthine oxidase (XO) and hypoxanthine (HX) under anaerobic conditions, were not diminished by GSH, but they completely disappeared with ferric ion. These results indicate that oxidative ADM B ring semiquinones oxidized the SH group in CK, but reductive ADM C ring semiquinone radicals may participate in the oxidation of lipids or DNA and not of the SH group.     

Leukotriene B4, C4, D4 and E4 inactivation by hydroxyl radicals

Leukotriene B4 chemotactic activity and leukotriene C4, D4 and E4 slow reacting substance activity were rapidly decreased by hydroxyl radicals generated by two different iron-supplemented acetaldehyde-xanthine oxidase systems. At low Fe2+, leukotriene inactivation was inhibited by catalase, superoxide dismutase, mannitol and ethanol, suggesting involvement of hydroxyl radicals generated by the iron-catalyzed interaction of superoxide and H2O2 (Haber-Weiss reaction). Leukotriene inactivation increased at high Fe2+ concentrations, but was no longer inhibitable by superoxide dismutase, suggesting that inactivation resulted from a direct interaction between H2O2 and Fe2+ to form hydroxyl radicals (Fenton reaction). The inactivation of leukotrienes by hydroxyl radicals suggests that oxygen metabolites generated by phagocytes may play a role in modulating leukotriene activity.     

Thiol Oxidation Induced by Oxidative Action of Adriamycin

To clarify the mechanism of the cardiotoxic action of adriamycin (ADM), the participation of free radicals from ADM in cardiotoxicity was investigated through the protective action of glutathione (GSH) or by using electron spin resonance (ESR). Oxidation of ADM by horseradish peroxidase and H₂O₂ (HRP-H₂O₂) was blocked by GSH concentration dependently. Inactivation of creatine kinase (CK) induced during interaction of ADM with HRP-H₂O₂ was also protected by GSH. Other anthracycline antitumor drugs that have a p-hydroquinone structure in the B ring also inactivated CK, and GSH inhibited the inactivation of CK. These results suggest that ADM was activated through oxidation of the p-hydroquinone in the B ring by HRP-H₂O₂. Although ESR signals of the oxidative ADM B ring semiquinone were not detected, glutathionyl radicals were formed during the interaction of ADM with HRP-H₂O₂ in the presence of GSH. ADM may be oxidized to the ADM B ring semiquinone and then reacts with the SH group. However, ESR signals of ADM C ring semiquinone, which was reductively formed by xanthine oxidase (XO) and hypoxanthine (HX) under anaerobic conditions, were not diminished by GSH, but they completely disappeared with ferric ion. These results indicate that oxidative ADM B ring semiquinones oxidized the SH group in CK, but reductive ADM C ring semiquinone radicals may participate in the oxidation of lipids or DNA and not of the SH group.     

Inactivation of the 2-oxo acid dehydrogenase complexes upon generation of intrinsic radical species.

Self-regulation of the 2-oxo acid dehydrogenase complexes during catalysis was studied. Radical species as side products of catalysis were detected by spin trapping, lucigenin fluorescence and ferricytochrome c reduction. Studies of the complexes after converting the bound lipoate or FAD cofactors to nonfunctional derivatives indicated that radicals are generated via FAD. In the presence of oxygen, the 2-oxo acid, CoA-dependent production of the superoxide anion radical was detected. In the absence of oxygen, a protein-bound radical concluded to be the thiyl radical of the complex-bound dihydrolipoate was trapped by alpha-phenyl-N-tert-butylnitrone. Another, carbon-centered, radical was trapped in anaerobic reaction of the complex with 2-oxoglutarate and CoA by 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO). Generation of radical species was accompanied by the enzyme inactivation. A superoxide scavenger, superoxide dismutase, did not protect the enzyme. However, a thiyl radical scavenger, thioredoxin, prevented the inactivation. It was concluded that the thiyl radical of the complex-bound dihydrolipoate induces the inactivation by 1e- oxidation of the 2-oxo acid dehydrogenase catalytic intermediate. A product of this oxidation, the DMPO-trapped radical fragment of the 2-oxo acid substrate, inactivates the first component of the complex. The inactivation prevents transformation of the 2-oxo acids in the absence of terminal substrate, NAD+. The self-regulation is modulated by thioredoxin which alleviates the adverse effect of the dihydrolipoate intermediate, thus stimulating production of reactive oxygen species by the complexes. The data point to a dual pro-oxidant action of the complex-bound dihydrolipoate, propagated through the first and third component enzymes and controlled by thioredoxin and the (NAD+ + NADH) pool.     

Protection by estrogens of biological damage by 2,2'-azobis(2-amidinopropane) dihydrochloride

We examined by using 2,2′-azobis(2-amidinopropane) dihydrochloride (AAPH) as a radical generator the ability of estrogens to scavenge carbon-centered and peroxyl radicals. Electron spin resonance signals of carbon-centered radicals from AAPH were diminished by catecholestrogens but not by phenolic estrogens, showing that catecholestrogens efficiently scavenged carbon-centered radicals. However, fluorescent decomposition of R-phycoerythrin by AAPH-derived peroxyl radicals was inhibited by catecholestrogens and phenolic estrogens. Evidently, peroxyl radicals were scavenged by catecholestrogens and by phenolic estrogens. However, the scavenging ability of 4-hydroxyestradiol was less than 2-hydroxyestradiol. Strand break of DNA induced by AAPH was inhibited by catecholestrogens, but not by phenolic estrogens under aerobic and anaerobic conditions. Inactivation of lysozyme induced by AAPH was completely blocked by 2-hydroxyestradiol under aerobic and anaerobic conditions, and by 4-hyroxyestradiol only under anaerobic conditions. Peroxidation of arachidonic acid by AAPH was strongly inhibited by catecholestrogens at low concentrations. Only large amounts of phenolic estrogens markedly inhibited lipid peroxidation. These results show that catecholestrogens were antioxidant against AAPH-induced damage to biological molecules through scavenging both carbon-centered and peroxyl radicals, but phenolic estrogens partially inhibited AAPH-induced damage because they scavenged only peroxyl radicals.     

Inactivation of 3 alpha-hydroxysteroid dehydrogenase by superoxide radicals. Modification of histidine and cysteine residues causes the conformational change.

3 alpha-Hydroxysteroid dehydrogenase (EC 1.1.1.50) from Pseudomonas testosterone was inactivated by superoxide radicals generated by the aerobic xanthine oxidase reaction. Superoxide dismutase, NAD+, bovine serum albumin and histidine and cysteine as free amino acids partially protected the enzyme from inactivation. NADH-binding properties were determined by fluorescence spectroscopy, and no variation was found between native enzyme and the unmodified fraction of the partly inactivated one. The fluorescence emission maximum for the completely inactivated enzyme was shifted 10 nm to a longer wavelength when compared with the native one, and it seems possible that the modification of histidine and cysteine residues by superoxide radicals causes the conformational change of the enzyme and the consequent loss of catalytic activity.     

The inactivation of enzymes by ultrasonic cavitation at 20 kHz

Alcohol dehydrogenase, lysozyme, and catalase were assayed after exposure to cavitating 20 kHz ultrasound for varying times. Catalase was little affected, but alcohol dehydrogenase and lysozyme were both inactivated at an exponential rate. The rate of enzyme inactivation decreased with increasing protein concentration and was inhibited by the presence of 2-mercaptoethanol. The presence of stainless steel in the sonication vessel accelerated enzyme inactivation. On the basis of the results obtained, it is suggested that the mechanism of inactivation is chemical rather than mechanical, and a comparison is made between the rate of inactivation and the yield of free radicals as measured with a radiochemical dosimeter. Suggestions are offered to minimize the sonochemical effects on proteins isolated from cells with an ultrasonic disintegrator.     

Phenothiazine radicals inactivate Trypanosoma cruzi dihydrolipoamide dehydrogenase: enzyme protection by radical scavengers

Phenothiazine cation radicals (PTZ + •) irreversibly inactivated Trypanosoma cruzi dihydrolipoamide dehydrogenase (LADH). These radicals were obtained by phenothiazine (PTZ) peroxidation with myeloperoxidase (MPO) or horseradish peroxidase (HRP/H 2 O 2 ) systems. LADH inactivation depended on PTZ structure and incubation time. After 10 min incubation of LADH with the MPO-dependent systems, promazine, trimeprazine and thioridazine were the most effective; after 30 min incubation, chlorpromazine, prochlorperazine and promethazine were similarly effective. HRP-dependent systems were equally or more effective than the corresponding MPO-dependent ones. Chloro, trifluoro, propionyl and nitrile groups at position 2 of the PTZ ring significantly decreased molecular activity, specially with the MPO/H 2 O 2 systems. Comparison of inactivation values for LADH and T. cruzi trypanothione reductase demonstrated a greater sensitivity of LADH to chlorpromazine and perphenazine and a 10-fold lower sensitivity to promazine, thioridazine and trimeprazine. Alkyl-amino, alkyl-piperidinyl or alkyl-piperazinyl groups at position 10 modulated PTZ activity to a limited degree. Production of PTZ + • radicals was demonstrated by optical and ESR spectroscopy methods. PTZ + • radicals stability depended on their structure as demonstrated by promazine and thioridazine radicals. Thiol compounds such as GSH and N -acetylcysteine, l -tyrosine, l -tryptophan, the corresponding peptides, ascorbate and Trolox, prevented LADH inactivation by the MPO/H 2 O 2 /thioridazine system, in close agreement with their action as PTZ + • scavengers. NADH (not NAD + ) produced transient protection of LADH against thioridazine and promazine radicals, the protection kinetics being affected by the relatively fast rate of NADH oxidation by these radicals. The role of the observed effects of PTZ radicals for PTZ cytotoxicity is discussed.     

Characteristics of chemiluminescence observed in the horseradish peroxidase-hydrogen peroxide-tyrosine system.

Electrolysis or horseradish peroxidase (HRP)-catalyzed oxidation of tyrosine and bityrosine in aqueous solution at pH 7.4 resulted in light emission in the visible region. Electrolysis of tyrosine emitted light which peaked at 490 nm and was almost completely quenched by superoxide dismutase (SOD), while emission by bityrosine peaked at 530 nm. In the HRP-H(2)O(2)-tyrosine system the oxidation-reduction of tyrosine emitted light with two prominent peaks, 490 and 530 nm, and was not quenched by SOD. The phenoxyl neutral radical of the tyrosine in HRP-H(2)O(2)-tyrosine system was detected by electron spin resonance (ESR) spectrometry using tert-nitrosobutane as a spin trap; the spin adduct was found to adhere to the HRP molecule during the enzymatic reaction. Further, bityrosine was detected in the HRP-H(2)O(2)-tyrosine reaction system. Changes in absorption spectra of HRP and chemiluminescence intensities during HRP-catalyzed oxidation of tyrosine suggest that for photon emission compound III is a candidate superoxide donor to the phenoxyl cation radical of tyrosine on the enzyme molecule. The luminescence observed in this study might be originated from at least two exciplexes involved with the tyrosine cation radical (Tyr(*+)) and the bityrosine cation radical (BT(*+))     

Hydroxyl radical production by H2O2 plus Cu,Zn-superoxide dismutase reflects the activity of free copper released from the oxidatively damaged enzyme.

To elaborate the catalytic activity of Cu2+ of Cu,Zn-superoxide dismutase (SOD) in the generation of hydroxyl radical (.OH) from H2O2, we investigated the mechanism of inactivation of alpha 1-protease inhibitor (alpha 1-PI), mediated by H2O2 and Cu,Zn-SOD. When alpha 1-PI was incubated with 500 units/ml Cu,Zn-SOD and 1.0 mM H2O2, 60% of anti-elastase activity of alpha 1-PI was lost within 90 min. ESR spin trapping using 5,5-dimethyl-1-pyrroline N-oxide showed that free .OH was indeed generated in the reaction of Cu,Zn-SOD/H2O2; this was substantiated by the almost complete eradication of .OH by either ethanol or dimethyl sulfoxide accompanied by the generation of carbon-centered radicals. .OH production and alpha 1-PI inactivation in the H2O2/SOD system became apparent at 30 min or later. Dimethyl sulfoxide and 5,5-dimethyl-1-pyrroline N-oxide protected inactivation of alpha 1-PI significantly in this system, indicating that alpha 1-PI inactivation was mediated by .OH. SOD activity decreased rapidly during the reaction with H2O2 for the initial 30 min. Time-dependent changes in the ESR signal of SOD showed the destruction of ligands for Cu2+ in SOD by H2O2 within this initial period. Thus we conclude that inactivation of alpha 1-PI is mediated in the H2O2/Cu,Zn-SOD system via the generation of .OH by free Cu2+ released from oxidatively damaged SOD.     

Active-site modification of native and mutant forms of inosine 5′-monophosphate dehydrogenase from Escherichia coli K12

IMP dehydrogenase of Escherichia coli was irreversibly inactivated by Cl-IMP (6-chloro-9-beta-d-ribofuranosylpurine 5'-phosphate, 6-chloropurine ribotide). The inactivation reaction showed saturation kinetics. 6-Chloropurine riboside did not inactivate the enzyme. Inactivation by Cl-IMP was retarded by ligands that bind at the IMP-binding site. Their effectiveness was IMP>XMP>GMP>AMP. NAD(+) did not protect the enzyme from modification. Inactivation of IMP dehydrogenase was accompanied by a change in lambda(max.) of Cl-IMP from 263 to 290nm, indicating formation of a 6-alkylmercaptopurine nucleotide. The spectrum of 6-chloropurine riboside was not changed by IMP dehydrogenase. With excess Cl-IMP the increase in A(290) with time was first-order. Thus it appears that Cl-IMP reacts with only one species of thiol at the IMP-binding site of the enzyme: 2-3mol of Cl-IMP were bound per mol of IMP dehydrogenase tetramer. Of ten mutant enzymes from guaB strains, six reacted with Cl-IMP at a rate similar to that for the native enzyme. The interaction was retarded by IMP. None of the mutant enzymes reacted with 6-chloropurine riboside. 5,5'-Dithiobis-(2-nitrobenzoic acid), iodoacetate, iodoacetamide and methyl methanethiosulphonate also inactivated IMP dehydrogenase. Reduced glutathione re-activated the methanethiolated enzyme, and 2-mercaptoethanol re-activated the enzyme modified by Cl-IMP. IMP did not affect the rate of re-activation of methanethiolated enzyme. Protective modification indicates that Cl-IMP, methyl methanethiosulphonate and iodoacetamide react with the same thiol groups in the enzyme. This is also suggested by the low incorporation of iodo[(14)C]acetamide into Cl-IMP-modified enzyme. Hydrolysis of enzyme inactivated by iodo[(14)C]acetamide revealed radioactivity only in S-carboxymethylcysteine. The use of Cl-IMP as a probe for the IMP-binding site of enzymes from guaB mutants is discussed, together with the possible function of the essential thiol groups.     

Inactivation of creatine kinase induced by dopa and dopamine in the presence of ferrylmyoglobin

We investigated the effect of dopa and dopamine on creatine kinase (CK) activity in the presence of ferrylmyoglobin (ferrylMb). CK was sharply inhibited by dopa and dopamine in the presence of ferrylMb. Dopa and dopamine markedly promoted the reduction of ferrylMb to metmyoglobin (metMb). The semiquinone from dopa and dopamine may be involved in CK inactivation. During inactivation of the enzyme, both kinetic parameters Vmax and Km changed. In addition, reduced glutathione restored the activity of CK at an early stage. These results suggest that inactivation of CK is dominantly due to oxidation of sulfhydryl (SH) groups of the enzyme. Other catechols, such as adrenaline and noradrenaline, little inactivated CK activity, whereas they promoted the reduction of ferrylMb to metMb. Other SH enzymes, including alcohol dehydrogenase (ADH) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH), were inactivated to a lesser extent by dopa and dopamine in the presence of ferrylMb. Adrenaline and noradrenaline did not significantly prevent the inactivation of ADH and very slightly inhibited GAPDH. These results suggest that dopa and dopamine act as prooxidants to inactivate SH enzymes in the presence of ferrylMb.     

Inactivation of cholinesterase induced by non-steroidal anti-inflammatory drugs with horseradish peroxidase: Implication for Alzheimer's disease

AimsTo clarify the mechanism of the protective effect of non-steroidal anti-inflammatory drugs (NSAIDs) on Alzheimer's disease, inactivation of cholinesterase (ChE) induced by NSAIDs was examined.Main methodsEquine ChE and rat brain homogenate were incubated with NSAIDs and horseradish peroxidase (HRP) and H₂O₂ (HRP–H₂O₂). ChE activity was measured by using 5,5'-dithiobis(nitrobenzoic acid). By using electron spin resonance, NSAID radicals induced by reaction with HRP–H₂O₂ were detected in the presence of spin trap agents.Key findingsEquine ChE was inactivated by mefenamic acid with HRP–H₂O₂. ChE activity in rat brain homogenate decreased dependent on the concentration of mefenamic acid in the presence of HRP–H₂O₂. NSAIDs diclofenac, indomethacin, phenylbutazone, piroxicam and salicylic acid inactivated ChE. Oxygen radical scavengers did not prevent inactivation of ChE induced by mefenamic acid with HRP–H₂O₂. However, spin trap agents 5,5-dimethyl-1-pyrroline-l-oxide and N-methyl-nitrosopropane, reduced glutathione and ascorbic acid strongly inhibited inactivation of ChE, indicating participation of mefenamic acid radicals. Fluorescent emission of ChE peaked at 400 nm, and the Vmax value of ChE changed during interaction of mefenamic acid with HRP–H₂O₂, indicating that ChE may be inactivated through modification of tyrosine residues by mefenamic radicals.SignificanceThe protective effect of NSAIDs on Alzheimer's disease seems to occur through inactivation of ChE induced by NSAIDs radicals.