Activation mechanism of prostaglandin endoperoxide synthetase by hemoproteins

The mechanism of the activation of prostaglandin endoperoxide synthetase by hemeproteins was investigated using the enzyme purified from bovine seminal vesicle microsomes. At pH 8, the maximal enzyme activities with methemoglobin (2 microM), indoleamine 2,3-dioxygenase (2 microM), and metmyoglobin (2 microM) were 70%, 42%, and 15% of that with 1 microM hematin. Apomyoglobin and apohemoglobin inhibited the enzyme activities caused by hemoproteins as well as that caused by hematin. The inhibition was removed by the addition of excess hematin. The dissociation of heme from hemoproteins was demonstrated by trapping the free heme with human albumin or to a DE-52 column. The dissociation of heme from methemoglobin was facilitated by increasing concentrations of arachidonic acid. The amount of heme dissociated from hemoproteins (methemoglobin, metmyoglobin, and indoleamine 2,3-dioxygenase) in the presence of arachidonic acid correlated with their stimulatory effects on the prostaglandin endoperoxide synthetase activity. Horseradish peroxidase and beef liver catalase, the hemes of which were not dissociated in the presence of arachidonic acid, were ineffective in activating prostaglandin endoperoxide synthetase. Spectrophotometric titration of prostaglandin endoperoxide synthetase with hematin demonstrated that the enzyme bound hematin at the ratio of 1 mol/mol with an association constant of 0.6 x 10(8) M-1. From these results, we conclude that hemoproteins themselves are ineffective in activating prostaglandin endoperoxide synthetase and free hematin dissociated from the hemoproteins by the interaction of arachidonic acid is the activating factor for the enzyme.     

Haemoglobin-catalysed retinoic acid 5,6-epoxidation.

Examination of the subcellular distribution of retinoic acid 5,6-epoxidase activity in rat liver and human liver homogenates showed that there is a prominent peak of activity in a high-density fraction. A corresponding peak was also detected in rat blood and human blood. Retinoic acid 5,6-epoxidation was catalysed by human blood cells but not by human plasma, and purified human haemoglobin also catalysed the epoxidation of retinoic acid to 5,6-epoxyretinoic acid. These results suggest that retinoic acid 5,6-epoxidase activity in human liver and rat liver homogenates is partially due to the presence of residual blood cells, and particularly haemoglobin, in the homogenates. In the retinoic acid 5,6-epoxidation catalysed by human haemoglobin, molecular O2 was required and its reaction was stimulated by Triton X-100. Boiling of haemoglobin solution resulted in an 94% decrease in the activity. NADPH (1 mM) and NADH (1 mM) completely [2-mercaptoethanol (5 mM) almost completely] inhibited the 5,6-epoxidation catalysed by haemoglobin, but catalase, superoxide dismutase and mannitol showed no inhibitory effect. CN- ion (100 mM) inhibited the reaction, but N3- ion (100 mM) did not.     

Decay Studies of Dmpo-Spin Adducts of Free Radicals Produced by Reactions of Metmyoglobin and Methemoglobin with Hydrogen Peroxide

The 5, 5-dimethyl-1-pyrroline-N-oxide (DMPO) spin adduct of myoglobin (Mb) or hemoglobin (Hb) was formed when metmyoglobin (MetMb) or methemoglobin (MetHb) reacted with H₂O₂ in the presence of DMPO, and both decayed with half-life of a few minutes. The DMPO spin adduct of Mb decayed with biphasic kinetics with k₁ = 0.645 min^-1 and k₂ = 0.012 min^-1, indicating that the spin adduct consisted of two kinetically heterogeneous species, stable and unstable ones. The DPMO spin adduct of Hb, however, was homogeneous. Decay of both spin adducts was accelerated in the presence of tyrosine, tryptophan or cysteine, but not phenylalanine, methionine or histidine. The decay obeyed the first order kinetics at varying concentrations of the spin adducts. The decay was accelerated by denaturation and proteolysis of protein moiety. The decay rate was not affected by the extra addition of MetMb or MetHb to each spin adduct. The decay rate of the spin adduct of Mb was increased by hematin in the presence of H₂O₂ and decreased by catalase. Decay of stable spin adduct of Mb, however, was not significantly changed under any experimental conditions used. These results led us to conclude that instability of the DMPO-spin adducts of Mb and Hb is due to intramolecular redox reactions between the spin adducts and amino acid residues and/or products of the reaction between heme and H₂O₂.     

Involvement of NADPH-cytochrome c reductase in the rat liver squalene epoxidase system.

Microsomal squalene epoxidase has previously been solubilized with Triton X-100 and resolved into fractions, FA and FB, by DEAE-cellulose chromatography (Ono T. and Bloch K (1975) J biol. Chem. 250, 1571-1579). It has now been found that FB is identical with NADPH-cytochrome c reductase (denoted FPT, EC 1.6.2.3). Although both NADPH and NADH served as electron donors, the former was preferred for squalene epoxidase activity in the reconstituted system of FA and FB. FB is characterized by its ability to reduce cytochrome c by NADPH. In place of FB, partially purified FPT was tested for its ability to support squalene epoxidation in the presence of FA. A stepwise purification of the deoxycholate-solubilized FPT yielded an increase in specific FPT activity with a parallel increase in squalene epoxidase activity. Bromelain-solubilized FPT was less effective. Rabbit antisera preparations to the purified FPT solubilized with trypsin were shown to inhibit concomitantly FPT activity and squalene epoxidase activity. These observations support the concept that squalene epoxidation is primarily mediated via a flavoprotein, NADPH-cytochrome c reductase, and a terminal oxidase, squalene epoxidase, which is distinct from cytochrome P-450.     

Nature of the FeO2 bonding in myoglobin and hemoglobin: A new molecular paradigm

The iron(II)-dioxygen bond in myoglobin and hemoglobin is a subject of wide interest. Studies range from examinations of physical-chemical properties dependent on its electronic structure, to investigations of the stability as a function of oxygen supply. Among these, stability properties are of particular importance in vivo. Like all known dioxygen carriers synthesized so far with transition metals, the oxygenated forms of myoglobin and hemoglobin are known to be oxidized easily to their ferric met-forms, which cannot bind molecular oxygen and are therefore physiologically inactive. The mechanistic details of this autoxidation reaction, which are of clinical, as well as of physical-chemical, interest, have long been investigated by a number of authors, but a full understanding of the heme oxidation has not been reached so far. Recent kinetic and thermodynamic studies of the stability of oxymyoglobin (MbO2) and oxyhemoglobin (HbO2) have revealed new features in the FeO2 bonding. In vivo, the iron center is always subject to a nucleophilic attack of the water molecule or hydroxyl ion, which can enter the heme pocket from the surrounding solvent and thereby irreversibly displace the bound dioxygen from MbO2 or HbO2 in the form of O2- so that the iron is converted to the ferric met-form. Since the autoxidation reaction of MbO2 or HbO2 proceeds through a nucleophilic displacement following one-electron transfer from iron(II) to the bound O2, this reaction may be viewed as a meeting point of the stabilization and the activation of molecular oxygen performed by hemoproteins. Along with these lines of evidence, we finally discuss the stability property of human HbO2 and provide with the most recent state of hemoglobin research. The HbA molecule contains two types of alphabeta contacts and seems to differentiate them quite properly for its functional properties. The alpha1beta2 or alpha2beta1 contact is associated with the cooperative oxygen binding, whereas the alpha1beta1 or alpha2beta2 contact is used for controlling the stability of the bound O2. We can thus form a unified picture for hemoglobin function by closely integrating the cooperative and the stable binding of molecular oxygen with iron(II) in aqueous solvent. These new views on the nature of FeO2 bonding and the possible role of globin moiety in stabilizing MbO2 and HbO2 are of primary importance, not only for a full understanding of various hemoprotein reactions with O2, but also for planning new molecular designs for synthetic oxygen carriers which may be able to function in aqueous solvent and at physiological temperature.     

Solubilization and partial characterization of rat liver squalene epoxidase.

The microsomal enzyme system from rat liver which catalyzes squalene epoxidation requires a supernatant protein and phospholipids (Tai, H., and Bloch, K. (1972) J. Biol. Chem. 247, 3767). It has now been found that these two cytoplasmic components can be replaced by Triton X-100. The same detergent solubilizes the microsomal squalene epoxidase and the resulting supernatant can be separated into two components, A and B, by DEAE-cellulose chromatography. Neither Fraction A nor B alone has significant squalene epoxidase activity but combining the two affords a reconstituted system 5-fold higher in specific epoxidase activity than that of the original microsomes. FAD and Triton X-100 in addition to molecular oxygen and NADPH are required in the reconstituted system. Subjecting Fraction A to a second DEAE-cellulose chromatography does not change its specific activity but lowers NADH-ferricyanide reductase activity and the protoheme content to 1/25 and 1/4, respectively. When Fraction B was chromatographed on Sephadex G-200, the specific epoxidase activity tested in the presence of Fraction A was increased 3-fold. This procedure also raised the specific activity of NADPH-cytochrome c reductase activity in Fraction B 3-fold. The reconstituted epoxidase system is not inhibited by either carbon monoxide, potassium cyanide, or o-phenanthrolien but Tiron at 1 mM was inhibitory (50%). Erythrocuprein has no effect on epoxidation. No evidence has been found for the participation of hemoproteins (P450 or cytochrome b5) in squalene epoxidation. Component B appears to be identical with the flavoprotein NADPH-cytochrome c reductase. Component A may be a flavoprotein with an easily dissociable prosthetic group.     

Initiation of membranal lipid peroxidation by activated metmyoglobin and methemoglobin

The interaction of hydrogen peroxide (H2O2) with metmyoglobin (MetMb) led very rapidly to the generation of an active species which could initiate lipid peroxidation. The activity of this prooxidant decreased rapidly during the first minutes, but 50% of its activity remained stable for more than 30 min. In this model system, it was found that small amounts of H2O2 (1-10 microM) could activate MetMb for significant lipid peroxidation. The incubation of the sarcosomal lipids with activated MetMb caused oxygen absorption. No absorption of oxygen was determined in the presence of membrane with MetMb or H2O2 alone. Methemoglobin (MetHb) was also found to be activated by H2O2 and to initiate lipid peroxidation. Membranal lipid peroxidation initiated by activated MetMb was inhibited by several reducing compounds and antioxidants. However, several hydroxyl radical scavengers and catalase failed to inhibit this reaction.     

Reactions of triethylphosphine gold(I) complexes with heme proteins: novel spin-state changes in cytochrome b562, myoglobin, and hemoglobin

Reactions of bacterial Fe(III) cyt b562, HbO2, met Hb and met Mb with Et3PAuCl and Et3PAuNO3 (and some related complexes) have been investigated by electronic absorption and EPR and NMR spectroscopy. Except for met Hb, which denatured, the products were novel high-spin Fe(III) heme proteins. The reactions of cyt b562 and Mb were reversible. Two distinct kinetic steps were observed in the autoxidation of HbO2 and MbO2. These may involve the liberation of superoxide. Autoxidation of HbO2 occurred more rapidly than that of MbO2. The kinetics of the spin-state change of cyt b562 were too fast to measure by conventional (spectrophotometric) methods. The reaction of Et3PAuCl with HbO2 was not blocked by N-ethylmaleimide. The reactions are discussed in terms of attack by Et3PAu+ on histidine residues in the hydrophobic haem pockets of the proteins.     

Prostaglandin endoperoxide synthetase from bovine vesicular gland microsomes. Inactivation and activation by heme and other metalloporphyrins.

Prostaglandin endoperoxide synthetase purified to apparent homogeneity from bovine vesicular gland microsomes contained iron far below the equimolar amount and essentially no heme. However, the enzyme required various metalloporphyrins including hematin or several hemoproteins such as hemoglobin. Preincubation of the enzyme with hematin or hemoglobin resulted in the loss of enzyme activity. The enzyme inactivation was protected by tryptophan or various other aromatic compounds. Furthermore, the simultaneous presence of tryptophan brought about activation of enzyme; namely, the enzyme preincubated with heme and tryptophan showed an almost full activity with a heme concentration in the reaction mixture far below the saturating level. Such inactivation and activation of the enzyme were also observed with manganese protoporphyrin. An identical heme requirement, heme-induced inactivation, and activation of the enzyme were observed in three types of reactions catalyzed by the enzyme: 1) bis-dioxygenation of 8,11,14-eicosatrienoic acid to produce prostaglandin G1, 2) 15-hydroperoxide cleavage of prostaglandin G1 to produce prostaglandin H1, and 3) guaiacol peroxidation. When heme was replaced by manganese protoporphyrin, the enzyme catalyzed only the bis-dioxygenation producing prostaglandin G1 and the activities of the latter two reactions were not detectable.     

Contribution of catalase to hydrogen peroxide resistance in Enterococcus faecalis

Enterococcus faecalis exhibits high resistance to oxidative stress. Several enzymes are responsible for this trait. The role of alkyl hydroperoxide reductase (Ahp), thiol peroxidase (Tpx), and NADH peroxidase (Npr) in oxidative stress defense was recently characterized. Enterococcus faecalis, in contrast to many other streptococci, contains a catalase (KatA), but this enzyme can only be formed when the bacterium is supplied with heme. We have used this heme dependency of catalase activity and mutants deficient in KatA and Npr to investigate the role of the catalase in resistance against exogenous and endogenous hydrogen peroxide stress. The results demonstrate that in the presence of environmental heme catalase contributes to the protection against toxic effects of hydrogen peroxide.     

Carbon Monoxide Alleviates Salt-Induced Oxidative Damage in Wheat Seedling Leaves

Carbon monoxide （CO）, a by-product released during the degradation of heme by heme oxygenases （EC 1.14.99.3） In animals, is regarded as an important physiological messenger or bioactive molecule involved in many biological events that has been recently reported as playing a major role in mediating the cytoprotectlon against oxidant-induced lung Injury. In the present study, we first determined the protective effect of exogenous CO against salt-induced oxidative damage in wheat seedling leaves. Wheat seedlings treated with 0.01μmol/L hematin as the CO donor demonstrated significant reversal of chlorophyll decay, dry weight, and water loss induced by 300 mmol/L NaCl stress. Interestingly, the increase in lipid peroxidation observed in salt-treated leaves was reversed by 0.01μmol/L hematin treatment. Time-couree analyses showed that application of 0.01μmol/L hematln enhanced gualacol peroxidase, superoxide dismutase, ascorbate peroxidase and catalase activities in wheat seedling leaves subjected to salt stress. These effects are specific for CO because the CO scavenger hemoglobin （1.2 mg/L） blocked the actions of the CO donor hematln. However, higher concentration of the CO donor （1.0μmol/L） did not alleviate dry weight and water loss of salt-stressed wheat seedlings. These results suggest that exogenous application of low levels of a CO donor may be advantageous against salinity toxicity.     

The interaction of methemoglobin and modified poly-(hydroxyethylmethacrylates) studied by spectroscopic methods

The interaction between methemoglobin (MetHb) and macroporous matrices on the basis of polymethacrylates was investigated by means of optical and e.p.r. spectroscopy. The spectroscopic data show that the adsorption of MetHb to imidazole-containing matrices occurs by complex formation between matrix-bound imidazole and the iron of the prosthetic group, with all 4 polypeptide chains of the MetHb molecule being included in the interaction. The adsorption to hydrophobic side chains containing matrices leads, via the protein-matrix interaction, to considerable disturbances of iron protoporphyrin IX in equilibrium or formed from protein-contacts, which are of general importance with respect to the functional variablity and control, respectively, of iron porphyrins in hemoproteins. In case of matrix containing n-hexyl groups deoxyHb is oxidized by O2 to MetHb, instead of being oxygenated to HbO2. Not all prosthetic groups are able to bind N-3. With the increase in hydrophobicity of the matrix a conformational change is enforced leading in the beta-chains to the direct interaction between iron and sulfur of cysteine (beta-cys 92), as it is proved in all cytochrome P-450 and other model compounds.     

No strict coupling of vitamin K1 (2-methyl-3-phytyl-1,4-naphthoquinone)-dependent carboxylation and vitamin K1 epoxidation in detergent-solubilized microsomal fractions from rat liver.

NAD(P)H dehydrogenase ('DT-diaphorase', EC 1.6.99.2) and vitamin K epoxidase were removed by affinity chromatography from detergent-solubilized microsomal fractions. Thereby the microsomal fractions normally carrying out vitamin K1-dependent carboxylation of the microsomal precursor proteins of the prothrombin complex were inactivated. Purified NAD(P)H dehydrogenase added to this system restored carboxylation in the presence of vitamin K1 (2-methyl-3-phytyl-1,4-naphthoquinone) plus NADH. Vitamin K1 hydroquinone (2-methyl-3-phytyl-1,4-naphthoquinol) had no effect, in contrast with its effect in the intact system, where it can substitute for vitamin K1 plus NADH. The ability of NAD(P)H dehydrogenase to restore carboxylation in a system without vitamin K epoxidase activity shows that there is no obligatory coupling of the vitamin K1-dependent carboxylation with vitamin K1 epoxidation. These results suggest that the form of vitamin K1 that is active in the carboxylation reaction can be produced independently in two reactions: by NAD(P)H dehydrogenase in the reduction of the quinone and by vitamin K epoxidase in the epoxidation of the hydroquinone.     

Purification and characterization of a catalase-peroxidase and a typical catalase from the bacterium Klebsiella pneumoniae

The bacterium Klebsiella pneumoniae synthesizes three different types of catalase: a catalase-peroxidase, a typical catalase and an atypical catalase, designated KpCP, KpT and KpA, respectively (Goldberg, I. and Hochman, A. (1989) Arch. Biochem. Biophys. 268, 124-128). KpCP, but not the other two enzymes, in addition to the catalatic activity, catalyzes peroxidatic activities with artificial electron donors, as well as with NADH and NADPH. Both KpCP and KpT are tetramers, with heme IX as a prosthetic group, and they show a typical high-spin absorption spectrum which is converted to low-spin when a cyanide complex is formed. The addition of dithionite to KpCP causes a shift in the absorption maxima typical of ferrous heme IX. KpCP has a pH optimum of 6.3 for the catalatic activity and 5.2-5.7 for the peroxidatic activity, and relatively low 'Km' values: 6.5 mM and 0.65 H2O2 for the catalatic and peroxidatic activities, respectively. The activity of the catalase-peroxidase is inhibited by azide and cyanide, but not by 3-amino-1,2,4-triazole. KpT has wide pH optimum: 5-10.5 and a 'Km' of 50 mM H2O2, it is inhibited by incubation with 3-amino-1,2,4-triazole and by the acidic forms of cyanide and azide. A significant distinction between the typical catalase and the catalase-peroxidase is the stability of their proteins: KpT is more stable than KpCP to H2O2, temperature, pH and urea.     

Optical and ESR-spectroscopic study of electronic adducts of oxymyoglobin and oxyhemoglobin

It has been shown that low temperatures (77 degrees K) irradiation of frozen water-glycerol solutions of oxymyoglobin and oxyhemoglobin induces kinetically stabilized nonequilibrium electronic adducts (MbO2-, HbO2-) at the expense of binding of thermolyzed electrons formed during matrix radiolysis to oxygenated hem iron. The absorption spectra of HbO2-and MbO2- have a wide band with the maximum at 545 nm and Soret's band at 421 nm. At 77 K MbO2- gives the ESR spectrum with g beta 1 = 2.203 and g beta 2 = 2.103. Unlike the latter HbO2- ESR spectrum consists of two signals g beta 1 = 2.234, g beta 2 = 2.135 and g alpha 1 = 2.195, g alpha 2 = 2.103. Two signals in HbO2- spectra are shown to be conditioned by electronic adducts of oxygenated alpha- and beta-subunits. The observed effect points to non-equivalency of O2 in alpha- and beta-subunits of oxyhemoglobin. Binding of inositolhexaphopshate to oxyhemoglobin induces changes in the electron structure of HbO2-active centres.     

Direct generation of superoxide anions by flash photolysis of human oxyhemoglobin.

The results presented in this report suggest that human oxyhemoglobin can directly form methemoglobin and superoxide anion when flashed with low intensity (38 joules) white light. The effect only occurred in quartz but not glass (cut off lambda approximately equal to 300 nm) cuvettes. The formation of O2 was established by observing the reduction of oxidized cytochrome c concomitant with MetHb formation at pH 9, and by showing that superoxide dismultase and catalse inhibit cytochrome c reduction at that pH. The inhibition of cytochrome c reduction by catalase led us to explore the possibility that H2O2 might reduce oxidized cytochrome c at pH 9. We show that H2O2 does reduce oxidized cytochrome c at that pH but not at pH 7. Furthermore, catalase but not superoxide dismutase, almost completely inhibited this reduction process. These experiments serve to confirm our interpretation of the effect of catalase on the reduction of oxidized cytochrome c in the photolytic experiments, thus establishing that H2O2 was also formed. In addition, we were able to identify the production of O2 and H2O2 due to the photolysis of water in agreement with the results of McCord and Fridovich ((1973) Photochem. Photobiol. 17, 115-121). Production of O2 from this source was considerably less than that observed when HbO2 was present. Addition of MetHb to aerated solutions of oxidized cytochrome c did not cause additional reduction, unlike addition of HbO2. The production of MetHb was found to have at least two components. One component was the primary photolytic process, and the second was a strongly pH-dependent reattack of HbO2 by O2. Addition of superoxide dismutase inhibited this second component, but did not significantly effect the primary photolytic process.     

Species-related variations in tissue antioxidant status--I. Differences in antioxidant enzyme profiles.

1. Antioxidant enzyme activity profiles in red cells of man, rabbit, quail, pig and rat have been investigated and found to exhibit striking differences. 2. No direct correlations between activities of "functionally coupled" enzymes (superoxide dismutase/catalase and glutathione peroxidase/glutathione reductase) were apparent, suggesting their independent regulation. 3. However, activities of red cell catalase and glutathione peroxidase in the various species studied were inversely correlated. 4. This was most evident in quail red cells, which showed negligible catalase activity but the highest levels of glutathione peroxidase of all the species examined. 5. A significant positive correlation between catalase and glutathione reductase activities was also demonstrated. 6. This may be relevant to the suggestion that the binding of NADPH to catalase may serve to decrease the intracellular inactivation of this reducing cofactor which may be limiting in the glutathione reductase reaction. 7. Basal levels of glutathione, which have been claimed to be limiting for the glutathione peroxidase reaction, were found to correlate positively with the activity of this enzyme in red cells. 8. Myocardial tissues also exhibited species-related differences in antioxidant enzyme profiles but these did not bear any obvious relationship to patterns observed in the corresponding red cells.     

Neuroglobin and cytoglobin as potential enzyme or substrate

The possible enzymatic activities of neuro- and cytoglobin as well as their potential function as substrates in enzymatic reactions were studied. Neuro- and cytoglobin are found to show no appreciable superoxide dismutase, catalase, and peroxidase activities. However, the internal disulfide bond (CD7-D5) of human neuroglobin can be reduced by thioredoxin reductase. Furthermore, our in vivo and in vitro studies show that Escherichia coli cells contain an enzymatic reducing system that keeps the heme iron atom of neuroglobin in the Fe(2+) form in the presence of dioxygen despite the high autoxidation rate of the molecule. This reducing system needs a low-molecular-weight compound as co-factor. In vitro tests show that both NADH and NADPH can play this role. Furthermore, the reducing system is not specific for neuroglobin but allows the reduction of the ferric forms of other globins such as cytoglobin and myoglobin. A similar reducing system is present in eukaryotic tissue protein extracts.     

Properties of NADPH and oxygen-dependent zeaxanthin epoxidation in isolated chloroplasts. A transmembrane model for the violaxanthin cycle.

Epoxidation of zeaxanthin in isolated lettuce chloroplasts (Lactuca saliva, var. Manoa) was dependent on reduced pyridine nucleotide and molecular oxygen and was stimulated by the presence of bovine serum albumin. Bovine serum albumin protected the epoxidase system from inhibition by fatty acids, and its effect was optimal at a bovine serum albumin/chlorophyll ratio of 14:1 ($\text{w}\text{w}$). NADPH and NADH were comparable in supporting epoxidation but were less effective than NADPH generated photosynthetically. Epoxidation was optimal at pH 7.8 and 7.4 in light and dark, respectively, and was inactive below pH 5.5.It is concluded that the epoxidase is an “external monooxygenase” and is located in a chloroplast compartment that remains neutral during illumination. The latter suggests that the violaxanthin cycle, of which epoxidation of zeaxanthin is a part, is a transmembrane system wherein de-epoxidation takes place on the loculus side and epoxidation on the stroma side of the membrane. This arrangement requires migration of the carotenoids of the violaxanthin cycle across the membrane in a type of shuttle. The possible role of this cycle in some regulatory mechanism of photosynthesis at the membrane level is discussed.