Fatty acid activation of guanylate cyclase from fibroblasts and liver.

Sodium arachidonate and sodium oleate increased particulate guanylate cyclase activity from homogenates of Balb 3T3 cells or rat liver. The fatty acids were about equipotent and were maximally effective at about 100 μm concentrations. Higher concentrations were less effective or inhibitory. Activation was similar in an air or nitrogen atmosphere and was unaltered by KCN, aspirin, or indomethacin. The dose-response curve was shifted to the right when arachidonate was preincubated prior to its addition to guanylate cyclase assays. Agents that facilitate fatty acid oxidation and the formation of malonyldialdehyde during preincubation such as glutathione, hemoglobin, Mn²⁺, Fe³⁺, or lipoxygenase shifted the dose-response curve further to the right. In contrast, agents that decreased or prevented arachidonate oxidation and malonyldialdehyde formation during preincubation such as butylated hydroxyanisole, propyl gallate, hydroquinone, and diphenylfuran prevented the shift in the dose-response curve or in some instances shifted the dose-response curve to the left. Activation of guanylate cyclase by arachidonate was reversed by the addition of lipoxygenase to incubations. These studies indicate that unsaturated fatty acids and not their oxidation products activate particulate enzyme from Balb 3T3 cells. The mechanism of fatty acid activation appears to be different from activation by nitro compounds. Fatty acids but not nitro compounds activated fibroblast preparations, and the effect of fatty acids in contrast to the activation by nitroprusside in liver preparations was not prevented with Lubrol PX.     

Activation of soluble guanylate cyclase by arachidonic acid and 15-lipoxygenase products

The activity of soluble guanylate cyclase can be increased by exposure of the enzyme to arachidonic acid or to some oxidized metabolites of the fatty acid. We have tried to determine whether activation of the enzyme by arachidonate requires that the fatty acid be converted to an oxidized metabolite, either by a possible trace contaminant of a lipoxygenase or by guanylate cyclase itself, which contains a heme moiety. Soluble guanylate cyclase purified from bovine lung was activated 4-6-fold by arachidonic acid. This activation was not dependent on the presence of oxygen in the incubation medium. No detectable metabolites of arachidonic acid were formed during incubation with soluble guanylate cyclase. Addition of soybean lipoxygenase to the incubation did not increase activation by arachidonic acid. The inhibitors of lipoxygenase activity, nordihydroguaiaretic acid and eicosatetraynoic acid, had direct effects on soluble guanylate cyclase and interfered with its activation by arachidonate, whereas another lipoxygenase inhibitor, BW 755 C, did not. The data suggest that arachidonic acid increases the activity of guanylate cyclase by direct interaction with the enzyme rather than by being converted to an active metabolite.     

Rabbit reticulocyte lipoxygenase catalyzes specific 12(S) and 15(S) oxygenation of arachidonoyl-phosphatidylcholine

The rabbit reticulocyte lipoxygenase is known to display an unusual facility for oxygenation of esterified polyunsaturated fatty acids, yet the precise structures of the products are not known. With free arachidonate as substrate the enzyme is known to catalyze 15S and 12S oxygenations, and demonstration of a facility for catalysis of these reactions on phospholipids would extend the potential scope of lipoxygenase reactions in cells. We elected to study in detail the reaction of the enzyme with a natural phospholipid, palmitoyl/arachidonoyl-phosphatidylcholine. We determined the nature of the products by initial isolation by RP-HPLC, followed by transesterification and identification of the oxygenated products by HPLC, uv, GC-MS, and steric analysis of hydroxyl configuration by HPLC. The major product was identified as a phosphatidylcholine in which the arachidonate component was converted to the 15(S)-hydroperoxy-eicosatetraenoate. A second oxygenated phospholipid was produced in smaller quantities (2-5% of the latter product) and identified as the 12(S)-oxygenated analog. These products were also identified after reaction of the reticulocyte lipoxygenase with human red cell membranes which were radiolabeled by preincubation with [3H]arachidonic acid. The finding of 12S oxygenation represents the first evidence that a lipoxygenase can control a reaction centered on the 10-carbon of an arachidonoyl phospholipid. This is an important precedent, because hydrogen abstraction from carbon-10 is a critical step in the lipoxygenase-catalyzed synthesis of 8- and 12-hydroperoxy-eicosatetraenoates (HPETEs) and for the conversion of 5- and 15-HPETEs to leukotrienes.     

Analysis of 15-Lipoxygenase Activity in Irradiated Thymocytes

We studied the effect of -irradiation on 15-lipoxygenase activity in rat thymocytes. The enzyme activity was determined as the rate of linoleic acid oxidation by the protein fraction isolated from the control and irradiated thymocytes under standard conditions. We demonstrate lipoxygenase activation immediately after irradiation of thymocytes. High lipoxygenase activity is observed in the cells for no more than an hour after irradiation. No high lipoxygenase activity later indicates that its synthesis is not directly induced by irradiation. Irradiation-induced generation of lipid peroxides can be the factor of lipoxygenase activation.     

Interaction between 5-lipoxygenase and allosteric effector--sodium dodecyl sulfate

The role of allosteric effector--sodium dodecyl sulfate (SDS) in the lipoxygenase catalysis in micelle system has been studied. The effect of the stable hydrophobic bis-nitroxides, blocking the free radical transformation, on the oxidation of linoleic acid or linoleic alcohol by 5-lipoxygenase from potato tuber has been investigated. The inhibiting effect of nitroxide compounds on oxidation of linoleic acid or linoleic alcohol by 5-lipoxygenase depends on SDS concentration. The inhibition percentage is determined by the substrate nature and presence of allosteric effector. The presence of SDS did not lead to an appreciable change in the pKa values of ionogenic enzyme groups. The effect of SDS and micellar system on thermodynamic parameters for thermoinactivation of 5-lipoxygenase was studied. It was found that thermoinactivation rate constants and activation energy of enzyme thermoinactivation were increased in the presence of SDS. It is suggested that interaction of 5-lipoxygenase and allosteric effector--SDS intensifies the dissociation of radical intermediates from the active site of the enzyme. These findings are of physiological significance in the light of the lipoxygenase involvement in the membrane lipid peroxidation.     

Biochemical characterization of the dual positional specific maize lipoxygenase and the dependence of lagging and initial burst phenomenon on pH, substrate, and detergent during pre-steady state kinetics

The wound-inducible lipoxygenase obtained from maize is one of the nontraditional lipoxygenases that possess dual positional specificity. In this paper, we provide our results on the determination and comparison of the kinetic constants of the maize lipoxygenase, with or without detergents in the steady state, and characterization of the dependence of the kinetic lag phase or initial burst, on pH, substrate, and detergent in the pre-steady state of the lipoxygenase reaction. The oxidation of linoleic acid showed a typical lag phase in the pre-steady state of the lipoxygenase reaction at pH 7.5 in the presence of 0.25% Tween-20 detergent. The reciprocal correlation between the induction period and the enzyme level indicated that this lag phenomenon was attributable to the slow oxidative activation of Fe (II) to Fe (III) at the active site of the enzyme as observed in other lipoxygenase reactions. Contrary to the lagging phenomenon observed at pH 7.5 in the presence of Tween-20, a unique initial burst was observed at pH 6.2 in the absence of detergents. To our knowledge, the initial burst in the oxidation of linoleic acid at pH 6.2 is the first observation in the lipoxygenase reaction. Kinetic constants (K(m) and k(cat) values) were largely dependent on the presence of detergent. An inverse correlation of the initial burst period with enzyme levels and interpretations on kinetic constants suggested that the observed initial burst in the oxidation of linoleic acid could be due to the availability of free fatty acids as substrates for binding with the lipoxygenase enzyme.     

Regeneration of vitamin E in human platelets

Human platelets possess active lipoxygenase and cyclooxygenase which convert arachidonic acid to (12S)-12-hydroperoxy-5,8,10,14-eicosatetraenoic acid (12-HPETE) plus (12S)-12-hydroxy-5,8,10,14-eicosatetraenoic acid (12-HETE) and thromboxane B2 plus 12-hydroxy-5,8,10-heptadecatrienoic acid (HHT), respectively. When platelet homogenates were incubated with arachidonate, there was a rapid consumption of platelet tocopherol. Time course analysis revealed that within 0.5 min, over half of arachidonate and tocopherol were metabolized. Mass formation of 12-HPETE and 12-HETE or thromboxane B2 and HHT exceeded that of the mass of tocopherol oxidized. Preincubation with the lipoxygenase inhibitor 5,8,11,14-eicosatetraynoic acid (ETYA) completely abolished this arachidonate-induced tocopherol oxidation whereas cyclooxygenase inhibitors (indomethacin and aspirin) further potentiated tocopherol oxidation, indicating that this oxidation is closely linked with platelet 12-lipoxygenase activity. Incubation with lipoxygenase metabolites of arachidonic acid showed that only 12-HPETE caused a rapid tocopherol oxidation which was followed by a gradual tocopherol regeneration. By using nordihydroguaiaretic acid (NDGA), a lipoxygenase inhibitor which is also a strong reductant, over 60% of the arachidonate-induced oxidized tocopherol was regenerated. Tocopherol regeneration declined with increasing oxidation time induced by arachidonate, and after 30-60 min virtually no regeneration could be observed, suggesting that the precursor molecule was unstable. We postulate that the precursor molecule is the tocopheroxyl radical. In the presence of ETYA, a lipoxygenase inhibitor without antioxidant properties, either ascorbate or GSH provided significant tocopherol regeneration. Kinetic studies showed that tocopherol regeneration after the addition of ascorbate was essentially completed by 1 min. By contrast, GSH addition caused a steady increase in tocopherol which peaked after 10 min of its addition. To determine whether this rapid regeneration is chemical or enzymic, regeneration was studied in the presence of chloroform and methanol. Comparison of various reductants in this denaturing condition for enzymes showed that ascorbate and NDGA afforded significant regeneration whereas GSH was ineffective, indicating that there are distinct enzymic and non-enzymic mechanisms for tocopherol regeneration. This study provides direct evidence from mass analysis that tocopherol can be regenerated in human cell homogenates. This finding implies that maintenance of membrane tocopherol status may be an essential function of ascorbate and GSH which operate in concert to ensure maximum membrane protection against oxidative damage.     

The specificity of lipoxygenase-catalyzed lipid peroxidation and the effects of radical-scavenging antioxidants

The oxidation of low density lipoprotein (LDL) by lipoxygenase has been implicated in the pathogenesis of atherosclerosis. It has been known that lipoxygenase-mediated lipid peroxidation proceeds in general via regio-, stereo- and enantio-specific mechanisms, but that it is sometimes accompanied by a share of random hydroperoxides as side reaction products. In this study we investigated the oxidation of various substrates (linoleic acid, methyl linoleate, phosphatidylcholine, isolated LDL, and human plasma) by the arachidonate 15-lipoxygenases from rabbit reticulocytes and soybeans aiming at elucidating the effects of substrate, lipoxygenase and reaction milieu on the contribution and mechanism of random oxidation and also the effect of antioxidant. The specific character of the rabbit 15-lipoxygenase reaction was confirmed under all conditions employed here. However, the specificity by soybean lipoxygenase was markedly dependent on the conditions. When phosphatidylcholine liposomes and LDL were oxygenated by soybean lipoxygenase, the product pattern was found to be exclusively regio-, stereo-, and enantio-random. When free linoleic acid was incorporated into PC liposomes and oxidized by soybean lipoxygenase, the free acid was specifically oxygenated, whereas esterified linoleate gave random oxidation products exclusively. Radical-scavenging antioxidants such as alpha-tocopherol, ascorbic acid and 2-carboxy-2,5,7,8-tetramethyl-6-chromanol selectively inhibited the random oxidation but did not influence specific product formation. It is assumed that the random reaction products originate from free radical intermediates, which have escaped the active site of the enzyme and thus may be accessible to radical scavengers. These data indicate that the specificity of lipoxygenase-catalyzed lipid oxidation and the inhibitory effects of antioxidants depend on the physico-chemical state of the substrate and type of lipoxygenase and that they may change completely depending on the conditions.     

Activity of soybean lipoxygenase in the absence of lipid hydroperoxide

Soybean lipoxygenase was assayed under conditions such that the concentration of the enzyme was in excess of the concentration of the substrate, arachidonic acid. Under these conditions, the concentration of lipid hydroperoxides present as contaminants in the substrate was negligible relative to the enzyme concentration, and the concentration of lipid hydroperoxide product could be determined accurately. The ferric form of the enzyme was observed to be fully active and to catalyze the oxidation of arachidonic acid at a near-diffusion-controlled rate, 1.4 X 10(7) M-1 s-1 at 0 degree C, at concentrations of lipid hydroperoxides as low as 5% of the enzyme concentration. From this, it can be concluded that the higher oxidation states that would be accessible by oxidation of Fe(III) by hydroperoxide are not required for catalysis by soybean lipoxygenase. Surprisingly, the activation of the ferrous form of the enzyme was also observed at insignificantly low lipid hydroperoxide concentrations. This activation presumably involves oxidation of the ferrous to the ferric form of the enzyme and must be more facile than has hitherto been reported. This result may rationalize previous reports that the ferrous and the ferric forms of the enzyme are both active.     

Albumin redirects platelet eicosanoid metabolism toward 12(S)-hydroxyeicosatetraenoic acid

Albumin is a major determinant of eicosanoid formation, affecting autacoids important in cell-cell interactions. We delineated three mechanisms by which albumin controlled platelet eicosanoid formation: 1) Albumin diverted free arachidonate toward 12-lipoxygenation. 2) Albumin enhanced release of arachidonate from phospholipids. 3) Albumin inhibited incorporation of arachidonate from the medium into platelet phospholipids. 12(S)-Hydroxyheptadecatrienoic acid (12-HHTrE) formation was reduced 70% by albumin as compared to that formed in albumin-free medium. In sharp contrast, formation of 12(S)-hydroxyeicosatetraenoic acid (12-HETE), the platelet lipoxygenase product, was much less influenced by albumin. Moreover, 12-HETE production in the presence of albumin was markedly increased and prolonged after aspirin treatment. These data suggested that albumin redirected released endogenous arachidonate from cyclooxygenase to lipoxygenase. Therefore, the metabolic fate of arachidonate present in the medium of stimulated platelets was studied by adding tracer [3H]arachidonate 30 sec before thrombin. Albumin increased arachidonate metabolism by lipoxygenase 7-fold as compared to albumin-free controls, while cyclooxygenation increased 2.7-fold. Redirection of eicosanoid metabolism by albumin toward lipoxygenase products constitutes a heretofore undescribed and potentially important physiological role for albumin. In vitro utilization of albumin may reflect in vivo events in thrombosis and hemostasis more accurately than previous studies without albumin could appreciate.     

Reticulocyte lipoxygenase exhibits both n-6 and n-9 activities

Purified reticulocyte lipoxygenase converts arachidonic acid to both 15- and 12-hydroxyperoxyeico-satetraenoic acids. The proportion of the two reaction products does not change during the purification procedure as shown by HPLC analysis. By means of isoelectric focusing it was not possible to separate the n-6 and n-9 activities. Reticulocyte lipoxygenase was completely inactivated by both 5,8,11-eicosatriynoic and 5,8,11,14-eicosatetraynoic acids in contrast to soybean lipoxygenase-1 which was inactivated only by 5,8,11,14-eicosatetraynoic acid. These results indicate that reticulocyte lipoxygenase exhibits both n-6 and n-9 activities. A contamination of the enzyme preparation with other lipoxygenases, e.g., the n-9 lipoxygenase from thrombocytes appears to be excluded.     

Occurrence of lipoxygenase products in membranes of rabbit reticulocytes. Evidence for a role of the reticulocyte lipoxygenase in the maturation of red cells

A lipoxygenase has been found in the reticulocytes of all mammalian species tested so far (rabbit, rat, mouse, monkey, and humans); evidence from in vitro studies suggests that the lipid-peroxidizing effects of this enzyme could render the mitochondrion and other intracellular organelles prone to the proteolytic degradation which is a natural step in development of the reticulocyte to the mature red cell. In this study we sought evidence of an active lipoxygenase in vivo. A bleeding anemia was induced in rabbits, and in the course of the subsequent reticulocytosis the red cell membranes were examined for the presence of the characteristic lipoxygenase products of linoleic and arachidonic acids. Erythrocyte membranes from control collections contained only small amounts of hydroxy fatty acids (0.03-0.08% of the polyenoic fatty acids). In contrast, reticulocyte-enriched red cells contained up to 3.3% of the polyenoic acids as hydroxylated derivatives. The main hydroxy fatty acid in reticulocyte membranes was identified as 13-L(S)-hydroxy-9Z,11E-octadecadienoic acid. Small amounts of other hydroxy derivatives including 15-hydroxy-5,8,11,13-(Z,Z,Z,E)eicosatetraenoic acid were also detected. These products appeared about 3 days after development of reticulocytosis. The precise structures of the hydroxylated polyenoic fatty acids and the time course of their appearance strongly suggest that their formation is due to the intracellular action of the cell-specific reticulocyte lipoxygenase. These findings are the first evidence for an activity of this enzyme in vivo, and the results support the hypothesis that enzymic peroxidation of reticulocyte intracellular membranes is a step in preparation of the intracellular organelles for proteolytic degradation.     

Optimization of cofactors which regulate RBL-1 arachidonate 5-lipoxygenase

The arachidonate lipoxygenase from rat basophilic leukemia cells (RBL-1) is widely utilized as a model to dissect the primary enzymatic reactions leading to leukotriene formation. The purpose of the present study was to optimize the specific activity of 5-lipoxygenase prepared from a high speed supernatant of RBL-1 cell homogenates. Activation of 5-lipoxygenase was observed in the presence of micromolar levels of calcium. A synergistic enhancement of 5-lipoxygenase was observed upon addition of equally low levels of ATP; maximal activation was induced by 5 microM CaCl2 plus 5 microM ATP. Addition of a microsomal-membrane preparation and NADPH further augmented 5-HETE biosynthesis. High concentrations (330 microM) of NADPH reversed the microsomal-induced stimulation of RBL-1 5-lipoxygenase, resulting in enzyme inhibition.     

Modulation of Cell-Substrate Adhesion by Arachidonic Acid: Lipoxygenase Regulates Cell Spreading and ERK1/2-inducible Cyclooxygenase Regulates Cell Migration in NIH-3T3 Fibroblasts

Adhesion of cells to an extracellular matrix is characterized by several discrete morphological and functional stages beginning with cell-substrate attachment, followed by cell spreading, migration, and immobilization. We find that although arachidonic acid release is rate-limiting in the overall process of adhesion, its oxidation by lipoxygenase and cyclooxygenases regulates, respectively, the cell spreading and cell migration stages. During the adhesion of NIH-3T3 cells to fibronectin, two functionally and kinetically distinct phases of arachidonic acid release take place. An initial transient arachidonate release occurs during cell attachment to fibronectin, and is sufficient to signal the cell spreading stage after its oxidation by 5-lipoxygenase to leukotrienes. A later sustained arachidonate release occurs during and after spreading, and signals the subsequent migration stage through its oxidation to prostaglandins by newly synthesized cyclooxygenase-2. In signaling migration, constitutively expressed cyclooxygenase-1 appears to contribute approximately 25% of prostaglandins synthesized compared with the inducible cyclooxygenase-2. Both the second sustained arachidonate release, and cyclooxygenase-2 protein induction and synthesis, appear to be regulated by the mitogen-activated protein kinase extracellular signal-regulated kinase (ERK)1/2. The initial cell attachment-induced transient arachidonic acid release that signals spreading through lipoxygenase oxidation is not sensitive to ERK1/2 inhibition by PD98059, whereas PD98059 produces both a reduction in the larger second arachidonate release and a blockade of induced cyclooxygenase-2 protein expression with concomitant reduction of prostaglandin synthesis. The second arachidonate release, and cyclooxygenase-2 expression and activity, both appear to be required for cell migration but not for the preceding stages of attachment and spreading. These data suggest a bifurcation in the arachidonic acid adhesion-signaling pathway, wherein lipoxygenase oxidation generates leukotriene metabolites regulating the spreading stage of cell adhesion, whereas ERK 1/2-induced cyclooxygenase synthesis results in oxidation of a later release, generating prostaglandin metabolites regulating the later migration stage.     

Arachidonic acid and related methyl ester mediate protein kinase C activation in intact platelets through the arachidonate metabolism pathways

Unlike unsaturated fatty acids, which almost fully activated purified brain protein kinase C in a phosphatidylserine- and Ca2(+)-free reaction, related methyl esters were poorly active in vitro. In contrast, methyl arachidonate was revealed to be as potent as arachidonic acid in activating protein kinase C in intact platelets. Arachidonic acid-mediated activation peaked at 20 s while methyl arachidonate-mediated activation plateaued at 2 min when both lipids were added at 50 microM. At concentrations higher than 0.3 mM, all tested unsaturated fatty acids and related methyl esters were weak activators of the enzyme, with the exception of linolenic acid and methyl linolenate which evoked strong enzyme activation. However, inhibitors of arachidonate metabolism blocked both arachidonic-acid and methyl-arachidonate-induced responses. At 5 microM arachidonic acid and methyl arachidonate, protein kinase C activation was due to a cyclooxygenase product(s) whereas at 50 microM the lipoxygenase pathway was mostly involved in the reaction. Therefore, arachidonic acid and its methyl ester activate protein kinase C in platelets mainly through action of their metabolites and eicosanoid synthesis. It is suggested that such indirect protein kinase C activation may account for the tumor-promoting activity of unsaturated fatty acids and related methyl esters.     

A re-interpretation of lipoxygenase-dependent insulin release: which metabolites of arachidonic acid, or none?

There are considerable data implicating a pancreatic islet 12-lipoxy-genase in glucose-induced insulin secretion. This enzyme traditionally is conceived as converting unesterified arachidonic acid to "free" hydroperoxyeicosatetraenoic acid and metabolites thereof. However, studies employing the provision of exogenous metabolites of arachidonic acid to islet tissue fail to identify convincingly the mediator of insulin release. It is proposed that the islet lipoxygenase directly peroxidizes unsaturated fatty acids esterified within membrane phospholipids, leading to changes in ion flux and enzyme activity (particularly phospholipase A2) at the membrane level. The release of unesterified metabolites of arachidonate, although reflecting islet lipoxygenase activity, may be an epiphenomenon.     

Membrane-bound lipoxygenase of rat cerebral microvessels

The microvessels isolated from rat cerebral cortex has arachidonate lipoxygenase activity, which was not due to possible contamination of the platelets. The major product was identified to be 12-hydroxyeicosatetraenoic acid. After homogenization and sonication of the microvessel preparations, the lipoxygenase activity was recovered both in the membrane- and the cytosol-fractions, whereas that in the platelets was recovered in the cytosol fraction. Membrane-bound lipoxygenase of the microvessels has apparent Km value of 3.8 microM for arachidonic acid, which was corresponded to 1/5 of that in the platelet enzyme. Microvessel lipoxygenase was inhibited by nordihydroguaiaretic acid but not by indomethacin.     

Arachidonate dilates basilar artery by lipoxygenase-dependent mechanism and activation of K(+) channels

Dilatation of cerebral arterioles in response to arachidonic acid is dependent on activity of cyclooxygenase. In this study, we examined mechanisms that mediate dilatation of the basilar artery in response to arachidonate. Diameter of the basilar artery (baseline diameter = 216 +/- 7 micrometer) (means +/- SE) was measured using a cranial window in anesthetized rats. Arachidonic acid (10 and 100 microM) produced concentration-dependent vasodilatation that was not inhibited by indomethacin (10 mg/kg iv) or N(G)-nitro-L-arginine (100 microM) but was inhibited markedly by baicalein (10 micrometerM) or nordihydroguaiaretic acid (NDGA; 10 microM), inhibitors of the lipoxygenase pathway. Dilatation of the basilar artery was also inhibited markedly by tetraethylammonium ion (TEA; 1 mM) or iberiotoxin (50 nM), inhibitors of calcium-dependent potassium channels. For example, 10 microM arachidonate dilated the basilar artery by 19 +/- 7 and 1 +/- 1% in the absence and presence of iberiotoxin, respectively. Measurements of membrane potential indicated that arachidonate produced hyperpolarization of the basilar artery that was blocked completely by TEA. Incubation with [(3)H]arachidonic acid followed by reverse-phase and chiral HPLC indicated that the basilar artery produces relatively small quantities of prostanoids but large quantities of 12(S)-hydroxyeicosatetraenoic acid (12-S-HETE), a lipoxygenase product. Moreover, the production of 12-HETE was inhibited by baicalein or NDGA. These findings suggest that dilatation of the basilar artery in response to arachidonate is mediated by a product(s) of the lipoxygenase pathway, with activation of calcium-dependent potassium channels and hyperpolarization of vascular muscle.     

The lipoxygenase of reticulocytes. Purification, characterization and biological dynamics of the lipoxygenase; its identity with the respiratory inhibitors of the reticulocyte.

A lipoxygenase has been purified from rabbit reticulocyte-rich anaemic blood cells. It possesses a molecular weight of 78 000 and an isoelectric point of 5.5 and contains 5% neutral sugars and two iron atoms per enzyme molecule. The lipoxygenase has proved to be identical with the inhibitors of respiratory proteins described formerly. The actions of the lipoxygenase on linoleic acid, phospholipids, mitochondrial and erythrocyte membranes and electron transfer particles were studied. A special feature of the reticulocyte lipoxygenase is the suicidal character of its action on lipids. With electron transfer particles the reticulocyte lipoxygenase causes a loss of acid-labile sulfur which accompanies respiratory inhibition; the strong respiratory inhibition is not exerted by soybean lipoxygenase. The reticulocyte lipoxygenase acts preferably on mitochondrial membranes as compared with cell membranes of the erythrocyte; erythrocyte cytosol moderates the action on mitochondrial membranes. Furthermore, the lipoxygenase reaction can concomitantly and irreversibly inactivate sulfhydryl enzymes as demonstrated with muscle glyceraldehyde-3-phosphate dehydrogenase. The occurrence of the lipoxygenase here described is restricted to reticulocytes; very low amounts were observed in bone marrow and no lipoxygenase was detectable in normal blood. During the course of an experimental anaemia the lipoxygenase is produced owing to superinduction in large amounts, which may persist for a long time since they escape inactivation. Preliminary evidence was obtained for the occurrence of other lipoxygenases in tissues of lung, spleen, kidney and also epithelial tumours.     

N-dealkylation of aminopyrine catalyzed by soybean lipoxygenase in the presence of hydrogen peroxide

A hypothesis that lipoxygenase may mediate N-dealkylation of xenobiotics was investigated using the prototype drug aminopyrine and soybean lipoxygenase as a model enzyme in the presence of hydrogen peroxide. Formaldehyde production as a result of N-demethylation of aminopyrine exhibited pH optimum of 6.5. The reaction was dependent on the incubation time, amount of enzyme, and concentration of aminopyrine and hydrogen peroxide. Under the experimental conditions employed, the specific activity for N-demethylation of aminopyrine was found to be 823 ± 93 nmoles per min/mg protein or 89 ± 10 nmoles per min/nmole of enzyme. The reaction was significantly inhibited by nordihydroguaiaretic acid and gossypol, the classical inhibitors of lipoxygenase. Spectrophotometric analyses indicated the generation of a nitrogen-centered free-radical cation as the initial oxidation product of aminopyrine. The rate of accumulation of this radical species was also dependent on pH, the amount of enzyme, and concentration of aminopyrine and hydrogen peroxide. The radical production was markedly suppressed by ascorbate, glutathione, and dithiothreitol in a concentration-dependent manner. Preliminary data gathered for the oxidation of other chemicals indicated that the lipoxygenase exhibits a unique substrate specificity. Collectively, the evidence presented suggests for the first time that lipoxygenase pathway may be involved in N-demethylation of aminopyrine and other chemicals. © 1998 John Wiley & Sons, Inc. J Biochem Toxicol 12: 175–183, 1998