Nonenzymatic reduction of prostaglandin H by lipoic acid.

Lipoic acid has recently been found to stimulate prostaglandin biosynthesis by sheep vesicular gland microsomes (Marnett, L. J., and Wilcox, C. L. (1977). Biochim. Biophys. Acta 487, 222). The increase in oxygenated products is predominantly in the formation of prostaglandin F and its structure has been verified by gas chromatography-mass spectrometry. Endoperoxide trapping experiments employing reduced glutathione show that the conversion of prostaglandin H to prostaglandin F is slow in lipoate containing incubation mixtures. Therefore, the net effect of the addition of lipoic acid to vesicular gland microsomes is the stimulation of prostaglandin endoperoxide biosynthesis. Further experiments reveal that the reduction of prostaglandin H to prostaglandin F by lipoate is nonenzymatic and occurs after the termination of biosynthesis in the work-up mixture. The reduction takes place preferentially in the organic phase of a Folch extract (chloroform-methanol-2% formic acid 8:4:3). Authentic prostaglandin H2 is reduced by lipoic acid to prostaglandin F 2alpha in high yield under these conditions.     

Regional distribution of prostaglandin endoperoxide synthase studied by enzyme-linked immunoassay using monoclonal antibodies

Prostaglandin endoperoxide synthase transforms arachidonic acid to prostaglandin H2 via prostaglandin G2. The enzyme purified from bovine vesicular gland was given to mice as antigen, and monoclonal antibodies were raised by the hybridoma technique. Two species of the monoclonal antibody recognizing different sites of the enzyme were utilized to establish a peroxidase-linked immunoassay of prostaglandin endoperoxide synthase. Fab' fragment of one of the antibodies was prepared and conjugated to horseradish peroxidase. The conjugate was then bound to prostaglandin endoperoxide synthase, and the labeled enzyme was precipitated by the addition of the other antibody. The peroxidase activity of the immunoprecipitate correlated linearly with the amount of prostaglandin endoperoxide synthase. This sensitive and convenient method to determine the enzyme amount rather than the enzyme activity was utilized to extensively screen the amount of prostaglandin endoperoxide synthase in various bovine tissues. In addition to vesicular gland, platelets and kidney medulla previously known as rich enzyme sources, the immunoenzymometric assay demonstrated a high content of the enzyme in various parts of alimentary tract and a low but significant amount of enzyme in some parts of brain.     

On the structure of slow reacting substance of anaphylaxis: evidence of biosynthesis from arachidonic acid.

The mononuclear cells in peritoneal washings from normal rats can be induced to produce large amounts of slow reacting substance of anaphylaxis by incubation with 10 mM cysteine in the presence of the calcium ionophore A-23187. This production of slow reacting substance could be inhibited by the addition of non-steroidal anti-inflammatory drugs, e.g., indomethacin, ibuprofen and flurbiprofen, Furthermore, mediator production was inhibited by eicosatetraynoic acid, the substrate analog of arachidonic acid, and by 9,11-azoprosta-5, 13-dienoic acid (AZO analog 1), a structural analog of the prostaglandin endoperoxide, PGH2, which known to inhibit thromboxane synthesis. Relatively high concentrations of hydrocortisone acetate inhibited mediator production; this inhibition could be partly reversed by the addition of arachidonic acid or to a lesser extent by eicosatrienoic acid. Preliminary results suggest that a small fraction of the 3H-labled arachidonic acid which was taken up by these cells in vitro was associated with slow reacting substance. We postulate that slow reacting substance of anaphylaxis may be derived from a prostaglandin endoperoxide which is formed during the oxidation of arachidonic acid by the prostaglandin fatty acid cyclooxygenase.     

On the structure of slow reacting substance of anaphylaxis: Evidence of biosynthesis from arachidonic acid

The mononuclear cells in peritoneal washings from normal rats can be induced to produce large amounts of slow reacting substance of anaphylaxis by incubation with 10 mM cysteine in the presence of the calcium ionophore A-23187. This production of slow reacting substance could be inhibited by the addition of non-steroidal anti-inflammatory drugs, e.g., indomethacin, ibuprofen and flurbiprofen. Furthermore, mediator production was inhibited by eicosatetraynoic acid, the substrate analog of arachidonic acid, and by 9,11-azoprosta-5,13-dienoic acid (AzO analog 1), a structural analog of the prostaglandin endoperoxide, PGH₂, which is known to inhibit thromboxane synthesis. Relatively high concentrations of hydrocortisone acetate inhibited mediator production; this inhibition could be partly reversed by the addition of arachidonic acid or to a lesser extent by eicosatrienoic acid. Preliminary results suggest that a small fraction of the ³H-labeled arachidonic acid which was taken up by these cells in vitro was associated with slow reacting substance. We postulate that slow reacting substance of anaphylaxis may be derived from a prostaglandin endoperoxide which is formed during the oxidation of arachidonic acid by the prostaglandin fatty acid cyclooxygenase.     

Identification of the mRNA and polypeptide subunit for prostaglandin endoperoxide synthase from mouse mastocytoma P-815 cells.

Cloned mouse mastocytoma P-815.2-E-6 cells are barely able to synthesize prostaglandins because of a lack of prostaglandin endoperoxide synthase activity. However, the addition of sodium n-butyrate at 1 mM induces synthesis de novo of prostaglandins in this cell line. Employing this system, we could isolate an mRNA for prostaglandin endoperoxide synthase by a combination of cell-free translation and immunoprecipitation. The antibody, prepared in rabbit by injecting purified prostaglandin endoperoxide synthase from bovine vesicular gland, was shown to cross-react with the corresponding enzyme from 2-E-6 cells. The poly(A)-containing mRNA has a sedimentation coefficient of 17S and codes for a single polypeptide chain of Mr 62 000 as estimated by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. The Mr of the mouse polypeptide chain appears very similar to that of the purified carbohydrate-free prostaglandin endoperoxide synthase from sheep vesicular gland. These findings are a contribution to the isolation of the gene for prostaglandin endoperoxide synthase.     

A test for the intermediacy of 11-hydroperoxyeicosa-5,8,12,14-tetraenoic acid [11-HPETE] in prostaglandin biosynthesis

11-Hydroperoxy-eicosa-5,8,12,14-tetraenoic acid [11-HPETE] was prepared by chromatographic separation of the hydroperoxides formed from the singlet oxygen oxidation of arachidonic acid [20:4]. 1-[¹⁴C]-HPETE was incubated with prostaglandin endoperoxide synthetase preparations from ram seminal vesicles. No prostaglandins products deriving from 11-HPETE were detected in any of the incubations. 11-Hydroxy-eicosa-5,8,12,14-tetraenoic acid [11-HETE], formed by the action of the hydroperoxidase component of prostaglandin endoperoxidase synthetase was the major product formed. The peroxidase activity was absolutely dependent on epinephrine and was stimulated by hematin. 11-HPETE does not appreciably effect the extent of conversion of arachidonic acid into prostaglandin.     

Mechanism of prostaglandin biosynthesis in rabbit kidney medulla. A rate-limiting step and the differential stimulatory actions of L-adrenaline and glutathione.

Microsomal prostaglandin synthase (EC 1.14.99.1) from rabbit kidney medulla was assayed with [5,6,8,9,11,12,14,15-3H]-and [1-14C]-arachidonic acid as the substrate. The ratios of prostaglandin F2 alpha to prostaglandin E2 and to prostaglandin D2 were determined by both 3H and 14C labelling. When 3H was used as a label the ratios were much higher than with 14C labelling indicating that the removal of hydrogen at C-9 or C-11 was the rate-limiting step in the biosynthesis of prostaglandin E2 or prostaglandin D2. This finding shows that the octatritiated arachidonic acid is not the appropriate substrate marker for studying the regulation of the synthesis of different prostaglandins by various agents. When the enzyme assay was carried out in the presence of SnCL2, which was capable of accumulating exclusively prostaglandin F2alpha at the expenses of prostaglandin E2 and prostaglandin D2, the addition of L-adrenaline to the microsomal fraction either alone or with reduced glutathione equally stimulated the formation of prostaglandin F2alpha, whereas the addition of reduced glutathione to the microsomal fraction either alone or with L-adrenaline produced no additional effect. These results suggest that endoperoxide is formed as the common intermediate for the biosynthesis of three different prostaglandins in rabbit kidney medulla, and that L-adrenaline stimulates the synthesis of endoperoxide, whereas reduced glutathione facilitates the formation of prostaglandins from endoperoxide.     

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.     

Studies on the reduction of endogenously generated prostaglandin G2 by prostaglandin H synthase

Prostaglandin H synthase oxidizes arachidonic acid to prostaglandin G2 (PGG2) via its cyclooxygenase activity and reduces PGG2 to prostaglandin H2 by its peroxidase activity. The purpose of this study was to determine if endogenously generated PGG2 is the preferred substrate for the peroxidase compared with exogenous PGG2. Arachidonic acid and varying concentrations of exogenous PGG2 were incubated with ram seminal vesicle microsomes or purified prostaglandin H synthase in the presence of the reducing cosubstrate, aminopyrine. The formation of the aminopyrine cation free radical (AP.+) served as an index of peroxide reduction. The simultaneous addition of PGG2 with arachidonic acid did not alter cyclooxygenase activity of ram seminal vesicle microsomes or the formation of the AP.+. This suggests that the formation of AP.+, catalyzed by the peroxidase, was supported by endogenous endoperoxide formed from arachidonic acid oxidation rather than by the reduction of exogenous PGG2. In addition to the AP.+ assay, the reduction of exogenous versus endogenous PGG2 was studied by using [5,6,8,9,11,12,14,15-2H]arachidonic acid and unlabeled PGG2 as substrates, with gas chromatography-mass spectrometry techniques to measure the amount of reduction of endogenous versus exogenous PGG2. Two distinct results were observed. With ram seminal vesicle microsomes, little reduction of exogenous PGG2 was observed even under conditions in which all of the endogenous PGG2 was reduced. In contrast, studies with purified prostaglandin H synthase showed complete reduction of both exogenous and endogenous PGG2 using similar experimental conditions. Our findings indicate that PGG2 formed by the oxidation of arachidonic acid by prostaglandin H synthase in microsomal membranes is reduced preferentially by prostaglandin H synthase.     

Macrophage eicosanoid formation is stimulated by platelet arachidonic acid and prostaglandin endoperoxide transfer

The present study was designed to determine whether platelets transfer arachidonic acid or prostaglandin endoperoxide intermediates to macrophages which may be further metabolized into cyclooxygenase products. Adherent peritoneal macrophages were prepared from rats fed either a control diet or an essential fatty acid-deficient diet, and incubated with a suspension of washed rat platelets. Macrophage cyclooxygenase metabolism was inhibited by aspirin. In the presence of a thromboxane synthetase inhibitor, 7-(1-imidazolyl)heptanoic acid, immunoreactive 6-ketoprostaglandin F1 alpha formation was significantly increased 3-fold. Since this increase was greater (P less than 0.01) than that seen with either 7-(1-imidazolyl)heptanoic acid-treated platelets or aspirin-treated macrophages alone, these results indicate that shunting of endoperoxide from platelets to macrophages may have occurred. In further experiments, macrophages from essential fatty acid-deficient rats were substituted for normal macrophages. Essential fatty acid-deficient macrophages, depleted of arachidonic acid, produced only 2% of the amount of eicosanoids compared to macrophages from control rats. When platelets were exposed to aspirin, stimulated with thrombin, and added to essential fatty acid-deficient macrophages, significantly more immunoreactive 6-ketoprostaglandin F1 alpha was formed than in the absence of platelets. This increased macrophage immunoreactive 6-ketoprostaglandin F1 alpha synthesis, therefore, must have occurred from platelet-derived arachidonic acid. These data indicate that in vitro, in the presence of an inhibition of thromboxane synthetase, prostaglandin endoperoxides, as well as arachidonic acid, may be transferred between these two cell types.     

Effect of valine on the control of fatty acid synthesis in white adipose tissue of the rat.

In adipocytes from fed rats, the rate of fatty acid synthesis in the presence of glucose and insulin was inhibited 40% by valine (5 mm). tthis inhibition was largely abolished by the addition to the incubation medium of the transaminase inhibitor aminooxy acetate, and of pyruvate and agents which raise the intracellular pyruvate levels such as N,N,N1,N1-tetramethyl-p-phenylenediamine. Pyruvate output into the incubation medium from fat pads obtained from fed rats and incubated with glucose and insulin was decreased significantly by the addition of valine. When adipocytes were incubated under similar conditions, the final concentration of pyruvate in the incubation medium was 42 +/- 1.6 muM under control conditions and approximately one third of this value in the presence of 2.5 mM valine. Valine had no significant effect on pyruvate dehydrogenase (lipoate) (EC 1.2.4.1) activity when assayed in homogenates prepared from adipose tissue previously incubated for 60 min with the amino acid. Although the ketoacid analogue of valine alpha-ketoisovaleric acid, is a competitive inhibitor of pyruvate dehydrogenase (lipoate) (K1 = 1.4 mM), this cannot solely account for the valine-induced reduced rate of lipogenesis. Rather, the mechanism involves a reduction in pyruvate concentration and thereby a diminished flow through pyruvate dehydrogenase (lipoate). Details of the possible mechanism are discussed.     

Different substrate utilization between prostaglandin endoperoxide H synthase-1 and -2 in NIH3T3 fibroblasts

Recent studies suggested that prostaglandin endoperoxide H synthase-1 and prostaglandin endoperoxide H synthase-2 (PGHS-1 and PGHS-2) utilize different pools of arachidonic acid for synthesizing prostanoids. Using cultured murine NIH3T3 fibroblasts, we investigated the mechanism for the different utilization of arachidonic acid between PGHS-1 and -2. Histofluorescence staining for PGHS activity in intact cells demonstrated that quiescent 3T3 cells expressed only PGHS-1 activity and serum-activated 3T3 cells pretreated with aspirin expressed only PGHS-2 activity. Endogenous arachidonic acid released by calcium ionophore A23187 was not converted by PGHS-1 but exclusively converted by PGHS-2. In the cell free system, the kinetics of PGHS-1 were not so much different from those of PGHS-2. However, in intact cells, arachidonic acid at concentrations lower than 2.5 μM was converted by PGHS-2 alone but not by PGHS-1. Our findings indicated that this small amount of arachidonic acid as released by some stimuli is converted exclusively by PGHS-2. Furthermore, treating the PGHS-2-expressing cells with sodium selenite or ebselen, reducing agents of intracellular peroxides, only decreased PGHS-2 activity. We speculate that only PGHS-2 has been activated by intracellular peroxides and subsequently, it can convert the arachidonic acid released endogenously.     

Prostaglandin hydroperoxidase, an integral part of prostaglandin endoperoxide synthetase from bovine vesicular gland microsomes.

The highly purified prostaglandin endoperoxide synthetase from bovine vesicular gland microsomes had two still unresolved enzyme activities; the oxygenative cyclization of 8,11,14-eicosatrienoic acid to produce prostaglandin G1 and the conversion of the 15-hydro-peroxide of prostaglandin G1 to a 15-hydroxyl group, producing prostaglandin H1. The latter enzymatic reaction required heme and was stimulated by a variety of compounds, including tryptophan, epinephrine, and guaiacol, but not by glutathione. A peroxidatic dehydrogenation was demonstrated with epinephrine or guaiacol in the presence of various hydroperoxides, including hydrogen peroxide and prostaglandin G1. Higher activity and affinity were observed with the 15-hydroperoxide of eicosapolyenoic acid, especially those with the prostaglandin structure. Both the dehydrogenation of epinephrine or guaiacol and the 15-hydroperoxide reduction of prostaglandin G1 were demonstrated in nearly stoichiometric quantities. With tryptophan, however, such a stoichiometric transformation was not observed. The peroxidase activity as followed with guaiacol and hydrogen peroxide and the tryptophan-stimulated conversion of prostaglandin G1 to H1 were not dissociable as examined by isoelectric focusing, heat treatment, pH profile, and heme specificity. The results suggest that the peroxidase with a broad substrate specificity is an integral part of prostaglandin endoperoxide synthetase which is responsible for the conversion of prostaglandin G1 to H1.     

Work in progress: Ductus arteriosus closure may result from suppression of prostacyclin synthetase by an intrinsic hydroperoxy fatty acid

Fetal sheep ductus arteriosus readily synthesized prostacyclin from exogenous prostaglandin endoperoxides, and in the presence of the high oxygen tension, this synthesis is markedly suppressed. Fetal aorta and pulmonary artery also synthesize prostacyclin; however, this synthesis is much less suppressed by high oxygen tension. We propose that ductal closure may be regulated by the oxygen dependent synthesis of hydroperoxy fatty acid which would block the production of the vasodilatory prostacyclin and expose the direct contractile properties of the intrinsic prostaglandin endoperoxide. This mechanism would result in ductal closure at birth.     

Enzymatic formation of prostamide F2alpha from anandamide involves a newly identified intermediate metabolite, prostamide H2

Prostaglandin F2alpha 1-ethanolamide (prostamide F2alpha) is a potent ocular hypotensive agent in animals and represents a new class of fatty acid amide compounds. Accumulated evidence indicated that anandamide, an endogenous bioactive ligand for cannabinoid receptors, may serve as a common substrate to produce all prostamides, including prostamide F2alpha. After incubation of anandamide with cyclooxygenase 2 (COX-2), the reaction mixture was profiled by HPLC and an intermediate metabolite was discovered and characterized as a cyclic endoperoxide ethanolamide using HPLC-tandem mass spectrometry. Formation of prostamide F2alpha was also demonstrated when the intermediate metabolite was isolated and incubated with prostaglandin F synthase (PGF synthase). These results suggest that the biosynthesis of prostamide F2alpha proceeds in two consecutive steps: oxidation of anandamide to form an endoperoxide intermediate by COX-2, and reduction of the endoperoxide intermediate to form prostamide F2alpha by PGF synthase. This endoperoxide ethanolamide intermediate has been proposed as prostamide H2.     

Hepatic lipoate uptake

Uptake of [35S]lipoate was studied in perfused rat liver and in isolated rat hepatocytes. During single-pass perfusion of [35S]lipoate about 30% of the radioactivity is retained in the liver. A substantial amount of 5,5'-dithiobis(2-nitrobenzoic acid)-reactive material appears in the effluent perfusate, while hepatic efflux of GSH is unchanged. The hepatic uptake of lipoate, the release of thiols, and also the biliary excretion of 35S-labeled compounds are suppressed by octanoate. In isolated hepatocytes the uptake of lipoate follows saturation kinetics showing a Km value of 38 microM and a Vmax of 180 pmol/mg X 10 s. The uptake is temperature-dependent; from the Arrhenius plot an activation energy of 14.8 kcal/mol at 20 microM lipoate is calculated. At high concentrations of lipoate (above 75 microM) a nonsaturable uptake component becomes predominant. Lipoate uptake is selectively inhibited by medium-chain fatty acids. Only slight inhibition is seen in the presence of long-chain fatty acids, and there is no inhibition with acetate or lactate. Substantial inhibition is also observed with acetylsalicylic acid, but not with taurocholate, bromosulfophthalein or biotin. Lipoate uptake can be inhibited by high concentrations of phloretin (200 microM) and is rather insensitive to 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (200 microM). The results indicate that hepatic uptake of lipoate at physiological concentrations is largely carrier-mediated.     

The interaction between lipid peroxidation and prostaglandin synthesis in rabbit kidney-medulla slices.

Lipid peroxidation induced by ascorbic acid and Fe2+ was inhibited by mepacrine (phospholipase A2 inhibitor) and aspirin (prostaglandin cyclo-oxygenase inhibitor) in rabbit kidney-medulla slices. Moreover, ascorbic acid and Fe2+ potentiated the inhibitory effect on prostaglandin E2 formation by mepacrine, but they had no influence on prostaglandin E2 production decreased by aspirin. Lipid peroxidation induced by ascorbic acid and Fe2+ appears to be affecting the activity of prostaglandin endoperoxide synthase. These results suggest that lipid peroxidation is connected closely with the prostaglandin-generating system, and it has the potential to modulate the turnover of arachidonic acid and prostaglandin synthesis.     

Oxygenation reactions of prostaglandins endoperoxide synthase and soybean lipoxygenase. Surprising stoichiometry in the formation of hydroperoxy and hydroxy derivatives of cis,cis-eicosa-11,14-dienoic acid

The stoichiometry of the oxygenation reaction of cis,cis-eicosa-11,14-dienoic acid catalyzed by prostaglandin endoperoxide synthase and soybean lipoxygenase has been investigated by using steady-state initial rate measurements. The rate of product formation (conjugated diene hydroperoxy and hydroxy derivatives) was followed spectrophotometrically at 235 nm, and the rate of oxygen consumption was measured polarographically. The ratio of the two rates, d[conjugated diene]/-d[O₂], is 2/1 for the prostaglandin endoperoxide synthase catalyzed reaction and 1/1 for the lipoxygenase reaction. The 2/1 ratio can be explained by two interrelated routes, each of which results in formation of the conjugated diene hydroxy derivative of the acid. One route, initiated by hydrogen atom abstraction from the acid by Compound I, results in formation of the conjugated diene hydroperoxy derivative. The latter is converted to the hydroxy derivative by regenerating Compound I from the native enzyme. The other route involves direct oxygen atom insertion into the acid by the tyrosyl radical form of Compound I. The decrease in absorbance at 235 nm obtained in the presteady-state phase suggests that during the initial contact of hydroperoxide and enzyme an epoxy-hydroxy fatty acid-enzyme complex may be formed.     

Xenobiotic-metabolizing cytochromes P450 convert prostaglandin endoperoxide to hydroxyheptadecatrienoic acid and the mutagen, malondialdehyde

Cyclooxygenases catalyze the oxygenation of arachidonic acid to prostaglandin endoperoxides. Cyclooxygenase-2- and the xenobiotic-metabolizing cytochrome P450s 1A and 3A are all aberrantly expressed during colorectal carcinogenesis. To probe for a role of P450s in prostaglandin endoperoxide metabolism, we studied the 12-hydroxyheptadecatrienoate (HHT)/malondialdehyde (MDA) synthase activity of human liver microsomes and purified P450s. We found that human liver microsomes have HHT/MDA synthase activity that is concentration-dependent and inhibited by the P450 inhibitors, ketoconazole and clotrimazole with IC(50) values of 1 and 0.4 microM, respectively. This activity does not require P450 reductase. HHT/MDA synthase activity was present in purified P450s but not in heme alone or other heme proteins. The catalytic activities of various purified P450s were determined by measuring rates of MDA production from prostaglandin endoperoxide. At 50 microM substrate, the catalytic activities of purified human P450s varied from 10 +/- 1 to 0.62 +/- 0.02 min(-1), 3A4 > 2E1 > 1A2. Oxabicycloheptane analogs of prostaglandin endoperoxide, U-44069 and U-46619, induced spectral changes in human P450 3A4 with K(s) values of 240 +/- 20 and 130 +/- 10 microM, respectively. These results suggest that co-expression of cyclooxygenase-2 and P450s in developing cancers may contribute to genomic instability due to production of the endogenous mutagen, MDA.