Limited utilization of exogenous arachidonic acid by the prostaglandin cyclooxygenase in gastric mucosa: The role of protein binding, glutathione peroxidase, and hydrogen peroxides

We investigated the utilization of exogenous ¹⁴C-labelled arachidonic acid by the cyclooxygenase system of the gastric mucosa and its alteration by cytosolic factors, protein binding, glutathione peroxidase (GSH-Px), and hydrogen peroxides.Total prostaglandin (PG) synthesis from gastric microsomes was reduced in a dose- dependent manner to 12% and 68% of controls by increasing amounts of the 105,000g supernatant or albumin (8mg protein/ml), respectively (p<0.01). The inhibitory cytosolic factor was heat labile, protease sensitive, and was retained by a 300,000 Dalton ultrafiltration membrane. Thus, it was likely a protein. Other possible inhibitory mechanisms like protease- or heme-induced destabilization of the cyclooxygenase, haptoglobin-mediated inhibition, or self-inactivation by endogenous substrate were excluded.N-ethylmaleimide (NEM), an agent that alkylates sulfhydryl-groups thereby inhibiting GSH-Px, abolished the inhibitory effect of cytosol in a dose-dependent fashion. In contrast to their inhibition of prostaglandin synthesis, the binding of arachidonic acid by albumin or cytosolic proteins accounted to 75% and 19% under comparable conditions, respectively, however, cytosolic fatty acid binding was unaffected by NEM. Thus, it was concluded that the inhibitory effect of cytosol, in contrast to albumin, was mediated by a sulfhydryl-depending process, probably a GSH-Px. This conclusion was supported by a qualitatively comparable inhibition by a purified GSH-Px from bovine erythrocytes.The inhibitory action of cytosolic proteins was reduced significantly by increasing concentrations or repeated application of arachidonic acid; therefore, cytosolic GSH-Px was likely to affect substrate utilization by the microsomal PGH synthase through reduction of activating substrate peroxides.Similarly, the in vitro formation of cyclooxygenase products by mucosal homogenate or gastric microsomes in the absence of cytosol was limited at substrate concentrations below 80μM, despite sufficient nonesterified arachidonic acid remaining in the incubate. This limitation was mediated only partially by self-inactivation of the prostaglandin cyclooxygenase. Neither N-ethylmaleimide nor repeated application of hydrogen peroxides increased substrate utilization by isolated microsomes, excluding contamination by GSH-Px or simply a lack of hydrogen peroxides as possible mechanisms for the limited utilization. From these results, a special role of substrate-linked lipid peroxides in the activation of mucosal prostaglandin synthesis is proposed. The reduction of these peroxides by glutathione dependent or independent peroxidases, e.g. the PGH synthase-linked hydroperoxidase activity itself, could explain the reduced utilization of nonesterified arachidonic acid by the gastric mucosa.     

Limited utilization of exogenous arachidonic acid by the prostaglandin cyclooxygenase in gastric mucosa: the role of protein binding, glutathione peroxidase, and hydrogen peroxides.

We investigated the utilization of exogenous 14C-labelled arachidonic acid by the cyclooxygenase system of the gastric mucosa and its alteration by cytosolic factors, protein binding, glutathione peroxidase (GSH-Px), and hydrogen peroxides. Total prostaglandin (PG) synthesis from gastric microsomes was reduced in a dose- dependent manner to 12% and 68% of controls by increasing amounts of the 105,000g supernatant or albumin (8mg protein/ml), respectively (p less than 0.01). The inhibitory cytosolic factor was heat labile, protease sensitive, and was retained by a 300,000 Dalton ultrafiltration membrane. Thus, it was likely a protein. Other possible inhibitory mechanisms like protease- or heme-induced destabilization of the cyclooxygenase, haptoglobin-mediated inhibition, or self-inactivation by endogenous substrate were excluded. N-ethylmaleimide (NEM), an agent that alkylates sulfhydryl-groups thereby inhibiting GSH-Px, abolished the inhibitory effect of cytosol in a dose-dependent fashion. In contrast to their inhibition of prostaglandin synthesis, the binding of arachidonic acid by albumin or cytosolic proteins accounted to 75% and 19% under comparable conditions, respectively, however, cytosolic fatty acid binding was unaffected by NEM. Thus, it was concluded that the inhibitory effect of cytosol, in contrast to albumin, was mediated by a sulfhydryl-depending process, probably a GSH-Px. This conclusion was supported by a qualitatively comparable inhibition by a purified GSH-Px from bovine erythrocytes. The inhibitory action of cytosolic proteins was reduced significantly by increasing concentrations or repeated application of arachidonic acid; therefore, cytosolic GSH-Px was likely to affect substrate utilization by the microsomal PGH synthase through reduction of activating substrate peroxides. Similarly, the in vitro formation of cyclooxygenase products by mucosal homogenate or gastric microsomes in the absence of cytosol was limited at substrate concentrations below 80 microM, despite sufficient nonesterified arachidonic acid remaining in the incubate. This limitation was mediated only partially by self-inactivation of the prostaglandin cyclooxygenase. Neither N-ethylmaleimide nor repeated application of hydrogen peroxides increased substrate utilization by isolated microsomes, excluding contamination by GSH-Px or simply a lack of hydrogen peroxides as possible mechanisms for the limited utilization. From these results, a special role of substrate-linked lipid peroxides in the activation of mucosal prostaglandin synthesis is proposed. The reduction of these peroxides by glutathione dependent or independent peroxidases, e.g. the PGH synthase-linked hydroperoxidase activity itself, could explain the reduced utilization of nonesterified arachidonic acid by the gastric mucosa.     

Regulatory role of cyclic adenosine 3′,5′-monophosphate on the plattelet cyclooxygenase and platelet function

Thromboxane A₂ plays and important role in arachidonic acid- and prostaglandin H₂-induced platelet aggregation. Agents that stimulate platelet adenylate cyclase (prostaglandin I₂, prostaglandin I₁, and prostaglandin E₁) and dibutyryl cyclic AMP inhibit both thromboxane A₂ formation and arachidonate-induced aggregation platelet-rich plasma. Despite complete suppression of aggregation with agents that elevate cyclic AMP, considerable thromboxane A₂ is still formed. Prostaglandin H₂-induced aggregations which bypass the cyclooxygenase regulatory step are also inhibited by agents that elevate cyclic AMP without any measurable effect on thromboxane A₂ production. These data demonstrate that cyclic AMP can inhibit platelet aggregation by a mechanism independent of its ability to suppress the cycyooxygenase enzyme. Parallel experiments with washed platelet preparations suggest that they may be an inadequate mode for studying relationship between the platelet cyclooxygenase and platelet function.     

Selective microdetermination of lipid hydroperoxides

A sensitive and selective assay for lipid hydroperoxides was developed based upon the activation by hydroperoxides of the cyclooxygenase activity of prostaglandin H synthase. The assay measures hydroperoxides directly by their stimulatory action on the cyclooxygenase and thus differs from the methods used currently which rely on the measurement of secondary products to estimate the amount of hydroperoxide. The present assay of enzymatic response was approximately linear in the range 10 to 150 pmol of added lipid hydroperoxide. This sensitivity for lipid peroxides is about 50-fold greater than that of the thiobarbiturate assay with fluorescence detection. When applied to samples of human plasma, the enzymatic assay indicated that the concentration of lipid hydroperoxides in normal subjects is 0.5 microM, more than 50-fold lower than estimated by the thiobarbiturate assay (30-50 microM). Nevertheless, the circulating concentration of 0.5 microM lipid hydroperoxide approaches that reported to have deleterious effects upon vascular prostacyclin synthase.     

Ascorbic acid reduces the frequency of iron induced micronuclei in bone marrow cells of mice

Iron is a potent oxidant that can lead to the formation of genotoxic lipid peroxides. Ascorbic acid, which enhances dietary iron absorption, has been suggested to enhance the oxidant effects of iron and to directly lead to the formation of lipid peroxides. The combined effects of dietary iron and ascorbic acid on genotoxicity were investigated by measuring the frequency of micronuclei in the bone marrow cells of C3H/He mice. In addition, liver iron concentration was measured in all treated groups. Three weeks old mice were fed diets for 3 weeks containing iron at 100 or 300 mg/kg diet in the form of FeSO₄ that were supplemented either with or without ascorbic acid (15 g/kg diet). The results of the bone marrow micronucleus test revealed that the high iron diet resulted in an increased frequency of micronucleated polychromatic erythrocytes (MnPCEs) as compared to low iron. Ascorbic acid supplementation in the low iron diet did not show any effect on incidence of MnPCEs and protected against the increased frequency of MnPCEs induced by the high iron diet. However, liver iron concentration was significantly increased only in the high iron treated and ascorbic acid supplemented group as compared to all other groups. These results demonstrate that ascorbic acid protects against the clastogenic effects of iron.     

Superoxide-dependent lipid peroxidation. Problems with the use of catalase as a specific probe for fenton-derived hydroxyl radicals

Hydroxyl radicals (OH.) can initiate lipid oxidation by hydrogen abstraction. Transition metals however, particularly iron and copper, stimulate lipid oxidation by reacting with lipid peroxides to form new radical species. The haem-iron protein catalase can react non-specifically with lipid peroxides in this way resulting in loss of their conjugated diene structures. When a superoxide-generating system is used to stimulate lipid autoxidation, catalase can conceivably inhibit the reaction in two ways (A) by decomposing lipid peroxides as they are formed (B) through the removal of hydrogen peroxide preventing OH. radical formation. Results presented here suggest that the latter interpretation, although commonly presented, cannot be automatically assumed.     

Regulatory role of cyclic adenosine 3',5'-monophosphate on the platelet cyclooxygenase and platelet function.

Thromboxane A2 plays an important role in arachidonic acid- and prostaglandin H2-induced platelet aggregation. Agents that stimulate platelet adenylate cyclase (prostaglandin I2, prostaglandin I1 and prostaglandin E1) and dibutyryl cyclic AMP inhibit both thromboxane A2 formation and arachidonate-induced aggregation in platelet-rich plasma. Despite complete suppression of aggregation with agents that elevate cyclic AMP, considerable thromboxane A2 is still formed. Prostaglandin H2-induced aggregations which bypass the cyclooxygenase regulatory step are also inhibited by agents that elevate cyclic AMP without any measurable effect on thromboxane A2 production. These data demonstrate that cyclic AMP can inhibit platelet aggregation by a mechanism independent of its ability to suppress the cyclooxygenase enzyme. Parallel experiments with washed platelet preparations suggest that they may be an inadequate model for studying the relationship between the platelet cyclooxygenase and platelet function.     

Lactoperoxidase-catalyzed lipid peroxidation of microsomal and artificial membranes

Lactoperoxidase, in the presence of H₂O₂, I^?, and rat liver microsomes, will peroxidize membrane lipids, as evidence by malondialdehyde formation. Fe³⁺ assists in the formation of malondialdehyde. Fe³⁺ can be added at the end of the reaction period as well as at the beginning with equal effectiveness, suggesting that it only acts to assist in the conversion of lipid peroxides, previously formed by lactoperoxidase, to malondialdehyde. The addition of EDTA to the microsomal reaction mixture results in a 40% decrease in malondialdehyde formation. The antioxidant butylated hydroxytoluene will completely block the formation of malondialdehyde. Malondialdehyde formation is not dependent upon the production of superoxide, singlet oxygen, or hydroxyl radicals. Peroxidation of membrane lipids by this system is equally effective in both intact microsomes and in liposomes, indicating that iodination of microsomal protein is not required for lipid peroxidation to occur.     

Lipoprotein Oxidation and Induction of Ferroxidase Activity in Stored Human Extracellular Fluids

It was observed that during the storage of human extracellular fluids at – 20°C the azide-inhibitable ferroxidase activity of caeruloplasmin declined, whilst a new azide-resistant ferroxidase activity (ARFA) developed. The literature suggested that storage-induced ARFA might be due to either a poorly defined enzymatic activity of a low density lipoprotein (LDL) or to lipid peroxides formed within the different lipoprotein fractions. To study this further, the major lipoprotein classes were separated from human serum by density gradient centrifugation. After storage of the lipoprotein fractions, it was found that the LDL fraction had the highest specific activity of ARFA and the highest content of lipid peroxidation products, as assessed by diene conjugates. The ARFA of LDL correlated with its content of diene conjugates and TBA reactive material, which initially suggested that the Fe(II) oxidising activity of peroxidised LDL arose from the reduction of peroxides by Fe(II) in the classical reaction between the metal ion and free radical reduction of lipid peroxides. However. steady state kinetic analysis indicated an enzymic role of LDL in Fe(II) oxidation, with lipid peroxides acting as a substrate for the enzyme. These results indicate that LDL may contain a peroxidase activity. catalysing the oxidation of Fe(II) by lipid peroxides, as well as a ferrous oxidase activity where O₂ is the oxidising substrate.     

Essential fatty acid metabolism in patients with essential hypertension, diabetes mellitus and coronary heart disease

Mortality and morbidity from coronary heart disease (CHD), diabetes mellitus (DM) and essential hypertension (HTN) are higher in people of South Asian descent than in other groups. There is evidence to believe that essential fatty acids (EFAs) and their metabolites may have a role in the pathobiology of CHD, DM and HTN. Fatty acid analysis of the plasma phospholipid fraction revealed that in CHD the levels of gamma-linolenic acid (GLA), arachidonic acid (AA), eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) are low, in patients with HTN linoleic acid (LA) and AA are low, and in patients with non-insulin dependent diabetes mellitus (NIDDM) and diabetic nephropathy the levels of dihomo-gamma-linolenic acid (DGLA), AA, alapha-linolenic acid (ALA) and DHA are low, all compared to normal controls. These results are interesting since DGLA, AA and EPA form precursors to prostaglandin E₁, (PGE₁), prostacyclin (PGI₂), and PGI₃, which are potent platelet anti-aggregators and vasodilators and can prevent thrombosis and atherosclerosis. Further, the levels of lipid peroxides were found to be high in patients with CHD, HTN, NIDDM and diabetic nephropathy. These results suggest that increased formation of lipid peroxides and an alteration in the metabolism of EFAs are closely associated with CHD, HTN and NIDDM in Indians. Since insulin resistance and hyperinsulinemia and features of obesity, NIDDM, HTN and CHD, diseases that are common in Indians, and as decreased insulin sensitivity is associated with decreased concentrations of polyunsaturated fatty acids (PUFAs) in skeletal muscle phospholipids and, possibly, in the plasma, the possibility is raised that changes in the metabolism of EFAs may have a fundamental role in the pathobiology of these conditions. If this is true, this suggests that supplementation of GLA, DGLA, AA, EPA and/or DHA may be indicated to prevent CHD, HTN and NIDDM in Indians.     

Lipid peroxidation during the oxidation of haemoproteins by hydroperoxides. Relation to electronically excited state formation

The formation of electronically excited states during hydroperoxide metabolism is analysed in terms of recombination reactions involving secondary peroxyl radicals and scission of the O? O bond of peroxides by haemoproteins, mainly myoglobin. Both processes may be sequentially interrelated, for the cleavage of H₂O₂ by metmyoglobin leads to the formation of a strong oxidizing equivalent with the capability to promote peroxidation of polyunsaturated fatty acids. The decomposition of lipid hydroperoxides by ferryl-hydroxo complexes, as that formed during the oxidation of metmyoglobin by H₂O₂, is a source of peroxyl radicals, the recombination of which proceeds with elimination of a conjugated triplet carbonyl or singlet oxygen.     

Prostaglandin H synthase: distinct binding sites for cyclooxygenase and peroxidase substrates

Prostaglandin H synthase has two distinct catalytic activities: a cyclooxygenase activity that forms prostaglandin G2 from arachidonic acid; and a peroxidase activity that reduces prostaglandin G2 to prostaglandin H2. Lipid hydroperoxides, such as prostaglandin G2, also initiate the cyclooxygenase reaction, probably via peroxidase reaction cycle enzyme intermediates. The relation between the binding sites for lipid substrates of the two activities was investigated with an analysis of the effects of arachidonic and docosahexaenoic acids on the reaction kinetics of the peroxidase activity, and their effects on the ability of a lipid hydroperoxide to initiate the cyclooxygenase reaction. The cyclooxygenase activity of pure ovine synthase was found to have an apparent Km value for arachidonate of 5.3 microM and a Ki value (competetive inhibitor) for docosahexaenoate of 5.2 microM. When present at 20 microM neither fatty acid had a significant effect on the apparent Km value of the peroxidase for 15-hydroperoxyeicosatetraenoic acid: the values were 7.6 microM in the absence of docosahexaenoic acid and 5.9 microM in its presence, and (using aspirin-treated synthase) 13.7 microM in the absence of arachidonic acid and 15.7 microM in its presence. Over a range of 1 to 110 microM the level of arachidonate had no significant effect on the initiation of the cyclooxygenase reaction by 15-hydroperoxyeicosatetraenoic acid. The inability of either arachidonic acid or docosahexaenoic acid to interfere with the interaction between the peroxidase and lipid hydroperoxides indicates that the cyclooxygenase and peroxidase activities of prostaglandin H synthase have distinct binding sites for their lipid substrates.     

Possible inhibitory function of endogenous 15-hydroperoxyeicosatetraenoic acid on prostacyclin formation in bovine aortic endothelial cells

Arachidonic acid is metabolized via the cyclooxygenase pathway to several potent compounds that regulate important physiological functions in the cardiovascular system. The proaggregatory and vasoconstrictive thromboxane A2 produced by platelets is opposed in vivo by the antiaggregatory and vasodilating activity of prostacyclin (prostaglandin I2) synthesized by blood vessels. Furthermore, arachidonic acid is metabolized by lipoxygenase enzymes to different isomeric hydroxyeicosatetraenoic acids (HETE's). This metabolic pathway of arachidonic acid was studied in detail in endothelial cells obtained from bovine aortae. It was found that this tissue produced 6-ketoprostaglandin F1 alpha as a major cyclooxygenase metabolite of arachidonic acid, whereas prostaglandins F2 alpha and E2 were synthesized only in small amounts. The monohydroxy fatty acids formed were identified as 15-HETE, 5-HETE, 11-HETE and 12-hydroxy-5,8,10-heptadecatrienoic acid (HHT). The latter two compounds were produced by cyclooxygenase activity. Nordihydroguaiaretic acid (NDGA), a rather selective lipoxygenase inhibitor and antioxidant blocked the synthesis of 15- and 5-HETE. It also strongly stimulated the cyclooxygenase pathway, and particularly the formation of prostacyclin. This could indicate that NDGA might exert its effect on prostacyclin levels by preventing the synthesis of 15-hydroperoxyeicosatetraenoic acid (15-HPETE), a potent inhibitor of prostacyclin synthetase. 15-HPETE could therefore act as an endogenous inhibitor of prostacyclin production in the vessel wall.     

Oxyferryl heme and not tyrosyl radical is the likely culprit in prostaglandin H synthase-1 peroxidase inactivation

Prostaglandin H synthase-1 (PGHS-1) is a bifunctional heme protein catalyzing both a peroxidase reaction, in which peroxides are converted to alcohols, and a cyclooxygenase reaction, in which arachidonic acid is converted into prostaglandin G2. Reaction of PGHS-1 with peroxide forms Intermediate I, which has an oxyferryl heme and a porphyrin radical. An intramolecular electron transfer from Tyr385 to Intermediate I forms Intermediate II, which contains two oxidants: an oxyferryl heme and the Tyr385 radical required for cyclooxygenase catalysis. Self-inactivation of the peroxidase begins with Intermediate II, but it has been unclear which of the two oxidants is involved. The kinetics of tyrosyl radical, oxyferryl heme, and peroxidase inactivation were examined in reactions of PGHS-1 reconstituted with heme or mangano protoporphyrin IX with a lipid hydroperoxide, 15-hydroperoxyeicosatetraenoic acid (15-HPETE), and ethyl hydrogen peroxide (EtOOH). Tyrosyl radical formation was significantly faster with 15-HPETE than with EtOOH and roughly paralleled oxyferryl heme formation at low peroxide levels. However, the oxyferryl heme intensity decayed much more rapidly than the tyrosyl radical intensity at high peroxide levels. The rates of reactions for PGHS-1 reconstituted with MnPPIX were approximately an order of magnitude slower, and the initial species formed displayed a wide singlet (WS) radical, rather than the wide doublet radical observed with PGHS-1 reconstituted with heme. Inactivation of the peroxidase activity during the reaction of PGHS-1 with EtOOH or 15-HPETE correlated with oxyferryl heme decay, but not with changes in tyrosyl radical intensity or EPR line shape, indicating that the oxyferryl heme, and not the tyrosyl radical, is responsible for the self-destructive peroxidase side reactions. Computer modeling to a minimal mechanism was consistent with oxyferryl heme being the source of peroxidase inactivation.     

Studies on the properties of the singlet oxygen-like factor produced during lipid peroxidation

The singlet oxygen reaction product of various trapping agents is observed during enzymic and nonenzymic peroxidation of microsomes as well as during the peroxidation of pure lipids extracted from microsomes. We now wish to report that purified fatty acid hydroperoxide alone, as well as peroxidized microsomal lipid and cumene hydroperoxide also form the singlet oxygen reaction product with 2,5-diphenylfuran. The reaction product (cis-1,2-dibenzoylethylene) was observed to be formed in an anaerobic system, with or without EDTA. The data indicate that a reaction of hydroxyl radicals with 2,5-diphenylfuran cannot account for the formation of dibenzoylethylene in these systems. These results are consistent with a hypothesis that the singlet oxygen-like factor was formed from the lipid peroxides per se and, in addition, supports the possibility that either the peroxides can react directly with diphenylfuran to produce dibenzoylethylene or that the self-reaction of organic peroxides may form an intermediate product which can react directly with singlet oxygen-trapping agents to produce substances which are identical to a reaction of the trapping agents with singlets oxygen.     

Isoprostanes and PGE2 production in human isolated pulmonary artery smooth muscle cells: concomitant and differential release.

The isoprostanes are a group of biologically active arachidonic acid metabolites initially thought to be formed under conditions of oxidative stress and independently of cyclooxygenase. However, recent studies have demonstrated isoprostane production under conditions in which cyclooxygenase is intentionally activated/induced. Here we describe for the first time formation of isoprostanes by human vascular cells via independent pathways of oxidative stress and cyclooxygenase induction. We compared the release of the isoprostane with that of the traditional prostaglandin, prostaglandin E2. Cyclooxygenase-2 induction was confirmed by Western blot. When cells were stimulated with cytokines, the release of isoprostanes was inhibited by the cyclooxygenase-1 and -2 inhibitor indomethacin as well by as the cyclooxygenase-2 selective inhibitor L-745,337. However, treatment of cells with the superoxide-producing enzyme xanthine oxidase also resulted in isoprostane release, which was not affected by cyclooxygenase inhibition, unlike PGE2 release under the same condition. Thus, two independent pathways relating to oxidative stress and cyclooxygenase-2 induction form isoprostanes. These findings may have particular importance in diseases such as sepsis and ARDS in which oxidant stress occurs and cyclooxygenase is induced.     

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.     

The effect of essential fatty acid deficiency on eicosanoid production in the inflamed rat colonic mucosa

Eicosanoids are potent mediators of inflammation and are synthesized in increased quantity in active ulcerative colitis. To elucidate the role of prostaglandin E2, thromboxane A2, prostaglandin I2, and leukotriene B2 in acute chemical colitis induced by 4% acetic acid, we utilized an animal model which has a deficiency of arachidonic acid, the precursor of eicosanoids due to an essential fatty acid deficient diet. Forty-eight hours after colitis was induced, mucosal synthesis of the cyclooxygenase products, prostaglandin E2, thromboxane A2, and prostaglandin I2, was significantly decreased in essential fatty acid deficient rats compared to normal controls. However, the 5-lipoxygenase product, leukotriene B4, was not different between groups. The decrease in cyclooxygenase products did not correlate with any change in the severity of colonic inflammation as assessed by gross morphology, histology, or myleoperoxidase activity. Thus inhibition of formation of the cyclooxygenase products of arachidonate metabolism does not appear to improve the degree of inflammation under the experimental conditions employed in this study.     

Role of prostaglandin endoperoxides in the serum thiobarbituric acid reaction

In the presence of heme and reduced glutathione, prostaglandin (PG) endoperoxides underwent rapid conversion to malondialdehyde and 12l-hydroxy-5,8,10-heptadecatrienoic acid. In addition, PG endoperoxides as well as lipid peroxides produced malondialdehyde to yield a red pigment during the thiobarbituric acid reaction with different efficiencies. The relative rates of the reaction were: 1,1,3,3-tetraethoxypropane, 100; PGG₂, 55; PGH₂, 32; and 15-hydroperoxyarachidonic acid, 6. The thiobarbituric acid reactive materials in rabbit serum decreased by 25–60%, after intravenous administration of aspirin (a cyclo-oxygenase inhibitor) and with a concomitant decline of serum PG levels. These results, taken together, suggested that serum thiobarbituric acid values, considered to be an indicator of lipid peroxide levels, were to a significant extent due to PG endoperoxides and their derivatives.     

Regulation of fibroblast cyclooxygenase synthesis by interleukin-1

We have prepared polyclonal antiserum against sheep seminal vesicle prostaglandin H synthase (also termed cyclooxygenase) which cross-reacted with human cyclooxygenase, thereby enabling us to directly determine the synthetic rate of cyclooxygenase protein and its modulation by the monokine interleukin-1 (IL-1). Cultured human dermal fibroblast cells were labeled with [35S]methionine, and the membrane-bound cyclooxygenase was solubilized and immunoprecipitated 35S-labeled fibroblast cyclooxygenase migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with a molecular size of approximately 73,000 daltons, similar to that of native sheep cyclooxygenase and of cyclooxygenase covalently labeled by [3H]aspirin, i.e. [3H]acetylcyclooxygenase. Additional validation of the immunoprecipitated 35S-labeled cyclooxygenase band indicated that it was specifically displaced by unlabeled sheep cyclooxygenase. N-terminal amino acid radiosequence analysis of [3H]proline-labeled cyclooxygenase revealed [3H]proline residues in positions 3, 6, and 8, consistent with the previously reported N-terminal sequence of sheep cyclooxygenase. Endoglycosidase H treatment of 35S-labeled fibroblast cyclooxygenase caused a decline in apparent molecular size (due to removal of mannose residues) which was similar to that seen with the native sheep cyclooxygenase. [35S]Methionine pulse-chase experiments indicated a half-life of 1 h for fibroblast cyclooxygenase. The monokine interleukin-1 stimulated fibroblast cyclooxygenase synthesis in a time- and dose-dependent fashion; as little as 0.03 unit/ml of IL-1 produced significant stimulation of 35S-labeled cyclooxygenase synthesis. Maximum stimulation was 3-10-fold after preincubation of the cells with 0.3 unit/ml of IL-1 for 12-16 h. IL-1 treatment of cells yielded parallel dose-response curves for stimulation of prostaglandin E2 formation, increased cellular cyclooxygenase activity, and increased synthetic rate of newly formed cyclooxygenase, suggesting that the IL-1 effect is mediated mainly, if not solely, via induction of cyclooxygenase synthesis.