Inhibitory action of soluble elastin on thromboxane B2 formation in blood platelets

Soluble elastin, prepared from insoluble elastin by treatment with oxalic acid or elastase, was found to inhibit the formation of thromboxane B₂ both from [1-¹⁴C]arachidonic acid added to washed platelets and from [1-¹⁴C]arachidonic acid in prelabeled platelets on stimulation with thrombin. In both systems, the formation of 12-hydroxy-5,8,10,14-eicosatetraenoic acid (12-HETE) was accelerated. Oxalic acid-treated soluble elastin st 1 and 10 mg/ml inhibited the formation of thromboxane B₂ from exogenously supplied arachidonic acid 21 and 59%, respectively, and the formation of thromboxane B₂ in prelabeled platelets stimulated by thrombin 44 and 94%, respectively. These concentrations of elastin increased the formation of 12-HETE from exogenously supplied arachidonic acid about 3.4- and 7.3-times, respectively. Almost all the added arachidonic acid was converted to metabolites. In prelabeled platelets, soluble elastin at 1 and 10 mg/ml increased the formation of 12-HETE stimulated by thrombin about 1.3- and 2.8-times, respectively, and inhibited the thrombin-induced total productions of thromboxane B₂ (12-hydroxy-5,8,10-heptadecatrienoic acid (12-HETE) and free arachidonic acid by 26 and 25%, respectively. Elastase-treated digested elastin also inhibited the formation of thromboxane B₂ and stimulated the formation of 12-HETE in prelabeled platelets stimulated by thrombin. This inhibitory action of elastin was not replaced by desmosine. The level of cAMP in platelets was not affected by soluble elastin. Soluble elastin was also found to inhibit platelet aggregation induced by thrombin. However, the inhibitory action of soluble elastin on platelet aggregation cannot be explained by inhibition of thromboxane B₂ formation by the elastin.     

Effect of ethinylestradiol on arachidonic acid incorporation, release, and conversion to prostaglandins in rabbit platelets

Intramuscular administration to female rabbits of 2 mg/kg ethinylestradiol every other day for 10 days increased the uptake and incorporation of [14C]arachidonic acid into platelet lipids, and increased the proportion of [14C]arachidonic acid released from platelets after stimulation by thrombin. The conversion of [14C]arachidonic acid to thromboxane B2 did not differ between the control and ethinylestradiol-treated groups. Thus, the results of this study indicate that the major site in the prostaglandin metabolic pathway influenced by estrogen is the incorporation and release of arachidonic acid in platelet phospholipids.     

Cyclic AMP and platelet prostaglandin synthesis

The present study has investigated the influence of agents which elevate intracellular levels of endogenous platelet adenosine 3′5′-cyclic monophosphate (cyclic AMP), and the effect of the exogenous cyclic AMP analog, dibutyryl cyclic AMP, on the conversion of ¹⁴C-arachidonic acid by washed platelets. Prostaglandin E₁ (PGE₁), PGE₁ with theophylline, or dibutyryl cyclic AMP incubated with washed platelets prevented arachidonic acid induced platelet aggregation, but had no effect on the conversion of arachidonic acid to 12L-hydroxy-5,8,10, 14-eicosatetraenoic acid (HETE), 12L-hydroxy-5,8,10 heptadecatrienoic acid (HHT), or thromboxane B₂. Ultrastructural studies of the platelet response revealed that agents acting directly or indirectly to increase the level of cyclic AMP inhibited the action of arachidonic acid on washed platelets and prevented internal platelet contraction as well as aggregation. The influence of PGE₁ with theophylline, and dibutyryl cyclic AMP on the thrombin induced release of ¹⁴C-arachidonic acid from platelet membrane phospholipids was also investigated. These agents were found to be potent inhibitors of the thrombin stimulated release of arachidonic acid from platelet phospholipids, due most likely to an inhibition of platelet phospholipase A activity. The results show that dibutyryl cyclic AMP and agents which elevate intracellular cyclic AMP levels act to inhibit platelet activation at two steps 1) internal contraction and 2) release of arachidonic acid from platelet phospholipids.     

Effect of essential polyunsaturated fatty acid modifications on prostaglandins production by MDCK canine kidney cells

Supplementation of growing MDCK canine kidney tubular epithelial cultures with linoleic acid produced a 3.6- to 4.9-fold increase in bradykinin-stimulated PGE₂ release as measured by radioimmunoassay. Under these conditions the cell phospholipids contained 3.9-times more linoleic acid and 5.6-times more arachidonic acid, with the inositol, ethanolamine and choline phosphoglycerie fractions becoming enriched in arachidonic acid. By contrast, supplementation with arachidonic acid did not enhance bradykinin-stimulated PGE₂ release even though the arachidonic acid content of the cell phospholipids was increased 8.8-fold. The distribution of radioactive prostaglandin products was unchanged by these fatty acid enrichments, with PGE₂ accounting for 55 to 68% of the total output from [1-¹⁴C]arachidonic acid. Linoleic acid supplementation also produced a 2.5-fold increase in PGE₂ formation stimulated by extracellular arachidonic acid, whereas supplementation during culture with arachidonic acid caused a 55 to 80% inhibition. This difference cannot be accounted for by changes in the ability of the cells to incorporate extracellular arachidonic acid. it is suggested that at least some of the effects of linoleate supplementation on prostaglandin production are due to the resulting enrichment of the intracellular phospholipid substrate pools with arachidonic acid. In addition, it appears that prolonged exposure to arachidonic acid during culture has an overriding inhibitory effect on prostaglandin production even though the total cell lipids bocome highly enriched in arachidonate.     

Effects of epoxymethano analogues of prostaglandin endoperoxides on aggregation,on release of 5-hydroxytryptamine and on the metabolism of 3′,5′-cyclic AMP and cyclic GMP in human platelets

The effects on human platelets of two synthetic analogues of prostaglandin endoperoxides were examined in order to explore the relationship between aggregation and prostaglandin and cyclic nucleotide metabolism, and to help elucidate the role of the natural endoperoxide intermediates in regulating platelet function.Both analogues (Compound I, (15S)-hydroxy-9α,11α-(epoxymethano)-prosta-(5Z,13E)-dienoic acid, and Compound II, (15S)-hydroxy-11α,9α-(epoxymethano)-prosta-(5Z,13E)-dienoic acid) caused platelets to aggregate, an effect which could be inhibited by prostaglandin E₁ but not by indomethacin. Compound II produced primary, reversible aggregation at concentrations which did not induce release of 5-hydroxytryptamine. Production of thromboxane B₂ and malonyldialdehyde was monitored as an index of endogenous production of prostaglandin endoperoxides and thromboxane A₂ and were increased after incubation of human platelets with thrombin, collagen or arachidonic acid. However, neither malonydialdehyde nor thromboxane B₂ levels were significantly influenced by the endoperoxide analogues. Both analogues produced a small elevation of adenylate cyclase activity in platelet membranes and of cyclic AMP content in intact platelets, but neither had any modifying effect on the much greater stimulation of adenylate cyclase and cyclic AMP levels by prostaglandin E₁. Of all the aggregating agents tested, only arachidonic acid produced any significant increase in platelet cyclic GMP levels.These results suggest that the epoxymethano analogues of prostaglandin endoperoxides induce platelet aggregation independently of thromboxane biosynthesis and without inhibiting adenylate cyclase or lowerin platelet cyclic AMP levels. They therefore differ from better known aggregating agents such as ADP, epinephrine and collagen, which increase thromboxane A₂ production and reduce cyclic AMP levels, at least in platelets previously exposed to prostaglandin E₁.     

Antiplatelet effects of clausine-D isolated from Clausena excavata

Clausine-D inhibited concentration-dependently the aggregation and release of washed rabbit platelets induced by arachidonic acid and collagen, without affecting those induced by U46619, PAF and thrombin. The IC₅₀ values of clausine-D on arachidonic acid-and collagen-induced platelet aggregation were calculated to be 9.0±1.1 and 58.9±0.9 μM, respectively. Thromboxane B₂ and prostaglandin D₂ formation in platelets caused by arachidonic acid were also suppressed. Clausine-D inhibited increased intracellular concentration of calcium in platelets caused by arachidonic acid and collagen, and also abolished the generation of inositol monophosphate caused by arachidonic acid, but not that by collagen U46619, PAF and thrombin. In human citrated platelet-rich plasma, clausine-D inhibited the secondary phase, but not the primary phase, of aggregation induced by epinephrine and ADP. These results indicate that the antiplatelet effect of clausine-D is due to inhibition of the formation of thromboxane A₂.     

Inhibition of thrombin-induced platelet arachidonic acid release by 15-hydroperoxy-arachidonic acid

Measuring platelet thromboxane B₂ biosynthesis by gas-liquid chromatography with capillary column, we found that 15-hydroperoxy-arachidonic acid (15-HPETE) abolished the above biosynthesis under thrombin stimulation but not from exogenous arachidonic acid. This fact indicates that 15-HPETE inhibits the release of arachidonic acid from platelet phospholipids. However, the hydroxy-derivative of 15-HPETE, called 15-HETE does not have this activity. In addition, 15-HPETE has no inhibiting effect on platelet phospholipase A₂ activity. Since, it has been previously published that 15-HPETE inhibits platelet diglyceride lipase, we conclude that the phosphatidylinositol specific phospholipase C-diglyceride lipase pathway could be essential in providing arachidonic acid from phospholipids, at least under low doses of thrombin.     

Synthesis of thromboxane A2 by non-aggregating dog platelets challenged with arachidonic acid or with prostaglandin H2

Dog platelets challenged with arachidonic acid fail to aggregate but synthesize a substance which aggregates rabbit and human platelets, this aggregation being suppressed by dibutyryl cyclic AMP. The aggregating substance contracts strips of rabbit aorta and of coeliac and mesenteric arteries, is soluble in diethyl ether, has a half-life of about 40 seconds at 37°C and of 100 seconds at 22°C. Its generation is blocked by various inhibitors of prostaglandin biosynthesis. The thromboxane A₂ synthetase inhibitor imidazole and its analogue benzimidazolamine also suppress generation of vessel contracting activity in incubates of dog platelets and prostaglandin H₂. Since dog platelets also transform prostaglandin H₂ into thromboxane A₂ their failure to aggregate, when stimulated by arachidonic acid or by prostaglandin H₂, is not due to lack of thromboxane synthesizing ability.     

Dietary n-9, n-6, and n-3 fatty acids modify linoleic acid more than arachidonic acid levels in plasma and platelet lipids and minimally affect platelet thromboxane formation in the rabbit

We have studied the effects of semisynthetic diets containing 5% by weight (12% of the energy) of either olive oil (70% oleic acid, OA) or corn oil (58% linoleic acid), or fish oil (Max EPA, containing about 30% eicosapentaenoic, EPA C 20:5 n-3, plus docosahexaenoic, DHA C 22:6 n-3, acids, and less than 2% linoleic acid), fed to male rabbits for a period of five weeks, on plasma and platelet fatty acids and platelet thromboxane formation. Aim of the study was to quantitate the absolute changes of n-6 and n-3 fatty acid levels in plasma and platelet lipid pools after dietary manipulations and to correlate the effects on eicosanoid-precursor fatty acids with those on platelet thromboxane formation. The major differences were found when comparing the group fed fish oil and depleted linoleic acid vs the other groups. The accumulation of n-3 fatty acids in various lipid classes was associated with modifications in the distribution of linoleic acid and arachidonic acid in different lipid pools. In platelets maximal incorporation of n-3 fatty acids occurred in phosphatidyl ethanolamine, which also participated in most of the total arachidonic acid reduction occurring in platelets, and linoleic acid, more than archidonic acid, was replaced by n-3 fatty acids in various phospholipids. The archidonic acid content of phosphatidyl choline was unaffected and that of phosphatidyl inositol only marginally reduced. Thromboxane formation by thrombin stimulated platelets did not differ among the three groups, and this may be related to the minimal changes of arachidonic acid in phosphatidyl choline and phosphatidyl inositol.     

High concentrations of arachidonic acid induce platelet aggregation and serotonin release independent of prostagladin endoperoxides and thromboxane A2

We examined platelet aggregation and serotonin release, induced by less than 60 μM arachidonic acid, using washed platelet suspensions in the absense of albumin. The concentration of arachidonic acid use did not cause platelet lysis. Platelet responses induced by less than 20 μM arachidonic acid were inhibited by aspirin, whereas those induced by above 30 μM arachidonic acid were not inhibited, even by both aspirin and 5,8,11,14-eicosatetraynoic acid. Although phosphatidic acid and 1,2-diacylglcerol increased after the addition of arachidonic acid in aspirin-treated platelets, the amounts were not parallel to platelet aggregation. Oleic, linoleic and linolenic acids also induced platelet responses, while palmitic, stearic and arachidic acids did not. EDTA, dibutyryl cyclic AMP, apyrase and creatine phosphate / creatin phosphokinase brought about almost the same effects in platelet responses induced by the unsaturated fatty acids, other than arachodinic acid, as those induced by 40 μM arachodonic acid. These results suggest that the mechanism of the actions of more than 30 μM arachodinic acid on platelets is the same as that of the other unsaturated fatty acids and is independent of prostaglandin endoperoxides, thromboxane A₂ and, perhaps, phosphatidic acid and 1,2-diacylglycerol.     

Reversal of platelet aggregation by aortic microsomes

The microsomal fraction of dog aortas inhibited human platelet aggregation induced by arachidonic acid, ADP, or thrombin. When aortic microsomes were added to a preparation of irreversibly aggregated platelets, the aggregates dispersed after 4–6 minutes. The fact that aortic microsomes inhibit platelet aggregation induced by ADP suggests that its effect is probably on the cellular function of platelets and not in direct competition against thromboxane A₂.     

Inhibition of PGE1-stimulated cAMP accumulation in human platelets by thromboxane A2

The prostaglandin endoperoxide PGH₂, HHT, HETE, thromboxane A₂, and thromboxane B₂, which are all products of arachidonic acid metabolites of human platelets, were tested for their ability to modulate platelet cyclic nucleotide levels. None of the compounds tested altered the basal level of cAMP or cGMP, and only PGH₂ and thromboxane A₂ inhibited PGE₁-stimulated cAMP accumulation. Thromboxane A₂ was found to be a more potent inhibitor of PGE₁-stimulated cAMP accumulation and inducer of platelet aggregation thatn PHG₂.     

Kinetic studies on the conversion of prostaglandin endoperoxide PGH2 by thromboxane synthase

We have investigated the time course of formation of thromboxane A₂, thromboxane B₂, and the C-17 hydroxy fatty acid, HHT, from arachidonic acid in a washed human platelet suspension. Our results indicate that HHT is not a breakdown product of thromboxane A₂, but rather thromboxane A₂ decomposes exclusively into thromboxane B₂. The kinetics of formation of thromboxane B₂ from the endoperoxide prostaglandin H₂ in human platelet microsomes was examined. Our data suggest that a bimolecular reaction is involved in the formation of thromboxane A₂ from prostaglandin H₂ and that thromboxane synthase is not an isomerase, but may be acting via a dismutase-type reaction. One possibility is that thromboxane and HHT are produced simultaneously from two molecules of prostaglandin H₂.     

Effect of docosahexaenoic acid (DHA) on arachidonic acid metabolism and platelet function

Studies from our laboratory have suggested a role for ferrous iron in the metabolism of arachidonic acid and demonstrated that inhibitors of prostaglandin synthesis exert their effect by complexing with the heme group of cyclooxygenase. Docosahexaenoic acid (DHA) is a potent competitive inhibitor of arachidonic acid metabolism by sheep vesicular gland prostaglandin synthetase. In this study we have evaluated the effect of exogenously added DHA on platelet function and arachidonic acid metabolism. DHA at 150 microM concentration inhibited aggregation of platelets to 450 microM arachidonic acid. At this concentration DHA also inhibited the second wave of the platelet response to the action of agonists such as epinephrine, adenosine diphosphate and thrombin. Inhibition induced by this fatty acid could be overcome by the agonists at higher concentrations. DHA inhibited the conversion of labeled arachidonic acid to thromboxane by intact, washed platelet suspensions. However, platelets in plasma incubated first with DHA then washed and stirred with labeled arachidonate generated as much thromboxane as control platelets. These results suggest that the polyenoic acids, if released in sufficient quantities in the vicinity of cyclooxygenase, could effectively compete for the heme site and inhibit the conversion of arachidonic acid.     

A comparison of imidazole and 9,11-azoprosta-5,13-dienoic acid Two selective thromboxane synthetase inhibitors

Two selective thromboxane A₂ synthetase inhibitors, imidazole and 9,11-azoprosta-5,13-dienoic acid (azo analog I) were compared to determine their effects on the quantitative formation of thromboxane B₂ and prostaglandin E₂ accompanying human platelet aggregation. Azo analog I was at least 200 times more potent, on a molar basis, than imidazole in suppressing thromboxane B₂ formation in either platelet-rich plasma or washed platelet suspensions aggregated with arachidonic acid or prostaglandin H₂. The inhibitors differed in their effect on the aggregation response itself. Azo analog I selectively suppressed thromboxane A₂ formation with an accompanying, parallel, suppression of the platelet aggregation.Imidazole selectively suppressed thromboxane A₂ formation, but only suppressed the accompanying aggregation in platelet rich plasma, and not washed platelet suspensions. The results indicate that azo analog I functions by competitive inhibition of prostaglandin H₂ on the thromboxane synthetase, and that imidazole, while it suppresses thromboxane A₂ formation, may have an associated agonist activity that enhances platelet aggregation. The data presented support this hypothesis, and they emphasize the importance of thromboxane A₂ in arachidonate mediated platelet aggregation.     

Control of prostanoid synthesis: Role of reincorporation of released precursor fatty acids

Prostanoid synthesis is limited by the availability of free arachidonic acid. This polyunsaturated fatty acid is liberated by phospholipases and usually is an intermediate of the deacylation-reacylation cycle of membrane phospholipids. In rat peritoneal macrophages, ethylmercurisalicylate (merthiolate) or N-ethylmaleimide (NEM) dose dependently inhibited the incorporation of arachidonic acid into cellular phospholipids, at lower concentrations specifically into phosphatidylcholine. Furthermore, merthiolate could be shown to be a rather selective inhibitor of lysophosphatidylcholine acyltransferase. In contrast, phospholipase A₂ activity was not affected over a wide dose range. Consequently, macrophages showed a large increase in prostanoid synthesis (prostaglandin E, prostacyclin and thromboxane) in the presence of both lysophosphatide acyltransferase inhibiting agents. Similar results were obtained with human platelets, in which merthiolate increased the release of thromboxane. Addition of free arachidonic acid also enhanced prostanoid synthesis in macrophages. At optimal concentrations, merthiolate had no further augmenting effect. It is concluded that the rate of prostanoid synthesis is not only controlled by phospholipase A₂ activity, but rather by the activity of the reacylating enzymes, mainly lysophosphatide acyltransferase.     

Manipulation of platelet aggregation by prostaglandins and their fatty acid precursors: Pharmacological basis for a therapeutic approach

Addition of the one-, two- or three- series endoperoxide to human platelet-rich plasma tend to supress aggregation, through the action of their respective non-enzymatic breakdown products PGE₁, PGD₂, or PGD₃ all of which elevate cyclic AMP levels. On the other hand, these stable primary products do not arise in appreciable amounts from intrinsic endoperoxides generated from either endogenous or exogenous free fatty acids. 5,8,11,14,17-Eicosapentaenoic acid (EPA) suppresses arachidonic acid (5,8,11,14-eicosatetraenoic acid) conversion by cycloogygenase (as well as lipoxygenase) to aggregatory metabolites in platelets. Exogenously added EPA was capable of inhibiting PRP aggregation induced either by exogenous or endogenous (released by ADP or collagen) arachidonate. The hypothetical combination of an EPA-rich diet and a thromboxane synthetase inhibitor might abolish production of the pro-aggregatory species, thromboxane A₂, and enhance formation of the anti-aggregatory metabolite, prostacyclin.Whereas EPA is not detectably metabolized by platelets, dihomo-γ-linolenic acid (8,11,14,-eicosatrienoic acid) is primariley converted by cyclooxygenase and thromboxane synthetase into the inactive metabolite, 12-hydroxyheptadecadienoic (HHD) acid. Pretreatment of human platelet suspensions with the thromboxane synthetase inhibitor imidazole unmasks the aggregatory property of PGH₁ and DLL which was partially compromised by the PGE₁ formed. The combination of the thromboxane synthetase inhibitor and an adenylate cyclase inhibitor unmasks a complete irreversible aggregation by DLL or PGH₁. The basis of a dietary strategy that replaces AA with DLL must rely on the production by the platelet of an inactive metabolite (HHD) rather than thromboxane A₂.     

Vitamin E exerts antiaggregatory effects without inhibiting the enzymes of the arachidonic acid cascade in platelets

Vitamin E (α-tocopherol) and tocopherol acetate produced a slightly increased amount of thromboxane in treated compared to untreated platelets. In tocopherol acetate-treated platelets significantly more lipoxygenase products were produced. α-tocopherol induced an increased, but not significant, production of thromboxane B₂ during blood clotting. α-tocopherol was not found to affect platelet phospholipase activity as determined by its effect on the release of labelled arachidonic acid from platelet phospholipids by challenging the platelets with calcium ionophore A23,187. α-tocopherol potentiated the incorporation of labelled arachidonate in the platelet phospholipids. Inspite of having no effect on the arachidonic acid cascade in platelets, α-tocopherol inhibited aggregation induced by several aggregating agents including A23,187. Inhibition of aggregation may be explained by the ability of α-tocopherol to inhibit intracellular mobilization of sequestered calcium from the dense tubular system to the cytoplasm.     

Inhibiton of platelet aggregation by 1-alkylimidazole derivatives,thromboxane a synthethase inhibitors

1-Alkylimidazole derivatives of various sidechain lengths with various functional groups at the terminal end of the alkychain inhibited the synthesis of thromboxane A₂ from arachidonic acid by rabbit platelets and the conversion of prostaglandin H₂ to thromboxane A₂ by the microsomes of rabbit platelets. These enzyme inhinitors were anti-aggregatory as examine with rabbit and human platelet-rich plasma under various experimental conditions.