Lipid peroxide makes rabbit platelet hyperaggregable to agonists through phospholipase A2 activation

Treatment of rabbit platelets with tert-butyl hydroperoxide and Fe2+ caused increasing arachidonic acid release, lysophosphatidylcholine formation, and aggregation with increasing concentrations of Fe2+. A combination of tert-butyl hydroperoxide and a low concentration of Fe2+, which by itself causes slight or no such activation, elicited synergistic release of arachidonic acid and aggregation under stimulation with a suboptimal concentration of collagen or arachidonic acid as an agonist. These responses were inhibited by pretreatment of the platelets with vitamin E or mepacrine in a concentration-dependent manner, but not by uric acid. The arachidonic acid release was dependent on the presence of Ca2+ in the medium. Synergistic formation of lysophosphatidylcholine, but not diacylglycerol, was also observed under this condition. The aggregation was also inhibited by indomethacin, a cyclooxygenase inhibitor. Cyclooxygenase activity was not affected by the oxidative treatment. These results suggest that lipid peroxide formed in membranes causes phospholipase A2 to become hypersusceptible to the agonist used, making the platelets hyperaggregable.     

Activation of phospholipase A2 and beta-thromboglobulin release in human platelets: comparative effects of thrombin and fluoroaluminate stimulation.

Several reports have suggested that the activity of platelet phospholipase A2 is modulated by GTP-binding protein(s) whose nature and properties need to be defined. Fluoroaluminate is known to activate G-proteins and this leads to a number of cellular responses including the activation of phospholipases. This paper demonstrates that human platelets, prelabelled with [3H]arachidonic acid, produce free arachidonic acid when stimulated with fluoroaluminate and this effect is time- and dose-dependent. The production of arachidonic acid is not inhibited by neomycin, a PI-cycle inhibitor, but is completely abolished by mepacrine, an inhibitor of both phospholipase A2 and C. At low concentration of fluoroaluminate (10 mM NaF) phospholipase A2 but not phospholipase C is activated. In addition, fluoroaluminate treatment releases beta-thromboglobulin (beta-TG) and this effect is not inhibited by acetylsalicylic acid. Under identical conditions both neomycin and mepacrine suppress the release of arachidonic acid and beta-TG induced by thrombin. Sodium nitroprusside, which increases cGMP levels in platelets, inhibits arachidonic acid liberation and beta-TG release in thrombin-stimulated platelets but has no effect in fluoroaluminate-treated platelets; cGMP was reported to suppress phospholipase C activation. These results are consistent with the hypothesis that, in thrombin-stimulated platelets, the liberation of arachidonic acid and beta-TG are strictly dependent on the activation of phospholipase C. We have also provided evidence for the existence of a phospholipase A2 activated by a G-protein which is independent from the degradation of phosphoinositides and, contrary to phospholipase C, it is not down regulated by cGMP.     

Biphasic effect on platelet aggregation by phospholipase a purified from Vipera russellii snake venom

A basic phospholipase A was isolated from Vipera russellii snake venom. It induced a biphasic effect on washed rabbit platelets suspended in Tyrode's solution. The first phase was a reversible aggregation which was dependent on stirring and extracellular calcium. The second phase was an inhibitory effect on platelet aggregation, occurring 5 min after the addition of the venom phospholipase A without stirring or after a recovery from the reversible aggregation. The aggregating phase could be inhibited by indomethacin, tetracaine, papaverine, creatine phosphate/creatine phosphokinase, mepacrine, verapamil, sodium nitroprusside, prostaglandin E1 or bovine serum albumin. The venom phospholipase A released free fatty acids from synthetic phosphatidylcholine and intact platelets. p-Bromophenacyl bromide-modified venom phospholipase A lost its phospholipase A enzymatic and platelet-aggregating activities, but protected platelets from the aggregation induced by the native enzyme. The second phase of the venom phospholipase A action showed a different degree of inhibition on platelet aggregation induced by some activators in following order: arachidonic acid greater than collagen greater than thrombin greater than ionophore A23187. The longer the incubation time or the higher the concentration of the venom phospholipase A, the more pronounced was the inhibitory effect. The venom phospholipase A did not affect the thrombin-induced release reaction which was caused by intracellular Ca2+ mobilization in the presence of EDTA, but inhibited collagen-induced release reaction which was caused by Ca2+ influx from extracellular medium. The inhibitory effect of the venom phospholipase A and also lysophosphatidylcholine or arachidonic acid could be antagonized or reversed by bovine serum albumin. It was concluded that the first stimulatory phase of the venom phospholipase A action might be due to arachidonate liberation from platelet membrane. The second phase of inhibition of platelet aggregation and the release of ATP might be due to the inhibitory action of the split products produced by this venom phospholipase A.     

Inhibition of platelet aggregation by unsaturated fatty acids through interference with a thromboxane-mediated process

cis- and trans-unsaturated fatty acids with 18 carbon atoms (oleic, linoleic, elaidic and linolelaidic acid) inhibited aggregation of washed rabbit platelets stimulated with collagen, arachidonic acid and U46619 when in the same concentration ranges. Thrombin-induced aggregation was not affected by any of them. Saturated fatty acid (stearic acid) had no effect on this response. The inhibition is independent of the induced change in membrane fluidity, since trans-isomers could not induce the change in fluorescence polarization of 1,6-diphenyl-1,3,5-hexatriene. Unsaturated fatty acids, except linoleic acid, did not interfere with the formation of thromboxane B2 from exogenously added arachidonic acid. All the unsaturated fatty acids only slightly inhibited the arachidonic acid liberation by phospholipase A2 in platelet lysate. This indicates that the unsaturated fatty acids may block a process after formation of thromboxane A2 in response to collagen and arachidonic acid. The increase in phosphatidic acid formation stimulated with U46619 was inhibited dose dependently by each of the unsaturated fatty acids but that stimulated with thrombin was not affected by any of them. Phospholipase C activity measured by diacylglycerol formation in unstimulated platelet lysate was not inhibited by the fatty acids. The elevation of cytosolic free Ca2+ induced by arachidonic acid or U46619 and Ca2+ influx by collagen were inhibited almost completely at the same concentration as that which inhibited their aggregation. These data suggest that the unsaturated fatty acids were intercalated into the membrane and inhibited collagen- and arachidonic acid-induced platelet aggregation by causing a significant suppression of the thromboxane A2-mediated increase in cytosolic free Ca2+, probably due to interference with the receptor-operated Ca2+ channel.     

Primary role of calcium ions in arachidonic acid release from rat platelet membranes. Comparison with human platelet membranes.

The liberation of arachidonic acid (AA) was investigated in platelet membranes prelabelled with [3H]AA. In rat platelet membranes, Ca2+ at concentrations over several hundred nanomolar induced [3H]AA release, with a concurrent decrease in 3H radioactivity of phosphatidylethanolamine and phosphatidylcholine. Some 4-6% of total radioactivity incorporated into platelet membrane lipids was released at 1-10 microM-Ca2+, which is nearly equivalent to that attained in agonist-stimulated platelets. Formation of lysophospholipids in [3H]glycerol-labelled membranes and decrease in [3H]AA liberated by the phospholipase A2 inhibitors mepacrine and ONO-RS-082 suggest that [3H]AA release is mainly catalysed by phospholipase A2. In intact platelets agonist-stimulated [3H]AA release was markedly decreased in the absence of extracellular Ca2+ or in the presence of the intracellular Ca2+ chelator quin 2. These results indicate that in rat platelets the rise of intracellular Ca2+ plays a primary role in the activation of phospholipase A2. In contrast, Ca2+ even at high millimolar concentrations did not effectively stimulate [3H]AA release in human platelet membranes. Thus factor(s) additional to or independent of Ca2+ is required for the liberation of AA in human platelets.     

Activation of phospholipases in platelets by polyclonal antibodies against a surface membrane protein.

In a previous paper we demonstrated using immunochemical techniques that propolypeptide of von Willebrand factor was present on the surface of resting platelets. In the present paper we show that polyclonal antibodies against propolypeptide of von Willebrand factor induce activation of phospholipase(s) in platelets and lead to platelet aggregation. The antibody-stimulation of platelets induced the synthesis of thromboxane A2 (TXA2). Furthermore, the aggregation was inhibited by aspirin and an antagonist of TXA2. Aspirin inhibited not only the aggregation but also the activation of arachidonic acid liberation from phospholipids, but the effect of aspirin on arachidonic acid liberation was cancelled by the combined effect of the antibodies and a TXA2 mimetic agonist, which itself did not activate arachidonic acid liberation. The antibody-induced activation of arachidonic acid liberation and the aggregation were blocked by cytochalasin B. All these results obtained with antibodies were quite similar to the results obtained with collagen.     

No direct correlation between Ca2+ mobilization and dissociation of Gi during platelet phospholipase A2 activation

Stimulation of human platelets with thrombin is accompanied by activation of both phospholipases C and A2. These have been considered to be sequential events, with phospholipase A2 activation resulting from the prior hydrolysis of inositol phospholipids and mobilization of intracellular Ca2+ stores. However, our and other laboratories have recently questioned this proposal, and we now present further evidence that these enzymes may be activated by separate mechanisms during thrombin stimulation. Alpha-thrombin induced the rapid hydrolysis of inositol phospholipids, and formation of inositol trisphosphate and phosphatidic acid. This was paralleled by mobilization of Ca2+ from internal stores. These responses were blocked by about 50% by prostacyclin. In contrast, the liberation of arachidonic acid induced by alpha-thrombin was totally inhibited by prostacyclin. The less-effective agonists, platelet activating factor (PAF) and gamma-thrombin also both stimulated phospholipase C, but whereas PAF evoked a rapid and transient response, that of gamma-thrombin was delayed and more sustained. The abilities of these agonists to induce the release of Ca2+ stores closely paralleled phospholipase C activation. However, the maximal intracellular Ca2+ concentrations achieved by these two agents were the same. Despite this, gamma-thrombin and not PAF, was able to release a small amount of arachidonic acid. When alpha-thrombin stimulation of platelets was preceded by epinephrine, there was a potentiation of phospholipase C activation, Ca2+ mobilization and aggregation. The same was true for gamma-thrombin and PAF. However, unlike alpha-thrombin, the gamma-thrombin-stimulated arachidonic acid release was not potentiated by epinephrine, but rather somewhat reduced. These results suggested that phospholipase C and phospholipase A2 were separable events in activated platelets. The mechanism by which alpha-thrombin stimulated phospholipase A2 did not appear to be through dissociation of the inhibitory GTP-binding protein, Gi, since gamma-thrombin decreased the pertussis toxin-induced ADP-ribosylation of the 41 kDa protein as much as did alpha-thrombin, but was a much less effective agent than alpha-thrombin at inducing arachidonic acid liberation.     

Mepacrine (quinacrine) inhibition of thrombin-induced platelet responses can be overcome by lysophosphatidic acid

Addition of thrombin to human platelets results in production of lysophosphatidic acid. Such synthesis of lysophosphatidic acid can be inhibited by mepacrine, an inhibitor of the phospholipase A2 which attacks phosphatidic acid to give lysophosphatidic acid. In the present study, mepacrine was used at a concentration of 2.5-20 microM, sufficient to block aggregation and lysophosphatidic acid formation induced by 0.1 U/ml thrombin. Mepacrine, at this concentration, also blocked thrombin-induced phosphorylation of platelet myosin light chain and a 47 kDa protein, thrombin-induced secretion and thrombin-induced release of arachidonic acid from platelet phospholipids. However, mepacrine also partly inhibited the formation of phosphatidic acid in response to thrombin, consistent with some simultaneous inhibition of phospholipase C. Lysophosphatidic acid (2.5-22 microM) overcame the mepacrine block in thrombin-stimulated aggregation, protein phosphorylation and secretion without stimulating the release of arachidonic acid from platelet phospholipids or the formation of lysophosphatidic acid, and only slightly increasing phosphatidic acid formation. The results suggest that lysophosphatidic acid primarily acts distal to mepacrine inhibition of phospholipase A2 and phospholipase C and are consistent with the possibility that lysophosphatidic acid might be a mediator of part of the effects of low-dose thrombin on human platelets.     

Platelet activation by tetraprenol via stimulation of phospholipase A2 action

Only tetraprenol (n = 4), among the (n)-polyprenols studied, induced activation of rabbit platelets. Tetraprenol-induced responses, including platelet aggregation, Ca2+ mobilization, inositol phosphate formation, and arachidonic acid release, were greatly inhibited by a thromboxane A2 (TXA2) receptor antagonist and a cyclooxygenase inhibitor, indicating an essential role for endogenously produced TXA2. The TXA2-mimetic agonist U46619 induced platelet aggregation, Ca2+ mobilization and phospholipase C action but did not induce arachidonic acid release. These results suggest that arachidonic acid is not released via phospholipase C but by phospholipase A2, and this is also supported by the finding that phospholipase C action was inhibited by depletion of extracellular Ca2+, while arachidonic acid release was not. Full arachidonic acid release was found to be induced by the synergistic action of U46619 and tetraprenol. Therefore, the initial, most essential response induced by tetraprenol is a small arachidonic acid release by phospholipase A2, which results in initial TXA2 formation. Further action of phospholipase C as well as Ca2+ mobilization and aggregation were induced by the initially formed TXA2 while further activation of phospholipase A2 required the synergistic action of tetraprenol and TXA2.     

Potential involvement of vicinal sulfhydryls in stimulus-induced rabbit platelet activation

The potential involvement of vicinal dithiols in the expression of platelet-activating factor (AGEPC)- and A23187-induced alterations in rabbit platelets was explored through the use of phenylarsine oxide (PhAsO) and certain analogous derivatives. PhAsO (As3+) but not phenylarsonic acid (As5+) inhibited markedly at 1 microM concentration the release of arachidonic acid initiated by AGEPC and the ionophore A23187. In contrast, AGEPC-induced phosphatidic acid formation, phosphorylation of 40- and 20-kDa proteins, and Ca2+ uptake from external medium were not inhibited substantially by 1 microM PhAsO. However, these latter metabolic responses to AGEPC were inhibited by PhAsO at higher doses (10 microM). AGEPC- and thrombin-induced platelet aggregation and serotonin secretion also were prevented by PhAsO. The IC50 value of PhAsO was 2.7 +/- 1.2 microM toward AGEPC (5 X 10(-10) M)-induced serotonin release. Further, ATP and cAMP levels in PhAsO-treated platelets were not changed from controls. Interestingly, addition of Ca2+ to platelet sonicates (prepared in EDTA) caused diacylglycerol production and free arachidonic acid formation, even in the presence of 133 microM PhAsO. This would suggest that in the intact platelets PhAsO acted indirectly on phospholipase A2 and/or phospholipase C activities. Finally, a dithiol compound, 2,3-dimercaptopropanol, reversed the inhibition of platelet aggregation and arachidonic acid release effected by PhAsO. On the other hand, a monothiol compound, 2-mercaptoethanol, was not effective in preventing or in reversing the action of PhAsO. These observations suggest that vicinal sulfhydryl residues may be involved in stimulus-induced platelet activation.     

Guanine nucleotides stimulate arachidonic acid release by phospholipase A2 in saponin-permeabilized human platelets

GTP or GTP gamma S alone caused low but significant liberation of arachidonic acid in saponin-permeabilized human platelets but not in intact platelets. GTP or GTP gamma S also enhanced thrombin-induced [3H]arachidonic acid release in permeabilized platelets. Inhibitors of the phospholipase C (neomycin)/diacylglycerol lipase (RHC 80267) pathway for arachidonate liberation did not reduce the [3H]arachidonic acid release. The loss of [3H]arachidonate radioactivity from phosphatidylcholine was almost equivalent to the increase in released [3H]arachidonic acid, suggesting the hydrolysis of phosphatidylcholine by phospholipase A2. The effect of GTP gamma S was greater at lower Ca2+ concentrations. These data indicate that the release of arachidonic acid by phospholipase A2 in saponin-treated platelets may be linked to a GTP-binding protein.     

Blockade of ADP-induced Ca2+-signal and platelet aggregation by lipoxygenase inhibitors

Stimulation of platelets results in the liberation of arachidonic acid (AA) which is further metabolized via the cyclooxygenase or lipoxygenase (LPG) pathway. We have examined the effect of inhibition of LPG on (i) the ADP-induced increase of cytoplasmic Ca2+ concentration and (ii) platelet aggregation. Lipoxygenase inhibitors, nordigidroguaiaretic acid (NDGA) and BW-755C, both suppressed ADP-induced Ca2+-signals and aggregation in a dose-dependent manner, with an IC50 value of 1 2 microM for NDGA. Qualitatively the same effect was obtained with 4-bromophenylacyl bromide, the inhibitor of phospholipases A2 and C. By contrast, cyclooxygenase inhibitor indomethacin had only a negligible effect on Ca2+-signals and suppressed only the second phase of ADP-induced aggregation. It is concluded that the LPG pathway of AA metabolism in platelets might play a crucial role in ADP-induced Ca2+-signal generation and platelet aggregation.     

High concentrations of exogenous arachidonate inhibit calcium mobilization in platelets by stimulation of adenylate cyclase.

1. Exposure of platelets to exogenous arachidonic acid results in aggregation and secretion, which are inhibited at high arachidonate concentrations. The mechanisms for this have not been elucidated fully. In our studies in platelet suspensions, peak aggregation and secretion occurred at 2-5 microM-sodium arachidonate, with complete inhibition around 25 microM. 2. In platelets loaded with quin2 or fura-2, the cytoplasmic Ca2+ concentration, [Ca2+]i, rose in the presence of 1 mM-CaCl2 from 60-80 nM to 300-500 nM at 2-5 microM-arachidonate, followed by inhibition to basal values at 25-50 microM. Thromboxane production was not inhibited at 25 microM-arachidonate. Cyclic AMP increased in the presence of theophylline, from 3.5 pmol/10(8) platelets in unexposed platelets to 8 pmol/10(8) platelets at 50 microM-arachidonate; all platelet responses were inhibited with doubling of cyclic AMP contents. 3. The adenylate cyclase inhibitor 2',5'-dideoxyadenosine attenuated the inhibitory effect of arachidonate, suggesting that it is mediated by increased platelet cyclic AMP and that it is unlikely to be due to irreversible damage to platelets. 4. Aspirin or the combined lipoxygenase/cyclo-oxygenase inhibitor BW 755C did not prevent the inhibition by arachidonate of either [Ca2+]i signals or aggregation induced by U46619. 5. Thus high arachidonate concentrations inhibit Ca2+ mobilization in platelets, and this is mediated by stimulation of adenylate cyclase. High arachidonate concentrations influence platelet responses by modulating intracellular concentrations of two key messenger molecules, cyclic AMP and Ca2+.     

Tumor promoter 12-O-tetradecanoylphorbol-13-acetate-induced insulin secretion: Inhibition by phospholipase A2- and lipoxygenase-inhibitors

In isolated pancreatic islets of rats, an insulin secretion was induced by a tumor promoter 12-o-tetradecanoylphorbol-13-acetate in a low glucose medium. The insulin secretion was inhibited by p-bromophenacyl bromide, mepacrine, nordihydroguaiaretic acid and 1-phenyl-3-pyrazolidinone but not by indomethacin. When the insulin secretion was suppressed by p-bromophenacyl bromide, the secretion was partially but not significantly restored by lysophosphatidyl choline and was fully restored by the simultaneous addition of arachidonic acid and lysophosphatidyl choline. These results suggest that activation of phospholipase A₂ and a lipoxygenase product(s) play important roles in the 12-o-tetradecanoylphorbol-13-acetate-induced insulin secretion.     

Stimulation of arachidonic acid metabolism via phospholipase A2 by triethyl lead

Human blood platelet aggregation and the formation of icosanoids were studied in response to triethyl lead chloride (Et3PbCl). Concentrations higher than 75 microM stimulate platelets to aggregate, whereas low concentrations (less than or equal to 20 microM) caused platelet hypersensitivity to aggregating agents such as collagen or arachidonic acid. Incubation of suspensions of washed platelets with Et3PbCl resulted in a stimulated liberation and subsequent metabolism of arachidonic acid. This response was dependent on the concentration of Et3PbCl and the incubation time. Using low concentrations of Et3PbCl and up to 3 h of incubation, the lipoxygenase product 12-hydroxy-5,8,10,14-icosatetraenoic acid was the major metabolite. Under normal conditions, however, stimulation of platelets with collagen, thrombin, or arachidonic acid leads to higher amounts of the cyclooxygenase products 12-hydroxy-5,8,10-heptadecatrienoic acid and thromboxane B2. The aggregation of human platelets induced by Et3PbCl was inhibited by three different drugs: acetylsalicylic acid, forskolin and quinacrine; but only quinacrine could prevent the liberation of arachidonic acid and the appearance of its metabolites. These specific effects of the inhibitors on Et3PbCl-stimulated platelets as well as the differences in the pattern of arachidonic acid metabolites and phosphatidic acid suggest a direct stimulatory action of Et3PbCl on platelet phospholipase A2.     

Carnitine inhibits arachidonic acid turnover,platelet function,and oxidative stress

Carnitine is a physiological cellular constituent that favors intracellular fatty acid transport, whose role on platelet function and O(2) free radicals has not been fully investigated. The aim of this study was to seek whether carnitine interferes with arachidonic acid metabolism and platelet function. Carnitine (10-50 microM) was able to dose dependently inhibit arachidonic acid incorporation into platelet phospholipids and agonist-induced arachidonic acid release. Incubation of platelets with carnitine dose dependently inhibited collagen-induced platelet aggregation, thromboxane A(2) formation, and Ca(2+) mobilization, without affecting phospholipase A(2) activation. Furthermore, carnitine inhibited platelet superoxide anion (O(2)(-)) formation elicited by arachidonic acid and collagen. To explore the underlying mechanism, arachidonic acid-stimulated platelets were incubated with NADPH. This study showed an enhanced platelet O(2)(-) formation, suggesting a role for NADPH oxidase in arachidonic acid-mediated platelet O(2)(-) production. Incubation of platelets with carnitine significantly reduced arachidonic acid-mediated NADPH oxidase activation. Moreover, the activation of protein kinase C was inhibited by 50 microM carnitine. This study shows that carnitine inhibits arachidonic acid accumulation into platelet phospholipids and in turn platelet function and arachidonic acid release elicited by platelet agonists.     

Activation of human platelet phospholipase C by ionophore A23187 is totally dependent upon cyclo-oxygenase products and ADP.

Human platelets exposed to the Ca2+ ionophore A23187 form cyclo-oxygenase metabolites from liberated arachidonic acid and secrete dense granule substituents such as ADP. I have shown previously that A23187 causes activation of phospholipase A2 and some stimulation of phospholipase C. I now report that, in contrast to the case for thrombin, the activation of phospholipase C in response to ionophore is completely dependent upon the formation of cyclo-oxygenase products and the presence of ADP. The addition of A23187 to human platelets induces a transient drop in the amount of phosphatidylinositol 4,5-bisphosphate, a decrease in the amount of phosphatidylinositol, and the formation of diacylglycerol and phosphatidic acid. In addition, lysophosphatidylinositol and free arachidonic acid are produced. The presence of cyclo-oxygenase inhibitors or agents which remove ADP partially impairs these changes. When both types of inhibitor are present, the changes in phosphatidylinositol 4,5-bisphosphate and the formation of diacylglycerol and phosphatidic acid are blocked entirely, whereas formation of lysophosphatidylinositol and free arachidonic acid are relatively unaffected. The prostaglandin H2 analogue U46619 activates phospholipase C. This stimulation is inhibited partially by competitors for ADP. I conclude that phospholipase C is not activated by Ca2+ in the platelet, and suggest that stimulation is totally dependent upon a receptor coupled event.     

Phospholipase A of Guinea Pig Spermatozoa: Its Preliminary Characterization and Possible Involvement in the Acrosome Reaction

Phospholipase A activity was demonstrated in guinea pig spermatozoa using [U-¹⁴C] phosphatidyl choline as a substrate. The activity had a neutral pH optimum, was stimulated by Ca²⁺ and low concentrations of detergent, and. was inhibited by EDTA, mepacrine and p-bromophenacyl bromide. Appropriate concentrations of mepacrine and p-bromophenacyl bromide inhibited the acrosome reactions of capacitated spermatozoa without interfering with their motility. These results support the notion that phospholipase A is involved in the acrosome reaction of mammalian spermatozoa.     

Possible involvement of cytoskeleton in collagen-stimulated activation of phospholipases in human platelets

The action of phospholipases A2 and C in the course of collagen-stimulated platelet activation and the effect of cytochalasins on the responses were studied. Stimulation of human platelets with collagen was accompanied by aggregation, Ca2+ mobilization, inositol phosphate formation, and arachidonic acid release. However, in the presence of a cyclooxygenase inhibitor or a thromboxane A2 (TXA2) receptor antagonist, collagen induced only weak arachidonic acid release and weak inositol phosphate formation. The TXA2 mimetic agonist U46619 induced all the responses except for arachidonic acid release, which was induced by synergistic action of collagen and U46619. The result that U46619 did not induce arachidonic acid release despite the activation of phospholipase C suggested that arachidonic acid was not released via phospholipase C but by phospholipase A2. These findings suggested that collagen initially induced weak activation of phospholipases A2 and C and that further activation of phospholipase C as well as Ca2+ mobilization and aggregation were induced by TXA2, whereas further activation of phospholipase A2 required the synergistic action of collagen and TXA2. Platelets pretreated with cytochalasins did not respond to collagen. Further analysis revealed that the initial activation of phospholipases A2 and C was specifically inhibited by cytochalasins, but the responses induced by U46619 or a synergistic action of collagen and U46619 were not inhibited. Therefore, we proposed that interaction of collagen receptor with actin filaments might have some roles in the collagen-induced initial activation of phospholipases.     

Stimulation of arachidonic acid release by guanine nucleotide in saponin-permeabilized neutrophils: evidence for involvement of GTP-binding protein in phospholipase A2 activation

Addition of a guanine nucleotide analog, guanosine 5'-O-(thiotriphosphate) (GTP gamma S)(1-100 microM) induced release of [3H]arachidonic acid from [3H]arachidonate-prelabeled rabbit neutrophils permeabilized with saponin. The chemotactic peptide N-formyl-methionyl-leucyl-phenylalanine (fMLP)-induced arachidonate release was enhanced by GTP gamma S, Ca2+, or their combination. Ca2+ alone (up to 100 microM) did not effectively stimulate lipid turnover. However, the combination of fMLP plus GTP gamma S elicited greater than additional effects in the presence of resting level of free Ca2+. The addition of 100 microM of GTP gamma S reduced the Ca2+ requirement for arachidonic acid liberation induced by fMLP. Pretreatment of neutrophils with pertussis toxin resulted in the abolition of arachidonate release and diacylglycerol formation. Neomycin (1 mM) caused no significant reduction of arachidonate release. In contrast, about 40% of GTP gamma S-induced arachidonate release was inhibited by a diacylglycerol lipase inhibitor, RHC 80267 (30 microM). These observations indicate that liberation of arachidonic acid is mediated by phospholipase A2 and also by phospholipase C/diacylglycerol lipase pathways. Fluoride, which bypasses the receptor and directly activates G proteins, induced arachidonic acid release and diacylglycerol formation. The fluoride-induced arachidonate release also appeared to be mediated by these two pathways. The loss of [3H]arachidonate was seen in phosphatidylinositol, phosphatidylcholine, and phosphatidylethanolamine. These data indicate that a G protein is involved between the binding of fMLP to its receptor and activation of phospholipase A2, and also that the arachidonic acid release is mediated by both phospholipase A2 and phospholipase C/diacylglycerol lipase.