Arachidonic acid causes lysis of human platelets in an artificial medium: Protection by plasma

Addition of 1 or 2 mM of arachidonic acid (AA) to a washed platelet suspension (WPS) resulted in an instantaneous rise of light transmission (LT) in the platelet aggregometer. The LT curves showed no evidence of shape change patterns and the recording pen showed no fluctuations. This rise of LT was not affected by the absence of CaCl₂, or the presence of PGI₂ or ASA. However, LT curves, showing shape change patterns and with pen fluctuations, were obtained when plasma, serum or albumin was included in the test system. These latter form of LT curves were also obtained in WPS samples exposed to lower concentrations of AA. Electron microscopic examination of these samples revealed varying degrees of lysis of every platelet in WPS exposed to 1 mM of AA. Numerous lyzed platelets were also found in samples either exposed to 0.5 mM of AA in the absence of added plasma, serum or albumin, or exposed to 1mM of AA in the presence of 5% of added plasma or 2.5 mg/ml albumin. The LT curves of these samples showed shape change patterns and pen fluctuations. These results indicate a pitfall of relying on platelet aggregometry alone in the study of certain AA-induced responses of washed platelets.     

Effect of low doses of ethanol on platelet function in long-life abstainers and moderate-wine drinkers

In vitro, high concentrations of ethanol (EtOH) reduce platelet aggregation. Less is known about the effect of low EtOH doses on platelet function in a selected human population of long-life abstainers and low moderate-wine drinkers to avoid rebound effect of EtOH on platelet aggregation. Results of our experiments suggest that moderate-wine drinkers have higher levels of high density lipoprotein (HDL) than long-life abstainers while fibrinogen levels are unchanged. Furthermore, platelets obtained from these individuals do not differ in their response when stimulated by agonists such as AA and collagen. The effect of in vitro exposure of low doses of EtOH has been studied in PRP and in washed platelets. EtOH (0.1-10 mM) inhibits platelet aggregation induced by collagen at its ED50 while is ineffective when aggregation was triggered by U-46619 and by 1 microM adenosine diphosphate (ADP). 5-10 mM EtOH partially reduces the second wave of aggregation induced by 3 microM ADP. 0.1-10 mM EtOH dose-dependently lowers the aggregation induced by AA at its ED50 but it is less effective at ED75 of AA. The antiaggregating effect of EtOH on aggregation induced by AA is unchanged by inhibitor of nitric oxide synthase. In addition, 10 mM EtOH reduces thromboxane (Tx) formation. In washed platelets, 1-10 mM EtOH partially inhibits platelet aggregation induced by thrombin. In washed resting platelets, 10 mM EtOH does not change the resting [Ca++]i while significantly reduces the increase in [Ca++]i triggered by AA. The results of ex vivo experiments have demonstrated that wine increases the HDL. However, this observation may or may not influence the response of platelets to agonists. Results of our studies demonstrate that low doses of alcohol reduces platelet function.     

Plasma protein regulation of platelet function and metabolism

Summary This reviews summarizes our evidence suggesting that the plasma protein environment influences platelet aggregation potential and metabolic activity.Cationic proteins are capable of restoring the aggregation potential of washed human platelets. The aggregation restoring effect of gamma globulin is inhibited by more anionic proteins in subfractions of Cohn fraction IV and fractions V and VI. Artificial enhancement of the net negative charge of plasma proteins through acylation produces derivatives capable of inhibiting platelet aggregation in platelet rich plasma.The oxygen consumption of washed human platelets is lower than in platelet rich plasma while the lactate production is identical. Autologous plasma, albumin or IgG immunoglobulin restores the oxygen consumption of washed platelets to values comparable to those obtained for platelet rich plasma, while the lactate production is unaffected. Fibrinogen or IgA myeloma protein increases the lactate production, but not the oxygen consumption. Cyclic AMP levels are considerably lower in washed platelets than in platelet rich plasma. Gamma globulin and albumin causes a further decrease, which is progressive with time. Fibrinogen causes no change in platelet cyclic AMP content.It is suggested that these observations may in part be explained by the equilibrium between anionic and cationic proteins in the platelet microenvironment.This hypothesis appears applicable in certain clinical situations.     

Characterization of the biosynthetic pathway of prostaglandin D2 in human platelet-rich plasma

The biosynthetic mechanism of prostaglandin D2 in human platelet-rich plasma has been investigated. Platelet-rich plasma was separated into washed platelets and platelet-poor plasma, and [1-14C]prostaglandin H2 was incubated with each fraction. The enzymatic conversion of the endoperoxide to prostaglandin D2 was found only in platelet-poor plasma and not in washed platelets or platelet lysate. This prostaglandin D synthetase activity was purified to homogeneity and identified as serum albumin by sodium dodecyl sulfate polyacrylamide gel electrophoresis, isoelectric focusing, and immunoelectrophoresis. The optimal pH and Km value for prostaglandin H2 were 9.0 and 6 microM, respectively. Glutathione was not required for the activity. Although prostaglandin H2 ws converted to prostaglandin D2 and E2 in the reaction, only the prostaglandin D2 formation was dependent on the protein amount and abolished by prior boiling. The action of this activity under physiological conditions was examined in a model system constituted of serum albumin and washed platelets. Prostaglandin D2 formation was observed in association with thrombin-evoked platelet aggregation in this system and was proportional to the number of platelets and the concentration of serum albumin, suggesting that thrombin-stimulated platelets released prostaglandin H2, and the latter compound was then converted to prostaglandin D2 by the action of serum albumin. Consistent with this interpretation, prostaglandin H2 added to platelet-rich plasma was converted in part to prostaglandin D2, and the aggregation caused by this endoperoxide was greatly enhanced by neutralizing the action of prostaglandin D2 with anti-prostaglandin D2 antiserum.     

In vitro effect of trichosanic acid, a major component of Trichosanthes japonica on platelet aggregation and arachidonic acid metabolism in human platelets

The in vitro effect of trichosanic acid (TCA; C18:3, omega-5), a major component of Trichosanthes japonica, on platelet aggregation and arachidonic acid (AA) metabolism in human platelets was studied. TCA dose-dependently suppressed platelet aggregation of platelet rich plasma and washed platelets. TCA decreased collagen (50 micrograms/ml)-stimulated production of thromboxane B2 (TXB2) and 12-hydroxyhepta-decatrienoic acid (HHT) in a dose-dependent manner, while that of 12-hydroxyeicosatetraenoic acid (12-HETE) was rather enhanced. The conversion of exogenously added [14C]AA to [14C]TXB2 and [14C]HHT in washed platelets was dose-dependently reduced by the addition of TCA, while that to [14C]12-HETE was increased. Similar observations were obtained when linolenic acid (LNA; C18:3, omega-3) was used. These results suggest that TCA may decrease TXA2 formation in platelets, probably due to the inhibition of cyclooxygenase pathway, and thereby reduce platelet aggregation.     

Neomycin inhibits inositol phosphate formation in human platelets stimulated by thrombin but not other agonists

Neomycin (0.1-1 mM) added to human platelet-rich plasma or washed platelets prelabeled with [3H]inositol inhibits aggregation, ATP secretion (ID50 0.2 mM) and formation of [3H]inositol mono-, bis- and trisphosphate (ID50 0.6-0.8 mM) in response to thrombin (0.25 U/ml). The production of inositol phosphates in response to other platelet agonists (vasopressin, platelet activating factor, prostaglandin endoperoxide analogs and collagen) is not inhibited by neomycin, even at a concentration of 2 mM. At this concentration neomycin reduces the secretion of ATP stimulated by these agents (by up to 50%). The results indicate that neomycin has multiple effects on platelets that are unrelated to a specific inhibition of inositol phospholipid degradation by phospholipase C. Low concentrations (0.1-1 mM) of neomycin might selectively inhibit the interaction of thrombin with the platelet surface, and high concentrations (greater than 2 mM) might unspecifically reduce platelet secretion in response to various platelet agonists.     

Protection by plasma proteins against condensed tannin-mediated platelet activation

Condensed tannins isolated from cotton bracts are potent platelet agonists. They promote the secretion of 5-hydroxytryptamine from washed bovine platelets with an EC50 of 35 micrograms/ml. However, when platelet-rich plasma was used in lieu of washed platelets, the potency of tannin was decreased over 50-fold. Reconstitution experiments demonstrated that some component in the plasma was responsible for the diminished potency of tannin. Fractionation of platelet-poor plasma suggested that albumin may be the inhibitory plasma component. Confirmation of this hypothesis was obtained from the finding that purified serum albumin at physiologic concentrations inhibited the tannin-mediated release of platelet 5-HT by more than 70%. These data suggest that any activation of platelets which may occur in vivo by the tannins present in inhaled cotton dust would require higher tannin concentrations than would have been predicted from our previous studies using washed platelets.     

Dihomogammalinolenic acid, but not eicosapentaenoic acid, activates washed human platelets

Dihomogammalinolenic acid (2.5-20 microM) added to suspensions of washed human platelets induces platelet shape change and the formation of 1,2-diacylglycerol and phosphatidic acid, indicating the activation of phospholipase C. It also stimulates the phosphorylation of a 40 kDa protein, indicating the activation of protein kinase C. Dihomogammalinolenic acid is converted mainly to 12-hydroxyheptadecadienoic acid and to a smaller extent to prostaglandin E1 and thromboxane B1. Small quantities of the lipoxygenase product 12-hydroxyeicosatrienoic acid are also observed. Indomethacin, by blocking platelet cyclooxygenase, prevents the activation of phospholipase C, protein kinase C, and platelet shape change induced by dihomogammalinolenic acid. Compound UK 38485, a specific thromboxane synthetase inhibitor, does not block platelet activation induced by dihomogammalinolenic acid. The results indicate that endoperoxides derived from dihomogammalinolenic acid, such as prostaglandin G1 or prostaglandin H1, may be responsible for the stimulation of phospholipase C and protein kinase C, and for the induction of platelet shape change. Eicosapentaenoic acid does not activate platelets and is poorly metabolized by platelet cyclooxygenase and lipoxygenase. Eicosapentaenoic acid is a better inhibitor of platelet activation induced by various agonists in washed platelets than dihomogammalinolenic acid. Eicosapentaenoic acid and dihomogammalinolenic acid are, however, equally effective in inhibiting aggregation induced by collagen in platelet-rich plasma. We suggest that eicosapentaenoic acid might be a better antithrombotic agent than dihomogammalinolenic acid.     

Localization of fibrinogen during ADP- or thrombin-induced aggregation of washed rabbit platelets

In contrast to human platelets, which aggregate poorly in response to ADP unless fibrinogen is present in the external medium, washed rabbit platelets form large aggregates in response to ADP without fibrinogen in the suspending medium. Addition of fibrinogen to the suspending medium of rabbit platelets frequently has little or no effect on the extent of ADP-induced platelet aggregation. We examined washed rabbit platelets by immunocytochemistry during ADP-induced aggregation and deaggregation and during thrombin-induced aggregation when the external medium did not contain added fibrinogen to determine if (a) fibrinogen was expressed on the surface of rabbit platelets that could support aggregation when the platelets were stimulated, or (b) fibrinogen secreted from the alpha granules supports platelet aggregation. Glutaraldehyde-fixed samples were prepared at different times after addition of ADP or thrombin, embedded in Lowicryl K4M, sectioned, incubated with sheep anti-rabbit fibrinogen, washed, reacted with gold-labeled anti-sheep IgG, and prepared for electron microscopy. The alpha granules of rabbit platelets were heavily labeled with immunogold; the platelet membrane was not labeled. During platelet aggregation and deaggregation in response to ADP, fibrinogen was not detectable on the platelet surface. In response to thrombin, large aggregates formed before fibrinogen was secreted from the alpha granules; fibrinogen was detectable focally at sites of granule discharge by 30-60 sec and fibrin formed by 3 min. Therefore, stimulated washed rabbit platelets can adhere to each other without large amounts of fibrinogen taking part in the close platelet-to-platelet contact, since aggregation occurs before detectable secretion, and large areas where the platelets are in contact are devoid of fibrinogen between the adherent membranes. Adhesion mechanisms not involving fibrinogen may support the aggregation of washed rabbit platelets.     

Studies of the mechanism of the human platelet release reaction induced by immunologic stimuli. III. Relationship between the binding of soluble IgG aggregates to the Fc receptor and cell response in the presence and absence of plasma

Aggregated IgG coupled covalently with bis-diazobenzidine (BDB-IgG) and labeled with 3H-diazobenzene (3H-BDB-IgG) has been used to study the binding of soluble IgG aggregates to human platelets in relationship to the release of the contents of intracellular granules (e.g., serotonin). In washed cell suspensions a minimum of 0.14 to 0.2 mug 3H-BDB-IgG per 5 X 10(8) platelets (40 to 70 aggregates per cell) was required for the triggering of the release reaction and cell aggregation. Binding was independent of divalent cations. The Arrhenius plot gave a straight line between 0 to 37 degrees C and a Q10 of 1.6. Neither inhibitors of the release reaction nor energy metabolism, nor formaldehyde fixation of the platelets affected binding. Bound 3H-BDB-IgG was not significantly eluted by IgG, bovine albumin (BSA), buffer, or plasma. Binding to washed platelets was more strongly inhibited by human IgG than by F(ab')2, bovine IgG, human albumin (HSA), or BSA. Plasma was an even more effective inhibitor of both binding and release. Plasma deficient in IgG or depleted of complement retained its inhibitory capacity. In the presence of plasma, at physiologic ratios of plasma and platelets, no release of serotonin was observed. Binding, although inhibited in rate, nevertheless occurred. It was enhanced by divalent cation chelation and had a Q10 of 2.5. The release reaction of washed platelets to which 3H-BDB-IgG had been bound in the presence of HSA or BSA was also inhibited by the subsequent addition of plasma or plasma proteins (human IgG being more effective than bovine IgG, F(ab')2, HSA, or BSA). 3H-BDB-IgG bound in the presence of either plasma or human IgG did not induce release when the platelets were subsequently suspended in media lacking these proteins. Thus, it appears that the platelet Fc receptor binds 3H-BDB-IgG by a process which is effectively inhibited by plasma, or by free IgG with an intact Fc, and to some extent by high concentrations of other proteins. The effects of bound IgG aggregates are dependent on the other proteins present both during binding and subsequently added. The mechanism of such receptor modulation and its implications in vivo are discussed.     

Recycling of platelet phosphorylation and cytoskeletal assembly

The shape change and aggregation of washed platelets induced by 10 microM arachidonic acid (AA) can be reversed by 20 ng/ml prostacyclin (PGI2), but these platelets can be reactivated by treatment with 30 microM epinephrine and subsequent addition of 10 microM AA mixture. These events may be modulated by cAMP since 2 mM dibutyryl cAMP also reversed activation without reactivation by epinephrine and AA. We examined protein phosphorylation and formation of cytoskeletal cores resistant to 1% Triton X-100 extraction of these platelets and correlated these processes with aggregation, fibrinogen binding, and changes in ultrastructure. Unactivated platelet cores contained less than 15% of the total actin and no detectable myosin or actin-binding protein. AA-induced cytoskeletal cores, which contained 60-80% of the total actin, myosin, and actin-binding protein as the major components, were disassembled back to unactivated levels by PGI2 and then fully reassembled by epinephrine and AA. Phosphorylation of myosin light chain and a 40,000-dalton protein triggered by AA (two- to fivefold) was reversed to basal levels by PGI2 but was completely restored to peak levels upon addition of the epinephrine and AA mixture. The reversibility of actin-binding protein phosphorylation could not be established clearly because both PGI2 and dibutyryl cAMP caused its phosphorylation independent of activation. With this possible exception, cytoskeletal assembly with associated protein phosphorylation, aggregation, fibrinogen binding, and changes in ultrastructure triggered by activation are readily and concertedly recyclable.     

Lanthanum stimulates the accumulation of cyclic AMP and inhibits secretion and thromboxane B2 formation in human platelets

La3+ was found to inhibit the secretion of 5-hydroxytryptamine and the production of thromboxane B2 by washed platelets exposed to collagen or thrombin. In addition, La3+ inhibited secretion in response to sodium arachidonate, although the conversion of arachidonate to thromboxane B2 was not affected. La3+ was also found to enhance the accumulation of cyclic AMP under basal conditions and in response to prostaglandin E1, in washed platelets. The inhibition of cyclic AMP accumulation by ADP was prevented by La3+, suggesting that the effect of ADP on cyclic AMP metabolism was dependent upon the presence or flux of calcium at the platelet membrane. La3+ inhibited the activity of adenylate cyclase in platelet lysates both in response to prostaglandin E1 and to F-, indicating a possible effect at the catalytic subunit of the enzyme. None of the observed effects of La3+ could be reversed by the addition of Ca2+ up to 10 mM. The stimulation of cyclic AMP production by La3+ may largely explain the inhibitory effect of La3+ upon platelet secretion and thromboxane B2 production. These results also suggest that Ca2+ localised at the platelet plasma membrane may be important in the regulation of cyclic AMP metabolism.     

Role of glycosaminoglycans in calcium metabolism of human platelets

Changes in intracellular Ca2+, [Ca2+]i, were measured in control and chondroitin ABC lyase-pretreated platelets. [Ca2+]i was measured with the fluorescent calcium probe Quin2. Chondroitin ABC lyase removed chondroitin 4-sulfate from the platelet surface without inducing shape change or release of serotonin. Compared to similarly prepared controls, enzyme treated platelets showed an increase of [Ca2+]i in response to stimulation by various agonists at high (1 mM) extracellular Ca2+ concentration. At low Ca2+ in the medium (1 mM EGTA), such platelets responded to agonists with a decreased rise in [Ca2+]i compared to the controls. These studies indicate that selective removal of glycosaminoglycans may sensitize platelets to the action of platelet aggregating agents. In addition, glycosaminoglycans may have a calcium storage function.     

Method for collecting rat thrombocytes and determining their aggregation

Three different methods of blood collection from rats are studied and compared, namely decapitation, catheterization of the carotid artery and puncture of the heart left ventricle. The latter method is preferable in studies of platelet aggregation. The method for isolation of washed platelets from rat blood is described in detail. The platelets stored for several hours at 20 degrees C did not lose the ability for aggregating under exposure to low concentrations of ADP. The curves of aggregation of washed and plasma platelets are provided. To study the rate of aggregation, a model is offered based on the approximation of the aggregation curves by the exponential A = A0exp (-alpha t). Such an approach made it possible to treat the data objectively and to reveal the features of platelet functional activity, particularly in arterial hypertension.     

Lysophosphatidic acid can activate platelets without increasing 32P-labelling of phosphatidic acid

Stimulation of platelets by thrombin produced a rise in [32P]phosphatidic acid labelling of platelets which was greater in medium without added calcium than in medium with 2.5 mM calcium. A rise in [32P]lysophosphatidic acid was also seen in platelets stimulated by thrombin in the presence of 2.5 mM extracellular calcium, though it was of lesser magnitude (average 35%) than the rise in phosphatidic acid. In platelets resuspended without added calcium no change in [32P]lysophosphatidic acid was seen in response to thrombin. Lysophosphatidic acid can itself induce platelet aggregation. Similarly to the calcium ionophore A23187, lysophosphatidic acid produced minimal change (in medium with no added calcium) to no change (in medium with 2.5 mM external calcium) in [32P]lysophosphatidic acid. The endoperoxide analog U46619 produced changes in 32P-labelling of platelet phosphatidic and lysophosphatidic acid similar to those produced by thrombin but of lesser magnitude. The results of these studies show that the action of lysophosphatidic acid on platelets differs from the action of thrombin, U46619 and platelet-activating factor, which produce a rapid rise in [32P]phosphatidic acid, and suggests that lysophosphatidic acid, like A23187, largely bypasses the initial receptor-coupled breakdown of phosphoinositides leading to formation of diacylglycerols and phosphatidic acid.     

Hypergravity results in human platelet hyperactivity

Thrombotic diseases or fatalities have been reported to occasionally occur under conditions of hypergravity although the mechanism is still unclear. To investigate the effect of hypergravity on platelets that are the primary players in thrombus formation, platelet rich plasma (PRP) or washed platelets were exposed to hypergravity at 8 G for 15 minutes. No platelet aggregation was induced by 8 G alone, whereas ristocetin or collagen-induced platelet aggregation was significantly increased. The number of platelets adherent to immobilized fibrinogen and the area of platelets spreading on von Willbrand factor (VWF) matrix were increased simultaneously. Flow cytometry assay indicated that integrin αIIbß3 was partially activated in 8 Gexposed platelets, but there was no significant difference in P-selectin surface expression between platelets treated with 8 G and 1 G control. The results indicate that hypergravity leads to human platelet hyperactivity, but fails to incur essential platelet activation events, suggesting a novel mechanism for thrombotic diseases occurring under hypergravitional conditions.     

Covalent binding of arachidonic acid metabolites to human platelet proteins. Identification of prostaglandin H synthase as one of the modified substrates

The covalent modification of proteins by metabolites of arachidonic acid (AA) was investigated in human platelets. Following incubation of washed human platelets with radiolabeled AA, ethanol precipitation of the proteins, and lipid extraction by organic solvents, a small fraction of the radioactivity added (0.3%) was tightly bound to the protein pellet. A dozen labeled protein bands were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Exhaustive hydrolysis of platelet proteins by proteases released an amphipathic radiolabeled material which had a chromatographic behavior similar to that of a known peptidolipid, leukotriene C4. These findings suggest a covalent nature for the observed binding. This binding was specific for AA since palmitate, myristate, or linoleate did not bind to a significant extent. It involved products of both cyclooxygenase and lipoxygenase pathways: it was indeed inhibited to a greater extent by eicosatetraynoic acid than by indomethacin. The protein-associated radioactivity was increased by the thromboxane synthase inhibitor dazoxiben. Indomethacin completely abolished this increase in binding, which could not be reproduced by exogenous prostaglandin (PG) E2, F2 alpha, or D2, and might thus involve PGG2 and/or PGH2. Diamide, an agent known to inhibit the reduction of 12-hydroperoxyeicosatetraenoic acid in platelets, produced an increase of the covalent binding, which was abolished by eicosatetraynoic acid but not by indomethacin: this suggests that the lipoxygenase product bound was 12-hydroperoxyeicosatetraenoic acid or a by-product. Dazoxiben and diamide produced distinct patterns of protein labeling after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. One labeled band had a Mr of 70,000 as the PGH synthase monomer. Addition of AA at 17 microM enhanced the labeling of this band, while 100 microM was inhibitory. Labeling of this band was also induced by thrombin in prelabeled platelets. Two monoclonal antibodies against PGH synthase caused immune precipitation of a 70-kDa labeled protein in homogenates of [3H]AA-labeled platelets. PGH synthase, purified from ram seminal vesicles, was covalently modified after incubation with [3H]AA: this labeling was almost completely abolished by indomethacin. As much as 40% of platelet PGH synthase was covalently modified after incubation with 17 microM AA. It can be concluded that in intact platelets PGH synthase is covalently modified by an eicosanoid following incubation with exogenous AA or after AA mobilization from phospholipids by thrombin.     

Aggregation and release reaction of washed platelets stimulated by lanthanum.

Ionized lanthanum caused clumping of washed platelets. This clumping response could be reversed by chelating agents but was not impaired by known inhibitors of platelets aggregation. Aggregation by lanthanum was not restricted to the unique clumping properties of platelets but occurred in fixed platelets and red cells and was most likely based on an electrostatic interaction.Lanthanum was able to stimulate as well as to inhibit serotonin release from platelets.At a concentration of 1 mM, lanthanum evoked a release of serotonin from washed platelets at 37°C. This release reaction was inhibited at 18°C or by prior treatment of platelets with neuraminidase or NEM.At a high concentration (10 mM), lanthanum did not stimulate the platelet release reaction but inhibited that induced by all stimuli investigated, presumably due to a fixation of membrane molecules.The release reaction promoted by thrombin or A 23187, but not that by collagen, was inhibited by a low concentration of lanthanum (0.1 mM). This inhibition is based on an interaction of lanthanum with the stimuli rather than with the platelet surface.     

Effects of a polyoxyethylene detergent (Brij 58) on platelet aggregation, release and clotting activity

Low concentrations of a polyoxyethylene detergent, Brij 58, inhibited the secondary phase of platelet aggregation induced by ADP in human citrated platelet-rich plasma but had no effect on primary aggregation. Thrombin-induced aggregation of washed human platelets suspended in Tyrode's buffer was inhibited after incubation of cells with 4.10(-6) M detergent. Efflux of [14C]serotonin, 45Ca2+ and labile aorta contracting substance (thromboxane A2) and development of prothrombin-converting activity (platelet factor 3) were abolished concomitantly. Aggregation of washed platelets either by sodium arachidonate or by collagen was also inhibited by the same concentration of Brij 58 which inhibited thrombin aggregation. This concentration did not itself produce any release of a cytoplasmic marker, lactate dehydrogenase, from platelets. Higher concentrations of Brij 58, exceeding 4.10(-5) M, lysed the cells liberating lactate dehydrogenase, serotonin and Ca2+. When albumin was included as a platelet stabilizer in the suspending medium the concentration of detergent required for the inhibitory effects was increased ten-fold. This could be attributed to competitive binding of the detergent to albumin, demonstrated with [14C]acetylated Brij 58. A variety of other polyoxyethylene detergents, at concentrations from 8.10(-4) to 5.10(-3) M, also inhibited platelet aggregation induced by thrombin. It is concluded that low concentrations of Brij 58 stabilize the platelets against the action of aggregating agents, while higher concentrations produce membrane destabilization and cell lysis.     

Evidence for multiple mechanisms of interaction between wheat germ agglutinin and human platelets

Wheat germ agglutinin induced aggregation and secretion of serotonin from human platelets in plasma. This aggregation of platelets was blocked by ethylenediaminetetraacetate, azide or prostaglandin E₁. The secretion of serotonin was not affected by ethylenediaminetetraacetate but was inhibited by progstaglin E₁. Thus, wheat germ agglutinin acts on platelets in plasma as a true aggregating agent.Washed platelets showed increased light transmission when treated with the lectin which was not blocked by ethylenediaminetetraacetate or prostaglandin E₁. The capacity to inhibit platelet clumping by the above agents was restored if plasma was added back to the cell suspension. Washed platelets did not release serotonin under the conditions of cell clumping. Thus, in contrast to platelets in plasma, washed platelets are agglutinated by the lection.Platelets fixed in formaldehyde were not agglutinated by the lectin in the aggregometer but agglutination was observed in the microtiter plate. This agglutination may be mediated by interplatelet bridging. These results show that the same agent may act on platelets by different mechanisms depending on the state of the cell and its environment.