Release of immunoreactive-neuropeptide by rat platelets

Neuropeptide Y, a potent vasoconstrictor and cardiac depressant, is re-leased from sympathetic nerve endings. Its presence in megakaryocytes suggests this peptide might be stored in platelet granules and released during aggregation. Immunoreactive-neuropeptide Y was measured in platelet rich and platelet poor plasma, and was substantially greater in the former. Addition of collagen to platelets resulted in release of neuropeptide Y which paralleled, in a concentration-dependent manner, the degree of platelet aggregation. Adenosine diphosphate, at concentrations which induce only the first phase of aggregation and not the release reaction, caused only a minor release of neuropeptide Y. These results suggest that platelet release could be a major source of circulating neuropeptide Y and could contribute to hemodynamics of pathophysiological states involving platelet activation.     

ATP augments von Willebrand factor-dependent shear-induced platelet aggregation through Ca2+-calmodulin and myosin light chain kinase activation

Shear stress triggers von Willebrand factor (VWF) binding to platelet glycoprotein Ibalpha and subsequent integrin alpha(IIb)beta(3)-dependent platelet aggregation. Concomitantly, nucleotides are released from plateletdense granules, and ADP is known to contribute to shear-induced platelet aggregation (SIPA). We found that the impaired SIPA of platelets from a Hermansky-Pudlak patient lacking dense granules was restored by exogenous l-beta,gamma-methylene ATP, a stable P2X(1) agonist, as well as by ADP, confirming that in addition to ADP (via P2Y(1) and P2Y(12)), ATP (via P2X(1)) also contributes to SIPA. Likewise, SIPA of apyrase-treated platelets was restored upon P2X(1) activation with l-beta,gamma-methylene ATP, which promoted granule centralization within platelets and stimulated P-selectin expression, which is a marker of alpha-granule release. In addition, during SIPA, platelet degranulation required both extracellular Ca(2+) and VWF-glycoprotein Ibalpha interactions without involving alpha(IIb)beta(3). Neither platelet release nor SIPA was affected by protein kinase C inactivation, even though protein kinase C blockade inhibits platelet responses to collagen and thrombin in stirring conditions. In contrast, inhibiting myosin light chain (MLC) kinase with ML-7 reduced platelet release and SIPA by 30%. Accordingly, the potentiating effect of P2X(1) stimulation on the aggregation of apyrase-treated platelets coincided with intensified phosphorylation of MLC and was abrogated by ML-7. SIPA-induced MLC phosphorylation occurred exclusively through released nucleotides and selective antagonism of P2X(1) with MRS2159-reduced SIPA, ATP release, and potently inhibited MLC phosphorylation. We conclude that the P2X(1) ion channel induces MLC-mediated cytoskeletal rearrangements, thus contributing to SIPA and degranulation during VWF-triggered platelet activation.     

PLATELET PHAGOCYTOSIS AND AGGREGATION

The addition of latex particles to native (no anticoagulant) or citrated human platelet-rich plasma (PRP), or to a once-washed platelet suspension causes platelet aggregation. This aggregation is associated with phagocytosis of the latex particles by the platelets and appears to be due to release of adenosine diphosphate (ADP) from the platelets. Adenosine and adenosine monophosphate, which are known to inhibit platelet aggregation induced by ADP, also block that induced by latex. These compounds do not prevent the phagocytosis of latex particles by the platelet. The addition of iodoacetate and 2,4-dinitrophenol in appropriate concentrations to the PRP, prior to the addition of the latex, blocks platelet aggregation and phagocytosis. This is also true for the chelating agent ethylenediaminetetraacetate (EDTA). Platelets left in contact with latex for a sufficient period of time show loss of their granules. Leucocytes phagocytose both latex and platelets that had themselves phagocytosed latex. It is concluded that phagocytosis of latex particles by platelets resembles that by white cells, and that in both processes metabolic changes appear to be involved.     

Adenosine diphosphate receptors on blood platelets: potential new targets for antiplatelet therapy

Platelets play a key role not only in physiological haemostasis, but also under pathological conditions such as thrombosis. Platelet activation may be initiated by a variety of agonists including thrombin, collagen, thromboxane or adenosine diphosphate (ADP). Although ADP is regarded as a weak agonist of blood platelets, it remains an important mediator of platelet activation evoked by other agonists, which induce massive ADP release from dense granules, where it occurs in molar concentrations. Thus, ADP action underlies a positive feedback that facilitates further platelet aggregation and leads to platelet plug formation. Additionally, ADP acts synergistically to other, even weak, agonists such as serotonin, adrenaline or chemokines. Blood platelets express two types of P2Y ADP receptors: P2Y(1) and P2Y(12). ADP-dependent platelet aggregation is initiated by the P2Y1 receptor, whereas P2Y(12) receptor augments the activating signal and promotes platelet release reaction. Stimulation of P2Y(12) is also essential for ADP-mediated complete activation of GPIIb-IIIa and GPIa-IIa, and further stabilization of platelet aggregates. The crucial role in blood platelet biology makes P2(Y12) an ideal candidate for pharmacological approaches for anti-platelet therapy.     

The proton gradient of secretory granules and glutamate transport in blood platelets during cholesterol depletion of the plasma membrane by methyl-β-cyclodextrin

Glutamate transport in blood platelets resembles that in brain nerve terminals because platelets contain neuronal Na⁺-dependent glutamate transporters, glutamate receptors in the plasma membrane, vesicular glutamate transporters in secretory granules, which use the proton gradient as a driving force, and can release glutamate during aggregation/activation. The acidification of secretory granules and glutamate transport were assessed during acute treatment of isolated platelets with cholesterol-depleting agent methyl-β-cyclodextrin (MβCD). Confocal imaging with the cholesterol-sensitive fluorescent dye filipin showed a quick reduction of cholesterol level in platelets. Using pH-sensitive fluorescent dye acridine orange, we demonstrated that the acidification of secretory granules of human and rabbit platelets was decreased by ∼15% and 51% after the addition of 5 and 15 mM MβCD, respectively. The enrichment of platelet plasma membrane with cholesterol by the application of complex MβCD-cholesterol (1:0.2) led to the additional accumulation of acridine orange in secretory granules indicating an increase in the proton pumping activity of vesicular H⁺-ATPase. MβCD did not evoke release of glutamate from platelets that was measured with glutamate dehydrogenase assay. Flow cytometric analysis did not reveal alterations in platelet size and granularity in the presence of MβCD. These data showed that the dissipation of the proton gradient of secretory granules rather than their exocytosis caused MβCD-evoked decrease in platelet acidification. Thus, the depletion of plasma membrane cholesterol in the presence of MβCD changed the functional state of platelets affecting storage capacity of secretory granules but did not evoke glutamate release from platelets.     

Ability of Different Glycoprotein IIb-IIIa Ligands to Support Platelet Aggregation Induced by Activating Antibody CRC54

The ability of different ligands of glycoprotein (GP) IIb-IIIa (alphaIIb/beta3-integrin) to support platelet aggregation stimulated by activating anti-GP IIb-IIIa monoclonal antibody (monoAB) CRC54 has been investigated. Antibody CRC54 stimulated aggregation of washed platelets not only in the presence of fibrinogen, the main GP IIb-IIIa ligand, but also in the presence of von Willebrand factor (vWF). Unlike these ligands, fibronectin failed to support CRC54-induced aggregation. Fibrinogen and vWF dependent platelet aggregation was completely suppressed by GP IIb-IIIa antagonists--preparations Monafram (F(ab')2 fragments of monoAB that blocked GP IIb-IIIa receptor activity) and aggrastat (RGD-like peptidomimetic). However, aggregation stimulated in the presence of vWF was also completely inhibited by monoAB AK2 directed against GP Ib and capable of blocking its binding with vWF. CRC54-induced aggregation of platelets from patient with GP Ib deficiency in the presence of vWF was significantly lower than aggregation of platelets from normal donors and was not inhibited by anti-GP Ib antibody but still blocked by GP IIb-IIIa antagonist Monafram. Monafram also suppressed CRC54-stimulated platelet adhesion to plastic-adsorbed fibrinogen, vWF, and fibronectin. Unlike CRC54-induced platelet aggregation supported by fluid phase vWF, CRC54-induced adhesion to adsorbed vWF was not affected by anti-GP Ib antibody. Aggregation induced by CRC54 in the presence of fibrinogen and vWF was only partially suppressed by prostaglandin E1, an inhibitor of platelet activation, and was associated with serotonin release from platelet granules only when Ca2+ concentration was decreased from 1 mM (physiological level) to 0.1 mM. The data indicate that vWF supports CRC54-induced platelet aggregation via interaction with two receptors--GP IIb-IIIa and GP Ib. Aggregation induced by CRC54 in the presence of vWF or fibrinogen is only partially dependent on platelet activation and is accompanied with granule secretion only at low Ca2+ concentrations.     

Reversible endocytosis apparatus of the blood platelets]

The functioning of ganules of blood platelets participating in the reversible endocytosis reaction was investigated in rabbits. Eczocytosis was shown to be initiated by inducers of two types: proteolytic enzymes and compounds accumulated by the granules (biogenic amines, dyes, anesthetics and phenothiazines). Heparin inhibits thrombin-induced eczocytosis. During eczocytosis produced by accumulation of compounds by blood platelet granules, the cells lose their capacity for maintaining the aggregation state. The nature of blood platelet granules participating in the reversible endocytosis reaction is discussed.     

Effects of diadenosine triphosphate (Ap3A) and diadenosine tetraphosphate (Ap4A) on platelet aggregation in unfractionated human blood

The effects on platelet aggregation of diadenosine triphosphate (Ap3A) and diadenosine tetraphosphate (Ap4A), both of which are stored in and released from platelet granules, have been studied in unfractionated human blood using a microscopic platelet-count ratio method. Ap3A at submicromolar concentrations induces platelet aggregation whereas the homologue dinucleotide Ap4A has disaggregating potency. In the concentration range between 10(-7) to 10(-5) M, Ap3A has been found to be as effective as ADP in triggering aggregate formation. These results confirm and essentially extend our recent findings with platelet-rich plasma that Ap3A is able to trigger platelet aggregation by a slow release of ADP from Ap3A which is catalyzed by a plasma hydrolase. Formation of platelet aggregates was also followed kinetically using a turbidometric method which has been developed for this purpose. In contrast to ADP which very rapidly induces a transient state of aggregation, the effect of Ap3A occurs much more slowly but induces the same maximum of aggregation. The duration of the Ap3A stimulus, however, is longer than that of ADP pointing to a potential physiological function of Ap3A as a "masked" source for ADP.     

Activation of platelets induced by mAb P256 specific for glycoprotein IIb-IIIa. Possible evidence for a role for IIb-IIIa in membrane signal transduction

Monoclonal antibody P256, which is specific for glycoprotein IIb-IIIa complex, was found to induce aggregation of normal platelets in plasma. The mechanism of platelet activation induced by this monoclonal antibody was thoroughly studied. The divalent binding to the IIb-IIIa molecule was necessary for triggering aggregation since Fab' fragments did not induce aggregation as did IgG and F(ab')2 fragments; however, F(ab')2 did not induce the release as did the whole IgG. P256-induced aggregation was accompanied by release of all three granule constituents, namely dense granules, alpha-granules and lysosomes, with parallel kinetics showing half-maximum release 50 s after addition of P256. Thromboxane synthesis was initiated at the same time. Using 32P-prelabeled platelets, no variation in level of [32P]phosphatidylinositol 4,5-bisphosphate could be detected in the first minute after P256 addition, indicating no activation of the calcium-independent phospholipase C specific for polyphosphoinositol phospholipid. P256 induced a calcium mobilization as measured by Indo-1 fluorescence of about the third of that measured in the presence of a thrombin concentration giving the same intensity of aggregation. P256 induced phosphorylation of the myosin light chain p20 and of the main substrate of protein kinase C, p43. Addition of aspirin inhibited almost totally calcium mobilization and partially aggregation, release and protein phosphorylations. By contrast, in the absence of external calcium, although no aggregation could occur, the release reaction was only partially reduced. In this activation, the glycoprotein IIb-IIIa complex thus appears to play a role in modulating platelet response, not only via calcium fluxes but also in activating protein kinase C responsible for p43 phosphorylation.     

In vitro inhibition of rat platelet aggregation by ochratoxin A

The mycotoxin ochratoxin A (OA) consists of 5-chloro-3-methyl-3,4-dihydro-8-hydroxyisocoumarin moiety linked by an amide bond to β-L-phenylalanine. When added to washed rat platelets in vitro, OA caused a dose-dependent inhibition of aggregation induced by agonists such as adenosine diphosphate (ADP) or thrombin. The aggregatory response induced by prior addition of an agonist was also reversed in a dose-dependent manner by OA. Inhibition of aggregation appeared to be irreversible since exposure of platelets to OA followed by several washings removed most of the mycotoxin associated with the platelets but did not diminish the inhibitory response. Serotonin secretion from dense granules and arachidonic acid release from membrane phospholipid (especially phosphatidylcholine) as well as its further metabolism were also inhibited by OA. These results suggest that a disruption of the platelet plasma membrane structure by OA is probably responsible for inhibition of the primary and secondary phases of aggregation.     

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.     

Adenylic dinucleotides produced by CD38 are negative endogenous modulators of platelet aggregation

Diadenosine 5',5'-P1,P2-diphosphate (Ap2A) is one of the adenylic dinucleotides stored in platelet granules. Along with proaggregant ADP, it is released upon platelet activation and is known to stimulate myocyte proliferation. We have previously demonstrated synthesis of Ap2A and of two isomers thereof, called P18 and P24, from their high pressure liquid chromatography retention time, by the ADP-ribosyl cyclase CD38 in mammalian cells. Here we show that Ap2A and its isomers are present in resting human platelets and are released during thrombin-induced platelet activation. The three adenylic dinucleotides were identified by high pressure liquid chromatography through a comparison with the retention times and the absorption spectra of purified standards. Ap2A, P18, and P24 had no direct effect on platelet aggregation, but they inhibited platelet aggregation induced by physiological agonists (thrombin, ADP, and collagen), with mean IC(50) values ranging between 5 and 15 mum. Moreover, the three dinucleotides did not modify the intracellular calcium concentration in resting platelets, whereas they significantly reduced the thrombin-induced intracellular calcium increase. Through binding to the purinergic receptor P2Y(11), exogenously applied Ap2A, P18, and P24 increased the intracellular cAMP concentration and stimulated platelet production of nitric oxide, the most important endogenous antiaggregant. The presence of Ap2A, P18, and P24 in resting platelets and their release during thrombin-induced platelet activation at concentrations equal to or higher than the respective IC(50) value on platelet aggregation suggest a role of these dinucleotides as endogenous negative modulators of aggregation.     

Platelet function testing in the pony

Platelet isolation techniques and platelet function were evaluated in 35 adult ponies. Platelet recovery from whole blood was consistent and the preparation of platelet rich plasma was facilitated by an enhanced erythrocyte sedimentation rate. All platelet samples aggregated in response to 10 microM ADP. However, concentrations of ADP as high as 100 microM did not elicit significant 14C-serotonin release. Collagen induced irreversible platelet aggregation and 14C-serotonin release in all samples. The threshold dose for collagen in most ponies was 1.5 micrograms. Arachidonic acid (500 microM) failed to induce irreversible platelet aggregation or 14C-serotonin release in any of the samples evaluated. Pony platelets were nonresponsive to epinephrine (5.5 microM).     

Metabolic Plasticity in Resting and Thrombin Activated Platelets

Platelet thrombus formation includes several integrated processes involving aggregation, secretion of granules, release of arachidonic acid and clot retraction, but it is not clear which metabolic fuels are required to support these events. We hypothesized that there is flexibility in the fuels that can be utilized to serve the energetic and metabolic needs for resting and thrombin-dependent platelet aggregation. Using platelets from healthy human donors, we found that there was a rapid thrombin-dependent increase in oxidative phosphorylation which required both glutamine and fatty acids but not glucose. Inhibition of fatty acid oxidation or glutamine utilization could be compensated for by increased glycolytic flux. No evidence for significant mitochondrial dysfunction was found, and ATP/ADP ratios were maintained following the addition of thrombin, indicating the presence of functional and active mitochondrial oxidative phosphorylation during the early stages of aggregation. Interestingly, inhibition of fatty acid oxidation and glutaminolysis alone or in combination is not sufficient to prevent platelet aggregation, due to compensation from glycolysis, whereas inhibitors of glycolysis inhibited aggregation approximately 50%. The combined effects of inhibitors of glycolysis and oxidative phosphorylation were synergistic in the inhibition of platelet aggregation. In summary, both glycolysis and oxidative phosphorylation contribute to platelet metabolism in the resting and activated state, with fatty acid oxidation and to a smaller extent glutaminolysis contributing to the increased energy demand.     

Prostaglandin receptors on human platelets. Structure-activity relationships of stimulatory prostaglandins.

1. Synthetic analogues of prostaglandins E2 or F2a (monocyclic bisenoic prostaglandins), like the endogenous prostaglandin endoperoxides (prostaglandins G2 and H2) from platelets, and like synthetic analogues of prostaglandin H2 (bicyclic bisenoic prostaglandins), can induce aggregation of human platelets, although prostaglandins E2 and F2a themselves are inactive. 2. All the prostanoid compounds that induce platelet aggregation release 5-hydroxytryptamine from platelet dense bodies, but do not release beta-N-acetylglucosaminidase from lysosomal granules. Arachidonic acid evokes a similar response. 3. All endoperoxide analogues tested (bicyclic compounds) were powerful platelet stimulants, and all active compounds (whether mono- or bi-cyclid) apparently acted via the same receptor as the endogenous prostaglandin endoperoxides. 4. The nature and stereospecificity of substituents at positions 11 and 15 (or 16) on prostaglandin E2 are critical determinants for platelet-stimulating activity: deoxy substitution at position 11 plus methylation at position 15 (or 16) produces a potent stimulant, particularly if the groups around C-15 are in the S configuration. 5. The effects of these structural modifications are apparently due to, at least in part, a change in side-chain conformation.     

The effects of short-term training on platelet functions and total antioxidant capacity in rats

The purpose of the present study was to investigate the effect of short-term endurance training on plasma total antioxidant status (TAS) and on in vitro platelet aggregation and ATP release. Blood samples were collected from the abdominal aorta of rats following short-term treadmill exercise (25 m/min, 0 % grade, 30 min) for three consecutive days, as well as in non-exercised control group. Platelet aggregation and platelet ATP release were evaluated by impedance and bioluminescence techniques, respectively. Plasma TAS was measured spectrophotometrically. Plasma TAS was higher and ADP-induced platelet ATP release was lower in the short-term training group with respect to the control group (p<0.001). Significant negative correlation (r = -0.56, p<0.05) was found between plasma TAS and ADP-induced platelet ATP release. Neither ADP- and collagen-induced maximum aggregation rate nor collagen-induced platelet ATP release were significantly different between the groups. According to these results, short-term training caused an alteration in platelet functions limited to the secretion response, which may be related to the oxidant/antioxidant balance changes favoring the antioxidants. The improved plasma total antioxidant capacity was possibly sufficient to prevent exercise-induced oxidative damage, and the adaptive response of platelets might be associated with enhanced antioxidant status.     

Abnormalities of platelet aggregation in chronic myeloproliferative disorders

A large variety of platelet dysfunctions has been described in chronic myeloproliferative disorders. These abnormalities may be due to deficiency of platelet granules, arahidonic acid metabolism defects or platelet membrane glycoproteins abnormalities. In this study we intend to detect the incidence of platelet function defects in 76 patients with various types of chronic myeloproliferative disorders. The platelet activity was studied in vitro by measuring platelet aggregation in response to ADP, epinephrine, collagen, arachidonic acid and ristocetin. These results were subsequently correlated with bleeding time and clinical aspects (bleeding or thrombosis). We found complex changes in platelet response with all agonists, in varied proportions. These abnormalities include absent, decreased or abnormal platelet aggregation response. In a few cases we found a markedly decreased, almost absent platelet response to all agonists while in some patients a normal platelet aggregation was noted. The correlation between these results and template bleeding time, thrombotic or hemorrhagic events and the type of diseases was difficult to establish and sometimes conflictual. Despite this fact, we consider that investigating platelet aggregation may be useful not only for the assesment of the hemostatic balance in chronic myeloproliferative disorders but also for a better insight into cell abnormalities occuring in these pathologic conditions.     

The role of phospholipase C in platelet responses

Degradation of inositides induced by phospholipase C in activated platelets leads to the formation of 1,2-diacylglycerol (1,2-DG) and its phosphorylated product, phosphatidic acid (PA). We have studied the relationship between activation of phospholipase C and the appearance of specific platelet responses, such as phosphorylation of proteins, shape change, release reaction and aggregation induced by different stimuli such as thrombin, platelet-activating factor, collagen, arachidonic acid (AA) and dihomogamma linolenic acid. A low degree of platelet activation induces only shape change which is associated with partial activation of phospholipase C (formation of phosphatidic acid), and phosphorylation of both a 40K molecular weight protein (protein kinase C activation) and a 20K molecular weight protein (myosin light chain). A higher degree of platelet activation induces aggregation, release of serotonin and a higher level of phospholipase C and protein kinase C activities. Metabolism of AA occurs concomitantly to aggregation and serotonin release, but AA metabolites are not related to the shape change of human platelets. Platelet shape change and the initial activation of phospholipase C induced by thrombin or platelet-activating factor is independent of the metabolites derived from cyclo-oxygenase activity. Further activation of phospholipase C which occurs during platelet aggregation and release reaction is, however, partly dependent on cyclo-oxygenase metabolites.     

Calcitonin gene-related peptide-mediated antihypertensive and anti-platelet effects by rutaecarpine in spontaneously hypertensive rats

We have previously reported that Chinese traditional medicine rutaecarpine (Rut) produced a sustained hypotensive effect in phenol-induced and two-kidney, one-clip hypertensive rats. The aims of this study are to determine whether Rut could exert antihypertensive and anti-platelet effects in spontaneously hypertensive rats (SHR) and the underlying mechanisms. In vivo, SHR were given Rut and the blood pressure was monitored. Blood was collected for the measurements of calcitonin gene-related peptide (CGRP), tissue factor (TF) concentration and activity, and platelet aggregation, and the dorsal root ganglia were saved for examining CGRP expression. In vitro, the effects of Rut and CGRP on platelet aggregation were measured, and the effect of CGRP on platelet-derived TF release was also determined. Rut exerted a sustained hypotensive effect in SHR concomitantly with the increased synthesis and release of CGRP. The treatment of Rut also showed an inhibitory effect on platelet aggregation concomitantly with the decreased TF activity and TF antigen level in plasma. Study in vitro showed an inhibitory effect of Rut on platelet aggregation in the presence of thoracic aorta, which was abolished by capsazepine or CGRP(8-37), an antagonist of vanilloid receptor or CGRP receptor. Exogenous CGRP was able to inhibit both platelet aggregation and the release of platelet-derived TF, which were abolished by CGRP(8-37). The results suggest that Rut exerts both antihypertensive and anti-platelet effects through stimulating the synthesis and release of CGRP in SHR, and CGRP-mediated anti-platelet effect is related to inhibiting the release of platelet-derived TF.     

Endocytosis by human platelets: metabolic and freeze-fracture studies

The mechanism by which platelets endocytose or release particulate or soluble substances is poorly understood. Engulfed materials enter the open canalicular system (OCS) by a process akin to phagocytosis, but fusion of platelet granules with the OCS is rarely observed. Secretion of granule contents, a concomitant of the "release reaction" which occurs during platelet aggregation, does not take place by extrusion at the surface membrane as is true for other secretory cells. Some substances may be secreted without obvious granule loss. To examine whether structural properties of the platelet membrane could account for this unusual behavior, thin section and freeze-fracture analyses were performed on platelets which had undergone endocytosis under a variety of experimental conditions. After freeze-cleavage, most of the intramembranous particles (IMP) remain associated with the outer leaflet of the platelet plasma membrane. The sites where the OCS reaches the surface membrane are marked by pits on the cytoplasmic leaflet (P face) and by complementary protrusions on the outer leaflet (E face) of the membrane. Endocytosis of small particles and solutes takes place via these structures. This process is not energy dependent but arrested at 4 degrees C. Distension of the OCS does not appear to affect the size or number of the pits. On the other hand, large particles are taken up by membrane invagination without redistribution of IMP's and independent of the pits. This process is sensitive to metabolic inhibition. Thus, the studies have demonstrated the existence of two different pathways for platelet endocytosis which are postulated to be also involved in secretion. The selective release of substances contained in different granules may be related to the "inside-out" structure of the plasma and OCS membranes.