The effect of hematoporphyrin and light on human platelets. III. Release of potassium and acid phosphatase

Human platelets, exposed to hematoporphyrin and light, were depleted of potassium and acid phosphatase. A linear relationship was demonstrated between the per cent depletion of potassium from irradiated platelets and the log dose of hematoporphyrin. The initial release of potassium and acid phosphatase from irradiated platelets was first order. Rate constants demonstrated that potassium was released five times faster than acid phosphatase. At 4°C, release of both potassium and acid phosphatase was the same as at 37°C. These results are compared to previous data on the release of serotonin from irradiated platelets.     

The effect of hematoporphyrin and light on human platelets. II. Uptake of hematoporphyrin

A linear relationship was demonstrated between the reciprocals of the concentration of free hematoporphyrin and the moles of hematoporphyrin taken up by the platelet in the dark. radiated platelets took up more hematoporphyrin than did controls; this increase in uptake was accounted for by the movement of the dye across the damaged membrane of the cell. platelets irradiated at 4°c remained impermeable to hematoporphyrin until warmed to 37°c. during the initial three to four minutes of exposure to light at 37°c, there was no additional uptake of hematoporphyrin by platelets in comparison to controls. between six to ten minutes irradiation, the uptake of hematoporphyrin increased linearly with the log time of irradiation. thereafter, no further uptake occurred. a further increase in uptake of dye was demonstrated by both control and irradiated platelets at a reduced ph. this study enables a correlation to be made between the effects of hematoporphyrin on the platelet and the uptake of this agent by the platelet.     

Transport and storage of serotonin by thrombin-treated platelets

Repeated thrombin treatment of washed platelets prepared from rabbits can decrease the serotonin content of the platelets by about 80%. When these platelets are deaggregated they reaccumulate serotonin but their storage capacity for serotonin is reduced by about 60%. If thrombin-pretreated platelets are allowed to equilibrate with a high concentration of serotonin (123 mu M), they release a smaller percentage of their total serotonin upon further thrombin treatment, in comparison with the percentage of serotonin released from control platelets equilibrated with the same concentration of serotonin calculations indicate that in thrombin-treated platelets reequilibrated with serotonin, two-thirds of the serotonin is in the granule compartment and one-third is in the extragranular compartment, presumably the cytoplasm. Analysis of the exchange of serotonin between the suspending fluid and the platelets showed that thrombin treatment does not alter the transport rate of serotonin across the platelet membrane and does not cause increased diffusion of serotonin from the platelets into the suspending fluid. The primary reason for the reduced serotonin accumulation by the thrombin-treated platelets appears to be loss of amine storage granules or of the storage capacity within the granules.     

An assay to measure the simultaneous uptake of [3H]dopamine and [14C]serotonin by the human platelet reveals an imipramine-insensitive [3H]dopamine uptake mechanism.

To determine whether a specific dopamine uptake mechanism is present on the human platelet the simultaneous uptake of [3H]dopamine and [14C]serotonin by platelets was measured. Utilising a dual radiolabel uptake technique, platelets have been shown to take up serotonin more rapidly and to a greater extent than they take up dopamine. Furthermore, at high concentrations serotonin was able to reduce dopamine uptake by platelets by 60% whereas dopamine had no effect on serotonin uptake. Similarly, imipramine and reserpine reduced (97% and 74% respectively) serotonin uptake by platelets in a dose-dependent manner, but did not affect the uptake of dopamine. Our data show that platelets take up dopamine by a mechanism independent of the imipramine-sensitive serotonin uptake mechanism. Furthermore, the increased capacity of platelets to store serotonin is because serotonin, unlike dopamine, is transported into the dense granules of the platelet.     

The roles of ATP and calcium in morphological changes and cytotoxicity induced by 1,4-benzoquinone in platelets

To understand the mechanism of 1,4-benzoquinone-induced cytotoxicity in platelets, the roles of ATP and calcium in platelet toxicity and morphological changes were investigated. Using scanning electron microscopy, morphological changes including membrane blebbing were observed in rat platelets 5 min after exposure to 1,4-benzoquinone, which were significantly different from shape changes (pseudopod formation) observed in response to physiological agonists. Benzoquinone-induced membrane blebbing of platelets was associated with rapid depletion of intracellular ATP and was independent of the presence of extracellular calcium. Benzoquinone-induced platelet lysis observed between 20 and 30 min was dependent on extracellular calcium and associated with increased cytosolic calcium. Cytotoxicity induced by 1,4-benzoquinone was inhibited by antagonists of calmodulin, suggesting that calmodulin could play an important role in platelet toxicity. These results suggested that the progression of events for benzoquinone-induced cytotoxicity in platelets was as follows: 1,4-benzoquinone depletes intracellular ATP; membrane blebbing occurs; calcium homeostasis is disrupted, activation of calmodulin-dependent processes results; finally cytotoxicity occurs.     

Synaptotagmin II could confer Ca(2+) sensitivity to phagocytosis in human neutrophils

To understand the mechanism of 1,4-benzoquinone-induced cytotoxicity in platelets, the roles of ATP and calcium in platelet toxicity and morphological changes were investigated. Using scanning electron microscopy, morphological changes including membrane blebbing were observed in rat platelets 5 min after exposure to 1,4-benzoquinone, which were significantly different from shape changes (pseudopod formation) observed in response to physiological agonists. Benzoquinone-induced membrane blebbing of platelets was associated with rapid depletion of intracellular ATP and was independent of the presence of extracellular calcium. Benzoquinone-induced platelet lysis observed between 20 and 30 min was dependent on extracellular calcium and associated with increased cytosolic calcium. Cytotoxicity induced by 1,4-benzoquinone was inhibited by antagonists of calmodulin, suggesting that calmodulin could play an important role in platelet toxicity. These results suggested that the progression of events for benzoquinone-induced cytotoxicity in platelets was as follows: 1,4-benzoquinone depletes intracellular ATP; membrane blebbing occurs; calcium homeostasis is disrupted, activation of calmodulin-dependent processes results; finally cytotoxicity occurs.     

Membrane microenvironmental changes during activation of human blood platelets by thrombin. A study with a fluorescent probe.

Membrane microenvironmental changes associated with thrombin-induced platelet activation were followed by fluorescence intensity and polarization studies of 1,6-diphenyl-1,3,5-hexatriene (DPH)-labeled human platelets. The labeling of washed platelets with DPH did not alter platelet intactness and morphology. In response to thrombin, DPH-labeled platelets exhibited reduced serotonin release, yet aggregation was barely inhibited. Shape change induced by thrombin or ADP was indistinguishable in control and in DPH-labeled platelets. During platelet aggregation induced by thrombin, fluorescence intensity increased by about 14%, which may indicate a more hydrophobic exposure of the probe. However, no change in fluorescence was detected during platelet shape change, induced either by thrombin in presence of EDTA or by ADP. Thrombin-activated platelets exhibited an increase in values of fluorescence polarization (P) during the stages of shape change and secretion, which further increased during aggregation. A similar pattern of increase in P values characterized platelet shape changes, caused either by thrombin in the presence of EDTA or by ADP. Changes in individual platelets are discernible from the alterations of the aggregating cells. These results may indicate that platelet activation is accompanied by an increase in rigidity of the membrane lipids. Functionally, the elevated "microviscosity" may reflect a primary role of membrane lipids in modulating the process of platelet activation or secondary transitions in lipids due to membrane events mediated by proteins.     

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.     

Metabolic aspects of the secretion of stored compounds from blood platelets. IV. Effects of ionophore X537A on washed platelets.

1. X537A at concentrations below 10 muM can liberate platelet serotonin from washed human platelets without inducing the platelet release reaction. Up to 100% of serotonin preabsorbed by the platelets can be liberated before initiation of the release reaction. 2. Concentrations of X537A above 10muM initiate the platelet release reaction, with a maximum release of adenine nucleotides and platelet factor 4 antigen comparable to that obtained with 1.25 units thrombin/ml. 3. The changes in ATP metabolism at the concentration necessary for X537A-induced release are more profound than those in platelets exposed to concentrations of thrombin or A23187 giving the same degree of release, and approach those seen with high concentrations of A23187. At concentrations where serotonin is liberated but no adenine nucleotide or platelet factor 4 antigen is released, short time incubation causes no change in the level of metabolic ATP.     

Primary dysfunction in aggregation and secretion of SHRSP platelets: not secondary to the circulation of "exhausted" platelets

The thrombin-induced secretion of [14C]-serotonin and adenine nucleotides from stroke-prone spontaneously hypertensive rats (SHRSP) platelets was markedly reduced with the development of hypertension accompanying hypo-aggregability compared with that from age-matched Wistar Kyoto rats (WKY) platelets. Calcium Ionophore A23187-induced secretion and aggregation were also attenuated in SHRSP platelets. Additionally, an enhancement of platelet secretion as well as aggregation by extracellular Ca2+ was less in SHRSP platelets than in WKY platelets. The platelet contents of adenine nucleotides and serotonin were not different between SHRSP and WKY at 5-16 weeks of age whereas they became significantly lower in SHRSP beginning at 22 weeks. The serotonin content in SHRSP platelets at 36 weeks of age was only 55% of that in WKY platelets. It is suggested that the reduced platelet aggregation and secretion observed in SHRSP platelets at ages lower than approximately 20 weeks are not secondary phenomena to the circulation of degranulated platelets, but the primary defect of SHRSP platelets appears to be an impaired function of Ca2+.     

Heterogeneity in microparticle formation and exposure of anionic phospholipids at the plasma membrane of single adherent platelets.

Adherent platelets were examined for their ability to form microvesicles and procoagulant sites for thrombin formation. Epifluorescence and phase-contrast microscopy were employed to visualize shape changes, changes in intracellular Ca(2+) levels ([Ca(2+)](i)), vesiculation of the plasma membrane and appearance of anionic phospholipids in the outer leaflet of the plasma membrane, as probed by annexin V binding. In the absence of extracellular Ca(2+) two stable populations of adherent platelets were observed. The majority of the adherent platelets were fully spread and about 10% remained in a non-spread dendritic state. In the presence of extracellular Ca(2+) vesiculation at the surface of spread platelets occurred at a rather slow rate (10% of the platelets after 20 min) concomitantly with an increase in [Ca(2+)](i) and binding of annexin V. However, a small fraction of the adherent platelets ( approximately 1%) responded much faster. Ionomycin-enhanced influx of Ca(2+) in dendritic platelets resulted in a rapid transformation of these platelets into inflated, balloon-shaped, platelets having a diameter of 2.0+/-0.7 microm without notable microvesicle formation. In contrast, fully spread platelets retained their shape but obtained frayed edges as a result of microvesicle formation. Confocal scanning fluorescence microscopy indicated that annexin V bound to very distinct sites at the outer plasma membrane of spread as well as balloon-shaped platelets. Inhibition of platelet calpain activity suppressed ionomycin-enhanced microvesicle formation and ballooning of platelets, but not annexin V binding. These findings indicate that vesiculation and ballooning, but not the exposure of phosphatidylserine at the outer leaflet of the adherent platelet membrane, are associated with cytoskeleton destruction. Altogether, the data suggest a similar relationship between [Ca(2+)](i) and the formation of platelet procoagulant sites as reported for platelets in suspension. However, the present investigations on single adherent platelets reveal for the first time that adhesion and spreading of platelets is not necessarily associated with the appearance of procoagulant sites. Secondly, an unexpected diversity was observed among adherent platelets with respect to sensitivity to Ca(2+)-induced generation of procoagulant sites and Ca(2+)-induced vesiculation of plasma membrane. It is tempting to speculate that this diversity is of importance for the procoagulant response of platelets to a hemostatic challenge elicited by an injured vessel wall.     

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.     

Serotonin organelles of rabbit platelets contain synaptophysin

Synaptophysin, an integral membrane protein of synaptic vesicles in nerve terminals and a class of small translucent vesicles in neuroendocrine cells, was detected in intact rabbit platelets by immunoblotting, immunofluorescence staining and immuno-electron microscopy. In a highly purified preparation of serotonin organelles isolated from rabbit platelets, synaptophysin was enriched approximately 10-15-fold over platelet homogenate. About 80% of total platelet synaptophysin was present in this purified fraction. The apparent molecular mass (approximately 38 kDa) and the extent of glycosylation of platelet-derived synaptophysin was more similar to the neuronal than to the neuroendocrine form of the protein. Immunofluorescence microscopy revealed that synaptophysin was compartmentalized in intact rabbit platelets and immuno-electron microscopy of subcellular fractions showed that it was localized exclusively to the membrane surface of serotonin organelles. No synaptophysin-like immunoreactivity was detected in platelets from other species such as human, guinea pig and rat. Another integral membrane protein of synaptic vesicles, p65, and a family of synaptic vesicle-associated phosphoproteins, the synapsins, were not detected in platelets of any species tested. These results provide evidence that serotonin organelles from rabbit platelets share a subset of protein components with synaptic vesicles from neurons. Synaptophysin in serotonin organelles from rabbit platelets, as suggested for small synaptic vesicles in neurons, might play a role in the formation of protein channels for the exocytotic release of serotonin.     

Correlation of thrombin-induced glycoprotein V hydrolysis and platelet activation

To assess the possibility that hydrolysis of the platelet surface thrombin substrate, glycoprotein V, is a necessary step in thrombin-induced platelet activation, thrombin-catalyzed hydrolysis of glycoprotein V was correlated with thrombin-induced platelet activation. Hydrolysis of tritium-labeled glycoprotein V on washed human platelets was measured by the appearance of a labeled supernatant fragment, and platelet activation was measured as secretion of ATP. Hydrolysis of glycoprotein V was linear with respect to both thrombin concentration and time of incubation. The extent of platelet activation was correlated with the rate of hydrolysis but not with the amount hydrolyzed. Maximum platelet activation could be obtained with thrombin treatments resulting in hydrolysis of as little as 4% of glycoprotein V per min. Glycoprotein V was partially removed from platelets by pretreatment with either platelet calcium-dependent protease or chymotrypsin. The rate of thrombin-catalyzed hydrolysis of the remaining glycoprotein V from these pretreated platelets was as little as 1.5% the rate from control platelets, but there was no impairment of the extent of platelet activation. Thus, these protease-pretreated platelets compared with control platelets showed a different correlation of glycoprotein V hydrolysis with platelet activation. Glycoprotein V was also partially removed by pretreatment of prostacyclin-inhibited platelets with thrombin. After removal of thrombin and prostacyclin, these platelets were desensitized to subsequent activation by thrombin. Incubation of desensitized platelets with nonsaturating levels of thrombin led to less than 25% of the activation seen with control platelets but to a slightly greater hydrolysis of glycoprotein V. Thus, the desensitization to thrombin was not due to loss of ability of the activating thrombin to hydrolyze glycoprotein V. These results do not exclude a role for glycoprotein V as a component of the platelet thrombin receptor, but they indicate that there is no simple relationship between thrombin-induced hydrolysis of glycoprotein V and platelet activation.     

Neuraminidase-induced thrombocytopenia in mice: effects on thrombopoiesis

Previous studies to examine the effects of thrombocytopenia on thrombopoiesis have generally utilized immune-mediated platelet depletion. We have developed a nonimmune model to exclude the possibility that adverse immune-mediated effects have been misinterpreted as the physiological response to stimulation of thrombopoiesis. Thrombopoiesis was examined in mice after induction of thrombocytopenia with a single injection of the nonimmunologic agent neuraminidase (Ndase). Utilizing electron microscopy, we examined platelets and megakaryocytes (MK) obtained 8, 12, 24, 48, 72, 96, and 120 hr after administration of Ndase. Eight to 48 hr after induction of acute, severe thrombocytopenia (mean platelet count less than 50,000/microliters), the medians of the platelet sectional area distributions, as measured morphometrically, were significantly greater than the median platelet sectional area of pooled controls. The maximum median value for platelet sectional area was observed at 24 hr. The largest platelets in these samples contained more profiles of endoplasmic reticulum and Golgi cisternae, and a lower concentration of surface-connected canalicular system, as compared with normal platelets. By 72 hr post-injection of Ndase, virtually all platelets exhibited normal size and organelle complement. Mean platelet volumes, determined by electrical impedance analysis, paralleled the serial changes in platelet sectional areas. MK frequency and ploidy, measured by two-color fluorescence activated flow cytometry, were unchanged 12 and 24 hr following Ndase. At 48 hr, total MK frequency increased significantly (P less than 0.01) from 0.11% to 0.17%, and MK ploidy distribution shifted with a reduction in 16N MK (P less than 0.005) and an increase in 32N MK (P less than 0.01). MK ploidy was maximally altered from normal at 72 hr with increased 32N MK frequency (32.0%, P less than 0.001) and increased 64N MK frequency (2.4%, P less than 0.005). Morphologic and morphometric examination of MK at all time points did not reveal detectable changes from normal in cytoplasmic appearance or size, respectively. Therefore, we have demonstrated marked alterations of morphology and size of platelets, and of MK ploidy, using this nonimmunologic model. These studies further support our previous observations that megakaryocyte ploidy and platelet volume are independently regulated in response to depletion of the circulating platelet mass, and they show that these changes are not dependent upon the mechanism of thrombocytopenia.     

Molecular link between membrane cholesterol and Na+/H+ exchange within human platelets.

Incubation of human platelets with cholesterol-poor, cholesterol-normal and cholesterol-rich liposomes revealed that: (i) acquisition or depletion of platelet membrane cholesterol was highly selective; (ii) variation in membrane cholesterol was highly selective. Variation in membrane cholesterol content (cholesterol-to-phospholipid molar ratio from 0.15-1.2) with respect to values found in unmodified normal platelets, was paralleled by the observed changes in amiloride-sensitive cytoplasmic pH, as well as phospholipase A2 activity. However, a decrease in cytoplasmic pH was accompanied by an increase in phospholipase A2 activity; (iii) membrane cholesterol-modulated changes in intra-platelet pH, as well as phospholipase A2 activity, was completely inhibited when platelets were pretreated with quinacrine (a specific phospholipase A2 inhibitor) before exposure to various types of liposomes. Although exposure of platelets (pretreated with amiloride) with various types of liposomes resulted in the inhibition of Na+/H+ exchange it had no noticeable effect upon the observed phospholipase A2 activity. Based upon these results we suggest that membrane cholesterol-modulated phospholipase A2 activity may be the basic mechanism responsible for the nature of Na+/H+ exchanger activity observed in cholesterol-enriched platelets, leading these platelets to a hypersensitized state.     

Functional distinction between serotonin uptake and serotonin-induced shape change receptors in rat platelets

Tyramine and dopamine are taken up by rat platelets through the serotonin uptake mechanism while phenethylamine is not taken up. This indicates that an aromatic hydroxyl group is a structural requirement for the uptake of phenethylamine derivatives by rat platelets. Although none of these phenethylamine derivatives induce platelet shape change, they inhibit serotonin-induced shape change and serotonin uptake with the same relative potency ($\text{tyramine}\text{>}\text{phenethylamine}\text{?}\text{dopamine}$). This suggests that the receptors controlling serotonin uptake and serotonin-induced shape change have a common structural component that binds phenethylamine derivatives. However, the fact that phenethylamine derivatives activate the serotonin uptake mechanism but do not induce platelet shape change suggests that serotonin uptake and serotonin-induced shape change are mediated by two distinct activation sites of serotonin receptors.     

Action of antitumoral platinum complexes on in vitro platelet functions

This report presents a comparison of the effects of cis- and trans-diamminedichloroplatinum complexes on in vitro platelet functions. Pretreatment of platelets with cis-platinum (cisplatin) induced a slow, dose-dependent (0.1–0.45 mM), increase in the cytosolic Ca²⁺ concentration, pleckstrin (47 kDa) phosphorylation and serotonin secretion, as well as a slight shape modification with emission of a few pseudopodia. All these effects were remarkably increased in platelets exposed to trans-platinum (transplatin). The rise in cytosolic Ca²⁺ concentration and serotonin secretion evoked by stimulation of platelets with thrombin were not significantly influenced by cellular exposure to cis-platinum, whereas they were enhanced and inhibited, respectively, by exposure to trans-platinum. Trans-platinum also inhibited thrombin-promoted platelet aggregation to a greater extent than the cis-isomer. While the viscosity of platelet rich-plasma tended to decrease in the presence of cis-platinum, it tended to increase in the presence of trans-platinum. Taken together, these results indicate that the effects on platelet functions of the efficacious antitumor complex cis-platinum is rather different from that of the inactive complex trans-platinum. Therefore, the in vitro tests of platelet functions employed in this study might provide an index of antitumor drug toxicity and serve as a preliminary indicator of therapeutic efficacy.     

The effect of different methods of isolating thrombocytes on the surface structure and biochemical parameters of the serotonin system of these cells]

The method of platelets' isolation influences their morphofunctional state. The study of the surface structure of platelets with the method of scanning electron microscopy shows, that the nonactivated form of platelets is characterized for the cells, isolated by gel filtration, but platelets which are isolated by centrifugation are activated. Platelets' activation under centrifugation is shown to connect with the changes of biochemical parameters of platelet serotonin system: the increase of the velocity of the 3H-serotonin reuptake and of the 3H-imipramine specific binding.     

Effects of propranolol and pindolol on platelet aggregation and serotonin release

The aggregation of human platelets by adrenaline and adenosine di-phosphate (ADP) and its inhibition by β-blockers was studied by measuring the light transmission of plateletrich plasma (PRP) and suspensions of washed platelets exposed to these agents. Inhibition of aggregation of PRP and washed platelets was dose related in the two β-blockers tested: propranolol and pindolol. The potent β-blockers pindolol was less inhibitory than propranolol when adrenaline and ADP were used to induce platelet aggregation. The aggregation of platelets by adrenaline has two phases. With low doses of the blockers only the second phase was inhibited whereas higher doses blocked both phases. Preincubation of human platelets (PRP and washed platelets) with both blockers per se resulted in release of ¹⁴C-labelled serotonin. Propranolol released more serotonin than pindolol. There was no concomitant release of lactic dehydrogenase. It is concluded that the effects of propranolol and pindolol on platelets do not correlate with the β-blocking activity of these agents. Rather, the more lypophilic agent, propranolol, is more active both in inhibition of aggregation and in releasing platelet serotonin. It is suggested that these actions of the drugs are related to their non-specific membrane effects.