Epinephrine potentiates calcium mobilization and activation of protein kinases in platelets stimulated by ADP through a mechanism unrelated to phospholipase C

ADP, added to suspensions of aspirinized 32P-prelabelled washed platelets, induced reversible platelet aggregation, the rapid elevation of cytosolic Ca2+ (maximum at 2 s), 20 kDa myosin light chain phosphorylation (maximum faster than 3 s), 40 kDa protein phosphorylation (maximum at 3-10 s) and phosphatidic acid formation (maximum at 30 s). Prior addition of epinephrine potentiated platelet aggregation, cytosolic Ca2(+)-elevation, 20 and 40 kDa protein phosphorylation evoked by ADP, but it did not enhance phosphatidic acid formation induced by ADP. The potentiating effect of epinephrine on aggregation, cytosolic Ca2(+)-increase and 20 and 40 kDa protein phosphorylation induced by ADP was also observed in the presence of EGTA. Ethylisopropylamiloride, an inhibitor of Na+/H(+)-exchange, did not affect the potentiation of ADP-induced platelet aggregation by epinephrine. We conclude that epinephrine primes platelets to increase Ca2(+)-influx and Ca2(+)-mobilization in response to ADP. The potentiation of cytosolic Ca2(+)-elevation by epinephrine leads to further stimulation of myosin light chain phosphorylation and protein kinase C activation and ultimately to enhanced platelet aggregation. These effects of epinephrine do not seem to take place at the level of phospholipase C.     

Interaction between ATP and catecholamines in stimulation of platelet aggregation

Platelets, on activation by endothelial damage, release ADP, ATP, serotonin, epinephrine, and norepinephrine. Although ATP is known to augment the action of norepinephrine in cardiovascular and endocrine systems, the possible interaction between ATP and catecholamines in regulation of platelet reactivity has not been reported. The addition of ATP (1-5 microM) to human platelet-rich plasma did not induce platelet aggregation; however, it selectively augmented the aggregatory response to norepinephrine and epinephrine, but not to serotonin. This potentiating action of ATP was dose dependent and was not due to contamination by, or hydrolysis to, ADP. The action of ATP was blocked by 10 microM of adenosine 3'-phosphate 5'-phosphosulfate, a selective P(2)Y(1) receptor antagonist. ATP alone did not cause release of intracellular Ca(2+), but produced a significant Ca(2+) response in the presence of norepinephrine. In contrast, the P(2)X(1) receptor agonists P(1),P(6)-diadenosine-5' hexophosphate and alpha,beta-methylene-ATP had no effect on norepinephrine-induced platelet aggregation even when added at 100 microM. This synergistic interaction between ATP and norepinephrine in stimulating platelet aggregation may have significant clinical implications and suggests a prothrombotic role for ATP in stress.     

Inhibition of hemostasis by a high affinity biogenic amine-binding protein from the saliva of a blood-feeding insect

The saliva of the blood-feeding insect Rhodnius prolixus contains numerous pharmacologically active substances. Included among these are a number of lipocalin proteins that bind various ligands important in hemostasis and inflammation. One such protein is a biogenic amine-binding protein (ABP) that binds serotonin, epinephrine, and norepinephrine. Based on amino acid alignments, it is most similar to the nitrophorin group of lipocalins found in the same insect species. Physiologically, this protein appears to act as both a vasodilator and platelet aggregation inhibitor. This protein inhibits smooth muscle contraction of the rat uterus in response to serotonin and of the rabbit aorta in response to norepinephrine. Platelet aggregation induced by a combination of low concentrations of ADP and either serotonin or epinephrine is inhibited because of the binding of serotonin and epinephrine. Potentiation of aggregation induced by low concentrations of collagen along with serotonin or epinephrine is also inhibited. Dissociation constants for biogenic amines were measured using isothermal titration calorimetry and the Hummel-Dreyer method of equilibrium gel filtration. In this manner, K(d) values of 102, 24, and 345 nm were found for serotonin, norepinephrine, and epinephrine, respectively. Molecular modeling of ABP suggests that ligand binding is mediated by interaction with the side chains of aromatic amino acids and charged residues that line the binding pocket.     

Action of aminoglycosides on platelet aggregation in vitro

The authors tested the influence of gentamicin, spectinomycin dihydrostreptomycin on the ADP and epinephrine in vitro induced platelet aggregation. Our aim was to demonstrate if platelet aggregation in vitro had some influences by antibiotics. A reduction in platelet aggregability, strictly dependent from the used antibiotic dose was observed. We have studied platelet function thanks to Born's method, adding to PRP gradual therapeutics doses of antibiotics. The results showed a reduction of platelet function which was dose-depended, and, particularly, gentamicin seemed to be the most effective among aminoglycosides. An interference between these drugs and the ADP and epinephrine binding to specific platelet receptor sites is proposed.     

蛋白激酶C在血小板聚集中的作用

利用￣（３２）Ｐ－ＮａＨ２ＰＯ４标记猪血小板,以蛋白激酶Ｃ的４０ｋＤ底物为蛋白激活的标志．用血小板激动剂在聚集浓度范围内处理血小板,结果表明,除了不能使猪血小板聚集的肾上腺素外,凝血酶等激动剂都使血小板４０ｋＤ底物蛋白磷酸化明显增加,同时３８ｋＤ,２６ｋＤ蛋白质磷酸化也明显增加,且４０ｋＤ底物磷酸化与血小板聚集有平行增加关系．蛋白激酶Ｃ在血小板聚集中可能起着重要的调节作用。     

Ca2+ signaling in the transformation of promastigotes to axenic amastigotes of Leishmania donovani

Three acidic phospholipases A₂ from Indian cobra (Naja naja naja) venom inhibited platelet aggregation in platelet rich plasma induced separately by ADP, collagen and epinephrine with different potencies. The order of inhibition was epinephrine > collagen > ADP. They did not inhibit platelet aggregation induced by arachidonic acid (10 M). The inhibition was dependent on concentration of the protein and the time of incubation of the phospholipases A₂ with platelet rich plasma. Parabromophenacyl bromide modified PLA₂ enzymes lost their enzymatic activity as well as platelet aggregation inhibition activity suggesting the involvement of catalytic function in platelet aggregation inhibitory activity.     

Dependence of the thrombocyte aggregation reaction on plasma fibronectin and the tripeptide arginyl-glycyl-asparagilin

If was shown that the addition of fibronectin antibodies exerted the inhibition of platelet aggregation. The tripeptide RGD inhibited the platelet aggregation induced by the same agents (ADP, epinephrine, thrombin, collagen) both in blood plasma and in suspension of washed platelets.     

Effect of heparin on platelet aggregation in vitro

Heparin added to citrated platelet rich plasma influences shape change and aggregation of platelets in different ways. In the presence of heparin neither ADP nor collagen induces shape change, while shape change after thrombin or arachidonic acid remains unaltered. Heparin potentiates the first aggregation step induced by ADP and epinephrine but inhibits aggregation induced by thrombin and ristocetin. The second phase of aggregation and the release reaction are not directly influenced by heparin no matter which aggregation agent is used.     

Epinephrine and shear stress synergistically induce platelet aggregation via a mechanism that partially bypasses vWF-Gp Ib interactions

Elevated shear stress levels in pathologically stenosed vessels induce platelet activation and aggregation, and may play a role in the pathogenesis of arterial disease. Increased plasma catecholamine concentrations have also been implicated in the onset of acute coronary ischemic syndromes. This study was designed to examine the synergistic interaction of shear stress and epinephrine in the activation of platelets. Platelets (in PRP) sheared at 60 dyn/cm² showed little or no aggregation unless pretreated with epinephrine. Pretreatment with 250 nM epinephrine followed by shear at 60 dyn/cm² induced >60% platelet aggregation. The specific α₂-adrenergic receptor antagonist yohimbine inhibited the synergistic aggregation, as did the ADP scavenging system phosphocreatine/creatine phosphokinase, indicating a three-way synergism with ADP. Chemical or monoclonal antibody blockade of von Willebrand factor (vWF) interactions with either platelet glycoprotein (Gp) Ib or Gp IIb/IIIa completely inhibited platelet aggregation induced by activating levels of shear stress alone. However, the combination of epinephrine and shear stress induced platelet aggregation that was blocked by 10E5, a monoclonal antibody that inhibits vWF binding to Gp IIb/IIIa, but not by aurin tricarboxylic acid or the monoclonal antibody 6D1, both of which inhibit vWF binding to Gp Ib. Synergistic platelet aggregation in response to epinephrine and shear stress was observed in washed platelets, platelet-rich plasma and whole blood in vitro, and also ex vivo following exercise to elevate endogenous levels of catecholamines. These results indicate that epinephrine synergizes with shear stress to induce platelet aggregation. This synergistic response requires functional Gp IIb/IIIa complexes, but is at least partially independent of vWF-Gp Ib interactions.     

Thiopental enhances human platelet aggregation by increasing arachidonic acid release.

Conflicting results have been reported regarding the effect of thiopental on aggregation and cytosolic calcium levels in platelets. The present study attempted to clarify these phenomena. Using platelet-rich plasma or washed suspensions, platelet aggregation, thromboxane (TX) B2 formation, arachidonic acid (AA) release, and cytosolic free calcium concentrations ([Ca2+]i) were measured in the presence or absence of thiopental (30-300 microM). Platelet activation was induced by adenosine diphosphate (ADP, 0.5-15 microM), epinephrine (0.1-20 microM) arachidonic acid (0.5-1.5 mM), or (+)-9,11-epithia-11,12-methano-TXA2 (STA2, 30-500 nM). Measurements of primary aggregation were performed in the presence of indomethacin (10 microM). Low concentrations of ADP and epinephrine, which did not induce secondary aggregation in a control study, induced strong secondary aggregation in the presence of thiopental (> or = 100 microM). Thiopental (> or = 100 microM) also increased the TXB2 formation induced by ADP and epinephrine. Thiopental (300 microM) increased ADP- and epinephrine-induced 3H-AA release. Thiopental (300 microM) also augmented the ADP- and epinephrine-induced increases in [Ca2+]i in the presence of indomethacin. Thiopental appears to enhance ADP- and epinephrine-induced secondary platelet aggregation by increasing AA release during primary aggregation, possibly by the activation of phospholipase A2.     

Leptin Does Not Play a Major Role in Platelet Aggregation in Obesity and Leptin Deficiency

Objective: A recent study suggested that high concentrations of leptin enhance platelet aggregations. Therefore, the aim of this study was to investigate whether platelet aggregation is altered in patients with leptin gene mutations compared with obese subjects or controls. Research Methods and Procedures: Four men (one homozygous man and his three heterozygous brothers) carrying a leptin gene mutation; 20 age‐matched, healthy, unrelated men; and 18 age‐matched obese men were enrolled in the study. Adenosine diphosphate (ADP)‐, collagen‐, and epinephrine‐induced platelet aggregation were evaluated in all individuals. Results: Our results show that patients with the leptin gene mutation (both the homozygous and heterozygous patients) had significantly higher ADP‐induced (78.3 ± 3.4% vs. 57.9 ± 9.3%, p = 0.001), collagen‐induced (78.1 ± 2.9% vs. 56.7 ± 9.3%, p = 0.007), and epinephrine‐induced (76.5 ± 9.2% vs. 59.5 ± 7.70%, p = 0.003) platelet aggregation compared with controls. However, ADP‐, collagen‐, or epinephrine‐induced platelet aggregations were similar to those in obese patients. Platelet aggregation responses to a combination of pretreatment with leptin at concentrations of 20, 50, 100, or 500 ng/mL for 5 minutes and ADP at concentrations of 2 μmol/liter also were evaluated. However, we did not find significant increases in platelet aggregation even at high concentrations of leptin (100 or 500 ng/mL) in leptin‐deficient patients, obese subjects, or controls. Discussion: Our data show that similar to findings in obese humans, homozygous or heterozygous leptin deficiency is associated with increased platelet aggregation compared with controls, and that higher concentrations of leptin do not increase platelet aggregation.     

Aggregin: a platelet ADP receptor that mediates activation

ADP is known to induce platelet shape change, aggregation, and exposure of fibrinogen binding sites as well as inhibit stimulated adenylate cyclase. The platelet is unique in that its purinergic receptor prefers ADP over ATP, which functions as a competitive antagonist. The affinity reagent, 5'-p-fluorosulfonylbenzoyl adenosine (FSBA), has been used to covalently label a single membrane protein, aggregin, on the external platelet surface with mol wt of 100 kDa. Concomitant with incorporation of FSBA, ADP-induced shape change, aggregation, and fibrinogen binding is inhibited. FSBA is also a weak agonist at short times and high concentration, which suggests that prior noncovalent binding to aggregin takes place before covalent modification. Aggregin differs from platelet glycoprotein IIIa in its physical and immunochemical properties. Aggregin is distinct from the receptor coupled to adenylate cyclase. Using FSBA as a probe, platelet aggregation by thromboxane A2 analogs and collagen was shown to be dependent on ADP but not the shape change induced by these agonists. Binding to aggregin is required for epinephrine-induced aggregation. In turn, epinephrine increases the affinity of ADP for its receptor. Thrombin at concentrations greater than 2 nM (0.2 units/ml) stimulates platelet aggregation independent of ADP, but by raising cytoplasmic Ca2+ it activates platelet calpain, which in turn cleaves aggregin. Thus aggregin, in addition to serving as the ADP receptor linked to shape change and aggregation, plays a role in fibrinogen receptor latency that is relieved entirely by ADP binding to or proteolysis of aggregin.     

Platelet ADP receptor and alpha 2-adrenoreceptor interaction. Evidence for an ADP requirement for epinephrine-induced platelet activation and an influence of epinephrine on ADP binding

The nucleotide affinity analog 5'-p-fluorosulfonylbenzoyl adenosine (FSBA) is a potent irreversible inhibitor of ADP-mediated platelet activation. Utilizing this compound, the role of ADP in epinephrine-mediated platelet activation was evaluated. Pretreatment of platelets with FSBA under conditions producing covalent incorporation was able to completely block epinephrine-stimulated aggregation of human platelets. In addition, the exposure of latent fibrinogen-binding sites by epinephrine was also inhibited in platelets modified by FSBA. The inhibition of epinephrine-mediated activation of the cells was time dependent, reflecting the need for covalent modification of the ADP receptor by FSBA. The inhibitory effect of FSBA was not due to effects on the affinity of binding methyl [3H]yohimbine or the number of platelet alpha 2-adrenergic receptors. Studies of the effect of epinephrine on the ability of ADP to protect against FSBA incorporation demonstrated that epinephrine can increase the affinity of ADP for its receptor 10-fold without affecting the total amount of FSBA covalently bound. This effect of epinephrine is mediated through the alpha 2-adrenoreceptor since the effect can be reversed by the competitive antagonist, methyl yohimbine. These results suggest that promotion of platelet aggregation and the exposure of fibrinogen receptors by epinephrine is dependent on ADP. The mechanism by which epinephrine renders low concentrations of ADP effective appears to be mediated by an increased avidity of the ADP receptor for the nucleotide.     

Effect of homocysteine, cysteine, and their derivatives on the platelet link of hemostasis system

The influence of homocysteine, homocysteine thiolactone, cysteine and their derivatives on activation and aggregation of human platelets was investigated using the model systems in vitro. It was established that homocysteine and cysteine increased platelet aggregation induced by ADP, epinephrine, or collagen. Their action began in a range of concentrations such as their physiological blood levels (10 microM) and was increasing with the rise of their concentrations. Cysteine increased ADP-induced platelet aggregation, hardly any affect on epinephrine-induced platelet aggregation and depressed collagen-induced platelet aggregation in the highest concentration (1000 microM). Their disulfides and thioethers did not influence platelet aggregation.     

The effect of halofenate and clofibrate on aggregation and release of serotonin by human platelets.

The hypolipidemic drugs halofenate and clofibrate inhibit the aggregation of human platelets induced by ADP, collagen and epinephrine. The effect of the drugs is primarily on the “second wave” of aggregation which is associated with the platelet release reaction. The drugs also inhibit the release of serotonin from platelets suggesting that the effect on aggregation is attributable to an inhibition of the release reaction. Halofenate is much more potent than clofibrate in inhibiting both the release of serotonin and the second wave of aggregation.     

Cyclic nucleotides and platelet aggregation. Effect of aggregating agents on the activity of cyclic nucleotide-metabolizing enzymes.

The activities of adenylate and guanylate cyclase and cyclic nucleotide 3':5'-phosphodiesterase were determined during the aggregation of human blood platelets with thrombin, ADP, arachidonic acid and epinephrine. The activity of guanylate cyclase is altered to a much larger degree than adenylate cyclase, while cyclic nucleotide phosphodiesterease activity remains unchanged. During the early phases of thrombin-and ADP-induced platelet aggregation a marked activation of the guanylate cyclase occurs whereas aggregation induced by arachidonic acid or epinephrine results in a rapid diminution of this activity. In all four cases, the adenylate cyclase activity is only slightly decreased when examined under identical conditions. Platelet aggregation induced by a wide variety of aggregating agents including collagen and platelet isoantibodies results in the "release" of only small amounts (1-3%) of guanylate cyclase and cyclic nucleotide phosphodiesterase and no adenylate cyclase. The guanylate cyclase and cyclic nucleotide phosphodiesterase activities are associated almost entirely with the soluble cytoplasmic fraction of the platelet, while the adenylate cyclase if found exclusively in a membrane bound form. ADP and epinephrine moderately inhibit guanylate and adenylate cyclase in subcellular preparations, while arachidonic and other unsaturated fatty acids moderately stimulate (2-4-fold) the former. It is concluded that (1) the activity of platelet guanylate cyclase during aggregation depends on the nature and mode of action of the inducing agent, (2) the activity of the membrnae adenylate cyclase during aggregation is independent of the aggregating agent and is associated with a reduction of activity and (3) cyclic nucleotide phosphodiesterase remains unchanged during the process of platelet aggregation and release. Furthermore, these observations suggest a role for unsaturated fatty acids in the control of intracellular cyclic GMP levels.     

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).     

Induction of the fibrinogen receptor on human platelets by epinephrine and the combination of epinephrine and ADP

The capacity of epinephrine alone and the combination of low dose epinephrine and ADP to support the binding of fibrinogen to washed human platelets has been examined, 125I-Fibrinogen was bound to epinephrine-stimulated platelets, but 90 min were required to achieve maximal binding at 22 degrees C in contrast to 20 to 30 min with ADP. The overall rate of interaction appeared to reflect the slow binding of fibrinogen to epinephrine-stimulated platelets as opposed to the rate of stimulation of the cell. Divalent ions were required for binding of fibrinogen to epinephrine-stimulated platelets, and both calcium and magnesium supported binding with a prolonged time course. Fibrinogen binding was maximally supported by 20 to 30 microM epinephrine. The combination of low dose epinephrine (5 microM) and low dose ADP (0.5 microM), which acted synergistically to induce platelet aggregation, supported the rapid (10 min) binding of fibrinogen to platelets. With 4 microM epinephrine, more fibrinogen bound per platelet at all ADP doses than with ADP alone. With all the stimuli, saturable binding of fibrinogen to the platelet was observed, and Scatchard plots were linear, yielding very similar apparent association constants. The number of molecules bound per cell was stimulus-dependent, with 30 microM epinephrine inducing the binding of fewer fibrinogen molecules per cell (mean = 20,400) than 10 microM ADP (mean = 35,900) or the combination of 5 microM epinephrine + 0.5 microM ADP (mean = 43,600). The participation of endogenous ADP in fibrinogen binding to epinephrine-stimulated platelets was suggested since enzymes which remove ADP, apyrase, and creatine phosphate/creatine phosphokinase, and the ADP analogue, 2-chloroadenosine, completely inhibited the binding of fibrinogen to the platelet.     

Effects of C-reactive protein on platelet function. III. The role of cAMP, contractile elements, and prostaglandin metabolism in CRP-induced inhibition of platelet aggregation and secretion.

It was previously demonstrated that C-reactive protein (CRP) inhibits platelet aggregation and release reactions, activation of platelet factor 3, and platelet-dependent clot retraction. Multiple considerations including selective inhibition of secondary wave aggregation suggested that CRP exerted its inhibitory effects by interfering with the release of endogenous ADP. In the present investigation, CRP was found by direct assay to inhibit the release of endogenous ADP and/or serotonin concomitant with inhibition of platelet aggregation stimulated by ADP, epinephrine, thrombin, and AHGG. CRP did not induce an increase in the basal level of platelet cAMP, suggesting independence of a direct effect upon this mediator system. Furthermore, CRP did not inhibit the aggregation and secretion induced by the antibiotic ionophore A23187, suggesting the absence of a direct effect upon the activation of platelet contractile elements. By contrast, CRP did inhibit both thrombin-induced release of malondialdehyde, a prostaglandin endoperoxide nonprostanoate endproduct, and platelet aggregation induced by the prostaglandin endoperoxide precursor arachidonic acid. These data, therefore, raise the possibility that CRP inhibits platelet reactivities by interfering with an aspect of porstaglandin metabolism, and that this occurs subsequent to the hydrolytic accumulation of arachidonic acid and prior to the movement of calcium from the platelet dense tubules. These studies support the concept that CRP serves to modulate platelet reactivities during acute inflammatory reactions.     

Aggregation-induced alterations in human platelet membranes: A spin label study

Washed human platelets were labeled with stearate or methyl stearate spin probe. The order parameter of stearate spin probe was decreased markedly when the platelets were aggregated by thrombin, ADP or epinephrine. Central peak width of methyl stearate spin probe was also reduced in the aggregation induced by thrombin and ADP. However, isolated plasma membrane did not show any decrease of the order parameter by the addition of thrombin. Aspirin inhibited both the platelet aggregation and the decrease of the order parameter. The results suggest that ESR spectral changes might be caused by reorganization of membrane constituents rather than their quantitative or qualitative alteration.