钙离子通道A23187对血小板聚集和蛋白质磷酸化的影响

以 ³²P-Na₂HPO₄标记猪血小板,在阿斯匹林阻断花生四烯酸代谢,Apyrase去除分泌的ADP情况下,以A23187和PMA为血小板激动剂,staurosporine为PKC抑制剂,研究Ca²⁺和蛋白激酶C在血小板聚集中的作用.结果表明,a.A23187在1～20 μmol/L引起血小板聚集,相应地,明显地引起40 ku、20 ku蛋白质磷酸化,且存在剂量和时间效应关系.b.A23187和PMA在血小板聚集和蛋白质磷酸化上都存在着协同效应.c.1 μmol/L staurosporine可大部分抑制20 μmol/L A23187诱导的血小板聚集和20 ku、40 ku蛋白质磷酸化.结果提示,Ca²⁺激活血小板是建立在激活PKC的基础上,Ca²⁺通过激活PKC诱导血小板聚集,这是Ca²⁺激活血小板的主要途径.     

激光散射浊度法测定剪切诱导血小板聚集

剪切诱导血小板聚集（ＳＩＰＡ）对动脉血栓性疾病的防治有十分重要的意义。利用激光散射浊度法的测量原理,在北京世帝科学仪器公司ＬＧ—Ｂ—１９０红细胞变形／聚集测试仪的基础上,经改进研制成功了测定剪切诱导血小板聚集的实验装置;该装置能方便地控制剪切率与剪切时间,并能连续记录血小板在剪切过程中的聚集情况。是研究ＳＩＰＡ的机理及抗ＳＩＰＡ的机理及抗ＳＩＰＡ药理的有力工具。     

长角血蜱唾液腺中胶原特异性血小板聚集抑制因子的纯化及机制的研究

从长角血蜱唾液腺匀浆纯化出一种新的胶原特异性血小板聚集抑制因子 ,命名为“longicornin” ,它能特异性地抑制胶原诱导的血小板聚集反应 ,而对其他激动剂如ADP、花生四烯酸、凝血酶、瑞斯托霉素、A2 31 87、U46 6 1 9、乙酸豆寇佛波醇所诱导的纯化的血小板聚集均无抑制作用 .longicornin还能抑制血小板激活过程 ,包括血小板颗粒的释放和细胞间质游离Ca ²⁺浓度的升高 ,对胶原与血小板的粘附无抑制作用 .longicornin可能与胶原在血小板上有同一受体 ,并且与血小板受体的结合是可逆的 .     

滇丹参注射液对兔血小板功能的影响

观察云南产滇丹参对血小板聚集功能的影响.方法采用Bom氏比浊法,测定滇丹参体内、体外对抗ADP、PAF、AA诱导的兔血小板聚集的作用.体外每种药物浓度分别为40 g/L、20 g/L、10 g/L、5 g/L、2.5 g/L,体内实验分为7组,即生理盐水组、两种丹参低中高剂量组分别为5 g/kg、10 g/kg、20 g/kg,每组6只.结果与对照组相比,滇丹参体外显著抑制ADP、AA诱导的血小板聚集,抑制效应呈浓度-效应关系(P＜0.05,0.01),IC50为33.7 g/L(ADP)、18.1 g/L(AA).滇丹参也显著抑制PAF诱导的血小板聚集,其最大抑制率为36.8%;体内实验结果显示,滇丹参在高剂量时可显著抑制ADP、PAF和AA诱导的血小板聚集(P＜0.05,0.01),且均具有剂量依赖性.滇丹参在药后20 min开始显效,40 min达到最大抑制作用,抑制率分别为95.6%(ADP)、91.5%(PAF)和88.5%(AA).结论以上结果表明,滇丹参体外、体内显著抑制血小板聚集,且其抗血小板聚集作用优于丹参,为进一步开发和利用滇丹参提供了依据.     

冠心病患者服用阿斯匹林、氯吡格雷前后血小板聚集功能比较

目的:通过比较冠心病患者单用或联用阿斯匹林、氯吡格雷前后血小板聚集功能,以指导临床用药.方法:将97例冠心病患者分成阿斯匹林组、氯吡格雷组和阿斯匹林与氯吡格雷两者联合用药组,比较各组用药前后四种不同诱导荆作用下血小板最大聚集率.结果:阿斯匹林组由花生四烯酸诱导血小板最大聚集率(29.9±11.0)与正常对照组(78.0±13.1)及用药前(96.8±8.1)比差异有非常显著意义;与之类似,氯吡格雷组由二磷酸腺苷诱导的血小板最大聚集率差异有非常显著意义;而联合用药组四种诱聚剂诱导的血小板最大聚集率差异均有显著意义.结论:阿斯匹林和氯吡格雷单用时对血小板聚集抑制作用仅限于ACA、ADP,而联合用药对四种诱聚剂均有抑制作用,因此联合用药对预防血栓形成更为有效.     

L—精氨酸L—门冬氨酸盐对血小板功能的抑制

用血小板聚集、粘附、释放实验和出血时间测定观察L-精氨酸*L-门冬氨酸盐(DR)对血小板功能的作用。实验结果显示DR15mg/kg静脉给药,可明显抑制腺苷二磷酸(ADP)诱导的大鼠血小板聚集(P<0.01);15mg/kg单次口服给药可明显抑制ADP诱导的家兔血小板聚集;其药效可持续8h以上(P<0.01);DR7.5、15、30mg/kg灌胃给药(Bid×3.5d),可明显抑制ADP、胶原或凝血酶诱导的大鼠血小板聚集(P<0.01),并延长出血时间(P<0.05)。DR30mg/kg可明显抑制大鼠血小板粘附,并促进血管内皮释放前列环素(PGI2),但对活化的血小板释放血拴素(TXA2)无明显影响。本研究发现,DR可抑制血小板聚集和粘附功能,其作用机制不同于阿司匹林。这些作用部分是由于DR增加了血管内皮PGI2的释放。此结果为血小板功能的调节提供了新线索。     

瑞舒伐他汀和阿托伐他汀在急性冠脉综合症中对氯吡格雷抗血 小板活性的对比研究

目的：在急性冠脉综合征( acute coronary syndromes, ACS )的治疗中,抗血小板治疗及调脂治疗是最基础的治疗方案。近来 有学者提出,氯吡格雷和他汀类药物都经过细胞色素CYP 3A4 途径代谢,二者因存在竞争性抑制,有可能降低氯吡格雷抗血小板 的活性。本试验将针对阿托伐他汀及瑞舒伐他汀进行研究。方法：选择急性冠脉综合症的患者42 例,所有患者均接受氯吡格雷治 疗（负荷剂量300 mg,维持剂量75 mg/d）。随机分配为A、B 两组,A 组（n=20）服用阿托伐他汀治疗（20 mg/d）,B 组（n=22 服用瑞 舒伐他汀治疗（10 mg/d）。分别于氯吡格雷服用前、服药治疗后3 天、服药治疗后7 天后采静脉血送检,测定ADP（10 滋mol/L）诱导 的血小板聚集率。结果：阿托伐他汀组（A 组）及瑞舒伐他汀组（B 组）相比,服用氯吡格雷前ADP 诱导的血小板聚集率基线值无 统计学差异。服用氯吡格雷3 日及7 日后,ADP诱导的血小板聚集率明显降低,(3.85± 2.58)vs(3.09± 2.27),(0.65± 0.88)vs(1.05± 0.95),P>0.05,无明显统计学差异。结论：氯吡格雷的确可以降低血小板的活性。同时,短期之内氯吡格雷的抗血小板活性未受到 他汀类的影响,包括经过CPY3A4途径的他汀,如阿托伐他汀。     

天麻成分对羟基苯甲醛抗血小板聚集作用及急性毒性研究

为探讨天麻成分对羟基苯甲醛的抗血小板聚集作用,本实验以二磷酸腺苷(ADP)、花生四烯酸(AA)、血小板活化因子(PAF)为诱导剂,探讨了对羟基苯甲醛的体外抗血小板聚集活性;采用ADP静脉注射致小鼠肺栓塞方法以及下腔静脉结扎致大鼠静脉血栓方法,考察了对羟基苯甲醛的体内抗血小板聚集活性;并对经口给药的对羟基苯甲醛的急性毒性进行了检测。结果表明,天麻成分对羟基苯甲醛对ADP诱导的家兔体外血小板聚集有明显的对抗作用,其半数抑制率(50%inhibitory concentration,IC50)为2mmol/L,对PAF诱导的家兔体外血小板聚集无明显影响;天麻成分对羟基苯甲醛能明显降低小鼠肺栓塞死亡率,并显著对抗大鼠下腔静脉血栓的形成。说明天麻成分对羟基苯甲醛在体外、体内均具有显著的抗血小板聚集活性。急性毒性研究结果表明天麻成分对羟基苯甲醛经口给药的小鼠半数致死量(lethal dose 50,LD50)为1.23 g/kg。     

紫锥菊提取物及酚酸化合物体外抗血小板聚集活性研究

为探究紫锥菊提取物及酚酸化合物体外抗血小板聚集活性,体外抗血小板聚集实验采用Born比浊法,以聚集抑制率和半数抑制浓度为指标评价。同时采用分子对接方法,选择凝血因子V(F5)、凝血因子VIII(F8)及凝血因子XI(F11)与酚酸类化合物进行虚拟对接,研究其抗血小板聚集的分子作用靶点。结果表明化合物S-1～S-10及其提取物对体外ADP诱导的血小板聚集有抑制作用,抑制率呈浓度依赖性,S-6与靶点的结合位点更多,选择性更强。紫锥菊中酚酸类化合物及其提取物在体外均显现出抗ADP诱导的血小板聚集活性,为紫锥菊体内研究提供依据。     

一种新型的α-纤维蛋白原酶对血小板聚集的影响

SDS-聚丙烯酰胺凝胶电泳(SDS-PAGE)检测中国眼镜蛇毒蛋白酶水解纤维蛋白原的作用方式,发现该蛋白酶可迅速水解纤维蛋白原Aα链,对γ链作用较弱,对Bβ链无作用,是一种新型的α-纤维蛋白原酶.用比浊法测定血小板聚集率,证实中国眼镜蛇毒蛋白酶低剂量(0.025 mg/kg)、中剂量(0.05 mg/kg)以及高剂量(0.1 mg/kg)体内给药浓度依赖性地抑制ADP(10 .Μmol/L)和胶原(100 mg/L)诱导的兔血小板聚集.     

Affinity labeling of a human platelet membrane protein with 5'-p-fluorosulfonylbenzoyl adenosine. Concomitant inhibition of ADP-induced platelet aggregation and fibrinogen receptor exposure

Incubation of washed human blood platelets with 5'-p-fluorosulfonylbenzoyl [3H]adenosine (FSBA) covalently labels a single polypeptide of Mr = 100,000. Protection by ADP has suggested that an ADP receptor on the platelet surface membrane was modified. The modified cells, unlike native platelets, failed to aggregate in response to ADP (100 microM) and fibrinogen (1 mg/ml). The extent of binding of 125I-fibrinogen and aggregation was inhibited to a degree related to the incorporation of 5'-p-sulfonylbenzoyl adenosine (SBA) into platelets, indicating FSBA could inhibit the exposure of fibrinogen receptors by ADP necessary for aggregation. Incubation of SBA platelets with alpha-chymotrypsin cleaved the covalently labeled polypeptide and concomitantly reversed the inhibition of aggregation and fibrinogen binding. Platelets proteolytically digested by chymotrypsin prior to exposure to FSBA did not require ADP for aggregation and fibrinogen binding. Moreover, subsequent exposure to FSBA did not inhibit aggregation or fibrinogen binding. The affinity reagent FSBA can displace fibrinogen bound to platelets in the presence of ADP, as well as promote the rapid disaggregation of the platelets. The apparent initial pseudo-first order rate constant of dissociation of fibrinogen was linearly proportional to FSBA concentrations. These studies suggest that a single polypeptide can be altered either by ADP-induced conformational changes or proteolysis by chymotrypsin to reveal latent fibrinogen receptors and promote aggregation of platelets after fibrinogen binding.     

Aggregation efficiency of activated normal or fixed platelets in a simple shear field: effect of shear and fibrinogen occupancy.

Shear rate can affect protein adsorption and platelet aggregation by regulating both the collision frequency and the capture efficiency (alpha). These effects were evaluated in well defined shear field in a micro-couette for shear rate G = 10 - 1000 s-1. The rate of protein binding was independent of G, shown for adsorption of albumin to latex beads and PAC1 to activated platelets. The initial aggregation rate for ADP-activated platelets in citrated platelet-rich plasma followed second order kinetics at the initial platelet concentrations between 20,000 and 60,000/microliters. alpha values, which dropped nearly fivefold for a 10-fold increase in G, were approximately proportional to G-1, contrary to a minor drop predicted by the theory that includes protein cross-bridging. Varying ADP concentration did not change alpha of maximally activated platelet subpopulations, suggesting that aggregation between unactivated and activated platelets is negligible. Directly blocking the unoccupied but activated GPIIb-IIIa receptors without affecting pre-bound Fg on "RGD"-activated, fixed platelets (AFP) by GRGDSP or Ro 43-5054 eliminated aggregation, suggesting that cross-bridging of GPIIb-IIIa on adjacent platelets by fibrinogen mediates aggregation. Alpha for AFP remained maximal (approximately 0.24) over 25-75% Fg occupancy, otherwise decreasing rapidly, with a half-maximum occurring at around 2% occupancy, suggesting that very few bound Fg were required to cause significant aggregation.     

Inhibition by ADP of prostaglandin induced accumulation of cyclic AMP in intact human platelets

The influence of extracellular ADP on cyclic AMP accumulation within intact human platelets was studied. ADP inhibited the increase in cyclic AMP which occurs when platelets are exposed to prostaglandin E1 or I2. The degree of inhibition varied in the range 70-95% , and was half maximal at ADP concentrations of between 0.3 and 2 microM. Other naturally occurring diphosphates, i.e. GDP, IDP and UDP, were at least 100 fold less effective than ADP, and UDP at 1mM partially reversed the effect of ADP. The effect by ADP was completely reversed by ATP, but only attenuated to a minor degree of 10 mM EDTA. Increasing concentrations of ADP caused a progressive degree of inhibition of cyclic AMP accumulation, and the kinetics of this inhibition were compatible with a simple saturable process with no cooperativity. ADP added 10 seconds after prostaglandin E1 blocked cyclic AMP accumulation within 1-2 seconds, and addition of ATP after ADP and prostaglandin I2 relieved the inhibition due to ADP within 2-3 seconds. The action of ADP was blocked by sulphydryl reagents including N-substituted maleimides, cytochalasin A, NBD chloride and p-mercuribenzene sulphonate. The data were considered to be consistent with mediation of the ADP effect through a sulphydryl-bearing specific extracellular receptor coupled to the adenylate cyclase.     

Physical and chemical effects of red cells in the shear-induced aggregation of human platelets.

Both chemical and physical effects of red cells have been implicated in the spontaneous aggregation of platelets in sheared whole blood (WB). To determine whether the chemical effect is due to ADP leaking from the red cells, a previously described technique for measuring the concentration and size of single platelets and aggregates was used to study the shear-induced aggregation of platelets in WB flowing through 1.19-mm-diameter polyethylene tubing in the presence and absence of the ADP scavenger enzyme system phosphocreatine-creatine phosphokinase (CP-CPK). Significant spontaneous aggregation was observed at mean tube shear rates, (G) = 41.9 and 335 s-1 (42% and 13% decrease in single platelets after a mean transit time (t) = 43 s, compared to 89 and 95% decrease with 0.2 microM ADP). The addition of CP-CPK, either at the time of, or 30 min before each run, completely abolished aggregation. In the presence of 0.2 microM ADP, CP-CPK caused a reversal of aggregation at (t) = 17 s after 30% of single cells had aggregated. To determine whether red cells exert a physical effect by increasing the time of interaction of two colliding platelets (thereby increasing the proportion of collisions resulting in the formation of aggregates), an optically transparent suspension of 40% reconstituted red cell ghosts in serum containing 2.5-micron-diameter latex spheres (3 x 10(5)/microliters) flowing through 100-microns-diameter tubes was used as a model of platelets in blood, and the results were compared with those obtained in a control suspension of latex spheres in serum alone. Two-body collisions between microspheres in the interior of the flowing ghost cell or serum suspensions at shear rates from 5 to 90 s-1 were recorded on cine film. The films were subsequently analyzed, and the measured doublet lifetime, tau meas, was compared with that predicted by theory in the absence of interactions with other particles, tau theor. The mean (tau meas/tau theor) for doublets in ghost cell suspensions was 1.614 +/- 1.795 (SD; n = 320), compared to a value of 1.001 +/- 0.312 (n = 90) for doublets in serum. Whereas 11% of doublets in ghost cell suspensions had lifetimes from 2.5 to 5 times greater than predicted, in serum, no doublets had lifetimes greater than 1.91 times that predicted. There was no statistically significant correlation between tau meas/tau theor and shear rate, but the values of tau meas/tau theor for low-angle collisions in ghost cell suspensions were significantly greater than for high-angle collisions.     

Dynamics of platelet glycoprotein IIb-IIIa receptor expression and fibrinogen binding. II. Quantal activation parallels platelet capture in stir-associated microaggregation.

There is broad agreement that platelet aggregation is generally dependent on fibrinogen (Fg) binding to the glycoprotein (GP) IIb-IIIa receptor expressed on the activated platelet surface. We therefore compared rates and extents of aggregation and of fibrinogen receptor expression and specific Fg binding to activated platelets, as a function of ADP concentration. Human citrated platelet-rich plasma (diluted 10-fold) was stirred with adenosine diphosphate (ADP) for 10 s or 2 min to measure rates and extent of aggregation, respectively, determined from the decrease in the total number of particles. The number of fibrinogen receptors and bound Fg were measured from mean fluorescence values obtained with FITC-labeled IgM monoclonal antibody PAC1 and the IgG monoclonal antibody, 9F9, respectively, using flow cytometry as presented in part I (Frojmovic et al., 1994). Because flow cytometric and aggregation measurements were routinely determined at room temperature and 37 degrees C, respectively, we also compared and found temperature-independent initial rates of aggregation. The fraction of platelets with fluorescence values above one critical threshold value, corresponding to maximally "activated" platelets (P*), increased with increasing activator concentration and correlated linearly with the fraction of platelets recruited into aggregates for ADP (r > 0.9). Aggregation was not rate-limited by fibrinogen receptor expression or by Fg binding. It appears that each platelet expresses its maximal Fg receptors at a critical ADP concentration, i.e., occupancy of ADP receptors. This, in turn, leads to rapid Fg occupancy and capture of such "quantally activated" platelets into aggregates.     

Adenosine diphosphate-induced aggregation of human platelets in flow through tubes. II. Effect of shear rate, donor sex, and ADP concentration.

The effect of shear rate on the adenosine diphosphate-induced aggregation of human platelets in Poiseuille flow was studied using the method described in part I (Bell, D.N., S. Spain, and H.L. Goldsmith. 1989. Biophys. J. 56:817-828). The rate and extent of aggregation in citrated platelet-rich plasma were measured over a range of mean transit time from 0.2 to 8.6 s and mean tube shear rate, G, from 41.9 to 1,920 s-1. At 0.2 microM ADP, changes in the single platelet concentration with time suggest that more than one type of platelet-platelet bond mediates platelet aggregation at physiological shear rates. At low G, a high initial rate of aggregation reflects the formation of a weak bond of high affinity, the strength of which diminishes with time. Here, the fraction of collisions yielding stable doublets, the collision efficiency, reached a maximum of 26%. The collision efficiency decreased with increasing G and was accompanied by a progressive delay in the onset of aggregation. However, the gradual expression of a more shear rate-resistant bond at high shear rates and long mean transit times produced a subsequent increase in collision efficiency and a corresponding increase in the rate of aggregation. Although the collision efficiencies here were less than 1%, the high collision frequencies were able to sustain a high rate of aggregation. At 0.2 microM ADP, aggregate size generally decreased with increasing G. At 1.0 microM ADP, aggregate size was still limited at high shear rates even though the rate of single platelet aggregation was much higher than at 0.2 microM ADP. Platelet aggregation was greater for female than for male donors, an effect related to differences in the hematocrit of donors before preparing platelet-rich plasma.     

The adenylate kinase of human plasma, erythrocytes and platelets in relation to the degradation of adenosine diphosphate in plasma

1. Adenylate kinase (EC 2.7.4.3) has been shown to be present in human plasma obtained by conventional means and the adenylate-kinase activities of plasma and of lysed and intact human platelets and erythrocytes have been measured at 37 degrees by sensitive spectrophotometric methods. 2. The activities found in plasma ranged from 2.7 to 22.9mumoles of ADP formed/min./l. and in lysed platelets and lysed erythrocytes mean values of 0.79 and 12.0mumoles of ADP formed/min./10(9) cells respectively were found. Intact platelets and erythrocytes showed little or no activity. 3. The apparent K(m) of plasma adenylate kinase for ADP was found to be 1.4-1.6mm. 4. The adenylate-kinase activity of plasma was correlated with the free haemoglobin present and the larger part of the activity could be accounted for by haemolysis occurring either during the withdrawal of the blood or in vivo. 5. Aggregation of platelets by ADP, collagen fibres or thrombin released up to 16% of the platelet adenylate kinase into the suspending medium. 6. Measurement of the rate of breakdown of 1.6mum-ADP in plasma gave values of about 0.1mmu-mole/min./ml. This was not increased by addition of sufficient erythrocyte lysate to increase the activity of plasma adenylate kinase five to ten times. 7. It was concluded that the activity of adenylate kinase found in plasma, even after aggregation of the platelets, is insufficient to account for the rate of breakdown of low concentrations of ADP usually observed, and that another enzyme is responsible for this process.     

Lack of influence of the COX inhibitors metamizol and diclofenac on platelet GPIIb/IIIa and P-selectin expression in vitro

BACKGROUND: The effect of non-steroidal anti-inflammatory drugs (NSAIDs) for reduced platelet aggregation and thromboxane A2 synthesis has been well documented. However, the influence on platelet function is not fully explained. Aim of this study was to examine the influence of the COX-1 inhibiting NSAIDs, diclofenac and metamizol on platelet activation and leukocyte-platelet complexes, in vitro. Surface expression of GPIIb/IIIa and P-selectin on platelets, and the percentage of platelet-leukocyte complexes were investigated. METHODS: Whole blood was incubated with three different concentrations of diclofenac and metamizol for 5 and 30 minutes, followed by activation with TRAP-6 and ADP. Rates of GPIIb/IIIa and P-selectin expression, and the percentage of platelet-leukocyte complexes were analyzed by a flow-cytometric assay. RESULTS: There were no significant differences in the expression of GPIIb/IIIa and P-selectin, and in the formation of platelet-leukocyte complexes after activation with ADP and TRAP-6, regarding both the time of incubation and the concentrations of diclofenac and metamizol. CONCLUSIONS: Accordingly, the inhibitory effect of diclofenac and metamizol on platelet aggregation is not related to a reduced surface expression of P-selectin and GPIIb/IIIa on platelets.     

Binding of adenosine diphosphate to human blood platelets and to isolated blood platelet membranes

The equilibrium binding of 14C-labeled ADP to intact washed human blood platelets and to platelet membranes was investigated. With both intact platelets and platelet membranes a similar concentration dependence curve was found. It consisted of a curvilinear part below 20 microM and a rectilinear part above this concentration. At high ADP concentrations, the rectilinear part appeared to be saturable. Because of this, two classes of saturable ADP binding sites were proposed. ADP was partly converted to ATP and AMP with intact platelets while this conversion was virtually absent in isolated platelet membranes. ADP was bound to platelet membranes with the same type of curves found for intact platelets. The ADP binding to the high affinity system, which was stimulated by calcium ions, was nearly independent of temperature and had a pH optimum at 7.8. A number of agents were investigated for inhibiting properties. Of the sulfhydryl reagents only p-chloromercuribenzene sulfonate inhibited both high and low affinity binding systems while iodoacetamide and N-ethylmaleimide were without effect. Compounds acting via cyclic AMP on platelet aggregation, such as adenosine and cyclic AMP itself, had no influence on binding. Some nucleosidediphosphates and nucleotide analogs at a concentration of 100 microM had no, or only a slight, effect on high affinity ADP binding. For some other nucleotides inhibitor constants were determined for both platelet ADP aggregation and ADP binding. The inhibitor constants of ATP, adenyl-5'-yl-(beta,gamma-methylene)diphosphate, IDP, adenosine-5'(2-O-thio)diphosphate, for aggregation and high affinity binding were in good correlation with each other. Exceptions formed fluorosulfonylbenzoyl adenosine and AMP. The ATP formation found with intact platelets could be attributed to a nucleosidediphosphate kinase. It was investigated in some detail. The enzyme was magnesium dependent, had a Q10 value of 1.41, a pH optimum at 8.0, was competitively inhibited by AMP and reacted via a ping pong mechanism. All findings described in this paper indicate that platelets as well as platelet membranes bind ADP with the same characteristics and they suggest that the high affinity binding of ADP is involved in platelet aggregation induced by ADP. The results on nucleosidediphosphate kinase did not permit a firm conclusion about the role of the enzyme in induction of platelet aggregation by ADP.     

Proteolytic degradation of vimentin and glial fibrillary acidic protein in rat astrocytes in primary culture

The receptor for ADP on the platelet membrane, which triggers exposure of fibrinogen-binding sites and platelet aggregation, has not yet been identified. Two enzymes with which ADP interacts on the platelet surface, an ecto-ATPase and nucleosidediphosphate kinase, have been proposed as possible receptors for ADP in ADP-induced platelet aggregation. In the present study, experiments were conducted with washed human platelets to examine if a relationship existed between platelet aggregation, fibrinogen binding and the enzymatic degradation of ADP. With 12 different platelet suspensions, a good correlation (P less than 0.01) was found between the extent of platelet aggregation and the amount of 125I-fibrinogen bound to platelets after ADP stimulation. No correlation was found between these parameters and the rate or extent of transformation of [14C]ADP to [14C]ATP or [14C]AMP. The binding of fibrinogen to platelets was inhibited in parallel with aggregation when ADP stimulation was impaired by the enzymatic degradation of ADP by the system creatine phosphate/creatine phosphokinase, or by the use of specific antagonists, such as ATP and AMP. These antagonists also influenced the enzymatic degradation of ADP. This effect occurred at lower concentrations of ATP or AMP than those required to inhibit ADP-induced platelet aggregation and fibrinogen binding. Our results demonstrate that ATP and AMP may be used as specific antagonists of the ADP-induced fibrinogen binding to platelets. They do not provide evidence to suggest that enzymes which metabolize ADP on the platelet surface are involved in the mechanism of ADP-induced platelet aggregation.