Quinton Todd M, Kim Soochong, Derian Claudia K, Jin Jianguo, Kunapuli Satya P
Sol Sherry Thrombosis Research Center, Temple University School of Medicine, Philadelphia, Pennsylvania 19140, USA.
J Biol Chem. 2004 Apr 30;279(18):18434-9. doi: 10.1074/jbc.M401431200. Epub 2004 Feb 18.
The activation of plasmin from its circulating precursor plasminogen is the mechanism of several clot-busting drugs used to clinically treat patients who have suffered a stroke; however, plasmin thus generated has been shown to activate platelets directly. There has been speculation as to whether plasmin interacts with the protease-activated receptors (PARs) because of its similarity in amino acid specificity with the classic platelet activator thrombin. We have investigated whether plasmin activates platelets via PAR activation through multiple complementary approaches. At concentrations sufficient to induce human platelet aggregation, plasmin released very little calcium compared with that induced by thrombin, the PAR-1 agonist peptide SFLLRN, or the PAR-4 agonist peptide AYPGKF. Stimulation of platelets with plasmin initially failed to desensitize additional stimulation with SFLLRN or AYPGKF, but a prolonged incubation with plasmin desensitized platelets to further stimulation by thrombin. The desensitization of PAR-1 had no effect on plasmin-induced platelet aggregation and yielded an aggregation profile that was similar to plasmin in response to a low dose of thrombin. However, PAR-4 desensitization completely eliminated aggregation in response to plasmin. Inclusion of the PAR-1-specific antagonist BMS-200261 inhibited platelet aggregation induced by a low dose of thrombin but not by plasmin. Additionally, mouse platelets naturally devoid of PAR-1 showed a full aggregation response to plasmin in comparison to thrombin. Furthermore, human and mouse platelets treated with a PAR-4 antagonist, as well as platelets isolated from PAR-4 homozygous null mice, failed to aggregate in response to plasmin. Finally, a protease-resistant recombinant PAR-4 was refractory to activation by plasmin. We conclude that plasmin induces platelet aggregation primarily through slow cleavage of PAR-4.
从循环前体纤溶酶原激活纤溶酶是几种用于临床治疗中风患者的溶栓药物的作用机制;然而,如此产生的纤溶酶已被证明可直接激活血小板。由于纤溶酶在氨基酸特异性上与经典血小板激活剂凝血酶相似,因此有人猜测纤溶酶是否与蛋白酶激活受体(PARs)相互作用。我们通过多种互补方法研究了纤溶酶是否通过PAR激活来激活血小板。在足以诱导人血小板聚集的浓度下,与凝血酶、PAR-1激动剂肽SFLLRN或PAR-4激动剂肽AYPGKF相比,纤溶酶释放的钙非常少。用纤溶酶刺激血小板最初未能使对SFLLRN或AYPGKF的额外刺激脱敏,但长时间用纤溶酶孵育可使血小板对凝血酶的进一步刺激脱敏。PAR-1的脱敏对纤溶酶诱导的血小板聚集没有影响,并且产生的聚集曲线与纤溶酶对低剂量凝血酶的反应相似。然而,PAR-4脱敏完全消除了对纤溶酶的聚集反应。加入PAR-1特异性拮抗剂BMS-200261可抑制低剂量凝血酶诱导的血小板聚集,但不能抑制纤溶酶诱导的聚集。此外,天然缺乏PAR-1的小鼠血小板与凝血酶相比,对纤溶酶表现出完全的聚集反应。此外,用PAR-4拮抗剂处理的人和小鼠血小板,以及从PAR-4纯合缺失小鼠分离的血小板,对纤溶酶均无聚集反应。最后,一种抗蛋白酶的重组PAR-4对纤溶酶的激活具有抗性。我们得出结论,纤溶酶主要通过缓慢切割PAR-4来诱导血小板聚集。
