Deconstructing the interaction of glu-plasminogen with its receptor α-enolase

Fibrinolysis and Proteolysis Pub Date : 2000-11-01 DOI:10.1054/fipr.2000.0090

N.M. Andronicos , M.S. Baker , M. Lackmann , M. Ranson

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引用次数: 15

Abstract

Objective: Plasminogen binds with apparent low affinity to cell-surface receptors via its lysine binding sites. This enhances/stabilizes the activation-susceptible conformation. However, it is not known whether this lysine-mediated conformational change of plasminogen may affect its subsequent dissociation rate and hence its stability at the cell surface. Therefore, we sought to determine the relationship between the lysine-dependent conformation of plasminogen and its dissociation rate from its receptor.

Design: BIACORE experiments were used to determine the kinetics of the interaction of glu-plasminogen with its receptor α-enolase. Intrinsic and extrinsic fluorescence spectroscopy were utilized to confirm if α-enolase induced a conformational change to glu-plasminogen as predicted by analyses of the BIACORE data.

Results: The dissociation of glu-plasminogen from α-enolase was mediated by at least two components with apparent dissociation rate constants of k_d1= 4.7 × 10⁻²s⁻¹and k_d2= 1.6 × 10⁻³s⁻¹. This second slower dissociation event reflects an increase in the stability of the complex. Global analysis of the interaction suggested a two-state conformational change reaction, mediated by a concentration-dependent increase in the initial association rate constant. The apparent K_dpredicted by this analysis was 1μM. Fluorescence spectroscopy confirmed that α-enolase induced a more open conformation of glu-plasminogen.

Conclusions: These results provide direct evidence that the binding of glu-plasminogen to α-enolase is not simply a low-affinity interaction, but involves a multivalent, competition binding reaction that is associated with a glu-plasminogen conformational change. This mechanism is compatible with the structure of glu-plasminogen. This has implications for the stability of binding and activation of glu-plasminogen at the cell surface.

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解构糖纤溶酶原与其受体α-烯醇化酶的相互作用

目的：纤溶酶原通过赖氨酸结合位点与细胞表面受体结合，亲和力明显较低。这增强/稳定了易活化构象。然而，尚不清楚赖氨酸介导的纤溶酶原构象变化是否会影响其随后的解离速率，从而影响其在细胞表面的稳定性。因此，我们试图确定纤溶酶原赖氨酸依赖性构象与其受体解离速率之间的关系。设计：BIACORE实验用于确定胶-纤溶酶原与其受体α-烯醇化酶相互作用的动力学。利用内源性和外源性荧光光谱来确认α-烯醇化酶是否如BIACORE数据分析所预测的那样诱导了葡萄糖-纤溶酶原的构象变化。结果：至少有两种组分介导了α-烯醇化酶与胶-纤溶酶原的解离，其表观解离速率常数为kd1=4.7×10−2s−1和kd2=1.6×10−3s−1。这第二个较慢的离解事件反映了复合物稳定性的增加。对相互作用的全局分析表明，初始缔合速率常数的浓度依赖性增加介导了两种状态的构象变化反应。该分析预测的表观Kd为1μM。荧光光谱证实，α-烯醇化酶诱导了葡萄糖-纤溶酶原更开放的构象。结论：这些结果提供了直接证据，证明葡萄糖-纤溶酶酶原与α-烯醇酶的结合不仅仅是一种低亲和力的相互作用，而是一种多价竞争结合反应，与葡萄糖-纤溶酶原体构象变化有关。这种机制与glu-纤溶酶原的结构是相容的。这对细胞表面胶-纤溶酶原结合和激活的稳定性有影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Fibrinolysis and Proteolysis

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