Xue S, Green M A, LoGrasso P V, Boettcher B R, Madison E L, Curtiss L K, Miles L A
The Scripps Research Institute, Department of Vascular Biology, La Jolla, CA 72037, USA.
Thromb Haemost. 1999 Mar;81(3):428-35.
Lipoprotein(a) [Lp(a)] is associated with atherosclerosis and with disease processes involving thrombosis. Lp(a) contains apoprotein (a) [apo(a)], which has a sequence highly homologous to plasminogen. Hence, Lp(a) binds directly to extracellular matrix, cellular plasminogen receptors and fibrin(ogen) and competes for the binding of plasminogen to these regulatory surfaces. These interactions may contribute to the proatherothrombogenic consequences of high Lp(a) levels. These interactions are mediated by lysine binding sites (LBS). Therefore, we examined the role of apo(a) kringle IV-10 [the only apo(a) kringle demonstrated to exhibit lysine binding activity in the intact lipoprotein] in the interaction of Lp(a) with these regulatory molecules. We have compared directly apo(a) KIV-10 with plasminogen K4 to examine whether these highly structurally homologous kringle modules are also functionally homologous. Futhermore, because the plasminogen K5-protease domain (K5-PD) binds directly to fibrin, we have also examined the ability of this plasminogen fragment to inhibit the interaction of Lp(a) with these regulatory molecules and with extracellular matrix. Apo(a) KIV-10 competed effectively for the binding of 125I-Lp(a) to these surfaces but was less effective than either intact Lp(a), plasminogen K4 or plasminogen. Plasminogen KS-PD was a better competitor than apo(a) KIV-10 for 125I-Lp(a) binding to the representative extracellular matrix, Matrigel, and to plasmin-treated fibrinogen. In contrast, plasminogen K5-PD did not compete for the interaction of Lp(a) with cells, although it effectively competed for plasminogen binding. These results suggest that Lp(a) recognizes sites in all of the regulatory molecules that are also recognized by apo(a) KIV-10 and that Lp(a) recognizes sites in extracellular matrix and in plasmin-modified fibrinogen that also are recognized by plasminogen K5-PD. Thus, the interaction of Lp(a) with cells is clearly distinct from that with extracellular matrix and with plasmin-treated fibrinogen and the recognition sites within Lp(a) and plasminogen for these regulatory molecules are not identical.
脂蛋白(a)[Lp(a)]与动脉粥样硬化以及涉及血栓形成的疾病过程相关。Lp(a)包含载脂蛋白(a)[apo(a)],其序列与纤溶酶原高度同源。因此,Lp(a)直接结合细胞外基质、细胞纤溶酶原受体和纤维蛋白(原),并竞争纤溶酶原与这些调节表面的结合。这些相互作用可能导致高Lp(a)水平产生促动脉粥样硬化血栓形成的后果。这些相互作用由赖氨酸结合位点(LBS)介导。因此,我们研究了apo(a)kringle IV-10[完整脂蛋白中唯一被证明具有赖氨酸结合活性的apo(a)kringle]在Lp(a)与这些调节分子相互作用中的作用。我们直接比较了apo(a)KIV-10与纤溶酶原K4,以研究这些高度结构同源的kringle模块在功能上是否也同源。此外,由于纤溶酶原K5-蛋白酶结构域(K5-PD)直接结合纤维蛋白,我们还研究了该纤溶酶原片段抑制Lp(a)与这些调节分子以及细胞外基质相互作用的能力。apo(a)KIV-10有效竞争125I-Lp(a)与这些表面的结合,但比完整的Lp(a)、纤溶酶原K4或纤溶酶效果差。纤溶酶原KS-PD在竞争125I-Lp(a)与代表性细胞外基质基质胶以及纤溶酶处理的纤维蛋白原的结合方面比apo(a)KIV-10更有效。相比之下,纤溶酶原K5-PD不竞争Lp(a)与细胞的相互作用,尽管它有效竞争纤溶酶原的结合。这些结果表明,Lp(a)识别所有调节分子中也被apo(a)KIV-10识别的位点,并且Lp(a)识别细胞外基质以及纤溶酶修饰的纤维蛋白原中也被纤溶酶原K5-PD识别的位点。因此,Lp(a)与细胞的相互作用明显不同于其与细胞外基质以及纤溶酶处理的纤维蛋白原的相互作用,并且Lp(a)和纤溶酶原中这些调节分子的识别位点并不相同。
