Sim Martha M S, Mollica Molly Y, Alfar Hammodah R, Hollifield Melissa, Chung Dominic W, Fu Xiaoyun, Gandhapudi Siva, Coenen Daniëlle M, Prakhya Kanakanagavalli Shravani, Mahmood Dlovan F D, Banerjee Meenakshi, Peng Chi, Li Xian, Thornton Alice C, Porterfield James Z, Sturgill Jamie L, Sievert Gail A, Barton-Baxter Marietta, Zheng Ze, Campbell Kenneth S, Woodward Jerold G, López José A, Whiteheart Sidney W, Garvy Beth A, Wood Jeremy P
Department of Molecular and Cellular Biochemistry, University of Kentucky, Lexington, KY.
Bloodworks Northwest Research Institute, Seattle, WA.
Blood Vessel Thromb Hemost. 2025 Feb;2(1). doi: 10.1016/j.bvth.2024.100030. Epub 2024 Sep 25.
The critical plasma anticoagulant protein S (PS) circulates in 2 functionally distinct pools: free (anticoagulant) or bound to complement component 4b-binding protein (C4BP; anti-inflammatory). Acquired free PS deficiency is detected in several viral infections, but its cause is unclear. Here, we used biochemical approaches and human patient plasma samples to identify an interaction between PS and von Willebrand factor (VWF), which causes free PS deficiency and reduced PS anticoagulant activity. We first identified a shear-dependent interaction between PS and VWF by mass spectrometry. Consistently, PS and VWF could be crosslinked together in plasma, and plasma PS and VWF comigrated in gel electrophoresis. The PS/VWF interaction was blocked by and tissue factor pathway inhibitor but not activated protein C, suggesting an interaction with the sex hormone binding globulin region of PS. Microfluidic systems demonstrated that PS stably binds VWF as VWF unfolds under turbulent flow. PS/VWF complexes also localized to platelet thrombi under laminar arterial flow. In thrombin generation-based assays, shearing plasma decreased PS activity, an effect not seen in the absence of VWF. Finally, free PS deficiency in patients with COVID-19 correlated with changes in VWF, but not C4BP, and with thrombin generation. Our data indicate that PS binds to a shear-exposed site on VWF, thus sequestering free PS and decreasing its anticoagulant activity, which would account for the increased thrombin generation potential. Because many viral infections present with free PS deficiency, elevated circulating VWF, and increased vascular shear, we propose that the PS/VWF interaction reported here is a likely contributor to virus-associated thrombotic risk.
关键的血浆抗凝蛋白S(PS)以两种功能不同的形式循环:游离(抗凝)形式或与补体成分4b结合蛋白(C4BP;抗炎)结合的形式。在几种病毒感染中可检测到获得性游离PS缺乏,但其原因尚不清楚。在此,我们使用生化方法和人类患者血浆样本,确定了PS与血管性血友病因子(VWF)之间的相互作用,这种相互作用导致游离PS缺乏并降低PS的抗凝活性。我们首先通过质谱法确定了PS与VWF之间的剪切依赖性相互作用。一致的是,PS和VWF可在血浆中交联在一起,并且血浆中的PS和VWF在凝胶电泳中一起迁移。PS/VWF相互作用被组织因子途径抑制剂阻断,但不被活化蛋白C阻断,这表明与PS的性激素结合球蛋白区域存在相互作用。微流控系统表明,在湍流作用下VWF展开时,PS能稳定地结合VWF。在层流动脉血流条件下,PS/VWF复合物也定位于血小板血栓处。在基于凝血酶生成的检测中,剪切血浆会降低PS活性,在没有VWF的情况下则未观察到这种效应。最后,COVID-19患者的游离PS缺乏与VWF的变化相关,但与C4BP无关,并且与凝血酶生成相关。我们的数据表明,PS与VWF上的一个剪切暴露位点结合,从而隔离游离PS并降低其抗凝活性,这可以解释凝血酶生成潜力的增加。由于许多病毒感染都伴有游离PS缺乏、循环VWF升高和血管剪切增加,我们提出本文报道的PS/VWF相互作用可能是病毒相关血栓形成风险的一个因素。
