Biophysical characterization of blood coagulation factor VIII binding to lipid nanodiscs that mimic activated platelet surfaces.

IF 5.5 2区 医学 Q1 HEMATOLOGY
Nathan G Avery, Isabelle R Young, Selena Lu, Jordan D Vaughan, Patrick S Korus, Tera N Richardson, Kenneth C Childers, Serge L Smirnov, P Clint Spiegel
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引用次数: 0

Abstract

Background: Following proteolytic activation, activated blood coagulation factor VIII (FVIIIa) binds to activated platelet membranes, forming the intrinsic tenase complex with activated factor IX (FIXa). Previous studies have identified the C1 and C2 domains as the membrane binding domains of FVIII through conserved arginine residues. A membrane binding model for the FVIII C domains proposes that surface exposed hydrophobic and positively charged residues at each C domain interact with the membrane, yet a comprehensive thermodynamic and structural description of this interaction is lacking.

Objective: To determine residues of interaction, thermodynamics, and membrane binding preference for FVIII membrane association.

Methods: Binding of FVIII constructs to lipid nanodiscs were characterized with nuclear magnetic resonance (NMR), isothermal titration calorimetry (ITC), bio-layer interferometry (BLI), and X-ray crystallography.

Results: The thermodynamics of FVIII membrane binding indicate that the C1 domain associates through an enthalpically driven process while the C2 domain is entropically driven. Alanine mutations to surface-exposed hydrophobic residues in the C2 domain reveal differential effects on membrane binding, highlighting important determinants at the residue-level. The structure of a C2 double mutant, L2251A/L2252A, demonstrates that its decreased affinity is likely due to decreasing the surface area hydrophobicity. NMR studies with the C2 domain identified residues of interaction with soluble O-phospho-L-serine (OPLS) as well as lipid nanodiscs. Lastly, increasing phosphatidylethanolamine (PE) and decreasing PS content decreases overall FVIII affinity for membrane surfaces.

Conclusion: This study provides further insight into the molecular basis for how FVIII interacts with platelets to form the intrinsic tenase complex.

血液凝固因子 VIII 与模拟活化血小板表面的脂质纳米圆片结合的生物物理特征。
背景:蛋白水解活化后,活化的凝血因子 VIII(FVIIIa)与活化的血小板膜结合,与活化的因子 IX(FIXa)形成内在十酶复合物。先前的研究通过保守的精氨酸残基确定了 C1 和 C2 结构域为 FVIII 的膜结合结构域。FVIII C 结构域的膜结合模型提出,每个 C 结构域中表面暴露的疏水和带正电荷的残基与膜相互作用,但缺乏对这种相互作用的全面热力学和结构描述:确定 FVIII 与膜结合的相互作用残基、热力学和膜结合偏好:方法:利用核磁共振(NMR)、等温滴定量热法(ITC)、生物层干涉测量法(BLI)和 X 射线晶体学对 FVIII 构建物与脂质纳米盘的结合进行表征:FVIII膜结合的热力学表明,C1结构域是通过焓驱动过程结合的,而C2结构域则是由熵驱动的。对 C2 结构域中暴露于表面的疏水残基进行丙氨酸突变显示了对膜结合的不同影响,突出了残基水平上的重要决定因素。C2 双突变体 L2251A/L2252A 的结构表明,其亲和力下降可能是由于表面疏水性降低所致。对 C2 结构域的核磁共振研究发现了与可溶性 O-磷酸-L-丝氨酸(OPLS)以及脂质纳米盘相互作用的残基。最后,增加磷脂酰乙醇胺(PE)含量和减少 PS 含量会降低 FVIII 对膜表面的总体亲和力:本研究进一步揭示了 FVIII 如何与血小板相互作用形成固有十肽酶复合物的分子基础。
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来源期刊
Journal of Thrombosis and Haemostasis
Journal of Thrombosis and Haemostasis 医学-外周血管病
CiteScore
24.30
自引率
3.80%
发文量
321
审稿时长
1 months
期刊介绍: The Journal of Thrombosis and Haemostasis (JTH) serves as the official journal of the International Society on Thrombosis and Haemostasis. It is dedicated to advancing science related to thrombosis, bleeding disorders, and vascular biology through the dissemination and exchange of information and ideas within the global research community. Types of Publications: The journal publishes a variety of content, including: Original research reports State-of-the-art reviews Brief reports Case reports Invited commentaries on publications in the Journal Forum articles Correspondence Announcements Scope of Contributions: Editors invite contributions from both fundamental and clinical domains. These include: Basic manuscripts on blood coagulation and fibrinolysis Studies on proteins and reactions related to thrombosis and haemostasis Research on blood platelets and their interactions with other biological systems, such as the vessel wall, blood cells, and invading organisms Clinical manuscripts covering various topics including venous thrombosis, arterial disease, hemophilia, bleeding disorders, and platelet diseases Clinical manuscripts may encompass etiology, diagnostics, prognosis, prevention, and treatment strategies.
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