Department of Pathology and Laboratory Medicine, University of North Carolina at Chapel Hill, Chapel Hill, NC.
Lineberger Comprehensive Cancer Center, University of North Carolina at Chapel Hill, Chapel Hill, NC.
Blood. 2024 Jan 11;143(2):105-117. doi: 10.1182/blood.2023020805.
Elevated circulating fibrinogen levels correlate with increased risk for both cardiovascular and venous thromboembolic diseases. In vitro studies show that formation of a highly dense fibrin matrix is a major determinant of clot structure and stability. Here, we analyzed the impact of nonpolymerizable fibrinogen on arterial and venous thrombosis as well as hemostasis in vivo using FgaEK mice that express normal levels of a fibrinogen that cannot be cleaved by thrombin. In a model of carotid artery thrombosis, FgaWT/EK and FgaEK/EK mice were protected from occlusion with 4% ferric chloride (FeCl3) challenges compared with wild-type (FgaWT/WT) mice, but this protection was lost, with injuries driven by higher concentrations of FeCl3. In contrast, fibrinogen-deficient (Fga-/-) mice showed no evidence of occlusion, even with high-concentration FeCl3 challenge. Fibrinogen-dependent platelet aggregation and intraplatelet fibrinogen content were similar in FgaWT/WT, FgaWT/EK, and FgaEK/EK mice, consistent with preserved fibrinogen-platelet interactions that support arterial thrombosis with severe challenge. In an inferior vena cava stasis model of venous thrombosis, FgaEK/EK mice had near complete protection from thrombus formation. FgaWT/EK mice also displayed reduced thrombus incidence and a significant reduction in thrombus mass relative to FgaWT/WT mice after inferior vena cava stasis, suggesting that partial expression of nonpolymerizable fibrinogen was sufficient for conferring protection. Notably, FgaWT/EK and FgaEK/EK mice had preserved hemostasis in multiple models as well as normal wound healing times after skin incision, unlike Fga-/- mice that displayed significant bleeding and delayed healing. These findings indicate that a nonpolymerizable fibrinogen variant can significantly suppress occlusive thrombosis while preserving hemostatic potential in vivo.
循环中纤维蛋白原水平的升高与心血管和静脉血栓栓塞疾病的风险增加相关。体外研究表明,高度密集的纤维蛋白基质的形成是血栓结构和稳定性的主要决定因素。在这里,我们使用表达不能被凝血酶裂解的纤维蛋白原的 FgaEK 小鼠分析了不可聚合纤维蛋白原对体内动脉和静脉血栓形成以及止血的影响。在颈动脉血栓形成模型中,与野生型(FgaWT/WT)小鼠相比,FgaWT/EK 和 FgaEK/EK 小鼠在 4%三氯化铁(FeCl3)挑战中受到保护而不发生闭塞,但这种保护在更高浓度的 FeCl3 下失去,损伤是由更高浓度的 FeCl3 驱动的。相比之下,纤维蛋白原缺陷(Fga-/-)小鼠即使在高浓度 FeCl3 挑战下也没有发生闭塞的证据。FgaWT/WT、FgaWT/EK 和 FgaEK/EK 小鼠的纤维蛋白原依赖性血小板聚集和血小板内纤维蛋白原含量相似,这与支持严重挑战时动脉血栓形成的纤维蛋白原-血小板相互作用的保留一致。在静脉血栓形成的下腔静脉淤滞模型中,FgaEK/EK 小鼠几乎完全免受血栓形成的影响。FgaWT/EK 小鼠在发生下腔静脉淤滞后也显示出血栓发生率降低和血栓质量显著减少,与 FgaWT/WT 小鼠相比,这表明非聚合纤维蛋白原的部分表达足以提供保护。值得注意的是,与 Fga-/-小鼠相比,FgaWT/EK 和 FgaEK/EK 小鼠在多种模型中均保留了止血作用,并且在皮肤切口后愈合时间正常,Fga-/-小鼠表现出明显的出血和延迟愈合。这些发现表明,不可聚合纤维蛋白原变体可以显著抑制闭塞性血栓形成,同时在体内保留止血潜能。
