Department of Pharmacology and Physiology and Faculté de Médecine et des Sciences de la Santé Université de Sherbrooke Sherbrooke QC Canada.
Department of Medicine, Service of Cardiology, Faculté de Médecine et des Sciences de la Santé Université de Sherbrooke Sherbrooke QC Canada.
J Am Heart Assoc. 2023 Feb 21;12(4):e028056. doi: 10.1161/JAHA.122.028056. Epub 2023 Feb 8.
Background Deep vein thrombosis (DVT) is the primary cause of pulmonary embolism and the third most life-threatening cardiovascular disease in North America. Post-DVT anticoagulants, such as warfarin, heparin, and direct oral anticoagulants, reduce the incidence of subsequent venous thrombi. However, all currently used anticoagulants affect bleeding time at various degrees, and there is therefore a need for improved therapeutic regimens in DVT. It has recently been shown that mast cells play a crucial role in a DVT murine model. The underlying mechanism involved in the prothrombotic properties of mast cells, however, has yet to be identified. Methods and Results C57BL/6 mice and mouse mast cell protease-4 (mMCP-4) genetically depleted mice (mMCP-4 knockout) were used in 2 mouse models of DVT, partial ligation (stenosis) and ferric chloride-endothelial injury model of the inferior vena cava. Thrombus formation and impact of genetically repressed or pharmacologically (specific inhibitor TY-51469) inhibited mMCP-4 were evaluated by morphometric measurements of thrombi immunochemistry (mouse and human DVT), color Doppler ultrasound, bleeding times, and enzymatic activity assays ex vivo Recombinant chymases, mMCP-4 (mouse) and CMA-1 (human), were used to characterize the interaction with murine and human plasmin, respectively, by mass spectrometry and enzymatic activity assays. Inhibiting mast cell-generated mMCP-4, genetically or pharmacologically, resolves and prevents venous thrombus formation in both DVT models. Inferior vena cava blood flow obstruction was observed in the stenosis model after 6 hours of ligation, in control- but not in TY-51469-treated mice. In addition, chymase inhibition had no impact on bleeding times of healthy or DVT mice. Furthermore, endogenous chymase limits plasmin activity in thrombi ex vivo. Recombinant mouse or human chymase degrades/inactivates purified plasmin in vitro. Finally, mast cell-containing immunoreactive chymase was identified in human DVT. Conclusions This study identified a major role for mMCP-4, a granule-localized protease of chymase type, in DVT formation. These findings support a novel pharmacological strategy to resolve or prevent DVT without affecting the coagulation cascade through the inhibition of chymase activity.
深静脉血栓形成(DVT)是肺栓塞的主要原因,也是北美第三大致命心血管疾病。华法林、肝素和直接口服抗凝剂等 DVT 后抗凝剂可降低随后静脉血栓形成的发生率。然而,目前所有使用的抗凝剂都在不同程度上影响出血时间,因此需要改进 DVT 的治疗方案。最近已经表明,肥大细胞在 DVT 小鼠模型中发挥着至关重要的作用。然而,肥大细胞促血栓形成特性的潜在机制尚未确定。
在 2 种 DVT 小鼠模型(部分结扎(狭窄)和氯化铁内皮损伤下腔静脉模型)中使用 C57BL/6 小鼠和小鼠肥大细胞蛋白酶-4(mMCP-4)基因缺失小鼠(mMCP-4 基因敲除)。通过血栓免疫化学(小鼠和人类 DVT)、彩色多普勒超声、出血时间和酶活性测定的形态计量学测量评估血栓形成和基因抑制或药理学(特异性抑制剂 TY-51469)抑制 mMCP-4 的作用。重组糜酶、mMCP-4(小鼠)和 CMA-1(人)分别用于通过质谱和酶活性测定来表征与小鼠和人纤溶酶的相互作用。基因抑制或药理学抑制肥大细胞产生的 mMCP-4 可解决并预防两种 DVT 模型中的静脉血栓形成。在狭窄模型中,在结扎后 6 小时观察到下腔静脉血流阻塞,而在 TY-51469 处理的小鼠中则没有观察到。此外,糜酶抑制对健康或 DVT 小鼠的出血时间没有影响。此外,内源性糜酶限制血栓中纤溶酶的活性。重组鼠或人糜酶在体外降解/失活纯化的纤溶酶。最后,在人类 DVT 中鉴定出含有肥大细胞的免疫反应性糜酶。
本研究确定了肥大细胞蛋白酶-4(一种颗粒定位的糜酶型蛋白酶)在 DVT 形成中的主要作用。这些发现支持通过抑制糜酶活性来解决或预防 DVT 而不影响凝血级联的新型药理学策略。
