剪切应力通过上调血小板糖苷酶活性促进血小板糖基化重塑:还有一件事

IF 5 2区 医学 Q1 HEMATOLOGY
Yana Roka-Moiia, Sabrina Lewis, Estevan Cleveland, Joseph E Italiano, Marvin J Slepian
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引用次数: 0

摘要

背景:机械循环支持(MCS)是晚期心力衰竭的主要治疗手段。剪切力介导的血小板功能障碍(SMPD)和病因不明的血小板减少症是 MCS 相关出血的主要原因。最近的研究表明,剥夺血小板表面糖基化与止血功能下降、微vesiculation 和过早凋亡有关。我们检验了剪切应力通过糖苷酶活性上调诱导血小板糖基化重塑,从而促进血小板数量下降和微vesiculation的假设。通过流式细胞术对血小板和血小板衍生微颗粒进行量化。使用凝集素染色法和多色流式细胞术评估血小板表面糖基化;使用凝集素印迹法验证单个糖蛋白的糖基化。使用基于 4-甲基伞形酮的荧光底物对神经氨酸酶、半乳糖酶、己糖胺酶和甘露糖苷酶活性进行了量化:结果:剪切应力通过下调 2,6-半乳糖酰化、末端半乳糖促进血小板糖基化的选择性重塑。神经氨酸酶抑制剂可部分减弱剪切力介导的脱糖基化,这有力地表明血小板神经氨酸酶参与了所观察到的现象。血小板表现出较高的基础己糖胺酶和甘露糖苷酶活性;血小板神经氨酸酶和半乳糖苷酶的基础活性相当低,并在剪切应力作用下显著上调。剪切应力会加剧血小板数量的递增性下降和微vesiculation的增加,神经氨酸酶会进一步加剧这两种情况,而神经氨酸酶抑制剂则会减弱这两种情况:结论:剪切应力累积与设备支持循环的超生理条件一致,通过选择性上调血小板糖苷酶活性促进血小板糖基化重塑。剪切力介导的血小板脱糖基化与血小板计数下降和微静脉化增加有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Shear Stress Promotes Remodeling of Platelet Glycosylation via Upregulation of Platelet Glycosidase Activity: One More Thing.

Background:  Mechanical circulatory support (MCS) is a mainstay of therapy for advanced and end-stage heart failure. Accompanied by systemic anticoagulation, contemporary MCS has become less thrombogenic, with bleeding complications emerging as a major cause of readmission and 1-year mortality. Shear-mediated platelet dysfunction and thrombocytopenia of undefined etiology are primary drivers of MCS-related bleeding. Recently, it has been demonstrated that deprivation of platelet surface glycosylation is associated with the decline of hemostatic function, microvesiculation, and premature apoptosis. We test the hypothesis that shear stress induces remodeling of platelet surface glycosylation via upregulation of glycosidase activity, thus facilitating platelet count decline and intense microvesiculation.

Methods:  Human gel-filtered platelets were exposed to continuous shear stress in vitro. Platelets and platelet-derived microparticles (PDMPs) were quantified via flow cytometry using size standard fluorescent nanobeads. Platelet surface glycosylation and NEU1 expression were evaluated using lectin- or immune-staining and multicolor flow cytometry; lectin blotting was utilized to verify glycosylation of individual glycoproteins. Platelet neuraminidase, galactosidase, hexosaminidase, and mannosidase activities were quantified using 4-methylumbelliferone-based fluorogenic substrates.

Results:  We demonstrate that shear stress promotes selective remodeling of platelet glycosylation via downregulation of 2,6-sialylation, terminal galactose, and mannose, while 2,3-sialylation remains largely unchanged. Shear-mediated deglycosylation is partially attenuated by neuraminidase inhibitors, strongly suggesting the involvement of platelet neuraminidase in observed phenomena. Shear stress increases platelet NEU1 surface expression and potentiates generation of numerous NEU1+ PDMPs. Platelets exhibit high basal hexosaminidase and mannosidase activities; basal activities of platelet neuraminidase and galactosidase are rather low and are significantly upregulated by shear stress. Shear stress of increased magnitude and duration promotes an incremental decline of platelet count and immense microvesiculation, both being further exacerbated by neuraminidase and partially attenuated by neuraminidase inhibition.

Conclusion:  Our data indicate that shear stress accumulation, consistent with supraphysiologic conditions of device-supported circulation, promotes remodeling of platelet glycosylation via selective upregulation of platelet glycosidase activity. Shear-mediated platelet deglycosylation is associated with platelet count drop and increased microvesiculation, thus offering a direct link between deglycosylation and thrombocytopenia observed in device-supported patients. Based on our findings, we propose a panel of molecular markers to be used for reliable detection of shear-mediated platelet deglycosylation in MCS.

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来源期刊
Thrombosis and haemostasis
Thrombosis and haemostasis 医学-外周血管病
CiteScore
11.90
自引率
9.00%
发文量
140
审稿时长
1 months
期刊介绍: Thrombosis and Haemostasis publishes reports on basic, translational and clinical research dedicated to novel results and highest quality in any area of thrombosis and haemostasis, vascular biology and medicine, inflammation and infection, platelet and leukocyte biology, from genetic, molecular & cellular studies, diagnostic, therapeutic & preventative studies to high-level translational and clinical research. The journal provides position and guideline papers, state-of-the-art papers, expert analysis and commentaries, and dedicated theme issues covering recent developments and key topics in the field.
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