Glycoprotein Remodeling in the Vasculopathy and Coagulopathy of Sepsis

脓毒症血管病变和凝血病中的糖蛋白重塑

• 批准号: 9271996
• 负责人: JAMEY MARTH
• 金额: $ 69.36万
• 依托单位: UNIVERSITY OF CALIFORNIA SANTA BARBARA
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-09-15 至 2019-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/9271996
• 关键词: Adherence; Apoptosis; Asialoglycoproteins; Automobile Driving; Bacteria; Binding; Biochemical Pathway; Biological; Blood; Blood Coagulation Disorders; Blood Platelets; Cell Communication; Cell Surface Proteins; Cellular biology; Cessation of life; Clinical; Coagulase; Coagulation Process; Coenzyme A; Complement; Deposition; Endothelial Cells; Endothelium; Fibrinogen; Functional disorder; Genetically Engineered Mouse; Glycobiology; Glycoproteins; Goals; Hepatic; Homeostasis; Human; Immune; Immunology; Incidence; Infection; Infectious Agent; Inflammatory; Investigation; Joints; Knockout Mice; Knowledge; Leukocytes; Life; Ligands; Manuscripts; Medicine; Membrane Glycoproteins; Microbiology; Microvascular Dysfunction; Modeling; Modification; Molecular Biology; Mus; Nature; Neuraminidase; Outcome; Pathogenesis; Pathogenicity; Phagocytes; Phagocytosis; Phenotype; Plasma; Plasma Cells; Platelet Activation; Population; Prevalence; Proteins; Publishing; Reporting; Research; Respiratory Burst; Role; ST3Gal IV; Sepsis; Serum; Sialic Acids; Sialyltransferases; Staphylococcus aureus; Streptococcus pneumoniae; Streptococcus pyogenes; Syndrome; System; Therapeutic; Therapeutic Effect; Treatment Efficacy; Vascular Diseases; Virulence; Virulence Factors; Whole Blood; Work; bactericide; comparative; cytokine; cytotoxicity; endothelial dysfunction; human tissue; improved; in vivo; infectious disease model; insight; macrophage; microbicide; mortality; multiple myeloma M Protein; mutant; neutrophil; novel; novel therapeutics; pathogen; receptor; response; sialylation; tissue culture; tool; transcytosis

DESCRIPTION (provided by applicant): The coagulopathy and vasculopathy of sepsis remain common disabling and life-threatening complications of infection that are increasing in incidence as human populations escalate with the prevalence and virulence of infectious organisms. Lack of sufficient knowledge of the pathophysiology of sepsis is represented by the paucity and ineffectiveness of current treatments. We have recently made discoveries that reveal a novel interaction between the host and pathogen in pneumococcal sepsis during which host glycoproteins in the blood and vasculature undergo a post-translational remodeling that alters their homeostasis and function. This remodeling results in asialoglycoproteins deficient in sialic acid linkages that are then selectively recognized by the endocytic Ashwell-Morell receptor (AMR). Asialoglycoproteins are formed by neuraminidases that hydrolyze sialic acid linkages or by a deficiency of one or more sialyltransferases. Asialoglycoprotein modulation by the AMR results in a profound mitigation of coagulopathy, vasculopathy, and mortality in pneumococcal sepsis. The present application represents an expanded investigation of the role of glycoprotein remodeling in the pathogenesis of coagulopathy and endothelial dysfunction during sepsis. The project takes continued advantage of a unique synergistic and productive interdisciplinary integration of glycobiology, molecular and cell biology with microbiology, immunology and infectious disease modeling that has to date produced unexpected and paradigm changing observations -- ones that carry strong translational implications for novel therapeutics. Glycoprotein remodeling will be modulated genetically in the mouse by targeting the biochemical pathways responsible for biologically important modifications involving terminal sialylation (host sialyltransferases ST3Gal-I and ST3Gal-IV) and by modulating the rapid and powerful asialoglycoprotein clearance function of the hepatic AMR - as we have recently published. From the microbiology perspective, we will expand our studies beyond our published work on Streptococcus pneumoniae (SPN) to include two other major human pathogens associated with invasive bloodstream infections and sepsis, Staphylococcus aureus (SA) and group A Streptococcus (GAS). Additional mechanistic insight will be provided through analysis of virulence factors express by these bacteria that provoke pathogenic coagulation and microvascular dysfunction (coagulases, M protein), including the use of isogenic bacterial mutants. Human tissue culture studies will explore the effects of glycoprotein remodeling on interactions between bacterial sepsis pathogens, coagulation proteins, neutrophils and endothelium. In vivo live infection models with wild-type and genetically engineered mice will guide therapeutic manipulation of glycoprotein remodeling, to identify tools to improve coagulation parameters, endothelial function, bacterial clearance and clinical outcomes in sepsis.

描述（由申请人提供）：脓毒症的凝血病和血管病仍然是常见的致残和危及生命的感染并发症，随着人口数量的增加以及传染性生物体的流行和毒力的增加，这些并发症的发病率也在增加。目前治疗方法的缺乏和无效表明对脓毒症的病理生理学缺乏足够的了解。我们最近的发现揭示了肺炎球菌败血症中宿主和病原体之间的新相互作用，在此过程中，血液和脉管系统中的宿主糖蛋白经历翻译后重塑，改变了它们的稳态和功能。这种重塑导致脱唾液酸糖蛋白缺乏唾液酸连接，然后被内吞的 Ashwell-Morell 受体 (AMR) 选择性识别。去唾液酸糖蛋白是由水解唾液酸键的神经氨酸酶或由一种或多种唾液酸转移酶的缺乏形成的。 AMR 调节去唾液酸糖蛋白可显着减轻肺炎球菌败血症的凝血病、血管病和死亡率。本申请代表了对糖蛋白重塑在脓毒症期间凝血病和内皮功能障碍的发病机制中的作用的扩展研究。该项目继续利用糖生物学、分子和细胞生物学与微生物学、免疫学和传染病模型之间独特的协同和富有成效的跨学科整合，迄今为止已经产生了意想不到的、改变范式的观察结果——这些观察结果对新疗法具有强烈的转化意义。通过靶向负责涉及末端唾液酸化（宿主唾液酸转移酶 ST3Gal-I 和 ST3Gal-IV）的生物学重要修饰的生化途径，以及通过调节肝脏 AMR 快速而强大的脱唾液酸糖蛋白清除功能，糖蛋白重塑将在小鼠中进行遗传调节最近发布了。从微生物学的角度来看，我们将把我们的研究扩展到已发表的肺炎链球菌 (SPN) 工作之外，包括与侵袭性血流感染和败血症相关的另外两种主要人类病原体：金黄色葡萄球菌 (SA) 和 A 族链球菌 (GAS)。通过分析这些细菌表达的引起致病性凝血和微血管功能障碍（凝血酶、M 蛋白）的毒力因子，包括使用同基因细菌突变体，将提供额外的机制见解。人体组织培养研究将探讨糖蛋白重塑对细菌性脓毒症病原体、凝血蛋白、中性粒细胞和内皮细胞之间相互作用的影响。野生型和基因工程小鼠的体内活感染模型将指导糖蛋白重塑的治疗操作，以确定改善脓毒症凝血参数、内皮功能、细菌清除和临床结果的工具。