Impact of dyslipidemia on endothelial biomechanics

血脂异常对内皮生物力学的影响

• 批准号: 7492115
• 负责人: Irena Levitan
• 金额: $ 38.57万
• 依托单位: UNIVERSITY OF ILLINOIS AT CHICAGO
• 依托单位国家: 美国
• 财政年份: 2007
• 资助国家: 美国
• 起止时间: 2007-09-04 至 2012-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7492115
• 关键词: Address; Aorta; Arteries; Artificial Membranes; Atomic Force Microscopy; Beds; Biochemical; Biomechanics; Biomedical Engineering; Blood Vessels; Cardiovascular Diseases; Caveolae; Cell Communication; Cell membrane; Cell physiology; Cells; Cellular Morphology; Cellular biology; Cholesterol; Complex; Condition; Coronary artery; Coupling; Cytoskeletal Proteins; Cytoskeleton; Data; Development; Device Designs; Diet; Disruption; Doctor of Philosophy; Dominant-Negative Mutation; Down-Regulation; Dyslipidemias; Endothelial Cells; Environment; Enzymes; Excision; F-Actin; Family suidae; Fluorescence Anisotropy; Fluorescent Dyes; Functional disorder; Gas-Liquid Chromatography; Goals; High Density Lipoproteins; Human; Image; Impairment; In Vitro; Intracellular Space; Invasive; Lateral; Lesion; Lipid Bilayers; Lipid Biochemistry; Low-Density Lipoproteins; Measurement; Measures; Mechanical Stress; Mechanics; Membrane; Membrane Fluidity; Membrane Proteins; Methods; Molecular; Molecular Biology; Monomeric GTP-Binding Proteins; Phospholipids; Plasma; Play; Production; Property; Proteins; Pulmonary artery structure; Regulation; Research Personnel; Risk Factors; Role; Simulate; Staging; Sterols; Sus scrofa; Testing; Three-Dimensional Image; Three-Dimensional Imaging; Time; Tissues; Toxin; Traction; Vascular remodeling; Very low density lipoprotein; analog; caveolin 1; cell injury; hemodynamics; in vivo; novel; oxidation; oxidized low density lipoprotein; physical property; programs; research study; response; rho GTP-Binding Proteins; vascular bed; vasoactive agent

DESCRIPTION (provided by applicant): Biomechanical properties of endothelial cells (ECs) are crucially important in regulation of EC mechanotransduction, cell-cell interactions, secretion of vasoactive agents, and vascular remodeling. Our recent studies have shown that EC biomechanical properties are significantly altered by changes in cellular cholesterol suggesting that EC mechanics is impaired under dyslipidemic conditions. The long-term goal of this project is to elucidate the mechanisms responsible for impairment of EC mechanics by dyslipidemia and to determine the impact of these effects on EC function. Our preliminary studies show that oxidized LDL strongly increases EC stiffness supporting the hypothesis that dyslipidemia is important for regulation of EC mechanics. In this study, we propose: (1) To determine the impact of dyslipidemic conditions on mechanical properties of arterial ECs in vitro and ex vivo. First, we will focus on determining the effects of oxLDL and its components on human ECs derived from different arterial beds. Thereafter, we will compare mechanical properties of ECs freshly-isolated from the arteries of normal and hypercholesterolemic pigs. A combination of three biophysical approaches: micropipette aspiration, atomic force and traction force microscopy will be used for comprehensive analysis of EC mechanics. We will further elucidate the relationship between EC mechanics, cytoskeleton organization and cellular cholesterol level using a combination of 3D imaging and lipid biochemistry. (2) To investigate molecular mechanisms responsible for dyslipidemia-induced changes in EC biomechanics. Specifically, we will first determine whether mechanical properties of membrane- cytoskeleton complex depend on the physical properties of the membrane lipid bilayer and/or on the integrity of cholesterol-rich membrane domains and caveolae. Next, we will test the hypothesis that Rho-GTPases and/or PI(4,5)P3, major regulators of membrane-cytoskeleton interactions, are responsible for cholesterol- induced changes in EC mechanics. (3) To elucidate the interplay between dyslipidemia and flow in the regulation of EC mechanics and cytoskeleton remodeling. In this part of the study, we will first investigate the relationship between dyslipidemia and hemodynamic conditions in regulating EC mechanical properties. Finally, we will extend these studies to determine the impact of dyslipidemia on flow-induced cytoskeleton remodeling and NO production.

描述（由申请人提供）：内皮细胞（EC）的生物力学特性在调节EC机械转导，细胞 - 细胞相互作用，血管活性剂的分泌和血管重塑方面至关重要。我们最近的研究表明，EC生物力学特性因细胞胆固醇的变化而显着改变，这表明在血脂症状条件下EC力学受损。该项目的长期目标是阐明血脂异常损害EC力学的机制，并确定这些影响对EC功能的影响。我们的初步研究表明，氧化的LDL强烈增加了EC刚度，支持了血脂异常对于调节EC力学很重要的假设。在这项研究中，我们提出：（1）确定血脂症条件对体外和离体动脉EC的机械性能的影响。首先，我们将专注于确定OXLDL及其成分对来自不同动脉床的人类EC的影响。此后，我们将比较正常和高胆固醇猪动脉新鲜分离的EC的机械性能。三种生物物理方法的组合：微孔抽吸，原子力和牵引力显微镜将用于全面分析EC力学。我们将使用3D成像和脂质生物化学的组合进一步阐明EC力学，细胞骨架组织与细胞胆固醇水平之间的关系。 （2）研究负责血脂异常诱导的EC生物力学变化的分子机制。具体而言，我们将首先确定膜细胞骨架复合物的机械性能是否取决于膜脂质双层膜的物理特性和/或/或/或或含有富含胆固醇的膜结构域和小切片的完整性。接下来，我们将检验以下假设：膜 - 细胞骨架相互作用的主要调节剂Rho-GTPase和/或Pi（4,5）P3负责胆固醇诱导的EC机械变化。 （3）在EC力学和细胞骨架重塑的调节中阐明血脂血症与流动之间的相互作用。在这一研究的这一部分中，我们将首先研究血脂异常与血液动力学条件之间在调节EC机械性能中的关系。最后，我们将扩展这些研究，以确定血脂异常对流动诱导的细胞骨架重塑和无生产的影响。