Red Blood Cell Adhesion in Sickle Cell Disease

镰状细胞病中的红细胞粘附

• 批准号: 6521813
• 负责人: Cheryl A Hillery
• 金额: $ 26.15万
• 依托单位: MEDICAL COLLEGE OF WISCONSIN
• 依托单位国家: 美国
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-07-01 至 2006-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6521813
• 关键词: blood vessel occlusion; brain circulation; cell adhesion; cell adhesion molecules; cerebral ischemia /hypoxia; cerebrovascular occlusions; clinical research; disease /disorder model; enzyme inhibitors; erythrocyte membrane; erythrocytes; genetically modified animals; hemoglobin Ss; intravital microscopy; laboratory mouse; model design /development; monoclonal antibody; nitric oxide synthase; pathologic process; protein structure function; sickle cell anemia; stroke; tissue /cell culture; vascular cell adhesion molecule; vascular endothelium

DESCRIPTION (provided by applicant): Vaso-occlusion is the major cause of morbidity and mortality in sickle cell disease (SS-D). We hypothesize that enhanced adhesion of sickle red blood cells (RBCs) to the vascular endothelium involves adhesive molecules within the sickle RBC membrane, ultimately leading to microvascular occlusion in SS-D. However, the ability to design rational approaches to treat sickle cell disease is dependent upon a more complete understanding of the predominant pathologic cellular interactions operative in sickle cell disease. Therefore, the central goal of this project is to further elucidate role of RBC adhesion in microvascular occlusion in SS-D. Consequently, the specific aims for this project are to: 1) Identify and characterize adhesive epitopes within the sickle RBC membrane, 2) Investigate the effect of modulators of sickle RBC adhesion on the evolution of vaso-occlusion in transgenic Sickle Mice, and 3) Examine sickle RBC adhesion in the cerebrovascular microcirculation of transgenic Sickle Mice. We will use recombinant phage display technology to develop monoclonal antibodies to identify and characterize adhesive epitopes within the sickle RBC membrane. To test the contribution of specific adhesive epitopes, we will employ an in vitro flow adhesion assay where washed RBCs interact with purified adhesive proteins or cultured endothelial cells under conditions of controlled shear force. We will also use transgenic mice that exclusively express sickle Hb to further examine the role of RBC adhesion in the development of acute vaso-occlusion in the more complex setting of an in vivo model of SS-D. Finally, we will use this transgenic mouse model of SS-D to specifically address RBC adhesion to the unique endothelium of the brain. We anticipate that these studies will lead to the identification of specific adhesive components within the sickle RBC membrane that augment the adhesion of sickle RBCs to the vessel wall, including cerebrovascular endothelium. These studies will also provide insight as to mechanisms that will inhibit the adhesion of the sickle RBC to the vessel wall, prevent endothelial injury and, therefore, subsequent vascular obstruction in vivo in SS-D. Thus, we expect that information derived from this proposal will lead to new therapeutic approaches for the treatment of vaso-occlusion in SS-D.

描述（由申请方提供）：血管闭塞是镰状细胞病（SS-D）发病和死亡的主要原因。我们假设镰状红细胞（RBC）与血管内皮的粘附增强涉及镰状红细胞膜内的粘附分子，最终导致SS-D的微血管闭塞。然而，设计合理的方法来治疗镰状细胞病的能力取决于对镰状细胞病中起作用的主要病理细胞相互作用的更完整的理解。因此，本项目的中心目标是进一步阐明红细胞粘附在SS-D微血管闭塞中的作用。因此，本项目的具体目标是：1）确定和表征镰状红细胞膜内的粘附表位，2）研究镰状红细胞粘附调节剂对转基因镰状小鼠血管闭塞演变的影响，3）检查转基因镰状小鼠脑血管微循环中的镰状红细胞粘附。我们将使用重组噬菌体展示技术开发单克隆抗体，以确定和表征镰状红细胞膜内的粘附表位。为了测试特异性粘附表位的贡献，我们将采用体外流动粘附测定，其中洗涤的RBC在受控剪切力的条件下与纯化的粘附蛋白或培养的内皮细胞相互作用。我们还将使用专门表达镰状血红蛋白的转基因小鼠，以进一步研究在更复杂的SS-D体内模型中RBC粘附在急性血管闭塞发展中的作用。最后，我们将使用这种SS-D转基因小鼠模型来专门解决RBC粘附到大脑独特内皮的问题。我们预计，这些研究将导致镰状红细胞膜内的特定粘附成分的识别，增加镰状红细胞的粘附血管壁，包括脑血管内皮。这些研究还将提供有关机制的见解，这些机制将抑制镰状红细胞与血管壁的粘附，防止内皮损伤，因此，在SS-D体内随后的血管阻塞。因此，我们期望从该建议中获得的信息将导致新的治疗方法用于治疗SS-D中的血管闭塞。