SICKLE RBC, INTERMITTENT HYPOXIA AND VASCULAR PATHOLOGY

镰状红细胞、间歇性缺氧和血管病理学

• 批准号: 6254829
• 负责人: Frans A. Kuypers
• 金额: $ 27.07万
• 依托单位: CHILDREN'S HOSPITAL & RES CTR AT OAKLAND
• 依托单位国家: 美国
• 财政年份: 2000
• 资助国家: 美国
• 起止时间: 2000-09-30 至 2004-09-29
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6254829
• 关键词: actin binding protein; blood vessel occlusion; cell cell interaction; cellular pathology; clinical research; disease /disorder model; enzyme activity; enzyme linked immunosorbent assay; erythrocyte membrane; erythrocytes; gelsolin; hemoglobin As; hemoglobin F; hemoglobin Ss; human subject; hypoxia; laboratory mouse; lysolecithins; nitric oxide; phospholipase A2; sickle cell anemia; superoxides; vascular endothelium

The unique oxygen sensing capacity of the sickle red cell defines sickle cell disease (SCD) pathology resulting from the polymerization of sickle hemoglobin under low partial oxygen pressure (PO2). Our long term goal is to understand how intermittent hypoxia changes the red cell membrane and its interactions with vascular endothelium (E.C.). We hypothesize a novel chain of events in which intermittent hypoxia will generate lysophosphatidic acid (LPA), a powerful lipid mediator, exposes phosphatidyl serine (PS) on the red surface, and depletes plasma gelsolin levels, the buffer protein for LPA. We pose that nitric oxide (NO) and related compounds, generated by E.C. under hypoxia will affect this process depending on the hemoglobin concentration and type (HbS, or HbF). Increased levels of the inflammatory mediator secretory phospholipase A2 (sPLA2) in SCD will further exacerbate this process which will ultimately lead to vascular drainage. To address these aspects of RBC-E.C. interaction, we have developed the following specific aims: I. To investigate the effect of intermittent hypoxia on sickle red cells. II. To investigate intermittent hypoxia on red cell-endothelial interaction, and III. To evaluate factors of intermittent hypoxia in sickle cell patients and murine models of sickle cell disease. To accomplish these goals, we will use a multidisciplinary approach using biochemistry and cell biology techniques to study RBC and E.C. under well-defined conditions of intermittent hypoxia in vitro, in a unique incubation system, separately or together. We will measure the generation of LPA in vitro and define its role, determine the LPA buffering capacity of the plasma actin-binding protein gelsolin, and define the role for E.C. derived NO and its derivatives. We will relate the data of in vitro studies to in vivo findings of LPA, gelsolin and NO footprints in SCD patients with vasoocclusive crisis, stroke and acute chest syndrome as well as our murine model for SCD. Together, our results may indicate novel treatment regiments in the management of SCD.

镰状红细胞独特的氧感应能力定义了镰状细胞病（SCD）病理学，该病理学由镰状血红蛋白在低氧分压（PO 2）下聚合而引起。我们的长期目标是了解间歇性缺氧如何改变红细胞膜及其与血管内皮（E.C.）的相互作用。我们假设一个新的事件链，其中间歇性缺氧将产生溶血磷脂酸（LPA），一个强大的脂质介质，暴露磷脂酰丝氨酸（PS）的红色表面，并耗尽血浆凝溶胶蛋白水平，LPA的缓冲蛋白。我们提出，一氧化氮（NO）和相关化合物，产生的E. C。在缺氧条件下，将影响这一过程，这取决于血红蛋白浓度和类型（HbS或HbF）。SCD中炎症介质分泌型磷脂酶A2（sPLA 2）水平的增加将进一步加剧这一过程，最终导致血管引流。为了解决RBC-E. C的这些方面，互动，我们制定了以下具体目标：一。探讨间歇性低氧对镰状红细胞的影响。二.研究间歇性缺氧对红细胞-内皮细胞相互作用的影响。探讨镰状细胞病患者和镰状细胞病小鼠模型间歇性缺氧的影响因素。为了实现这些目标，我们将使用生物化学和细胞生物学技术的多学科方法来研究RBC和E. C。在明确定义的体外间歇缺氧条件下，在独特的孵育系统中，单独或一起。我们将在体外测量LPA的产生并确定其作用，确定血浆肌动蛋白结合蛋白凝溶胶蛋白的LPA缓冲能力，并确定E.C. NO及其衍生物。我们将把体外研究的数据与患有血管闭塞危象、中风和急性胸部综合征的SCD患者以及我们的SCD小鼠模型中的LPA、凝溶胶蛋白和NO足迹的体内发现相关联。总之，我们的研究结果可能表明新的治疗方案在SCD的管理。