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CELLULAR DETERMINANTS OF RED CELL SICKLING

红细胞镰状化的细胞决定因素

基本信息

批准号：
6325889
负责人：
Carlo Brugnara
金额：
$ 26.66万
依托单位：
BOSTON MEDICAL CENTER
依托单位国家：
美国
项目类别：
财政年份：
2000
资助国家：
美国
起止时间：
2000-04-01 至 2001-03-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/6325889
关键词：
cell morphology cell water cellular pathology clinical research erythrocytes genetically modified animals hemoglobin Ss human subject ion transport laboratory mouse molecular cloning polymerase chain reaction polymerization potassium channel potassium chloride sickle cell anemia sickle cell crisis

项目摘要

Hb S polymerization and sickling are the central events in the pathophysiology of sickle cell disease. The blood of these patients is characterized by the presence of dehydrated, dense erythrocytes, with an elevated hemoglobin S concentration. Since increases in hemoglobin S concentration markedly increase the rate of Hb S polymer formation and the extent of cell sickling, a possible therapeutic approach is based on the prevention of cell dehydration by specific blockade of the transport pathways involved. Two K efflux pathways play a major role in cell dehydration, namely the K-C cotransport system and the Ca-activated (Gardos) K channel. The molecular identity of K-Cl cotransport system and the Ca-activated (Gardos) K channel. The molecular identity of K-Cl cotransport (hKCC1) has been recently elucidated. Although the erythroid Gardo channel has not been yet cloned, several related Ca-gated K channels of large (BK) and small (SK) conductance have been cloned. Studies in vitro in sickle erythrocytes and in vivo in transgenic SAD mice and patients with homozygous Hb S (ss) disease have shown that dehydration of sickle erythrocytes can be diminished by specific blockade of the Gardos channel by the imidazole antimycotic clotrimazole (CLT) or by specific blockade of K-Cl cotransport by increasing the erythrocyte microgram content via dietary microgram supplements. Our studies will be aimed at the following: 1) Role of Gardos channel and K-Cl cotransport in dehydration of sickle erythrocytes and reticulocytes; 2) Molecular characterization of the human and mouse erythrocyte K-Cl cotransporters: The major focus of these two specific aims is the molecular and biophysical characterization of the Gardos channel and the K-Cl cotransporter, with special emphasis on those properties which can be therapeutically manipulated in mouse and in humans, as shown in our ongoing clinical and mouse studies. 3) The effect of in vivo modulation of K transport pathways on red cell hydration state and on sickle disease phenotype in transgenic sickle mice: We will focus on how the clinical manifestation of sickle cell disease in the mouse model can be affected by modulating the activity of either one of the two transport pathways. The effect of pharmacological blockade of K-Cl cotransport or Gardos channel will be studied, as ell as the effect of up- and down-modulation of K-Cl cotransport by either breeding sickle mice into strains with high or low K-Cl cotransport activity or by genetic manipulation of K-Cl cotransport gene or its regulators. These studies are designed to gain insight into the bases of cell dehydration in sickle cells with the final objective of developing new therapeutic options of patients with sickle cell disease. They represent the logical extension of the productive collaboration and successful studies supported by the present funding cycle.

Hb S聚合和镰状化是这一过程的中心事件。镰状细胞病的病理生理学这些病人的血液其特征在于存在脱水的致密红细胞，血红蛋白S浓度升高由于血红蛋白S的增加浓度显著增加Hb S聚合物的形成速率，细胞镰状化的程度，一种可能的治疗方法是基于通过特异性阻断转运防止细胞脱水参与的途径。两种钾离子外排途径在细胞内钾离子转运中起主要作用。脱水，即K-C共转运系统和Ca激活的 K频道。K-Cl共转运系统的分子同一性及钙激活（Gardos）K通道。K-Cl的分子同一性共转运蛋白（hKCC 1）最近已被阐明。虽然红细胞 Gardo通道尚未被克隆，几个相关的钙门控钾通道大电导（BK）和小电导（SK）的克隆。研究体外镰状红细胞和体内转基因SAD小鼠，纯合Hb S（ss）疾病患者的脱水表现为镰状红细胞可通过特异性阻断Gardos 通过咪唑类抗真菌药克霉唑（CLT）或特异性通过增加红细胞微克数阻断K-Cl共转运通过膳食微克补充剂的含量。我们的研究将针对如下： 1)Gardos通道和K-Cl共转运在镰刀菌脱水中的作用红细胞和网织红细胞; 2）人红细胞的分子表征和小鼠红细胞K-Cl协同转运蛋白：这两个研究的主要焦点是具体目标是分子和生物物理表征的 Gardos通道和K-Cl协同转运蛋白，特别强调这些可以在小鼠和小鼠中进行治疗操作的性质，人类，正如我们正在进行的临床和小鼠研究所示。3)效果 K转运途径对红细胞水合状态的体内调节以及转基因镰状小鼠的镰状病表型：我们将重点关注关于镰状细胞病在小鼠中的临床表现模型可以通过调节两者中的任何一个的活性来影响。运输途径。氯化钾的药理学阻断作用共运输或Gardos通道将被研究，以及向上的效果- 和K-Cl共转运的下调，转化到具有高或低K-Cl共转运活性的菌株中，或者通过遗传学方法转化到具有高或低K-Cl共转运活性的菌株中。操纵K-Cl共转运基因或其调控因子。这些研究旨在深入了解细胞的基础，镰状细胞脱水，最终目的是开发新的镰状细胞病患者的治疗选择。它们代表生产性合作的逻辑延伸，本供资周期支持的研究。