Potassium Channel Dysfunction in Cerebral Arteries

脑动脉钾通道功能障碍

• 批准号: 7103464
• 负责人: DAVID W BUSIJA
• 金额: $ 35.03万
• 依托单位: WAKE FOREST UNIVERSITY HEALTH SCIENCES
• 依托单位国家: 美国
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-09-01 至 2009-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7103464
• 关键词: SDS polyacrylamide gel electrophoresis; brain circulation; cardiovascular pharmacology; cerebral artery; cerebrovascular disorders; comorbidity; free radical oxygen; gene delivery system; hemodynamics; inflammation; insulin sensitivity /resistance; laboratory rat; membrane potentials; oxidation; potassium channel; statistics /biometry; subarachnoid hemorrhage; vascular smooth muscle; vasoconstriction; vasodilation

DESCRIPTION (provided by applicant): Potassium (K) channel activation in vascular smooth muscle (VSM) promotes dilation of arteries to physiological stimuli. Our new finding is that insulin resistance (IR) impairs dilator responses of cerebral arteries to stimuli, which are dependent on opening of K channels in VSM. The underlying basis of K channel dysfunction in IR may involve increased production of reactive oxygen species (ROS). This vascular impairment may account for the increased incidence of and/or impaired recovery from cerebrovascular accidents such as subarachnoid hemorrhage (SAH). However, these issues have not been adequately investigated. We have created 2 specific aims to examine these issues in the in situ basilar artery of the Zucker Obese rat model of IR: Specific Aim 1. Elucidation of mechanisms of deranged K function in VSM of the cerebral circulation. We will test the hypotheses that IR impairs K channel function of cerebral arteries in a subtype-specific fashion and that vascular production and actions of ROS mediate K channel dysfunction. First, we will examine effects of selective K channel agonists and antagonists on the basilar artery and its branches in vivo. Second, we will determine whether IR changes vascular levels of K channel subunits. Third, we will assess the role of ROS in K channel dysfunction in IR using pharmacological and gene transfer approaches. Fourth, we will determine the metabolic source of ROS. Fifth, we will determine whether impaired K channel-mediated dilation leads to enhance constrictor effects. And sixth, we will use electrophysiological approaches to characterize the relationship between VSM membrane potential and diameter in cerebral arteries from IR rats. Specific Aim 2. Examination of effects of IR on cerebral arterial function following experimental SAH. We will test the hypothesis that underlying IR will potentiate adverse effects of SAH on baseline artery diameter and reverse augmented vascular responses to K channel-dependent dilator agents. First, we will examine the effects of SAH on baseline diameter and vascular responsiveness in IR. Second, we will explore the role of K channels in impairment of arterial function following SAH in IR. Third, we will determine whether gene transfer protects vascular responses against SAH in IR animals. And fourth, we will examine the relationship between membrane potential and diameter in cerebral VSM in IR and SAH.

描述（由申请人提供）：血管平滑肌（VSM）中的钾（K）通道激活促进动脉对生理刺激的扩张。我们的新发现是胰岛素抵抗（IR）损害脑动脉对刺激的扩张反应，这种反应依赖于VSM中K通道的开放。IR中K通道功能障碍的潜在基础可能涉及活性氧（ROS）的产生增加。这种血管损伤可能是脑血管意外（如蛛网膜下腔出血（SAH））发生率增加和/或恢复受损的原因。然而，这些问题尚未得到充分调查。我们已经创建了2个具体的目标，以检查这些问题在原位基底动脉的Zucker肥胖大鼠模型的IR：具体目标1。阐明脑循环VSM中K功能紊乱的机制。我们将测试IR以亚型特异性方式损害脑动脉K通道功能以及血管产生和ROS作用介导K通道功能障碍的假设。首先，我们将研究选择性K通道激动剂和拮抗剂对基底动脉及其分支在体内的影响。其次，我们将确定IR是否改变血管K通道亚基的水平。第三，我们将使用药理学和基因转移方法评估ROS在IR中K通道功能障碍中的作用。第四，我们将确定ROS的代谢来源。第五，我们将确定受损的K通道介导的扩张是否导致增强收缩效应。第六，我们将用电生理学的方法来表征VSM膜电位与IR大鼠脑动脉直径的关系。具体目标2。IR对实验性SAH后脑动脉功能的影响。我们将检验以下假设：基础IR将增强SAH对基线动脉直径的不良影响，并逆转K通道依赖性扩张剂增强的血管反应。首先，我们将研究SAH对IR基线直径和血管反应性的影响。其次，我们将探讨K通道在IR SAH后动脉功能受损中的作用。第三，我们将确定基因转移是否保护IR动物对SAH的血管反应。第四，我们将研究IR和SAH时脑VSM膜电位与直径的关系。