A novel cation channel in excitatory neuronal injury

兴奋性神经元损伤中的新型阳离子通道

• 批准号: 7210598
• 负责人: ZHIGANG XIONG
• 金额: $ 30.59万
• 依托单位: LEGACY EMANUEL HOSPITAL AND HEALTH CENTER
• 依托单位国家: 美国
• 财政年份: 2005
• 资助国家: 美国
• 起止时间: 2005-04-01 至 2009-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7210598
• 关键词: AMPA Receptors; Affect; Affinity; Antibiotics; Bathing; Brain; Brain Ischemia; Calcium; Carbenoxolone; Cations; Cells; Characteristics; Chemosensitization; Condition; Data; Dependence; Development; Disease; Dose; Down-Regulation; Dyes; Fractionation; Free Radical Scavengers; Gadolinium; Glucose; Glutamate Receptor; GsMTx-4 toxin; Heptanol; High Pressure Liquid Chromatography; Hippocampus (Brain); Homeostasis; Hypoxia; Image; Imaging Techniques; In Vitro; Injury; Ion Channel; Ions; Ischemia; Ischemic Brain Injury; Ischemic Neuronal Injury; Lipids; Mediating; Membrane; Membrane Potentials; Modeling; Molecular; N-Methyl-D-Aspartate Receptors; N-Methylaspartate; Neomycin; Neuraxis; Neuronal Injury; Neurons; Numbers; Oxygen; Pathology; Peptides; Permeability; Personal Satisfaction; Phospholipase C; Physiological Processes; Play; Principal Investigator; Property; Protocols documentation; Regulation; Reporting; Research Personnel; Role; Screening procedure; Signal Transduction; Slice; Spider Venoms; Spiders; Standards of Weights and Measures; Stretching; Synaptic Transmission; System; Tarantula Venoms; Techniques; Testing; Thapsigargin; Time; Tissues; Toxic effect; Toxin; Turtles; Venoms; channel blockers; deprivation; excitotoxicity; expression cloning; extracellular; gap junction channel; in vitro Model; in vivo; ligand gated channel; mature animal; nervous system disorder; neuronal excitability; novel; patch clamp; prevent; programs; receptor; research study; response; voltage

DESCRIPTION (provided by applicant): Calcium is one of the most important ions in the central nervous system, essential for the regulation of neuronal excitability, synaptic transmission, neuronal development and differentiation. Alterations of Ca2+ homeostasis have been shown to be involved in the pathology of various neurological diseases/disorders. Accumulation of intracellular Ca2+ ([Ca2+]i), for example, has been recognized as a central pathological feature in brain ischemia. Along with an increase in [Ca2+]i, ischemia also causes a dramatic decrease in the concentration of extracellular Ca2+ ([Ca2+]e). Although it is well-known that the increase of [Ca2+]j is critical for excitatory neuronal injury, it is not clear whether the alteration of [Ca2+]e plays any role in the pathology of brain ischemia. We have previously demonstrated that lowering [Ca2+]e to the level commonly seen in brain ischemia strongly depolarized and excited cultured hippocampal neurons through activation of a non-selective cation channel. This channel has electrophysiological properties and pharmacological profiles different from known channels, suggesting activation of a novel Ca2+-sensitive ion channel. Our preliminary study also demonstrated that activation of this channel caused an increase in [Ca2+]i and potentiated NMDA-receptor mediated membrane responses as well as neuronal injury. We therefore hypothesize that decreases of [Ca2+]e to the level seen in brain ischemia activates a distinct Ca2+-sensing non-selective cation (csNSC) channel. Activation of these channels induces membrane depolarization and neuronal excitation, which contributes to excitotoxicity either directly, or indirectly through potentiation of NMDA receptor mediated responses. Our objective is to provide additional evidence that csNSC is indeed a distinct new channel and to investigate its pathological role in hypoxic/ischemic neuronal injury. In addition to cultured neurons, we will characterize detailed electrophysiological properties of the csNSC channel in acutely dissociated mature neurons and the neurons in brain slices, develop a pharmacological profile and search for a specific channel blocker. We will define the Ca2+-permeability of the csNSC channel, and determine whether ischemic treatment enhances the Ca2+-permeability. Since NMDA channels play a critical role in excitatory neuronal injury, we will characterize detailed interaction of csNSC channels with NMDA receptor-mediated membrane responses and neuronal injury. Using in vitro ischemic models, we will determine whether preventing the activation of csNSC channels protects neurons from ischemic injury. Specific Aims are: 1. Provide further evidence that lowering [Ca2+]e to the level seen in brain ischemia activates a distinct nonselective cation channel in the central nervous system. 2. Demonstrate that csNSC channels are Ca2+-permeable. 3. Demonstrate potentiation of NMDA channel function by csNSC activation. 4; Determine the potential role of csNSC channels in ischemic neuronal injury.

描述（由申请人提供）：钙是中枢神经系统中最重要的离子之一，对于调节神经元兴奋性、突触传递、神经元发育和分化至关重要。Ca 2+稳态的改变已被证明参与各种神经系统疾病/病症的病理学。例如，细胞内Ca 2+（[Ca 2 +]i）的积累已被认为是脑缺血的中心病理特征。沿着[Ca 2 +]i的增加，缺血也引起细胞外Ca 2+浓度（[Ca 2 +]e）的急剧降低。虽然众所周知[Ca ~（2+）]_i的增加对于兴奋性神经元损伤是至关重要的，但[Ca ~（2+）]_e的改变是否在脑缺血的病理学中起任何作用尚不清楚。我们以前已经证明，降低[Ca 2 +]e的水平，常见于脑缺血强烈去极化和兴奋培养的海马神经元通过激活非选择性阳离子通道。该通道具有不同于已知通道的电生理学特性和药理学特性，表明激活了一种新的Ca 2+敏感离子通道。我们的初步研究还表明，该通道的激活引起[Ca 2 +]i的增加和增强NMDA受体介导的膜反应以及神经元损伤。因此，我们假设，[Ca 2 +]e降低到脑缺血中所见的水平激活了一个独特的Ca 2+敏感非选择性阳离子（csNSC）通道。这些通道的激活诱导膜去极化和神经元兴奋，这直接或间接地通过增强NMDA受体介导的反应导致兴奋性毒性。我们的目标是提供额外的证据，csNSC确实是一个独特的新通道，并探讨其在缺氧/缺血性神经元损伤的病理作用。除了培养的神经元，我们将详细描述急性分离的成熟神经元和脑切片中的神经元中csNSC通道的电生理特性，开发药理学特征并寻找特定的通道阻滞剂。我们将定义csNSC通道的Ca 2+渗透性，并确定缺血治疗是否增强Ca 2+渗透性。由于NMDA通道在兴奋性神经元损伤中起关键作用，我们将详细描述csNSC通道与NMDA受体介导的膜反应和神经元损伤的相互作用。使用体外缺血模型，我们将确定是否阻止激活csNSC通道保护神经元免受缺血性损伤。具体目标是：1。提供进一步的证据，证明将[Ca 2 +]e降低至脑缺血中观察到的水平可激活中枢神经系统中的一种独特的非选择性阳离子通道。2.证明csNSC通道是Ca 2+可渗透的。3.通过csNSC激活证明NMDA通道功能增强。4.确定csNSC通道在缺血性神经元损伤中的潜在作用。