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The potassium channel Kv1.3 in perinatal brain injury

钾通道Kv1.3在围产期脑损伤中的作用

基本信息

批准号：
10551853
负责人：
LEE-WAY JIN
金额：
$ 40.71万
依托单位：
UNIVERSITY OF CALIFORNIA AT DAVIS
依托单位国家：
美国
项目类别：
财政年份：
2019
资助国家：
美国
起止时间：
2019-03-15 至 2024-01-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10551853
关键词：
Adult Affect Alzheimer&apos s Disease Brain Brain Hypoxia-Ischemia Brain Injuries Cations Cell membrane Cell physiology Cell surface Cells Clinical Trials Data Dose Drug Targeting Electrophysiology (science)Goals Hypoxic-Ischemic Brain Injury Immune Infection Inflammation Inflammatory Injections Injury Intervention Invaded Knock-out Kv1.3 potassium channel Leukocytes Link Lipopolysaccharides Macrophage Measures Membrane Potentials Metabolic Metabolic Pathway Microglia Mitochondria Modeling Molecular Target Mononuclear Motor Mus Myeloid Cells Neonatal Neonatal Intensive Care Units Neuroimmunomodulation Neurologic Neuronal Injury Newborn Infant Oral Pathologic Peptides Perinatal Brain Injury Perinatal Infection Phagocytes Pharmacology Play Potassium Channel Premature Birth Proteins RNA Role Signal Transduction Stroke Survivors Tamoxifen Testing Translations Tumor Cell Line Validation Voltage-Gated Potassium Channel comparative efficacy design immune activation inhibitor insight interest mitochondrial membrane monocyte mouse model neonatal brain neuroimaging neuroinflammation neuropathology neuroprotection neurotoxic novel novel therapeutic intervention novel therapeutics patch clamp pharmacologic stroke model therapeutic target tool transcriptome sequencing

项目摘要

Project Summary/Abstract Many survivors of premature birth and perinatal brain injury suffer from long-term neurological sequelae. These newborns urgently need early effective and safe interventions for neuroprotection. Our group is interested in the pharmacology of a voltage-gated potassium channel called Kv1.3 (KCNA3), which plays an important role in immune cell activation by modulating membrane potential to influence intracellular mechanisms such as Ca2+ signaling. Our group previously found that Kv1.3 is required for the pro-inflammatory state of microglia, and has provided evidence to support Kv1.3 as a therapeutic target for Alzheimer's disease and adult stroke. Recently we extended our study to a mouse model of neonatal lipopolysaccharides- sensitized hypoxic-ischemic brain injury (LPS-HI), in which activation of mononuclear phagocytes (MPs, which include microglia, monocytes, and macrophages) plays a key pathological role. This model replicates a major form of perinatal brain injury in which perinatal infection/inflammation sensitizes the brain to subsequent HI insult and augments brain injury. We showed that Kv1.3 knockout or selective pharmacological inhibition of Kv1.3 mitigates the LPS-HI brain injury. Surprisingly, while Kv1.3 RNA and protein levels were increased in MPs isolated from LPS-HI brains, whole-cell patch-clamp failed to detect significant plasma membrane Kv1.3 (PM-Kv1.3) channel activity on the MP cell surface. A logical inference is that an intracellular pool of Kv1.3, such as Kv1.3 in mitochondria, described in some tumor cell lines, is activated instead. Indeed, our recent data show increased mitochondrial Kv1.3 (mito-Kv1.3) in MPs isolated from LPS-HI brains. This discovery marks an important difference in MP activation mechanisms between the neonatal LPS-HI model and the adult models of stroke, Alzheimer's, and LPS injection, as in the latter the PM-Kv1.3 activity is significantly upregulated. Our hypothesis, therefore, is that pro-inflammatory activation of MPs, critical for neurotoxic actions in LPS-HI, requires Kv1.3, with a major contribution from mito-Kv1.3. To test this hypothesis, we will address three Aims. In Aim 1 we will use a targeted deletion approach to distinguish the respective contributions of Kv1.3 in residential microglia and Kv1.3 in invading monocytes. Such a determination will help understand dynamic neuroimmune mechanisms involving monocyte-microglia interactions and neuronal injury, about which little is known in neonatal brains. In view of our novel findings regarding mito-Kv1.3, in Aim 2 we will validate mito- Kv1.3 as a potential therapeutic target for LPS-HI brain injury. Pharmacological tools that are able to selectively target PM-Kv1.3 and mito-Kv1.3 will be tested for their efficacy in mitigating brain injury in the LPS- HI model. In Aim 3, we will further test the hypothesis that mito-Kv1.3, via regulating mitochondrial membrane potential, facilitates reprogramming of mitochondrial metabolic state to drive functional polarization. Our goal is to uncover the mechanistic link between mito-Kv1.3 and MP activation state, and design promising new therapeutic approaches to mitigate perinatal brain injury.

项目概要/摘要许多早产和围产期脑损伤的幸存者患有长期的神经系统后遗症。这些新生儿迫切需要早期有效且安全的神经保护干预措施。我们组是对称为 Kv1.3 (KCNA3) 的电压门控钾通道的药理学感兴趣，该通道在通过调节膜电位影响细胞内，在免疫细胞激活中发挥重要作用 Ca2+信号传导等机制。我们小组之前发现Kv1.3是促炎细胞所必需的小胶质细胞的状态，并提供了支持 Kv1.3 作为阿尔茨海默病治疗靶点的证据和成人中风。最近，我们将研究扩展到新生儿脂多糖小鼠模型 - 致敏性缺氧缺血性脑损伤（LPS-HI），其中单核吞噬细胞（MPs，包括小胶质细胞、单核细胞和巨噬细胞）起着关键的病理作用。这个模型复制了一个主要的围产期脑损伤的一种形式，其中围产期感染/炎症使大脑对随后的 HI 敏感侮辱并加剧脑损伤。我们证明 Kv1.3 敲除或选择性药理学抑制 Kv1.3 减轻 LPS-HI 脑损伤。令人惊讶的是，虽然 Kv1.3 RNA 和蛋白质水平在从 LPS-HI 大脑中分离出的 MP，全细胞膜片钳未能检测到显着的质膜 Kv1.3 (PM-Kv1.3) MP 细胞表面的通道活性。一个逻辑推论是 Kv1.3 的细胞内池，例如在某些肿瘤细胞系中描述的线粒体中的 Kv1.3 被激活。事实上，我们最近的数据显示从 LPS-HI 大脑中分离的 MP 中线粒体 Kv1.3 (mito-Kv1.3) 增加。这一发现标志着新生儿LPS-HI模型与成人模型MP激活机制存在重要差异中风、阿尔茨海默病和 LPS 注射，因为后者 PM-Kv1.3 活性显着上调。我们的因此，假设 MP 的促炎激活对 LPS-HI 的神经毒性作用至关重要，需要 Kv1.3，其中 mito-Kv1.3 做出了主要贡献。为了检验这个假设，我们将实现三个目标。在目标 1 中，我们将使用定向删除方法来区分 Kv1.3 在入侵单核细胞中的驻留小胶质细胞和 Kv1.3。这样的确定将有助于理解动态涉及单核细胞-小胶质细胞相互作用和神经元损伤的神经免疫机制，但对此知之甚少在新生儿大脑中已知。鉴于我们关于 mito-Kv1.3 的新发现，在目标 2 中，我们将验证 mito- Kv1.3 作为 LPS-HI 脑损伤的潜在治疗靶点。药理学工具能够选择性靶向 PM-Kv1.3 和 mito-Kv1.3 将测试其在 LPS 中减轻脑损伤的功效嗨模型。在目标 3 中，我们将进一步检验 mito-Kv1.3 通过调节线粒体膜的假设潜力，促进线粒体代谢状态的重新编程以驱动功能极化。我们的目标是揭示 mito-Kv1.3 和 MP 激活状态之间的机制联系，并设计有前途的新产品减轻围产期脑损伤的治疗方法。