Impact of Astrocytic Glutamate Transport on Epilepsy Associated with Developmenta

星形细胞谷氨酸转运对发育相关癫痫的影响a

• 批准号: 8496153
• 负责人: Chris G Dulla
• 金额: $ 34.83万
• 依托单位: TUFTS UNIVERSITY BOSTON
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-07-01 至 2017-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8496153
• 关键词: Acute; Address; Animal Model; Antiepileptic Agents; Antiepileptogenic; Astrocytes; Astrocytosis; Attenuated; Biological Assay; Biosensor; Brain; Calcium; Carrier Proteins; Ceftriaxone; Cells; Clinical; Cortical Dysplasia; Cortical Malformation; Data; Development; Disease; Electrophysiology (science); Epilepsy; Epileptogenesis; Excision; Excitatory Synapse; Fluorescence Resonance Energy Transfer; Freezing; Genetic; Glutamate Transporter; Glutamates; Homeostasis; Human; Image; Imaging Techniques; Injury; Knock-out; Lasers; Lead; Lesion; Long-Term Effects; Maps; Modeling; Molecular; Neonatal; Neurons; Neurotransmitters; Operative Surgical Procedures; Pathogenesis; Patients; Pharmaceutical Preparations; Play; Process; Refractory; Resistance; Rodent Model; Role; Scanning; Seizures; Signal Transduction; Small Interfering RNA; Synapses; Techniques; Testing; Therapeutic; Translating; Viral; Western Blotting; base; brain tissue; extracellular; in vivo; innovation; kainate; knock-down; migration; network dysfunction; novel; research study; reuptake; sensor; synaptogenesis; therapeutic target; tool; transport inhibitor; treatment strategy

DESCRIPTION (provided by applicant): Diseases of cortical malformation cause approximately 25% of all cases of epilepsy. They are also the most common cause for surgical resection of epileptic brain tissue. Almost 80% of people with a cortical malformation suffer from epilepsy and greater than 70% of those people have seizures which are not managed by anti-epileptic drugs. Novel treatment strategies are urgently needed to treat this problematic group of epilepsies. In this proposal we will address the hypothesis that loss of astrocytic glutamate reuptake during the development of a cortical malformation acutely disrupts glutamate homeostasis and has long term effects on synaptic connectivity and cortical network function. Normally, astrocytes remove the neurotransmitter glutamate via glutamate transporters. In diseases of cortical malformation, however, astrocytes become reactive which we believe decreases their ability to remove extracellular glutamate. In the developing cortex glutamate directly drives synapse formation. Therefore, we hypothesize that loss of astrocytic glutamate reuptake during the development of a cortical malformation increases extracellular glutamate levels which promotes excitatory synapse formation and leads to long term cortical hyperexcitability. We will test our hypothesis utilizing cutting-edge imaging techniques, electrophysiological recording from astrocytes, in vivo assays of cortical excitability and molecular disruption and augmentation of astrocyte glutamate transport. Our experiments are extremely innovative. We have developed a novel rodent model of cortical malformation which closely replicates focal cortical dysplasia type 1, a disease with no current animal model. We will utilize exciting, novel glutamate biosensor imaging techniques to assay network function and astrocytic glutamate reuptake. We will record cortical glutamate transporter currents, which have not previously been investigated, and we will do so in the malformed cortex. We will utilize laser-scanning photostimulation to spatially map how astrocytic glutamate reuptake is altered in the malformed cortex. Utilizing molecular modulation of astrocytic glutamate transport we will test whether developmental loss of astrocytic glutamate transport is sufficient to induce cortical hyperexcitability and whether increasing glutamate reuptake in the malformed cortex interrupts epileptogenic processes which we believe lead to later network dysfunction. Importantly, we will utilize drugs which are already clinically available to increase glutamate reuptake. Should this approach successfully attenuate cortical hyperexcitability it could be rapidly translated into a potential anti-epileptogenic clinical tool.

描述（由申请人提供）：皮质畸形疾病约占所有癫痫病例的25%。它们也是手术切除癫痫脑组织的最常见原因。几乎80%的皮质畸形患者患有癫痫，其中70%以上的患者癫痫发作无法通过抗癫痫药物治疗。迫切需要新的治疗策略来治疗这组有问题的癫痫。在这个建议中，我们将解决的假设，即损失的星形胶质细胞谷氨酸再摄取在发展过程中的皮质畸形急性破坏谷氨酸稳态和突触连接和皮质网络功能的长期影响。正常情况下，星形胶质细胞通过谷氨酸转运蛋白去除神经递质谷氨酸。然而，在皮质畸形的疾病中，星形胶质细胞变得具有反应性，我们认为这降低了它们清除细胞外谷氨酸的能力。在发育中的皮层中，谷氨酸直接驱动突触的形成。因此，我们推测，在皮质畸形的发展过程中，星形胶质细胞谷氨酸再摄取的损失增加了细胞外谷氨酸水平，从而促进兴奋性突触的形成，并导致长期皮质过度兴奋。我们将测试我们的假设，利用先进的成像技术，从星形胶质细胞的电生理记录，在体内测定皮质兴奋性和分子破坏和增强星形胶质细胞谷氨酸转运。我们的实验极具创新性。我们已经开发了一种新的啮齿动物模型的皮质畸形密切复制局灶性皮质发育不良1型，目前没有动物模型的疾病。我们将 利用令人兴奋的、新颖的谷氨酸生物传感器成像技术来测定网络功能和星形胶质细胞谷氨酸再摄取。我们将记录皮层谷氨酸转运体电流，这是以前没有研究过的，我们将在畸形皮层中这样做。我们将利用激光扫描光刺激空间映射星形胶质细胞谷氨酸再摄取是如何改变畸形皮层。利用星形胶质细胞谷氨酸转运的分子调节，我们将测试星形胶质细胞谷氨酸转运的发育损失是否足以诱导皮质过度兴奋，以及畸形皮质中谷氨酸再摄取的增加是否会中断致癫痫过程，我们认为这会导致后来的网络功能障碍。重要的是，我们将利用临床上已经可用的药物来增加谷氨酸盐的再摄取。如果这种方法成功地减弱皮质过度兴奋，它可以迅速转化为一个潜在的抗癫痫临床工具。