Cannabinoid modulation of epileptiform activity in mice

大麻素对小鼠癫痫样活动的调节

• 批准号: 6958047
• 负责人: Bret N Smith
• 金额: $ 17.17万
• 依托单位: TULANE UNIVERSITY OF LOUISIANA
• 依托单位国家: 美国
• 财政年份: 2005
• 资助国家: 美国
• 起止时间: 2005-07-01 至 2007-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6958047
• 关键词: action potentials; cannabinoid receptor; cannabinoids; dentate gyrus; disease /disorder model; electrophysiology; epilepsy; granule cell; immunocytochemistry; laboratory mouse; neuropharmacology; neurophysiology; neuroregulation; photolysis; pilocarpine; receptor expression; temporal lobe /cortex; voltage /patch clamp

DESCRIPTION (provided by applicant): A principal goal of epilepsy research is to identify and develop novel treatment strategies for seizure control that may be relatively selective for modulation of the synaptically reorganized circuitry in the epileptic brain. The objective of this Exploratory/Developmental (R21) research proposal is to identify the effects of exogenous and endogenous cannabinoids on neurons of the dentate gyrus in mice with pilocarpine-induced temporal lobe epilepsy (TLE), characterized by chronic spontaneous seizures, mossy fiber sprouting, and increased neuronal excitability and synchrony. The use of cannabinoids for treating seizure disorders has been proposed, but results of case study analyses have been mixed. The goal of this proposal is to determine how cannabinoids modulate activity in the dentate gyrus in a murine model of TLE in order to understand effects of the substance on a system that has undergone synaptic reorganization (versus effects on normal neural circuits). Most known central effects of cannabinoids are mediated by cannabinoid type 1 receptors (CB1R), usually located on presynaptic terminals. In the hippocampus, cannabinoids suppress synaptic input-especially feedback inhibition--to principal neurons, including dentate gyrus granule cells. Although cannabinoids appear to suppress some types of seizures, the cellular "disinhibitory" properties appear to be proconvulsive in normal brains. Recent analyses suggest that cannabinoids may suppress seizure activity in the epileptic brain. However, no studies at the cellular level have been performed in the dentate gyrus in an animal model of TLE (i.e., having cell loss, axon sprouting, and synaptic reorganization). Preliminary data presented here suggest that, in the absence of GABAA receptor-mediated inhibition, cannabinoids can inhibit epileptiform discharges that are attributable to activation of newly-formed recurrent excitatory circuitry in the dentate gyrus in mice with pilocarpine-induced TLE. Using electrophysiological, anatomical, and molecular biological techniques, the hypotheses that: 1) cannabinoids inhibit new recurrent excitatory circuitry; 2) cannabinoids inhibit granule cells directly, and 3) CB1R expression is upregulated in animals with TLE and synaptic reorganization will be tested in a murine model of TLE developed in this lab. Understanding these effects may promote more effective treatment strategies designed specifically for TLE patients, whose brains have undergone a degree of synaptic reorganization.

描述（由申请人提供）：癫痫研究的主要目标是确定和开发用于控制癫痫发作的新治疗策略，该策略可能对癫痫脑中突触重组回路的调制具有相对选择性。这项探索性/发展性（R21）研究提案的目的是确定外源性和内源性大麻素对匹罗卡品诱导的颞叶癫痫（TLE）小鼠齿状回神经元的影响，其特征是慢性自发性癫痫发作，苔藓纤维发芽以及神经元兴奋性和同步性增加。已经提出使用大麻素治疗癫痫发作，但案例研究分析的结果好坏参半。本提案的目标是确定大麻素如何调节TLE小鼠模型中齿状回的活动，以了解该物质对经历突触重组的系统的影响（与对正常神经回路的影响相比）。大多数已知的大麻素的中枢作用是由大麻素1型受体（CB 1 R）介导的，通常位于突触前末梢。在海马体，大麻素抑制突触输入，特别是反馈抑制，主要神经元，包括齿状回颗粒细胞。虽然大麻素似乎可以抑制某些类型的癫痫发作，但在正常大脑中，细胞的“去抑制”特性似乎是促惊厥的。最近的分析表明，大麻素可以抑制癫痫大脑中的癫痫发作活动。然而，尚未在TLE动物模型的齿状回中进行细胞水平的研究（即，具有细胞损失、轴突发芽和突触重组）。这里提出的初步数据表明，在GABAA受体介导的抑制的情况下，大麻素可以抑制癫痫样放电，这是由于激活新形成的经常性兴奋性电路在小鼠的齿状回毛果芸香碱诱导的TLE。使用电生理学，解剖学和分子生物学技术，假设：1）大麻素抑制新的复发兴奋性回路; 2）大麻素直接抑制颗粒细胞，和3）CB 1 R表达上调TLE和突触重组的动物将在本实验室开发的TLE小鼠模型中进行测试。了解这些影响可能会促进更有效的治疗策略，专门为TLE患者设计，他们的大脑已经经历了一定程度的突触重组。