癫痫引起癫痫:对GABA的关键作用的探索。

Yehezkel Ben-Ari
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引用次数: 101

摘要

由γ -氨基丁酸(GABA) A受体介导的突触在增强活动期间发生了众所周知的改变。由于抑制性张力的丧失是癫痫发作的基本原因,因此确定潜在的机制以及减轻或至少减少这种机制的方法是很重要的。细胞内氯化物含量的改变被认为是多动发作后一系列事件的主要参与者。在这篇综述中,我讨论了这些机制在成人和发育中的大脑,依赖于氯离子和gaba能电流的研究,通过电生理和成像技术测量。主要结论是,在成人系统中,癫痫持续状态诱导网络的完全重组,细胞死亡、轴突生长和谷氨酸能新突触的形成导致谷氨酸能驱动的增加。反过来,这将降低癫痫发作的阈值,从而有助于癫痫发作的发生。相反,gaba能突触不容易“可塑性”,因为失去的中间神经元和突触不会被替换。支配海马主要细胞树突的生长抑素阳性0-LM中间神经元选择性退化,导致树突中的抑制驱动丧失,而体投射篮细胞和体抑制驱动相对幸免。这种不平衡导致抑制强度的降低,抑制强度是必要的,但不足以产生持续的癫痫发作。另一个重要因素是细胞内氯化物浓度的持续增加,导致GABA作用的去极化方向的长期变化,这也会导致癫痫发作。在发育中的大脑中,癫痫发作的一个主要来源是由于未成熟神经元中较高的细胞内氯离子浓度([Cl-]I)而导致的GABA的去极化和通常的兴奋作用,这一特性在所有发育系统和研究的动物物种中都得到了证实。因此,不成熟的gaba能突触将刺激目标并促进癫痫发作的出现,这与众所周知的癫痫发作在发育中的大脑中发生率较高保持一致。使用一种独特的制剂,将两个完整的海马体放置在体外三室室中,我们已经提供了直接的证据,证明癫痫发作引起癫痫发作,并且GABA信号在这一现象中起着核心作用。事实上,抽搐剂在一个海马区引发的反复发作会传播到另一个海马区,一旦与另一个海马区断开连接,就会将原始海马区转变为产生癫痫发作的海马区。这种转变是由高频振荡(40赫兹及以上)发作期间的发生所决定的。有趣的是,只有当n -甲基- d -天冬氨酸(NMDA-)和GABA受体在naïve海马中起作用且未被阻断时,这些振荡才会产生。因此,gaba受体拮抗剂在发育中的大脑中具有促惊厥作用,但实际上具有抗癫痫作用。这个矛盾的结论有相当多的临床意义讨论。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Seizures beget seizures: the quest for GABA as a key player.

Synapses mediated by gamma-aminobutyric acid (GABA) A receptors are notoriously altered during periods of enhanced activity. Since a loss of inhibitory tone is a basic cause of seizures and epilepsies, it is important to determine the underlying mechanisms and the way this could be alleviated or at least reduced. Alterations of the intracellular content of chloride are thought to be a major player in the sequence of events that follow episodes of hyperactivity. In this review, I discuss these mechanisms both in the adult and developing brain, relying on studies in which chloride and GABAergic currents were measured by electrophysiological and imaging techniques. The main conclusion is that in adult systems, status epilepticus induces a complete re-organization of the networks, with cell death, axonal growth, and glutamatergic neosynapse formation leading to an increased glutamatergic drive. This, in turn, will decrease the threshold of seizure generation and thus contribute to seizure generation. In contrast, GABAergic synapses are not readily "plastic" as the lost interneurones and synapses are not replaced. Somatostatin-positive 0-LM Interneurons that innervate the dendrites of the principal cells in the hippocampus degenerate selectively, leading to a loss of the inhibitory drive in the dendrites, whereas somatic projecting basket cells and somatic inhibitory drives are relatively spared. This imbalance leads to a reduction of the inhibitory strength that is necessary but not sufficient to generate ongoing seizures. An additional important factor is the persistent increase of the intracellular chloride concentration that leads to a long-lasting shift in the depolarizing direction of the actions of GABA that will also contribute to seizure generation. In the developing brain, a major source of seizure generation is the depolarizing and often excitatory actions of GABA due to a higher intracellular chloride concentration ([Cl-]I) in immature neurons, a property that has been confirmed in all developing systems and animal species studied. As a consequence, immature GABAergic synapses will excite targets and facilitate the emergence of seizures, in keeping with the well-known higher incidence of seizures in the developing brain. Using a unique preparation with two intact hippocampi placed in a three-compartment chamber in vitro, we have provided direct evidence that seizures beget seizures and that GABA signaling plays a central role in this phenomenon. Indeed, recurrent seizures triggered in one hippocampus by a convulsive agent propagate to the other hippocampus and transform the naive hippocampus into one that generates seizures once disconnected from the other hippocampus. This transformation is conditioned by the occurrence during the seizures of high-frequency oscillations (40 Hz and above). Interestingly, these oscillations are only produced when N-methyl-D-aspartate (NMDA-) and GABA receptors are operative and not blocked in the naïve hippocampus. Therefore, GABA-receptor antagonists are pro-convulsive in the developing brain but, in fact, anti-epileptic. This paradoxical conclusion has quite a few clinical implications that are discussed.

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