一种关键的糖酵解酶在gaba能神经传递和人类癫痫中起双重作用。

René Pumain, Jacques Laschet
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引用次数: 9

摘要

我们之前已经描述了一种新的内源性磷酸化机制,该机制维持了嗜电性γ -氨基丁酸受体(GABAAR)的功能,并表明所涉及的激酶是糖酵解酶甘油醛-3-磷酸脱氢酶(GAPDH)。该酶与受体密切相关,并磷酸化受体的α 1亚基。在大量的研究中,gaba能神经传递的减少已被认为是人类癫痫的病理生理机制。在本文中,我们提供的证据表明,与非致痫性人类皮质组织相比,在部分癫痫发作患者的治愈性手术中获得的致痫性皮质组织样本中,糖酵解依赖性GABAAR磷酸化机制和gaba能抑制的功效都有所降低。这种特征不是由于光亲和标记所证明的致痫组织中GABAAR α 1亚基密度的降低。通过促进内源性磷酸化或抑制膜结合磷酸酶来维持受体处于磷酸化状态,可维持人致痫皮质中的GABAAR反应。内源性磷酸化的缺乏和相关的GABAAR功能的下降可以解释GABAAR能抑制的短暂失败,并可能有利于癫痫发作的开始和传播。这些发现表明癫痫病理与局部癫痫患者观察到的区域脑葡萄糖代谢低下之间存在功能联系,因为gaba能机制的功能障碍依赖于局部产生的糖酵解ATP。他们还指出了开发抗药癫痫分子的新目标。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A key glycolytic enzyme plays a dual role in GABAergic neurotransmission and in human epilepsy.

We have previously described a new endogenous phosphorylation mechanism that maintains ionotropic gamma-aminobutyric acid receptor (GABAAR) function and have shown that the kinase involved is the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH). This enzyme is closely associated with the receptor and phosphorylates the alpha1 subunit of the receptor. In a wealth of studies, a reduction in GABAergic neurotransmission has been suggested as a pathophysiological mechanism for human epilepsy. In this paper, we present evidence showing both reduced efficacy of this glycolysis-dependent GABAAR phosphorylation mechanism and of GABAergic inhibition in epileptogenic cortical tissue samples obtained during curative surgery of patients with partial seizures, as compared to non-epileptogenic human cortical tissue. This feature is not due to a reduction in the density of GABAAR alpha1 subunits in the epileptogenic tissue as evidenced by photoaffinity labeling. Maintaining the receptor in a phosphorylated state either by favoring the endogenous phosphorylation or by inhibiting a membrane-bound phosphatase sustains the GABAAR responses in the human epileptogenic cortex. The deficiency in endogenous phosphorylation and the associated decreased GABAAR function can account for transient failures of GABAergic inhibition and may favor seizure initiation and propagation. These findings suggest a functional link between epileptic pathology and the regional cerebral glucose hypometabolism observed in patients with partial epilepsies, since the dysfunction of the GABAergic mechanism is dependent on locally produced glycolytic ATP. They also point to new targets for developing molecules active in drug-resistant epilepsies.

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