Mapping the effect of the antisecretory factor on GABAA receptor α1 and α6 subunits in cerebellar granule cells in vitro

IF 2 Q3 NEUROSCIENCES
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Abstract

The Antisecretory Factor (AF) is a protein that can reduce intestinal hypersecretion and various inflammation disorders in vivo. Discovered in many mammalian tissues and plasma, its mechanism of action remains unknown. Interestingly, its induction has been found to counteract vertigo in patients with Méniere's disease. This suggests an inherent ability to control body balance and posture, an activity that may play a role in cerebellar function. Therefore, it may be worthwhile to investigate whether this activity can inhibit neuronal cells involved in cerebellar circuitries and its potential action on enteric nervous system ganglia, which could explain its antisecretory effect in the intestine.

Previously, we studied the role of AF on GABAA receptors in cerebellar granule cells, taking advantage of electrophysiology and evaluating the effects of the administration of AF-16, an AF peptide. Treatment with AF-16 increased GABAA receptor responses, especially those containing the α6 subunit. Here, we performed immunofluorescence experiments by staining α1 and α6 subunits before and after incubation with AF-16, analyzed super-resolved images comparing pre- and post-treatment maps and critically examined these experimental results with our previous electrophysiological data to shed light on the mechanisms of action of AF protein on GABAA receptor subpopulations, specifically the "fast" receptors of αn β2/3 γ2 composition that contain either the α1 or the α6 subunit.

The results indicate that the α6 subunit is redistributed, with a decrease in neurites and an increase in soma. Conversely, the α1 subunit shows opposite results, with an increase in neurites and a decrease in soma.

体外绘制抗分泌因子对小脑颗粒细胞中 GABAA 受体 α1 和 α6 亚基的影响图
抗分泌因子(AF)是一种蛋白质,可减少体内肠道分泌过多和各种炎症疾病。它在许多哺乳动物的组织和血浆中被发现,但其作用机制仍不清楚。有趣的是,在梅尼埃病患者身上发现,诱导该蛋白可抵消眩晕。这表明它具有控制身体平衡和姿势的内在能力,这种活动可能在小脑功能中发挥作用。因此,可能值得研究这种活动是否能抑制参与小脑回路的神经元细胞,以及它对肠道神经系统神经节的潜在作用,这可能解释了它在肠道中的抗分泌作用。此前,我们研究了 AF 对小脑颗粒细胞 GABAA 受体的作用,利用电生理学的优势,评估了服用 AF 肽 AF-16 的效果。AF-16能增加GABAA受体的反应,尤其是含有α6亚基的受体。在此,我们通过对 AF-16 培养前后的 α1 和 α6 亚基进行染色,进行了免疫荧光实验,分析了对比处理前后图谱的超分辨图像,并将这些实验结果与我们之前的电生理数据进行了批判性研究,以揭示 AF 蛋白对 GABAA 受体亚群的作用机制,特别是含有 α1 或 α6 亚基的 αn β2/3 γ2 组成的 "快速 "受体。结果表明,α6 亚基重新分布,神经元减少,体细胞增加。相反,α1 亚基则显示出相反的结果,神经元增多,体节减少。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
IBRO Neuroscience Reports
IBRO Neuroscience Reports Neuroscience-Neuroscience (all)
CiteScore
2.80
自引率
0.00%
发文量
99
审稿时长
14 weeks
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