豚鼠嗅皮质切片中神经胶质细胞的离子活性及钾摄取机制
Ion activities and potassium uptake mechanisms of glial cells in guinea-pig olfactory cortex slices.
作者信息
Ballanyi K, Grafe P, ten Bruggencate G
出版信息
J Physiol. 1987 Jan;382:159-74. doi: 10.1113/jphysiol.1987.sp016361.
Abstract
- Double-barrelled ion-sensitive micro-electrodes were used to measure changes in the intracellular activities of K+, Na+ and Cl- (aiK, aiNa, aiCl) in glial cells of slices from guinea-pig olfactory cortex during repetitive stimulation of the lateral olfactory tract. 2. Base-line levels of aiK, aiNa and aiCl were about 66, 25 and 6 mM, respectively, for cells with resting potentials higher than -80 mV. During stimulation, intraglial aiK and aiCl increased, whereas aiNa decreased. Within about 2 min after stimulation the ion activities returned to their base-line levels. 3. The Cl- equilibrium potential was found to be close to the membrane potential (Em). There was also a strong correlation between changes of Em and aiCl. These observations indicate a high Cl- conductance of the glial cell membrane. 4. In the presence of Ba2+, the usual depolarizing response of the glial cells to a rise of the extracellular K+ activity (aeK) reversed into a membrane hyperpolarization. Furthermore, Ba2+ strongly reduced the stimulus-related rise of intraglial aiK. An additional application of ouabain blocked both the membrane hyperpolarization as well as the remaining rise of aiK. 5. In conclusion, our data show that glial cells in guinea-pig olfactory cortex slices possess at least two mechanisms of K+ accumulation. One mechanism is sensitive to the K+ channel blocker Ba2+ and might be a passive KCl influx. The other appears to be the electrogenic Na+/K+ pump, which can be activated by excess extracellular K+.
摘要
- 在对豚鼠嗅皮质切片的胶质细胞进行外侧嗅束重复刺激期间,使用双管离子敏感微电极来测量细胞内K⁺、Na⁺和Cl⁻(aiK、aiNa、aiCl)活性的变化。2. 对于静息电位高于 -80 mV的细胞,aiK、aiNa和aiCl的基线水平分别约为66 mM、25 mM和6 mM。在刺激过程中,胶质细胞内的aiK和aiCl增加,而aiNa减少。刺激后约2分钟内,离子活性恢复到基线水平。3. 发现Cl⁻平衡电位接近膜电位(Em)。Em的变化与aiCl之间也存在很强的相关性。这些观察结果表明胶质细胞膜具有高Cl⁻电导。4. 在Ba²⁺存在的情况下,胶质细胞对细胞外K⁺活性(aeK)升高通常的去极化反应转变为膜超极化。此外,Ba²⁺强烈降低了刺激相关的胶质细胞内aiK升高。额外应用哇巴因可阻断膜超极化以及aiK的剩余升高。5. 总之,我们的数据表明豚鼠嗅皮质切片中的胶质细胞至少具有两种K⁺积累机制。一种机制对K⁺通道阻滞剂Ba²⁺敏感,可能是被动的KCl内流。另一种似乎是电生Na⁺/K⁺泵,它可被细胞外过量的K⁺激活。
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