非洲爪蟾早期胚胎中的细胞内pH值:其对卵裂球间电流的影响。
Intracellular pH in early Xenopus embryos: its effect on current flow between blastomeres.
作者信息
Turin L, Warner A E
出版信息
J Physiol. 1980 Mar;300:489-504. doi: 10.1113/jphysiol.1980.sp013174.
Abstract
- Electrophysiological techniques were used to monitor the flow of electric current from one cell to the next in Xenopus laevis embryos between the 4-cell and early blastula stages of development. Intracellular pH and blastocoel pH were determined using pH-sensitive micro-electrodes. 2. The resting intracellular pH was 7.74+/-0.02 (S.E. of mean, n = 29); there were no systematic differences between developmental stages. Blastocoel cavity pH was 8.4+/-0.06 (S.E. of mean, n = 10). The intracellular buffer value was 18 m-equiv. H+/pH unit per litre. 3. In embryos treated with bicarbonate buffered Holtfreter solution equilibrated with 100% CO2 the intracellular pH fell to 6.3+/-0.17 (S.D., n = 8). The membrane potential fell and the input resistance increased. The size of the effect on membrane potential and input resistance varied. 4. From the 32-cell stage onwards current flow from one cell to the next was abolished when the intracellular pH fell to below 6.5; the effect was rapid in onset and completely reversible. At cleavage stages of development lowering intracellular pH with CO2 had no effect on current flow from cell to cell. 5. The relationship between intracellular pH and current flow from cell to cell was sigmoid and covered between 0.2 and 0.4 pH units. The pH at which current flow was completely abolished ranged from 6.85 to 6.4. 6. Alterations in extraembryonic pH over the range 5.8-7.5 had no effect on any parameter measured. 7. We conclude that lowering the intracellular pH increases the resistance of both non-junctional junctional membranes. The data do not allow us to extract the pH junctional conductance relationship. 8. Variations in intracellular pH may provide a useful tool for the study of the functional role of direct cell to cell communication in both adult organs and early embryos.
摘要
- 采用电生理技术监测非洲爪蟾胚胎在4细胞期至囊胚早期发育阶段从一个细胞到下一个细胞的电流流动情况。使用对pH敏感的微电极测定细胞内pH值和囊胚腔pH值。2. 静息细胞内pH值为7.74±0.02(平均值的标准误,n = 29);发育阶段之间无系统性差异。囊胚腔pH值为8.4±0.06(平均值的标准误,n = 10)。细胞内缓冲值为每升18毫当量H⁺/pH单位。3. 在用与100% CO₂平衡的碳酸氢盐缓冲霍尔特弗雷ter溶液处理的胚胎中,细胞内pH值降至6.3±0.17(标准差,n = 8)。膜电位下降,输入电阻增加。对膜电位和输入电阻的影响大小各不相同。4. 从32细胞期开始,当细胞内pH值降至6.5以下时,细胞间的电流流动被阻断;这种效应起效迅速且完全可逆。在发育的卵裂阶段,用CO₂降低细胞内pH值对细胞间电流流动没有影响。5. 细胞内pH值与细胞间电流流动的关系呈S形,范围在0.2至0.4 pH单位之间。电流流动完全被阻断时的pH值范围为6.85至6.4。6. 胚外pH值在5.8 - 7.5范围内的变化对所测量的任何参数均无影响。7. 我们得出结论,降低细胞内pH值会增加非连接性连接膜的电阻。这些数据无法让我们得出pH值与连接电导的关系。8. 细胞内pH值的变化可能为研究成体器官和早期胚胎中细胞间直接通讯的功能作用提供一种有用的工具。
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