小龙虾整流突触的电压钳分析。
Voltage-clamp analysis of a crayfish rectifying synapse.
作者信息
Giaume C, Kado R T, Korn H
机构信息
I.N.S.E.R.M. U261, Département des Biotechnologies, Institut Pasteur, Paris, France.
出版信息
J Physiol. 1987 May;386:91-112. doi: 10.1113/jphysiol.1987.sp016524.
Abstract
- The rectifying crayfish giant motor synapse has been studied in the second abdominal ganglion, using the double-voltage-clamp technique which allowed direct measurements of junctional current at various fixed transjunctional potentials. 2. The transjunctional potential (Vj), defined as the difference between the voltages recorded in the lateral giant axon and the giant motor fibre, was varied from -70 to +50 mV, the minimum and maximum junctional chord conductances (gmin and gmax, respectively) were found to be 1.2 +/- 1.3 microS (n = 10) and 22.9 +/- 6.3 microS (n = 10), respectively. 3. For a given Vj, changes in the lateral giant axon or giant motor fibre membrane potential over a range of +/- 30 mV around their resting levels did not influence the junctional permeability (gj), indicating that the inside-outside potential of the junctional channel does not control gj. 4. Therefore, the steady-state junctional chord conductances were dependent only upon Vj. 5. The voltage dependence of the chord conductance was well fitted by a modified Boltzmann relation given by the equation (Formula: see text) with the constants: A = 0.15 +/- 0.03 mV-1 (n = 10) and V0 = 28 +/- 4 mV (n = 10); the latter two parameters were also found to be independent of both transmembrane potentials. 6. The junctional currents were already constant 1 ms after step changes in the junctional voltage; this was three orders of magnitude faster than the other known examples of voltage-controlled gap junctions between embryonic cells. 7. Our results may be interpreted by a highly voltage-dependent probability of opening of the junctional channels. They also suggest that the gap-junction channels forming the giant motor synapse respond very rapidly to potential and that the hemi-channels which constitute them may not be symmetric.
摘要
- 利用双电压钳技术,在第二腹神经节中对螯虾的整流性巨运动突触进行了研究,该技术能够在各种固定的跨结电位下直接测量结电流。2. 跨结电位(Vj)定义为在外侧巨轴突和巨运动纤维中记录的电压之差,其变化范围为-70至+50 mV,最小和最大结弦电导(分别为gmin和gmax)分别为1.2±1.3微西门子(n = 10)和22.9±6.3微西门子(n = 10)。3. 对于给定的Vj,外侧巨轴突或巨运动纤维膜电位在其静息水平周围±30 mV范围内的变化不会影响结通透性(gj),这表明结通道的内外电位并不控制gj。4. 因此,稳态结弦电导仅取决于Vj。5. 弦电导的电压依赖性通过由方程(公式:见正文)给出的修正玻尔兹曼关系很好地拟合,常数为:A = 0.15±0.03 mV-1(n = 10)和V0 = 28±4 mV(n = 10);还发现后两个参数与两个跨膜电位均无关。6. 结电压阶跃变化1毫秒后,结电流就已恒定;这比胚胎细胞之间其他已知的电压控制间隙连接示例快三个数量级。7. 我们的结果可以用结通道开放的高度电压依赖性概率来解释。它们还表明,形成巨运动突触的间隙连接通道对电位反应非常迅速,并且构成它们的半通道可能不对称。
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