大鼠海马快速放电中间神经元与主神经元之间钠离子通道门控的功能差异
Functional differences in Na+ channel gating between fast-spiking interneurones and principal neurones of rat hippocampus.
作者信息
Martina M, Jonas P
机构信息
Physiologisches Institut, Universität Freiburg, Germany.
出版信息
J Physiol. 1997 Dec 15;505 ( Pt 3)(Pt 3):593-603. doi: 10.1111/j.1469-7793.1997.593ba.x.
Abstract
- GABAergic interneurones differ from glutamatergic principal neurones in their ability to discharge high-frequency trains of action potentials without adaptation. To examine whether Na+ channel gating contributed to these differences, Na+ currents were recorded in nucleated patches from interneurones (dentate gyrus basket cells, BCs) and principal neurones (CA1 pyramidal cells, PCs) of rat hippocampal slices. 2. The voltage dependence of Na+ channel activation in BCs and PCs was similar. The slope factors of the activation curves, fitted with Boltzmann functions raised to the third power, were 11.5 and 11.8 mV, and the mid-point potentials were -25.1 and -23.9 mV, respectively. 3. Whereas the time course of Na+ channel activation (-30 to +40 mV) was similar, the deactivation kinetics (-100 to -40 mV) were faster in BCs than in PCs (tail current decay time constants, 0.13 and 0.20 ms, respectively, at -40 mV). 4. Na+ channels in BCs and PCs differed in the voltage dependence of inactivation. The slope factors of the steady-state inactivation curves fitted with Boltzmann functions were 6.7 and 10.7 mV, and the mid-point potentials were -58.3 and -62.9 mV, respectively. 5. The onset of Na+ channel inactivation at -55 mV was slower in BCs than in PCs; the inactivation time constants were 18.6 and 9.3 ms, respectively. At more positive potentials the differences in inactivation onset were smaller. 6. The time course of recovery of Na+ channels from inactivation induced by a 30 ms pulse was fast and mono-exponential (tau = 2.0 ms at -120 mV) in BCs, whereas it was slower and bi-exponential in PCs (tau 1 = 2.0 ms and tau 2 = 133 ms; amplitude contribution of the slow component, 15%). 7. We conclude that Na+ channels of BCs and PCs differ in gating properties that contribute to the characteristic action potential patterns of the two types of neurones.
摘要
- γ-氨基丁酸能中间神经元与谷氨酸能主神经元的不同之处在于,它们能够发放高频动作电位序列而不出现适应现象。为了研究钠离子通道门控是否导致了这些差异,我们在大鼠海马切片的中间神经元(齿状回篮状细胞,BCs)和成神经元(CA1锥体细胞,PCs)的有核膜片上记录了钠离子电流。2. BCs和PCs中钠离子通道激活的电压依赖性相似。用三次方的玻尔兹曼函数拟合的激活曲线的斜率因子分别为11.5和11.8 mV,中点电位分别为-25.1和-23.9 mV。3. 虽然钠离子通道激活的时间进程(-30至+40 mV)相似,但BCs中失活动力学(-100至-40 mV)比PCs更快(在-40 mV时,尾电流衰减时间常数分别为0.13和0.20 ms)。4. BCs和PCs中的钠离子通道在失活的电压依赖性方面存在差异。用玻尔兹曼函数拟合的稳态失活曲线的斜率因子分别为6.7和10.7 mV,中点电位分别为-58.3和-62.9 mV。5. 在-55 mV时,BCs中钠离子通道失活的起始比PCs慢;失活时间常数分别为18.6和9.3 ms。在更正的电位下,失活起始的差异较小。6. BCs中钠离子通道从30 ms脉冲诱导的失活中恢复的时间进程快速且呈单指数形式(在-120 mV时,τ = 2.0 ms),而PCs中则较慢且呈双指数形式(τ1 = 2.0 ms,τ2 = 133 ms;慢成分的幅度贡献为15%)。7. 我们得出结论,BCs和PCs的钠离子通道在门控特性上存在差异,这有助于两种神经元的特征性动作电位模式。
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