Baker M D, Bostock H
Sobell Department of Neurophysiology, Institute of Neurology, London WC1N 3BG, United Kingdom.
J Neurophysiol. 1998 Nov;80(5):2538-49. doi: 10.1152/jn.1998.80.5.2538.
Na+ currents in adult rat large dorsal root ganglion neurons were recorded during long duration voltage-clamp steps by patch clamping whole cells and outside-out membrane patches. Na+ current present >60 ms after the onset of a depolarizing pulse (late Na+ current) underwent partial inactivation; it behaved as the sum of three kinetically distinct components, each of which was blocked by nanomolar concentrations of tetrodotoxin. Inactivation of one component (late-1) of the whole cell current reached equilibrium during the first 60 ms; repolarizing to -40 or -50 mV from potentials of -30 mV or more positive gave rise to a characteristic increase in current (tau >/= 5 ms), attributed to removal of inactivation. A second component (late-2) underwent slower inactivation (tau > 80 ms) at potentials more positive than -80 mV, and steady-state inactivation appeared complete at -30 mV. In small membrane patches, bursts of brief openings (gamma = 13-18 pS) were usually recorded. The distribution of burst durations indicated that two populations of channel were present with inactivation rates corresponding to late-1 and late-2 macroscopic currents. The persistent Na+ current in the whole cell that extended to potentials more positive than -30 mV appeared to correspond to sporadic, brief openings that were recorded in patches (mean open time approximately 0.1 ms) over a wide potential range. None of the three types of gating described corresponded to activation/inactivation gating overlap of fast transient currents.
采用全细胞膜片钳和外向膜片钳技术,在长时间电压钳步骤中记录成年大鼠大背根神经节神经元的Na⁺电流。去极化脉冲开始后>60 ms出现的Na⁺电流(晚Na⁺电流)发生部分失活;它表现为三个动力学上不同的成分之和,每个成分都被纳摩尔浓度的河豚毒素阻断。全细胞电流的一个成分(晚-1)的失活在最初60 ms内达到平衡;从-30 mV或更正的电位复极化到-40或-50 mV会导致电流特征性增加(时间常数τ≥5 ms),这归因于失活的解除。第二个成分(晚-2)在比-80 mV更正的电位下经历较慢的失活(时间常数τ>80 ms),并且在-30 mV时稳态失活似乎完全。在小膜片中,通常记录到短暂开放的爆发(电导γ = 13 - 18 pS)。爆发持续时间的分布表明存在两种通道群体,其失活速率对应于晚-1和晚-2宏观电流。全细胞中持续到比-30 mV更正电位的持续Na⁺电流似乎对应于在宽电位范围内在膜片中记录到的零星短暂开放(平均开放时间约0.1 ms)。所描述的三种门控类型均与快速瞬态电流的激活/失活门控重叠无关。
