Kiernan M C, Baker M D, Bostock H
Sobell Department of Neurophysiology, Institute of Neurology, Queen Square, WC1N 3BG, London, UK.
Neuroscience. 2003;119(3):653-60. doi: 10.1016/s0306-4522(03)00194-5.
Na(+) currents were recorded using patch-clamp techniques from small-diameter (<25 micrometers) dorsal root ganglion neurons, cultured from adult rats (>150 g). Late Na(+) currents maintained throughout long-duration voltage-clamp steps (>/=200 ms) were of two types: a low-threshold, tetrodotoxin-sensitive (TTX-s) current that was largely blocked by 200 nM TTX, and a high-threshold, TTX-resistant (TTX-r) current. TTX-s late current was found in approximately 28% (10/36) of small-diameter neurons and was recorded only in neurons exhibiting TTX-s transient current. TTX-s transient current activation/inactivation gating overlap existed over a narrow potential range, centered between -30 and -40 mV, whereas late current operated over a wider range. The kinetics associated with de-inactivation of TTX-s late current were slow (tau approximately 37 ms at -50 mV), strongly suggesting that different subpopulations of TTX-s channel generate transient and late current. High-threshold TTX-r late current was only present in neurons generating TTX-r transient current. TTX-r late current operated over the same potential range as that for TTX-r transient current activation/inactivation gating overlap, and activation/inactivation gating overlap could be measured even after 1.5-s-duration pre-pulses. We suggest that TTX-s late sodium current results from channel openings different from those generating transient current. As in large-diameter sensory neurons, TTX-s channels generating late openings may play a key role in controlling membrane excitability. In contrast, a single population of high-threshold TTX-r channels may account for both transient and late TTX-r currents.
采用膜片钳技术,从成年大鼠(体重>150克)培养的小直径(<25微米)背根神经节神经元记录钠电流。在长时间电压钳步骤(≥200毫秒)中持续存在的晚期钠电流有两种类型:一种低阈值、河豚毒素敏感(TTX-s)电流,在很大程度上被200 nM河豚毒素阻断;另一种是高阈值、河豚毒素抵抗(TTX-r)电流。在约28%(10/36)的小直径神经元中发现了TTX-s晚期电流,且仅在表现出TTX-s瞬时电流的神经元中记录到。TTX-s瞬时电流的激活/失活门控重叠存在于一个狭窄的电位范围内,中心在-30至-40 mV之间,而晚期电流在更宽的范围内起作用。与TTX-s晚期电流去失活相关的动力学缓慢(在-50 mV时τ约为37毫秒),这强烈表明TTX-s通道的不同亚群产生瞬时电流和晚期电流。高阈值TTX-r晚期电流仅存在于产生TTX-r瞬时电流的神经元中。TTX-r晚期电流在与TTX-r瞬时电流激活/失活门控重叠相同的电位范围内起作用,即使在持续1.5秒的预脉冲后也能测量到激活/失活门控重叠。我们认为,TTX-s晚期钠电流是由与产生瞬时电流不同的通道开放引起的。与大直径感觉神经元一样,产生晚期开放的TTX-s通道可能在控制膜兴奋性方面起关键作用。相比之下,单一的高阈值TTX-r通道群体可能同时负责瞬时和晚期TTX-r电流。
