Tazaki K, Cooke I M
J Neurophysiol. 1986 Dec;56(6):1739-62. doi: 10.1152/jn.1986.56.6.1739.
Crustacean cardiac ganglion neuronal somata, although incapable of generating action potentials, produce regenerative, slow (greater than 200 ms) depolarizing potentials reaching -20 mV (from -50 mV) in response to depolarizing stimuli. These potentials initiate a burst of action potentials in the axon and are thus termed driver potentials. The somata of the anterior-most neurons (cells 1 or 2) were isolated by ligaturing for study of their membrane currents with a two-electrode voltage clamp. Inward current is attributed to Ca2+ by reason of dependence of driver potential amplitude on [Ca2+]0, independence of [Na+]0, resistance to tetrodotoxin, and inhibition by Cd (0.2 mM) and Mn (4 mM). Ca-mediated current (ICa) is present at -40 mV. It is optimally activated by a holding potential (Vh) of -50 to -60 mV and by clamps (command potential, Vc) to -10 mV. Time to peak (10-30 ms) and amplitude are strongly voltage dependent. Maximum tail-current amplitudes observed at -70 to -85 mV are ca. 100 nA. Inward tail peaks may not be resolved by our clamp (settling time, 2 ms). Tails relax with a time constant (tau) of approximately equal to 12 ms (at -70 to -85 mV). ICa exhibits inactivation in double pulse regimes. Recovery has a tau of approximately equal to 0.7 s. Tail current analyses indicate an exponential decline (tau approximately equal to 23 ms at -20 mV) toward a maintained amplitude of inward current tails. Analysis of outward currents indicates the presence of three conductance mechanisms having voltage dependences, time courses, and pharmacology similar to those of early outward current (IA), delayed outward current (IK), and outward current (IC) of molluscan neurons. Analysis of tail currents indicates a reversal potential for each of these near -75 mV, indicating that they are K currents. Early outward current, IA, shows a peak at 5 ms followed by rapid decline. Response to a second clamp given within 0.4 s is reduced; recovery is exponential, with a tau of approximately equal to 200 ms (at Vh = -50 mV). The amplitude of IA tested at 0 mV shows activation or deactivation by subthreshold shifts of Vh. The extent and rate of these changes shows voltage dependence (tau approximately equal to 100-500 ms for subthreshold prepulses). At the normal cell resting potential of -50 mV the amplitude of IA is 25% of that tested from -80 mV.(ABSTRACT TRUNCATED AT 400 WORDS)
甲壳类动物心脏神经节神经元胞体虽然不能产生动作电位,但在受到去极化刺激时,会产生再生性的缓慢(大于200毫秒)去极化电位,从-50毫伏达到-20毫伏。这些电位会引发轴突中的一阵动作电位,因此被称为驱动电位。最前端神经元(细胞1或2)的胞体通过结扎进行分离,以便用双电极电压钳研究其膜电流。内向电流归因于Ca2+,原因是驱动电位幅度依赖于[Ca2+]0、独立于[Na+]0、对河豚毒素有抗性,以及受Cd(0.2毫摩尔)和Mn(4毫摩尔)抑制。Ca介导的电流(ICa)在-40毫伏时存在。它在-50至-60毫伏的钳制电位(Vh)以及钳制到-10毫伏(指令电位,Vc)时被最佳激活。达到峰值的时间(10 - 30毫秒)和幅度强烈依赖于电压。在-70至-85毫伏观察到的最大尾电流幅度约为100纳安。我们的电压钳可能无法分辨内向尾峰(建立时间为2毫秒)。尾电流以约12毫秒的时间常数(tau)松弛(在-70至-85毫伏时)。ICa在双脉冲模式下表现出失活。恢复的时间常数约为0.7秒。尾电流分析表明内向电流尾向维持幅度呈指数下降(在-20毫伏时tau约为23毫秒)。外向电流分析表明存在三种电导机制,其电压依赖性、时间进程和药理学与软体动物神经元的早期外向电流(IA)、延迟外向电流(IK)和外向电流(IC)相似。尾电流分析表明这些电流各自的反转电位接近-75毫伏,表明它们是K电流。早期外向电流IA在5毫秒时达到峰值,随后迅速下降。在0.4秒内给予的第二个钳制的反应会降低;恢复是指数性的,时间常数约为200毫秒(在Vh = -50毫伏时)。在0毫伏测试的IA幅度会因Vh的阈下变化而激活或失活。这些变化的程度和速率显示出电压依赖性(阈下预脉冲的tau约为100 - 500毫秒)。在正常细胞静息电位-50毫伏时,IA的幅度是在-80毫伏测试时的25%。(摘要截断于400字)
