Binder M D, Robinson F R, Powers R K
Department of Physiology and Biophysics, University of Washington, School of Medicine, Seattle, Washington 98195, USA.
J Neurophysiol. 1998 Jul;80(1):241-8. doi: 10.1152/jn.1998.80.1.241.
We measured the effective synaptic currents (IN) produced by stimulating the contralateral pyramidal tract (PT) in triceps surae motoneurons of the cat. This is an oligosynaptic pathway in the cat that generates both excitation and inhibition in hindlimb motoneurons. We also determined the effect of the PT synaptic input on the discharge rate of some of the motoneurons by inducing repetitive firing with long, injected current pulses during which the PT stimulation was repeated. At resting potential, all but one triceps motoneuron received a net depolarizing effective synaptic current from the PT stimulation. The effective synaptic currents (IN) were much larger in putative type F motoneurons than in putative type S motoneurons [+4.6 +/- 2.9 (SD) nA for type F vs. 0.9 +/- 2.4 nA for putative type S]. When the values of IN at the threshold for repetitive firing were estimated, the distribution was markedly altered. More than 60% of the putative type S motoneurons received a net hyperpolarizing effective synaptic current from the pyramidal tract stimulation as did 33% of the putative type F motoneurons. This distribution pattern is very similar to that observed previously for the effective synaptic currents produced by stimulating the contralateral red nucleus. As would be expected from the wide range of IN values at threshold (-4.8 to +8.7 nA), the PT stimulation produced dramatically different effects on the discharge of different triceps motoneurons. The discharge rates of those motoneurons that received depolarizing effective synaptic currents at threshold were accelerated by PT stimulation (+1 to +8 imp/s), whereas the discharge rates of cells that received hyperpolarizing currents were retarded by the PT input (-2 to -7 imp/s). The change in firing rates produced by the PT stimulation was generally approximated by the product of the effective synaptic currents and the slopes of the motoneurons' frequency-current relations. Our findings indicate that the contralateral pyramidal tract may provide a powerful source of synaptic drive to some high-threshold motoneurons while concurrently inhibiting low-threshold cells. Thus this input system, like that from the contralateral red nucleus, can potentially alter the gain of the input-output function of the motoneuron pool as well as disrupt the normal hierarchy of recruitment thresholds.
我们测量了刺激猫腓肠三头肌运动神经元的对侧锥体束(PT)所产生的有效突触电流(IN)。这是猫体内的一条多突触通路,可在后肢运动神经元中产生兴奋和抑制作用。我们还通过在长时间注入电流脉冲期间重复PT刺激来诱导重复放电,从而确定了PT突触输入对一些运动神经元放电率的影响。在静息电位时,除一个腓肠三头肌运动神经元外,其他所有运动神经元均从PT刺激中接收到净去极化有效突触电流。假定的F型运动神经元中的有效突触电流(IN)比假定的S型运动神经元中的大得多[F型为+4.6±2.9(标准差)nA,假定的S型为0.9±2.4 nA]。当估计重复放电阈值时的IN值时,分布明显改变。超过60%的假定S型运动神经元从锥体束刺激中接收到净超极化有效突触电流;33%的假定F型运动神经元也是如此。这种分布模式与先前观察到的刺激对侧红核所产生的有效突触电流的分布模式非常相似。正如从阈值处IN值的广泛范围(-4.8至+8.7 nA)所预期的那样,PT刺激对不同的腓肠三头肌运动神经元的放电产生了截然不同的影响。那些在阈值处接收到去极化有效突触电流的运动神经元的放电率因PT刺激而加速(+1至+8次/秒),而接收到超极化电流的细胞的放电率则因PT输入而减慢(-2至-7次/秒)。PT刺激所产生的放电率变化通常可由有效突触电流与运动神经元频率-电流关系的斜率之积近似得出。我们的研究结果表明,对侧锥体束可能为一些高阈值运动神经元提供强大的突触驱动源,同时抑制低阈值细胞。因此,这个输入系统与来自对侧红核的输入系统一样,有可能改变运动神经元池的输入-输出功能增益,并打乱募集阈值的正常等级。
