Angstadt J D, Calabrese R L
Department of Biology, Emory University, Atlanta, Georgia 30322.
J Neurosci. 1991 Mar;11(3):746-59. doi: 10.1523/JNEUROSCI.11-03-00746.1991.
Synaptic transmission between reciprocally inhibitory heart interneurons (HN cells) of the medicinal leech was examined in the absence of Na-mediated action potentials. Under voltage clamp, depolarizing steps from a holding potential of -60 mV elicited 2 kinetically distinct components of inward current in the presynaptic HN cell: an early transient current that inactivates within 200 msec and a persistent current that only partially decays over several seconds. Both currents begin to activate near -60 mV. Steady-state inactivation occurs over the voltage range between -70 and -45 mV and is completely removed by 1-2-sec hyperpolarizing voltage steps to -80 mV. The inward currents are carried by Ca2+, Ba2+, or Sr2+ ions, but not by Co2+, Mn2+, or Ni2+. These same inward currents underlie the burst-generating plateau potentials previously described in HN cells (Arbas and Calabrese, 1987a,b). With a presynaptic holding potential of -60 mV, the threshold for transmitter release is near -45 mV. Postsynaptic currents in the contralateral HN cell have a reversal potential near -60 mV. The largest postsynaptic currents (300-400 pA) exhibit an initial peak response that is followed by a more slowly decaying component. The persistent component of Ca2+ current in the presynaptic neuron is strongly correlated with the prolonged component of the postsynaptic current, while the transient presynaptic Ca2+ current appears to correspond to the early peak of postsynaptic current. These data are consistent with the hypothesis that voltage-dependent calcium currents contribute to the oscillatory capability of reciprocally inhibitory HN cells by (1) generating the plateau potential that drives the burst of action potentials and (2) underlying the release of inhibitory transmitter onto the contralateral cell.
在无钠介导动作电位的情况下,对药用水蛭相互抑制性心脏中间神经元(HN细胞)之间的突触传递进行了研究。在电压钳制下,从-60 mV的钳制电位进行去极化阶跃,在突触前HN细胞中引发了2种动力学上不同的内向电流成分:一种早期瞬态电流,在200毫秒内失活;一种持续电流,在数秒内仅部分衰减。两种电流均在接近-60 mV时开始激活。稳态失活发生在-70至-45 mV的电压范围内,并通过1 - 2秒的超极化电压阶跃至-80 mV而完全消除。内向电流由Ca2+、Ba2+或Sr2+离子携带,但不由Co2+、Mn2+或Ni2+携带。这些相同的内向电流是先前在HN细胞中描述的爆发性产生平台电位的基础(阿尔巴斯和卡拉布雷斯,1987a,b)。突触前钳制电位为-60 mV时,递质释放的阈值接近-45 mV。对侧HN细胞中的突触后电流的反转电位接近-60 mV。最大的突触后电流(300 - 400 pA)表现出一个初始峰值反应,随后是一个衰减更慢的成分。突触前神经元中Ca2+电流的持续成分与突触后电流的延长成分密切相关,而瞬态突触前Ca2+电流似乎对应于突触后电流的早期峰值。这些数据与以下假设一致,即电压依赖性钙电流通过以下方式促进相互抑制性HN细胞的振荡能力:(1)产生驱动动作电位爆发的平台电位,(2)为抑制性递质释放到对侧细胞上提供基础。