Lang E J, Paré D
Département de Physiologie, Université Laval, Québec, Canada.
J Neurophysiol. 1997 Jan;77(1):353-63. doi: 10.1152/jn.1997.77.1.353.
The companion paper demonstrated that the responses of lateral amygdaloid (LAT) projection neurons to the stimulation of major input and output structures are dominated by monophasic hyperpolarizing potentials of large amplitude. To characterize the mechanisms underlying these inhibitory potentials, intracellular recordings of cortically evoked responses were obtained from morphologically and/or physiologically identified LAT projection neurons in barbiturate anesthetized cats. The reversal potential of the cortically evoked hyperpolarization was measured at its peak, and 115 ms later (tail), an interval corresponding to the peak latency of the gamma-aminobuturic acid-B (GABAB) response previously recorded in vitro. When recorded with K-acetate (KAc) pipettes, these reversal potentials were -86.9 +/- 1.6 mV (peak; mean +/- SE) and -90.7 +/- 1.7 mV (tail), suggesting that both Cl- and K+ conductances contribute throughout the cortically evoked hyperpolarization. The small, but consistent, difference between the two reversal potentials suggested that an additional slowly activating K(+)-mediated component contributed to the inhibitory postsynaptic potential (IPSP) tail. To determine whether Cl- conductances contributed to the evoked hyperpolarization, recordings were performed with KCl; the peak (-57.8 +/- 2.2 mV) and tail (-61.3 +/- 2.1 mV) reversal potentials were approximately 15-20 mV more depolarized than those recorded with KAc pipettes. However, the difference between the peak and tail reversals remained. In an attempt to block the Cl- conductance, recordings were obtained with pipettes filled with KAc or KCl and 4,4'-diisothiocyanostilbene-2,2'-disulphonic acid (DIDS), a Cl- pump blocker that also was reported to block GABAA responses. With KAc and DIDS, the initial depolarization was prolonged and the amplitude of the hyperpolarization decreased relative to that seen with KAc alone. However, with KCl and DIDS, the reversal potential was shifted to an even greater extent than with KCl pipettes with the evoked response consisting entirely of a large depolarization, which produced a spike burst. These results suggest that LAT neurons have a Cl- pump that is blocked by DIDS, but that their Cl- channels are not blocked by DIDS. To assess the contribution of K+ conductances to cortically evoked hyperpolarizing potentials, recordings were obtained with Cs-acetate pipettes. Under these conditions, the response reversed at more depolarized potentials (peak, -71.9 +/- 1.0 mV; tail, -72.0 +/- 0.9 mV) compared with KAc recordings, with no difference between the peak and tail reversal potentials. These cells also had depolarized resting potentials (-66.2 +/- 1.8 mV) compared with those of cells recorded with KAc pipettes (-73.6 +/- 1.8 mV); however, this difference was too small to attribute the shift in reversals to a redistribution of Cl- ions across the membrane. The action potentials generated by LAT neurons under Cs+ had a shoulder that prolonged their falling phase. The increased duration of the spikes was presumably due to a dendritic Ca2+ conductance because LAT amygdaloid neurons are known to possess such conductances and Cs+ blocks the delayed rectifier and some Ca(2+)-dependent K+ currents. The dramatic reduction of this shoulder by spontaneous and evoked IPSPs suggests that the activation of dendritic conductances by back-propagating somatic action potentials is regulated tightly by synaptic events. Intracellular injection of the Ca2+ chelating agent, 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (100 mM) caused a depolarization of the peak (-75.3 +/- 1.3 mV) and tail (-77.7 +/- 1.7 mV) reversal potentials during a time course of 15-45 min. Concurrently, the amplitude of the excitatory postsynaptic potential increased whereas that of the hyperpolarization decreased, suggesting that a Ca(2+)-dependent K+ conductance contributes significantly to the evoked hyperpolarization. (ABSTRACT TRUNCATED)
相关论文表明,外侧杏仁核(LAT)投射神经元对主要输入和输出结构刺激的反应,主要由大幅度的单相超极化电位主导。为了阐明这些抑制性电位背后的机制,在巴比妥类麻醉的猫中,从形态学和/或生理学上鉴定的LAT投射神经元获得皮质诱发反应的细胞内记录。在皮质诱发超极化的峰值处测量其反转电位,并在115毫秒后(尾期)测量,该间隔对应于先前在体外记录的γ-氨基丁酸B(GABAB)反应的峰值潜伏期。当用醋酸钾(KAc)微电极记录时,这些反转电位在峰值时为-86.9±1.6 mV(平均值±标准误),在尾期为-90.7±1.7 mV,这表明Cl-和K+电导在整个皮质诱发超极化过程中都有作用。两个反转电位之间虽小但一致的差异表明,一个额外的缓慢激活的K+介导成分对抑制性突触后电位(IPSP)的尾期有贡献。为了确定Cl-电导是否对诱发的超极化有作用,用氯化钾进行记录;峰值(-57.8±2.2 mV)和尾期(-61.3±2.1 mV)的反转电位比用KAc微电极记录时大约去极化15 - 20 mV。然而,峰值和尾期反转之间的差异仍然存在。为了试图阻断Cl-电导,用充满KAc或KCl以及4,4'-二异硫氰基芪-2,2'-二磺酸(DIDS,一种也被报道可阻断GABAA反应的Cl-泵阻滞剂)的微电极进行记录。使用KAc和DIDS时,初始去极化延长,超极化幅度相对于单独使用KAc时减小。然而,使用KCl和DIDS时,反转电位比使用KCl微电极时更大程度地偏移,诱发反应完全由一个大的去极化组成,产生了一个动作电位爆发。这些结果表明,LAT神经元有一个被DIDS阻断的Cl-泵,但它们的Cl-通道不被DIDS阻断。为了评估K+电导对皮质诱发超极化电位的贡献,用醋酸铯微电极进行记录。在这些条件下,与KAc记录相比,反应在更正的电位处反转(峰值,-71.9±1.0 mV;尾期,-72.0±0.9 mV),峰值和尾期反转电位之间没有差异。与用KAc微电极记录的细胞(-73.6±1.8 mV)相比,这些细胞的静息电位也去极化了(-66.2±1.8 mV);然而,这种差异太小,无法将反转的偏移归因于Cl-离子跨膜的重新分布。在Cs+存在下LAT神经元产生的动作电位有一个平台期,延长了其下降相。动作电位持续时间的增加可能是由于树突状Ca2+电导,因为已知LAT杏仁核神经元具有这种电导,并且Cs+阻断延迟整流器和一些Ca(2+)依赖性K+电流。自发和诱发的IPSP使这个平台期显著缩短,这表明由躯体动作电位反向传播激活的树突状电导受到突触事件的严格调节。细胞内注射Ca2+螯合剂1,2-双(2-氨基苯氧基)乙烷-N,N,N',N'-四乙酸(100 mM)在15 - 45分钟的时间进程中导致峰值(-75.3±1.3 mV)和尾期(-77.7±1.7 mV)反转电位去极化。同时,兴奋性突触后电位的幅度增加而超极化的幅度减小,这表明一个Ca(2+)依赖性K+电导对诱发的超极化有显著贡献。(摘要截断)
