Wilson C J, Chang H T, Kitai S T
Department of Anatomy and Neurobiology, University of Tennessee, Memphis College of Medicine 38163.
J Neurosci. 1990 Feb;10(2):508-19. doi: 10.1523/JNEUROSCI.10-02-00508.1990.
Intracellular recordings were made in vivo from 9 giant aspiny neurons in the neostriatum of urethane-anesthetized rats. The cells were identified by intracellular staining with HRP or biocytin. The neurons exhibited morphological features typical of neostriatal cholinergic interneurons. Six of the cells were obtained from intact animals, while 3 were recorded from rats with ipsilateral hemidecortications. Giant aspiny neurons were characterized by their slow irregular but tonic (3-10/sec) spontaneous activity and long-duration action potentials. Examination of the underlying membrane potential trajectories during spontaneous firing revealed that individual action potentials were triggered from spontaneous small (1-5 mV) depolarizing potentials. These spontaneous potentials exhibited the voltage sensitivity of ordinary EPSPs. They were much less frequent during the 80-200 msec pause in tonic afferent input that follows the excitation evoked by cortical or thalamic stimulation, and were decreased in frequency in decorticate animals. Their rise times and half-widths matched those expected for unitary synaptic potentials placed proximally on the surface of the neurons. Low-intensity stimulation of neostriatal afferents produced small short-latency EPSPs that appeared to be composed of responses identical to the spontaneous depolarizing potentials. The latencies of the EPSPs evoked from the cerebral cortex and thalamus were consistent with a monosynaptic input from both structures, but the maximal size of the EPSPs was much smaller than that evoked in spiny neurons, suggesting that a smaller number of afferent inputs make synapses with each of the aspiny cells. Giant aspiny neurons exhibited much larger input resistances and longer time constants than spiny neostriatal neurons. They also exhibited relatively linear steady-state current-voltage relationship compared to spiny projection cells. Input resistances ranged from 71-105 M omega, and time constants ranged from 17.8-28.5 msec. Analysis of the charging transients in response to current pulses yielded estimates of dendritic length of approximately 1 length constant. Repetitive firing of the neurons was limited by a powerful spike afterhyperpolarization and by a strong spike frequency adaptation. The sensitivity of the giant aspiny interneuron to a relatively small number of proximal afferent synaptic contacts, its tonic firing, and its widespread dendritic and axonal fields place it in an excellent position to act as a modulator of the excitability of neostriatal projection neurons in advance of the onset of movement-related neostriatal activity.
在对氨基甲酸乙酯麻醉的大鼠新纹状体中的9个巨大无棘神经元进行了体内细胞内记录。通过用辣根过氧化物酶(HRP)或生物胞素进行细胞内染色来识别这些细胞。这些神经元表现出典型的新纹状体胆碱能中间神经元的形态特征。其中6个细胞取自完整动物,而3个细胞是从同侧半大脑皮层切除的大鼠中记录的。巨大无棘神经元的特征在于其缓慢不规则但持续性的(3 - 10次/秒)自发活动以及长时程动作电位。在自发放电期间对基础膜电位轨迹的检查表明,单个动作电位是由自发的小(1 - 5毫伏)去极化电位触发的。这些自发电位表现出普通兴奋性突触后电位(EPSP)的电压敏感性。在皮层或丘脑刺激诱发的兴奋之后的80 - 200毫秒紧张性传入输入暂停期间,它们的频率要低得多,并且在去大脑皮层动物中频率降低。它们的上升时间和半高宽与置于神经元表面近端的单个突触电位预期的相符。新纹状体传入纤维的低强度刺激产生小的短潜伏期EPSP,这些EPSP似乎由与自发去极化电位相同的反应组成。从大脑皮层和丘脑诱发的EPSP的潜伏期与来自这两个结构的单突触输入一致,但EPSP的最大幅度比在有棘神经元中诱发的要小得多,这表明与每个无棘细胞形成突触的传入输入数量较少。巨大无棘神经元表现出比有棘新纹状体神经元大得多的输入电阻和更长的时间常数。与有棘投射细胞相比,它们还表现出相对线性的稳态电流 - 电压关系。输入电阻范围为71 - 105兆欧,时间常数范围为17.8 - 28.5毫秒。对电流脉冲响应的充电瞬变分析得出树突长度估计约为1个长度常数。神经元的重复放电受到强大的动作电位后超极化和强烈的动作电位频率适应性的限制。巨大无棘中间神经元对相对较少数量的近端传入突触联系的敏感性、其紧张性放电以及其广泛的树突和轴突场,使其处于一个极佳的位置,能够在与运动相关的新纹状体活动开始之前,作为新纹状体投射神经元兴奋性的调节剂发挥作用。