低频节律性突触电位在猫丘脑皮质细胞同步化中的作用。
A role for low-frequency, rhythmic synaptic potentials in the synchronization of cat thalamocortical cells.
作者信息
Soltesz I, Crunelli V
机构信息
Department of Visual Science, Institute of Ophthalmology, London.
出版信息
J Physiol. 1992 Nov;457:257-76. doi: 10.1113/jphysiol.1992.sp019377.
Abstract
- Low-frequency, rhythmic synaptic potentials and their ability to evoke and modulate membrane potential oscillations in thalamocortical (TC) cells of the cat dorsal lateral geniculate nucleus (dLGN) were investigated using intracellular recordings in a brain slice preparation. Three types of rhythmic synaptic potentials were distinguished: EPSPs, IPSPs and 'complex synaptic potentials' consisting of an IPSP followed by an EPSP. 2. The frequency of all three types of synaptic potentials was insensitive to changes in the membrane potential. At potentials positive to -50 mV, the EPSPs and the complex potentials gave rise to action potentials, while between -65 and -80 mV all three types of synaptic potential evoked low-threshold Ca2+ potentials. TC cells which displayed rhythmic synaptic potentials were either cells that showed spontaneous pacemaker oscillation or cells that were brought to oscillate by the rhythmic EPSPs or depolarizing (i.e. reversed IPSPs. 3. The low-frequency (1.9 +/- 0.2 Hz), rhythmic EPSPs were observed in 23 (out of 192) cells, were abolished by tetrodotoxin (TTX; n = 4) and by the combined application of DL-2-amino-5-phosphonovaleric acid and 6-cyano-7-nitroquinoxaline-2,3-dione (n = 3), and were insensitive to bicuculline (n = 4). Paired intracellular recordings (n = 32) demonstrated the presence of simultaneously occurring EPSPs in a pair of cells situated 75 microns apart. 4. The low-frequency (2.2 +/- 0.3 Hz), rhythmic IPSPs were observed in 5 (out of 192) cells, were blocked by bicuculline (n = 3), and reversed in polarity at -65 mV. The low-frequency (1.3 +/- 0.3 Hz), rhythmic 'complex potentials' were observed in 5 (out of 192) cells and were abolished by TTX (n = 2). 5. Intracellular depolarizing current pulses delivered at different phases of the pacemaker oscillations revealed the existence of two different types of phase resetting. Furthermore, a current pulse of critical amplitude and duration applied at a specific phase of the cycle abolished the pacemaker oscillations. 6. These results indicate that the low-frequency, rhythmic synaptic potentials recorded in TC cells of the dLGN (i) originate from other TC cells that are in the pacemaker oscillating mode, (ii) are capable of driving other TC cells to oscillate rhythmically, or of modulating the frequency of pacemaker oscillations, and (iii) provide a means by which oscillatory activities of TC cells can be synchronized in the absence of sensory, cortical and reticular thalamic inputs.
摘要
- 利用脑片制备中的细胞内记录技术,研究了猫背外侧膝状体核(dLGN)丘脑皮质(TC)细胞中低频、节律性突触电位及其诱发和调节膜电位振荡的能力。区分出三种类型的节律性突触电位:兴奋性突触后电位(EPSPs)、抑制性突触后电位(IPSPs)以及由一个IPSP后跟一个EPSP组成的“复合突触电位”。2. 所有这三种类型突触电位的频率对膜电位的变化不敏感。在高于 -50 mV的电位时,EPSPs和复合电位可引发动作电位,而在 -65至 -80 mV之间,所有三种类型的突触电位均可诱发低阈值Ca2+电位。显示节律性突触电位的TC细胞要么是表现出自发性起搏器振荡的细胞,要么是被节律性EPSPs或去极化(即反向IPSPs)带动振荡的细胞。3. 在192个细胞中的23个细胞中观察到了低频(1.9±0.2 Hz)、节律性EPSPs,它们被河豚毒素(TTX;n = 4)以及DL - 2 - 氨基 - 5 - 膦酸戊酸和6 - 氰基 - 7 - 硝基喹喔啉 - 2,3 - 二酮的联合应用(n = 3)所消除,并且对荷包牡丹碱不敏感(n = 4)。配对细胞内记录(n = 32)表明,在相距75微米的一对细胞中存在同时发生的EPSPs。4. 在192个细胞中的5个细胞中观察到了低频(2.2±0.3 Hz)、节律性IPSPs,它们被荷包牡丹碱阻断(n = 3),并且在 -65 mV时极性反转。在192个细胞中的5个细胞中观察到了低频(1.3±0.3 Hz)、节律性“复合电位”,它们被TTX消除(n = 2)。5. 在起搏器振荡的不同阶段施加细胞内去极化电流脉冲,揭示了存在两种不同类型的相位重置。此外,在周期的特定阶段施加临界幅度和持续时间的电流脉冲可消除起搏器振荡。6. 这些结果表明,在dLGN的TC细胞中记录到的低频、节律性突触电位:(i)源自处于起搏器振荡模式的其他TC细胞;(ii)能够驱动其他TC细胞进行节律性振荡,或调节起搏器振荡的频率;(iii)提供了一种在没有感觉、皮质和丘脑网状输入的情况下使TC细胞的振荡活动同步的方式。
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