Rörig B, Grantyn R
Department of Neurophysiology, Max Planck Institute for Psychiatry, Martinsried, FRG.
Brain Res Dev Brain Res. 1993 Jul 16;74(1):98-110. doi: 10.1016/0165-3806(93)90088-r.
This study was aimed at characterizing the earliest phases of synaptogenesis in the mammalian retina. Spontaneous activity of ganglion cells in the isolated superfused retina was used as an indicator for the functionality of synaptic connections. Retinal ganglion neurons (RGNs) were identified by location of their somata in the ganglion cell layer (GCL) and by their ability to generate large (> 500 pA) voltage-activated sodium currents. Spontaneous spiking was found in many RGNs prior to cell perfusion. Between postnatal day (P) 1 and 18, a total of 195 RGNs was tested for light-induced currents, conductance changes in response to exogenous glutamate (Glu) and gamma-aminobutyric acid (GABA), and depolarizing or hyperpolarizing synaptic activity. The vast majority of the material was derived from RGNs at day P5. Whole-cell ion currents were always sampled at somatic sites, using either conventional or perforated patch whole-cell recordings. On day P5, 5% of tested RGNs (n = 73) were already responsive to light stimulation. A higher percentage of cells (23%, n = 187) generated spontaneous depolarizing currents that were regarded as glutamatergic excitatory postsynaptic currents (EPSCs), since (1) they were blocked by Glu antagonists, (2) they conformed to the Na+/Cs+ equilibrium potential, (3) and they displayed a time course characteristic of glutamatergic EPSCs. The mean EPSC amplitude was 19.0 pA (S.D. 11.83 pA). Amplitude distributions were fitted by multiple Gaussian equations rendering a quantal size of 6.6 to 9.1 pA at a holding voltage (Vh) of -70 mV (driving force about 70 mV). Spontaneous EPSCs were never observed under condition of Ca(2+)-free solutions, but they persisted in the presence of tetrodotoxin. Bath application of quisqualate (500 microM) consistently increased EPSC frequencies. In contrast to the relatively high percentage of RGNs generating spontaneous EPSCs, very few RGNs at P5 (3%, n = 187) displayed inhibitory postsynaptic currents (IPSCs), although by that time all tested RGNs (n = 14) were responsive to both exogenous Glu and GABA. These results indicate that in the postnatal rat retina development of excitatory synapses precedes the maturation of inhibitory afferents. Excitatory inputs to RGNs were to some extent functional before the animals opened their eyes. Glutamatergic synaptic activity may, thus, play an important role in shaping visual connections in the absence of visual experience.
本研究旨在表征哺乳动物视网膜突触发生的最早阶段。将分离的灌注视网膜中神经节细胞的自发活动用作突触连接功能的指标。视网膜神经节神经元(RGNs)通过其胞体在神经节细胞层(GCL)中的位置以及产生大的(>500 pA)电压激活钠电流的能力来识别。在细胞灌注前,在许多RGNs中发现了自发放电。在出生后第(P)1天至18天期间,总共对195个RGNs进行了光诱导电流、对外源性谷氨酸(Glu)和γ-氨基丁酸(GABA)的电导变化以及去极化或超极化突触活动的测试。绝大多数材料来自P5天的RGNs。使用传统的或穿孔膜片全细胞记录,总是在体细胞部位采样全细胞离子电流。在P5天,5%的测试RGNs(n = 73)已经对光刺激有反应。更高比例的细胞(23%,n = 187)产生自发去极化电流,这些电流被视为谷氨酸能兴奋性突触后电流(EPSCs),因为(1)它们被Glu拮抗剂阻断,(2)它们符合Na+/Cs+平衡电位,(3)并且它们表现出谷氨酸能EPSCs的时间进程特征。平均EPSC幅度为19.0 pA(标准差11.83 pA)。幅度分布通过多个高斯方程拟合,在-70 mV的钳制电压(Vh)下(驱动力约70 mV)得出量子大小为6.6至9.1 pA。在无钙溶液条件下从未观察到自发EPSCs,但在存在河豚毒素的情况下它们持续存在。浴用quisqualate(500 microM)持续增加EPSC频率。与产生自发EPSCs的RGNs相对较高的比例相反,P5天的RGNs中很少(3%,n = 187)表现出抑制性突触后电流(IPSCs),尽管此时所有测试的RGNs(n = 14)对外源性Glu和GABA都有反应。这些结果表明,在出生后的大鼠视网膜中,兴奋性突触的发育先于抑制性传入神经的成熟。在动物睁眼之前,对RGNs的兴奋性输入在一定程度上已经起作用。因此,谷氨酸能突触活动可能在缺乏视觉经验的情况下塑造视觉连接中发挥重要作用。
