Bosman Laurens W J, Rosahl Thomas W, Brussaard Arjen B
Department of Experimental Neurophysiology, Research Institute Neurosciences, Faculty of Earth and Life Sciences, Vrije Universiteit Amsterdam, De Boelelaan 1085, 1081 HV Amsterdam, The Netherlands.
J Physiol. 2002 Nov 15;545(1):169-81. doi: 10.1113/jphysiol.2002.026534.
Each GABA(A) receptor consists of two alpha and three other subunits. The spatial and temporal distribution of different alpha subunit isomeres expressed by the CNS is highly regulated. Here we study changes in functional contribution of different alpha subunits during neonatal development in rat visual cortex. First, we characterized postsynaptic alpha subunit expression in layer II-III neurons, using subunit-specific pharmacology combined with electrophysiological recordings in acutely prepared brain slices. This showed clear developmental downregulation of the effects of bretazenil (1 microm) and marked upregulation of the effect of 100 nM of zolpidem on the decay of spontaneous inhibitory postsynaptic currents (sIPSCs). Given the concentrations used we interpret this as downregulation of the synaptic alpha3 and upregulation of alpha1 subunit. Furthermore, the effect of furosemide, being indicative of the functional contribution of alpha4, was increased between postnatal days 6 and 21. Our second aim was to study the effects of plasticity in alpha subunit expression on decay properties of GABAergic IPSCs. We found that bretazenil-sensitive IPSCs have the longest decay time constant in juvenile neurons. In mature neurons, zolpidem- and furosemide-sensitive IPSCs have relatively fast decay kinetics, whereas bretazenil-sensitive IPSCs decay relatively slowly. Analysis of alpha1 deficient mice and alpha1 antisense oligonucleotide deletion in rat explants showed similar results to those obtained by zolpidem application. Thus, distinct alpha subunit contributions create heterogeneity in developmental acceleration of IPSC decay in neocortex.
每个GABA(A)受体由两个α亚基和另外三个亚基组成。中枢神经系统表达的不同α亚基异构体的空间和时间分布受到高度调控。在此,我们研究大鼠视觉皮层新生儿发育过程中不同α亚基功能贡献的变化。首先,我们利用亚基特异性药理学结合急性制备脑片中的电生理记录,对II-III层神经元中突触后α亚基的表达进行了表征。这显示了bretazenil(1微摩尔)作用的明显发育性下调以及100纳摩尔唑吡坦对自发性抑制性突触后电流(sIPSCs)衰减作用的显著上调。鉴于所使用的浓度,我们将此解释为突触α3的下调和α1亚基的上调。此外,速尿的作用(指示α4的功能贡献)在出生后第6天至21天之间增强。我们的第二个目标是研究α亚基表达可塑性对GABA能IPSCs衰减特性的影响。我们发现,bretazenil敏感的IPSCs在幼年神经元中具有最长的衰减时间常数。在成熟神经元中,唑吡坦和速尿敏感的IPSCs具有相对较快的衰减动力学,而bretazenil敏感的IPSCs衰减相对较慢。对α1缺陷小鼠和大鼠外植体中α1反义寡核苷酸缺失的分析显示,结果与应用唑吡坦获得的结果相似。因此,不同的α亚基贡献在新皮层IPSC衰减的发育加速中产生了异质性。