Bollmann Johann H, Engert Florian
Department of Molecular and Cellular Biology, Harvard University, Biolabs 2073, 16 Divinity Avenue, Cambridge, MA 02138, USA.
Neuron. 2009 Mar 26;61(6):895-905. doi: 10.1016/j.neuron.2009.01.018.
Neural pathways projecting from sensory organs to higher brain centers form topographic maps in which neighbor relationships are preserved from a sending to a receiving neural population. Sensory input can generate compartmentalized electrical and biochemical activity in the dendrites of a receiving neuron. Here, we show that in the developing retinotectal projection of young Xenopus tadpoles, visually driven Ca2+ signals are topographically organized at the subcellular, dendritic scale. Functional in vivo two-photon Ca2+ imaging revealed that the sensitivity of dendritic Ca2+ signals to stimulus location in visual space is correlated with their anatomical position within the dendritic tree of individual neurons. This topographic distribution was dependent on NMDAR activation, whereas global Ca2+ signals were mediated by Ca2+ influx through dendritic, voltage-dependent Ca2+ channels. These findings suggest a framework for plasticity models that invoke local dendritic Ca2+ signaling in the elaboration of neural connectivity and dendrite-specific information storage.
从感觉器官投射到高级脑中枢的神经通路形成了拓扑图,其中从发送神经群体到接收神经群体的邻接关系得以保留。感觉输入可在接收神经元的树突中产生分隔的电活动和生化活动。在这里,我们表明,在非洲爪蟾幼体发育中的视网膜顶盖投射中,视觉驱动的Ca2+信号在亚细胞、树突尺度上呈拓扑组织。功能性体内双光子Ca2+成像显示,树突Ca2+信号对视觉空间中刺激位置的敏感性与其在单个神经元树突树内的解剖位置相关。这种拓扑分布依赖于NMDAR激活,而全局Ca2+信号则由通过树突电压依赖性Ca2+通道的Ca2+内流介导。这些发现为可塑性模型提供了一个框架,该模型在神经连接的细化和树突特异性信息存储中调用局部树突Ca2+信号传导。