海马体中的树突抑制支持恐惧学习。
Dendritic inhibition in the hippocampus supports fear learning.
机构信息
Doctoral Program in Neurobiology and Behavior, Columbia University, New York, NY, USA.
出版信息
Science. 2014 Feb 21;343(6173):857-63. doi: 10.1126/science.1247485.
Abstract
Fear memories guide adaptive behavior in contexts associated with aversive events. The hippocampus forms a neural representation of the context that predicts aversive events. Representations of context incorporate multisensory features of the environment, but must somehow exclude sensory features of the aversive event itself. We investigated this selectivity using cell type-specific imaging and inactivation in hippocampal area CA1 of behaving mice. Aversive stimuli activated CA1 dendrite-targeting interneurons via cholinergic input, leading to inhibition of pyramidal cell distal dendrites receiving aversive sensory excitation from the entorhinal cortex. Inactivating dendrite-targeting interneurons during aversive stimuli increased CA1 pyramidal cell population responses and prevented fear learning. We propose subcortical activation of dendritic inhibition as a mechanism for exclusion of aversive stimuli from hippocampal contextual representations during fear learning.
摘要
恐惧记忆指导与不愉快事件相关的环境中的适应性行为。海马体形成了对预测不愉快事件的环境的神经表示。环境的表示包括环境的多感官特征,但必须以某种方式排除不愉快事件本身的感官特征。我们使用行为小鼠的海马体 CA1 中的细胞类型特异性成像和失活来研究这种选择性。通过胆碱能输入,不愉快的刺激激活 CA1 树突靶向中间神经元,导致来自内侧颞叶皮层的不愉快感觉传入抑制接收树突靶向中间神经元的锥体细胞远端树突。在不愉快的刺激期间失活树突靶向中间神经元会增加 CA1 锥体细胞群体的反应,并防止恐惧学习。我们提出,作为在恐惧学习期间将不愉快刺激从海马体情境表示中排除的机制,是下皮质对树突抑制的激活。
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