模型杏仁核神经元被分配到恐惧记忆痕迹取决于竞争的突触相互作用。
Assignment of model amygdala neurons to the fear memory trace depends on competitive synaptic interactions.
机构信息
Department of Electrical and Computer Engineering, University of Missouri, Columbia, Missouri 65211, USA.
出版信息
J Neurosci. 2013 Sep 4;33(36):14354-8. doi: 10.1523/JNEUROSCI.2430-13.2013.
Abstract
We used biophysical modeling to examine a fundamental, yet unresolved, question regarding how particular lateral amygdala (LA) neurons are assigned to fear memory traces. This revealed that neurons with high intrinsic excitability are more likely to be integrated into the memory trace, but that competitive synaptic interactions also play a critical role. Indeed, when the ratio of intrinsically excitable cells was increased or decreased, the number of plastic cells remained relatively constant. Analysis of the connectivity of plastic and nonplastic cells revealed that subsets of principal LA neurons effectively band together by virtue of their excitatory interconnections to suppress plasticity in other principal cells via the recruitment of inhibitory interneurons.
摘要
我们使用生物物理建模来研究一个基本但尚未解决的问题,即特定的外侧杏仁核 (LA) 神经元如何被分配到恐惧记忆痕迹中。这表明兴奋性较高的神经元更有可能被整合到记忆痕迹中,但竞争的突触相互作用也起着关键作用。事实上,当内在兴奋性细胞的比例增加或减少时,可塑细胞的数量仍然相对恒定。对可塑细胞和非可塑细胞的连接性分析表明,主要 LA 神经元的亚群通过其兴奋性连接有效地聚集在一起,通过招募抑制性中间神经元来抑制其他主要细胞的可塑性。
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