扣带回旁皮质输入控制新皮质 1 层的学习。
Perirhinal input to neocortical layer 1 controls learning.
机构信息
Institute for Biology, Humboldt-Universität zu Berlin, D-10117 Berlin, Germany.
Bernstein Center for Computational Neuroscience, Humboldt-Universität zu Berlin, D-10115 Berlin, Germany.
出版信息
Science. 2020 Dec 18;370(6523). doi: 10.1126/science.aaz3136.
Abstract
Hippocampal output influences memory formation in the neocortex, but this process is poorly understood because the precise anatomical location and the underlying cellular mechanisms remain elusive. Here, we show that perirhinal input, predominantly to sensory cortical layer 1 (L1), controls hippocampal-dependent associative learning in rodents. This process was marked by the emergence of distinct firing responses in defined subpopulations of layer 5 (L5) pyramidal neurons whose tuft dendrites receive perirhinal inputs in L1. Learning correlated with burst firing and the enhancement of dendritic excitability, and it was suppressed by disruption of dendritic activity. Furthermore, bursts, but not regular spike trains, were sufficient to retrieve learned behavior. We conclude that hippocampal information arriving at L5 tuft dendrites in neocortical L1 mediates memory formation in the neocortex.
摘要
海马体的输出会影响新皮层中的记忆形成,但这一过程的理解还很不深入,因为确切的解剖位置和潜在的细胞机制仍难以捉摸。在这里,我们表明,边缘下区的输入,主要是到感觉皮层的第 1 层(L1),控制着啮齿动物的海马体依赖性联想学习。这个过程的标志是,在 L5 锥体神经元的特定亚群中出现了不同的放电反应,其树突棘接收来自 L1 的边缘下区输入。学习与爆发式放电和树突兴奋性增强相关,而其被树突活动的破坏所抑制。此外,爆发式放电,而不是常规的尖峰序列,足以检索到学习到的行为。我们的结论是,到达新皮层 L1 中 L5 树突棘的海马体信息介导了新皮层中的记忆形成。
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