The role of the dentate gyrus in mnemonic functions

Q3 Medicine

Neuroforum Pub Date : 2020-10-05 DOI:10.1515/nf-2020-0021

Jonas-Frederic Sauer, M. Bartos

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引用次数: 0

Abstract

Abstract The hippocampus is decisive for the storage of conscious memories. Current theories suggest that experience-dependent modifications in excitation–inhibition balance enable a select group of neurons to form a new cell association during learning which represents the new memory trace. It was further proposed that particularly GABAergic-inhibitory interneurons have a large impact on population activity in neuronal networks by means of their inhibitory output synapses. They synchronize active principal cells at high frequencies, thereby supporting their binding to cell assemblies to jointly encode information. However, how cell associations emerge in space and time and how interneurons may contribute to this process is still largely unknown. We started to address this fundamental question in the dentate gyrus (DG) as the input gate of the hippocampus, which has an indispensable role in conscious memory formation. We used a combination of in vivo chronic two-photon imaging of population activity in the DG and the hippocampal areas CA1–3 of mice exposed to a virtual reality, in which they perform a goal-oriented spatial memory tasks, with high-density in vivo recordings and multiple whole-cell recordings in acute slice preparations, to determine how memory engrams emerge during learning. We further examine how GABAergic interneurons may contribute to this process. We believe that these lines of research will add to a better understanding on the mechanisms of memory formation in cortical networks.

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齿状回在记忆功能中的作用

摘要海马体对有意识记忆的储存起决定性作用。目前的理论表明，兴奋-抑制平衡的经验依赖性改变使一组选定的神经元能够在学习过程中形成新的细胞联想，代表新的记忆轨迹。进一步提出，特别是GABA能抑制性中间神经元通过其抑制性输出突触对神经元网络中的群体活动有很大影响。它们以高频同步活跃的主细胞，从而支持它们与细胞组装体的结合，共同编码信息。然而，细胞关联是如何在空间和时间中出现的，中间神经元是如何参与这一过程的，在很大程度上仍然未知。我们开始在作为海马体输入门的齿状回（DG）中解决这个基本问题，齿状回在意识记忆形成中起着不可或缺的作用。我们使用了暴露于虚拟现实的小鼠DG和海马CA1-3区群体活动的体内慢性双光子成像的组合，在该成像中，它们执行以目标为导向的空间记忆任务，在急性切片制备中进行高密度体内记录和多个全细胞记录，以确定记忆印迹在学习过程中是如何出现的。我们进一步研究了GABA能中间神经元如何参与这一过程。我们相信，这些研究将有助于更好地理解皮层网络中记忆形成的机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neuroforum NEUROSCIENCES-

CiteScore

1.70

自引率

0.00%

发文量

期刊介绍： Neuroforum publishes invited review articles from all areas in neuroscience. Readership includes besides basic and medical neuroscientists also journalists, practicing physicians, school teachers and students. Neuroforum reports on all topics in neuroscience – from molecules to the neuronal networks, from synapses to bioethics.