失忆症小鼠海马 CA1 神经元之间的高阶交互作用受到破坏

IF 21.2 1区医学 Q1 NEUROSCIENCES

Nature neuroscience Pub Date : 2024-07-19 DOI:10.1038/s41593-024-01713-4

Chen Yan, Valentina Mercaldo, Alexander D. Jacob, Emily Kramer, Andrew Mocle, Adam I. Ramsaran, Lina Tran, Asim J. Rashid, Sungmo Park, Nathan Insel, A. David Redish, Paul W. Frankland, Sheena A. Josselyn

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引用次数: 0

摘要

在整个系统中，各组成部分之间的高阶交互作用支配着突发动态。在这里，我们测试了小鼠的情境威胁记忆检索是否依赖于需要学习诱导的树突棘可塑性的背侧 CA1 海马神经元之间的高阶相互作用。我们比较了野生型小鼠（具有完整的学习诱导脊柱可塑性和记忆力）和失忆小鼠（TgCRND8 小鼠，具有高水平的淀粉样蛋白-β和学习诱导脊柱可塑性和记忆力缺陷）进行记忆测试时的群体水平 Ca2+ 瞬态。我们的研究结果表明，野生型小鼠的记忆表征中存在复杂的神经元相互作用，而失忆型小鼠则没有。此外，一种能部分恢复学习诱导的脊柱可塑性的多肽也能恢复 Tg 小鼠记忆表征和记忆行为的统计复杂性。这些发现为记忆研究提供了一个以前缺失的桥梁，将受体、脊柱、高阶神经元动力学和行为联系起来。

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Higher-order interactions between hippocampal CA1 neurons are disrupted in amnestic mice

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Higher-order interactions between hippocampal CA1 neurons are disrupted in amnestic mice

Across systems, higher-order interactions between components govern emergent dynamics. Here we tested whether contextual threat memory retrieval in mice relies on higher-order interactions between dorsal CA1 hippocampal neurons requiring learning-induced dendritic spine plasticity. We compared population-level Ca2+ transients as wild-type mice (with intact learning-induced spine plasticity and memory) and amnestic mice (TgCRND8 mice with high levels of amyloid-β and deficits in learning-induced spine plasticity and memory) were tested for memory. Using machine-learning classifiers with different capacities to use input data with complex interactions, our findings indicate complex neuronal interactions in the memory representation of wild-type, but not amnestic, mice. Moreover, a peptide that partially restored learning-induced spine plasticity also restored the statistical complexity of the memory representation and memory behavior in Tg mice. These findings provide a previously missing bridge between levels of analysis in memory research, linking receptors, spines, higher-order neuronal dynamics and behavior. Coordinated neuronal activity may mediate memory in hippocampal CA1. Here, the authors use an array of machine-learning classifiers to reveal how higher-order population dynamics and learning-induced spine plasticity are disrupted in amnestic mice.

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来源期刊

Nature neuroscience 医学-神经科学

CiteScore

38.60

自引率

1.20%

发文量

212

审稿时长

1 months

期刊介绍： Nature Neuroscience, a multidisciplinary journal, publishes papers of the utmost quality and significance across all realms of neuroscience. The editors welcome contributions spanning molecular, cellular, systems, and cognitive neuroscience, along with psychophysics, computational modeling, and nervous system disorders. While no area is off-limits, studies offering fundamental insights into nervous system function receive priority. The journal offers high visibility to both readers and authors, fostering interdisciplinary communication and accessibility to a broad audience. It maintains high standards of copy editing and production, rigorous peer review, rapid publication, and operates independently from academic societies and other vested interests. In addition to primary research, Nature Neuroscience features news and views, reviews, editorials, commentaries, perspectives, book reviews, and correspondence, aiming to serve as the voice of the global neuroscience community.