DELTA: a method for brain-wide measurement of synaptic protein turnover reveals localized plasticity during learning

IF 21.2 1区医学 Q1 NEUROSCIENCES

Nature neuroscience Pub Date : 2025-03-31 DOI:10.1038/s41593-025-01923-4

Boaz Mohar, Gabriela Michel, Yi-Zhi Wang, Veronica Hernandez, Jonathan B. Grimm, Jin-Yong Park, Ronak Patel, Morgan Clarke, Timothy A. Brown, Cornelius Bergmann, Kamil K. Gebis, Anika P. Wilen, Bian Liu, Richard Johnson, Austin Graves, Tatjana Tchumatchenko, Jeffrey N. Savas, Eugenio F. Fornasiero, Richard L. Huganir, Paul W. Tillberg, Luke D. Lavis, Karel Svoboda, Nelson Spruston

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Abstract

Synaptic plasticity alters neuronal connections in response to experience, which is thought to underlie learning and memory. However, the loci of learning-related synaptic plasticity, and the degree to which plasticity is localized or distributed, remain largely unknown. Here we describe a new method, DELTA, for mapping brain-wide changes in synaptic protein turnover with single-synapse resolution, based on Janelia Fluor dyes and HaloTag knock-in mice. During associative learning, the turnover of the ionotropic glutamate receptor subunit GluA2, an indicator of synaptic plasticity, was enhanced in several brain regions, most markedly hippocampal area CA1. More broadly distributed increases in the turnover of synaptic proteins were observed in response to environmental enrichment. In CA1, GluA2 stability was regulated in an input-specific manner, with more turnover in layers containing input from CA3 compared to entorhinal cortex. DELTA will facilitate exploration of the molecular and circuit basis of learning and memory and other forms of plasticity at scales ranging from single synapses to the entire brain.

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突触可塑性会改变神经元连接以应对经验，这被认为是学习和记忆的基础。然而，与学习相关的突触可塑性的位置，以及可塑性的定位或分布程度，在很大程度上仍然未知。在这里，我们描述了一种新方法--DELTA，它基于 Janelia Fluor 染料和 HaloTag 基因敲入小鼠，以单突触分辨率绘制全脑突触蛋白周转变化图。在联想学习过程中，作为突触可塑性指标的离子型谷氨酸受体亚基GluA2的周转率在多个脑区都有所提高，其中以海马CA1区最为明显。在环境富集作用下，还观察到分布更广的突触蛋白周转率增加。在CA1中，GluA2的稳定性受到输入特异性的调节，在含有来自CA3的输入的各层中，其周转率高于内侧皮层。DELTA 将有助于探索学习和记忆的分子和电路基础，以及从单个突触到整个大脑的其他形式的可塑性。

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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.