Hippocampal engram networks for fear memory recruit new synapses and modify pre-existing synapses in vivo

Chaery Lee; Byung Hun Lee; Hyunsu Jung; Chiwoo Lee; Yongmin Sung; Hyopil Kim; Jooyoung Kim; Jae Youn Shim; Ji il Kim; Dong Il Choi; Hye Yoon Park; Bong Kiun Kaang

doi:10.1016/j.cub.2022.12.038

Hippocampal engram networks for fear memory recruit new synapses and modify pre-existing synapses in vivo

Chaery Lee, Byung Hun Lee, Hyunsu Jung, Chiwoo Lee, Yongmin Sung, Hyopil Kim, Jooyoung Kim, Jae Youn Shim, Ji il Kim, Dong Il Choi, Hye Yoon Park, Bong Kiun Kaang

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

As basic units of neural networks, ensembles of synapses underlie cognitive functions such as learning and memory. These synaptic engrams show elevated synaptic density among engram cells following contextual fear memory formation. Subsequent analysis of the CA3-CA1 engram synapse revealed larger spine sizes, as the synaptic connectivity correlated with the memory strength. Here, we elucidate the synapse dynamics between CA3 and CA1 by tracking identical synapses at multiple time points by adapting two-photon microscopy and dual-eGRASP technique in vivo. After memory formation, synaptic connections between engram populations are enhanced in conjunction with synaptogenesis within the hippocampal network. However, extinction learning specifically correlated with the disappearance of CA3 engram to CA1 engram (E-E) synapses. We observed “newly formed” synapses near pre-existing synapses, which clustered CA3-CA1 engram synapses after fear memory formation. Overall, we conclude that dynamics at CA3 to CA1 E-E synapses are key sites for modification during fear memory states.

Original language	English (US)
Pages (from-to)	507-516.e3
Journal	Current Biology
Volume	33
Issue number	3
DOIs	https://doi.org/10.1016/j.cub.2022.12.038
State	Published - Feb 6 2023
Externally published	Yes

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Publisher Copyright:
© 2022 The Author(s)

Keywords

CA1
CA3
engram
extinction
fear memory
hippocampus
synapse
synaptic density
two-photon imaging

PubMed: MeSH publication types

Journal Article
Research Support, Non-U.S. Gov't

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title = "Hippocampal engram networks for fear memory recruit new synapses and modify pre-existing synapses in vivo",

abstract = "As basic units of neural networks, ensembles of synapses underlie cognitive functions such as learning and memory. These synaptic engrams show elevated synaptic density among engram cells following contextual fear memory formation. Subsequent analysis of the CA3-CA1 engram synapse revealed larger spine sizes, as the synaptic connectivity correlated with the memory strength. Here, we elucidate the synapse dynamics between CA3 and CA1 by tracking identical synapses at multiple time points by adapting two-photon microscopy and dual-eGRASP technique in vivo. After memory formation, synaptic connections between engram populations are enhanced in conjunction with synaptogenesis within the hippocampal network. However, extinction learning specifically correlated with the disappearance of CA3 engram to CA1 engram (E-E) synapses. We observed “newly formed” synapses near pre-existing synapses, which clustered CA3-CA1 engram synapses after fear memory formation. Overall, we conclude that dynamics at CA3 to CA1 E-E synapses are key sites for modification during fear memory states.",

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AU - Sung, Yongmin

AU - Kim, Hyopil

AU - Kim, Jooyoung

AU - Shim, Jae Youn

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AU - Choi, Dong Il

AU - Park, Hye Yoon

AU - Kaang, Bong Kiun

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Hippocampal engram networks for fear memory recruit new synapses and modify pre-existing synapses in vivo

Abstract

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