Orchestrated ensemble activities constitute a hippocampal memory engram

Khaled Ghandour; Noriaki Ohkawa; Chi Chung Alan Fung; Hirotaka Asai; Yoshito Saitoh; Takashi Takekawa; Reiko Okubo-Suzuki; Shingo Soya; Hirofumi Nishizono; Mina Matsuo; Makoto Osanai; Masaaki Sato; Masamichi Ohkura; Junichi Nakai; Yasunori Hayashi; Takeshi Sakurai; Takashi Kitamura; Tomoki Fukai; Kaoru Inokuchi

doi:10.1038/s41467-019-10683-2

Orchestrated ensemble activities constitute a hippocampal memory engram

Khaled Ghandour, Noriaki Ohkawa^*, Chi Chung Alan Fung, Hirotaka Asai, Yoshito Saitoh, Takashi Takekawa, Reiko Okubo-Suzuki, Shingo Soya, Hirofumi Nishizono, Mina Matsuo, Makoto Osanai, Masaaki Sato, Masamichi Ohkura, Junichi Nakai, Yasunori Hayashi, Takeshi Sakurai, Takashi Kitamura, Tomoki Fukai, Kaoru Inokuchi

^*この論文の責任著者

研究成果: ジャーナルへの寄稿 › 学術論文 › 査読

109 被引用数 (Scopus)

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The brain stores and recalls memories through a set of neurons, termed engram cells. However, it is unclear how these cells are organized to constitute a corresponding memory trace. We established a unique imaging system that combines Ca²⁺ imaging and engram identification to extract the characteristics of engram activity by visualizing and discriminating between engram and non-engram cells. Here, we show that engram cells detected in the hippocampus display higher repetitive activity than non-engram cells during novel context learning. The total activity pattern of the engram cells during learning is stable across post-learning memory processing. Within a single engram population, we detected several sub-ensembles composed of neurons collectively activated during learning. Some sub-ensembles preferentially reappear during post-learning sleep, and these replayed sub-ensembles are more likely to be reactivated during retrieval. These results indicate that sub-ensembles represent distinct pieces of information, which are then orchestrated to constitute an entire memory.

本文言語	英語
論文番号	2637
ジャーナル	Nature Communications
巻	10
号	1
DOI	https://doi.org/10.1038/s41467-019-10683-2
出版ステータス	出版済み - 2019/12/01

ASJC Scopus 主題領域

化学一般
生化学、遺伝学、分子生物学一般
物理学および天文学一般

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10.1038/s41467-019-10683-2

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Ghandour, K., Ohkawa, N., Fung, C. C. A., Asai, H., Saitoh, Y., Takekawa, T., Okubo-Suzuki, R., Soya, S., Nishizono, H., Matsuo, M., Osanai, M., Sato, M., Ohkura, M., Nakai, J., Hayashi, Y., Sakurai, T., Kitamura, T., Fukai, T., & Inokuchi, K. (2019). Orchestrated ensemble activities constitute a hippocampal memory engram. Nature Communications, 10(1), 記事 2637. https://doi.org/10.1038/s41467-019-10683-2

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title = "Orchestrated ensemble activities constitute a hippocampal memory engram",

abstract = "The brain stores and recalls memories through a set of neurons, termed engram cells. However, it is unclear how these cells are organized to constitute a corresponding memory trace. We established a unique imaging system that combines Ca2+ imaging and engram identification to extract the characteristics of engram activity by visualizing and discriminating between engram and non-engram cells. Here, we show that engram cells detected in the hippocampus display higher repetitive activity than non-engram cells during novel context learning. The total activity pattern of the engram cells during learning is stable across post-learning memory processing. Within a single engram population, we detected several sub-ensembles composed of neurons collectively activated during learning. Some sub-ensembles preferentially reappear during post-learning sleep, and these replayed sub-ensembles are more likely to be reactivated during retrieval. These results indicate that sub-ensembles represent distinct pieces of information, which are then orchestrated to constitute an entire memory.",

author = "Khaled Ghandour and Noriaki Ohkawa and Fung, {Chi Chung Alan} and Hirotaka Asai and Yoshito Saitoh and Takashi Takekawa and Reiko Okubo-Suzuki and Shingo Soya and Hirofumi Nishizono and Mina Matsuo and Makoto Osanai and Masaaki Sato and Masamichi Ohkura and Junichi Nakai and Yasunori Hayashi and Takeshi Sakurai and Takashi Kitamura and Tomoki Fukai and Kaoru Inokuchi",

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doi = "10.1038/s41467-019-10683-2",

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Ghandour, K, Ohkawa, N, Fung, CCA, Asai, H, Saitoh, Y, Takekawa, T, Okubo-Suzuki, R, Soya, S, Nishizono, H, Matsuo, M, Osanai, M, Sato, M, Ohkura, M, Nakai, J, Hayashi, Y, Sakurai, T, Kitamura, T, Fukai, T & Inokuchi, K 2019, 'Orchestrated ensemble activities constitute a hippocampal memory engram', Nature Communications, vol. 10, no. 1, 2637. https://doi.org/10.1038/s41467-019-10683-2

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AU - Ohkawa, Noriaki

AU - Fung, Chi Chung Alan

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AU - Takekawa, Takashi

AU - Okubo-Suzuki, Reiko

AU - Soya, Shingo

AU - Nishizono, Hirofumi

AU - Matsuo, Mina

AU - Osanai, Makoto

AU - Sato, Masaaki

AU - Ohkura, Masamichi

AU - Nakai, Junichi

AU - Hayashi, Yasunori

AU - Sakurai, Takeshi

AU - Kitamura, Takashi

AU - Fukai, Tomoki

AU - Inokuchi, Kaoru

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N2 - The brain stores and recalls memories through a set of neurons, termed engram cells. However, it is unclear how these cells are organized to constitute a corresponding memory trace. We established a unique imaging system that combines Ca2+ imaging and engram identification to extract the characteristics of engram activity by visualizing and discriminating between engram and non-engram cells. Here, we show that engram cells detected in the hippocampus display higher repetitive activity than non-engram cells during novel context learning. The total activity pattern of the engram cells during learning is stable across post-learning memory processing. Within a single engram population, we detected several sub-ensembles composed of neurons collectively activated during learning. Some sub-ensembles preferentially reappear during post-learning sleep, and these replayed sub-ensembles are more likely to be reactivated during retrieval. These results indicate that sub-ensembles represent distinct pieces of information, which are then orchestrated to constitute an entire memory.

AB - The brain stores and recalls memories through a set of neurons, termed engram cells. However, it is unclear how these cells are organized to constitute a corresponding memory trace. We established a unique imaging system that combines Ca2+ imaging and engram identification to extract the characteristics of engram activity by visualizing and discriminating between engram and non-engram cells. Here, we show that engram cells detected in the hippocampus display higher repetitive activity than non-engram cells during novel context learning. The total activity pattern of the engram cells during learning is stable across post-learning memory processing. Within a single engram population, we detected several sub-ensembles composed of neurons collectively activated during learning. Some sub-ensembles preferentially reappear during post-learning sleep, and these replayed sub-ensembles are more likely to be reactivated during retrieval. These results indicate that sub-ensembles represent distinct pieces of information, which are then orchestrated to constitute an entire memory.

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Orchestrated ensemble activities constitute a hippocampal memory engram

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