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Orchestrated ensemble activities constitute a hippocampal memory engram.

Khaled GhandourNoriaki OhkawaChi Chung Alan FungHirotaka AsaiYoshito SaitohTakashi TakekawaReiko Okubo-SuzukiShingo SoyaHirofumi NishizonoMina MatsuoMakoto OsanaiMasaaki SatoMasamichi OhkuraJunichi NakaiYasunori HayashiTakeshi SakuraiTakashi KitamuraTomoki FukaiKaoru Inokuchi
Published in: Nature communications (2019)
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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