Prefrontal feature representations drive memory recall

Yadav, Nakul; Noble, Chelsea; Niemeyer, James E.; Terceros, Andrea; Victor, Jonathan; Liston, Conor; Rajasethupathy, Priyamvada

Prefrontal feature representations drive memory recall

Nakul Yadav, Chelsea Noble, James E. Niemeyer, Andrea Terceros, Jonathan Victor, Conor Liston and Priyamvada Rajasethupathy ()
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Nakul Yadav: The Rockefeller University
Chelsea Noble: The Rockefeller University
James E. Niemeyer: The Rockefeller University
Andrea Terceros: The Rockefeller University
Jonathan Victor: Weill Cornell Medicine
Conor Liston: Weill Cornell Medicine
Priyamvada Rajasethupathy: The Rockefeller University

Nature, 2022, vol. 608, issue 7921, 153-160

Abstract: Abstract Memory formation involves binding of contextual features into a unitary representation1–4, whereas memory recall can occur using partial combinations of these contextual features. The neural basis underlying the relationship between a contextual memory and its constituent features is not well understood; in particular, where features are represented in the brain and how they drive recall. Here, to gain insight into this question, we developed a behavioural task in which mice use features to recall an associated contextual memory. We performed longitudinal imaging in hippocampus as mice performed this task and identified robust representations of global context but not of individual features. To identify putative brain regions that provide feature inputs to hippocampus, we inhibited cortical afferents while imaging hippocampus during behaviour. We found that whereas inhibition of entorhinal cortex led to broad silencing of hippocampus, inhibition of prefrontal anterior cingulate led to a highly specific silencing of context neurons and deficits in feature-based recall. We next developed a preparation for simultaneous imaging of anterior cingulate and hippocampus during behaviour, which revealed robust population-level representation of features in anterior cingulate, that lag hippocampus context representations during training but dynamically reorganize to lead and target recruitment of context ensembles in hippocampus during recall. Together, we provide the first mechanistic insights into where contextual features are represented in the brain, how they emerge, and how they access long-range episodic representations to drive memory recall.

Date: 2022
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DOI: 10.1038/s41586-022-04936-2

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