Claustral Projections to Anterior Cingulate Cortex Modulate Engagement with the External World

Engagement is a major determinant of performance. Hyper-engagement risks impulsivity and is fatiguing over time, while hypo-engagement could lead to missed opportunities. Even in sleep, when engagement levels are minimal, sensory responsiveness varies. Thus, maintaining an optimal engagement level w...

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Bibliographic Details
Published inbioRxiv
Main Authors Atlan, Gal, Matosevich, Noa, Peretz-Rivlin, Noa, Yvgi, Idit, Chen, Eden, Kleinman, Timna, Bleistein, Noa, Sheinbach, Efrat, Groysman, Maya, Nir, Yuval, Citri, Ami
Format Paper
LanguageEnglish
Published Cold Spring Harbor Cold Spring Harbor Laboratory Press 19.06.2021
Subjects
Acuity
Basal ganglia
Calcium
Cognitive ability
Cortex (cingulate)
Cortex (frontal)
Cortex (somatosensory)
EEG
Impulsive behavior
Neural networks
Photometry
Sensory stimuli
Sleep
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Summary:Engagement is a major determinant of performance. Hyper-engagement risks impulsivity and is fatiguing over time, while hypo-engagement could lead to missed opportunities. Even in sleep, when engagement levels are minimal, sensory responsiveness varies. Thus, maintaining an optimal engagement level with the environment is a fundamental cognitive ability. The claustrum, and in particular its reciprocal connectivity with executive regions in the frontal cortex, has been associated with salience, attention and sleep. These apparently disparate roles can be consolidated within the context of engagement. Here we describe the activity of claustro-frontal circuits in a task imposing a tradeoff between response inhibition and sensory acuity (ENGAGE). Recording calcium fiber photometry during >80,000 trials, we characterize claustrum recruitment during salient behavioral events, and find that a moderate level of activity in claustro-cingulate projections defines optimal engagement. Low activity of this pathway is associated with impulsive actions, while high activity is associated with behavioral lapses. Chemogenetic activation of cingulate-projecting claustrum neurons suppressed impulsive behavior and reduced the engagement of mice in the task. This relationship became even clearer upon addressing individual variability in the strategy mice employed during the ENGAGE task. Furthermore, this association of claustrum activity and engagement extends into sleep. Using simultaneous EEG and photometry recordings in the claustrum, we find that cingulate projecting claustrum neurons are most active during deep unresponsive slow-wave sleep, when mice are less prone to awakening by sensory stimuli. Competing Interest Statement The authors have declared no competing interest.
DOI:10.1101/2021.06.17.448649