Abstract
The claustrum is recognized for its significant impact on various cognitive functions and its extensive connections with other brain regions, yet its functional role remains to be fully understood. Here, we utilized an optogenetic approach to investigate the claustrum’s influence on neuronal activity within the dorsal prefrontal cortex (dPFC) of mice. We conducted two-photon calcium imaging to assess dPFC cell responses during exposure to visual stimuli and widefield photostimulation of claustrum axons embedded in the dPFC. We identified three distinct subpopulations of neurons — sensory responsive, opto responsive, and opto-boosted cells — each exhibiting unique response dynamics to combined visual and optogenetic stimuli. Our findings reveal that stimulation of claustrum axons can normalize neuronal responsiveness, while enhancing neural variability, and significantly increasing network homogeneity. Training in a Pavlovian task showed that while enhanced variability with claustrum axon stimulation in neural responses persists, training does not further increase this variability but instead leads to greater network homogeneity. Additionally, we also performed claustrum axon silencing experiments that revealed that the claustrum may operate bidirectionally to maintain enhanced variability and homogeneity in the prefrontal cortex. These results highlight the crucial role of the claustrum in dynamically modulating dPFC activity, impacting both neuronal variability and network synchronization.
Huriye Atilgan, Ivan P. Lazarte, Adam M. Packer. The claustrum enhances neural variability by modulating the responsiveness of the prefrontal cortex. bioRxiv, 2024-9. [LINK]
Speaker: Qiyue Zhang
Time: 9:00 am, 2024/10/21
Location: CIBR A622
