Abstract
The ability to update actions depends on the thalamus's parafascicular nucleus (PF); however, which PF's inputs control this function is unknown. Here, using fiber photometry, retrograde labeling, ex vivo electrophysiology, and optogenetic manipulations, we identify the contribution of the PF and its glutamatergic inputs to the update from a spatial to a visually guided strategy in a set-shifting task conducted in mice (of either sex). Our results show the following: (1) GCaMP signals from the PF recorded along the update from a spatial to a visual strategy correlate with the probability of selecting the correct action based on a light stimulus. (2) Optogenetic inhibition of the PF during this update decreases the probability of selecting the correct action. (3) The mesencephalic locomotor region (MLR) was found to have the highest probability of synaptic connections with the PF. (4) GCaMP recordings from the MLR→PF input support it as a main driver in allowing the PF update function. (5) Inhibition of the MLR→PF connection decreases the probability of updating the contingency. These findings identify the inputs from the MLR as a crucial driver of the PF's role in controlling the update of actions.