Juvenile-to-adult refinement of thalamic reticular circuits via LRRTM3 enables high-resolution sensory encoding

Abstract

Sensory processing enables adaptive behavior by accurately encoding dynamic environmental stimuli. Within thalamocortical (TC) circuits, the thalamic reticular nucleus (TRN) functions as a key inhibitory gate that regulates cortical access to sensory input. While classical models posit that sensory circuits stabilize after early critical periods, we uncover a previously unrecognized phase of synaptic refinement in TRN circuitry extending from the juvenile period into adulthood. This late-stage remodeling is driven by a progressive reduction in corticothalamic (CT) excitatory input and is essential for enhancing sensory gain, response linearity, and stimulus discriminability. We identify LRRTM3, a TRN-enriched synaptic adhesion molecule, as a molecular gatekeeper of this process. TRN-specific deletion of LRRTM3 disrupts CT–TRN refinement, elevates TRN-mediated inhibition, and impairs fine tactile discrimination. These findings revise canonical views of sensory circuit maturation, revealing that LRRTM3-mediated juvenile-to-adult TRN plasticity is essential for the emergence of high-resolution sensory encoding in the adult brain.