Parietal top-down projections balance flexibility and stability in adaptive learning

The ability to flexibly modify behavior in response to changing environmental contingencies is fundamental to adaptive decision-making, yet how distributed brain circuits coordinate such rapid adaptation remains unclear. Here, we show that the posterior parietal cortex (PPC) facilitates adaptive learning via parallel projections to the auditory cortex (AC) and inferior colliculus (IC). In a within-session auditory reversal task, AC neurons supported flexible stimulus updating following rule reversal, whereas IC neurons preserved stable auditory discrimination across rules. Dual retrograde tracing revealed anatomically segregated PPC neurons projecting to AC (PPCAC) and IC (PPCIC). PPCAC neurons flexibly encoded stimulus-outcome contingencies, while PPCIC neurons stably represented response outcomes. Circuit-specific optogenetic inactivation confirmed their distinct contributions to behavioral adaptation. This double dissociation reveals a circuit mechanism by which parallel PPC projections coordinate flexible rule updating and stable motor execution, enabling rapid behavioral adaptation and providing a mechanistic framework for cognitive flexibility.