Role of Cortical Dopamine circuits in regulating Striatal Dopamine dynamics during Reversal Learning

Abstract

Dopamine is a catecholamine neuromodulator implicated in locomotion, motivation, learning and cognitive behaviors. Although striatal dopamine signaling and circuitry are well established, the role of cortical dopamine projection circuitry in regulating striatal dopamine dynamics and behavior is not clear. Glutamatergic pyramidal neurons in the prefrontal cortex (PFC) are topographically organized and dopamine D1 and D2 receptors are expressed on glutamatergic pyramidal neurons in the PFC. Using a retrograde adeno‐associated virus (AAVRG)‐based approach we show that D1R+ subpopulations in medial orbitofrontal or prelimbic regions project to nucleus accumbens core (NAcc) or dorsal striatum (dSTR), respectively. However, D2R+ subpopulations in medial orbitofrontal, or medial prelimbic PFC, project to NAcc or the midbrain (SNpc/VTA) but not dSTR, respectively. Additionally, D1R+ and D2R+ medial orbitofrontal subpopulations have indirect connections to the medial SNpc through the NAcc core. We next wanted to test which of these topographically organized circuits regulate striatal dopamine dynamics during reversal learning. We used fiber photometry to measure striatal dopamine dynamics in the dorsomedial striatum (DMS) during reversal learning. We were able to measure reward prediction error (RPE) like responses in the DMS during reversal learning. We will next use an intersectional genetic approach to specifically activate or inhibit dopamine receptor cortical projection circuits and test their effect on striatal dopamine dynamics and reversal learning. Our studies will identify previously unappreciated roles for cortical dopamine projection circuits and their regulation of striatal dopamine dynamics.