The Bilateral Prefronto-striatal Pathway Is Necessary for Learning New Goal-Directed Actions

© 2018 Elsevier Ltd The acquisition of new goal-directed actions requires the encoding of action-outcome associations. At a neural level, this encoding has been hypothesized to involve a prefronto-striatal circuit extending between the prelimbic cortex (PL) and the posterior dorsomedial striatum (pDMS); however, no research identifying this pathway with any precision has been reported. We started by mapping the prelimbic input to the dorsal and ventral striatum using a combination of retrograde and anterograde tracing with CLARITY and established that PL-pDMS projections share some overlap with projections to the nucleus accumbens core (NAc) in rats. We then tested whether each of these pathways were functionally required for goal-directed learning; we used a pathway-specific dual-virus chemogenetic approach to selectively silence pDMS-projecting or NAc-projecting PL neurons during instrumental training and tested rats for goal-directed action. We found that silencing PL-pDMS projections abolished goal-directed learning, whereas silencing PL-NAc projections left goal-directed learning intact. Finally, we used a three-virus approach to silence bilateral and contralateral pDMS-projecting PL neurons and again blocked goal-directed learning. These results establish that the acquisition of new goal-directed actions depends on the bilateral PL-pDMS pathway driven by intratelencephalic cortical neurons. The acquisition of goal-directed actions is hypothesized to be mediated by a prefronto-striatal circuit. Here, Hart et al. establish that the acquisition of such actions requires a monosynaptic, bilateral circuit involving the bilaterally projecting intratelencephalic neurons in the prelimbic cortex that target the posterior dorsomedial striatum

Medial Orbitofrontal Cortex Mediates Outcome Retrieval in Partially Observable Task Situations.

Choice between actions often requires the ability to retrieve action consequences in circumstances where they are only partially observable. This capacity has recently been argued to depend on orbitofrontal cortex; however, no direct evidence for this hypothesis has been reported. Here, we examined whether activity in the medial orbitofrontal cortex (mOFC) underlies this critical determinant of decision-making in rats. First, we simulated predictions from this hypothesis for various tests of goal-directed action by removing the assumption that rats could retrieve partially observable outcomes and then tested those predictions experimentally using manipulations of the mOFC. The results closely followed predictions; consistent deficits only emerged when action consequences had to be retrieved. Finally, we put action selection based on observable and unobservable outcomes into conflict and found that whereas intact rats selected actions based on the value of retrieved outcomes, mOFC rats relied solely on the value of observable outcomes