Accumbens Nitrergic Interneurons Drive the Cell Type-Specific Synaptic Plasticity Required for Cue-Induced Cocaine Seeking

Abstract

AbstractCocaine use disorder (CUD) remains a serious public health crisis, with relapse vulnerability continuing to pose the largest impediment to effective clinical treatment. Relapse to cocaine seeking is often triggered by drug craving evoked by exposure to drug-associated environmental cues. Data from preclinical models of rodent self-administration (SA) and cue-induced reinstatement demonstrate that exposure to drug predictive cues following a period of withdrawal engages a large induction of glutamate release in the nucleus accumbens core (NAc), not observed during cued sucrose seeking. This profound glutamate release engages neuronal nitric oxide synthase (nNOS) expressing interneurons likely through activation of metabotropic glutamate receptor 5 (mGluR5), leading to increased production of nitric oxide (NO). Importantly, cue-induced glutamate and NO production have been linked to activation of matrix metalloproteinases (MMPs) and induction of the transient synaptic plasticity in medium spiny neurons (MSNs) required for cued cocaine seeking. Recent evidence suggests that cue-induced structural and synaptic plasticity occurs predominantly in D1 Dopamine receptor expressing MSNs, yet despite these findings, how cue-induced glutamate release is translated into D1 MSN plasticity has yet to be elucidated. We show here that knockdown of nNOS is sufficient to block cue-induced reinstatement to cocaine and prevents cue-induced functional and structural synaptic adaptions specifically in D1 receptor containing MSNs. Next, we demonstrate that knockdown of mGluR5, selectively on nitrergic interneurons in the NAc, is sufficient to block both conditioned place preference (CPP) and cue-induced reinstatement to cocaine, mechanistically linking cue-associated glutamate release to NO signaling. Finally, we demonstrate that downstream of glutamate-mediated activation of mGluR5 on nitrergic interneurons and MMP activation, expression of β3 integrin receptors on D1 MSNs is required for cued cocaine seeking. Taken together, our data provide a mechanistic link between cocaine cue-induced glutamate release, activation of nitrergic interneurons and the D1 MSN plasticity required for cued cocaine seeking,Significance StatementRelapse vulnerability to cocaine is a persistent challenge to successful treatment of CUD. Relapse precipitated by drug-associated environment cues requires synaptic plasticity in MSNs. Here, we show that knockdown of nNOS, or mGluR5 on nitrergic interneurons, or β3 integrin receptors on D1 MSNs is sufficient to block cue-induced cocaine seeking. Taken together our data support the following cocaine seeking signaling cascade.□Cocaine cues → PrL driven NAc glutamate release → mGluR5-mediated Activation of NAc nitrergic neurons → Activation of B3 integrins → D1 MSN plasticity → Reinstated Cocaine seeking.