ABSTRACTBACKGROUNDCues predicting heroin delivery induce heroin seeking by initiating synaptic glutamate release in the nucleus accumbens core. The intensity of heroin seeking is negatively modulated by cue-induced increases in synaptic proximity of astrocytes. Glutamate-driven heroin seeking is also negatively regulated by compounds that promote glutamate uptake through the astrocytic transporter GLT-1. We hypothesized that the cue-induced increase in astrocyte synaptic proximity reduces heroin seeking by increasing GLT-1 synaptic proximity.METHODSRats were trained to self-administer heroin or sucrose before undergoing extinction and cued reinstatement of heroin or sucrose seeking. We used confocal microscopy to assess expression and co-registration of GLT-1 with the synaptic marker Synapsin I in the nucleus accumbens core.RESULTSExtinction from heroin, but not sucrose self-administration, downregulated GLT-1. Heroin cues increased surface expression of GLT-1 in parallel with heroin seeking, but counter to expectations, the increase was not proximal to synapses identified by Synapsin I. In fact, astroglia showing cue-induced increased surface expression of GLT-1 constituted a distinct subpopulation of astroglia from those showing increased synaptic proximity. Supporting discrete mechanisms, preventing cue-evoked increases in astrocyte synaptic proximity by knocking down the astroglial-selective actin binding protein ezrin did not impact cue-induced increases in GLT-1 surface expression.CONCLUSIONSOur data demonstrate that heroin-paired cues elicit two transient adaptations in astrocytes in the nucleus accumbens core, restoration of synaptic proximity and increased surface expression of GLT-1. Each adaptation occurs in largely non-overlapping subpopulations of astrocytes, but both adaptations appear to dampen reinstated heroin seeking.
Long‐access to cocaine self‐administration dysregulates the glutamate synapse in the nucleus accumbens core of serotonin transporter knockout rats
