Abstract
Presentation of drug-associated cues provokes craving and drug seeking, and elimination of these associative memories would facilitate recovery from addiction. Emotionally salient memories are maintained during retrieval, as particular pharmacologic or optogenetic perturbations of memory circuits during retrieval, but not after, can induce long-lasting memory impairments. For example, in rats, inhibition of noradrenergic beta-receptors, which control intrinsic neuronal excitability, in the prelimbic medial prefrontal cortex (PL-mPFC) can cause long-term memory impairments that prevent subsequent cocaine-induced reinstatement. The physiologic mechanisms that allow noradrenergic signaling to maintain drug-associated memories during retrieval, however, are unclear. Here we combine patch-clamp electrophysiology ex vivo and behavioral neuropharmacology in vivo to evaluate the mechanisms that maintain drug-associated memory during retrieval in rats. Consistent with previous studies, we find that cocaine experience increases the intrinsic excitability of pyramidal neurons in PL-mPFC. In addition, we now find that this intrinsic plasticity positively predicts the retrieval of a cocaine-induced conditioned place preference (CPP) memory, suggesting that such plasticity may contribute to drug-associated memory retrieval. In further support of this, we find that pharmacological blockade of a cAMP-dependent signaling cascade, which allows noradrenergic signaling to elevate neuronal excitability, is required for memory maintenance during retrieval. Thus, inhibition of PL-mPFC neuronal excitability during memory retrieval not only leads to long-term deficits in the memory, but this memory deficit provides protection against subsequent cocaine-induced reinstatement. These data reveal that PL-mPFC intrinsic neuronal excitability maintains a cocaine-associated memory during retrieval and suggest a unique mechanism whereby drug-associated memories could be targeted for elimination.
Highlights
Presentation of environmental stimuli that predict drug availability can drive compulsive drug seeking and taking (Childress et al, 1986; Heather et al, 1991), making recovery from addiction difficult
We categorized rats as having high retrieval (HR) scores or low retrieval (LR) scores
We evaluate how long-term and short-term intrinsic plasticity in prelimbic medial prefrontal cortex (PFC) (PL-mPFC) pyramidal neurons may contribute to drug-associated memory retrieval
Summary
Presentation of environmental stimuli that predict drug availability can drive compulsive drug seeking and taking (Childress et al, 1986; Heather et al, 1991), making recovery from addiction difficult. PL-mPFC cells that project to NAc are cue-responsive layer V pyramidal neurons (Otis et al, 2017), and these neurons undergo synaptic potentiation following drug experience (Robinson and Kolb, 1999, 2004; Robinson et al, 2001). This plasticity correlates with the acquisition of cocaine-associated memories in vivo (Muñoz-Cuevas et al, 2013). These data reveal that synaptic plasticity in layer V pyramidal neurons in PL-mPFC underlies drug-associated memories; how intrinsic plasticity might contribute to drug-associated memories remains unclear
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