The infralimbic and prelimbic cortices contribute to the inhibitory control of cocaine‐seeking behavior during a discriminative stimulus task in rats

Drug addiction is a chronic relapsing disorder of compulsive drug use. Studies of the neurobehavioral factors that promote drug relapse have yet to produce an effective treatment. Here we take a different approach and examine the factors that suppress—rather than promote—relapse. Adapting Pavlovian procedures to suppress operant drug response, we determined the anti-relapse action of environmental cues that signal drug omission (unavailability) in rats. Under laboratory conditions linked to compulsive drug use and heightened relapse risk, drug omission cues suppressed three major modes of relapse-promotion (drug-predictive cues, stress, and drug exposure) for cocaine and alcohol. This relapse-suppression is, in part, driven by omission cue-reactive neurons, which constitute small subsets of glutamatergic and GABAergic cells, in the infralimbic cortex. Future studies of such neural activity-based cellular units (neuronal ensembles/memory engram cells) for relapse-suppression can be used to identify alternate targets for addiction medicine through functional characterization of anti-relapse mechanisms.

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“…These results extend previous reports 10,11,13,14,43 and establish the anti-relapse action of cocaine omission cues.…”

Section: Resultssupporting

confidence: 92%

“…Disrupting neural activity in IL, using inhibitory GABA agonists, interferes not only with extinction (suppression) 12,35,36 (also see ref. 14 ), but also with reinstatement (promotion) 37,38 of drug seeking. Yet other reports indicate that GABA agonists in IL do not produce a significant effect on drug seeking 11,39 (also see ref.…”

Section: Introductionmentioning

confidence: 99%

Anti-relapse neurons in the infralimbic cortex of rats drive relapse-suppression by drug omission cues

et al. 2019

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“…However, our studies using Daun02 inactivation do not agree with this anatomical framework and demonstrate that neuronal ensembles in vmPFC and NAc shell promote rather than inhibit heroin or cocaine seeking, respectively (Bossert et al, 2011;Cruz et al, 2014). Other studies suggest that the mPFC subregions play more complex roles in drug seeking, via the efferent projections of individual neurons (Marchant et al, 2015;Moorman et al, 2015;McGlinchey et al, 2016;Gutman et al, 2017), rather than an anatomical divide between dorsal and ventral subregions.…”

Section: Introductioncontrasting

confidence: 84%

Separate vmPFC Ensembles Control Cocaine Self-Administration Versus Extinction in Rats

et al. 2019

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Recent studies suggest that the ventral medial prefrontal cortex (vmPFC) encodes both operant drug self-administration and extinction memories. Here, we examined whether these opposing memories are encoded by distinct neuronal ensembles within the vmPFC with different outputs to the nucleus accumbens (NAc) in male and female rats. Using cocaine self-administration (3 h/d for 14 d) and extinction procedures, we demonstrated that vmPFC was similarly activated (indexed by Fos) during cocaine-seeking tests after 0 (no-extinction) or 7 extinction sessions. Selective Daun02 lesioning of the self-administration ensemble (no-extinction) decreased cocaine seeking, whereas Daun02 lesioning of the extinction ensemble increased cocaine seeking. Retrograde tracing with fluorescent cholera toxin subunit B injected into NAc combined with Fos colabeling in vmPFC indicated that vmPFC self-administration ensembles project to NAc core while extinction ensembles project to NAc shell. Functional disconnection experiments (Daun02 lesioning of vmPFC and acute dopamine D1-receptor blockade with SCH39166 in NAc core or shell) confirm that vmPFC ensembles interact with NAc core versus shell to play dissociable roles in cocaine self-administration versus extinction, respectively. Our results demonstrate that neuronal ensembles mediating cocaine self-administration and extinction comingle in vmPFC but have distinct outputs to the NAc core and shell that promote or inhibit cocaine seeking.

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“…This study examined the effect of repeated cocaine self-administration (SA) on neuronal firing in the prelimbic (PL) cortex before, during, and immediately after SA. The PL cortex has an established involvement in drug-related behaviors: PL inactivation significantly reduces cocaine SA (Di Pietro et al, 2006;Gutman et al, 2016) whereas PL inactivation immediately prior to reinstatement suppresses context (Fuchs et al, 2005), cue (McLaughlin and See, 2003;Stefanik et al, 2016), cocaine-primed (Di Pietro et al, 2006;McFarland and Kalivas, 2001), and stress-induced (Capriles et al, 2003;McFarland et al, 2004) drug seeking. Corresponding changes take place in the PL cortex with continued cocaine use that contribute to relapse.…”

Section: Introductionmentioning

confidence: 99%

Cocaine Self-Administration and Time-dependent Decreases in Prelimbic Activity

Dennis

Jhou

McGinty

2018

Preprint

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Cocaine self-administration causes dephosphorylation of proteins in prelimbic (PL) cortex that mediate excitation-transcription coupling, suggesting that cocaine causes decreased activity in PL neurons. Thus, we used in vivo single-unit extracellular recordings in awake, behaving rats to measure activity in PL neurons before, during, and after cocaine self-administration on the first and last session day (range 12-14 days). On the last day, cocaine suppressed 52% of recorded neurons in the PL cortex when compared to a 20 min baseline, significantly more than the 23% of neurons suppressed on the first day of cocaine. There was no change in the percentage of neurons that were excited on the first vs. the last day of self-administration (14% vs.13%, respectively). To determine whether the tonic inhibitory shift was induced by the behavior or by the drug itself, rats received a final session in which cocaine availability was delayed for the first 30 min or in which cocaine was administered non-contingently in the absence of levers or cues in a subset of rats. These manipulations indicated that cocaine was both necessary and sufficient to induce a downshift in PL neuronal activity.However, this activity decrease was not observed in rats that received only noncontingent cocaine for 12-14 days, indicating that contingency during self-administration training contributes to the cocaine-induced tonic downshift in PL activity. These data suggest that the session-by-session decrease in PL neuronal activity induced by cocaine is a reflection of learned drug-seeking behavior and, hence, reducing this inhibition may lessen cocaine addiction. peer-reviewed)

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The infralimbic and prelimbic cortices contribute to the inhibitory control of cocaine‐seeking behavior during a discriminative stimulus task in rats

Cited by 28 publications

References 42 publications

Anti-relapse neurons in the infralimbic cortex of rats drive relapse-suppression by drug omission cues

Anti-relapse neurons in the infralimbic cortex of rats drive relapse-suppression by drug omission cues

Separate vmPFC Ensembles Control Cocaine Self-Administration Versus Extinction in Rats

Cocaine Self-Administration and Time-dependent Decreases in Prelimbic Activity

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