Membrane excitability of nucleus accumbens neurons gates the incubation of cocaine craving

After drug withdrawal, a key factor triggering relapse is progressively intensified cue-associated drug craving, termed incubation of drug craving. After withdrawal from cocaine self-administration, incubation of cocaine craving develops more reliably in rats compared to mice. This species differenc...

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Published in:Neuropsychopharmacology (New York, N.Y.) N.Y.), 2023-08, Vol.48 (9), p.1318-1327
Main Authors: He, Yi, Wang, Junshi, Li, King-Lun, Wang, Yao Q, Freyberg, Zachary, Dong, Yan
Format: Article
Language:English
Subjects:
Adaptation
Animals
Channel gating
Cocaine
Cocaine-Related Disorders - metabolism
Craving
Dopamine D1 receptors
Dopamine D2 receptors
Drug addiction
Drug self-administration
Drug withdrawal
Excitability
Humans
Mice
Neurons - metabolism
Nucleus accumbens
Nucleus Accumbens - metabolism
Rats
Receptors, Dopamine - metabolism
Spiny neurons
Substance Withdrawal Syndrome - metabolism
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Summary:After drug withdrawal, a key factor triggering relapse is progressively intensified cue-associated drug craving, termed incubation of drug craving. After withdrawal from cocaine self-administration, incubation of cocaine craving develops more reliably in rats compared to mice. This species difference provides an opportunity to determine rat-specific cellular adaptations, which may constitute the critical mechanisms that contribute to incubated cocaine craving in humans. Expression of incubated cocaine seeking is mediated, in part, by cocaine-induced cellular adaptations in medium spiny neurons (MSNs) within the nucleus accumbens (NAc). In rats, decreased membrane excitability in NAc MSNs is a prominent cellular adaptation, which is induced after cocaine self-administration and lasts throughout prolonged drug withdrawal. Here, we show that, similar to rats, mice exhibit decreased membrane excitability of dopamine D receptor (D1)-, but not D (D2)-, expressing MSNs within the NAc shell (NAcSh) after 1 d withdrawal from cocaine self-administration. However, in contrast to rats, this membrane adaptation does not persist in mice, diminishing after 45-d withdrawal. We also find that restoring the membrane excitability of NAcSh MSNs after cocaine withdrawal decreases cocaine seeking in rats. This suggests that drug-induced membrane adaptations are essential for behavioral expression of incubated cocaine craving. In mice, however, experimentally inducing hypoactivity of D1 NAcSh MSNs after cocaine withdrawal does not alter cocaine seeking, suggesting that MSN hypo-excitability alone is insufficient to increase cocaine seeking. Together, our results demonstrate an overall permissive role of cocaine-induced hypoactivity of NAcSh MSNs in gating increased cocaine seeking after prolonged cocaine withdrawal.
ISSN:0893-133X
1740-634X
1740-634X
DOI:10.1038/s41386-023-01580-w