The use of psilocybin to treat alcohol use disorder is very promising, but the mechanisms of action remain poorly understood. We combined behavioral, pharmacological and gene expression analyses to decipher the mechanisms of action of psilocybin, for the first time injected into the brain. Male Long Evans rats underwent chronic operant ethanol self-administration before testing the effect of intraperitoneal psilocybin or directly within the nucleus accumbens core or the ventral tegmental area. Transcripts from the dopaminergic system were quantified in the nucleus accumbens and prefrontal cortex. Psilocybin significantly reduced (50%) ethanol self-administration when injected 4 hours before the session either intraperitoneally (1mg/kg) or directly within the left nucleus accumbens (0.15μg) but not the right nucleus accumbens or the left ventral tegmental area. The effect of intraperitoneal injection of psilocybin was prevented by intra left nucleus accumbens injection of 0.3μg of the 5-HT2AR antagonist ketanserin. In rats that self-administered ethanol but not in those self-administering saccharin, dopamine D2 receptor mRNA were increased in both the nucleus accumbens and the prefrontal cortex by psilocybin, while D1R mRNA was increased only in the prefrontal cortex. As in humans, psilocybin reduced ethanol self-administration in rats through the 5-HT2AR within the left nucleus accumbens possibly through increased D2R expression. Our results open unexpected perspectives regarding the hemispheric lateralization of psychedelic effects.
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