The serotonin 2C receptor (5-HT 2C ) is involved in processes like mood and appetite and is a target for drugs treating obesity, addiction, and depression, including psychedelics. This analysis of 5-HT 2C signaling confirms that the receptor activates multiple G protein pathways—Gi/o/z and G12/13 in addition to its main Gq/11 pathway—and preferentially recruits β-arrestin2 over β-arrestin1. Increased RNA editing of the receptor reduces signaling across all G protein pathways, especially G12/13, while preserving β-arrestin recruitment. Profiling of ligands shows that psychedelics like LSD and psilocin produce a strong Gq/11 bias by minimally activating other G proteins. These findings provide a foundation for considering broader signaling modalities in 5-HT 2C drug development.
Selectivity for the 5-HT2A receptor over the closely related 5-HT2C receptor can be achieved by targeting residue L1232.53 in transmembrane 2 of the extended binding pocket through increasing steric aliphatic bulk on the α-methylene group of the N-benzyl chemical scaffold. This selectivity was confirmed across 5-HT2C RNA editing isoforms, TM2 reciprocal mutants, and mouse orthologs, producing the most highly selective 5-HT2A agonists to date. Using structure–activity relationships, molecular docking, and mouse head-twitch response assays, the work demonstrates that such agonists can be rationally designed to improve target engagement, advancing the study of the neurobiological mechanisms of psychedelic effects.