A single dose of psilocybin increases dendritic spine density in two types of pyramidal cells in the mouse medial frontal cortex: subcortical-projecting pyramidal tract (PT) and intratelencephalic (IT) neurons. Silencing PT neurons eliminates psilocybin's ability to reduce stress-related behaviors, while silencing IT neurons has no effect. Psilocybin boosts synaptic calcium transients and firing rates specifically in PT neurons shortly after administration. Knocking out the 5-HT2A receptor blocks psilocybin's effects on both stress-related behavior and structural plasticity. These findings identify PT neurons and the 5-HT2A receptor as essential for psilocybin's long-term actions.
Psilocybin, a classic psychedelic, alters the activity of specific inhibitory neurons in the mouse medial frontal cortex. It reduces firing of somatostatin-expressing interneurons while increasing activity of parvalbumin-expressing interneurons. This cell type-specific response depends on the 5-HT1A receptor on somatostatin interneurons, and contributes to the drug's long-term behavioral effects. The findings reveal that psilocybin changes cortical inhibition in a targeted manner, highlighting a mechanism beyond the commonly studied pyramidal cells.
A single dose of psilocybin increased the density of dendritic spines in both subcortical-projecting pyramidal tract (PT) and intratelencephalic (IT) cell types in the mouse medial frontal cortex. Silencing PT neurons eliminated psilocybin's ability to ameliorate stress-related phenotypes, whereas silencing IT neurons had no detectable effect. In PT neurons only, psilocybin boosted synaptic calcium transients and elevated firing rates acutely after administration. Targeted knockout of 5-HT2A receptors abolished psilocybin's effects on stress-related behavior and structural plasticity. These results identify a pyramidal cell type and the 5-HT2A receptor in the medial frontal cortex as essential for psilocybin's long-term drug action.