u/SentientMonoamine

No evidence for direct physical interaction of 5-HT2A-mGluR2 receptors in vitro or in vivo

This is a spicy meatball (but a fresh preprint so proceed with caution)

Coming from the Roth lab, is a challenge to decades of work coming from Javier Gonzalez Maeso's lab (oooh drama) - while there is still an established functional relationship between 5HT2A/mGlu2 - the Roth lab, using cutting edge technology, was unable to discern a physical interaction between the two in vitro/vivo. A good read for the mechanistic psychedelic enthusiast 🌝

Abstract:

is well established that activating the mGluR2 metabotropic glutamate receptor (mGluR2), which is the main presynaptic autoreceptor for glutamate in the brain, attenuates the behavioral and electrophysiological actions of LSD and other psychedelics. However, the mechanisms responsible for these actions are controversial. The two competing mechanistic hypotheses have been proposed to explain this phenomenon are: (1) direct actions mediated by mGluR2/5-HT2A heterodimers, and (2) inhibition of 5-HT2A-mediated excitation of pyramidal neurons via presynaptic inhibition of glutamate release by mGluR2 receptors. Consistent with prior reports, we show mGluR2 agonist pretreatment attenuates the head twitch response induced by the psychedelic drug 1-(2,5-Dimethoxy-4-iodophenyl)-2-aminopropane (DOI) in these mice. We next employed multiple orthogonal in vivo and in vitro approaches to explore the potential for direct physical interactions between mGluR2 and 5-HT2A receptors. We next engineered mice to express mGluR2-mCherry-CT and 5-HT2A-eGFP-CT tagged receptors and found no evidence for receptor colocalization or oligomerization under basal or 5-HT2A agonist-exposed conditions in vitro or in vivo. Radioligand binding and kinetic analyses revealed no evidence for mGluR2-mediated modulation of 5-HT2A ligand binding in vitro or in vivo. Collectively, our findings support models in which mGluR2 signaling modulates the activity of Gq-coupled 5-HT2A receptors in layer V pyramidal neurons, rather than models positing the requirement of mGluR2/5-HT2A multimers.  

biorxiv.org
u/SentientMonoamine — 4 days ago

Single-nucleus transcriptomics reveals cell type-specific and time-dependent effects of psilocybin and ketamine on gene expression

Next up in the Kwan series on the cell type specific effects of Psilocybin. A revised preprint of his exhaustive sn-RNA-seq studies on the differential effects of Psilocybin on pyramidal neurons and interneurons. Great stuff that is genuinely pushing the needle in this space.

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NOTE: You have to download the PDF in order to view the whole article, otherwise only the abstract is accessible.

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Abstract:

There is growing interest to investigate classic psychedelics and ketamine as therapeutics for mental illnesses. Previous studies have demonstrated that one dose of psilocybin or ketamine leads to persisting neural and behavioral changes. The durability of these effects suggests that there are likely alterations in gene expression at the transcriptional level. In this study, we performed single-nucleus RNA sequencing of the dorsal medial frontal cortex of male and female mice. Samples were collected at 1, 2, 4, 24, or 72 hours after psilocybin or ketamine administration and from control animals. At baseline, major subtypes of excitatory and GABAergic neurons selectively express particular serotonin receptor transcripts. The psilocybin-evoked differentially expressed genes in excitatory neurons are involved in synaptic plasticity, distinct from genes enriched in GABAergic neurons, which contribute to mitochondrial function and cellular metabolism, and non-neuronal glial cells. The effect of psilocybin on gene expression is time-dependent, including an early phase at 1 hour followed by a late phase at 72 hours of transcriptional response after administration, and differs from the changes following ketamine administration, which peaks at 2 - 4 hours. Collectively, the results provide a resource for understanding the cell type-specific and time-dependent changes in gene expression induced by psilocybin and ketamine in the mouse medial frontal cortex, which may underpin the drug's long-term effects on neural circuits and behavior.

biorxiv.org
u/SentientMonoamine — 17 days ago