Frequent Low-Dose Δ9-Tetrahydrocannabinol in Adolescence Disrupts Microglia Homeostasis and Disables Responses to Microbial Infection and Social Stress in Young Adulthood

Science Direct- Biological Psychiatry Volume 92, Issue 11, 1 December 2022, Pages 845-860
2022
Hye-Lim Lee a ∗, Kwang-Mook Jung a ∗, Yannick Fotio a, Erica Squire a, Francesca Palese a, Lin Lin a, Alexa Torrens a, Faizy Ahmed a, Alex Mabou Tagne a, Jade Ramirez a, Shiqi Su a, Christina Renee Wong a, Daniel Hojin Jung a, Vanessa M. Scarfone e, Pauline U. Nguyen e, Marcelo Wood b, Kim Green b, Daniele Piomelli

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Abstract

Background

During adolescence, microglia are actively involved in neocortical maturation while concomitantly undergoing profound phenotypic changes. Because the teenage years are also a time of experimentation with cannabis, we evaluated whether adolescent exposure to the drug’s psychotropic constituent, Δ9-tetrahydrocannabinol (THC), might persistently alter microglia function.

Methods

We administered THC (5 mg/kg, intraperitoneal) once daily to male and female mice from postnatal day (PND) 30 to PND44 and examined the transcriptome of purified microglia in adult animals (PND70 and PND120) under baseline conditions or following either of two interventions known to recruit microglia: lipopolysaccharide injection and repeated social defeat. We used high-dimensional mass cytometry by time-of-flight to map brain immune cell populations after lipopolysaccharide challenge.

Results

Adolescent THC exposure produced in mice of both sexes a state of microglial dyshomeostasis that persisted until young adulthood (PND70) but receded with further aging (PND120). Key features of this state included broad alterations in genes involved in microglia homeostasis and innate immunity along with marked impairments in the responses to lipopolysaccharide- and repeated social defeat–induced psychosocial stress. The endocannabinoid system was also dysfunctional. The effects of THC were prevented by coadministration of either a global CB1 receptor inverse agonist or a peripheral CB1 neutral antagonist and were not replicated when THC was administered in young adulthood (PND70–84).

Conclusions

Daily low-intensity CB1 receptor activation by THC during adolescence may disable critical functions served by microglia until young adulthood with potentially wide-ranging consequences for brain and mental health.

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