The Relationship Between Circulating Endogenous Cannabinoids and the Effects of Smoked Cannabis.

Background: The endogenous cannabinoid system (ECS), including the endocannabinoids (eCBs), anandamide (AEA), and 2-arachidonoylglycerol (2-AG), plays an integral role in psychophysiological functions. Although frequent cannabis use is associated with adaptations in the ECS, the impact of acute smoked cannabis administration on circulating eCBs, and the relationship between cannabis effects and circulating eCBs are poorly understood. Methods: This study measured the plasma levels of AEA, 2-AG, and Δ-9-tetrahydrocannabinol (THC), subjective drug-effects ratings, and cardiovascular measures at baseline and 15-180 min after cannabis users (n=26) smoked 70% of a cannabis cigarette (5.6% THC). Results: Cannabis administration increased the ratings of intoxication, heart rate, and plasma THC levels relative to baseline. Although cannabis administration did not affect eCB levels relative to baseline, there was a significant positive correlation between baseline AEA levels and peak ratings of "High" and "Good Drug Effect." Further, baseline 2-AG levels negatively correlated with frequency of cannabis use (mean days/week) and with baseline THC metabolite levels. Conclusions: In a subset of heavy cannabis smokers: (1) more frequent cannabis use was associated with lower baseline 2-AG, and (2) those with lower AEA got less intoxicated after smoking cannabis. These findings contribute to a sparse literature on the interaction between endo- and phyto-cannabinoids. Future studies in participants with varied cannabis use patterns are needed to clarify the association between circulating eCBs and the abuse-related effects of cannabis, and to test whether baseline eCBs predict the intoxicating effects of cannabis and are a potential biomarker of cannabis tolerance.

Deletion of Maged1 in mice abolishes locomotor and reinforcing effects of cocaine.

Melanoma antigen genes (Mage) were first described as tumour markers. However, some of Mage are also expressed in healthy cells where their functions remain poorly understood. Here, we describe an unexpected role for one of these genes, Maged1, in the control of behaviours related to drug addiction. Mice lacking Maged1 are insensitive to the behavioural effects of cocaine as assessed by locomotor sensitization, conditioned place preference (CPP) and drug self-administration. Electrophysiological experiments in brain slices and conditional knockout mice demonstrate that Maged1 is critical for cortico-accumbal neurotransmission. Further, expression of Maged1 in the prefrontal cortex (PFC) and the amygdala, but not in dopaminergic or striatal and other GABAergic neurons, is necessary for cocaine-mediated behavioural sensitization, and its expression in the PFC is also required for cocaine-induced extracellular dopamine (DA) release in the nucleus accumbens (NAc). This work identifies Maged1 as a critical molecule involved in cellular processes and behaviours related to addiction.

Polysialic acid is required for active phases of morphological plasticity of neurosecretory axons and their glia.

The morphology of axons and astrocytes in the neurohypophysis changes considerably during physiological stimulation, increasing neurovascular contact and facilitating neurosecretion. We here assessed the contribution of alpha2, 8-linked polysialic acid (PSA), which intervenes in axonal changes during development and covers all neurohypophysial axon and glial surfaces. Using an in vitro model, we first analyzed neurohypophysial ultrastructure under different conditions of plasticity. After 2 h incubation in hyperosmotic medium or with the beta-adrenergic agonist, isoprenaline, neurovascular contact significantly increased, due essentially to an enhanced number of terminals, and gliovascular contact decreased correspondingly. This morphology was maintained during 22 h exposure to isoprenaline and reversed 2 h after agonist washout. Removal of PSA from cell surfaces with endoneurominidase prevented stimulation-related induction and reversal of axon and glial changes but had no effect once remodeling had occurred. PSA, therefore, by promoting dynamic cell interactions, is necessary for plasticity of axons and their associated glia.