Abstract
Recreational use of synthetic cannabinoid agonists (i.e., "spice compounds") that target the cannabinoid type 1 receptor (CB(1)) can cause acute respiratory failure in humans. However, Δ(9)-tetrahydrocannabinol (Δ(9)-THC), the major psychoactive phytocannabinoid in cannabis, is not traditionally thought to interact with the brain respiratory system, based largely upon sparse labeling of CB(1) receptors in the medulla and relative safety suggested by widespread human use. Here we used whole body plethysmography and RNAscope in situ hybridization in mice to reconcile this conflict between conventional wisdom and human data. We examined the respiratory effects of the synthetic CB(1) full agonist CP55,940 and Δ(9)-THC in male and female mice. CP55,940 and Δ(9)-THC potently and dose-dependently suppressed minute ventilation and tidal volume, decreasing measures of respiratory effort (i.e., peak inspiratory and expiratory flow). Both cannabinoids reduced respiratory frequency, decreasing inspiratory and expiratory time while markedly increasing inspiratory and expiratory pause. Respiratory suppressive effects were fully blocked by the CB(1) antagonist AM251, were minimally impacted by the peripherally-restricted CB(1) antagonist AM6545, and occurred at doses lower than those that produce cardinal behavioral signs of CB(1) activation. Using RNAscope in situ hybridization, we also demonstrated extensive coexpression of Cnr1 (encoding the CB(1) receptor) and Oprm1 (encoding the µ-opioid receptor) mRNA in respiratory cells in the medullary pre-Bötzinger complex, a critical nucleus of respiratory control. Our results show that mRNA for CB(1) is present in respiratory cells in a medullary brain region essential for breathing and demonstrate that cannabinoids produce respiratory suppression via activation of central CB(1) receptors.