Rôle(s) du récepteur aux cannabinoïdes mitochondrial de type 1 dans le cerveau

Type-1 cannabinoid receptor CB1 is a G protein-coupled receptor (GPCR), widely expressed in the brain, which regulates numerous physiological processes. However, the cellular mechanisms of CB1-mediated control of these functions are poorly understood. Although CB1 are known to signal at the plasma membrane, a portion of these receptors are also present in mitochondria (mtCB1), where mtCB1 activation decreases mitochondrial activity. The goal of this thesis was to dissect the impact of brain mtCB1 signaling in known behavioral effects induced by cannabinoids. To distinguish the functions of mtCB1 from other receptor pools, we developed tools based on the characterization of the intra-mitochondrial molecular cascade induced by mtCB1 receptors. In isolated brain mitochondria, we found that intra-mitochondrial decrease of soluble-adenylyl cyclase (sAC) activity links mtCB1- dependent activation of Gαi/o proteins to decrease cellular respiration. Local brain inhibition of sAC activity blocks cannabinoid-induced amnesia, catalepsy and contributes to the hypolocomotor effect of cannabinoids. In addition, we generated a functional mutant CB1 protein (DN22-CB1) lacking the first 22 amino acid of CB1 and its mitochondrial localization. Differently from CB1, activation of DN22-CB1 does not affect mitochondrial activity. Hippocampal in vivo expression of DN22-CB1 abolished both cannabinoid-induced impairment of synaptic transmission and amnesia in mice. Together, these studies couple mitochondrial activity to behavioral performances. The involvement of mtCB1 in the effects of cannabinoids on memory and motor control highlights the key role of bioenergetic processes as regulators of brain functions.Le récepteur aux cannabinoïdes de type 1 (CB1) est un récepteur couplé aux protéines G, abondamment exprimé dans le cerveau et régulant plusieurs processus physiologiques. Cependant, les mécanismes cellulaires par lesquels les CB1 régulent ces processus n’ont été que peu analysés. Bien que les CB1 localisés dans les membranes plasmiques sont connus pour induire la transduction de signal; une partie de ces récepteurs sont aussi fonctionnels au niveau des mitochondries (mtCB1), où leur stimulation réduit la respiration mitochondriale. L’objectif de cette thèse fut d’évaluer l’impact de l’activation des récepteurs mtCB1 du cerveau sur les effets connus des cannabinoïdes. Afin de distinguer la fonction des mtCB1 de celle des autres populations de récepteurs, nous avons développé des outils basés sur la signalisation induite par les mtCB1. Dans les mitochondries isolées de cerveau, l’activation des protéines Gαi/o, dépendante des mtCB1 diminue l’activité de l’adénylyl cyclase soluble (sAC). L'inhibition locale de l’activité de sAC prévient l’amnésie, la catalepsie et partiellement l’hypolocomotion induite par les cannabinoïdes. De plus, nous avons généré une protéine fonctionnelle mutante CB1 (DN22-CB1) dépourvue des 22 premiers acides aminés des CB1 ainsi que de sa localisation mitochondriale. Contrairement aux CB1, l'activation des DN22-CB1 n’affecte pas l'activité mitochondriale. Enfin, l’expression des DN22-CB1 dans l’hippocampe bloque à la fois la diminution de la transmission synaptique et l’amnésie induites par les cannabinoïdes. Ces travaux démontrent l’implication des mtCB1 dans certains effets des cannabinoïdes et le rôle clé des processus bioénergétiques contrôlant les fonctions cérébrales

Metabolic consequences of chronic sleep restriction in rats:Changes in body weight regulation and energy expenditure

Epidemiological studies have shown an association between short or disrupted sleep and an increased risk to develop obesity. In animal studies, however, sleep restriction leads to an attenuation of weight gain that cannot be explained by changes in energy intake. In the present study, we assessed whether the attenuated weight gain under conditions of restricted sleep is a consequence of an overall increase in energy expenditure. Adult male rats were subjected to a schedule of chronic sleep restriction (SR) for 8 days with a 4 h window of unrestricted rest per day. Electroencephalogram and electromyogram recordings were performed to quantify the effect of the sleep restriction schedule on sleep-wake patterns. In a separate experiment, we measured sleep restriction-induced changes in body weight, food intake, and regulatory hormones such as glucose, insulin, leptin and corticosterone. To investigate whether a change in energy expenditure underlies the attenuation of weight gain, energy expenditure was measured by the doubly labeled water method from day 5 until day 8 of the SR protocol. Results show a clear attenuation of weight gain during sleep restriction but no change in food intake. Baseline plasma glucose, insulin and leptin levels are decreased after sleep restriction which presumably reflects the nutritional status of the rats. The daily energy expenditure during SR was significantly increased compared to control rats. Together, we conclude that the attenuation of body weight gain in sleep restricted rats is explained by an overall increase in energy expenditure together with an unaltered energy intake. Published by Elsevier Inc

The endocannabinoid system controls food intake via olfactory processes

Comment in Sensory systems: the hungry sense. [Nat Rev Neurosci. 2014] Inhaling: endocannabinoids and food intake. [Nat Neurosci. 2014]; International audience; Hunger arouses sensory perception, eventually leading to an increase in food intake, but the underlying mechanisms remain poorly understood. We found that cannabinoid type-1 (CB1) receptors promote food intake in fasted mice by increasing odor detection. CB1 receptors were abundantly expressed on axon terminals of centrifugal cortical glutamatergic neurons that project to inhibitory granule cells of the main olfactory bulb (MOB). Local pharmacological and genetic manipulations revealed that endocannabinoids and exogenous cannabinoids increased odor detection and food intake in fasted mice by decreasing excitatory drive from olfactory cortex areas to the MOB. Consistently, cannabinoid agonists dampened in vivo optogenetically stimulated excitatory transmission in the same circuit. Our data indicate that cortical feedback projections to the MOB crucially regulate food intake via CB1 receptor signaling, linking the feeling of hunger to stronger odor processing. Thus, CB1 receptor-dependent control of cortical feedback projections in olfactory circuits couples internal states to perception and behavior

Subcellular specificity of cannabinoid effects in striatonigral circuits

Recent advances in neuroscience have positioned brain circuits as key units in controlling behavior, implying that their positive or negative modulation necessarily leads to specific behavioral outcomes. However, emerging evidence suggests that the activation or inhibition of specific brain circuits can actually produce multimodal behavioral outcomes. This study shows that activation of a receptor at different subcellular locations in the same neuronal circuit can determine distinct behaviors. Pharmacological activation of type 1 cannabinoid (CB1) receptors in the striatonigral circuit elicits both antinociception and catalepsy in mice. The decrease in nociception depends on the activation of plasma membrane-residing CB1 receptors (pmCB1), leading to the inhibition of cytosolic PKA activity and substance P release. By contrast, mitochondrial-associated CB1 receptors (mtCB1) located at the same terminals mediate cannabinoid-induced catalepsy through the decrease in intra-mitochondrial PKA-dependent cellular respiration and synaptic transmission. Thus, subcellular-specific CB1 receptor signaling within striatonigral circuits determines multimodal control of behavior

Role(s) of the mitochondrial type-1 cannabinoid receptor in the brain

Le récepteur aux cannabinoïdes de type 1 (CB1) est un récepteur couplé aux protéines G, abondamment exprimé dans le cerveau et régulant plusieurs processus physiologiques. Cependant, les mécanismes cellulaires par lesquels les CB1 régulent ces processus n’ont été que peu analysés. Bien que les CB1 localisés dans les membranes plasmiques sont connus pour induire la transduction de signal; une partie de ces récepteurs sont aussi fonctionnels au niveau des mitochondries (mtCB1), où leur stimulation réduit la respiration mitochondriale. L’objectif de cette thèse fut d’évaluer l’impact de l’activation des récepteurs mtCB1 du cerveau sur les effets connus des cannabinoïdes. Afin de distinguer la fonction des mtCB1 de celle des autres populations de récepteurs, nous avons développé des outils basés sur la signalisation induite par les mtCB1. Dans les mitochondries isolées de cerveau, l’activation des protéines Gαi/o, dépendante des mtCB1 diminue l’activité de l’adénylyl cyclase soluble (sAC). L'inhibition locale de l’activité de sAC prévient l’amnésie, la catalepsie et partiellement l’hypolocomotion induite par les cannabinoïdes. De plus, nous avons généré une protéine fonctionnelle mutante CB1 (DN22-CB1) dépourvue des 22 premiers acides aminés des CB1 ainsi que de sa localisation mitochondriale. Contrairement aux CB1, l'activation des DN22-CB1 n’affecte pas l'activité mitochondriale. Enfin, l’expression des DN22-CB1 dans l’hippocampe bloque à la fois la diminution de la transmission synaptique et l’amnésie induites par les cannabinoïdes. Ces travaux démontrent l’implication des mtCB1 dans certains effets des cannabinoïdes et le rôle clé des processus bioénergétiques contrôlant les fonctions cérébrales.Type-1 cannabinoid receptor CB1 is a G protein-coupled receptor (GPCR), widely expressed in the brain, which regulates numerous physiological processes. However, the cellular mechanisms of CB1-mediated control of these functions are poorly understood. Although CB1 are known to signal at the plasma membrane, a portion of these receptors are also present in mitochondria (mtCB1), where mtCB1 activation decreases mitochondrial activity. The goal of this thesis was to dissect the impact of brain mtCB1 signaling in known behavioral effects induced by cannabinoids. To distinguish the functions of mtCB1 from other receptor pools, we developed tools based on the characterization of the intra-mitochondrial molecular cascade induced by mtCB1 receptors. In isolated brain mitochondria, we found that intra-mitochondrial decrease of soluble-adenylyl cyclase (sAC) activity links mtCB1- dependent activation of Gαi/o proteins to decrease cellular respiration. Local brain inhibition of sAC activity blocks cannabinoid-induced amnesia, catalepsy and contributes to the hypolocomotor effect of cannabinoids. In addition, we generated a functional mutant CB1 protein (DN22-CB1) lacking the first 22 amino acid of CB1 and its mitochondrial localization. Differently from CB1, activation of DN22-CB1 does not affect mitochondrial activity. Hippocampal in vivo expression of DN22-CB1 abolished both cannabinoid-induced impairment of synaptic transmission and amnesia in mice. Together, these studies couple mitochondrial activity to behavioral performances. The involvement of mtCB1 in the effects of cannabinoids on memory and motor control highlights the key role of bioenergetic processes as regulators of brain functions

Role(s) of the mitochondrial type-1 cannabinoid receptor in the brain

Le récepteur aux cannabinoïdes de type 1 (CB1) est un récepteur couplé aux protéines G, abondamment exprimé dans le cerveau et régulant plusieurs processus physiologiques. Cependant, les mécanismes cellulaires par lesquels les CB1 régulent ces processus n’ont été que peu analysés. Bien que les CB1 localisés dans les membranes plasmiques sont connus pour induire la transduction de signal; une partie de ces récepteurs sont aussi fonctionnels au niveau des mitochondries (mtCB1), où leur stimulation réduit la respiration mitochondriale. L’objectif de cette thèse fut d’évaluer l’impact de l’activation des récepteurs mtCB1 du cerveau sur les effets connus des cannabinoïdes. Afin de distinguer la fonction des mtCB1 de celle des autres populations de récepteurs, nous avons développé des outils basés sur la signalisation induite par les mtCB1. Dans les mitochondries isolées de cerveau, l’activation des protéines Gαi/o, dépendante des mtCB1 diminue l’activité de l’adénylyl cyclase soluble (sAC). L'inhibition locale de l’activité de sAC prévient l’amnésie, la catalepsie et partiellement l’hypolocomotion induite par les cannabinoïdes. De plus, nous avons généré une protéine fonctionnelle mutante CB1 (DN22-CB1) dépourvue des 22 premiers acides aminés des CB1 ainsi que de sa localisation mitochondriale. Contrairement aux CB1, l'activation des DN22-CB1 n’affecte pas l'activité mitochondriale. Enfin, l’expression des DN22-CB1 dans l’hippocampe bloque à la fois la diminution de la transmission synaptique et l’amnésie induites par les cannabinoïdes. Ces travaux démontrent l’implication des mtCB1 dans certains effets des cannabinoïdes et le rôle clé des processus bioénergétiques contrôlant les fonctions cérébrales.Type-1 cannabinoid receptor CB1 is a G protein-coupled receptor (GPCR), widely expressed in the brain, which regulates numerous physiological processes. However, the cellular mechanisms of CB1-mediated control of these functions are poorly understood. Although CB1 are known to signal at the plasma membrane, a portion of these receptors are also present in mitochondria (mtCB1), where mtCB1 activation decreases mitochondrial activity. The goal of this thesis was to dissect the impact of brain mtCB1 signaling in known behavioral effects induced by cannabinoids. To distinguish the functions of mtCB1 from other receptor pools, we developed tools based on the characterization of the intra-mitochondrial molecular cascade induced by mtCB1 receptors. In isolated brain mitochondria, we found that intra-mitochondrial decrease of soluble-adenylyl cyclase (sAC) activity links mtCB1- dependent activation of Gαi/o proteins to decrease cellular respiration. Local brain inhibition of sAC activity blocks cannabinoid-induced amnesia, catalepsy and contributes to the hypolocomotor effect of cannabinoids. In addition, we generated a functional mutant CB1 protein (DN22-CB1) lacking the first 22 amino acid of CB1 and its mitochondrial localization. Differently from CB1, activation of DN22-CB1 does not affect mitochondrial activity. Hippocampal in vivo expression of DN22-CB1 abolished both cannabinoid-induced impairment of synaptic transmission and amnesia in mice. Together, these studies couple mitochondrial activity to behavioral performances. The involvement of mtCB1 in the effects of cannabinoids on memory and motor control highlights the key role of bioenergetic processes as regulators of brain functions

Increased food intake and changes in metabolic hormones in response to chronic sleep restriction alternated with short periods of sleep allowance

Rodent models for sleep restriction have good face validity when examining food intake and related regulatory metabolic hormones. However, in contrast to epidemiological studies in which sleep restriction is associated with body weight gain, sleep-restricted rats show a decrease in body weight. This difference with the human situation might be caused by the alternation between periods of sleep restriction and sleep allowance that often occur in real life. Therefore, we assessed the metabolic consequences of a chronic sleep restriction protocol that modeled working weeks with restricted sleep time alternated by weekends with sleep allowance. We hypothesized that this protocol could lead to body weight gain. Male Wistar rats were divided into three groups: sleep restriction (SR), forced activity control (FA), and home cage control (HC). SR rats were subjected to chronic sleep restriction by keeping them awake for 20 h per day in slowly rotating drums. To model the human condition, rats were subjected to a 4-wk protocol, with each week consisting of a 5-day period of sleep restriction followed by a 2-day period of sleep allowance. During the first experimental week, SR caused a clear attenuation of growth. In subsequent weeks, two important processes occurred: 1) a remarkable increase in food intake during SR days, 2) an increase in weight gain during the weekends of sleep allowance, even though food intake during those days was comparable to controls. In conclusion, our data revealed that the alternation between periods of sleep restriction and sleep allowance leads to complex changes in food intake and body weight, that prevent the weight loss normally seen in continuous sleep-restricted rats. Therefore, this “week-weekend” protocol may be a better model to study the metabolic consequences of restricted sleep.