Autocrine Endocannabinoid Signaling through CB<sub>1</sub>Receptors Potentiates OX<sub>1</sub>Orexin Receptor Signaling

Jäntti, Maria; Putula, Jaana; Turunen, Päivi; Näsman, Johnny; Reijonen, Sami; Lindqvist, Christer; Kukkonen, Jyrki P.

doi:10.1124/mol.112.080523

Cited by 35 publications

(36 citation statements)

References 57 publications

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“…Besides the heteromerization, an additional mechanism has been proposed to explain the increase in the potency of hypocretin-1 to activate the ERK pathway in the presence of CB1 (Jäntti et al, 2013; Kukkonen and Leonard, 2013). Recent studies report that HcrtR1-expressing CHO cells may release 2-AG in response to hypocretin-1 stimulation.…”

Section: Molecular Interactions Between Cb1 and Hcrtr1mentioning

confidence: 99%

Cannabinoid-hypocretin cross-talk in the central nervous system: what we know so far

2013

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Emerging findings suggest the existence of a cross-talk between hypocretinergic and endocannabinoid systems. Although few studies have examined this relationship, the apparent overlap observed in the neuroanatomical distribution of both systems as well as their putative functions strongly point to the existence of such cross-modulation. In agreement, biochemical and functional studies have revealed the existence of heterodimers between CB1 cannabinoid receptor and hypocretin receptor-1, which modulates the cellular localization and downstream signaling of both receptors. Moreover, the activation of hypocretin receptor-1 stimulates the synthesis of 2-arachidonoyl glycerol culminating in the retrograde inhibition of neighboring cells and suggesting that endocannabinoids could contribute to some hypocretin effects. Pharmacological data indicate that endocannabinoids and hypocretins might have common physiological functions in the regulation of appetite, reward and analgesia. In contrast, these neuromodulatory systems seem to play antagonistic roles in the regulation of sleep/wake cycle and anxiety-like responses. The present review attempts to piece together what is known about this interesting interaction and describes its potential therapeutic implications.

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Section: Molecular Interactions Between Cb1 and Hcrtr1mentioning

confidence: 99%

Cannabinoid-hypocretin cross-talk in the central nervous system: what we know so far

2013

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“…In any biological system, the abundance of endogenously-produced endocannabinoids is an important determinant of whether the CB 1 R is under the influence of high “endocannabinoid tone” that could be reversed by a competitive antagonist (for discussion, see [42]). CHO cells express phospholipase C and diacylglycerol lipase [43;44], as do neuronal cell lines (Howlett, unpublished observations), enzymes that govern production of the endocannabinoid 2-AG. This suggests the necessity of testing responses to a diaceylglycerol lipase inhibitor to demonstrate whether forskolin-activated cAMP accumulation can be influenced by endocannabinoids produced by the cultured cells.…”

Section: Discussionmentioning

confidence: 99%

CB₁ cannabinoid receptor-mediated increases in cyclic AMP accumulation are correlated with reduced Gi/o function

Eldeeb¹,

Leone-Kabler

Howlett

2016

Journal of Basic and Clinical Physiology and Pharmacology

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Introduction CB1 cannabinoid receptors (CB1Rs) stimulate Gi/o-dependent signaling pathways. CB1R-mediated cAMP increases were proposed to result from Gs activation, but CB1R-stimulated GTPγS binding to Gs has not heretofore been investigated. Methods Three models of CB1R- stimulated cAMP production were tested: Pertussis toxin disruption of Gi/o in N18TG2 cells; L341A/A342L-CB1R expressed in CHO cells; and CB1 and D2 dopamine receptors endogenously co-expressed in MN9D cells. cAMP was assayed by [3H]cAMP binding competition. G protein activation was assayed by antibody-targeted Scintillation Proximity Assay (SPA). Results In L341A/A342L-CB1-CHO cells, cannabinoid agonists significantly stimulated cAMP accumulation over vehicle; CP55940-stimulated [35S]GTPγS binding to Gi1/2/3 was reversed, whereas binding to Gs was not different from CB1R. In MN9D cells, CB1 agonist HU210 or D2 agonist quinpirole alone inhibited forskolin-activated cAMP accumulation, whereas HU210 plus quinpirole increased cAMP accumulation above basal. HU210 alone stimulated [35S]GTPγS binding to Gi1/2/3, whereas co-stimulation with quinpirole reversed HU210-stimulated [35S]GTPγS binding to Gi1/2/3. Conclusions CB1R couples to Gs but with low efficacy compared to Gi/o. The L341A/A342L mutation in CB1R reversed CP55940 activation of Gi to an inhibition, but had no effect on Gs. Combined CB1 plus D2 agonists in MN9D cells converted the CB1 agonist-mediated activation of Gi to inhibition of Gi. In these models, the CB1 agonist response was converted to an inverse agonist response at Gi activation. Cannabinoid agonist-stimulated cAMP accumulation can be best explained as reduced activation of Gi, thereby attenuating the tonic inhibitory influence of Gi on the major isoforms of adenylyl cyclase.

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“…25 In an in vitro study, it was demonstrated that the coexpression of CB1 and OX1 receptors results in a higher potentiation of ERK signalling, possibly because of heterodimerization/oligomerization of these two receptors. 26 Recently, however, it was also shown that 2-AG produced and released through the activation of OX1 receptor acts as both a paracrine and autocrine messenger via CB1 receptors, 23,27 thus possibly explaining the above-mentioned findings in the rat dorsal raphe nucleus and periaqueductal gray, as well as the potentiation of ERK phoshorylation that follows OX1/CB1 receptor coexpression. These data suggest the involvement of 2-AG and CB1 receptors not only in orexin-A release but also in orexin-mediated regulation of synaptic transmission.…”

Section: Leptin-mediated Hypothalamic Ecb/orexin Interactionsmentioning

confidence: 94%

New horizons on the role of cannabinoid CB1 receptors in palatable food intake, obesity and related dysmetabolism

2014

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Excessive consumption of high-energy, palatable food contributes to obesity, which results in the metabolic syndrome, heart disease, type-2 diabetes and death. Current knowledge on the function of the hypothalamus as the brain 'feeding centre' recognizes this region as the main regulator of body weight in the central nervous system. Because of their intrinsically fast and adaptive activities, feeding-controlling neural circuitries are endowed with synaptic plasticity modulated by neurotransmitters and hormones that act at different hierarchical levels of integration. In the hypothalamus, among the chemical mediators involved in this integration, endocannabinoids (eCBs) are ideal candidates for the fast (that is, nongenomic), stress-related fine-tuning of neuronal functions. In this article, we overview the role of the eCB system (ECS) in the control of energy intake, and particularly in the consumption of high-energy, palatable food, and discuss how such a role is affected in the brain by changes in the levels of feeding-regulated hormones, such as the adipose tissue-derived anorexigenic mediator leptin, as well as by high-fat diets. The understanding of the molecular mechanisms underlying the neuronal control of feeding behaviours by eCBs offers many potential opportunities for novel therapeutic approaches against obesity. Highlights of the latest advances in the development of strategies that minimize central ECS overactivity in 'western diet'-driven obesity are discussed.International Journal of Obesity Supplements (2014) 4, S26--S30; doi:10.1038/ijosup.2014.8Keywords: CB1; hypothalamus; leptin; high-fat diet; synaptic rewiring; endocannabinoids INTRODUCTIONThe hypothalamus is the most extensively interconnected area of the brain, and through its wide web of neural circuits it controls a variety of essential autonomic and somatomotor functions. Neuroanatomical studies have demonstrated direct projections to hypothalamic areas from several brain regions such as cortical/ limbic areas and autonomic motor systems of the brainstem. Such extensive connectivity is thought to represent the anatomical basis supporting sleep--wake regulation, energy homeostasis and cognitive and reward-related functions.1 Hormonal and nutrient signals are processed in the hypothalamus and inform the brain about the free and stored levels of fuel available to the organism. In turn, the hypothalamic neuronal circuits use this information to regulate energy intake, energy expenditure and peripheral lipid and glucose metabolism.2 Because of their intrinsic functional activities, and the necessity to adapt to often significant changes in nutritional status, neural feeding circuitries are endowed with synaptic plasticity modulated by neurotransmitters and hormones that act at different hierarchical levels of integration.1 Among the chemical mediators involved in this integration, the endocannabinoids (eCBs) are the master regulators of the fast (that is, nongenomic) and stress-related fine-tuning of energy intake and processing. The eCB sys...

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Autocrine Endocannabinoid Signaling through CB₁Receptors Potentiates OX₁Orexin Receptor Signaling

Cited by 35 publications

References 57 publications

Cannabinoid-hypocretin cross-talk in the central nervous system: what we know so far

Cannabinoid-hypocretin cross-talk in the central nervous system: what we know so far

CB₁ cannabinoid receptor-mediated increases in cyclic AMP accumulation are correlated with reduced Gi/o function

New horizons on the role of cannabinoid CB1 receptors in palatable food intake, obesity and related dysmetabolism

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Autocrine Endocannabinoid Signaling through CB1Receptors Potentiates OX1Orexin Receptor Signaling

Cited by 35 publications

References 57 publications

Cannabinoid-hypocretin cross-talk in the central nervous system: what we know so far

Cannabinoid-hypocretin cross-talk in the central nervous system: what we know so far

CB1 cannabinoid receptor-mediated increases in cyclic AMP accumulation are correlated with reduced Gi/o function

New horizons on the role of cannabinoid CB1 receptors in palatable food intake, obesity and related dysmetabolism

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Resources

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Autocrine Endocannabinoid Signaling through CB₁Receptors Potentiates OX₁Orexin Receptor Signaling

CB₁ cannabinoid receptor-mediated increases in cyclic AMP accumulation are correlated with reduced Gi/o function