Cover Story Current Issue

Excessive lipid accumulation in adipose tissue triggers hypertrophy and stress of adipocytes, leading to infiltration of proinflammatory immune cells, fibrosis and adipocyte cell death, collectively referred to as adipose tissue dysfunction. As consequence, adipocytes capacity to store lipids is impaired and fat is ectopically accumulated in organs such as muscle, liver and pancreas, a condition that promotes organ dysfunction and insulin resistance, contributing to the pathogenesis of type 2 diabetes (T2D).

Although fat accumulation in human pancreas was described decades ago, it has for long remained an underexplored facet of ectopic fat distribution. Pancreatic fat has been associated with improved insulin secretion in normoglycaemic subjects, but with impaired insulin secretion in patients at increased risk of T2D. Furthermore, T2D diabetes remission, i.e. recovery of beta cell function was accompanied by reduction of pancreatic fat. These clinical observations point to the controversial role of pancreatic fat in insulin secretion, and emphasize the need for experimental evidence demonstrating plausible lipolysis derived fatty acids-/secretome-mediated effects of pancreatic adipocytes in islets. To date, detailed studies on the mechanistic interactions between pancreatic adipocytes and insulin secretion remain sparse, as reliable in vitro models replicating the unique properties of these cells have been lacking.

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Current Issue

Cannabinoid type-1 receptors in CaMKII neurons drive impulsivity in pathological eating behavior.

Elena Martin-Garcia, Laura Domingo-Rodriguez, Beat Lutz, Rafael Maldonado, Inigo Ruiz de Azua

 

Overconsumption of palatable food and energy accumulation are evolutionary mechanisms of survival when food is scarce. This innate mechanism becomes detrimental in obesogenic environment promoting obesity and related comorbidities, including mood disorders. The endocannabinoid system favors energy accumulation and regulates reward circuits. We applied a genetic strategy to reconstitute cannabinoid type-1 receptor (CB1) expression at functional levels specifically in CaMKII+ neurons (CaMKII-CB1-RS) and adipocytes (Ati-CB1-RS), respectively, in a CB1 deficient background. Rescued CB1 expression in CaMKII+ neurons, but not in adipocytes, promotes feeding behavior, leading to fasting-induced hyperphagia, increased motivation, and impulsivity to palatable food seeking. In a diet-induced obesity model, CB1 re-expression in CaMKII+ neurons, but not in adipocytes, compared to complete CB1 deficiency, was sufficient to largely restore weight gain, food intake without any effect on glucose intolerance associated with high-fat diet consumption. In a model of glucocorticoid-mediated metabolic syndrome, CaMKII-CB1-RS mice showed all metabolic alterations linked to the human metabolic syndrome except of glucose intolerance. In a binge-eating model mimicking human pathological feeding, CaMKII-CB1-RS mice showed increased seeking and compulsive behavior to palatable food, suggesting crucial roles in foraging and an enhanced susceptibility to addictive-like eating behaviors. Importantly, other contingent behaviors, including increased cognitive flexibility and reduced anxiety-like behaviors, but not depressive-like behaviors, were also observed. To sum up, CB1 in CaMKII+ neurons is instrumental in feeding behavior and energy storage under physiological conditions. The exposure to risk factors (hypercaloric diet, glucocorticoid dysregulation) leads to obesity, metabolic syndrome, binge-eating and food addiction.

Keywords

Endocannabinoid system

cannabinoid type 1 receptor (CB1)

impulsivity

feeding behavior

obesity

metabolic syndrome

food addiction

 

Articles in Press

Cannabinoid type-1 receptors in CaMKII neurons drive impulsivity in pathological eating behavior.

Elena Martin-Garcia, Laura Domingo-Rodriguez, Beat Lutz, Rafael Maldonado, Inigo Ruiz de Azua

 

Overconsumption of palatable food and energy accumulation are evolutionary mechanisms of survival when food is scarce. This innate mechanism becomes detrimental in obesogenic environment promoting obesity and related comorbidities, including mood disorders. The endocannabinoid system favors energy accumulation and regulates reward circuits. We applied a genetic strategy to reconstitute cannabinoid type-1 receptor (CB1) expression at functional levels specifically in CaMKII+ neurons (CaMKII-CB1-RS) and adipocytes (Ati-CB1-RS), respectively, in a CB1 deficient background. Rescued CB1 expression in CaMKII+ neurons, but not in adipocytes, promotes feeding behavior, leading to fasting-induced hyperphagia, increased motivation, and impulsivity to palatable food seeking. In a diet-induced obesity model, CB1 re-expression in CaMKII+ neurons, but not in adipocytes, compared to complete CB1 deficiency, was sufficient to largely restore weight gain, food intake without any effect on glucose intolerance associated with high-fat diet consumption. In a model of glucocorticoid-mediated metabolic syndrome, CaMKII-CB1-RS mice showed all metabolic alterations linked to the human metabolic syndrome except of glucose intolerance. In a binge-eating model mimicking human pathological feeding, CaMKII-CB1-RS mice showed increased seeking and compulsive behavior to palatable food, suggesting crucial roles in foraging and an enhanced susceptibility to addictive-like eating behaviors. Importantly, other contingent behaviors, including increased cognitive flexibility and reduced anxiety-like behaviors, but not depressive-like behaviors, were also observed. To sum up, CB1 in CaMKII+ neurons is instrumental in feeding behavior and energy storage under physiological conditions. The exposure to risk factors (hypercaloric diet, glucocorticoid dysregulation) leads to obesity, metabolic syndrome, binge-eating and food addiction.

Keywords

Endocannabinoid system

cannabinoid type 1 receptor (CB1)

impulsivity

feeding behavior

obesity

metabolic syndrome

food addiction

 

You are what you eat

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