Divergent circuitry underlying food reward and intake effects of ghrelin: Dopaminergic VTA-accumbens projection mediates ghrelin's effect on food reward but not food intake

Obesity has reached global epidemic proportions and creating an urgent need to understand mechanisms underlying excessive and uncontrolled food intake. Ghrelin, the only known circulating orexigenic hormone, potently increases food reward behavior. The neurochemical circuitry that links ghrelin to t...

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Bibliographic Details
Published in:Neuropharmacology 2013-10, Vol.73, p.274-283
Main Authors: Skibicka, Karolina P., Shirazi, Rozita H., Rabasa-Papio, Cristina, Alvarez-Crespo, Mayte, Neuber, Corinna, Vogel, Heike, Dickson, Suzanne L.
Format: Article
Language:English
Subjects:
Animals
appetite
Benzazepines - administration & dosage
Benzazepines - pharmacology
Catechol O-Methyltransferase - biosynthesis
Conditioning, Operant
Dopamine
Eating - drug effects
Eating - physiology
Food intake
Food motivation
Fysiologi
Gene Expression - drug effects
Ghrelin
Ghrelin - administration & dosage
Ghrelin - physiology
Male
Microinjections
Monoamine Oxidase - biosynthesis
Neural Pathways - drug effects
Neural Pathways - physiology
Neurosciences
Neurovetenskaper
Nucleus Accumbens - drug effects
Nucleus Accumbens - metabolism
Nucleus Accumbens - physiology
Operant conditioning
Overeating
Physiology
Rats
Receptors, Dopamine - biosynthesis
Reward
Salicylamides - administration & dosage
Salicylamides - pharmacology
Ventral Tegmental Area - drug effects
Ventral Tegmental Area - physiology
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Summary:Obesity has reached global epidemic proportions and creating an urgent need to understand mechanisms underlying excessive and uncontrolled food intake. Ghrelin, the only known circulating orexigenic hormone, potently increases food reward behavior. The neurochemical circuitry that links ghrelin to the mesolimbic reward system and to the increased food reward behavior remains unclear. Here we examine whether VTA-NAc dopaminergic signaling is required for the effects of ghrelin on food reward and intake. In addition, we examine the possibility of endogenous ghrelin acting on the VTA-NAc dopamine neurons. A D1-like or a D2 receptor antagonist was injected into the NAc in combination with ghrelin microinjection into the VTA to investigate whether this blockade attenuates ghrelin-induced food reward behavior. VTA injections of ghrelin produced a significant increase in food motivation/reward behavior, as measured by sucrose-induced progressive ratio operant conditioning, and chow intake. Pretreatment with either a D1-like or D2 receptor antagonist into the NAc, completely blocked the reward effect of ghrelin, leaving chow intake intact. We also found that this circuit is potentially relevant for the effects of endogenously released ghrelin as both antagonists reduced fasting (a state of high circulating levels of ghrelin) elevated sucrose-motivated behavior but not chow hyperphagia. Taken together our data identify the VTA to NAc dopaminergic projections, along with D1-like and D2 receptors in the NAc, as essential elements of the ghrelin responsive circuits controlling food reward behavior. Interestingly results also suggest that food reward behavior and simple intake of chow are controlled by divergent circuitry, where NAc dopamine plays an important role in food reward but not in food intake. •Intra-VTA ghrelin engages accumbal D1 and D2 receptors.•Food deprivation elevates food reward behavior via accumbal D1 and D2 receptors.•Food intake is unaffected by accumbal D1 and D2 manipulations.•Food reward behavior and simple chow intake are controlled by divergent circuitry.•NAc dopamine plays an important role in food reward but not in food intake.
ISSN:0028-3908
1873-7064
1873-7064
DOI:10.1016/j.neuropharm.2013.06.004