Glutamatergic and Nonglutamatergic Neurons of the Ventral Tegmental Area Establish Local Synaptic Contacts with Dopaminergic and Nondopaminergic Neurons

103

Amylin acts in the CNS to reduce feeding and body weight. Recently, the ventral tegmental area (VTA), a mesolimbic nucleus important for food intake and reward, was identified as a site-of-action mediating the anorectic effects of amylin. However, the long-term physiological relevance and mechanisms mediating the intake-suppressive effects of VTA amylin receptor (AmyR) activation are unknown. Data show that the core component of the AmyR, the calcitonin receptor (CTR), is expressed on VTA dopamine (DA) neurons and that activation of VTA AmyRs reduces phasic DA in the nucleus accumbens core (NAcC). Suppression in NAcC DA mediates VTA amylin-induced hypophagia, as combined NAcC D1/D2 receptor agonists block the intake-suppressive effects of VTA AmyR activation. Knockdown of VTA CTR via adeno-associated virus short hairpin RNA resulted in hyperphagia and exacerbated body weight gain in rats maintained on high-fat diet. Collectively, these findings show that VTA AmyR signaling controls energy balance by modulating mesolimbic DA signaling.

Section: Discussionmentioning

confidence: 99%

Amylin Modulates the Mesolimbic Dopamine System to Control Energy Balance

Mietlicki‐Baase

Reiner

Cone

et al. 2014

103

“…Among these are changes in excitatory transmission to the ventral tegmental area (VTA; Saal et al, 2003), origin of the mesocorticolimbic dopamine system, and a critical link between reward-predictive cues and brain reward circuitry (You et al, 2007). This system is responsive not only to a variety of glutamatergic inputs from local (Dobi et al, 2010) and distal (Geisler et al, 2007) neuronal sources, but also to a number of state variables mediated by blood-borne factors including leptin (Figlewicz et al, 2003;Krugel et al, 2003;Hommel et al, 2006;Liu et al, 2011;Thompson and Borgland, 2013). Leptin is an endogenous inhibitor of food reward (Figlewicz et al, 2007;Domingos et al, 2011) that has both direct (Fulton et al, 2006a;Krugel et al, 2003;Leinninger et al, 2009;Davis et al, 2011;Domingos et al, 2011) and indirect (Leinninger et al, 2009) effects on brain reward function and that is depressed in heroin addicts (Housová et al, 2005) and fluctuates abnormally during craving for alcohol (Kiefer et al, 2005) or nicotine (al 'Absi et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Reciprocal Inhibitory Interactions Between the Reward-Related Effects of Leptin and Cocaine

You

Wang

Liu

et al. 2015

Cocaine is habit-forming because of its ability to enhance dopaminergic neurotransmission in the forebrain. In addition to neuronal inputs, forebrain dopamine circuits are modulated by hormonal influences; one of these is leptin, an adipose-derived hormone that attenuates the rewarding effects of food-and hunger-associated brain stimulation reward. Here we report reciprocal inhibition between the rewardrelated effects of leptin and the reward-related effects of cocaine in rats. First, we report that cocaine and the expectancy of cocaine each depresses plasma leptin levels. Second, we report that exogenous leptin, given systemically or directly into the ventral tegmental area, attenuates the ability of cocaine to elevate dopamine levels in the nucleus accumbens, the ability of cocaine to establish a conditioned place preference, and the ability of cocaine-predictive stimuli to prolong responding in extinction of cocaine-seeking. Thus, whereas leptin represents an endogenous antagonist of the habit-forming and habit-sustaining effects of cocaine, this antagonism is attenuated by cocaine and comes to be attenuated by the expectancy of cocaine.

“…The switch from tonic to phasic firing is controlled by glutamate signaling at its ionotropic receptors. Activation of glutamatergic afferents (Geisler et al, 2007;Grace and Bunney, 1984;Omelchenko and Sesack, 2009), and possibly VM VGluT2-containing interneurons (Dobi et al, 2010), control the transition from peacemaker tonic to phasic burst firing of DA neurons. In contrast, blockade of VM ionotropic glutamate receptors disrupts burst firing (Charlety et al, 1991;Chergui et al, 1993).…”

Section: Introductionmentioning

confidence: 99%

Reduction in Ventral Midbrain NMDA Receptors Reveals Two Opposite Modulatory Roles for Glutamate on Reward

Hernández

Khodami-Pour

Lévesque

et al. 2015

Glutamate is a major component of the reward circuitry and recent clinical studies suggest that new molecules that would target glutamate neurotransmission are most likely to constitute more effective medications for mood disorders. It is well known that activation of N-methyl-D-aspartate glutamate receptors (NMDARs) initiates dopamine burst firing, a mode associated with reward signaling; but NMDARs also contribute to the maintenance of an inhibitory drive to dopamine neurons. Such opposite modulatory functions imply that different subtypes of NMDARs are expressed on different ventral midbrain (VM) neurons and/or afferent inputs to dopamine neurons. By using the small interfering RNA (siRNA) technique, we studied the effects of VM downregulation of NMDAR subunits GluN1, GluN2A, and GluN2D on reward induced by dorsal raphe electrical stimulation. Reward thresholds were measured before and 24 h after each of three consecutive daily bilateral microinjections of siRNA for the targeted receptor subunit(s) or non-active RNA sequence. After the last measurement, reward thresholds were reassessed following a bilateral microinjection of the preferred GluN2A-NMDA antagonist, (2R,4S)-4-(3-Phosphopropyl)-2-piperidinecarboxylic acid (PPPA). Western-blot analysis showed that siRNAs reduced GluN1-and GluN2A-containing receptors whereas behavioral tests showed that only a reduction in GluN1 produced reward attenuation. Despite NMDAR reduction, reward-enhancing effect of PPPA remained unchanged. We conclude that VM glutamate relays the reward signal initiated by dorsal raphe electrical stimulation by acting on NMDARs devoid of GluN2A/2D subunits and exerts an inhibition on this reward signal by acting on GluN2A-containing NMDARs most likely located on afferent terminals.