Identification of a Dopamine Receptor-Mediated Opiate Reward Memory Switch in the Basolateral Amygdala–Nucleus Accumbens Circuit

Lintas, Alessandra; Chi, Ning; Lauzon, Nicole M.; Bishop, Stephanie F.; Gholizadeh, Saber; Sun, Ning; Tan, Huibing; Laviolette, Steven R.

doi:10.1523/jneurosci.1781-11.2011

Cited by 76 publications

(85 citation statements)

References 31 publications

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“…1a). The BLA-shell projection has also been implicated in morphine reward (Lintas et al 2011). In this study, dopamine receptor antagonists in the BLAwere capable of altering neurophysiological responses of shell neurons to morphine (Lintas et al 2011).…”

Section: Amygdala Outputsmentioning

confidence: 67%

“…The BLA-shell projection has also been implicated in morphine reward (Lintas et al 2011). In this study, dopamine receptor antagonists in the BLAwere capable of altering neurophysiological responses of shell neurons to morphine (Lintas et al 2011). The BLA potentiates shell neuronal activity in part via stimulation of NMDA-Rs (Floresco et al 1998;Floresco et al 2001).…”

Section: Amygdala Outputsmentioning

confidence: 69%

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Glutamate Mechanisms Underlying Opiate Memories

Peters

Vries

2012

Cold Spring Harbor Perspectives in Medicine

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Correspondence: tj.devries@vumc.nlAs the major excitatory neurotransmitter in the brain, glutamate plays an undisputable integral role in opiate addiction. This relates, in part, to the fact that addiction is a disorder of learning and memory, and glutamate is required for most types of memory formation. As opiate addiction develops, the addict becomes conditioned to engage in addictive behaviors, and these behaviors can be triggered by opiate-associated cues during abstinence, resulting in relapse. Some medications for opiate addiction exert their therapeutic effects at glutamate receptors, especially the NMDA receptor. Understanding the neural circuits controlling opiate addiction, and the locus of glutamate's actions within these circuits, will help guide the development of targeted pharmacotherapeutics for relapse.

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Section: Amygdala Outputsmentioning

confidence: 67%

Section: Amygdala Outputsmentioning

confidence: 69%

Glutamate Mechanisms Underlying Opiate Memories

Peters

Vries

2012

Cold Spring Harbor Perspectives in Medicine

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“…Furthermore, animal studies have shown that D1R antagonism blocks nicotine motivation in nondependent mice (36). A recent study showed that blockade of D1R but not D2R transmission prevented acquisition of opiate-reward memory in nondependent rats, and D2R but not D1R blockade prevented opiate-reward encoding in dependent and withdrawn rats (37). However, previous studies suggest that both acute nicotine and opiate reward are mediated by the non-DAergic brainstem tegmental pedunculopontine (TPP) nucleus (9,12,21), and thus must involve separate cells in the TPP that are thought to mediate burst-firing of VTA DA neurons (5, 14); burst-firing that we show here is involved in the response to acute nicotine.…”

Section: Discussionmentioning

confidence: 99%

Phasic D1 and tonic D2 dopamine receptor signaling double dissociate the motivational effects of acute nicotine and chronic nicotine withdrawal

Grieder

George

Tan

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Nicotine, the main psychoactive ingredient of tobacco smoke, induces negative motivational symptoms during withdrawal that contribute to relapse in dependent individuals. The neurobiological mechanisms underlying how the brain signals nicotine withdrawal remain poorly understood. Using electrophysiological, genetic, pharmacological, and behavioral methods, we demonstrate that tonic but not phasic activity is reduced during nicotine withdrawal in ventral tegmental area dopamine (DA) neurons, and that this pattern of signaling acts through DA D2 and adenosine A2A, but not DA D1, receptors. Selective blockade of phasic DA activity prevents the expression of conditioned place aversions to a single injection of nicotine in nondependent mice, but not to withdrawal from chronic nicotine in dependent mice, suggesting a shift from phasic to tonic dopaminergic mediation of the conditioned motivational response in nicotine dependent and withdrawn animals. Either increasing or decreasing activity at D2 or A2A receptors prevents the aversive motivational response to withdrawal from chronic nicotine, but not to acute nicotine. Modification of D1 receptor activity prevents the aversive response to acute nicotine, but not to nicotine withdrawal. This double dissociation demonstrates that the specific pattern of tonic DA activity at D2 receptors is a key mechanism in signaling the motivational effects experienced during nicotine withdrawal, and may represent a unique target for therapeutic treatments for nicotine addiction.negative reinforcement | place conditioning | burst firing | population activity | osmotic minipumps T obacco addiction is the leading avoidable cause of disease and premature death in North America (1). Of more than 3,000 chemicals present in tobacco smoke, nicotine is the main psychoactive ingredient responsible for tobacco addiction (2). Withdrawal from chronic nicotine is hypothesized to represent a powerful source of negative reinforcement that drives relapse and compulsive tobacco use (3); therefore, understanding the neurobiological substrates mediating the motivational properties of nicotine withdrawal is an important step in the development of new treatments for nicotine addiction. Current hypotheses suggest that nicotine withdrawal leads to a decrease in dopamine (DA) signaling in the brain (4) and that DA neurons exhibit two activity states, phasic and tonic, that mediate separate aspects of behavior (5-7).Nicotine acutely produces both aversive and positive motivational effects (8, 9) by activating the mesolimbic DA system (7, 10) as well as non-DAergic neural substrates (11,12). DA neurons exhibit burst-and population-firing activity that leads to phasic and tonic DA release, respectively (5-7). Burst-firing produces a fast and large phasic DA release that mainly activates postsynaptic DA D1 receptors (D1Rs), and population-firing produces a slower tonic DA release that mainly activates the higher affinity (13) DA D2 receptors (D2Rs) (5, 6). The phasic and tonic activities of DA neurons are though...

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“…113,114 In particular, the pyramidal neurons of the basolateral amygdala receive input from the VTA. In saline-treated amygdala slices, DA reduced the amplitude of excitatory postsynaptic currents (EPSCs) by inhibiting α-amino-3-hydroxy-5-mehtyl-4-isoxazoleproprionic acid (AMPA) receptors.…”

Section: Molecular Changes In the Amygdalamentioning

confidence: 99%