Ion channel control of electrical activity in dopaminergic midbrain neurones

Wolfart, Jakob

January 2002

No description available.

612

Dopamine release

Behavioural and pharmacological properties of barakol : a natural anxiolytic

Thongsaard, Watchareewan

January 1997

No description available.

615.1

Anxiety; Dopamine release

Neurotensin : an ontogenic study

Moss, Sharon Helen

January 1996

No description available.

572

Neurotransmitters; Dopamine release

The role of the μ-opioid receptors in the mechanism of ethanol-stimulated mesolimbic dopamine release

Job, Martin Olufemi

05 February 2010

The goal of this dissertation was to investigate the role of μ-opioid receptors in the mechanism of ethanol-stimulated dopamine release in the nucleus accumbens shell (NAcS) of rats. The underlying hypothesis is that blockade of the μ-opioid receptors leads to an attenuation of ethanol-stimulated mesolimbic dopamine release. We prepared ethanol-naïve male Long Evans rats (n = 95) for intravenous (i.v.) drug administration and in vivo microdialysis (in awake, freely moving animals), and analyzed our samples using HPLC and GC for dopamine and ethanol detection, respectively. In one set of experiments, we looked at the effects of naltrexone, a non-selective opioid antagonist, on ethanol-stimulated mesolimbic dopamine release. First of all, we checked to see if naltrexone affected basal dopamine levels in the NAcS. Thereafter, we looked for a dose of naltrexone (i.v.) that was effective in suppressing the release of dopamine in the NAcS evoked by morphine (1 mg/kg, i.v.). Subsequently, we checked to see if doses of naltrexone that inhibited morphine-evoked dopamine were also effective in attenuating dopamine release due to ethanol (1g/kg, 10% w/v, i.v.). To do this, we pretreated rats with naltrexone doses, followed 20 min later by morphine, ethanol or saline (all drugs were administered i.v.). In another set of experiments, we looked at the effect of β-funaltrexamine, a selective μ-opioid antagonist, on ethanol-stimulated dopamine release in the NAcS. Similarly to the previous set of experiments, we looked for a dose of β-funaltrexamine (s.c.) that was effective in suppressing the release of dopamine the NAcS evoked by morphine (1 mg/kg, i.v.), and checked to see if this dose of β-funaltrexamine was also effective in attenuating ethanol-stimulated dopamine release in the NAcS. For the β- funaltrexamine experiments, rats were pretreated with β-funaltrexamine (s.c.) 20- 25 h before i.v. infusions of saline, morphine and ethanol. Morphine increased dopamine release in the NAcS. Naltrexone and β- funaltrexamine significantly attenuated morphine-evoked dopamine release. Also, ethanol increased dopamine release in the NAcS. Naltrexone and β- funaltrexamine, at doses effective in attenuating morphine-evoked dopamine release, suppressed the prolongation, but not the initiation of dopamine release in the NAcS due to ethanol. Naltrexone and β-funaltrexamine did not affect the peak concentration and clearance of ethanol in the brain. The conclusion of this study is that the μ-opioid receptors are involved in a delayed component of ethanol-stimulated dopamine release in the NAcS in ethanol-naïve rats. This is the first study to show that the ethanol-stimulated dopamine response consists of a delayed μ-opioid mechanism. / text

Opioid receptors

Dopamine release

Nucleus accumbens shell

Alcohol Modulation of Dopamine Release

Schilaty, Nathan Dan

01 December 2014

The mesolimbic dopamine (DA) system projects from the ventral tegmental area (VTA) to structures associated with the limbic system, primarily the nucleus accumbens (NAc). This system has been implicated in the rewarding effects of drugs of abuse. Many drugs of abuse act in the VTA, the NAc, or both. Dopamine neurons in the VTA that project to the NAc, and the GABA neurons that inhibit DA neurons locally in the VTA or project to the NAc, play an important role in mediating addiction to various drugs of abuse, in particular alcohol. There is a growing body of evidence of co-dependence of nicotine and ethanol drug abuse. Given this evidence, it is possible that both ethanol and nicotine target similar receptors in the NAc. The GABA-A and GABA-B receptors have also been implicated in the modulation of ethanol's reinforcing properties (Anstrom, Cromwell, Markowski, & Woodward, 2003; Besheer, Lepoutre, & Hodge, 2004; Colombo et al., 2000; Moore & Boehm, 2009; Stromberg, 2004; Walker & Koob, 2007). Thus, there is a growing literature suggesting that GABA receptors are implicated in ethanol reward. In these studies, we evaluated the possibility of co-dependence of nicotine and ethanol by activity on a similar receptor in the NAc. In addition, we evaluated the role of GABA modulation of DA release, in particular GABA-A receptors and GABA-B receptors, in modulating DA release in the NAc with acute ethanol exposure. The rationale for this study was predicated on the belief that advancement in the understanding of the brain mechanisms underlying the recreational use and abuse potential of alcohol will pave the way for more effective treatment strategies that could reverse alcohol dependence and co-dependence and save lives and resources throughout the world.

dopamine release

ethanol

GABA

nicotine

nucleus accumbens

voltammetry

Cell and Developmental Biology

Physiology

Role for Reactive Oxygen Species in Methamphetamine Modulation of Dopamine Release in the Striatum

Hedges, David Matthew

01 May 2016

Methamphetamine (METH) is a highly addictive substance that is highly prevalent in today’s society, with over 1 in 20 adults over 26 having taken it at least once. While it is known that METH, a common psychostimulant, acts on both the mesolimbic dopamine (DA) and nigrostriatal DA systems by affecting proteins involved in DA reuptake and vesicular packaging, the specific mechanism of what is known as METH neurotoxicity remains obscure, but has been shown to involve oxidative stress. Studies have shown that reactive oxygen species act on the same proteins that METH affects. Oxidative species have also been known to catalyze the formation of melanins in dopaminergic cells. We explore this link more fully here. In an in vitro system, oxidative species (including Fe3+, an inorganic catalyst for oxidative stress), enhance the rate of melanization of DA. Methamphetamine increased oxidative stress in an in vivo model. Additionally, METH enhanced phasic (stimulated) DA release and caused an electrically-independent efflux of DA. Lidocaine abolished phasic DA release, but did not affect METH-induced DA efflux, indicating action-potential dependent and independent mechanisms behind METH’s effects. The sigma-1 receptor antagonist BD 1063 significantly attenuated METH’s effect on DA release. Depletion of intracellular calcium (Ca2+) reserves also attenuated METH-enhancement of DA release. We investigated the role of oxidative species in METH-induced DA efflux. Reduced glutathione (the substrate for glutathione peroxidase) and 4-hydroxy-TEMPOL (a superoxide dismutase mimetic) blocked METH’s effect on DA release, suggesting that a reactive oxygen species (ROS), most likely superoxide, is necessary for METH-induced DA efflux. Finally, oxidative stress as well as acute METH impairs the vesicular monoamine transporter 2 (VMAT2) by S-glutathionylation modification of Cys-488, highlighting VMAT2 as a likely regulator of METH’s effects on electrically independent DA release. These findings help outline a model in which METH induces DA release in the NAc through a signaling cascade involving the sigma receptor and ROS signaling molecules.

dopamine release

methamphetamine

reactive oxygen species

neuromelanin

nucleus accumbens

voltammetry

Chemistry