Inducible ablation of dopamine D2 receptors in adult mice impairs locomotion, motor skill learning and leads to severe parkinsonism

Bello, Estefanía P.; Casas-Cordero, Rodrigo; Galiñanes, Gregorio L.; Casey, Emily; Belluscio, Mariano; Rodríguez, Victoria Eli; Noaín, Daniela; Murer, Mario Gustavo; Rubinstein, Marcelo

doi:10.1038/mp.2016.105

Cited by 53 publications

(45 citation statements)

References 62 publications

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“…D 2 R −/− mice demonstrated a significant ( P < .05) but relatively small reduction in spontaneous locomotor activity (Figure A,B), as previously reported in the D 2 R −/− C57BL/6 mouse . This is in contrast with the pronounced akinesia and catalepsy that characterizes pharmacological D 2 R blockade, which may be associated with neuroadaptations counteracting the loss of a D 2 R‐mediated tonic stimulatory effect on psychomotor activity (see Reference ). Likewise, the spontaneous locomotor activity of A 2A R −/− mice was significantly reduced ( P < .01) (Figure A,B), as also previously reported in the A 2A R C57BL/6 mouse .…”

Section: Resultssupporting

confidence: 79%

Behavioral control by striatal adenosine A_2A‐dopamine D₂ receptor heteromers

Taura

Valle-León

Sahlholm

et al. 2017

Genes Brain and Behavior

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G protein-coupled receptors (GPCR) exhibit the ability to form receptor complexes that include molecularly different GPCR (ie, GPCR heteromers), which endow them with singular functional and pharmacological characteristics. The relative expression of GPCR heteromers remains a matter of intense debate. Recent studies support that adenosine A receptors (A R) and dopamine D receptors (D R) predominantly form A R-D R heteromers in the striatum. The aim of the present study was evaluating the behavioral effects of pharmacological manipulation and genetic blockade of A R and D R within the frame of such a predominant striatal heteromeric population. First, in order to avoid possible strain-related differences, a new D R-deficient mouse with the same genetic background (CD-1) than the A R knock-out mouse was generated. Locomotor activity, pre-pulse inhibition (PPI) and drug-induced catalepsy were then evaluated in wild-type, A R and D R knock-out mice, with and without the concomitant administration of either the D R agonist sumanirole or the A R antagonist SCH442416. SCH442416-mediated locomotor effects were demonstrated to be dependent on D R signaling. Similarly, a significant dependence on A R signaling was observed for PPI and for haloperidol-induced catalepsy. The results could be explained by the existence of one main population of striatal postsynaptic A R-D R heteromers, which may constitute a relevant target for the treatment of Parkinson's disease and other neuropsychiatric disorders.

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Section: Resultssupporting

confidence: 79%

Behavioral control by striatal adenosine A_2A‐dopamine D₂ receptor heteromers

Taura

Valle-León

Sahlholm

et al. 2017

Genes Brain and Behavior

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“…However, a compensatory response in dopamine‐deficient mice may result in the supersensitivity of dopamine signaling, in which dopamine‐deficient mice have low levels of dopamine beginning in the neonatal stage. Indeed, compensatory responses that are caused by long‐term low dopamine tone have been reported in several studies other than those that have employed mouse models of dopamine deficiency . However, dopamine‐deficient mouse could be used as a good model to understand phenotypes when dopamine is depleted.…”

Section: Strategy To Investigate Dopamine‐independent Opioid Rewardmentioning

confidence: 99%

Opioid and nondopamine reward circuitry and state‐dependent mechanisms

Fujita

Ide

Ikeda

2018

Annals of the New York Academy of Sciences

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A common notion is that essentially all addictive drugs, including opioids, activate dopaminergic pathways in the brain reward system, and the inappropriate use of such drugs induces drug dependence. However, an opioid reward response is reportedly still observed in several models of dopamine depletion, including in animals that are treated with dopamine blockers, animals that are subjected to dopaminergic neuron lesions, and dopamine-deficient mice. The intracranial self-stimulation response is enhanced by stimulants but reduced by morphine. These findings suggest that dopaminergic neurotransmission may not always be required for opioid reward responses. Previous findings also indicate the possibility that dopamine-independent opioid reward may be observed in opioid-naive states but not in opioid-dependent states. Therefore, a history of opioid use should be considered when evaluating the dopamine dependency of opioid reward.

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“…35 Ablation of dopamine D2 receptor or age-related reduction of the brain dopaminergic activity was involved in motor dysfunction. 36,37 Thus, the present finding that finasteride treatment inhibited brain dopaminergic system, implies finasteride as a potential therapeutic option for neuropsychiatric disorders with hyperactivities of dopaminergic system and androgen.…”

Section: Discussionmentioning

confidence: 72%

“…The doses of finasteride were determined based on the previous reports. [20][21][22] Rats in finasteride group were repeatedly administrated with finasteride dissolved in sesame oil and ethanol (5% v/v) by subcutaneous injection on the back of rats once a day for 14 days from postnatal day [35][36][37][38][39][40][41][42][43][44][45][46][47][48]. Rats in control group were administrated with vehicle (sesame oil) as the same protocol to those in finasteride group.…”

Section: Groupings and Protocolsmentioning

confidence: 99%