Mu and delta opioid receptors oppositely regulate motor impulsivity in the signaled nose poke task

Impulsivity is a primary feature of many psychiatric disorders, most notably attention deficit hyperactivity disorder and drug addiction. Impulsivity includes a number of processes such as the inability to delay gratification, the inability to withhold a motor response, or acting before all of the r...

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Veröffentlicht in:	PloS one 2009-02, Vol.4 (2), p.e4410-e4410
Hauptverfasser:	Olmstead, Mary C, Ouagazzal, Abdel-Mouttalib, Kieffer, Brigitte L
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Associative learning Attention deficit hyperactivity disorder Behavior, Animal - physiology Biochemistry, Molecular Biology Brain research Cannabinoids Conditioning Conditioning (Psychology) Cues Deactivation Disorders Disruptive, Impulse Control, and Conduct Disorders - genetics Disruptive, Impulse Control, and Conduct Disorders - metabolism Dopamine Drug abuse Drug addiction Ethanol Genotypes House mouse Impulsive behavior Inactivation Information processing Kinases Learning Life Sciences Mental disorders Mental Health/Neuropsychiatric Disorders Mental Health/Substance Abuse Mice Mice, Inbred C57BL Mice, Knockout Neuroscience/Behavioral Neuroscience Neuroscience/Experimental Psychology Norepinephrine Nose Opioid receptors (type delta) Opioid receptors (type mu) Oprd1 gene Receptors Receptors, Opioid, delta - genetics Receptors, Opioid, delta - metabolism Receptors, Opioid, mu - genetics Receptors, Opioid, mu - metabolism Reinforcement Reward Rodents Serotonin Sucrose Sugar
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description	Impulsivity is a primary feature of many psychiatric disorders, most notably attention deficit hyperactivity disorder and drug addiction. Impulsivity includes a number of processes such as the inability to delay gratification, the inability to withhold a motor response, or acting before all of the relevant information is available. These processes are mediated by neural systems that include dopamine, serotonin, norepinephrine, glutamate and cannabinoids. We examine, for the first time, the role of opioid systems in impulsivity by testing whether inactivation of the mu- (Oprm1) or delta- (Oprd1) opioid receptor gene alters motor impulsivity in mice. Wild-type and knockout mice were examined on either a pure C57BL6/J (BL6) or a hybrid 50% C57Bl/6J-50% 129Sv/pas (HYB) background. Mice were trained to respond for sucrose in a signaled nose poke task that provides independent measures of associative learning (responses to the reward-paired cue) and motor impulsivity (premature responses). Oprm1 knockout mice displayed a remarkable decrease in motor impulsivity. This was observed on the two genetic backgrounds and did not result from impaired associative learning, as responses to the cue signaling reward did not differ across genotypes. Furthermore, mutant mice were insensitive to the effects of ethanol, which increased disinhibition and decreased conditioned responding in wild-type mice. In sharp contrast, mice lacking the Oprd1 gene were more impulsive than controls. Again, mutant animals showed no deficit in associative learning. Ethanol completely disrupted performance in these animals. Together, our results suggest that mu-opioid receptors enhance, whereas delta-opioid receptors inhibit, motor impulsivity. This reveals an unanticipated contribution of endogenous opioid receptor activity to disinhibition. In a broader context, these data suggest that alterations in mu- or delta-opioid receptor function may contribute to impulse control disorders.
doi_str_mv	10.1371/journal.pone.0004410
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Impulsivity includes a number of processes such as the inability to delay gratification, the inability to withhold a motor response, or acting before all of the relevant information is available. These processes are mediated by neural systems that include dopamine, serotonin, norepinephrine, glutamate and cannabinoids. We examine, for the first time, the role of opioid systems in impulsivity by testing whether inactivation of the mu- (Oprm1) or delta- (Oprd1) opioid receptor gene alters motor impulsivity in mice. Wild-type and knockout mice were examined on either a pure C57BL6/J (BL6) or a hybrid 50% C57Bl/6J-50% 129Sv/pas (HYB) background. Mice were trained to respond for sucrose in a signaled nose poke task that provides independent measures of associative learning (responses to the reward-paired cue) and motor impulsivity (premature responses). Oprm1 knockout mice displayed a remarkable decrease in motor impulsivity. This was observed on the two genetic backgrounds and did not result from impaired associative learning, as responses to the cue signaling reward did not differ across genotypes. Furthermore, mutant mice were insensitive to the effects of ethanol, which increased disinhibition and decreased conditioned responding in wild-type mice. In sharp contrast, mice lacking the Oprd1 gene were more impulsive than controls. Again, mutant animals showed no deficit in associative learning. Ethanol completely disrupted performance in these animals. Together, our results suggest that mu-opioid receptors enhance, whereas delta-opioid receptors inhibit, motor impulsivity. This reveals an unanticipated contribution of endogenous opioid receptor activity to disinhibition. 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Impulsivity includes a number of processes such as the inability to delay gratification, the inability to withhold a motor response, or acting before all of the relevant information is available. These processes are mediated by neural systems that include dopamine, serotonin, norepinephrine, glutamate and cannabinoids. We examine, for the first time, the role of opioid systems in impulsivity by testing whether inactivation of the mu- (Oprm1) or delta- (Oprd1) opioid receptor gene alters motor impulsivity in mice. Wild-type and knockout mice were examined on either a pure C57BL6/J (BL6) or a hybrid 50% C57Bl/6J-50% 129Sv/pas (HYB) background. Mice were trained to respond for sucrose in a signaled nose poke task that provides independent measures of associative learning (responses to the reward-paired cue) and motor impulsivity (premature responses). Oprm1 knockout mice displayed a remarkable decrease in motor impulsivity. This was observed on the two genetic backgrounds and did not result from impaired associative learning, as responses to the cue signaling reward did not differ across genotypes. Furthermore, mutant mice were insensitive to the effects of ethanol, which increased disinhibition and decreased conditioned responding in wild-type mice. In sharp contrast, mice lacking the Oprd1 gene were more impulsive than controls. Again, mutant animals showed no deficit in associative learning. Ethanol completely disrupted performance in these animals. Together, our results suggest that mu-opioid receptors enhance, whereas delta-opioid receptors inhibit, motor impulsivity. This reveals an unanticipated contribution of endogenous opioid receptor activity to disinhibition. In a broader context, these data suggest that alterations in mu- or delta-opioid receptor function may contribute to impulse control disorders.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>19198656</pmid><doi>10.1371/journal.pone.0004410</doi><tpages>e4410</tpages><oa>free_for_read</oa></addata></record>
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source	MEDLINE; DOAJ Directory of Open Access Journals; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; Public Library of Science (PLoS); PubMed Central; Free Full-Text Journals in Chemistry
subjects	Animals Associative learning Attention deficit hyperactivity disorder Behavior, Animal - physiology Biochemistry, Molecular Biology Brain research Cannabinoids Conditioning Conditioning (Psychology) Cues Deactivation Disorders Disruptive, Impulse Control, and Conduct Disorders - genetics Disruptive, Impulse Control, and Conduct Disorders - metabolism Dopamine Drug abuse Drug addiction Ethanol Genotypes House mouse Impulsive behavior Inactivation Information processing Kinases Learning Life Sciences Mental disorders Mental Health/Neuropsychiatric Disorders Mental Health/Substance Abuse Mice Mice, Inbred C57BL Mice, Knockout Neuroscience/Behavioral Neuroscience Neuroscience/Experimental Psychology Norepinephrine Nose Opioid receptors (type delta) Opioid receptors (type mu) Oprd1 gene Receptors Receptors, Opioid, delta - genetics Receptors, Opioid, delta - metabolism Receptors, Opioid, mu - genetics Receptors, Opioid, mu - metabolism Reinforcement Reward Rodents Serotonin Sucrose Sugar
title	Mu and delta opioid receptors oppositely regulate motor impulsivity in the signaled nose poke task
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