Behavioral characteristics of dopamine D5 receptor knockout mice.

Major psychiatric disorders such as attention-deficit/hyperactivity disorder and schizophrenia are often accompanied by elevated impulsivity. However, anti-impulsive drug treatments are still limited. To explore a novel molecular target, we examined the role of dopamine D5 receptors in impulse control using mice that completely lack D5 receptors (D5KO mice). We also measured spontaneous activity and learning/memory ability because these deficits could confound the assessment of impulsivity. We found small but significant effects of D5 receptor knockout on home cage activity only at specific times of the day. In addition, an analysis using the q-learning model revealed that D5KO mice displayed lower behavioral adjustment after impulsive actions. However, our results also showed that baseline impulsive actions and the effects of an anti-impulsive drug in D5KO mice were comparable to those in wild-type littermates. Moreover, unlike previous studies that used other D5 receptor-deficient mouse lines, we did not observe reductions in locomotor activity, working memory deficits, or severe learning deficits in our line of D5KO mice. These findings demonstrate that D5 receptors are dispensable for impulse control. Our results also indicate that time series analysis and detailed analysis of the learning process are necessary to clarify the behavioral functions of D5 receptors.

Serotonin 5-HT2C receptor knockout in mice attenuates fear responses in contextual or cued but not compound context-cue fear conditioning.

Previous findings have proposed that drugs targeting 5-HT2C receptors could be promising candidates in the treatment of trauma- and stress-related disorders. However, the reduction of conditioned freezing observed in 5-HT2C receptor knock-out (KO) mice in previous studies could alternatively be accounted for by increased locomotor activity. To neutralize the confound of individual differences in locomotor activity, we measured a ratio of fear responses during versus before the presentation of a conditioned stimulus previously paired with a footshock (as a fear measure) by utilizing a conditioned licking suppression paradigm. We first confirmed that 5-HT2C receptor gene KO attenuated fear responses to distinct types of single conditioned stimuli (context or tone) independently of locomotor activity. We then assessed the effects of 5-HT2C receptor gene KO on compound fear responses by examining mice that were jointly conditioned to a context and a tone and later re-exposed separately to each. We found that separate re-exposure to individual components of a complex fear memory (i.e., context and tone) failed to elicit contextual fear extinction in both 5-HT2C receptor gene KO and wild-type mice, and also abolished differences between genotypes in tone-cued fear extinction. This study delineates a previously overlooked role of 5-HT2C receptors in conditioned fear responses, and invites caution in the future assessment of molecular targets and candidate therapies for the treatment of PTSD.

Disruption of model-based decision making by silencing of serotonin neurons in the dorsal raphe nucleus.

Adapting to changing environmental conditions requires a prospective inference of future actions and their consequences, a strategy also known as model-based decision making.1-3 In stable environments, extensive experience of actions and their consequences leads to a shift from a model-based to a model-free strategy, whereby behavioral selection is primarily governed by retrospective experiences of positive and negative outcomes. Human and animal studies, where subjects are required to speculate about implicit information and adjust behavioral responses over multiple sessions, point to a role for the central serotonergic system in model-based decision making.4-8 However, to directly test a causal relationship between serotonergic activity and model-based decision making, phase-specific manipulation of serotonergic activity is needed in a one-shot test, where learning by trial and error is neutralized. Moreover, the serotonergic origin responsible for this effect is yet to be determined. Herein, we demonstrate that optogenetic silencing of serotonin neurons in the dorsal raphe nucleus, but not in the median raphe nucleus, disrupts model-based decision making in lithium-induced outcome devaluation tasks.9-11 Our data indicate that the serotonergic behavioral effects are not due to increased locomotor activity, anxiolytic effects, or working memory deficits. Our findings provide insights into the neural mechanisms underlying neural weighting between model-free and model-based strategies.

Different roles of distinct serotonergic pathways in anxiety-like behavior, antidepressant-like, and anti-impulsive effects.

Serotonergic agents have been widely used for treatment of psychiatric disorders, but the therapeutic effects are insufficient and these drugs often induce severe side effects. We need to specify the distinct serotonergic pathways underlying each mental function to overcome these problems. Preclinical studies have demonstrated that the central serotonergic system is involved in several emotional/cognitive functions including anxiety, depression, and impulse control, but it remains unclear whether each function is regulated by a different serotonergic system. We used optogenetic strategy to increase central serotonergic activity in mice and evaluated the behavioral consequences. Pharmacological and genetic tools were used to determine the subtype of 5-HT receptors responsible for the observed effects. We demonstrated that the serotonergic activation in the median raphe nucleus enhanced anxiety-like behavior, the serotonergic activation in the dorsal raphe nucleus exerted antidepressant-like effects, and the serotonergic activation in the median or dorsal raphe nucleus suppressed impulsive action. We also found that different serotonergic terminals, ventral hippocampus, ventral tegmental area/substantia nigra, and subthalamic/parasubthalamic nucleus, are involved in regulating anxiety-like behavior, antidepressant-like, and anti-impulsive effects, respectively. Furthermore, we found, using triple-transgenic mice, that the stimulation of the 5-HT2C receptor is required to evoke anxiety-like behavior, but not to exert anti-impulsive effects. These results suggest the need for pathway-specific treatments and provide important insights that will help the development of more effective and safer therapeutics. This article is part of the special issue entitled 'Serotonin Research: Crossing Scales and Boundaries'.

Blonanserin suppresses impulsive action in rats.

High impulsivity will increase the risk of criminal behavior, drug abuse, and suicide. We chose two drugs by following a strategy recently we proposed for identifying potential anti-impulsivity drugs, and examined the effects on impulsive action in rats by using a 3-choice serial reaction time task. We showed that the administration of blonanserin, an atypical antipsychotic, reduced impulsive actions in a U-shaped manner. 1-(2-Pyriidinyl)-piperazine, an active metabolite of buspirone or tandospirone, also slightly reduced impulsive actions, though it impaired motor functions. These results affirm the validity of our strategy, but require its refinement for developing anti-impulsivity drugs.

Noradrenaline reuptake inhibition increases control of impulsive action by activating D1-like receptors in the infralimbic cortex.

Higher impulsivity is a risk factor for criminal involvement, substance abuse, and suicide. However, only a few drugs are clinically available for the treatment of deficient impulse control. We recently proposed a strategy for identifying potential drugs to treat such disorders by investigating clinically available drugs that increase extracellular dopamine levels in the medial prefrontal cortex and stimulate dopamine D1-like receptors without increasing extracellular dopamine levels in the ventral striatum. To determine whether this strategy is promising, we examined the effects of duloxetine, a serotonin-noradrenaline reuptake inhibitor that might meet these criteria, on impulsive action in adult male Wistar/ST rats using a 3-choice serial reaction time task. The effects of duloxetine on extracellular dopamine levels in the medial prefrontal cortex and nucleus accumbens, a part of the ventral striatum were evaluated using in vivo microdialysis, as the noradrenaline transporter transports dopamine in some brain regions. Our results showed that the administration of duloxetine reduced impulsive actions and increased extracellular dopamine levels in the mPFC but not in the nucleus accumbens. Microinjection of a selective D1-like receptor antagonist into the infralimbic cortex blocked the suppression of impulsive action by duloxetine. In addition, we demonstrated that the microinjection also blocked the suppression of impulsive action by atomoxetine, a noradrenaline reuptake inhibitor and an established anti-impulsive drug. These results support our proposed strategy for identifying and developing anti-impulsivity drugs.

Assessment of impulsivity in adolescent mice: A new training procedure for a 3-choice serial reaction time task.

Immaturity in impulse control among adolescents could result in substance abuse, criminal involvement, and suicide. The brains of adolescents and adults are anatomically, neurophysiologically, and pharmacologically different. Therefore, preclinical models of adolescent impulsivity are required to screen drugs for adolescents and elucidate the neural mechanisms underlying age-related differences in impulsivity. The conventional 3- or 5-choice serial reaction time task, which is a widely used task to assess impulsivity in adult rodents, cannot be used for young mice because of two technical problems: impaired growth caused by food restriction and the very long training duration. To overcome these problems, we altered the conventional training process, optimizing the degree of food restriction for young animals and shortening the training duration. We found that almost all basal performance levels were similar between the novel and conventional procedures. We also confirmed the pharmacological validity of our results: the 5-hydroxytryptamine 2C (5-HT2C) receptor agonist Ro60-0175 (0.6 mg/kg, subcutaneous) reduced the occurrence of premature responses, whereas the 5-HT2C receptor antagonist SB242084 (0.5 mg/kg intraperitoneal) increased their occurrence, consistent with results of previous studies using conventional procedures. Furthermore, we detected age-related differences in impulsivity using the novel procedure: adolescent mice were found to be more impulsive than adult mice, congruent with the results of human studies. Thus, the new procedure enables the assessment of impulsivity in adolescent mice and facilitates a better understanding of the neurophysiological/pharmacological properties of adolescents.

The data set describing cognitive performance after varenicline administration in a 3-choice serial reaction time task in rats.

The data shows attentional function, impulsivity, motivation, motor function, and motor activity in rats treated with varenicline, a stop-smoking aid. The data also shows these parameters in rats treated with varenicline after acute/chronic nicotine administration. Our interpretation and discussion of these data were described in the article "Varenicline Provokes Impulsive Action by Stimulating α4ß2 Nicotinic Acetylcholine Receptors in the Infralimbic Cortex in a Nicotine Exposure Status-Dependent Manner" (Ohmura et al., 2017) [1].

Varenicline provokes impulsive action by stimulating α4ß2 nicotinic acetylcholine receptors in the infralimbic cortex in a nicotine exposure status-dependent manner.

Higher impulsivity is a risk factor for criminal involvement and drug addiction. Because nicotine administration enhances impulsivity, the effects of stop-smoking aids stimulating nicotinic acetylcholine receptors (nAChRs) on impulsivity must be determined in different conditions. Our goals were 1) to confirm the relationship between varenicline, a stop-smoking aid and α4ß2 nAChR partial agonist, and impulsivity, 2) to elucidate the mechanisms underlying the effects of varenicline, 3) to examine whether a low dose of varenicline that does not evoke impulsive action could block the stimulating effects of nicotine on impulsive action, 4) to determine whether the route of administration could modulate the effects of varenicline on impulsive action, and 5) to determine whether the effects of varenicline on impulsivity could be altered by smoking status. We used a 3-choice serial reaction time task to assess impulsivity and other cognitive functions in rats. Our findings are as follows: 1) acute subcutaneous (s.c.) injection of varenicline evoked impulsive action in a dose-dependent manner; 2) the effects of varenicline on impulsivity were blocked by the microinjection of dihydro-ß-erythroidine, a α4ß2 nAChR antagonist, into the infralimbic cortex; 3) the low dose of varenicline did not attenuate the effects of nicotine on impulsive action at all; 4) oral administration of varenicline evoked impulsive action in a similar manner to s.c. injection; and 5) the stimulating effects of varenicline on impulsive action were not observed in rats that received nicotine infusion for 8days or nicotine-abstinent rats after discontinuing infusion. Additionally, we found that oral varenicline administration enhanced attentional function whether nicotine was infused or not. Thus, although varenicline administration could be harmless to heavy smokers or ex-smokers, it could be difficult for non-smokers with respect to impulsivity, whereas it may be beneficial with respect to attentional function.