Mesolimbic pathway

Summary

The mesolimbic pathway, sometimes referred to as the reward pathway, is a dopaminergic pathway in the brain. The pathway connects the ventral tegmental area in the midbrain to the ventral striatum of the basal ganglia in the forebrain. The ventral striatum includes the nucleus accumbens and the olfactory tubercle. The release of dopamine from the mesolimbic pathway into the nucleus accumbens regulates incentive salience (e.g. motivation and desire for rewarding stimuli) and facilitates reinforcement and reward-related motor function learning; it may also play a role in the subjective perception of pleasure. The dysregulation of the mesolimbic pathway and its output neurons in the nucleus accumbens plays a significant role in the development and maintenance of an addiction. Anatomy The mesolimbic pathway is a collection of dopaminergic (i.e., dopamine-releasing) neurons that project from th

Official source

https://en.wikipedia.org/wiki/Mesolimbic_pathway

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Latency to Reward Predicts Social Dominance in Rats: A Causal Role for the Dopaminergic Mesolimbic System

Sonia Abad Florensa, Simone Astori, Laura Lozano Montes, Maria del Carmen Sandi Perez, Ioannis Zalachoras

Reward signals encoded in the mesolimbic dopaminergic system guide approach/seeking behaviors to all varieties of life-supporting stimuli (rewards). Differences in dopamine (DA) levels have been found between dominant and submissive animals. However, it is still unclear whether these differences arise as a consequence of the rewarding nature of the acquisition of a dominant rank, or whether they preexist and favor dominance by promoting reward-seeking behavior. Given that acquisition of a social rank determines animals’ priority access to resources, we hypothesized that differences in reward-seeking behavior might affect hierarchy establishment and that modulation of the dopaminergic system could affect the outcome of a social competition. We characterized reward-seeking behaviors based on rats’ latency to get a palatable-reward when given temporary access to it. Subsequently, rats exhibiting short (SL) and long (LL) latency to get the rewards cohabitated for more than 2 weeks, in order to establish a stable hierarchy. We found that SL animals exhibited dominant behavior consistently in social competition tests [for palatable-rewards and two water competition tests (WCTs)] after hierarchy was established, indicating that individual latency to rewards predicted dominance. Moreover, because SL animals showed higher mesolimbic levels of DA than LL rats, we tested whether stimulation of mesolimbic DA neurons could affect the outcome of a social competition. Indeed, a combination of optical stimulation of mesolimbic DA neurons during individual training and during a social competition test for palatable rewards resulted in improved performance on this test.

2019

Parkinson disease (PD) is a common neurodegenerative disorder characterized by the progressive loss of dopaminergic neurons in the substantia nigra pars compacta. The resulting failure of the nigrostriatal pathway leads to profound dopamine deficiency, causing bradykinesia, tremor, rigidity and postural imbalance. The current therapeutic options for this disabling disorder remain symptomatic and are devoid of any impact on the neurodegeneration process per se. The development of neuroprotective and regenerative strategies constitute therefore an important challenge, in order to halt and possibly reverse the loss of the nigrostriatal pathway in PD. In the present study, we have investigated two different approaches to protect or restore the nigrostriatal dopaminergic system in rodent models of PD. In the first part, we examined the potential of a spontaneous dominant mutation in mice called slow Wallerian degeneration (Wlds) to confer protection of the dopaminergic pathway against the catecholaminergic toxin 6-hydroxydopamine (6-OHDA). Interestingly, the Wlds fusion protein proved capable to provide functional preservation of the nigrostriatal dopaminergic terminals. The observed Wlds-mediated protection of dopaminergic axons might help to further elucidate the mechanisms leading to the loss of dopamine axons in PD and conduct to the development of new therapeutic modalities for this disorder. In the second approach, we assessed the protective and regenerative potential of the neurotrophic factor glial cell line-derived neurotrophic factor (GDNF) delivered via capsules in a rat model of PD. GDNF delivery by encapsulated cells resulted in regeneration of dopaminergic fibers and behavioral improvement in a bilateral 6-OHDA model in the rat. Importantly, GDNF withdrawal did not affect the morphological and behavioral effects in our model. The sustainability of the striatal dopaminergic reinnervation and behavioral performances following GDNF washout has important implications. It suggests that GDNF needs to be delivered only transiently to allow prolonged functional regenerative effect, rendering the retrievable capsules attractive to achieve this purpose in PD patients. The promising potential of GDNF to protect and regenerate the nigrostriatal pathway has been hampered by several recent studies showing that long-term GDNF overexpression in the intact nigrostriatal pathway induces a downregulation of tyrosine hydroxylase (TH), the rate-limiting enzyme in the synthesis of dopamine. In the last part of this work, we aimed therefore at investigating the effect of GDNF on other enzymes of dopamine biosynthesis, using a lentiviral vector-mediated gene transfer technique, in order to overexpress GDNF in rat striatum. We showed that in addition to TH downregulation, long-term GDNF overexpression results in tetrahydrobiopterin upregulation, and importantly in dopamine decrease in the intact striatum of rats. In a clinical perspective, dose and treatment duration of the trophic factor will thus have to be established and optimized with the aim of achieving beneficial neuroprotective effects while circumventing undesirable pharmacologic effects on dopamine biosynthesis. The discovery of new protective molecules such as the Wlds protein, as well as a better understanding of cellular effects of the promising neurotrophic factor GDNF might lead to the establishment of neuroprotective and neuroregenerative strategies for PD in the close future.

EPFL2005

The impact of anxiety and reward-seeking traits on social competition and the role of the mesolimbic dopaminergic system

Laura Lozano Montes

Social hierarchies are established across a range of different taxa in the animal kingdom. Given that hierarchy inequalities are highly present in nowadays society and the health problems that low rank individuals suffer from this, it is surprising that not much is known about the underlying neurobiological mechanisms that predispose an individual to become dominant or submissive. We aimed to have a better understanding of personality-related factors (such as anxiety and reward-seeking behaviors) and underlying brain mechanisms that predispose rats to become dominant. We aimed to study the neurobiological mechanisms involved in the modulation of dominance by anxiety. Peripheral injection of anxiolytic drugs has been shown to modulate the dopaminergic mesolimbic system by acting in the GABAergic neurons on the ventral tegmental area (VTA). Our studies specifically targeted GABAergic receptors within the VTA modulating both anxiety and dominance. However, the activation of GABAergic receptors in the nucleus accumbens (NAc) affected dominance but had no effect on anxiety. Furthermore, we found that the NAc is required for the effects of the anxiolytic diazepam on the establishment of social dominance. We assessed potential differences on the accumbal dopaminergic system in relation to anxiety. To this end, we assessed catecholamines levels by high performance liquid chromatography (HPLC) and confirmed the existence of differences in accumbal dopamine content between high and low anxious rats. Subsequently, we showed that pharmacological activation of D1 receptors within the NAc enhanced social dominance. In addition, activation of GABAergic receptors in the VTA, in addition to enhancing social dominance, enhanced the accumbal dopaminergic system. These findings lead us to hypothesize a critical role on the observed behavioral effects for the firing of the VTA dopaminergic neurons that project to the NAc. Subsequently, we investigated the consequences of phasically activating VTA dopaminergic neurons projecting to the NAc in a social competition test. To specifically modulate firing properties of dopaminergic neurons within the VTA of behaving animals, we performed optogenetic activation in TH::Cre rats infused with Cre-dependent virus expressing channelrhodopsin-2 (ChR2). Our results showed that phasic activation of the VTA dopaminergic neurons during the social competition test for palatable rewards was not sufficient to modify the output of the encounters. Winners of the social competition tests were found to have a trend for higher reward-seeking phenotype (lower latencies to get rewards on their last day of individual training) which leads us to subsequently study the role of reward-seeking trait on the rank attained in a social hierarchy. Our data indicates a role for reward-seeking behaviors during last day of individual training (on social competition for palatable rewards test) on the output of several social competition tests. Interestingly, the combination of phasic optical activation of VTA dopaminergic neurons during the last two days of training and during social competition increased dominance. Altogether, our studies have elucidated the effects of anxiety and reward-seeking traits on rat's hierarchy establishment. Furthermore, we were able to modulate the output of a social competition test by optical activations of the mesolimbic dopaminergic system.

EPFL2015

EPFL2005

The impact of anxiety and reward-seeking traits on social competition and the role of the mesolimbic dopaminergic system

Laura Lozano Montes

EPFL2015