Projection Neurons of the Nucleus Accumbens: An Intracellular Labeling Study

Chang, H. T., Kitai, S. T.

11 November 1985

Projection neurons of nucleus accumbens (NAC) of the rat were identified by either antidromic activation from stimulation of midbrain ventral tegmental area-substantia nigra (VTA-SN) regions, or by tracing axons of intracellularly labeled NAC neurons into the ventral pallidum. The morphology of these NAC projection neurons were determined to be medium spiny neurons similar to those identified in the caudate-putamen.

intracellular labeling

nucleus accumbens

ventral striatum

ventral tegmental area (VTA)

The role of ventral tegmental dopamine neurons and the effects of central and peripheral dopamine agonists on fear motivation as measured by the potentiated acoustic startle reflex in rats

Borowski, Thomas Brian

01 January 1997

The involvement of dopamine (DA) in the emotional and psychiatric disturbances associated with schizophrenia and psychomotor stimulant abuse is well known; however, the mechanism by which DA mediates fear expression and anxiety is not well defined. Accordingly, the objective of the present thesis was to determine the fear-motivational functions of DA neurons in the ventral tegmental area (VTA) and to examine the role of DA in fear extinction using the potentiated startle paradigm. In Experiment 1, it was observed that electrical stimulation of the VTA produced a pronounced increase in the amplitude of the acoustic startle reflex. In subsequent experiments fear-potentiated startle was assessed following axon-sparing N-methyl-D-aspartic acid (NMDA) lesions of the VTA and after bilateral intra-VTA infusion of the DA D_2/3 receptor agonist quinpirole (Experiments 2-4). The NMDA lesions resulted in substantial cell loss in the medial ventral tegmentum and blocked fear-potentiated startle. Similarly, inhibition of DA neuronal activity associated with locally-administered quinpirole suppressed the expression of the conditioned fear-induced increase in startle amplitudes. The quinpirole results implicate DA neuronal functioning in fear motivation. To explore further the involvement of DA in aversive emotional behavior, pharmacological experiments were conducted in which the effects of peripherally-administered DA agonist drugs on fear extinction were assessed. Subjects in Experiment 5 received an acute injection of either cocaine hydrochloride (40.0 mg/kg), d-amphetamine sulphate (5.0 mg/kg), the D_2/3 agonist quinpirole hydrochloride (5.0 mg/kg), or the D₁-type agonist SKF 38393 (5.0 mg/kg) during a single extinction session following fear acquisition. Animals treated with cocaine, d-amphetamine, and SKF 38393 exhibited fear-potentiated startle, whereas quinpirole treatment failed to alter fear extinction to the nonreinforced conditioned stimulus (CS). Also, it was revealed using a within-subjects design in Experiment 6 that cocaine administration reinstated fear-potentiated startle following extinction. Taken together, the results of the present experiments suggests fundamental role for DA and DA D₁ receptors in fear expression. It was proposed that VTA DA neurons gate levels of aversive emotional arousal within the amygdala-based fear system.

ventral tegmental area (VTA)

amygdala

rats - neurochemistry

psychology

dopamine neurons

fear motivation

Elucidating the fear - maintaining properties of the Ventral Tegmental Area

Taylor, Amanda Lee

January 2008

The ventral tegmental area (VTA) and its dopaminergic (DA) mesocorticolimbic projections are thought to be essential in the brain’s reward neurocircuitry. In humans and animal experimental subjects, mild electrical VTA stimulation increases dopamine levels and can induce euphoria. Paradoxically, aversive stimuli activate VTA neurons and forebrain DA activity, and excessive electrical stimulation of the VTA exaggerates fearfulness. Research suggests that experimental manipulation of either the amygdala or the VTA has similar effects on the acquisition and expression of Pavlovian conditioned fear. Recently it was demonstrated that electrical stimulation of the amygdala produced fear extinction deficits in rats. Fear extinction involves the progressive dissipation of conditioned fear responses by repeated non-reinforced exposure to a conditioned stimulus (CS). Maladaptive states of fear in fear-related anxiety disorders, such as post-traumatic stress disorders (PTSD) or specific phobias are thought to reflect fear extinction learning deficits. The primary purpose of the present study was to examine the effects of intra-VTA stimulation on fear extinction learning. Using fear-potentiated startle as a behavioural index of conditioned fear, it was found that 120 VTA stimulations paired or unpaired with non-reinforced CS presentations impaired the extinction of conditioned fear. This effect was not apparent in rats that received electrical stimulation of the substantia nigra (SN), suggesting that not all midbrain regions respond similarly. Electrical stimulation parameters did not have aversive affects because rats failed to show fear conditioning when electrical VTA stimulation was used as the unconditioned stimulus. Also, VTA stimulation did not alter conditioned fear expression in non-extinguished animals. Based on the results it is suggested that VTA activation disinhibited conditioned fear responding. Therefore, VTA neuronal excitation by aversive stimuli may play a role in fear-related anxiety disorders thought to reflect extinction learning deficits.

Ventral tegmental area (VTA)

Pavlovian conditioned fear

fear extinction

intra-VTA electrical stimulation

Elucidating the fear - maintaining properties of the Ventral Tegmental Area

Taylor, Amanda Lee

January 2008

The ventral tegmental area (VTA) and its dopaminergic (DA) mesocorticolimbic projections are thought to be essential in the brain’s reward neurocircuitry. In humans and animal experimental subjects, mild electrical VTA stimulation increases dopamine levels and can induce euphoria. Paradoxically, aversive stimuli activate VTA neurons and forebrain DA activity, and excessive electrical stimulation of the VTA exaggerates fearfulness. Research suggests that experimental manipulation of either the amygdala or the VTA has similar effects on the acquisition and expression of Pavlovian conditioned fear. Recently it was demonstrated that electrical stimulation of the amygdala produced fear extinction deficits in rats. Fear extinction involves the progressive dissipation of conditioned fear responses by repeated non-reinforced exposure to a conditioned stimulus (CS). Maladaptive states of fear in fear-related anxiety disorders, such as post-traumatic stress disorders (PTSD) or specific phobias are thought to reflect fear extinction learning deficits. The primary purpose of the present study was to examine the effects of intra-VTA stimulation on fear extinction learning. Using fear-potentiated startle as a behavioural index of conditioned fear, it was found that 120 VTA stimulations paired or unpaired with non-reinforced CS presentations impaired the extinction of conditioned fear. This effect was not apparent in rats that received electrical stimulation of the substantia nigra (SN), suggesting that not all midbrain regions respond similarly. Electrical stimulation parameters did not have aversive affects because rats failed to show fear conditioning when electrical VTA stimulation was used as the unconditioned stimulus. Also, VTA stimulation did not alter conditioned fear expression in non-extinguished animals. Based on the results it is suggested that VTA activation disinhibited conditioned fear responding. Therefore, VTA neuronal excitation by aversive stimuli may play a role in fear-related anxiety disorders thought to reflect extinction learning deficits.

Ventral tegmental area (VTA)

Pavlovian conditioned fear

fear extinction

intra-VTA electrical stimulation

The Bed Nucleus of the Stria Terminalis between Stress and Reward / Le Noyau du Lit de la Strie Terminale : entre Stress et Récompense

Glangetas, Christelle

18 December 2014

L’objectif principal de mon projet de thèse a été d’identifier les mécanismes neuronaux adaptatifs se mettant en place au niveau des circuits de la récompense et des circuits activés en réponse à un stress aigu. Plus spécifiquement, nous avons étudié le rôle du noyau du lit de la strie terminale (BNST) au sein de ces deux circuits. Mon hypothèse est que le BNST appartient à un circuit de structures interconnectées dans lequel il intègre des informations contextuelles (hippocampe ventral) et des informations émotionnelles (cortex préfrontal médian) afin, d’une part, de réguler les niveaux d’anxiété innés ainsi que les réponses induites par les centres du stress suite à un épisode de stress aigu mais également, d’adapter l’activité des neurones dopaminergiques de l’aire tegmentale ventrale (VTA) en vue de motiver ou d’empêcher la reproduction d’un comportement associé à un stimulus récompensant ou aversif. Afin de tester cette hypothèse, nous avons mis en place et développé différents projets de recherche combinant des approches d’électrophysiologie in vivo, anatomiques et comportementales. Dans un premier temps, nous nous sommes intéressés au BNST en tant que structure clef participant à la régulation des centres de stress. Grâce à l’utilisation d’approches d’électrophysiologie in vivo chez la souris anesthésiée, nous avons montré qu’après l’exposition à un stress aigu, les neurones du BNST adaptent leur réponse suite à la stimulation du cortex préfrontal médian et passent d’une dépression à long terme (LTD) en situation contrôle à une potentialisation à long terme (LTP) après un stress aigu. Nous avons disséqué une partie des mécanismes permettant l’élaboration de ces plasticités grâce à l’utilisation de souris génétiquement modifiés pour le récepteur aux endocannabinoïdes de type 1 (CB1-R). Ainsi, nous avons trouvé que la LTD et la LTP mis en place dans le BNST sont médiées par le système endocannabinoïde via les récepteurs CB1. Ensuite, nous avons étudié le rôle du ventral subiculum (vSUB) dans la régulation des neurones du BNST ainsi que l’impact de l’activation de cette voie vSUB-BNST sur l’autre voie glutamatergique ILCx-BNST. Tout d’abord, nous avons montré par des approches électrophysiologiques et anatomiques, qu’un même neurone du BNST est capable d’intégrer des informations provenant à la fois du ventral subiculum et du cortex infralimbic (ILCx). Nous avons induit in vivo une LTP NMDA dépendante dans la voie vSUB-BNST suite à un protocole de stimulation haute fréquence dans le vSUB alors qu’en parallèle ce même protocole induit une LTD sur ces mêmes neurones dans la voie ILCx–BNST. Deplus, nous avons noté que ces adaptations plastiques se mettant en place dans le BNST suiteà une simple stimulation haute fréquence dans le vSUB permettent à long terme de diminuerles niveaux d’anxiété innés chez le rat. Enfin, nous avons mis en évidence que le BNST est un relai excitateur entre le vSUBet la VTA. Nous avons montré qu’une stimulation à haute fréquence dans le vSUBpotentialise in vivo l’activité des neurones dopaminergiques (DA) de la VTA. Or le vSUBne projette pas de manière directe sur les neurones DA de la VTA. Nous avons observé quece protocole de stimulation haute fréquence dans le vSUB induit dans un premier temps uneLTP NMDA dépendante dans les neurones du BNST projetant à la VTA qui est nécessairepour observer cette potentialisation des neurones DA. En dernier lieu, nous avons montréque cette potentialisation des neurones DA de la VTA augmente la réponse locomotrice à unchallenge avec de la cocaine.Ainsi, l’ensemble de ces projets nous ont permis de confirmer et de préciser lafonction majeure du BNST dans la régulation du stress et de l’anxiété ainsi que dans lecircuit de la motivation. / The main goal of my PhD was to identify the adaptive neuronal mechanismsdeveloping in the reward circuit and in the circuit implicated in the regulation of stressresponses. More specifically, we have studied the function of the bed nucleus of the striaterminalis (BNST) in both circuits.My hypothesis was that, the BNST belongs to interconnected circuits in whichintegrates contextual (from ventral hippocampus) and emotional informations (from medialprefrontal cortex). Thus, the BNST diffuses these informations in order to regulate the basalinnate level of anxiety and stress centers responses induced after acute stress exposure, butalso to adapt the activity of dopaminergic neurons of the ventral tegmental area (VTA) thatcan promote or prevent a behavioral task associated with a rewarding or aversive stimulus.To test this hypothesis, we decided to develop several research projects usingelectrophysiological, anatomical and behavioral approaches.Firstly, we focused our interest on the stress circuit in which the BNST is a keystructure which participates in regulating the responses of stress centers after acute stressexposure. By using in vivo electrophysiology approach in anesthetized mice, we haveshown that after acute restraint stress, BNST neurons adapt their plastic responses inducedby the tetanic stimulation of the medial prefrontal cortex: switch from long term depression(LTD) under control condition to long term potentiation (LTP) after acute stress condition.Furthermore, we demonstrated that both LTD and LTP are endocannabinoid dependent byusing genetic modified mice for the type 1 endocannabinoid receptors and localpharmacological approach in the BNST.In a second step, we studied the function of the ventral subiculum (vSUB) in theregulation of BNST neurons and the impact of the vSUB-BNST pathway activation on theother glutamatergic ILCx-BNST pathway. In a first set of experiments, we showed that asame single BNST neuron could integrate informations from both vSUB and the infralimbiccortex. By using high frequency stimulation (HFS) protocols, we induced in vivo NMDAdependentLTP in the vSUB-BNST pathway whereas the same protocol led to LTD in thesame BNST neurons in the ILCx-BNST pathway. Moreover, we noted single application ofHFS protocol in the vSUB induced a long term decrease of the basal innate level of anxietyin rats.Lastly, we presented the BNST as a key excitatory relay between the vSUB and theVTA. Here, we have shown that in vivo HFS protocols in the vSUB potentiate the activity ofdopaminergic (DA) neurons of the VTA. However, the vSUB does not directly project to theVTA. We observed that a HFS protocol in the vSUB first induce NMDA-dependent LTP inBNST neurons that project to the VTA, which is necessary to promote the potentiation of7VTA DA neurons. In the last step, we demonstrated in vivo that the potentiation of VTA DAneurons increases the locomotor response to cocaine challenge.All together, these projects allow us to confirm and detail the major function of theBNST in the regulation of stress and anxiety and also in the motivational circuit.

Endocannabinoïde

Stress

Anxiété

Stimulation à haute fréquence

Endocannabinoid

Stress

Anxiety

High frequency stimulation