吗啡相关情境线索的形成及效应表达的神经基础——海马与基底外侧杏仁核在其中的作用

Drug-associated cue-induced relapse to drug seeking causes most difficulties of therapy for drug addiction. Addicts are exposed to two forms of environmental stimuli during drug-taking: contextual stimuli (e.g. a house in which the drug is consumed) and discrete stimuli (DS, e.g. a crack pipe or a syringe for drug). These stimuli become contextual cues and discrete cues, respectively. The incentive value of contextual cues plays a great role in opiates relapse. Compared with drug self-administration model, conditioned place preference (CPP) reflects the approach behavior for drug cues, not concerned with acquisition of operant behaviors. The present study aimed to investigate the role of basolateral amygdala (BLA) and hippocampus in the effect of opiates-related contextual cues using CPP model. Establishing DS-dependent or contextual cues-dependent CPP, the effect of BLA or hippocampus inactivation prior to training phase on acquisition of contextual cues-opiates association was evaluated. Inactivation prior to test phase was used to evaluate roles of BLA and hippocampus in expression of contextual cues-dependent morphine CPP. The main results were as follows: Inactivation of BLA or dorsal hippocampus selectively impaired acquisition of contextual cue-dependent CPP, but inactivation of ventral hippocampus had no impact on acquisition of either DS-dependent or contextual cue-dependent morphine CPP. Inactivation of BLA selectively inhibited expression of contextual cue-depended CPP. Inactivation of ventral hippocampus inhibited expression of both DS-dependent and contextual cue-dependent morphine CPP. These results suggest that BLA and dorsal hippocampus contribute to contextual cue association with opiates but not DS-opiates association. BLA and ventral hippocampus play important roles in incentive value of contextual cues. The present study provides more information for the neurological substrates underlying contextual cues associated with opiates.

影响吗啡动物行为效应的因素及其机制

Credible and stable animal behavioral models are necessary to research the mechanisms of addiction in vivo, especially to study the relationship between memory or stress and drug addiction, which has been one of the focuses in this field. So the object of this study was to observe the influences of several factors on the behavioral effects of morphine shown in the paradigms of conditioned place preference (CPP) and locomotor activity (LA), and to explore the effects of adrenalectomy on LA induced by morphine in rats. In addition, the cortexes of rats were examined, which were exposed to chronic administration of several doses of morphine with or without foot shock. Moreover, a new behavioral model was built to quantify the motivation of drug seeking. The results showed that CPP was more sensitive to low dose of morphine than to high dose. The period of experiment could be shortened by increasing the training times everyday, whereas in this way the dose of morphine should be low enough to avoid the impact between the near two exposures to morphine. Effects of chronic administration of morphine on LA in rats were dose- and time- dependent, which supplied evidence to choose parameters in other behavioral models. The results obtained by the simplified LA paradigm showed that hyperactivity of low dose of morphine following hypoactivity, and naloxone had no effects on LA but blocked the locomotion effects of morphine. Obvious effects of morphine on LA of rats might depend on a reasonable level of plasma corticosterone, which may determine individual vulnerability to drug addiction. Stress may also potentiate the vulnerability by aggravating damage to cortex of rats induced by drug dose-dependently, which is suggested by the results of histological examination. The result that frontal and temporal cortexes and hippocampus were injured suggests that there may be a close relationship between memory and drug addiction. It was showed that the new behavioral model on the basis of Morris water maze might be used to quantify the motivation of drug-craving.

Enhanced rewarding properties of morphine, but not cocaine, in beta(arrestin)-2 knock-out mice.

The reinforcing and psychomotor effects of morphine involve opiate stimulation of the dopaminergic system via activation of mu-opioid receptors (muOR). Both mu-opioid and dopamine receptors are members of the G-protein-coupled receptor (GPCR) family of proteins. GPCRs are known to undergo desensitization involving phosphorylation of the receptor and the subsequent binding of beta(arrestins), which prevents further receptor-G-protein coupling. Mice lacking beta(arrestin)-2 (beta(arr2)) display enhanced sensitivity to morphine in tests of pain perception attributable to impaired desensitization of muOR. However, whether abrogating muOR desensitization affects the reinforcing and psychomotor properties of morphine has remained unexplored. In the present study, we examined this question by assessing the effects of morphine and cocaine on locomotor activity, behavioral sensitization, conditioned place preference, and striatal dopamine release in beta(arr2) knock-out (beta(arr2)-KO) mice and their wild-type (WT) controls. Cocaine treatment resulted in very similar neurochemical and behavioral responses between the genotypes. However, in the beta(arr2)-KO mice, morphine induced more pronounced increases in striatal extracellular dopamine than in WT mice. Moreover, the rewarding properties of morphine in the conditioned place preference test were greater in the beta(arr2)-KO mice when compared with the WT mice. Thus, beta(arr2) appears to play a more important role in the dopaminergic effects mediated by morphine than those induced by cocaine.

Defining and assessing animal pain

The detection and assessment of pain in animals is crucial to improving their welfare in a variety of contexts in which humans are ethically or legally bound to do so. Thus clear standards to judge whether pain is likely to occur in any animal species is vital to inform whether to alleviate pain or to drive the refinement of procedures to reduce invasiveness, thereby minimizing pain. We define two key concepts that can be used to evaluate the potential for pain in both invertebrate and vertebrate taxa. First, responses to noxious, potentially painful events should affect neurobiology, physiology and behaviour in a different manner to innocuous stimuli and subsequent behaviour should be modified including avoidance learning and protective responses. Second, animals should show a change in motivational state after experiencing a painful event such that future behavioural decision making is altered and can be measured as a change in conditioned place preference, self-administration of analgesia, paying a cost to access analgesia or avoidance of painful stimuli and reduced performance in concurrent events. The extent to which vertebrate and selected invertebrate groups fulfil these criteria is discussed in light of the empirical evidence and where there are gaps in our knowledge we propose future studies are vital to improve our assessment of pain. This review highlights arguments regarding animal pain and defines criteria that demonstrate, beyond a reasonable doubt, whether animals of a given species experience pain.

Effets motivationnels des cannabinoïdes dans un modèle animal de la schizophrénie

Depuis quelques décennies, la consommation de cannabis et son usage thérapeutique sont le sujet de nombreux débats. Le cannabis est la drogue illicite la plus consommée au monde et cette consommation se trouve dix fois plus élevée chez les patients atteints de schizophrénie que dans la population générale. L’hypothèse d’une automédication initialement proposée afin d’expliquer la consommation élevée de cannabis chez les patients atteints de schizophrénie est maintenant remise en question. En effet, les rapports indiquant une aggravation des symptômes plutôt qu’une amélioration suite à une consommation à long terme sont de plus en plus nombreux. Sachant que le cannabis peut induire des effets soit plaisants soit aversifs, la question se pose à savoir si une prédominance de la valence motivationnelle positive ou une diminution de la valence négative du cannabis peut expliquer la consommation élevée parmi les individus ayant un diagnostic de schizophrénie? Bien qu’un grand nombre de recherches pré-cliniques aient été menées chez l’animal normal pour évaluer l’effet motivationnel du Δ9-tétrahydrocannabinol (THC) et autres cannabinoïdes synthétiques, aucune n’a abordé cette problématique dans un modèle animal de la schizophrénie. Cette lacune nous a donc amené à étudier la valence motivationnelle du THC et de l’agoniste cannabinoïde WIN55,212-2 (WIN) dans un modèle animal de la schizophrénie: la lésion néonatale de l’hippocampe ventral (NVHL). Dans le premier article, nous présentons les résultats de quatre expériences. Une première avait pour objectif de déterminer si la procédure expérimentale que nous avons utilisée permettait de reproduire des signes distinctifs du modèle animal de la schizophrénie. Par la suite, nous avons évalué i) l’effet d’une dose de WIN sur l’activité locomotrice spontanée et ii) la valence motivationnelle du THC (0.5 mg/kg, i.p) et du WIN (1 mg/kg, i.p) chez les rats adolescents (jour post-natal 28-40, PD28-40) et adultes (PD56) au moyen du paradigme de préférence de place conditionnée (PPC). Tel qu’attendu, la réponse locomotrice à l’amphétamine (0.75 et 1.5 mg/kg) chez les rats NVHL adultes était supérieure à celle des rats contrôles (test distinctif du modèle). Le THC a induit une tendance aversive chez les rats contrôles adultes. Enfin, le WIN a stimulé l’activité locomotrice et induit une aversion significative chez les rats adultes NVHL. Dans un deuxième article, nous avons évalué la valence motivationnelle du THC (0.5 mg/kg), du WIN (1 et 3 mg/kg) et l’effet de l’amphétamine au moyen du paradigme d’autostimulation électrique intracérébrale (ASI). Les résultats montrent que : i) l’effet amplificateur de l’amphétamine sur l’ASI était de plus courte durée chez les rats NVHL; ii) le THC produit une légère atténuation de la récompense chez les rats contrôles tandis que le WIN a produit une atténuation plus prononcée de la récompense chez les rats NVHL, un effet qui a été bloqué par l’antagoniste aux récepteurs CB1, le AM251 (3 mg/kg). Pour la première fois les résultats suggèrent une altération du système endocannabinoïde dans un modèle animal de la schizophrénie. Ils indiquent qu’une exposition aigüe conduit à une prédominance de la valence négative. Bien qu’en apparente contradiction avec les études cliniques, ces résultats soulignent l’importance du contexte socio-environnemental pour expliquer les effets du cannabis chez les patients. De plus ils encouragent les futures études à évaluer cette valence sur un modèle d’exposition chronique.

Neurotensinergic modulation of glutamatergic neurotransmission in VTA neurons.

L’aire tegmentaire ventrale (VTA) contient une forte densité de terminaisons neurotensinergiques ainsi que des récepteurs à la surface des neurones dopaminergiques et non-dopaminergiques. Le VTA a été impliqué dans des maladies comme la schizophrénie, les psychoses et l’abus de substance. Les drogues d’abus sont connues pour induire le phénomène de sensibilisation - un processus de facilitation par lequel l’exposition à un stimulus produit une réponse augmentée lors de l’exposition subséquente au même stimulus. La sensibilisation se développe dans le VTA et implique mécanismes dopaminergiques et glutamatergiques. Il a été montré que les antagonistes neurotensinergiques bloquaient le développement de la sensibilisation et certains mécanismes de récompense et ces effets pourraient être médiés indirectement par une modulation de la neurotransmission glutamatergique. Cependant, on connaît peu les mécanismes de modulation de la transmission glutamatergique par la neurotensine (NT) dans le VTA. Le but de la présente thèse était d’étudier la modulation neurotensinergique de la neurotransmission glutamatergique dans les neurones dopaminergiques et non-dopaminergiques du VTA. Pour ce faire, nous avons utilisé la technique du patch clamp dans la cellule entière dans des tranches horizontales du VTA pour étudier les effets de différents agonistes et antagonistes neurotensinergiques. Les neurones ont été identifié comme Ih+ (présumés dopaminergiques) ou Ih- (présumés non-dopaminergiques) selon qu’ils exprimaient ou non un courant cationique activé par l’hyperpolarisation (Ih). Des techniques d’immunocytochimie ont été utilisées pour marquer les neurones et vérifier leur localisation dans le VTA. Dans une première étude nous avons trouvé que la neurotensine indigène (NT1-13) ou son fragment C-terminal, NT8-13, induisait une augmentation comparable des courants postsynaptiques excitateurs glutamatergiques (CPSEs) dans les neurones Ih+ ou Ih- du VTA. L'augmentation induite dans les neurones Ih+ par la NT8-13 a été bloquée par le SR48692, un antagoniste des récepteurs NTS1, et par le SR142948A, un antagoniste des récepteurs NTS1 et NTS2, suggérant que l'augmentation était médiée par l’activation des récepteurs NTS1. Dans les neurones Ih- l'augmentation n’a été bloquée que par le SR142948A indiquant une implication des récepteurs NTS2. Dans une deuxième étude, nous avons testé les effets de la D-Tyr[11]NT (un analogue neurotensinergique ayant différentes affinités de liaison pour les sous-types de récepteurs neurotensinergiques) sur les CPSEs glutamatergiques dans les neurones Ih+ et Ih- en parallèle avec une série d’expériences comportementales utilisant un paradigme de préférence de place conditionnée (PPC) menée dans le laboratoire de Pierre-Paul Rompré. Nous avons constaté que la D-Tyr[11]NT induisaient une inhibition dépendante de la dose dans les neurones Ih+ médiée par l'activation de récepteurs NTS2. En revanche, la D-Tyr[11]NT a produit une augmentation des CPSEs glutamatergiques médiée par des récepteurs NTS1 dans les neurones Ih-. Les résultats des expériences comportementales ont montré que des microinjections bilatérales de D-Tyr[11]NT dans le VTA induisait une PPC bloquée uniquement par la co-injection de SR142948A et SR48692, indiquant un rôle pour les deux types de récepteurs, NTS1 et NTS2. Cette étude nous a permis de conclure que i) la D-Tyr[11]NT agit dans le VTA via des récepteurs NTS1 et NTS2 pour induire un effet de récompense et ii) que cet effet est dû, au moins en partie, à une augmentation de la neurotransmission glutamatergique dans les neurones non-dopaminergiques (Ih-). Dans une troisième étude nous nous sommes intéressés aux effets de la D-Tyr[11]NT sur les réponses isolées médiées par les récepteurs N-méthyl-D-aspartate (NMDA) et acide α-amino-3- hydroxy-5-méthyl-4-isoxazolepropionique (AMPA) dans les neurones du VTA. Nous avons constaté que dans les neurones Ih+ l’amplitude des CPSEs NMDA et AMPA étaient atténuées de la même manière par la D-Tyr[11] NT. Cette modulation des réponses était médiée par les récepteurs NTS1 et NTS2. Au contraire, dans les neurones Ih-, l’amplitude des réponses NMDA et AMPA étaient augmentées en présence de D-Tyr[11]NT et ces effets dépendaient de l’activation des récepteurs NTS1 localisés sur les terminaisons glutamatergiques. Ces résultats fournissent une preuve supplémentaire que le NT exerce une modulation bidirectionnelle sur la neurotransmission glutamatergique dans les neurones du VTA et met en évidence un nouveau type de modulation peptidergique des neurones non-dopaminergiques qui pourrait être impliqué dans la sensibilisation. En conclusion, la modulation neurotensinergique de la neurotransmission glutamatergique dans les neurones dopaminergiques et non-dopaminergiques du VTA se fait en sens opposé soit, respectivement, par une inhibition ou par une excitation. De plus, ces effets sont médiés par différents types de récepteurs neurotensinergiques. En outre, nos études mettent en évidence une modulation peptidergique de la neurotransmission glutamatergique dans le VTA qui pourrait jouer un rôle important dans les mécanismes de lutte contre la toxicomanie.

Ethanol-induced sensitization depends preferentially on D(1) rather than D(2) dopamine receptors

Behavioral sensitization, defined as a progressive increase in the locomotor stimulant effects elicited by repeated exposure to drugs of abuse, has been used as an animal model for drug craving in humans. The mesoaccumbens dopaminergic system has been proposed to be critically involved in this phenomenon; however, few studies have been designed to systematically investigate the effects of dopaminergic antagonists on development and expression of behavioral sensitization to ethanol in Swiss mice. We first tested the effects of D(1) antagonist SCH-23390 (0-0.03 mg/kg) or D(2) antagonist Sulpiride (0-30 mg/kg) on the locomotor responses to an acute injection of ethanol (2.0 g/kg). Results showed that all tested doses of the antagonists were effective in blocking ethanol`s stimulant effects. In another set of experiments, mice were pretreated intraperitoneally with SCH-23390 (0.01 mg/kg) or Sulpiride (10 mg/kg) 30 min before saline or ethanol injection, for 21 days. Locomotor activity was measured weekly for 20 min. Four days following this pretreatment, all mice were challenged with ethanol. Both antagonists attenuated the development of ethanol sensitization, but only SCH-23390 blocked the expression of ethanol sensitization according to this protocol. When we tested a single dose (30 min before tests) of either antagonist in mice treated chronically with ethanol, both antagonists attenuated ethanol-induced effects. The present findings demonstrate that the concomitant administration of ethanol with D(1) but not D(2) antagonist prevented the expression of ethanol sensitization, suggesting that the neuroadaptations underlying ethanol behavioral sensitization depend preferentially on D(1) receptor actions. (C) 2010 Elsevier Inc. All rights reserved.

Efeitos da cafeína sobre a memória de saguis (Callithrix jacchus)

Caffeine is considered the most consumed psychostimulant in the world, presenting several central and peripheral effects. In the Central Nervous System the major effect occur by its antagonistic activity at the A1 and A2a subtypes of the adenosine receptors. These receptors are responsible for the slow-wave sleep induction, and their binding, caused by the consumption of foods and beverages that contain caffeine, cause behaviors like increase of alertness, mood and locomotion. The effects of caffeine on memory are still discussed because of the diversity of experimental protocols. Also, it does not have the same effects on all stages of the processing of memory - acquisition, consolidation and recall. Thus, using the marmoset (Callitrhix jacchus) as subject, we aim to evaluate the effects of caffeine on the memory of this primate through the conditioned place preference paradigm, where the animal selects a context by presence of food. This cognitive task consists of five phases. The first phase was two sessions of pre-exposure, in which they were evaluated for preference for any compartment of the apparatus. Then, we proceeded the training, conditioning the animals to the food-present context for 8 days. Then, there was administration of caffeine or placebo (10mg/kg) for 8 consecutive days, during the pre-sleep phase, where the 20 animals were distributed in two groups: placebo and repeated. The forth phase was one day of retraining, a re-exposure of the apparatus to the marmosets followed by the administration of caffeine (for the repeated group and a new group called abstinence) or placebo (for placebo and abstinence groups). Finally, was the test where we evaluated if the subjects learned where the food was present. Moreover, in this work we evaluate the existence of differences between females and males on the task, and the locomotor activity for the experimental groups. The results showed that in the pre-exposure phase the animals were habituated on the apparatus and did not present differences for any contexts. In training, they were able to learn the conditioning task, independent of gender. For the retraining, the two groups exhibited more interactions in rewarded context than that in non-rewarded context. Nevertheless, in the locomotor activity, the repeated group moved similarly in contact with the apparatus and outside of it. In the other hand, the animals of the placebo group moved more when in contact with the apparatus. In the test phase, the marmosets under influence of caffeine presented an increase in the locomotor activity when compared with the placebo group, corroborating works that show this increase in locomotion. In the learning evaluation, the continuous and abstinence groups had a bad performance in the task in relation to the placebo and acute groups. This suggests that the prolonged administration of caffeine disrupts the memories because it affected sleep, which is largely responsible offline processing of memories

Álcool e comportamento: efeitos na aprendizagem e memória

Excessive alcohol consumption is responsible for many harmful effects on individuals and society. Despite years of research, the mechanisms by which alcohol affects neurological functions and the exact causes of cognitive impairment related to long-term use are unknown. In this sense, this master study proposed to observe how different doses of alcohol affect the addiction response and the learning ability of two fish species: Betta splendens and Danio rerio, the latter a commonly model due to organizational and functional characteristics shared with mammals. For this, different concentrations of ethanol (0%, 0.1%, 0.25%, 1% and 1.5%) were used in acute, chronic and withdrawal treatments. We tested the fish in three experimental protocols: 1) alcohol addiction potential using conditioned place preference, 2) associative conditioning using light as unconditioned stimulus and food as conditioned stimulus and 3) spatial learning using a maze without cues. For the alcohol addiction potential, preference between two different places in a shuttle box was tested before and after alcohol exposure (chronic and acute). In this test, the animals intoxicated by 0.1% did not change behavior, while animals receiving 1% and 1.5% alcohol changed the initial preference to the side where they received alcohol For the associative conditioning, the results show that the groups undergoing low dose (0.1%), both in chronic and withdrawal treatment, learned the task faster than control; groups under 0.25 and 1% alcohol withdrawal learned the task after control; groups chronically intoxicated with these doses did not learn the task. For the spatial learning test, fish submitted to acute and chronic treatments decreased the time to exit the maze; there were significant differences in the animal s performance in a dose-dependent pattern. This difference was not observed for the withdrawal treatment. Given these results, we conclude that the effects of alcohol on learning are dependent on the dosage. Furthermore, low doses of alcohol seem to maximize animal performance on learning tasks and do not alter their seeking behavior, while higher doses induced addition and hinder learning

Diethylpropion produces psychostimulant and reward effects

Diethylpropion (DEP) is a stimulant drug widely used for weight control in Brazil and other American countries. However, its effects on behavior and addiction potential are not yet well known. Data suggest that sensitization resulting from pre-exposure to psychostimulants could be a possible risk factor in subsequent drug addiction. The purpose of this investigation was to verify whether pre-exposure to DEP would sensitize rats to the motor activating effect and to the rewarding value of DEP. Two experiments were conducted. In both experiments rats were pre-exposed to DEP (20 mg/kg) or vehicle for 7 consecutive days. The acute effect of DEP (0.0, 1.0, 2.5 or 5.0 mg/kg) on motor activity (Experiment 1) and induction of Conditioned Place Preference-CPP (Experiment 2) were then measured. Results from Experiment 1 showed that 2.5 and 5.0 mg/kg DEP increased motor activity. Sensitization of this motor effect was observed. In Experiment 2, the doses of 2.5 and 5.0 mg/kg DEP induced CPP, indicating their rewarding value. However, no sensitization effect was observed. The results suggest that DEP at low doses has psychostimulant and rewarding properties. It is recommended that more effort should be dedicated to elucidating DEP abuse Potential. (c) 2008 Elsevier Inc. All rights reserved.

Environmental enrichment blocks ethanol-induced locomotor sensitization and decreases BDNF levels in the prefrontal cortex in mice

The use of addictive drugs can lead to long-term neuroplastic changes in the brain, including behavioral sensitization, a phenomenon related to addiction. Environmental enrichment (EE) is a strategy used to study the effect of environment on the response to several manipulations, including treatment with addictive drugs. Brain-derived neurotrophic factor (BDNF) has been associated with behaviors related to ethanol addiction. The aim of the present study was to evaluate the effects of EE on ethanol-induced behavioral sensitization and BDNF expression. Mice were exposed to EE and then repeatedly treated with a low dose (1.8 g/kg) of ethanol. Another group of mice was first subjected to repeated ethanol treatment according to the behavioral sensitization protocol and then exposed to EE. Environmental enrichment prevented the development of ethanol-induced behavioral sensitization and blocked behavioral sensitization in sensitized mice. Both repeated ethanol and EE decreased BDNF levels in the prefrontal cortex but not in the hippocampus. However, BDNF levels were lower in ethanol-treated mice exposed to EE. These findings suggest that EE can act on the mechanisms implicated in behavioral sensitization, a model for drug-induced neuroplasticity and relapse. Additionally, EE alters BDNF levels, which regulate addiction-related behaviors.

The periaqueductal gray as a critical site to mediate reward seeking during predatory hunting

Previous studies using morphine-treated dams reported a role for the rostral lateral periaqueductal gray (rIPAG) in the behavioral switching between nursing and insect hunting, likely to depend on an enhanced seeking response to the presence of an appetitive rewarding cue (i.e., the roach). To elucidate the neural mechanisms mediating such responses, in the present study, we first observed how the rIPAG influences predatory hunting in male rats. Our behavioral observations indicated that bilateral rIPAG NMDA lesions dramatically interfere with prey hunting, leaving the animal without chasing or attacking the prey, but do not seem to affect the general levels of arousal, locomotor activity and regular feeding. Next, using Phaseolus vulgaris-leucoagglutinin (PHA-L), we have reviewed the rIPAG connection pattern, and pointed out a particularly dense projection to the hypothalamic orexinergic cell group. Double labeled PHA-L and orexin sections showed an extensive overlap between PHA-L labeled fibers and orexin cells, revealing that both the medial/perifornical and lateral hypothalamic orexinergic cell groups receive a substantial innervation from the rIPAG. We have further observed that both the medial/perifornical and lateral hypothalamic orexinergic cell groups up-regulate Fos expression during prey hunting, and that rIPAG lesions blunted this Fos increase only in the lateral hypothalamic, but not in the medial/perifornical, orexinergic group, a finding supposedly associated with the lack of motivational drive to actively pursue the prey. Overall, the present results suggest that the rIPAG should exert a critical influence on reward seeking by activating the lateral hypothalamic orexinergic cell group. (C) 2011 Elsevier B.V. All rights reserved.

Assessment of Alcohol Reward in Prairie Voles (Microtus ochrogaster)

The purpose of our study was to assess whether prairie voles find alcohol rewarding. Prairie voles have recently become a species of interest for alcohol studies, which have traditionally used other rodent model species including several different strains of mice and rats. The prairie vole is one of only two known rodent species that readily administers high levels of unsweetened alcohol, implicating it as a potentially effective animal model for studying alcohol abuse. However, voluntary consumption does not necessarily imply that prairie voles find it rewarding. Therefore the purpose of our study was to investigate if alcohol has rewarding properties for prairie voles using three different approaches: place conditioning, flavor conditioning, and immunohistochemistry. Furthermore, we sought to characterize their reward profile and compare it to other commonly used rodent models ¿ C57BL/6 mice, DBA/2J mice, and Sprague-Dawley rats. Place and flavor conditioning are behavioral methods that rely on the learned association between a stimulus and the effects of a drug; the drug of interest in these studies is alcohol. To assess whether prairie voles will demonstrate a conditioned preference for alcohol-paired stimuli, seven place conditioning studies were run that investigated a range of different doses, individual conditioning session durations, and trial durations. Video analysis revealed no difference in the amount of time spent on the alcohol-paired floor, suggesting no conditioned place preference for alcohol. Two flavor conditioning tests were conducted to assess whether voles would demonstrate a preference for an alcohol-paired flavored saccharin solution. Voles demonstrated reduced consumption of the alcohol-paired flavored saccharin solution, regardless of dose or flavor, when alcohol administration occurred after conditioning sessions (p=<0.001). When alcohol was administered before conditioning sessions, no difference in consumption of the alcohol-paired and saline-paired flavored saccharin solutions was seen (p=0.545). Previous studies that have documented similar behavior have hypothesized that this is an example of an anticipatory contrast effect. This theory proposes that prairie voles reduce their intake of a hedonic solution (flavored saccharin solution) in anticipation of later drug administration (alcohol). However, conditioning-based behavioral methods of studying alcohol reward are highly sensitive to the parameters of the conditioned stimulus, thus it is possible that voles will not show preference for alcohol-related stimuli, even if they do find alcohol rewarding. Immunohistochemical analysis supplemented this behavioral data by allowing us to identify specific neural regions that were directly activated in response to the acute administration of alcohol. No difference in the number of activated c-Fos neurons in the Nucleus Accumbens (NAc) core or shell was seen (p=0.3364; p=0.6698) in animals that received an acute injection of alcohol or saline. There was a significant increase in the number of activated c-Fos neurons in the Paraventricular Nucleus of the Hypothalamus (PVN) in alcohol-treated animals compared to saline-treated animals (p=0.0034). There was no difference in the pixel count of activated c-Fos neurons or in the % area activated in the Arcuate Nucleus between alcohol and saline-treated animals (p=0.4523; p=0.3304). In conclusion, the place conditioning studies that were conducted in this thesis suggest that prairie voles do not demonstrate preference or aversion towards alcohol-paired stimuli. The flavor conditioning studies suggest that prairie voles do not demonstrate aversion but rather avoidance of the alcohol-paired flavor in anticipation of future alcohol administration. The preliminary immunohistochemical data collected is inconclusive but cannot rule out the possibility of neuronal activation patterns indicative of reward. Taken together, our data indicate that prairie voles hav

FosB mutant mice: Loss of chronic cocaine induction of Fos-related proteins and heightened sensitivity to cocaine’s psychomotor and rewarding effects

Chronic exposure to cocaine leads to prominent, long-lasting changes in behavior that characterize a state of addiction. The striatum, including the nucleus accumbens and caudoputamen, is an important substrate for these actions. We previously have shown that long-lasting Fos-related proteins of 35–37 kDa are induced in the striatum by chronic cocaine administration. In the present study, the identity and functional role of these Fos-related proteins were examined using fosB mutant mice. The striatum of these mice completely lacked basal levels of the 35- to 37-kDa Fos-related proteins as well as their induction by chronic cocaine administration. This deficiency was associated with enhanced behavioral responses to cocaine: fosB mutant mice showed exaggerated locomotor activation in response to initial cocaine exposures as well as robust conditioned place preference to a lower dose of cocaine, compared with wild-type littermates. These results establish the long-lasting Fos-related proteins as products of the fosB gene (specifically ΔFosB isoforms) and suggest that transcriptional regulation by fosB gene products plays a critical role in cocaine-induced behavioral responses. This finding demonstrates that a Fos family member protein plays a functional role in behavioral responses to drugs of abuse and implicates fosB gene products as important determinants of cocaine abuse.

Effects of palmitoylethanolamide in cocaine-induced behaviours

Aims. Cocaine addiction is a chronically relapsing disorder characterized by the compulsion to seek and take the drug. Previous investigations have demonstrated that several drugs of abuse, as cocaine, can alter the levels of lipid-based signalling molecules such as the N-acylethanolamines (NAEs). In addition, NAEs levels in the brain are sensitive to cocaine self-administration and extinction training. In this context, this study aimed to investigate the effect of repeated and acute palmitoylethanolamide (PEA), an endogenous NAE, on the behavioural effects of cocaine using mouse models of conditioned reward and psychomotor activation. Methods. Using male C57BL/6J mice, the ability of repeated PEA injections (1 or 10 mg/kg i.p) to modulate the development of a conditioned place preference (CPP) and behavioural sensitization (BS) induced by cocaine (20 mg/kg i.p.) was evaluated. In addition, the expression of cocaine-induced CPP and BS after acute PEA administration was also studied. Results. PEA (1 and 10 mg/kg i.p) significantly reduced the development of cocaine-induced BS, but did not modify the acquisition of cocaine-induced CPP. Furthermore, both doses of PEA were able to reduce the expression of BS and CPP. Conclusions. Altogether, these findings show that exogenous administration of PEA attenuated psychomotor activation and impaired the expression of CPP induced by cocaine. Our results may be relevant in order to understand the role of NAEs in the development and treatment of cocaine addiction.