BDNF-TrkB signaling through Erk1/2 MAPK phosphorylation mediates the enhancement of fear memory induced by glucocorticoids.

Activation of glucocorticoid receptors (GR) by glucocorticoid hormones (GC) enhances contextual fear memories through the activation of the Erk1/2(MAPK) signaling pathway. However, the molecular mechanism mediating this effect of GC remains unknown. Here we used complementary molecular and behavioral approaches in mice and rats and in genetically modified mice in which the GR was conditionally deleted (GR(NesCre)). We identified the tPA-BDNF-TrkB signaling pathway as the upstream molecular effectors of GR-mediated phosphorylation of Erk1/2(MAPK) responsible for the enhancement of contextual fear memory. These findings complete our knowledge of the molecular cascade through which GC enhance contextual fear memory and highlight the role of tPA-BDNF-TrkB-Erk1/2(MAPK) signaling pathways as one of the core effectors of stress-related effects of GC.

The enhancement of stress-related memory by glucocorticoids depends on synapsin-Ia/Ib.

The activation of glucocorticoid receptors (GR) by glucocorticoids increases stress-related memory through the activation of the MAPK signaling pathway and the downstream transcription factor Egr-1. Here, using converging in vitro and in vivo approaches, respectively, GR-expressing cell lines, culture of hippocampal neurons, and GR genetically modified mice (GR(NesCre)), we identified synapsin-Ia/Ib as one of the effectors of the glucocorticoid signaling cascade. Stress and glucocorticoid-induced activation of the GR modulate synapsin-Ia/Ib through two complementary mechanisms. First, glucocorticoids driving Egr-1 expression increase the expression of synapsin-Ia/Ib, and second, glucocorticoids driving MAPK activation increase its phosphorylation. Finally, we showed that blocking fucosylation of synapsin-Ia/Ib in the hippocampus inhibits its expression and prevents the glucocorticoid-mediated increase in stress-related memory. In conclusion, our data provide a complete molecular pathway (GR/Egr-1/MAPK/Syn-Ia/Ib) through which stress and glucocorticoids enhance the memory of stress-related events and highlight the function of synapsin-Ia/Ib as molecular effector of the behavioral effects of stress.

Influence of glucocorticoids on dopaminergic transmission in the rat dorsolateral striatum.

Glucocorticoid hormones exert strong influences on central neurotransmitter systems. In the present work, we examined the functional consequences of corticosterone suppression on the dopaminergic transmission in the dorsolateral striatum by studying the expression of Fos-like proteins and extracellular dopamine levels. Glucocorticoid hormones were suppressed by adrenalectomy, and the specificity of the effects assessed by restoring physiological plasmatic corticosterone concentrations. We show that, in the dorsolateral striatum, glucocorticoids modify postsynaptic dopaminergic transmission. Suppression of glucocorticoids decreased the induction of Fos proteins in response to a direct agonist of dopamine D(1) receptors (SKF 82958, 1.5 mg/kg, i.p.), but not the release of dopamine induced by morphine (2 mg/kg, s.c.) or the density of the limiting enzyme of dopamine synthesis, tyrosine hydroxylase. In contrast to the dopaminergic response to morphine, the response to cocaine (15 mg/kg, i.p.) was modified by the suppression of corticosterone. In this case, adrenalectomy increased cocaine-induced changes in extracellular dopamine but did not modify the expression of Fos-like proteins. This absence of changes in cocaine-induced Fos-like proteins might result from a compensatory mechanism between the increase in the dopaminergic response and the decrease in the functional activity of dopamine D(1) receptors. The increased dopaminergic response to cocaine also contrasts with the decreased response previously observed in the shell of the nucleus accumbens [Barrot et al. (2000) Eur. J. Neurosci., 12, 973-979]. The present data highlight the profound heterogeneous influence of glucocorticoids within dopaminergic projections.

Distinct functions of the two isoforms of dopamine D2 receptors.

Signalling through dopamine D2 receptors governs physiological functions related to locomotion, hormone production and drug abuse. D2 receptors are also known targets of antipsychotic drugs that are used to treat neuropsychiatric disorders such as schizophrenia. By a mechanism of alternative splicing, the D2 receptor gene encodes two molecularly distinct isoforms, D2S and D2L, previously thought to have the same function. Here we show that these receptors have distinct functions in vivo; D2L acts mainly at postsynaptic sites and D2S serves presynaptic autoreceptor functions. The cataleptic effects of the widely used antipsychotic haloperidol are absent in D2L-deficient mice. This suggests that D2L is targeted by haloperidol, with implications for treatment of neuropsychiatric disorders. The absence of D2L reveals that D2S inhibits D1 receptor-mediated functions, uncovering a circuit of signalling interference between dopamine receptors.

Vertical shifts in self-administration dose-response functions predict a drug-vulnerable phenotype predisposed to addiction.

The role of individual differences in the etiology of addiction is a very controversial issue. Neuroendocrine phenotypes that are able to predispose an individual to the development of drug intake have been identified previously. However, such information has been gathered by comparing individuals who differ in their sensitivity to low doses of the drug. Consequently, it remains unclear whether a phenotype predicting a higher sensitivity to low drug doses would be relevant in environmental conditions, such as the ones encountered by humans in which high drug doses are available. In this report, we studied dose-response, dose-intake, and ratio-intake functions for intravenous cocaine self-administration in the laboratory rat. We show that individual differences in drug self-administration originate from vertical shift in the dose-response function. Thus, no matter the dose, drug intake is very high in some "vulnerable" subjects and very low in other "resistant" ones. Vulnerable subjects, the upward shifted ones, would then have a higher chance to develop drug abuse also when high drug doses are available. In conclusion, these results provide a solid foundation for the existence of a drug-vulnerable phenotype relevant for the etiology of addiction.

The dopaminergic hyper-responsiveness of the shell of the nucleus accumbens is hormone-dependent.

The dopaminergic projection to the shell of the nucleus accumbens is the most reactive to stress, reward and drugs of abuse and this subregion of the nucleus accumbens is also considered a target of therapeutic effects of atypical antipsychotic drugs (APD). In this report we show, by means of in vivo microdialysis and Fos immunohistochemistry, that the hyper-responsiveness which characterizes the dopaminergic transmission to the shell is dependent on glucocorticoid hormones. In Sprague-Dawley rats, after suppression of endogenous glucocorticoids by adrenalectomy, extracellular dopamine levels selectively decreased in the shell, whilst they remained unchanged in the core. This effect was observed in basal conditions, after a mild stress (vehicle injection), as well as after subcutaneous administration of morphine (2 mg/kg, s.c. ) or intraperitoneal injection of cocaine (15 mg/kg, i.p.). The decrease in dopamine observed in the shell had a postsynaptic impact, as shown by less induction of Fos-like proteins selectively in the shell in response to cocaine. However, the induction of Fos-like proteins by the full D1 agonist SKF82958 (1.5 mg/kg, i.p.) remained unchanged after adrenalectomy, suggesting that the changes in Fos expression after cocaine injection were likely to depend on changes in extracellular dopamine levels rather than on changes in postsynaptic sensitivity to dopamine. The effects of adrenalectomy were glucocorticoid-specific given that they were prevented by corticosterone treatment. This anatomical specificity in the control of neuronal activity by a hormonal input highlights the role of steroid hormones in shaping the functional activity of the brain.

Release of endogenous dopamine in cultured mesencephalic neurons: influence of dopaminergic agonists and glucocorticoid antagonists.

Several electrochemical techniques allow the measurement of dopamine release in freely moving animals and brain slices. In this report, we applied one of these techniques, coulometry, coupled to high-performance liquid chromatography (HPLC), to the study of dopamine release in primary cultures of embryonic mesencephalic dopaminergic neurons. Between day 9 and 33 of culture, concentrations of dopamine, above the detection threshold, were found in the incubation buffer (Krebs ringer buffer, KRB). Concentrations of dopamine in the incubation buffer reflected neuronal release as they were: (i) positively correlated with the number of tyrosine hydroxylase-positive dopamine neurons in the culture; (ii) tetrodotoxin (TTX) sensitive and Ca2+ dependent; (iii) increased by a depolarizing stimulus, e.g. K+ (20 mM), or by the indirect dopamine agonists amphetamine and cocaine; (iv) decreased by a hyperpolarizing stimulus, e.g. the dopamine D2-like receptor agonist quinpirole. Dopamine release in this model was also sensitive to the manipulation of glucocorticoids, potent modulators of dopamine release in vivo. Long-term treatment of the cell cultures with RU 39305, a selective antagonist of glucocorticoid receptors (GR), but not with spironolactone, a selective antagonist of mineralocorticoid receptors (MR), dose-dependently decreased K+-stimulated dopamine release. In conclusion, these results demonstrate an in vitro model that allows the studying of the release of endogenous dopamine in cell cultures and the effects of glucocorticoid hormones on the release dynamics.

Functional heterogeneity in dopamine release and in the expression of Fos-like proteins within the rat striatal complex.

The dorsolateral striatum, and the core and shell of the nucleus accumbens are three major anatomical regions of the striatal complex. The shell is considered as a part of the extended amygdala, and is involved in the control of motivation and reward. The core and the striatum are considered central to sensory motor integration. In this study we compared the responses of these three regions to mild stress and drugs of abuse by measuring extracellular dopamine (DA) concentrations and Fos-like immunoreactivity (Fos-LI). The results are summarrized as follows. (i) In unchallenged conditions, extracellular DA concentrations were highest in the dorsolateral striatum and lowest in the core, whereas Fos-LI was highest in the shell and lowest in the dorsolateral striatum. (ii) After challenges that increase DA by depolarizing DAergic neurons (injection stress or 2 mg/kg morphine), the shell presented the largest increase in DA levels and Fos-LI. (iii) After the administration of a DA-uptake blocker (15 mg/kg cocaine), the percentage increase in DA was still largest in the shell. However, the absolute increase in DA and Fos-LI in the shell and the dorsolateral striatum were similar. (iv) After a full D1 agonist (SKF82958), Fos-LI was highest in the shell and lowest in the dorsolateral striatum. In conclusion, the nucleus accumbens shell seems to be the area of the striatal complex most functionally reactive to stress and drugs of abuse. However, the dorsolateral striatum and the core appear functionally distinct, as for most of the parameters studied these two regions differed.

Individual differences in stress-induced dopamine release in the nucleus accumbens are influenced by corticosterone.

Stressful experiences, glucocorticoids hormones and dopaminergic neurons seems to interact in determining a higher propensity to develop drug abuse. In this report, we studied the acute interaction between these three factors. For this purpose, we compared stress-induced dopamine release in intact rats and in rats in which stress-induced corticosterone secretion was experimentally blocked. Ten-minute tail-pinch was used as a stressor and dopamine release estimated in the nucleus accumbens by using the microdialysis technique. Individual differences were also taken into account by comparing rats identified as either predisposed (HRs) or resistant (LRs) to develop self-administration of drugs of abuse, on the basis of their locomotor response to novelty. It was found that suppression of stress-induced corticosterone secretion significantly decreased stress-induced dopamine release. However, such an effect greatly differed between HR and LR rats. When corticosterone secretion was intact HR animals had a higher and longer dopamine release in response to stress than LRs. The blockade of stress-induced corticosterone secretion selectively reduced the dopaminergic response of HRs that did not differ from LRs anymore. These findings strength the idea that glucocorticoids could be involved in determining propensity to develop drug self-administration. In particular, these hormones could play a role in determining the higher dopaminergic activity that characterizes drug proned individuals.

Glucocorticoids and behavioral effects of psychostimulants. I: locomotor response to cocaine depends on basal levels of glucocorticoids.

In this study, we explored the influence of corticosterone, the major glucocorticoid in the rat, on the locomotor response to cocaine. In particular, in a first series of experiments, we determined the effects of suppressing endogenous glucocorticoids by adrenalectomy on a full dose-response curve of cocaine-induced locomotion and the influence, on this behavioral response, of different corticosterone concentrations, by implanting different corticosterone pellets in adrenalectomized rats. Adrenalectomy decreased the locomotor response to cocaine, inducing a vertical shift in the dose-response curve, and corticosterone dose-dependently reversed the decrease induced by adrenalectomy. The effects of adrenalectomy were fully replicated by the acute central infusion of corticosteroid receptor antagonists, and the action of glucocorticoids did not seem to depend on nonspecific effects such as a general alteration of motor responses or drug metabolism. Thus, neither adrenalectomy, corticosterone receptor antagonists nor corticosterone replacement modified saline-induced locomotion and the administration of corticosterone did not increase locomotion. Furthermore, adrenalectomy slightly increased brain concentrations of cocaine, an effect that cannot account for the decrease in drug-induced locomotion it induced. In a second series of experiments, we tested whether corticosterone levels at the time of adrenalectomy could influence the outcome of this surgical procedure on the locomotor response to cocaine. We thus adrenalectomized rats under different conditions resulting in different levels of the hormone. Corticosterone levels at the moment of adrenalectomy had dose-dependent long-term facilitatory effects on the response to the drug. These findings underline a facilitatory role of glucocorticoids in the behavioral effects of psychostimulant drugs.

Acute blockade of corticosterone secretion decreases the psychomotor stimulant effects of cocaine.

Previous reports have shown that long-term blockade of corticosterone secretion, by either adrenalectomy or repeated treatment with an inhibitor of corticosterone synthesis, metyrapone, profoundly reduces sensitivity to drugs of abuse. In this report we investigated whether acute blockade of corticosterone secretion has similar effects. Animals received a single injection of metyrapone (50 mg/kg SC) and were tested for their locomotor response to cocaine (15 mg/kg IP) 3 hours later. Acute metyrapone treatment reduced the locomotor response to cocaine by about 50%, and this effect was reversed by corticosterone (20 mg/kg SC). The behavioral effects of these treatments paralleled changes in plasma corticosterone levels 20 minutes after an injection of cocaine. Despite the differences in behavior and corticosterone levels, the brain levels of cocaine in these groups did not differ. These results indicate that the behavioral effects of cocaine can be modified by an acute pharmacological manipulation of corticosterone secretion.

Suppression of glucocorticoid secretion and antipsychotic drugs have similar effects on the mesolimbic dopaminergic transmission.

Specific antagonists of central dopaminergic receptors constitute the major class of antipsychotic drugs (APD). Two principal effects of APD are used as criteria for the pre-clinical screening of their antipsychotic action: (i) inhibition of basal and depolarization-induced activity of mesolimbic dopaminergic neurons; (ii) antagonism of the locomotor effects of dopaminergic agonists. Given that glucocorticoid hormones in animals increase dopamine release and dopamine-mediated behaviors and that high levels of glucocorticoids can induce psychotic symptoms in humans, these experiments examined whether inhibition of endogenous glucocorticoids might have APD-like effects on mesolimbic dopaminergic transmission in rats. It is shown that suppression of glucocorticoid secretion by adrenalectomy profoundly decreased (by greater than 50%): (i) basal dopaminergic release and the release of dopamine induced by a depolarizing stimulus such as morphine (2 mg/kg, s.c.), as measured in the nucleus accumbens of freely moving animals by microdialysis; (ii) the locomotor activity induced by the direct dopaminergic agonist apomorphine. The effects of adrenalectomy were glucocorticoid specific given that they were reversed by the administration of glucocorticoids at doses within the physiological range. Despite its profound diminution of dopaminergic neurotransmission, adrenalectomy neither modified the number of mesencephalic dopaminergic neurons nor induced gliosis in the mesencephalon or in the nucleus accumbens, as shown by tyrosine hydroxylase and glial fibrillary acidic protein immunostaining. In conclusion, these findings suggest that blockade of central effects of glucocorticoids might open new therapeutic strategies of behavioral disturbances.

Glucocorticoids have state-dependent stimulant effects on the mesencephalic dopaminergic transmission.

An increase in the activity of mesencephalic dopaminergic neurons has been implicated in the appearance of pathological behaviors such as psychosis and drug abuse. Several observations suggest that glucocorticoids might contribute to such an increase in dopaminergic activity. The present experiments therefore analyzed the effects of corticosterone, the major glucocorticoid in the rat, both on dopamine release in the nucleus accumbens of freely moving animals by means of microdialysis, and on locomotor activity, a behavior dependent on accumbens dopamine. Given that glucocorticoids have certain state-dependent neuronal effects, their action on dopamine was studied in situations differing in dopaminergic tonus, including during the light and dark phases of the circadian cycle, during eating, and in groups of animals differing in their locomotor reactivity to novelty. Dopaminergic activity is increased in the dark period, further increased during food-intake, and is higher in rats defined as high responders to novelty than in low responders. Corticosterone, peripherally administered in a dose that approximates stress-induced plasma concentrations, increased extracellular concentrations of dopamine, and this increase was augmented in the dark phase, during eating, and in high responder rats. Corticosterone had little or no effects in the light phase and in low responder rats. Corticosterone also stimulated locomotor activity, an effect that paralleled the release of dopamine and was abolished by neurochemical (6-hydroxydopamine) depletion of accumbens dopamine. In conclusion, glucocorticoids have state-dependent stimulant effects on mesencephalic dopaminergic transmission, and an interaction between these two factors might be involved in the appearance of behavioral disturbances.

Stress-induced sensitization and glucocorticoids. II. Sensitization of the increase in extracellular dopamine induced by cocaine depends on stress-induced corticosterone secretion.

Secretion of glucocorticoids seems to control stress-induced sensitization of the behavioral effects of drugs of abuse by acting on the mesencephalic dopaminergic transmission, the principal neural substrate of sensitization. In order to investigate the mechanisms of this interaction between glucocorticoids and dopamine, we studied the sensitization of the increase in extracellular concentration of dopamine induced by cocaine in male rats in which corticosterone secretion was either intact or blocked. Extracellular concentrations of dopamine were evaluated in the nucleus accumbens of freely moving animals by means of microdialysis. Metyrapone, an inhibitor of corticosterone synthesis, was used to block stress-induced corticosterone secretion. Food-restriction (90% of the initial body weight) was the stressor used to induce sensitization. It was found that metyrapone (100 mg/kg s.c. twice a day for 8 d) suppressed stress-induced sensitization of the increase in accumbens dopamine induced by cocaine (10 mg/kg, i.p.) and sensitization of cocaine-induced locomotion Metyrapone suppressed both the development and the expression of sensitization. Thus, sensitization was equally blocked when the metyrapone treatment started either 1 d before the start of food-restriction or 8 d later, that is, when food-restriction-induced sensitization to cocaine was already established. In conclusion, our results suggest that glucocorticoids modify sensitization of the behavioral effects of cocaine by acting on extracellular concentrations of dopamine. Since addictive properties of psychostimulants seem mediated by the increase in extracellular concentrations of dopamine they induce, these findings may have implications for the development of new therapeutic strategies of addiction.

Inhibition of corticosterone synthesis by Metyrapone decreases cocaine-induced locomotion and relapse of cocaine self-administration.

Several studies have recently shown that basal and stress-induced secretion of corticosterone may enhance vulnerability to drugs of abuse. In this report, we studied the effects of metyrapone, an inhibitor of the synthesis of corticosterone, on cocaine-induced locomotion and on the relapse of cocaine self-administration. Locomotor response to cocaine was studied because psychomotor effects of drugs have been shown to be related to their reinforcing properties. Self-administration was studied in the relapse phase since blockade of relapse is central to the therapy of addiction. Before these behavioral tests, rats in different experimental groups were injected subcutaneously with either metyrapone (100 mg/kg) or vehicle, twice a day for 8 days. Metyrapone treatment reduced cocaine-induced locomotor activity and relapse of cocaine self-administration, without inducing a nonspecific disruption of motor or food-directed behaviors. Under these experimental conditions, the metyrapone treatment totally blocked stress-induced corticosterone secretion but did not modify basal corticosterone levels. These results confirm the involvement of glucocorticoids in the pathophysiological mechanisms underlying vulnerability to drug abuse, and may have implications for the development of new therapeutic strategies of drug addiction.

Brain monoaminergic, neuroendocrine, and immune responses to an immune challenge in relation to brain and behavioral lateralization.

Host responses to immune challenges involve central neurotransmission, the hypothalamo-pituitary adrenal axis, and the immune system. In the present work, we investigated the possibility of an asymmetry in the modification of brain monoamine metabolism induced by a systemic injection of lipopolysaccharide (LPS) in adult female mice. We also studied the possible influence of behavioral lateralization, as assessed by a paw preference test, on the reactivity of the nervous, neuroendocrine, and immune systems to a LPS challenge. The results showed that LPS administration induced an enhanced brain activity as demonstrated by an increase in noradrenergic, serotoninergic, and dopaminergic metabolism. Increased serotonin metabolism, observed in the hypothalamus and hippocampus, only occurred on the left side. Furthermore, the increase in serotonin turnover in the medial hypothalamus, the elevation of plasma adrenocorticotropin levels, and the decrease in T lymphocyte proliferation were observed in right-handed and ambidextrous mice but not in left-handed animals. Taken together, the results demonstrate that an immune challenge could induce neurochemical, neuroendocrine, and immune responses similar to those of stress, suggesting that LPS may be a stress inducer. Interestingly, these responses that may be asymmetrically expressed appear to depend on behavioral lateralization.

Basal and stress-induced corticosterone secretion is decreased by lesion of mesencephalic dopaminergic neurons.

There is evidence that certain psychopathological conditions are accompanied by a dysfunction in both the hypothalamo-pituitary-adrenal axis and dopaminergic systems, although the relationship between these two systems is as yet unclear. In the present study we investigated the effect of a specific lesion of dopamine mesencephalic neurons (Ventral Tegmental Area) on basal and stress-induced corticosterone secretion. Three weeks after injection of 6-OHDA, there was a depletion in dopamine in the frontal cortex and in the ventral and dorsal striatum, whereas norepinephrine and serotonin levels were unchanged. The dopamine-lesioned rats exhibited a lower basal and stress-induced corticosterone secretion than the sham-lesioned animals. The results indicate that the dopaminergic system may have a stimulatory influence on the hypothalamo-pituitary-adrenal axis.

Effects of intracerebral dopaminergic grafts on behavioural deficits induced by neonatal 6-hydroxydopamine lesions of the mesotelencephalic dopaminergic pathway.

The functional capabilities of dopamine neuron-rich grafts implanted into the accumbens and striatal regions in neonatal rats were evaluated in a series of behavioural tests. The ascending mesotelencephalic dopaminergic system of three-day-old rat pups was bilaterally lesioned by injecting 6-hydroxydopamine at the level of the lateral hypothalamus. Five days later a suspension containing dopaminergic neurons obtained from embryonic day 14 mesencephali was injected bilaterally into the striatal complex. The functional effects of such grafts were evaluated using behavioural tests for which it was known that the performance of the animals is changed following the lesion of the mesotelencephalic pathway and for which the influence of dopaminergic grafts implanted into adult hosts have previously been described. The dopamine-rich grafts compensated for the modifications of the locomotor responsiveness to amphetamine and apomorphine induced by neonatal dopamine depletion. However, the grafts were unable to restore more complex behaviours such as hoarding for food pellets, schedule-induced polydipsia and learning behaviours. Moreover, the neonatal transplants induced additional deficits such as catalepsia, nocturnal hyperactivity and day-time hyperactivity during food deprivation. It was concluded that, at least in the present paradigm, the implantation into neonatal brain does not lead to any greater functional recovery than that observed after implantation during adulthood.