Miguel Pérez de la Mora

Role of dopamine receptor mechanisms in the amygdaloid modulation of fear and anxiety: Structural and functional analysis

Dopamine plays an important role in fear and anxiety modulating a cortical brake that the medial prefrontal cortex exerts on the anxiogenic output of the amygdala and have an important influence on the trafficking of impulses between the basolateral (BLA) and central nuclei (CeA) of amygdala. Dopamine afferents from the ventral tegmental area innervate preferentially the rostrolateral main and paracapsular intercalated islands as well as the lateral central nucleus of amygdala activating non-overlapping populations of D1- and D2-dopamine receptors located in these structures. Behaviorally, the intra-amygdaloid infusion of D1 agonists and antagonists elicits anxiogenic and anxiolytic effects respectively on conditioned and non-conditioned models of fear/anxiety suggesting an anxiogenic role for D1 receptors in amygdala. The analysis of the effects of D2 agonists and antagonists suggest that depending of the nature of the threat the animal experiences in anxiety models either anxiogenic or anxiolytic effects are elicited. It is suggested that D1- and D2-dopamine receptors in the amygdala may have a differential role in the modulation of anxiety. The possibility is discussed that D1 receptors participate in danger recognition facilitating conditioned-unconditioned associations by the retrieval of the affective properties of the unconditioned stimuli, and in the control of impulse trafficking from cortical and BLA regions to BLA and CeA nuclei respectively whereas D2 receptors have a role in setting up adaptive responses to cope with aversive environmental stimuli.

The Vigilance Promoting Drug Modafinil Increases Extracellular Glutamate Levels in the Medial Preoptic Area and the Posterior Hypothalamus of the Conscious Rat: Prevention by Local GABAA Receptor Blockade

The effects of modafinil on glutamatergic and GABAergic transmission in the rat medial preoptic area (MPA) and posterior hypothalamus (PH), are analysed. Modafinil (30–300 mg/kg) increased glutamate and decreased GABA levels in the MPA and PH. Local perfusion with the GABAA agonist muscimol (10 μM), reduced, while the GABAA antagonist bicuculline (1 μM and 10 μM) increased glutamate levels. The modafinil (100 mg/kg)-induced increase of glutamate levels was antagonized by local perfusion with bicuculline (1 μM). When glutamate levels were increased by the local perfusion with the glutamate uptake inhibitor L-trans-PDC (0.5 mM), modafinil produced an additional enhancement of glutamate levels. Modafinil (1–33 μM) failed to affect [3H]glutamate uptake in hypothalamic synaptosomes and slices. These findings show that modafinil increases glutamate and decreases GABA levels in MPA and PH. The evidence that bicuculline counteracts the modafinil-induced increase of glutamate levels strengthens the evidence for an inhibitory GABA/glutamate interaction in the above regions controlling the sleep-wakefulness cycle.

Circadian rhythmicity in the GABAergic system in the suprachiasmatic nuclei of the rat

The participation of GABAergic mechanisms in the regulation of circadian rhythmicity by the suprachiasmatic nuclei (SCN) has been suggested from different lines of evidence. Little is known, however, whether GABA synthesis, release, uptake or content within the SCN may show a circadian pattern. The present results show that the activity of the GABAergic system within the SCN region of the rat exhibits circadian rhythmicity, which is manifested by correlative changes of the GABA content and the glutamic acid decarboxylase activity under the light/dark cycle, and by changes in the GABA content in animals kept under constant darkness.

Modafinil and cortical γ-aminobutyric acid outflow. Modulation by 5-hydroxytryptamine neurotoxins

Abstract The acute or chronic administration of modafinil, (diphenyl-methyl-sulfinyl-2-acetamide, 30 mg/kg s.c.) decreased γ-aminobutyric acid (GABA) outflow from the cerebral cortex of freely moving guinea pigs and rats. In 5,7-dihydroxytryptamine intracerebroventricularly pretreated guinea pigs, the effect of modafinil on GABA outflow was reversed and the noradrenaline cortical levels increased. Prazosin (35,8 ng/kg i.p.) blocked the drug-induced increase in GABA efflux. In vitro experiments, performed in rat cortical slices, showed that modafinil failed to affect [3H]GABA release and uptake as well as glutamic acid decarboxylase activity. In conclusion, our results suggest that the balance between central noradrenaline and 5-hydroxytryptamine transmission is important for the regulation by modafinil of the GABAergic release in the cerebral cortex.

Anxiolytic-like effects of the selective metabotropic glutamate receptor 5 antagonist MPEP after its intra-amygdaloid microinjection in three different non-conditioned rat models of anxiety

The intercalated islands, clusters of dopamine D1‐rich GABAergic neurons, are interposed between the basolateral and central nuclei of the amygdala, and control the traffic of nerve impulses between these two structures. Metabotropic glutamate receptor 5‐ (mGluR5)‐like immunoreactivity was studied by immunohistochemistry in this part of the amygdala and was found to be mainly restricted to the central and basolateral nuclei and to a lesser extent to the medial paracapsular intercalated islands. The role of the metabotropic glutamate receptor 5 in the modulation of anxiety has been studied in this region by microinjection of small volumes of the mGluR5 antagonist 2‐methyl‐6(phenylethenyl) pyridine (MPEP), with restricted diffusion from its injection site, into the rostral amygdala near the basolateral and central amygdaloid nuclei and the intercalated islands, and the behavior of the animals was evaluated using three non‐conditioned models of anxiety. Anxiolytic‐like effects were observed after MPEP administration in all tests used. In the White and Black Box test, MPEP (2 nmol per side) significantly increased the time spent in the white compartment of the box. In line with these results, MPEP (8 nmol per side) increased the exploration of the open arms of the Elevated Plus‐Maze. Burying behavior latency was increased and burying behavior itself was decreased in the Shock‐Probe Burying test. It is suggested that anxiolytic effects of MPEP may be mediated by blockade of mGluR5 in the basolateral and/or central amygdaloid nuclei, reducing glutamate transmission in the basolateral amygdaloid nuclei and glutamate output from the central amygdala.

Free amino acids and glutamate decarboxylase activity in brain of mice during drug-induced convulsions

Abstract Previous administration of l -glutamic acid-γ-hydrazide (GAH) to mice did not protect them against the convulsant action of thiosemicarbazide, methionine sulfoximine, insulin, or pentylenetetrazol (Metrazol). The concentrations of some free amino acids were measured in the brains from these mice at the moment of convulsions. The changes in free amino acid concentrations produced by the convulsant agents used were in general similar whether GAH had been administered or not. In the first case, however, the changes were exerted on the altered pattern of amino acids obtained by the previous GAH treatment. In all cases when GAH and the convulsant agent were injected and convulsions were produced, a two- to four-fold increase of γ-aminobutyric acid (GABA) concentration was found in brain. In other experiments, it was found that GAH administration increased both free and bound GABA concentrations. When a single convulsant dose of GAH was injected, brain glutamate decarboxylase activity progressively decreased with time. The maximal glutamate decarboxylase inhibition was observed at the onset of convulsions; at this moment GABA levels were increased. γ-Aminobutyric aminotransferase activity was diminished more intensely before the onset than at the occurrence of the convulsive state. Similarly, after the injection of a convulsant dose of amino-oxyacetic acid, glutamate decarboxylase activity was decreased at the onset of convulsions, whereas γ-aminobutyric transferase activity was totally inhibited; GABA levels were significantly increased. Anticonvulsant doses of amino-oxyacetic acid protected mice against convulsions induced by the simultaneous administration of GAH and pyridoxal phosphate. Glutamate decarboxylase activity was found equally diminished in protected and in nonprotected mice in comparison with control animals. It is concluded that the inhibition of glutamate decarboxylase activity, independently of the total concentration of GABA in brain, may be a factor involved in the production of some types of convulsions, and probably the anticonvulsant action of amino-oxyactic acid is not related to its effect on GABA metabolism in brain.

Anxiolytic effects of intra-amygdaloid injection of the D1 antagonist SCH23390 in the rat.

The intercalated islands are intra-amigdaloid clusters of D1 receptor rich GABAergic neurons, which control impulse traffic between the basolateral complex and the central nucleus of the amygdala. As dopaminergic transmission within the amygdala may play a role in anxiety, the effect of the D1 antagonist SCH23390 microinjected mainly close to the rostral intercalated islands in rats was studied, using the White and Black Box test. SCH23390 reduced anxiety by an increase in the latency of the first entry into the black compartment and by an increase in the total time spent in the white compartment of the White and Black Box test, while there was no significant modification of locomotion. It is suggested that blockade of D1 receptors in the rostral intercalated islands may reduce anxiety through a reduction of GABA-mediated dishinibition of the central amygdaloid nucleus.

Cholecystokinin-8 increases K+-evoked [3H]γ-aminobutyric acid release in slices from various brain areas

[3H] gamma-Aminobutyric acid (GABA) release was studied in rat brain slices in the absence or presence of cholecystokinin-8 (CCK-8). [3H]GABA release under the conditions used was Ca(2+)-dependent and insensitive to the presence of the glial uptake blocker beta-alanine. While the basal release of [3H]GABA was not affected by CCK-8, the K(+)-stimulated release of [3H]GABA was significantly enhanced by 300 nM of CCK-8 in the caudate putamen, the substantia nigra, the hippocampal formation and the parietofrontal cortex. In the cerebral cortex the CCK-8 enhancement of [3H]GABA release was concentration-dependent and abolished by the CCKB receptor antagonists PD135,158 (1.0 nM) and L-365,260 (100 nM). A significant counteraction of the CCK-8 action was also found with the CCKA receptor antagonist L-364,718 (100 nM) but only in concentrations at which both CCKA and CCKB receptors are blocked. No CCK-8 effects on [3H]GABA release were observed when tetrodotoxin was superfused 5 min before the K(+)-induced [3H]GABA release. It is suggested that the enhancing actions of CCK-8 on K(+)-stimulated [3H]GABA release is mainly related to an activation of CCKB receptors.

The intercalated paracapsular islands as a module for integration of signals regulating anxiety in the amygdala.

The intercalated paracapsular (IPC) islands are clusters of dopamine-D1-and μ-opioid 1-receptor rich GABAergic neurons which surround the rostral half of the basolateral complex of the amygdala (BLA) giving rise to several subgroups which can be further subdivided. IPC cells are small-sized and have an axonal and dendritic pattern which differs according to the group they belong. Functionally, IPC neurons are endowed with unique properties that set them apart from other amygdaloid interneurons and allow them to participate in integrative functions. Consistent with this role IPC cells usually remain confined within the amygdala where they receive BLA and cortical inputs and interact synaptically with each other. They project into both the central (CeA) and medial (MeA) amygdaloid nuclei. Their main effect at the network level seems to control the trafficking of nerve impulses to the main input (BLA) and output (CeA) stations of the amygdala. Such a task seems to be accomplished by providing feedforward inhibition to BLA neurons from putative inputs of the medial prefrontal cortex (mPFC) and to CeA from both mPFC and BLA projections. Current experimental evidence will be discussed suggesting that through feedforward inhibitory effects on specific amygdaloid nuclei IPC neurons participate in the maintenance of basal anxiety as well as in the modulation of unconditioned and conditioned fear, and in the process of fear extinction. This article is part of a Special Issue entitled: Brain Integration.

Effects of the vigilance promoting drug modafinil on the synthesis of GABA and glutamate in slices of rat hypothalamus.

The effects of the vigilance promoting drug modafil were studied ex vivo (100 mg/kg; i.p.) and in vitro (10-1000 microM modafinil) on the synthesis of [3H]gamma-aminobutyric acid ([3H]GABA) and [3H]glutamate from [3H]glutamine within the rat hypothalamus. No effects of modafinil were observed on the overall synthesis of these neurotransmitters nor, in vitro (1-33 microM modafinil) on other parameters related to the compartmentalization of their synthesis (glutamate decarboxylase and phosphate-activated glutaminase activities, and [3H]glutamine uptake). It is suggested on these grounds, that the modafinil-induced reductions and increases in regional GABA and glutamate extracellular levels respectively using in vivo microdialysis may be a consequence of an indirect effect of modafinil on these neurons.