Autoradiographic localisation of [3H]2-BFI imidazoline I2 binding sites in mouse brain.

Imidazoline I2 binding sites are heterogeneous in nature and have been observed in the brain of a number of species. Development of specific imidazoline I2 radioligands, such as [3H]2-BFI and [3H]BU224, that have a high affinity for the imidazoline I2 binding site, has enabled the central distribution of these sites to be mapped. Extensive studies have been conducted on the rat brain with a number of radioligands. However, to date a comprehensive analysis of imidazoline I2 ligand binding in mouse brain has not been completed. In the present work we describe levels of [3H]2-BFI specific binding found throughout the mouse brain. [3H]2-BFI (2 nM) showed discrete regional distribution which was readily displaced by saturating concentrations of the specific imidazoline I2 ligand BU224. The highest levels of [3H]2-BFI specific binding were found in the dorsal raphe, paraventricular thalamus and nucleus accumbens. Moderate levels were found throughout the lining of the aqueduct, lateral ventricle, lateral 4th ventricle, 4th ventricle, 3rd ventricle, but not the dorsal 3rd ventricle. Based on the loss of [3H]idazoxan binding in brain homogenates from monoamine oxidase-A and B (MAO-A and MAO-B) deficient mice it has been suggested that imidazoline I2 binding sites are predominantly on MAO. Consistent with this hypothesis the regional distribution of [3H]2-BFI shows some overlap with that previously reported for MAO. However, in the rat imidazoline I2 binding sites have been shown to be heterogeneous in nature and it is likely [3H]2-BFI is binding to multiple imidazoline I2 binding sites within mouse brain.

Increased 5-HT2A receptor expression and function following central glucocorticoid receptor knockdown in vivo.

Central glucocorticoid receptor function may be reduced in depression. In vivo modelling of glucocorticoid receptor underfunctionality would assist in understanding its role in depressive illness. The role of glucocorticoid receptors in modulating 5-HT(2A) receptor expression and function in the central nervous system (CNS) is presently unclear, but 5-HT(2A) receptor function also appears altered in depression. With the aid of RNAse H accessibility mapping, we have developed a 21-mer antisense oligodeoxynucleotide (5'-TAAAAACAGGCTTCTGATCCT-3', termed GRAS-5) that showed 56% reduction in glucocorticoid receptor mRNA and 80% down-regulation in glucocorticoid receptor protein in rat C6 glioma cells. Sustained delivery to rat cerebral ventricles in slow release biodegradable polymer microspheres produced a marked decrease in glucocorticoid receptor mRNA and protein in hypothalamus (by 39% and 80%, respectively) and frontal cortex (by 26% and 67%, respectively) 5 days after a single injection, with parallel significant up-regulation of 5-HT(2A) receptor mRNA expression (13%) and binding (21%) in frontal cortex. 5-HT(2A) receptor function, determined by DOI-head-shakes, showed a 55% increase. These findings suggest that central 5-HT(2A) receptors are, directly or indirectly, under tonic inhibitory control by glucocorticoid receptor.

Chronic administration of 2-(2-benzofuranyl)-2-imidazoline (2-BFI) induces region-specific increases in [3H]2-BFI binding to rat central imidazoline I2 sites.

Chronic administration of I(2) ligands increases the density of central I(2) sites as measured in brain homogenates. Here, we have used autoradiography to examine whether the increase in I(2) site density induced by chronic administration of 2-(2-benzofuranyl)-2-imidazoline (2-BFI) is uniform across brain regions. We dosed rats with 2-BFI 7 mg/kg or with saline vehicle i.p. over 96 days. Compared with vehicle-treated rats, this treatment significantly increased specific [(3)H]2-BFI binding only in the arcuate nucleus and area postrema, by 63% and 67% respectively. There were no significant effects in the pineal gland or interpeduncular nucleus which, like the arcuate nucleus and area postrema, are rich in I(2) sites. These data indicate that chronic administration of 2-BFI selectively alters radioligand binding in two I(2) rich brain ideas, namely the arcuate nucleus and area postrema, suggesting there may be more than one population of I(2) sites in the rat brain.

Potential serotonergic and noradrenergic involvement in the discriminative stimulus effects of the selective imidazoline I2-site ligand 2-BFI.

The functional significance of imidazoline I2 binding sites is unknown but microdialysis studies have indicated that the administration of I2-site ligands leads to an increase in extracellular levels of monoamines. The specific I2-site ligand 2-(-2-benzofuranyl)-2-imidazoline (2-BFI) generates a cue in drug discrimination, thereby indicating functional consequences of I2-site ligand binding. In the present work, we explored the ability of selective noradrenergic and serotonergic ligands to substitute for 2-BFI. Hooded Lister rats were trained in two-lever operant chambers with condensed milk reward to distinguish 2-BFI (7 mg/kg) from saline vehicle, by pressing the correct lever to a predetermined success criterion. Training sessions were then interspersed with sessions in which animals were administered test substances and the proportion of lever presses on the 2-BFI-associated lever (substitution) recorded. Several agents exhibited significant partial substitution for 2-BFI: The monoamine-releasing agents D-amphetamine and fenfluramine dose-dependently substituted for 2-BFI, while norepinephrine (desipramine, reboxetine) and serotonin (clomipramine, citalopram) reuptake inhibitors substituted at one or more doses. Further investigation using specific receptor agonists and antagonists indicated a possible role for activation of alpha1-adrenoceptors but failed to support involvement of alpha2-adenoceptor, beta-adrenoceptor or 5-HT1A receptor activation. These results support the concept that the 2-BFI cue may contain both noradrenergic and serotonergic components.

Characterization of the discriminable stimulus produced by 2-BFI: effects of imidazoline I(2)-site ligands, MAOIs, beta-carbolines, agmatine and ibogaine.

1. The molecular nature and functions of the I(2) subtype of imidazoline binding sites are unknown but evidence suggests an association with monoamine oxidase (MAO). Rats can distinguish the selective imidazoline I(2)-site ligand 2-BFI from vehicle in drug discrimination, indicating functional consequences of occupation of these sites. We have used drug discrimination to investigate the nature of the discriminable stimulus, especially in relation to MAO inhibition. 2. Following training to distinguish 2-BFI 7 mg kg(-1) i.p. from saline vehicle in two-lever operant-chambers, male Hooded Lister rats underwent sessions where test substances were given instead and the proportion of lever presses on the 2-BFI-associated lever (substitution) recorded. 3. 2-BFI; its cogeners BU216, BU224, BU226 and LSL60101; the reversible MAO-A inhibitors moclobemide and RO41-1049; the beta-carbolines harmane, norharmane and harmaline which also reversibly inhibit MAO-A, and the anti-addictive substance ibogaine exhibited potent, dose-dependent substitution for 2-BFI. 4. Agmatine, and LSL60125 substituted at one dose only. The reversible MAO-B inhibitors lazabemide and RO16-1649; the sigma(2)-site ligand SKF10,047 and the I(2A)-site ligand, amiloride, failed to substitute. The irreversible inhibitor of MAO, deprenyl, substituted for 2-BFI while clorgyline did not. 5. These results suggest imidazoline I(2) site ligands produce a common discriminable stimulus that appears associated with reversible inhibition of MAO-A rather than MAO-B, possibly through increases in extracellular concentration of one or more monoamines. Ibogaine exhibits a commonality in its subjective effects with those of I(2)-site ligands.

Reduced salivary cortisol in children with comorbid Attention deficit hyperactivity disorder and oppositional defiant disorder.

OBJECTIVES: There is growing interest in the role of the hypothalamic-pituitary-adrenal (HPA) axis in neuropsychiatric disorders and there is some evidence that the HPA axis may be underfunctional in behaviorally disturbed children. However, co-morbidity is common in childhood neuropsychiatric disorders. Stimulant medication is widely used in the treatment of Attention-deficit hyperactivity disorder (ADHD) and can increase cortisol secretion when given acutely. We therefore set out to determine the whether salivary cortisol would be reduced in a group of children with ADHD/ODD (Oppositional-defiant disorder) and to examine the effect of stimulant medication on any such relationship. DESIGN: Salivary cortisol was determined in thirty-two children with co-morbid ADHD and Oppositional-defiant disorder (ODD) according to DSM-IV criteria, compared to twenty-five healthy controls of similar age and ethnic background. Data were analysed according to prescription of stimulant medication in the patient group. RESULTS: Salivary cortisol was significantly lower in the ADHD/ODD group than in the controls. Further analysis revealed that this reduction was restricted to the subgroup of patients not prescribed stimulant medication. CONCLUSIONS: The results support the possibility of a dysfunction of control of the HPA axis in these behaviorally disturbed children. A reduction in salivary cortisol could reflect underarousal, an elevated threshold for detection of stressors or a subsensitivity of the HPA axis itself. It remains to be determined whether the ability of stimulant medications to negate the apparent deficit in cortisol secretion in these ADHD/ODD patients is an unrelated consequence of increased dopamine release or a reflection of their therapeutic benefit. The use of stimulant medication for co-existing ADHD should be taken into account in future studies of cortisol in behaviorally disturbed children.