Influence of restraint stress, corticosterone and betamethasone on brain amine levels

Neurochemical Anatomy of Cushing's Syndrome

The neurochemical anatomy underlying Cushing's syndrome is examined for regional brain metabolism as well as neurotransmitter levels and receptor binding of biogenic amines and amino acids. Preliminary studies generally indicate that glucose uptake, blood flow, and activation on fMRI scans decreased in neocortical areas and increased in subcortical areas of patients with Cushing's syndrome or disease. Glucocorticoid-mediated increases in hippocampal metabolism occurred despite in vitro evidence of glucocorticoid-induced decreases in glucose uptake or consumption, indicating that in vivo increases are the result of indirect, compensatory, or preliminary responses. In animal studies, glucocorticoid administration decreased 5HT levels and 5HT1A receptor binding in several brain regions while adrenalectomy increased such binding. Region-specific effects were also obtained in regard to the dopaminergic system, with predominant actions of glucocorticoid-induced potentiation of reuptake blockers and releasing agents. More in-depth neuroanatomical analyses are warranted of these and amino acid-related neurotransmission.

Spontaneous activity and brain 5-hydroxyindole levels measured in rats tested in two designs of elevated X-maze

The spontaneous activity of rats tested both acutely and chronically (15 minutes per day for 25 days) in an elevated X-maze composed entirely of open runways was found to be significantly less (P less than 0.01) than that measured for rats tested in a maze of similar dimensions composed entirely of enclosed runways. Acute exposure to both mazes caused significant increases (P less than 0.01) in plasma corticosterone when compared with unstressed control rats. Chronic exposure to the open, but not the enclosed maze caused a significant (P less than 0.01) attenuation of this response. Chronic exposure to the open maze caused significant increases (P less than 0.01) in the concentrations of 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) in hippocampus, hypothalamus and cerebral cortex when compared with unstressed control rats. When compared with the data for the rats tested repeatedly in the enclosed maze, chronic exposure to the open maze increased the 5-HT concentrations in hypothalamus (P less than 0.05) and cerebral cortex (P less than 0.01) and the 5-HIAA concentrations in hypothalamus (P less than 0.01) and hippocampus (P less than 0.01). The spontaneous locomotor activity of the rats tested in the open maze, correlated significantly (P less than 0.01) with plasma corticosterone and the 5-HIAA concentrations in hippocampus (P less than 0.01), hypothalamus (P less than 0.05) and cerebral cortex (P less than 0.01). In the rats tested in the enclosed maze, spontaneous activity only correlated significantly (P less than 0.01) with hippocampal 5-HIAA. It is concluded that the study has revealed clear differences in the behavioral, plasma corticosterone and brain 5-hydroxyindole responses to the two mazes but that the results do not provide unequivocal evidence that these differences occurred because the open maze was more aversive than the enclosed. It is also concluded that the study provides further support for the hypothesis that 5-HT turnover in the hippocampus may be directly related to the level of spontaneous locomotor activity.

Brain serotonin and catecholamine responses to repeated stress in rats

This study was designed to compare the effects of single and repeated administration of a discrete 2-min restraint stress on serotonin (5-HT) and catecholamine neuron activity in various regions of rat brain. A single 2-min restraint stress significantly increased the 5-hydroxyindoleacetic acid (5-HIAA) and 5-HT responses in hypothalamus and cerebral cortex and the 5-HIAA response in brainstem. A second 2-min restraint stress applied 90 min after the initial stress did not appreciably alter the steady-state concentrations of 5-HIAA and 5-HT nor did it produce any further changes in the 5-HIAA and 5-HT responses compared to those seen following a single stress in these 3 brain regions. In addition, the synthesis rate of 5-HT in anterior hypothalamus, posterior hypothalamus, hippocampus and brainstem was not altered by a second stress applied 90 min after the initial stress. In contrast, a second 2-min restraint stress applied 30 or 60 min after the initial stress significantly increased the 5-HIAA concentration in hypothalamus, cerebral cortex and brainstem. Also, the synthesis rate of 5-HT was greater following application of a second stress at 30 min than following either a single stress or a second stress applied at 90 min. Following application of a single 2-min restraint stress the hypothalamic concentration of norepinephrine (NE) was significantly decreased at 5 min after onset of the stress and returned to prestress levels by 15 min; the hypothalamic dopamine (DA) concentration was significantly increased at 30 min after the onset of the stress, while the hypothalamic epinephrine (EPI) concentration remained unchanged. A second 2-min restraint stress applied at 30 min markedly lowered NE concentrations in whole and mediobasal hypothalamus but not in laterobasal hypothalamus, and the NE concentrations remained decreased for a period lasting at least 60 min; there was a significant decrease in the hypothalamic EPI concentration 60 min after application of the second stress at 30 min. In addition, the synthesis rate of catecholamines was significantly greater in anterior but not in posterior hypothalamus after application of a second stress 30 min after the initial stress than following either a single stress or a second stress applied at 90 min. Negative correlations were demonstrated between increased synthesis rates of both hypothalamic 5-HT and anterior hypothalamic catecholamines and decreased corticosterone response to single and repeated stress.(ABSTRACT TRUNCATED AT 400 WORDS)

Mechanism of decline in rat brain 5-hydroxytryptamine after induction of liver tryptophan pyrrolase by hydrocortisone: roles of tryptophan catabolism and kynurenine synthesis

1 Two mechanisms have been proposed to explain the decline in brain tryptophan and 5-hydroxytryptamine (5-HT) after administration of hydrocortisone and the subsequent induction of liver pyrrolase. These are depletion of tryptophan by high rates of tryptophan catabolism and inhibition of tryptophan uptake by elevated levels of the tryptophan catabolite, kynurenine.2 The increase in plasma kynurenine after hydrocortisone injection (25 mg/kg) was small, and kynurenine, at a concentration ten fold greater, did not inhibit tryptophan uptake by brain as measured by the Oldendorf technique. Thus, inhibition of tryptophan uptake by kynurenine is not an important mechanism in the control of brain tryptophan and 5-HT.3 The decline in brain tryptophan after hydrocortisone was comparable to that seen in other tissues, which comprise more than half of the body weight of a rat.4 The total decline in free tryptophan stores in whole animals treated with hydrocortisone was estimated to be about 450 mug. This amount of tryptophan would be catabolized by tryptophan pyrrolase in about 20 min, when the enzyme is induced, according to an earlier estimate of the rate of tryptophan catabolism in vivo.5 Tryptophan pyrrolase activity remains high for much longer than 20 min, suggesting that there is net protein catabolism, which releases tryptophan and prevents non-protein tryptophan levels falling very far.6 These results demonstrate that the decline in brain tryptophan and 5-HT after hydrocortisone is caused by depletion of tryptophan stores due to the high activity of tryptophan pyrrolase. However, our data suggest that this effect is diminished by release of tryptophan from proteins. Thus, peripheral protein metabolism may be an important factor in the control of brain tryptophan levels and 5-HT synthesis.

Liver and brain tryptophan metabolism following hydrocortisone administration to rats and gerbils

1 Liver tryptophan pyrrolase activity is low in the mongolian gerbil (Meriones unguiculatus) and is not induced by hydrocortisone (5 mg/kg). In contrast, there is measurable activity in the rat liver and this is induced by hydrocortisone. In vivo measurements confirmed the absence of induction in gerbils but suggested that they were able to metabolize tryptophan. However no detectable pyrrolase activity was found in any other tissues either before or after hydrocortisone. 2 In agreement with previous observations hydrocortisone decreased rat brain 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) 6 h after administration. Brain tryptophan concentrations were also decreased at this time. In contrast, hydrocortisone did not alter gerbil brain 5-HT, 5-HIAA or trytophan. alpha-Methyltryptophan activated hepatic tryptophan pyrrolase and decreased brain 5-HT and 5-HIAA in both animals. 3 Results suggest that the decrease in rat brain 5-HT and 5-HIAA following hydrocortisone may be associated with the rise in liver tryptophan pyrrolase and that the brain amine changes are mediated through the decrease in brain tryptophan concentration.

Effects of immobilization on rat liver tryptophan pyrrolase and brain 5-hydroxytryptamine metabolism

1. Rat liver tryptophan pyrrolase increased on immobilization. The concentration of 5-hydroxyindoleacetic acid in the brain also rose and that of 5-hydroxytryptamine fell.2. When adrenalectomized rats were immobilized pyrrolase activity did not rise and brain 5-hydroxytryptamine concentration fell to a lesser extent but the 5-hydroxyindoleacetic acid concentration rose as in intact animals.3. When intact rats were injected with the pyrrolase inhibitor Allopurinol both the increase of pyrrolase and the fall of 5-hydroxytryptamine on immobilization were less prominent but the concentration of 5-hydroxyindoleacetic acid rose as before. Allopurinol did not affect the changes in immobilized adrenalectomized rats.4. Immobilization thus appears to cause (a) decreased brain 5-hydroxytryptamine synthesis resulting from pyrrolase induction and (b) increased 5-hydroxytryptamine breakdown by a more direct effect on the brain. Results of experiments on rats injected with lysergic acid diethylamide, and with alpha-methyltryptophan or probenecid are consistent with the above interpretation.5. The 5-hydroxytryptamine and 5-hydroxyindoleacetic acid changes were maximal after 5-6 hours' immobilization and became less on more prolonged immobilization, which suggests regulatory changes.