Effects of repeated lithium administration on the subcellular distribution of 5-hydroxytryptamine in rat brain.

1 The content and distribution of 5-hydroxytryptamine (5-HT) between subcellular fractions from rat whole brain (excluding cerebellum) were examined following repeated lithium administration. 2 Lithium chloride (3 mEq/kg body wt. s.c.) administered twice daily for 3 days produced no change in the 5-HT content of primary subcellular fractions (P1-nuclear; P2-crude synaptosomal; SNT-soluble) measured on the 4th day. 3 Similarly, repeated lithium treatment alone did not appear to produce increases in the 5-HT content of either cytoplasmic (S) or vesicular (M2) fractions derived from hypo-osmotically disrupted synaptosomes (P2) when compared to control rats receiving NaCl only. 4 One hour after monoamine oxidase inhibition with tranylcypromine, there was a further selective 25% increase in 5-HT accumulation in the lithium-treated rats over control values in the soluble cytoplasmic fraction (S) and in fractions containing occluded cytoplasm only. This increase did not occur in the synaptic vesicle fraction (M2). This corresponds to an increase in 5-HT turnover rate due to the lithium treatment of approx. 50%. 5 These findings lend additional support to the hypothesis that lithium treatment alters the intraneuronal storage or compartmentation of 5-HT between vesicles and cytoplasm.

Interactions between vasopressin and glucagon on ketogenesis and oleate metabolism in isolated hepatocytes from fed rats.

Vasopressin (10nM) inhibited ketogenesis (56%) in hepatocytes from fed rats when oleate (1 mM) was the substrate, but had no effect with butyrate (10mM). The hormone increased the accumulation of lactate and stimulated the esterification of [1(-14)C]oleate (70%). These effects of vasopressin were reversed by glucagon (10 nM). The physiological implications of these findings are discussed.

Electroconvulsive shock increases the behavioural responses of rats to brain 5-hydroxytryptamine accumulation and central nervous system stimulant drugs.

1 A single electroconvulsive shock (ECS) of 150 V for 1 s increased the concentration of rat brain 5-hydroxyindoleacetic acid (5-HIAA) but did not alter brain 5-hydroxytryptamine (5-HT) or tryptophan concentrations 3 h later. 2 A single ECS decreased 5-HT synthesis 3 h and 6 h later. Synthesis was back to normal after 24 hours. The ECS-treated rats did not show greater hyperactivity produced by the increased brain 5-HT accumulation following administration of L-tryptophan and tranylcypromine at any time up to 24 h later. This suggests that a single electroshock does not alter 5-HT functional activity. 3 Twenty-four hours after the final ECS of a series of 10 shocks given once daily, the rats were given tranylcypromine and L-tryptophan. They displayed greater hyperactivity than control rats not treated with ECS, suggesting that ECS increases 5-HT functional activity. Brain concentrations of 5-HT, 5-HIAA and tryptophan were then unchanged by ECS. 5-HT synthesis and accumulation of 5-HT following tranylcypromine and L-tryptophan were not altered by ECS. 4 The hyperactivity following administration of the 5-HT agonist 5-methoxy N,N-dimethyltryptamine was enhanced by repeated (10 day) ECS, suggesting altered post-synaptic responses to 5-HT receptor stimulation. 5 Repeated ECS enhanced locomotor activity following tranylcypromine and L-DOPA. It did not alter brain noradrenaline or dopamine concentrations. 6 The latent period before a pentylenetetrazol-induced convulsion was shortened by repeated ECS. 7 Following repeated ECS there appears to be increased neuronal sensitivity to certain stimuli producing centrally mediated behavioural stimulation. This is discussed in relation to the mechanism by which electroconvulsive therapy (ECT) produces its therapeutic effect.

Elevation of brain GABA concentrations with amino-oxyacetic acid; effect on the hyperactivity syndrome produced by increased 5-hydroxytryptamine synthesis in rats.

Pretreatment of rats with aminooxyacetic acid (AOAA; 40 mg/kg) raised the concentration of rat brain GABA and inhibited the hyperactivity produced by increasing brain 5-hydroxytryptamine (5-HT) concentration by administration of tranylcypromine and L-tryptophan. The maximum effect was seen 90 min after AOAA injection with smaller effects 30 and 180 min after injection. AOAA did not affect the rate of 5-HT accumulation in the brain, but did inhibit the hyperactivity response which follows injection of the 5-HT agonist 5-methoxy-N,N-dimethyltryptamine, suggesting that post-synaptic 5-HT responses were being inhibited. AOAA also inhibited the locomotor activity which follows administration of tranylcypromine and L-dopa. Blockade of GABA receptors by injection of picrotoxin (2.5 mg/kg) enhanced the dopamine hyperactivity. Since a dopaminergic system has been shown to be involved in the 5-HT hyperactivity syndrome and appears to act post-synaptically to the 5-HT neurones initiating the syndrome it is suggested that inhibition of the 5-HT hyperactivity syndrome may be due to accumulation of GABA distal to the dopaminergic receptors.