Brain biogenic amines and altered thyroid function.

Evidence has been presented that alterations in thyroidal status produce marked changes in the metabolism of several biogenic amines in developing brain. Neonatal hypothyroidism induced either by ¹³¹I or by an anti-thyroid agent, methimazole, markedly decreased the concentrations of norepinephrine, dopamine and 5-hydroxytryptamine and the activity of their rate-limiting enzymes, tyrosine hydroxylase and tryptophan hydroxylase. However, the levels of 5-hydroxyindoleacetic acid, the chief metabolite of 5-hydroxytryptamine were elevated in several regions of the brain. Whereas thyroid deficiency in early life produced no appreciable change in whole brain monoamine oxidase activity, it was increased in mid brain and decreased in the hypothalamus. Brain acetylcholine levels were significantly elevated and the activity of acetylcholinesterase remained unchanged in rats made hypothyroid at 1 day of age. Delaying thyroidectomy for 20 days after birth produced less appreciable changes in norepinephrine and 5-hydroxytryptamine metabolism. Thyroid deficiency suppressed the ontogenesis of behavioural arousal and spontaneous locomotor activity. The administration of L-triiodothyronine to hypothyroid animals in early life restored the metabolism of various neurohumors virtually to the normal limits. However, when the replacement therapy was postponed until adulthood, L-triiodothyronine failed to produce any restorative effects, suggesting that a critical period exists in early life during which thyroid hormone must be present to permit normal developmental pattern of central amines. Data also have been obtained demonstrating that neonatal hyperthyroidism induced by daily administration of L-triiodothyronine results in an increased turnover of norepinephrine and 5-hydroxytryptamine. These amine changes were accompanied by a marked rise in the spontaneous locomotor activity in hyperthyroid rats. Finally, chronic treatment with lithium, an antimanic drug, also known to suppress thyroid hormone production, significantly decreased not only the spontaneous locomotor activity, but also changes in the turnover of 5-hydroxytryptamine and norepinephrine in neonatally hyperthyroid rats.     

Assay of biogenic amines by bioluminescence

A bioluminescent procedure to measure noradrenaline and serotonin has been realized. The amines are oxidized by the monoamine oxidase of pig brain mitochondria. The NH3 generated in this reaction is directly measured by enzymatic reaction. The coenzyme of this last reaction is the NADH,H+ which is measured with a bioluminescent system: the FMN-oxidoreductase-luciferase. The extension to other amines is possible, it depends only of the specificity of the monoamine oxidase.     

The molecular mechanism of nondegranulative release of biogenic amines.

According to current teaching biogenic amines are released by exocytosis, i.e. by evacuation of amine storing vesicles or granules into the extracellular space. The release of transmitter amines is quantal, i.e. occurs in packs of transmitter molecules. These packs are assumed to be identical with vesicle contents, in other words, the smallest releasable quantum equals the amine content of one vesicle. However, there are experimental observations which do not fit in with this version of an exocytotic release theory. Observed quantitative discrepancies could be explained if the release mechanism allowed a fractional release of transmitter amine from several vesicles instead of the total evacuation of a few. The lack of adequate knowledge about the mechanisms of storage of biogenic amines within the vesicles has up til now rendered it difficult to envisage the machinery behind a fractional release of the amine content of a vesicle. In extensive in-vitro studies we have found that the matrices of amine storing granules (i.e. from mast cells, chromaffin cells and nerve terminals) show the properties of weak cation exchanger materials, carboxyl groups serving as amine binding ionic sites. When exposed to cations like sodium and potassium ions, the amines are released from their storage sites according to kinetics characteristic of weak cation exchangers. In vivo, amine release from cat adrenals on splanchnic nerve stimulation also occurs according to ion exchange kinetics. Histamine release from mast cells is considered to occur as the result of degranulation, i.e. the expulsion of histamine storing granules to the extracellular space, a typical example of exocytosis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stimulation of cerebral cortical synaptosomal Na-K-ATPase by biogenic amines.

The amines noradrenaline, dopamine, 5-hydroxytryptamine, and histamine (0.01-0.5 mM) enhanced the activity of Na-K-ATPase (EC 3.6.1.3) in rat cerebral cortical synaptosomal fractions. The activities of Mg-ATPase and Ca-Mg-ATPase were not significantly affected. No stimulation of Na-K-ATPase occurred in the presence of chelating agents (0.5 mM EGTA or EDTA) unless 0.5 mM calcium had also been added to the incubation medium. These results are consistent with the hypothesis that amines depress cerebral cortical neurones by activation of an electrogenic sodium pump. Calcium ions appear to be involved in this process.     

Catabolism of biogenic amines in Pseudomonas species

Biogenic amines (BAs; 2-phenylethylamine, tyramine, dopamine, epinephrine, norepinephrine, octopamine, histamine, tryptamine, serotonin, agmatine, cadaverine, putrescine, spermidine, spermine and certain aliphatic amines) are widely distributed organic molecules that play basic physiological functions in animals, plants and microorganisms. Pseudomonas species can grow in media containing different BAs as carbon and energy sources, a reason why these bacteria are excellent models for studying such catabolic pathways. In this review, we analyse most of the routes used by different species of Pseudomonas (P. putida, P. aeruginosa, P. entomophila and P. fluorescens) to degrade BAs. Analysis of these pathways has led to the identification of a huge number of genes, catabolic enzymes, transport systems and regulators, as well as to understanding of their hierarchy and functional evolution. Knowledge of these pathways has allowed the design and collection of genetically manipulated microbes useful for eliminating BAs from different sources, highlighting the biotechnological applications of these studies.     

Neurochemical changes following the administration of precursors of biogenic amines.

Male Wistar rats were injected intraperitoneally with either saline, L-trytophan, D,L-5hydroxytryptophan, L-tyrosine, L-DOPA or choline and killed by the near-freezing method 15 and 45 min after injection. The brains were removed, pulverized and acetylcholine, dopamine, norepinephrine, 5-hydroxytryptamine, aspartate, glutamate, glycine and γ-aminobuttyric acid wwere extracted and concurrently measured using previously reported methods. Compared to saline injected controls, some precursors not only resulted in changes in the specific neurotransmiter systems being pertubated, but also changes in the content of other neurotransmitters.     

Electromigration methods for amino acids, biogenic amines and aromatic amines

Methods of electromigration in laboratory apparatus of small-bore size have recently undergone development at a remarkably rapid pace, leading to a variety of new analytical techniques. One such technique is called “capillary electrophoresis” (CE), which is further classified on the basis of electromigration mode, viz., “capillary zone electrophoresis” (CZE), which, in turn, has several variations. This review aims to give a short overview of the various electromigration methods for amino compounds by using CE. Firstly, this review briefly summarizes the detection methods employed for detection of monoamines and polyamines by CE for both native and derivative forms. Next, current CE methods are described, and their applications to detection of amino acids, biogenic amines, aromatic amines, including heteroaromatic amines and their enantiomers, are introduced from representative papers. Finally, new methods for single-cell analysis and microchip CE techniques are focused on.     

Electrophysiological responses of crayfish oocytes to biogenic amines

Intracellular recordings were made from immature, growing oocytes of the crayfish Pacifastacus leniusciulus. Oocytes had a relatively negative resting potential of -74.7+/-2.2 mV (n=26; range -53 to -90) and a mean input resistance of 0.86+/-0.19 MOmega (n=22; range 0.17-3.3). Octopamine induced a long-lasting response involving biphasic changes in input resistance, together with bi- or multiphasic changes in membrane potential. The resistance-decreasing phase involved (in different oocytes) membrane hyperpolarization, depolarization or both. The resistance-increasing phase was usually a depolarization. The hyperpolarizing form of the resistance-decreasing response, and the depolarizing resistance-increasing response reversed in polarity at membrane potentials of (respectively) -90 and -92 mV, suggesting increases and decreases in K(+) conductance underly the biphasic changes in input resistance. The threshold concentration for the response was remarkably low (>10(-12) M) and showed little or no dose-dependence over the concentration range 10(-12)-10(-6) M. Similar responses were evoked by dopamine and serotonin (at 10(-9) M), although a higher proportion of oocytes responded to octopamine and/or dopamine than to serotonin.