A Weissman

Bio: A Weissman is an academic researcher. The author has contributed to research in topics: Monoamine neurotransmitter & Serotonin. The author has an hindex of 1, co-authored 1 publications receiving 1747 citations.

p-CHLOROPHENYLALANINE: A SPECIFIC DEPLETOR OF BRAIN SEROTONIN

Abstract: p -Chlorophenylalanine has been found to be a potent and selective depletor of brain serotonin (5HT) in mice, rats and dogs. Brain 5-hydroxy-3-indolylacetic acid (5HIAA) content was also depleted by the drug, but catecholamine concentrations were only slightly decreased. Peripheral stores of 5HT were also lowered. In rats, p -chlorophenylalanine reduced the normal increase in brain 5-hydroxyl-3-indolyl compounds following L-tryptophan loading (without apparently affecting tryptophan uptake into brain), completely prevented the increase in brain 5HT accompanying inhibition of monoamine oxidase by pargyline and blocked the increase in brain 5HIAA usually observed after reserpine treatment. p -Chlorophenylalanine slightly diminished the usual increase in brain 5HT in rats following 5-hydroxytryptophan (5HTP) administration, but decreased the rate of disappearance of excess 5HT and antagonized the increase in brain 5HIAA. p -Chlorophenylalanine did not inhibit monoamine oxidase or 5HTP-decarboxylase in vitro and exerted no effect on monoamine oxidase or 5HTP decarboxylase activity of rat tissues in vivo. In contrast, p -chlorophenylalanine inhibited liver tryptophan hydroxylase in vitro and strongly suppressed the tryptophan- and phenylalanine-hydroxylating capabilities of livers of rats treated with it. These results suggest that p -chlorophenylalanine may effect 5HT depletion by inhibiting the biosynthesis of this monoamine, possibly by blocking tryptophan hydroxylation. A blockade of uptake of amino acid precursor might also contribute to the effect of decreasing 5HT biosynthesis. The slow depletion (2-3 days) of brain 5HT induced by p -chlorophenylalanine suggests that an active metabolite might be formed. p -Chlorophenylpyruvic acid exerted essentially the same pharmacologic effects as the amino acid, but it cannot be ascertained at present whether it is the active metabolite because of the interconversion of α-amino acids and α-keto acids in vivo. p -Chlorophenethylamine may be excluded as the metabolite responsible for the action of p -chlorophenylalanine because of the brief duration of the amine in brain and the short lasting, nonselective decrease of both 5HT and norepinephrine produced by the amine. A study of structural variation in the phenylalanine series indicated a specific requirement of a single chlorine substituent in the para position for potent in vivo activity. Rats treated with p -chlorophenylalanine displayed few apparent signs, and certainly not sedation. p -Chlorophenylalanine did not block characteristic signs elicited by reserpine or tetrabenazine in rats. Accordingly, the central actions of reserpine and reserpine-like drugs may possibly be dissociated from both 5HT concentrations and the formation of new 5HT in brain.

Aggression in humans correlates with cerebrospinal fluid amine metabolites

Abstract: Cerebrospinal fluid of the major central metabolites of serotonin (5HT), norepinephrine (NE), and dopamine (DA)--5-hydroxyindoleacetic acid (5HIAA), 3-methoxy-4-hydroxy=phenylglycol (MHPG), and homovanillic acid (HVA), respectively--were studied in a group of 26 age-similar military men with no history of major psychiatric illness, but with various personality disorders and difficulties adjusting to military life. Independently scored history of aggressive behavior showed a significant negative correlation with 5HIAA (r = -0.78) and a significant positive correlation with MHPG (r = 0.64).

The inhibitory action of noradrenaline and adrenaline on acetylcholine output by guinea‐pig ileum longitudinal muscle strip

Abstract: 1. Noradrenaline and adrenaline reduce the output of acetylcholine by the guinea-pig ileum longitudinal strip by up to 80%, both in resting conditions and after stimulation. The effect is graded with dose, and is detectable with noradrenaline 2 x 10(-7) g/ml. Adrenaline is approximately 4 times as active as noradrenaline, and its action after being washed out is more persistent.2. If resting output is high, both amines have a proportionately greater effect and their action, as dosage is increased, is to reduce resting output to a basal level, relatively constant from strip to strip, of about 10 ng/g/min.3. With stimulation, the effect of the amine is greater at low frequencies, when the output per volley is high, than at high frequencies. The effect is reduced by increasing the number of shocks delivered. There thus appears to be a basal output per volley, of the order of 1-2 ng/g/volley, which can be reached either by relatively rapid stimulation, by prolonged stimulation, or by treatment with these amines.4. If noradrenaline is applied during continued stimulation at 40/min, the depression of acetylcholine output during its presence is followed by an augmented output when the drug is withdrawn. The magnitude of this "overshoot" increases with the duration of noradrenaline exposure.5. Phenylephrine 4 mug/ml. and amphetamine 20 mug/ml. reduced the acetylcholine output, but isoprenaline 1 mug/ml., dopamine 1 mug/ml. and methoxamine 10 mug/ml. were ineffective.6. Phenoxybenzamine reduced the resting output and increased the stimulation output. Of the two other blocking agents examined, phentolamine had no effect on either resting or stimulation output and ergotamine transiently reduced stimulation output. The effect of phenoxybenzamine was not due to a reaction with either adrenoceptive or muscarinic receptors.7. Phenoxybenzamine, phentolamine and ergotamine abolished the effect of adrenaline and noradrenaline on both resting output and on output in response to stimulation.8. In strips obtained from animals treated with reserpine and guanethidine, a rise in resting acetylcholine output and in stimulation output at low frequencies was found. In these conditions, noradrenaline was still effective.9. Reducing the hydroxytryptamine content of the strips by treatment with p-chloro-(+/-)-phenylalanine did not significantly affect acetylcholine output.10. It is concluded that acetylcholine output by the nervous networks of the longitudinal strip is under the normal control of the sympathetic by a species of presynaptic inhibition mediated by alpha receptors. This implies that for a tissue under dual autonomic control, withdrawal of sympathetic control will lead to a parasympathetic response which is not only unopposed but also itself enhanced.

Studies in vivo on the relationship between brain tryptophan, brain 5‐ht synthesis and hyperactivity in rats treated with a monoamine oxidase inhibitor and l‐tryptophan

Abstract: — The effect of l-tryptophan loading upon the amount of 5-HT accumulating in the brains of rats pretreated with a monoamine oxidase inhibitor was studied. The amount of brain 5-HT accumulated increased with increasing tryptophan dosages and brain tryptophan concentrations up to a tryptophan dose of 120 mg/kg body wt. and a brain tryptophan of about 70 μg/g brain. Above this dose and concentration no further increase in brain 5-HT accumulation occurred. After monoamine oxidase inhibition and tryptophan loading gross hyperactivity and hyperpyrexia occurred. Monoamine oxidase inhibition, tryptophan administration and intact aromatic amino acid decarboxylase activity were all collectively essential for the production of hyperactivity and hyperpyrexia. DL-Parachlorophenyl-alanine prevented both the occurrence of hyperactivity and the increased accumulation of, brain 5-HT. Indices of hyperactivity correlated with the amount of brain 5-HT accumulating in 1 h after tryptophan loading but not with the overall concentration of brain 5-HT, suggesting that hyperactivity was dependent upon the rate of 5-HT synthesis. Reserpine and tetra-benazine pretreatment speeded the onset and rate of development of the hyperactive state without altering the synthesis of brain 5-HT. It is suggested that when monoamine oxidase is inhibited and the rate of 5-HT synthesis is increased, granular uptake and storage of 5-HT and other rate-limiting mechanisms for 5-HT inactivation are unable to prevent 5-HT 'spilling over’to produce hyperactivity. The crucial dependence of 5-HT synthesis upon brain tryptophan concentration and the ability of intraneuronal metabolism, when monoamine oxidase activity is intact, to cope with increased 5-HT synthesis and prevent ‘spillover’, raise the possibility that brain 5-HT synthesis is normally in excess of functional needs, and suggest that intraneuronal metabolism and the intraneuronal organization of 5-HT pools are of more importance than synthesis in regulating the amount of 5-HT available for functional activity.