Since the identification of 2‐phenylethylamine (β‐phenylethylamine; PE) as a biogenic amine, there has been much discussion about what role, if any, it may have in the CNS. Indeed, the low endogenous concentration of PE in the brain and its relatively low potency in behavioral and pharmacological experiments have led some researchers to conclude that perhaps PE possessed no physiological role at all but that it was merely a metabolic by‐product. Our findings have caused us to conclude otherwise, and in this article we review the neurochemical, neuropharmacological, and neurophysiological findings that lead us to propose that PE is a neuromodulator of catecholamine neurotransmission in the CNS.
Classically, aromatic L-amino acid decarboxylase (AADC) has been regarded as an unregulated, rather uninteresting enzyme. In this review, we describe advances made during the past 10 years, demonstrating that AADC is regulated both pre- and post-translation. The significance of such regulatory mechanisms is poorly understood at present, but the presence of tissue specific control of expression raises the real possibility of AADC being involved in processes other than neuro-transmitter synthesis. We further discuss clinical and physiological situations in which such regulatory mechanisms may be important, including the intriguing possibility of AADC gene regulation being linked to that of factors thought to have a role in apoptosis and its prevention.
Decarboxylation of phenylalanine by aromatic L-amino acid decarboxylase (AADC) is the rate-limiting step in the synthesis of 2-phenylethylamine (PE), a putative modulator of dopamine transmission. Because neuroleptics increase the rate of accumulation of striatal PE, these studies were performed to determine whether this effect may be mediated by a change in AADC activity. Administration of the D1 antagonist SCH 23390 at doses of 0.01-1 mg/kg significantly increased rat striatal AADC activity in an in vitro assay (by 16-33%). Pimozide, a D2-receptor antagonist, when given at doses of 0.01-3 mg/kg, also increased AADC activity in the rat striatum (by 25-41%). In addition, pimozide at doses of 0.3 and 1 mg/kg increased AADC activity in the nucleus accumbens (by 33% and 45%) and at doses of 0.1, 0.3, and 1 mg/kg increased AADC activity in the olfactory tubercles (by 23%, 30%, and 28%, respectively). Analysis of the enzyme kinetics indicated that the Vmax increased with little change in the Km with L-3,4-dihydroxyphenylalanine as substrate. The AADC activity in the striatum showed a time-dependent response after the administration of SCH 23390 and pimozide: the activity was increased within 30 min and the increases lasted 2-4 h. Inhibition of protein synthesis by cycloheximide (10 mg/kg, 0.5 h) had no effect on the striatal AADC activity or on the increases in striatal AADC activity produced by pimozide or SCH 23390. The results indicate that the increases in AADC activity induced by dopamine-receptor blockers are not due to de novo synthesis of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)
A series of aliphatic propargylamine derivatives has been synthesized. Some of them possess highly potent, irreversible, selective, inhibitory activity toward monoamine oxidase B (MAO-B). The potency of the inhibitors is related to chain length and substitution of a hydrogen on the terminal carbon of the aliphatic chain. MAO inhibitory activity as assessed in vitro increased as the aliphatic carbon chain length increased. Substitution of a hydrogen by hydroxyl, carboxyl, or carbethoxyl groups at the aliphatic chain terminal or replacement of the methyl group on the nitrogen atom by an ethyl group considerably reduced the inhibitory activity. Stereospecific effects were observed with the R-(-)-enantiomer being 20-fold more active than the S-(+)-enantiomer. Inhibitors with relatively short carbon chain lengths (i.e. four to six carbons) were found to be more potent than those with longer chains in inhibiting brain MAO-B activity in vivo especially after oral administration. Chronic administration of low doses of the aliphatic propargylamines caused a slight cumulative inhibition of MAO-A activity in the mouse brain. These MAO-B inhibitors appear to be nontoxic, and they do not possess an amphetamine-like moiety in their structure as is the case for deprenyl. We expect that these aliphatic propargylamines may be useful in the treatment in certain neuropsychiatric disorders.
The trace amines phenylethylamine, tryptamine, p‐tyramine and m‐tyramine have been measured in the striatum of both control and MAO‐treated rats. Dose‐response and time‐response studies have been carried out with clorgyline and deprenyl, inhibitors which preferentially inhibit the A and B forms of MAO, respectively, and with tranylcypromine and phenylethylhydrazine, which are used clinically in the treatment of depression. Phenylethylamine was increased by 1 mg/kg of deprenyl, but was unaffected by clorgyline at doses up to 50 mg/kg, while the tyramines and tryptamine were increased by low doses of clorgyline, but were increased only by much greater doses of deprenyl than those required to affect phenylethylamine. Phenylethylamine is oxidized by the B form of MAO, but tryptamine and the tyramines appear to be oxidized by both A and B MAO. The observed proportional increases in trace amine levels are much greater than those observed for the classical neurotransmitters, noradrenaline, dopamine and 5‐hydroxytryptamine. As these increases are differential, selective manipulation of trace amine concentrations is possible.
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