Beta-phenylethylamine inhibits K+ currents in neocortical neurons of the rat: a possible mechanism of beta-phenylethylamine-induced seizures

Monoamine oxidases in development

Monoamine oxidases (MAOs) are flavoproteins of the outer mitochondrial membrane that catalyze the oxidative deamination of biogenic and xenobiotic amines. In mammals there are two isoforms (MAO-A and MAO-B) that can be distinguished on the basis of their substrate specificity and their sensitivity towards specific inhibitors. Both isoforms are expressed in most tissues, but their expression in the central nervous system and their ability to metabolize monoaminergic neurotransmitters have focused MAO research on the functionality of the mature brain. MAO activities have been related to neurodegenerative diseases as well as to neurological and psychiatric disorders. More recently evidence has been accumulating indicating that MAO isoforms are expressed not only in adult mammals, but also before birth, and that defective MAO expression induces developmental abnormalities in particular of the brain. This review is aimed at summarizing and critically evaluating the new findings on the developmental functions of MAO isoforms during embryogenesis.

Credneramides A and B: neuromodulatory phenethylamine and isopentylamine derivatives of a vinyl chloride-containing fatty acid from cf. Trichodesmium sp. nov

Credneramides A (1) and B (2), two vinyl chloride-containing metabolites, were isolated from a Papua New Guinea collection of cf. Trichodesmium sp. nov. and expand a recently described class of vinyl chloride-containing natural products. The precursor fatty acid, credneric acid (3), was isolated from both the aqueous and organic fractions of the parent fraction as well as from another geographically and phylogenetically distinct cyanobacterial collection (Panama). Credneramides A and B inhibited spontaneous calcium oscillations in murine cerebrocortical neurons at low micromolar concentrations (1, IC(50) 4.0 μM; 2, IC(50) 3.8 μM).

Trace amines depress D(2)-autoreceptor-mediated responses on midbrain dopaminergic cells

BACKGROUND AND PURPOSE

Although trace amines (TAs) are historically considered 'false neurotransmitters' on the basis of their ability to induce catecholamine release, there is evidence that they directly affect neuronal activity via TA receptors, ligand-gated receptor channels and/or sigma receptors. Here, we have investigated the effects of two TAs, tyramine (TYR) and beta-phenylethylamine (beta-PEA), on electrophysiological responses of substantia nigra pars compacta (SNpc) dopaminergic cells to the D(2) receptor agonist, quinpirole.

EXPERIMENTAL APPROACH

Electrophysiological recordings of D(2) receptor-activated G-protein-gated inward rectifier K(+) channel (GIRK) currents were performed on dopaminergic cells from midbrain slices of mice and on Xenopus oocytes expressing D(2) receptors and GIRK channels.

KEY RESULTS

TYR and beta-PEA reversibly reduced D(2) receptor-activated GIRK currents in a concentration-dependent manner on SNpc neurones. The inhibitory effect of TAs was still present in transgenic mice with genetically deleted TA(1) receptors and they could not be reproduced by the selective TA(1) agonist, o-phenyl-3-iodotyramine (O-PIT). Pretreatment with antagonists of sigma1 and sigma2 receptors did not block TA-induced effects. In GTPgammaS-loaded neurones, the irreversibly-activated GIRK-current was still reversibly reduced by beta-PEA. Moreover, beta-PEA did not affect basal or dopamine-evoked GIRK-currents in Xenopus oocytes.

CONCLUSIONS AND IMPLICATIONS

TAs reduced dopamine-induced responses on SNpc neurones by acting at sites different from TA(1), sigma-receptors, D(2) receptors or GIRK channels. Although their precise mechanism of action remains to be identified, TAs, by antagonizing the inhibitory effects of dopamine, may render dopaminergic neurones less sensitive to autoreceptor feedback inhibition and hence enhance their sensitivity to stimulation.