Regional release of aromatic amines from tissues of the rat brain in vitro

Electrophysiological effects of trace amines on mesencephalic dopaminergic neurons

Trace amines (TAs) are a class of endogenous compounds strictly related to classic monoamine neurotransmitters with regard to their structure, metabolism, and tissue distribution. Although the presence of TAs in mammalian brain has been recognized for decades, until recently they were considered to be by-products of amino acid metabolism or as "false" neurotransmitters. The discovery in 2001 of a new family of G-protein-coupled receptors (GPCRs), namely trace amines receptors, has re-ignited interest in TAs. In particular, two members of the family, trace amine receptor 1 (TA(1)) and trace amine receptor 2 (TA(2)), were shown to be highly sensitive to these endogenous compounds. Experimental evidence suggests that TAs modulate the activity of catecholaminergic neurons and that TA dysregulation may contribute to neuropsychiatric disorders, including schizophrenia, attention deficit hyperactivity disorder, depression and Parkinson's disease, all of which are characterized by altered monoaminergic networks. Here we review recent data concerning the electrophysiological effects of TAs on the activity of mesencephalic dopaminergic neurons. In the context of recent data obtained with TA(1) receptor knockout mice, we also discuss the mechanisms by which the activation of these receptors modulates the activity of these neurons. Three important new aspects of TAs action have recently emerged: (a) inhibition of firing due to increased release of dopamine; (b) reduction of D2 and GABA(B) receptor-mediated inhibitory responses (excitatory effects due to disinhibition); and (c) a direct TA(1) receptor-mediated activation of GIRK channels which produce cell membrane hyperpolarization. While the first two effects have been well documented in our laboratory, the direct activation of GIRK channels by TA(1) receptors has been reported by others, but has not been seen in our laboratory (Geracitano et al., 2004). Further research is needed to address this point, and to further characterize the mechanism of action of TAs on dopaminergic neurons.

Trace amine-associated receptor 1-Family archetype or iconoclast?

Interest has recently been rekindled in receptors that are activated by low molecular weight, noncatecholic, biogenic amines that are typically found as trace constituents of various vertebrate and invertebrate tissues and fluids. The timing of this resurgent focus on receptors activated by the "trace amines" (TA) beta-phenylethylamine (PEA), tyramine (TYR), octopamine (OCT), synephrine (SYN), and tryptamine (TRYP) is the direct result of 2 publications that appeared in 2001 describing the cloning of a novel G protein-coupled receptor (GPCR) referred to by their discoverers Borowsky et al. as TA1 and Bunzow et al. as TA receptor 1 (TAR1). When heterologously expressed in Xenopus laevis oocytes and various eukaryotic cell lines, recombinant rodent and human TAR dose-dependently couple to the stimulation of adenosine 3',5'-monophosphate (cAMP) production. Structure-activity profiling based on this functional response has revealed that in addition to the TA, other biologically active compounds containing a 2-carbon aliphatic side chain linking an amino group to at least 1 benzene ring are potent and efficacious TA receptor agonists with amphetamine (AMPH), methamphetamine, 3-iodothyronamine, thyronamine, and dopamine (DA) among the most notable. Almost 100 years after the search for TAR began, numerous TA1/TAR1-related sequences, now called TA-associated receptors (TAAR), have been identified in the genome of every species of vertebrate examined to date. Consequently, even though heterologously expressed TAAR1 fits the pharmacological criteria established for a bona fide TAR, a major challenge for those working in the field is to discern the in vivo pharmacology and physiology of each purported member of this extended family of GPCR. Only then will it be possible to establish whether TAAR1 is the family archetype or an iconoclast.

The mysterious trace amines: protean neuromodulators of synaptic transmission in mammalian brain

The trace amines are a structurally related group of amines and their isomers synthesized in mammalian brain and peripheral nervous tissues. They are closely associated metabolically with the dopamine, noradrenaline and serotonin neurotransmitter systems in mammalian brain. Like dopamine, noradrenaline and serotonin the trace amines have been implicated in a vast array of human disorders of affect and cognition. The trace amines are unique as they are present in trace concentrations, exhibit high rates of metabolism and are distributed heterogeneously in mammalian brain. While some are synthesized in their parent amine neurotransmitter systems, there is also evidence to suggest other trace amines may comprise their own independent neurotransmitter systems. A substantial body of evidence suggests that the trace amines may play very significant roles in the coordination of biogenic amine-based synaptic physiology. At high concentrations, they have well-characterized presynaptic "amphetamine-like" effects on catecholamine and indolamine release, reuptake and biosynthesis; at lower concentrations, they possess postsynaptic modulatory effects that potentiate the activity of other neurotransmitters, particularly dopamine and serotonin. The trace amines also possess electrophysiological effects that are in opposition to these neurotransmitters, indicating to some researchers the existence of receptors specific for the trace amines. While binding sites or receptors for a few of the trace amines have been advanced, the absence of cloned receptor protein has impeded significant development of their detailed mechanistic roles in the coordination of catecholamine and indolamine synaptic physiology. The recent discovery and characterization of a family of mammalian G protein-coupled receptors responsive to trace amines such as beta-phenylethylamine, tyramine, and octopamine, including socially ingested psychotropic drugs such as amphetamine, 3,4-methylenedioxymethamphetamine, N,N-dimethyltryptamine, and lysergic acid diethylamide, have revitalized the field of scientific studies investigating trace amine synaptic physiology, and its association with major human disorders of affect and cognition.

Analysis of biogenic amines in bovine retina by gas chromatography-negative ion chemical ionisation mass spectrometry

Biogenic amines in bovine retina have been identified and quantified by an extraction-derivatisation procedure involving their reaction with 3,5-di(trifluoromethyl)benzoyl chloride (DTFMBCl) in the aqueous phase followed by extraction into an organic solvent, hydrolysis of phenolic esters, and conversion of free hydroxyl groups to trimethylsilyl ethers. Subsequent analysis of these DTFMB-trimethylsilyl derivatives by gas chromatography-negative ion chemical ionisation mass spectrometry revealed that the molecular ion carried most (greater than 60%) of the ion current, which made the method highly specific and gave a potential limit of detection below the picogram level. This method establishes unequivocally that the principal amines in bovine retina are p-tyramine, dopamine, and 5-hydroxytryptamine.

Release of 3H-dopamine and analogous monoamines from rat striatal tissue

1. The release of previously accumulated 3H-dopamine (DA) from minces of striatal tissue prepared from the brains of pargyline-pretreated rats was evaluated by superfusion with a physiological buffer solution in a six-chamber apparatus with silver toroid electrodes to provide electrical field stimuli. The identity of released tritium as 3H-DA was demonstrated chromatographically and 3H-DA taken up was found in a synaptosomal subcellular fraction. 2. Release of 3H-DA previously accumulated at 0.3 microM was found to be linearly dependent on stimulus intensity between 1 and 10 V (for 60 sec); 5 V was selected as a standard stimulus. 3. Release of 3H-DA did not occur from minces of rat liver, nor was there release of previously accumulated labeled urea or leucine from striatal tissue by electrical stimulation, 50 mM KCL, or 0.1 mM (+)-amphetamine. When 3H-DA was taken up in the presence of cocaine (1 mM) or benztropine (100 microM), electrically induced release of 3H-DA was markedly reduced, while spontaneous efflux was much less altered. 4. Release of 3H-DA was also induced by depolarizing concentrations of K+, as well as by Rb+ or NH4+, and by veratridine. Electrical release and that induced by 50 mM K+ or 100 microM veratridine was blocked by the omission of Ca2+ (with EDTA added) and that induced by veratridine was blocked by tetrodotoxin (30 microM).

Plasma levels of phenylacetic acid, m- and p-hydroxyphenylacetic acid, and platelet monoamine oxidase activity in schizophrenic and other patients

Blood from chronic schizophrenic patients in two hospitals (A and B) and from institutional and noninstitutional controls was analyzed for platelet monoamine oxidase (MAO) activity toward three different substrates (tryptamine, phenylethylamine, and p-tyramine) and for plasma levels of conjugated and unconjugated phenylacetic acid (PAA) and m- and p-hydroxyphenylacetic acids (mHPA and pHPA). Compared to the controls, schizophrenic patients were found to have significantly reduced MAO activity. Although significant differences were found between unconjugated PAA (reduced) in Hospital B, conjugated pHPA (increased) in Hospital A, and conjugated PAA (increased) in Hospitals A and B and noninstitutional controls, the most consistent significant finding was a reduced unconjugated mHPA in both groups of schizophrenic patients compared with both control groups.

The noradrenergic system in cultured aggregates of fetal rat brain cells: morphology of the aggregates and pharmacological indices of noradrenergic neurons

Spherical aggregates formed rapidly in culture by re-aggregation of trypsin-dissociated brain cells from the 17-day-old fetal rat. Over about 10 days in initially random distribution of cells evolved into a 3-layered arrangement; cells with characteristics of neurons were found largely in the intermediate layer. The survival of neuronal and glial cell types was evaluated histologically and verified by electron microscopy, which revealed synaptic and myelin structures that rapidly increased in number after 18 days in culture. Levels of norepinephrine (NE) and dopamine (DA) reached peaks of 9.5 and 4.4 ng/mg protein, respectively, at culture day 21. Uptake of [3H]NE paralleled these amine levels and was blocked by desipramine or pretreatment with either reserpine or 6-OH-DA. Autoradiographs of aggregates labeled with [3H]NE showed a high density of silver grains over cells, apparently neurons, with branching processes traced for 120 micrometer. Previously accumulated [3H]NE was released under depolarizing conditions (high [K+] or vertridine) only in the presence of Ca2+. Release was induced to a lesser extent by kainic greater than glutamic acid. Thus, such aggregates appear to contain catecholaminergic neurons capable of synthesis, uptake and release of NE. The time course of development of these functions supports suggestions that aggregate preparations might be useful in studying neurochemical or morphological aspects of brain development and function in vitro.

A comparison of the effects of methylphenidate and amphetamine on the simultaneous release of radiolabelled dopamine and p- or m-tyramine from rat striatal slices

The release of [14C]dopamine (DA) from slices of rat caudate nucleus was studied simultaneously with the release of either [3H]para-tyramine (pTA) or [3H]meta-tyramine (mTA). Amphetamine (10(-5) M) caused a large concurrent release of [14C]DA and [3H]pTA; similar results were obtained when [14C]DA and [3H]mTA release were studied. The release of all three amines by amphetamine was quantitatively similar. In contrast, methylphenidate caused a release of [3H]pTA similar to that seen with amphetamine, but only a very small simultaneous release of [14C]DA. [3H]mTA was also strongly released by methylphenidate concurrent with a minimal release of [14C]DA. The inclusion of reserpine in the incubation medium had no detectable effect on the release of any of the three amines by amphetamine. Methylphenidate-induced release of tritiated mTA and pTA was also unaffected by reserpine. However, the release of [14C]DA by methylphenidate was potentiated in the presence of reserpine. The uptake of radiolabelled pTA, mTA and DA was inhibited by both amphetamine and methylphenidate, although amphetamine was a stronger inhibitor of the uptake of all three amines. It is suggested that release of endogenous tyramines may be involved in mediating some actions of psychomotor stimulant drugs.

Presynaptic noradrenergic alpha-receptors and modulation of 3H-noradrenaline release from rat brain synaptosomes

The depolarization (15 mM K+)-induced release of 3H-NA from superfused rat brain synaptosomes and the effects of alpha-noradrenergic drugs thereon were studied. Noradrenaline (NA; in the presence of the uptake inhibitor desipramine) reduced synaptosomal 3H-NA release. Reduction of the concentration of calcium ions in the medium during K+ stimulation greatly enhanced the sensitivity of 3H-NA release to alpha-receptor-mediated inhibition. Under these conditions NA dose-dependently inhibited 3H-NA release from synaptosomes obtained from cortex or hypothalamus, but did not affect 3H-NA release from striatal (i.e dopaminergic) synaptosomes. Adrenaline, clonidine and oxymetazoline potently inhibited 3H-NA release from cortex synaptosomes at concentrations in the nanomolar range. Phentolamine by itself did not affect synaptosomal 3H-NA release, but antagonized the inhibitory effects of both noradrenaline and adrenaline. The data obtained further substantiate the hypothesis that the alpha-receptors mediating a local negative feedback control of NA release are localized on the varicosities of central noradrenergic neurons, Furthermore, noradrenergic nerve terminals in the hypothalamus appear to be less senstive to alpha-receptor-mediated presynaptic inhibition than those in the cortex.

Effects of alternative transmitter amines on cyclic AMP formation in rat brain tissue

Aromatic amines and related compounds, some of which are taken up and released from nerve terminals, might act at brain receptors ordinarily stimulated by traditional amine neurotransmitters. Several of these compounds were evaluated for their ability to stimulate or impede synthesis of cyclic AMP in rat striatal homogenates and cortical slices. In contrast to catecholamines, most had no effect, consistent with their possible role as false transmitters.

Determination of plasma octopamine and its level in renal disease

A radioenzymatic assay method for the estimation of octopamine levels in plasma was developed. Preparation of the enzyme, phenylethanolamine-N-methyl transferase, dilution of the plasma sample, preparation of a suitable blank, and the assay conditions were found to have a significant effect on the sensitivity of the assay. Plasma octopamine levels were measured in a population of 33 normal individuals ranging in age from 19 to 94 years. Significantly higher plasma octopamine levels were found in the age group 70-90 years. Excluding those individuals over the age of 70 years, no significant differences in plasma octopamine levels were found for males or females, the range of values was 0 to 0.68 ng per ml, with a mean value of 0.23 ng per ml (n = 25). Examination of plasma octopamine levels in patients with severe renal disease requiring hemoperfusion dialysis, revealed a significantly higher level of plasma octopamine in renal disease (1.9 ng per ml), and an increase in plasma octopamine during dialysis; the mean level post dialysis being 2.7 ng per ml.

Uptake and release of meta-tyramine, para-tyramine, and dopamine in rat striatal slices

The uptakes of high-affinity concentrations (10(-8)M) of meta-tyramine (m-TA), para-tyramine (p-TA), and dopamine (DA) into rat striatal slices have been shown to be inhibited by DNP and ouabain. We now demonstrate that cocaine (5 x 10(-6)M) and low concentrations of sodium ion (26 x 10(-3)M) also reduced these uptakes. The spontaneous efflux and the release [induced by an elevated concentration of potassium ion (5 x 10(-2)M)] of each of the previously accumulated amines were studied in the presence and absence of added calcium ions. The spontaneous efflux of each amine (especially the tyramines) was enhanced by the absence of calcium ions. Part of this enhancement seemed to be due to an inhibition of a calcium-dependent reuptake. The elevated concentration of potassium ion proved to be an effective releaser of each amine; and for DA, such release was decreased by the removal of calcium. For m- and p-TA, however, the removal of calcium either did not reduce or completely abolished the releases depending upon the duration of the calcium removal. The significance of these findings is discussed.

Differential blockade of octopamine and dopamine receptors by analogues of clozapine and metoclopramide

1. Sulpiride, but not procainamide, antagonizes the excitatory effects of (+/-)-octopamine receptors in the Tapes ventricle. Neither compound attenuates dopamine excitation. 2. Clozapine will attenuate the effects of (+/-)-octopamine and (-)-alpha-methyl octopamine at the octopamine receptor but not the excitatory effect of dopamine at dopamine receptors. 3. Clozapine is more potent than its 2-positional isomer HF 2046 in attenuating octopamine excitation. However, HF 2046, unlike clozapine, will attenuate the excitatory effects of dopamine. 4. These data indicate that replacement of the 8-chloro substituent in the clozapine nucleus with a 2-chloro substituent decreases the ability of the compound to blockaed octopamine receptors. However, the 2-chloro-substituted compound (HF 2046) now has the added ability to blockade excitatory dopamine receptors. 5. The greater potency of clozapine than HF 2046 as an octopamine antagonist suggests that it is the 8-chloro-substituted aromatic ring of clozapine which overlaps the aromatic site usually occupied by the octopamine aromatic ring.

Liquid chromatographic analysis of endogenous catecholamine release from brain slices

A simple new liquid chromatographic technique has been applied to transmitter release studies in brain slice preparations. This method, which gives direct readings of picomoles of endogenous transmitter released, has been shown to yield reliable results with a variety of brain slice manipulations.

Octopamine

Octopamine is highly concentrated in neurones of several invertebrate species. Unlike in mammals, octopaminergic neurones in invertebrates are spatially separated from catecholaminergic neurons. In identified nerve cells of Aplysia, however, this amine coexists with other putative neurotransmitters. Octopamine is synthesized in nerves from tyrosine and tyramine and metabolised mainly by monoamine oxidase. When lobster nerves are depolarized, octopamine is liberated by a Ca2+-dependent process. A specific adenylate cyclase is stimulated by octopamine in several invertebrates to activate phosphorylase in the cockroach, induce a light-flash in firefly lattern or inhibit rhythm contractions in locust muscle. All of these observations provide compelling evidence that octopamine is a neurotransmitter in invertebrates. In mammals octopamine is localised in nerves in peripheral tissues and brain where it seems to coexist with noradrenaline, the catecholamine being present in much higher concentrations. Octopamine is released from nerves together with noradrenaline and it may under certain conditions modify the actions of the adrenergic neurotransmitter. Octopamine is present in unusually high concentrations in certain neurological and hepatic diseases and may have a pathophysiological role.