5-Hydroxytryptamine binding to synaptic membranes from rat brain.

The ³H-5HT binding capacity of rat brain synaptic membranes prepared by density gradient centrifugation has been investigated using a rapid ultrafiltration technique. A saturable, high affinity (K_D = 1.10^?9 M), 5HT displaceable binding has been found. It is thermosensitive, temperature dependent and pH dependent. 5HT and related tryptamines are the most effective displacers of bound ³H-5HT, whereas compounds which are not structurally related to 5HT (chlorpromazine, imipramine, cyproheptadine and cinanserine) and other neuro-transmitters (noradrenalin, dopamine) are ineffective. The distribution of 5HT-specific binding sites in the brain is related to serotonergic input. We conclude that these 5HT binding sites might possibly represent 5HT receptor sites.     

Twenty-four hour rhythms in serum and brain indoleamine concentrations: tryptophan-5-hydroxylase and monoamine oxidase activity in the rat.

The relationship between the 24 h rhythm in 5-hydroxy-tryptamine (5HT) levels in rat brain, the availability of precursors of 5HT and the concentration of its major metabolite, 5-hydroxyindole acetic acid (5HIAA) has been investigated. Serum total and "free" tryptophan (TRY) levels and brain TRY levels all show a 24 h rhythm with highest concentrations in the middle of the dark phase i.e. 12 h displaced from that of the 5HT rhythm. No 24 h variation in either tryptophan-5-hydroxylase or monoamine oxidase activity was detected, nor did brain 5-hydroxytryptophan (5HTP) levels vary with clock hour. Changes in 5HIAA concentration paralleled those of 5Ht. The uptake of 14C-5HTP, 14C-TRY and 14C-5HT into homogenates of the septal region of rat brain did not display a circadian rhythm, although there was evidence that uptake of 14C-TRY in an isolated synaptosomal preparation from the same region was greater during the light phase, indicating the possibility that uptake of the precursor into the nerve ending may be, in part, responsible for the 24 h rhythm in brain 5HT. It is concluded that brain 5HT levels are independent of the serum or brain TRY concentrations measured. Since changes in 5HT with clock hour are paralleled by changes in 5HIAA, it also seems unlikely that the increase in brain 5HT during the light phase is caused by a decreased release of 5HT from nerve endings.     

The chronic ingestion of diets containing different proteins produces marked variations in brain tryptophan levels and serotonin synthesis in the rat

Serotonin (5HT) synthesis in brain is influenced by precursor (tryptophan (TRP)) concentrations, which are modified by food ingestion. Hence, in rats, a carbohydrate meal raises brain TRP and 5HT; a protein-containing meal does not, but little attention has focused on differences among dietary proteins. Recently, single meals containing different proteins have been shown to produce marked changes in TRP and 5HT. The present studies evaluate if such differences persist when rats ingest such diets chronically. Male rats were studied that ingested diets for 9 days containing zein, wheat gluten, soy protein, casein, or α-lactalbumin (17% dry weight). Brain TRP varied up to eightfold, and 5HT synthesis fivefold among the different protein groups. TYR and LEU concentrations, and catecholamine synthesis rate in brain varied much less. The effects of dietary protein on brain TRP and 5HT previously noted after single meals thus continue undiminished when such diets are consumed chronically.     

Diazepam increases 5-hydroxyindole concentrations in rat brain and spinal cord

Diazepam elevates serotonin (5HT) and 5-hydroxyindoleacetic acid (5HIAA) concentrations in rat brain and spinal cord. The maximal effect occurs 1–2 hrs after drug injection and is dose related between 5–20 mg/kg (intraperitoneal). The action of diazepam on brain 5HT and 5HIAA concentrations is modified by previous food consumption: the ingestion of a diet that raises brain 5HT and 5HIAA one hour before drug injection enhances the diazepam-induced increase in brain indoles; consumption of a diet that lowers brain 5HT and 5HIAA partially blocks the elevation in brain indoles that follows diazepam injection.     

Studies on the mechanisms of L-dopa-induced depletion of 5-hydroxytryptamine in the mouse brain

The administration of L-dopa to mice causes an increase in the brain concentrations of dopa and dopamine which is related temporally to a reduction in the brain concentration of 5HT. These effects occur concurrently with a reduction in the conversion of intravenously administered ³H-tryptophan to ³H-5HT without an alteration in the accumulation of ³H-tryptophan in the brain. The L-dopa-induced changes in the brain concentrations of dopa, dopamine and 5HT are not altered by pretreatment with drugs (imipramine, chlorimipramine, benztropine, cocaine) which inhibit the neuronal uptake of amines. Current evidence suggests that L-dopa is decarboxylated in 5HT neurons to dopamine, which displaces 5HT from intraneuronal storage sites.     

THE PREVENTION BY INHIBITORS OF BRAIN PROTEIN SYNTHESIS OF THE HYPERACTIVITY AND HYPERPYREXIA PRODUCED IN RATS BY MONOAMINE OXIDASE INHIBITION AND THE ADMINISTRATION OF L-TRYPTOPHAN OR 5-METHOXY-N,N-DIMETHYLTRYPTAMINE

Abstract— In rats treated with a monoamine oxidase inhibitor, (tranylcypromine), L- tryptophan produces a stereotyped syndrome of hyperactivity and hyperpyrexia due to an increased rate of brain serotonin (5-hydroxytryptamine) synthesis. Pretreatment of rats with intraperitoneal injections of cycloheximide, acetoxycycloheximide, emetine and dehydroemetine and of mice with puromycin inhibited this syndrome. Cycloheximide also inhibited the hyperactivity caused by tranylcypromine and DL-15-hydroxtryptophan and did not affect the increased rate of brain serotonin ‘synthes’ is produced by tryptophan thus excluding a primary effect on tryptophan-5-hydroxylase. Inhibition of hyperactivity did not occur until brain protein synthesis was inhibited by greater than 65 per cent as measured by the incorporation of L-[U-¹⁴C]tyrosine into brain protein in vivo. Emetine, which has been shown to inhibit brain protein synthesis inhibited hyperactivity whereas isoemetine which did not inhibit brain protein synthesis, did not inhibit hyperactivity. Under conditions where cycloheximide inhibited hyperactivity produced by tranylcypromine and L-tryptophan, a large dose of 5-methoxy-N,N-dimethyltryptamine(5-MeODMT) still produced hyperactivity showing that the rats were still capable of the same pattern of hyperactivity. However, cycloheximide did inhibit hyperactivity due to 5-MeODMT, the degree of this inhibition being dependent upon a balance between the doses of cycloheximide and 5-MeODMT. 5-MeODMT probably acts directly within the brain to cause behavioural excitation and it seems likely that the inhibitors of brain protein synthesis interfere with the mechanism of action of brain 5HT and administered 5-MeODMT rather than upon any aspect of synthesis, storage or release of brain 5HT. It is suggested that the behaviourally excitant effects of brain 5HT and 5-MeODMT are mediated in some way by a brain protein with a short biological half-life. Such a protein may act either as a factor specifically mediating the central effects of brain 5HT or as a factor regulating the neuronal response to excitation by 5HT and 5-MeODMT.     

Regional turnover of norepinephrine and dopamine in rat brain following acute exposure to air ions

Exposure to air ions has been reported to influence serotonin (5HT), although critical reviews of these studies and previous measurements in our laboratory of the concentration, release, and utilization of brain 5HT indicate that neither the data nor the interpretations of the data are particularly convincing. Measurements of other possibly relevant neurotransmitter systems--norepinephrine (NE) and dopamine (DA)--were made in brain regions selected because of their importance in the modulation of brain functions relating to motivation, arousal, endocrine function, and motor activity, all responses that have been reported to be influenced by air ion exposure. Results indicate that exposure of male Holtzman rats to high concentrations (5.0 X 10(5)/cm3) of positive or negative air ions or to DC electric fields (3.0 kV/m) for periods up to 66 h failed to affect the concentration of NE or DA significantly in any of the brain regions.     

Cerebral ischemia: Changes in brain choline,acetylcholine, and other monoamines as related to energy metabolism

The relationship of cerebral neurotransmitters acetylcholine (ACh), noradrenaline (NA), dopamine (DA), 5-hydroxytryptamine (5HT) to the energy state of the brain was examined in mice at various times following complete ischemia produced by decapitation, in gerbils submitted to transient global ischemia (10 min bilateral carotid artery occlusion, 5 or 30 min recirculation), and in rats 24 hr after irreversible microembolism. Ischemia caused significant reductions in brain monoamine concentrations. The alterations in NA, DA, and 5HT levels persisted during recirculation and were unrelated to energy restoration. They were accompanied by an increase in the concentrations of related metabolites, suggesting that synthesis was unable to compensate for the release of the transmitters at early post-ischemic time periods. As described for the catecholamines and 5HT, ischemia resulted in a significant decrease in ACh level, but recirculation was associated with a rapid increase in ACh concentration. Impaired synthesis and/or increased release of ACh can be responsible for the decrease in ACh concentration during ischemia. Early post-ischemic elevation of ACh may be related to the large increase in brain choline brought about by ischemia.     

Relationship between serotonergic measures in periphery and the brain of mouse.

Circadian rhythm and the relationship between the concentration of serotonin (5HT) and related substances (5-hydroxyindoleacetic acid; 5HIAA and tryptophan; Trp) in mouse brain, stomach and blood have been studied. All factors underwent circadian changes in the brain and blood. 5HT and 5HIAA levels in the stomach showed no circadian fluctuation. The concentrations of 5HT in the brain and blood did not correlate. Significant correlations were found between other serotonergic parameters analyzed in brain, stomach and blood. A significant negative correlation was observed between brain 5HIAA and blood 5HIAA. The concentration of tryptophan in the brain was correlated with the plasma total tryptophan level. There was fairly significant correlation (p less than 0.06) between brain serotonin and plasma tryptophan levels. The brain serotonin and tryptophan levels were strongly correlated (R = 0.410, p less than 0.03). Significant negative correlation was found between serotonin in the blood and serotonin in the stomach as well as between its level in the brain and in the stomach. The significance of these findings and their relationship to the use of peripheral serotonergic system as a model of neurons are discussed.     

Evidence for the localization of 5HT1A binding sites on serotonin containing neurons in the raphe dorsalis and raphe centralis nuclei of the rat brain

Precise anatomical distribution of 5HT1 binding sites has been investigated in the nuclei raphe dorsalis, raphe centralis and locus caeruleus of the rat brain. An original pattern of distribution was observed in the raphe nuclei, closely correlated to the already known distribution of 5HT containing elements. This pattern, more pronounced when 5HT1A sites were labelled, completely disappeared after lesioning by 5, 7DHT indicating the presence of this subtype of 5HT1 binding sites on 5HT containing neurons. It is postulated that these 5HT1A sites correspond in these raphe nuclei to 5HT autoreceptors.     

Long-term tryptophan administration enhances cognitive performance and increases 5HT metabolism in the hippocampus of female rats

Summary. It has been shown in various studies that increase in serotonergic neurotransmission is associated with increased memory consolidation whereas low brain 5HT impairs memory performance. In the first phase of our study we found that tryptophan (TRP) administration for 6 weeks increased plasma TRP and whole brain TRP, 5HT and 5HIAA levels. Many brain regions are involved in the learning process but particularly the hippocampus is known to have key role in learning and memory. The present study was therefore designed to investigate the effects of TRP loading particularly on hippocampal 5HT metabolism and cognitive performance in rats. TRP-treated rats demonstrated spatial enhancement as evidenced by a significant decrease in time to find the hidden food reward in radial arm maze test (RAM). The important finding of the present study was the greater increase in the 5HT metabolism in hippocampus than in any other brain region of the TRP-treated rats. This increased 5HT metabolism in the hippocampus emphasizes the involvement of this region in memory process.     

In vivo electrochemistry--principles and applications

Differential pulse voltammetry (DPV) with electrically pretreated carbon fibre microelectrodes has been used to monitor dopamine (DA) and serotonin (5HT) metabolism in specific regions of the rat brain in vivo. Using this technique we have located the 5HT receptor subtype responsible for controlling 5HT release and metabolism in the suprachiasmatic nucleus. The autoreceptor involved in the control of DA metabolism has also been studied and the effects of chronic neuroleptic administration on their sensitivity determined.     

mCPP but not TFMPP is an antagonist at cardiac 5HT3 receptors.

The prototypic arylpiperazines, meta-chlorophenylpiperazine (mCPP), meta-trifluoromethylphenylpiperazine (TFMPP) and quipazine are widely studied serotonergic ligands with nonselective effects at 5HT1 and 5HT2 receptor subtypes. The present study was designed to compare the affinities of these arylipiperazines at 5HT3 receptors, and to determine agonist or antagonist activity at 5HT3 receptors. Quipazine showed high affinity at brain 5HT3 receptors (IC50 = 4.4 nM) and was a potent agonist of the von Bezold-Jarisch reflex in anesthetized rats, a response mediated by cardiac 5HT3 receptors. In concentrations that activated 5HT3 receptors, quipazine also antagonized serotonin-induced bradycardia in anesthetized rats. Taken together, these data suggest that quipazine is an agonist/antagonist with high affinity at 5HT3 receptors in both brain and cardiac tissue. Although mCPP also showed relatively high affinity at brain 5HT3 receptors (IC50 = 61.4 nM), it did not activate the von Bezold-Jarisch reflex; instead, mCPP potently antagonized serotonin-induced bradycardia. Thus, mCPP acts as an antagonist at 5HT3 receptors in the periphery. Although both quipazine and mCPP possessed relatively high affinity at brain 5HT3 receptors, TFMPP did not bind appreciably to 5HT3 receptors in brain (IC50 = 2373 nM) and neither activated nor inhibited cardiac 5HT3 receptors. That TFMPP did not interact with 5HT3 receptors, whereas quipazine and mCPP did, is in marked contrast to the similar effects of all three arylpiperazines at other serotonin receptors. The selectivity of TFMPP for 5HT1 and 5HT2 receptors (i.e., its minimal affinity for 5HT3 receptors) suggests that this arylpiperazine may be a preferred ligand relative to mCPP when studying 5HT1 or 5HT2 receptor mediated responses.     

Further evidence that the serotonin receptor in the rat stomach fundus is not 5HT1A or 5HT1B

The nature of the receptor mediating serotonin contraction in the rat stomach fundus has not been clearly associated with either 5HT1 or 5HT2 receptors. We have explored the possibility that such receptors in the rat fundus may better correlate with 5HT1A or 5HT1B receptor subtypes as defined by radiolabeled ligand binding studies with brain cortical membranes. Meta chlorophenylpiperazine (CPP) and meta trifluoromethylphenylpiperazine (TFMPP), selective ligands for the 5HT1B receptor and LY165163, a selective ligand for the 5HT1A receptor, have been evaluated for their agonist and antagonist activity at serotonin receptors in the rat stomach fundus. CPP and TFMPP were partial agonists in the rat stomach fundus whereas LY165163 showed no agonist activity in this smooth muscle in concentrations up to 10(-4)M. All three phenylpiperazines antagonized serotonin-induced contractions in the rat stomach fundus. The affinity for serotonin receptors in the rat fundus was similar for all three phenylpiperazines in spite of the reported selectivity of MCPP and TFMPP for 5HT1B and of LY165163 for 5HT1A receptors. Furthermore, the affinity of these agents for serotonin receptors in the rat stomach fundus did not agree with their reported affinity for either 5HT1A or 5HT1B binding sites in rat cortical membranes. Thus, the similarity in affinities of these phenylpiperazine derivatives for serotonin receptors mediating contraction in the rat fundus along with their different affinities for 5HT1A and 5HT1B binding sites argues against the possibility that the serotonin receptor in the rat fundus is of the 5HT1A or 5HT1B subtype of serotonin receptor.     

Effects of β-endorphin on brain serotonin metabolism

Human β-endorphin (15 μg) administered intracisternally increased concentrations of serotonin (5HT) and its metabolite, 5-hydroxyindoleacetic. acid (5-HIAA), in brain stem and hypothalamus and decreased 5-HIAA concentrations in hippocampus. These data are compatible with the hypothesis that β-endorphin increases 5HT turnover in brain stem and hypothalamus and decreases 5HT turnover in hippocampus. β-endorphin increased in brain stem and hypothalamus and decreased in hippocampus the rate of pargyline-induced decline of 5-HIAA. β-endorphin decreased the rate of pargyline-induced accumulation of 5HT in all these brain regions. The probenecid-induced accumulation of 5-HIAA in brain stem was decreased by β-endorphin. These data are compatible with the hypothesis that β-endorphin increases release of 5HT from neurons in brain stem and hypothalamus and decreases release of 5HT from neurons in hippocampus. The data require further a hypothesis that β-endorphin either decreases 5HT reuptake in these three brain regions or increases 5-HIAA egress from brain.     

Acute exposure of rats to air ions: effects on the regional concentration and utilization of serotonin in brain

Exposure to electrically charged gas molecules (air ions) has been reported to influence physiological and behavioral functions in animals and humans although there is controversy as to whether these findings are valid. A popular hypothesis concerning the reported effects of air ions is that alterations in serotonin (5HT) metabolism, particularly in the brain, are involved. We measured the concentration and turnover of 5HT in rats exposed to 5.0 X 10(5) ions/cm3 for up to 66 hours. Contrary to previous reports of other investigators, we were unable to demonstrate any effect of exposure to air ions or associated DC electric fields on the concentration or turnover of 5HT in rats under carefully controlled and characterized exposure conditions.     

Serotonin in cisternal cerebrospinal fluid of the rat: measurement and use as an index of functionally active serotonin

A simple, selective reverse-phase HPLC-fluorometric method is described for the determination of serotonin (5HT) in cisternal CSF of the rat. The mean (+/- SE) value of CSF 5HT observed in control adult rats was 457 +/- 83 pg/ml (N = 16). In an attempt to validate the measure as an index of extracellular, or functionally active, 5HT, groups of animals were treated with fenfluramine, amitriptyline, pargyline, pargyline plus tryptophan, and 5-hydroxytryptophan plus carbidopa. In all cases CSF 5HT appeared to reflect well the presumed effects of the agents on extracellular levels of 5HT. CSF 5HT was superior in this regard to brain 5HT, brain 5HIAA, or CSF 5HIAA levels. The measurement of cisternal CSF 5HT would appear to offer a convenient index of functionally active 5HT.     

Regional Distribution and Relative Abundance of Serotonin2c Receptors in Human Brain: Effect of Suicide

Abnormalities in serotonin receptor subtypes have been observed in the postmortem brain of suicide victims. We examined the regional distribution of serotonin (5HT)(2C) receptor mRNA in several areas of the human brain and also compared its protein and mRNA expression in the prefrontal cortex (PFC), hippocampus, and choroid plexus between suicide victims and normal control subjects. 5HT(2C) receptors were found to be distributed in several areas of the human brain (in order of abundance): highly concentrated and richest in choroid plexus; hypothalamus; nucleus accumbens; with the lowest abundance in PFC and cerebellum. Comparison of 5HT(2C) receptors between suicide victims and control subjects showed higher protein levels in the PFC but not the hippocampus or choroid plexus of suicide victims. However, there were no significant differences in mRNA levels between suicide victims and control subjects in these brain areas. These results suggest that 5HT(2C) receptors are richly distributed throughout the brain with the highest level in the choroid plexus and that abnormalities in protein expression of 5HT(2C) receptors in the PFC may be associated with suicide.     

A rapid method for the simultaneous determination of noradrenaline, dopamine and 5HT in small samples of brain tissue

A rapid and sensitive method for the concurrent assay of 25 ng noradrenaline, dopaine or 5HT is presented, enabling the concentration of all three amines to be measured in a single small sample (20–40 mg) of brain tissue. The method has been applied to determine the concentration of these amines in different regions of rabbit brain.