Further evidence for the heterogeneous storage of noradrenaline in central noradrenergic terminals

Peptides that regulate food intake: norepinephrine is not required for reduction of feeding induced by cholecystokinin

CCK octapeptide (CCK-8) is released by the gut in response to a meal and acts via CCK(A) receptors on vagal afferents to induce satiety. However, the central neural pathways by which peripheral CCK-8 affects feeding are poorly understood. In the present study, we tested the hypothesis that norepinephrine (NE) is necessary for satiety induced by peripheral CCK-8 by using mice lacking dopamine beta-hydroxylase (Dbh(-/-)), the enzyme responsible for synthesizing NE and epinephrine from dopamine. We found that Dbh(-/-) mice are as responsive to the satiating effects of CCK-8 as their normal littermates.

Release of serotonin induced by 3,4-methylenedioxymethamphetamine (MDMA) and other substituted amphetamines in cultured fetal raphe neurons: further evidence for calcium-independent mechanisms of release

The substituted amphetamines 3,4-methylenedioxymethamphetamine (MDMA), 3,4-methylenedioxyamphetamine (MDA), p-chloro-amphetamine (PCA) and fenfluramine (FEN) all exert their effects by releasing serotonin (5-HT) from presynaptic nerve terminals. In the current study, we examined the ability of these agents to induce the release of 5-HT in culture fetal raphe neurons. The data indicate that the rank order of release potencies for these agents was (+/-)PCA>(+)MDMA=(+)MDA=(+/-)FEN. Studies examining the role fo calcium in 5-HT release demonstrate that preventing calcium influx with L- and N-type calcium channel blockers inhibits potassium-stimulated release of -3H-5-HT but has no effect on release induced by the substituted amphetamines. Furthermore, omitting calcium from the extracellular media or depleting the vesicular pool of neurotransmitter with continual potassium stimulation did not affect the release of -3H-5-HT induced by these compounds. Administration of fluoxetine prior to the substituted amphetamines significantly attenuated the releasing effects of these agents, while producing no effect on potassium-stimulated release. These results are consistent with the notion that the amphetamines induce release of cytoplasmic 5-HT via the plasma membrane transporter.

Central alpha 1-adrenergic stimulation in relation to the behaviour stimulating effect of modafinil; studies with experimental animals

Single administration of the new drug modafinil was followed by an increase in locomotor activity in mice and in nocturnal activity in monkeys. Stereotyped behaviour in mice and rats, and potentiation of amphetamine-induced stereotyped behaviour were not observed; however, at the highest dose used, a slight potentiation of apomorphine-induced stereotyped behaviour was observed in rats. The modafinil-induced increase in locomotor activity in mice was prevented by the centrally acting alpha 1-adrenoceptor antagonists, prazosin and phenoxybenzamine, and by reserpine but not by the mixed dopamine D-1/D-2 antagonist, haloperidol, the dopamine D-2 antagonist, sulpiride, the peripherally acting alpha 1-adrenoceptor antagonist, phentolamine, the alpha 2-adrenoceptor antagonist, yohimbine, the beta-adrenoceptor antagonist, propranolol, or by the catecholamine synthesis inhibitor, alpha-methyl-p-tyrosine. Likewise, the modafinil-induced increase in nocturnal activity in monkeys was prevented by prazosin. Interestingly, modafinil did not produce obvious peripheral sympathetic effects in mice and rats (no salivation, no contraction of the pilomotor muscles, slight mydriasis only at high doses). Therefore, modafinil appears to produce a strong stimulating effect in rodents and in primates. These effects could be linked to modulation (stimulation) of central alpha 1-adrenoceptors unaccompanied by peripheral sympathetic effects, which is unexpected.

Dopamine-beta-hydroxylase inhibition acutely stimulates rats hypothalamic noradrenaline and dopamine neuronal activity as assessed from metabolic ratios and circulating glucose and ACTH responses

Because central noradrenaline neuronal activity is tonically inhibited by noradrenaline (NA) itself via an action at prejunctional alpha 2-adrenoceptors, it was hypothesised that the blockade of central NA synthesis following acute dopamine-beta -hydroxylase (DBH) inhibition might primarily deplete prejunctional NA levels and result in an increase in central NA neuronal activity through reduced NA autoinhibition. This hypothesis was tested in the rat following the acute administration of the DBH inhibitors diethyldithiocarbamate (DDC) and cysteamine (CSH). Computerised gas chromatography/mass spectrometry was used to precisely measure the hypothalamic levels of NA and dopamine (DA) together with those of their primary neuronal metabolites dihydroxyphenylethyleneglycol (DHPG) and dihydroxyphenylacetic acid (DOPAC), respectively. Both DDC (at 4 h) and CSH (at 30 min.) caused approximately a 50% reduction of hypothalamic NA concentrations. However this was associated with marked and highly significant increases in hypothalamic DHPG levels (by 50-100%) and in the hypothalamic ratio DHPG/NA. Also, when measured after CSH, the hypothalamic levels of the DHPG metabolite 3-methoxy-4-hydroxyphenylethyleneglycol were highly significantly increased. Consistent with increased DA neuronal activity, both DBH inhibitors raised DA and DOPAC levels and also the ratio DOPAC/DA in the hypothalami of treated rats and markedly suppressed serum prolactin levels (all p less than 0.01). The rise in hypothalamic concentrations of DHPG indicates that an increase in hypothalamic NA neuronal activity occurs following DBH inhibition. Significant elevations of blood glucose, corticosterone and ACTH were also observed after DBH inhibition. As we have previously demonstrated that increased central NA activity is associated with elevations of blood glucose, corticosterone and ACTH, these data provide further evidence for a functional increase in central NA activity caused by acute DBH inhibition. It is proposed that the increase in hypothalamic NA activity after DBH inhibition results from a primary depletion of the prejunctional alpha 2-active autoregulatory pool of NA.

Association of serotonin, dopamine, or noradrenaline with an actin-like component in pheochromocytoma (PC12) cells

A rat pheochromocytoma (PC12) cell line was used to examine the possibility that 5-hydroxytryptamine (serotonin), 3,4-dihydroxyphenylethylamine (dopamine), or noradrenaline may be associated with cytoplasmic actin, as was suggested by previous in vitro binding studies on an actin-like protein from rat brain synaptosomes. When PC12 cells were incubated with [3H]serotonin. [3H]dopamine, or [3H]noradrenaline for 30 min at 37 degrees C, approximately 2-4% of the radioactivity present in the cells was found to be associated with a high-molecular-weight (actin-like) component in supernatant fractions. Evidence relating this monoamine binding component to actin filaments includes: (a) its strong absorption by myosin filaments at low ionic strength: (b) a decrease in its affinity for myosin in the presence of 1 mM ATP, which lowers the affinity of authentic actin for myosin: (c) displacement of bound [3H]serotonin from it by DNase I, which binds strongly to actin and which inhibits [3H]serotonin binding to actin in vitro; (d) an increase in its binding of each monoamine (by 25-40%) after PC12 cells were preincubated with 10 microM cytochalasin B (a drug that induces depolymerization of F-actin). These findings suggest that serotonin, dopamine, or noradrenaline may associate with actin filaments in vivo.

Selective noradrenaline depletion markedly alters stress responses in rats

Rats were given FLA-63, followed by R04-1284 0.5 h later to relatively selectively deplete brain NA. After 8 h, some animals were examined for regional brain NA and MHPG-SO4, while some were subjected to 3 h of cold-restraint stress and then examined. All brain regions examined showed significant NA and MHPG reduction. Specific NA depletion markedly exacerbated restraint ulcer formation and plasma corticosterone levels. NA depletion without restraint stress did not induce ulcers or elevate corticosterone. Intact brain NA activity appears to be essential for coping with stress.

Stress and brain noradrenaline: a review

Noradrenergic neural systems have been expressly implicated in pathophysiological conditions induced by stress. The majority of experimental evidence supports a central role for brain noradrenaline in mediating the effects of stress and predisposing an organism to stress pathology as well as in producing a well-documented consequence of stress exposure-behavioral depression. This review briefly discusses the noradrenergic (NA) pathways involved, the functioning of NA synapses and their associated receptors and focuses directly upon the effects of stress on NA activity in the brain. These broad categories are discussed in terms of: 1. behavioral versus neurochemical explanations for the effects of stress; 2. the methods used to produce stress; 3. measurement of NA and its major metabolite ("turnover"); 4. regional brain effects of stress; 5. effects of pre-stress alterations in brain NA activity upon subsequent stress-induced brain NA changes; 6. correlation of stress-induced brain NA changes with peripheral manifestations of stress; and 7. predisposing factors in stress-induced neurochemical alterations.

Noradrenergic neurotransmission in the brain of a convulsive mutant mouse, differences between the cerebral cortex and the brain stem

The Quaking mouse is a genetically determined model of convulsive disorders. We investigated the modulation of noradrenergic neurotransmission through alpha 2-adrenoceptors in the occipital cortex and the brain stem of this mutant. The endogenous levels of noradrenaline were similar in the cerebral cortex of the Quaking mice and their corresponding controls, while a significant increase of endogenous noradrenaline was found in the brain stem of the mutants. The rate of disappearance of noradrenaline in the cerebral cortex and the brain stem after injection of FLA 63 was identical in control and Quaking mice. The calcium-dependent electrically evoked overflow of 3H-noradrenaline from slices of occipital cortex was inhibited by clonidine and enhanced by yohimbine in Quaking as well as in normal mice. The negative feed-back mechanism mediated by presynaptic alpha 2-adrenoceptors operates to a similar extent in both strains of mice. In contrast to the occipital cortex, in the brain stem, the amount of neurotransmitter released by electrical stimulation was significantly increased in Quaking mice when compared with controls. However, in the brain stem, the negative feed-back regulation of noradrenaline release operates to a similar extent in both strains of mice. When the endogenous levels of MOPEG were determined in the brain stem, they were found to be significantly higher in the Quaking mice when compared to the controls. The results suggest that an increase in noradrenergic neurotransmission in the brain stem, rather than in the cerebral cortex, could contribute to the behavioural abnormalities exhibited by the Quaking mice.

An improved pharmacological procedure for depletion of noradrenaline: pharmacology and assessment of noradrenaline-associated behaviors

A pharmacological procedure which initially depletes noradrenaline (NA), dopamine (DA) and 5-hydroxytryptamine (5-HT) but permits repletion of DA and 5-HT was used to evaluate the role of NA in feeding behavior and intracranial self-stimulation behavior. The rapid-onset 'reserpine-like' vesicular depletion drug RO 4-1284 reduced NA and 5-HT 99% and DA 90% in rat forebrain within 1 h after administration with complete repletion of all amines occurring within 6 to 12 h. Treatment with the dopamine-beta-hydroxylase inhibitor FLA-63 significantly reduced NA (maximum depletion 42%) but not DA or 5-HT over the 12 h period of evaluation. The two drugs together produced a specific depletion of NA. Forebrain levels of NA in subjects pretreated with FLA-63 then given RO 4-1284 0.5 h later were reduced to 2% of control values for 8 h while vesicular stores of DA and 5-HT were repleted 77% and 93%, respectively, within 8 h after administration. Selective depletion of NA, in this manner, reduced deprivation induced food intake and lateral hypothalamic self-stimulation.

Kinetic characteristics of newly synthesized 3H-5-HT in the brain of control and reserpinized mice. Evidence for the heterogeneous distribution of 5-HT in serotoninergic neurons

Following an intravenous administration of 3H-tryptophan to mice, 3H-serotonin rapidly accumulated in the brain, with a maximum around the 20th min after the injection. In mice whole monoamine oxidase activity was blocked by pargyline (75 mg/kg i.p.), reserpine pretreatment (5 mg/kg, 24 h before death) did not alter the initial accumulation of 3H-5-HT indicating that the rate of 5 HT synthesis was similar in control and reserpinized animals. When monoamine oxidase was not blocked, the accumulation of 3H-5-HT was significantly lower in reserpine-treated mice than in controls. However, the specific activity of 3H-5-HT accumulated in brain was 2-3 times higher in reserpinized (45 h) than in control mice. Since neither the specific activity of the precursor 3H-tryptophan, the reuptake process for 3H-5-HT nor the absolute synthesis rate of 5-HT was altered in the brain of reserpinized mice, it is proposed that the differences observed in the specific activity of 3H-5-HT reflected the presence of 3H-5-HT in different compartments in control and reserpinized mice. Serotonin would be distributed in a "storage" and a "functional" compartments in serotoninergic neurons under normal conditions whereas only the functional compartment would exist 18-48 h after the administration of reserpine.

Absence of glucoprivic feeding after stress suggest impairment of noradrenergic neuron function

Feeding in response to 2-deoxy-D-glucose (2DG), a quantifiable behavior which appears to depend on noradrenergic (NE) neuron function, was used in these experiments to evaluate the functional capabilities of NE neurons after stress exposure. Depletion of hypothalamic NE after footshock or hypothermic stress was directly correlated with impairment of glucoprivic feeding. When NE depletion was prevented by prior exposure to chronic stress, no impairment of feeding was observed. After hypothermic stress, repletion of NE proceeded more rapidly in the telencephalon than in the hypothalamus and reappearance of a normal feeding response precisely paralleled the time course of repletion in the hypothalamus. Drinking in response to cell dehydration, a behavior not directly dependent on brain catecholamines, was not impaired after either footshock or hypothermic stress, despite similar NE depletions. Presence of a normal drinking response assured that deficits observed in the 2DG test were not due to nonspecific behavioral suppression resulting from stress. These data suggest that NE neuron function may be impaired or temporarily abolished after severe stress exposure. In addition, these results demonstrate that behavioral pathology need not be the result of massive neurotransmitter depletion but may result from relatively subtle alterations of specific neurotransmitter pools.

The functional pool of brain catecholamines: its size and turnover rate

Behavioral data are reviewed that give evidence for an indiscriminate involvement of brain catecholamines (CA), especially dopamine (DA), in nerve function, regardless of the time elapsed from their synthesis. Critical analysis of biochemical and pharmacological studies shows that a clear-cut distribution of brain catecholamines in two compartments ['newly synthesized' (NS) and 'main storage'] is not at all established, and moreover that there is no adequate proof that the difference in turnover rates attributed to these two supposed pools is due to a preferential extraneuronal release of NS-CA during nerve function rather than to a preferential (nonfunctional) intraneuronal deamination of NS-CA, or at least of NS-DA.