Passive avoidance performance correlates with catecholamine turnover in discrete limbic brain regions

Experimentally naive male rats were sequentially tested for an exploratory (open-field) and a one-trial learning passive avoidance behavior. Subsequently, α-MPT-induced disappearance of noradrenaline (NA) and dopamine (DA) was determined in microdissected brain regions. The animals were classified as good or poor avoiders on the basis of their performance in passive avoidance retention test. Trained controls were subjected to the same training except of electric foot-shock during the learning trial. The rate constant of NA disappearance was higher in the hippocampal dentate gyrus of the good vs. poor avoiders. In the good avoiders, the rate constant of DA disappearance was significantly higher in the central nucleus of the amygdala. The different turnover of catecholamines in the dorsal hippocampus and the amygdala in relation to passive avoidance performance suggests that individual differences in memory and/or learning may correlate with the catecholamine turnover of certain limbic structures.     

Arginine8-vasopressin affects catecholamine metabolism in specific brain nuclei

Following the i.c.v. administration of arginine⁸-vasopressin (30 ng in 1 μl saline) to rats that had been injected i.p with α-MPT 30 min prior to the administration of the peptide catecholamine metabolism was altered in a restricted number of brain nuclei. Noradrenaline disappearance was accelerated as compared to saline treated controls in the dorsal septal nucleus, the anterior hypothalamic nucleus, the medial forebrain bundle, the parafascicular nucleus, the dorsal raphe nucleus, the locus coeruleus, the nucleus tractus solitarii and the Al-region. In the supraoptic nucleus and the nucleus ruber a decreased noradrenaline disappearnce was observed after the administration of the peptide. Dopamine disappearance was accelerated in the caudate nucleus, the median eminence, the dorsal raphe nucleus and the A8-region. These results support the view that vasopressin is participating in the regulation of a variety of physiological processes by modulating neurotransmission in specific brain nuclei.     

Effect of a fall of blood pressure on the release of catecholamines in the hypothalamus

The posterior hypothalamus of anaesthetized cats was superfused through a push-pull cannula and the release of endogenous catecholamines was determined in the superfusate which was continuously collected in 15 min periods. Fall in blood pressure elicited by nitroprusside or bleeding led to an increased rate of release of noradrenaline, adrenaline and dopamine in the hypothalamus. Transection of the brain causal to hypothalamus greatly reduced the rate of resting release of the catecholamines and abolished the enhancing effects of bleeding and nitroprusside. Determination of the catecholamines in samples which were collected in 90 s periods suggested a different pattern of release of the three catecholamines. Further shortening of the collection period (10 s) showed that the fall in blood pressure immediately increased the release of dopamine, while the rates of release of noradrenaline and adrenaline were increased gradually. Hypotension did not influence the rates of release of the catecholamines in the anterior hypothalamus. It is concluded that dopamine, adrenaline and noradrenaline systems of the hypothalamus are involved in the regulation of the arterial blood pressure. The different patterns of release might indicate that dopamine exerts a different function from those of noradrenaline and adrenaline in the normalization of the blood pressure after acute hypotension.     

THE METABOLISM OF TRITIATED DOPAMINE IN REGIONS OF THE RAT BRAIN IN VIVO—II

Abstract— The levels of tritiated catecholamines and metabolites were measured in regions of the rat brain at intervals after the intraventricular injection of [³H]dopamine, [³H]nor-adrenaline and [³H]normetanephrine. The disappearance of catecholamines and appearance of metabolites with time and the regional turnover rates of these amines indicate that the major pathway of the metabolism of noradrenaline and dopamine actively released from physiological storage sites is to the neutral alcoholic metabolites. The acid metabolites, homovanillic acid and 3,4-dihydroxyphenylacetic acid appear to be only minor products of normal dopamine metabolism in rat brain regions including the striate, but are the main end products of the metabolism of excess exogenous dopamine.
The active metabolism of stored noradrenaline to alcohol metabolites is also indicated by the increase in neutral alcohol metabolites accompanying the increased noradrenaline turnover when rats were subjected to electroshock stress. Therefore in the rat brain, neutral alcohol metabolites of dopamine and noradrenaline have great significance in the study of physiological catecholamine turnover in any region.     

Differential effects of experimentally induced blood pressure changes on the release of catecholamines in hypothalamic and limbic areas of rats

The effects of longer lasting blood pressure changes on the release of endogenous catecholamines (CA) in limbic and hypothalamic areas were studied in anaesthetized rats. For this purpose the central nucleus of the amygdala (AC), ventral hippocampus (VH) and medial hypothalamus (MH) were simultaneously superfused through push-pull cannulae with artificial cerebrospinal fluid and the release of the endogenous catecholamines dopamine (DA), noradrenaline (NA) and adrenaline (A) was determined before and after blood pressure manipulations. A fall in blood pressure elicited by the ganglionic blocking agent chlorisondamine resulted in different changes of the various CA release patterns in AC. Short lasting increased CA release rates as compared to prehypotension levels could be observed in the hippocampus. The activity of catecholaminergic neurons in MH remained unchanged. A rise in arterial blood pressure induced by intravenous injection of tramazoline did not change the release rates of DA in all 3 brain areas studied. In hippocampus, NA levels in the superfusates decreased initially during hypertension but returned to normal values 40 min after drug injection. In the late phase of hypertension increased rates of release of NA in the amygdala and of A in the hypothalamus could be observed. The different patterns in the release of CA suggest that DA, NA and A are differentially implicated in the regulation of experimentally induced blood pressure changes.     

Immobilization stress-induced changes in catecholamine levels in the individual cerebral nuclei in rats of different zoosocial ranks

Immobilization stress induced catecholamines level changes were studied in brain nuclei, taking part in blood pressure central regulation in rats with different zoosocial position. The significant differences in catecholamines level between the zoosocial groups of rats were shown in dopamine synthesized hypothalamic nuclei-n. arcuatus, n. periventricularis and noradrenaline synthesized-n. subcoeruleus++. The dominant rats were characterized by the highest catecholamines level.     

Age related changes in noradrenaline,noradrenaline turnover and adrenaline in brainstem nuclei of wistar kyoto and spontaneously hypertensive rats

Noradrenaline and noradrenaline turnover were determined in regions enriched in catecholamine nuclei of the brainstem (A1, A2, C1, C2 and C3), in the locus coeruleus (A6) and in the nucleus tractus spinalis n. trigemini (Sp5C) of Wistar Kyoto and spontaneously hypertensive rats at four ages from 6 to 40 weeks. Adrenaline levels were also determined but were only consistently detected in the C1 and C2 regions. There was an age-related decline in noradrenaline concentrations in both strains of rats in all brainstem catecholamine nuclei however noradrenaline turnover decreased only in the A2 and C3 regions and this may contribute to the progressive rise in blood pressure with age in spontaneously hypertensive and Wistar Kyoto rats. Adrenaline levels did not alter with age providing evidence of a functional disassociation between adrenaline and noradrenaline neuronal systems. There were several strain-related differences in noradrenaline and adrenaline concentrations in the regions studied, however noradrenaline turnover was reduced only in the A2 and C2 regions (nucleus tractus solitarius) of spontaneously hypertensive rats which is consistent with the sympathoinhibitory role of this nucleus in central blood pressure regulation.     

Catecholamines in Regulation of Development of GnRH Neurons of Rat Fetuses

The contents of dopamine, serotonin, and noradrenaline in rat fetuses developing under the conditions of their deficiency induced by administration of α-methyl-para-tyrosine to females during 11th to 16th or 20th day of pregnancy and in fetuses, whose mothers were given saline at the same time, were determined using HPLC with subsequent electrochemical detection. Administration of α-methyl-para-tyrosine led to decreased levels of dopamine and noradrenaline in the areas of migration of GnRH-neurons in fetuses on days 17 and 21 of prenatal development. The concentration of serotonin remained unchanged, except in the head nasal area in males on day 21. The areas of interaction between the brain catecholaminergic systems and migrating and differentiating GnRH-neurons were determined by double immunohistochemical labeling. Close topographical location of GnRH-immunoreactive neurons and tyrosine hydroxylase-immunoreactive in the area of nucleus accumbens on days 17 and 20, as well as in the median eminence on day 20. The GnRH concentration in the caudal areas of migration of GnRH-neurons under the normal conditions and in the case of catecholamine deficiency was determined using radioimmunoassay. After administration of α-methyl-para-tyrosine the GnRH concentration in the anterior hypothalamus decreased in females. The data obtained suggest the involvement of catecholamines in the regulation of development of GnRH-Neurons during prenatal development. In addition, the adequacy and efficiency of the used model of catecholamine deficiency for studying the development of such neurons was confirmed.     

Regional distribution of catecholamines in rat brain after L-3-O-methyldopa and L-dopa

The distribution of labelled dopamine (DA) and noradrenaline (NA) in the various brain regions of the rat was similar after administration of L-¹⁴C-3-0-methyldopa (OMD) or L-¹⁴C-dopa, DA showing the greatest accumulation in the striatum and NA in the hypothalamus. The concentration of catecholamines 2 hours after OMD amounted to 2–15 % of those found after L-dopa. In the whole brain, the cerebral catecholamines formed from dopa decreased more rapidly than those originating from OMD. In conclusion, OMD is a precursor of cerebral catecholamines; however, it is less effective than dopa.     

Photoaffinity Labelling of MSH Receptors on Anolis Melanophores: Effects of Catecholamines,Calcium and Forskolin

Abstract

Photoaffinity labelling of MSH receptors on Anolis melanophores was used as a tool for studying the effects of catecholamines, calcium and forskolin on hormone-receptor interaction and receptor-adenylate cyclase coupling. Covalent attachment of photoreactive α-MSH to its receptor was suppressed in calcium-free buffer but was hardly influenced by catecholamines or forskolin. The longlasting signal generated by the covalent MSH-receptor complex was readily and reversibly abolished by adrenaline, noradrenaline, dopamine or clonidine or by the absence of calcium. The suppression of pigment dispersion by catecholamines was blocked by the simultaneous presence of yohimbine but not prazosin, indicating that the catecholamines antagonize the α-MSH signal by inhibitory action on the adenylate cyclase system through an alpha-2 receptor. Forskolin, which stimulates melanophores by direct action on the catalytic unit of the adenylate cyclase and at about the same speed as α-MSH, produced a slower and weaker response in the presence of noradrenaline. If MSH receptors were covalently labelled and then exposed to noradrenaline, the characteristics of the forskolin-induced response were identical to those of unlabelled cells that had not been exposed to noradrenaline. This may point to a partial restoration of receptor-adenylate cyciase coupling by forskolin. The results show that the longlasting stimulation of Anolis melanophores by photoaffinity labelling proceeds via a permanently stimulated adenylate-cyclase system whose coupling to the receptor depends on calcium and is abolished by alpha-2 receptor agonists. Calcium is also essential for hormone-receptor binding.     

The effects of biogenic monoamines and related agonists and antagonists on the isolated,perfused branchial heart of sepia officinalis L. (cephalopoda)

1. The chronotropic and inotropic effects of biogenic monoamines were examined on the isolated and perfused branchial heart of the common cuttlefish Sepia officinalis (L.).2. Adrenaline, noradrenaline and dopamine caused concentration-dependent increases in pressure amplitude, dopamine being 100-fold less potent than adrenaline and noradrenaline. The catecholamines hardly affected frequency.3. Octopamine, histamine and GABA did not influence normal heartbeat.4. Serotonin was either ineffective or produced variable responses, whereby the efficacy of the substance was not graded to the concentrations applied. It is supposed that serotonin is not involved in branchial heart regulation.5. The actions of different adrenergic agonists and antagonists indicate the presence of a myocardial adrenoceptor which closely resembles the α₁-type.     

Effects of 6-hydroxydopamine on brain and blood catecholamines, ammonia, and amino acids in rats

The effect of 6-hydroxydopamine (6-OHDA) upon brain and blood catecholamines, ammonia, and amino acids has been studied in rats subjected to increasing doses of the drug. Time dependent effects after injection have also been studied. Systemically injected 6-OHDA significantly, acutely reduced brain adrenaline (A), noradrenaline (NA), total catecholamines (TC), gamma-aminobutyric acid (GABA), and glutamic acid (Glu); concomitantly brain ammonia (NH3) increased. In blood, NA and TC were reduced and A and NH3 increased. The changes in brain monoamines are surprising since it has been reported that 6-OHDA does not cross the blood-brain barrier. We have proposed that these changes result from a general stress response or a reflex peripheral sympathetic response to falling blood pressure which in some manner communicates to the central nervous system. As the dose of 6-OHDA increased, brain NH3 increased and Glu decreased. A similar effect was seen from a single dose as the time after injection for sampling brain and blood constituents increased. Blood ammonia increases without change in Glu, glutamine, or asparagine. The source of NH3 may be from deamination of adenine nucleotide or catechols released from nerve terminals under the abnormal stimulus of 6-OHDA.     

Systolic Blood Pressure is Related to Catecholamine Sensitivity in Subcutaneous Abdominal Fat Cells

A relationship between abdominal obesity and hypertension is well established. In search for an early-onset defect in adipocyte function linking these two conditions, we compared catecholamine sensitivity in subcutaneous abdominal fat cells with 24-hour systolic, mean arterial and diastolic blood pressure in 16 healthy, normotensive subjects. Clear inter-individual variations in the adipocyte lipolytic adrenoceptor sensitivity (pD₂) for noradrenaline were observed in dose-response experiments (i.e., about 4 log units). An inverse and independent correlation was found between the 24-hour systolic blood pressure and pD₂ for noradrenaline (r = ?0.67, p < 0.01). The mean arterial blood pressure was also negatively correlated to peripheral noradrenaline sensitivity (r = ?0.58, p < 0.05). However, no significant relationship between the 24-hour diastolic blood pressure and pD₂ for noradrenaline was demonstrated. In conclusion we suggest that catecholamine resistance in subcutaneous fat cells may be associated with autonomic dysfunction and impaired blood pressure regulation. This finding is supported by the fact that both noradrenaline sensitivity and 24-hour systolic blood pressure also are correlated to the individual orthostatic heart rate responses, reflecting the sympathetic nervous system tone (r=0.61, p=0.01 and r= ?0.53, p=0.03, respectively). The relationship between noradrenaline sensitivity and systolic blood pressure may be of importance in the early development of hypertension in man.     

Autonomic nervous control of blood pressure and heart rate during hypoxia in the cod,Gadus morhua

Summary The autonomic nervous and possible adrenergic humoral control of blood pressure and heart rate during hypoxia was investigated in Atlantic cod. The oxygen tension in the water was reduced to 4.0–5.3 kPa (i.e.. P_wO₂=30–40 mmHg), and the fish responded with an immediate increase in ventral and dorsal aortic blood pressure (P _va P _da), as well as a slowly developing bradycardia. The plasma concentrations of circulating catecholamines increased during hypoxia with a peak in the plasma level of noradrenaline occurring before the peak for adrenaline. Bretylium was used as a chemical tool to differentiate between neuronal and humoral adrenergic control of blood pressure and heart rate (f _H) during hypoxia. The increase in P _va and P _da in response to hypoxia was strongly reduced in bretylium-treated cod, which suggests that adrenergic nerves are responsible for hypoxic hypertension. In addition, a small contribution by circulating catecholamines to the adrenergic tonus affecting P _va during hypoxia was suggested by the decrease in P _va induced by injection of the -adrenoceptor antagonist phentolamine. The cholinergic and the adrenergic tonus affecting heart rate were estimated by injections of atropine and the -adrenoceptor antagonist sotalol. The experiments demonstrate an increased cholicholinergic as well as adrenergic tonus on the heart during hypoxia.     

Chemical sympathectomy and diurnal fluctuations of noradrenaline calorigenic action in the rat

In the rat, in which a diurnal fluctuation of the sensitivity to noradrenaline was previously found, the effect of injected 6-hydroxydopamine (6-OHDA) was investigated. The heat production and catecholamines contents in the interscapular brown adipose tissue, heart and adrenals were measured. Chemical sympathectomy induces a disappearance of diurnal fluctuation in the sensitivity to injected noradrenaline. In these animals a lower capacity for heat production was found. However, a significant calorigenic effect of injected noradrenaline in 6-OHDA-treated animals was still present. In sympathectomized animals a depletion of noradrenaline from interscapular brown adipose tissue and the heart was observed. Besides, a change in adrenaline/noradrenaline ratio was found in the adrenals.     

Acute flesinoxan treatment produces a different effect on rat brain serotonin synthesis than chronic treatment: An α-methyl-l-tryptophan autoradiographic study

5-HT_1A receptor agonists display anxiolytic and anti-depressant properties in clinical studies. In this study, we used the α-[¹⁴C]methyl-l-tryptophan (α-MTrp) autoradiographic method to evaluate the effects of the 5-HT_1A agonist, flesinoxan, on regional 5-HT synthesis in the rat brain, following acute or a 14-day continuous treatment. In the first series of experiments, flesinoxan (5 mg/kg; i.p.) was administered 40 min before the α-MTrp. It resulted in a significant increase of the arterial blood oxygen partial pressure (pO₂) and a reduction of the regional rate of 5-HT synthesis throughout the brain, with the exception of a few regions (medial geniculate body and thalamus). In the second series of experiments, flesinoxan (5 mg/kg day) was administered for 14 days, using an osmotic minipump implanted subcutaneously. When compared to rats treated with saline, there was an overall significant (p < 0.05) reduction in the synthesis (one-sample two-tailed t-test). However, there was no significant influence on the 5-HT synthesis rate in the dorsal and median raphe nuclei and the majority of their projection areas. A significant (p < 0.05) reduction was observed in the nucleus raphe magnus, medial caudate, ventral thalamus, amygdala, ventral tegmental area, medial forebrain bundle, nucleus accumbens, medial anterior olfactory nucleus and superior olive. The unaltered 5-HT synthesis rates in a large majority of regions following the 14-day treatment of flesinoxan may reflect the normalization (implies to not be different from salne treated control) of synthesis due to a desensitization of 5-HT_1A autoreceptors on the cell body of 5-HT neurons as well as at postsynaptic sites, which is known to occur following long-term treatment with 5-HT_1A agonists. It is of some importance to note that the normalization of the synthesis occurred in the majority of the brain limbic structures, the brain areas implicated in affective disorders and the corresponding successful treatments, as well as in the cortical regions, which are implicated in mood. However, there were some terminal regions (e.g., accumbens, anterior olfactory, lateral thalamus, raphe magnus and obscurus) in which the chronic flesinoxan treatment resulted in a significant reduction of synthesis, suggesting that there was not a full desensitization across the brain of the receptors controlling 5-HT synthesis.     

Changes in the balance of biogenic monoamines and their metabolites in the organs of rats with oxygen-induced epilepsy

The content of some biogenic monoamines and their metabolites in rat brain and heart in different periods of oxygen epilepsia was studied using high performance liquid chromatography with electrochemical detection. It was shown that already at the 5th minute of exposure to oxygen adrenaline, DOPA and some noradrenaline metabolites disappeared in the brain and noradrenaline level reduced. At this period in rat heart the reduction of catecholamine content was the most distinct and serotonin level was unchanged. At the beginning of convulsive period the modifications of biogenic amines content were nonparallel in brain regions: in the heart the reduction of catecholamine level went on, especially in right ventricle. In the terminal phase of oxygen epilepsia brain biogenic amines increased, however, not up to normal meaning, heart catecholamines at this period were at the same level as at the beginning of the convulsive period.     

Cerebrovascular reserve in the cat after acute bilateral carotid occlusion

Cerebral blood flow in the cat was studied before and after acute bilateral common carotid occlusion under normocapnic and hypercapnic conditions and after induced hypotension. Regional blood flow to different brain structures was studied with the microsphere method. Local blood flow in the caudate nucleus, the cerebral cortex and medulla oblongata was studied with H2-polarography. Although the blood flow to the anterior brain regions is significantly decreased after bilateral common carotid occlusion, their blood supply is kept above ischaemic levels by re-distribution of the vertebrobasilar flow. Cerebrovascular reserve in anterior brain regions, however, is lost as indicated by the severe impairment of both the flow response to hypercapnia and to blood pressure decrease. After bilateral common carotid occlusion paradoxical CO2-reactions, indicating intracerebral steal, were seen in the caudate nucleus. In posterior brain regions resting blood flow, flow-reaction to hypercapnia and to hypotension are better preserved under these conditions. Measurement of the CBF responses to induced hypercapnia is a dependable test for appreciation of cerebrovascular reserve after cerebrovascular occlusion but may be potentially hazardous where local flow is close to ischaemic levels.     

SUBCELLULAR DISTRIBUTION OF DOPAMINE-β-HYDROXYLASE AND INHIBITORS IN THE HIPPOCAMPUS AND CAUDATE NUCLEUS IN SHEEP BRAIN

—The enzyme dopamine-β-hydroxylase (EC 1.14.17.1) which converts dopamine to noradrenaline was found to be present in substantial amounts in sheep brain hypothalamus and caudate nucleus and was located to the synaptic vesicle fractions in these two brain regions by subcellular fractionation. This dopamine-β-hydroxylase was associated with paniculate matter in these two brain regions since it was resistant to solubilization with butan-1-ol and 0.1% Triton X-100. As highly significant levels of dopamine-β-hydroxylase were present in the caudate nucleus, factors other than a simple lack of this enzyme must operate to maintain the low levels of noradrenaline and high levels of dopamine in the caudate nucleus. Purified adrenal dopamine-β-hydroxylase was substantially inhibited by two factors prepared from sheep brain hypothalamus and caudate nucleus. These were found to be cupric ions and a sulphydryl inhibitor. High levels of the sulphydryl inhibitor of dopamine-β-hydroxylase were found in synaptosomal fractions from sheep brain hypothalamus and caudate nucleus and the levels were comparable in both regions. Upon subfractionation of a synaptosome-containing fraction from the hypothalamus, the inhibitor was located predominantly in the soluble fraction, although there were significant levels in the synaptic vesicle fraction. Therefore, the sulphydryl inhibitor must be considered as a possible regulator of dopamine-β-hydroxylase activity. Free cupric ion concentrations as low as 2·5 μM were found to inhibit purified adrenal dopamine-β-hydroxylase in vitro and the concentration of copper in the soluble tissue component of hypothalamus and caudate nucleus was well above this minimal copper concentration. The percentage content of soluble copper in the caudate nucleus was significantly higher than in the hypothalamus. The importance of the soluble to particulate-bound ratio of copper in brain was shown in studies of the developing rat brain. A rapid increase in the level of copper in brain was found in the first 4 weeks but the level was constant by 2 months of age. The percentage of soluble copper, however, was maximal soon after birth and had declined to a constant figure by 2 months of age. A scheme for the regulation of dopamine-β-hydroxylase activity involving these factors is proposed.     

Influence of plasma substitutes on the concentration of tissue catecholamines in rats

The concentration of catecholamines was determined in the brain, heart and adrenals in normovolaemic and hypovolaemic rats after reinfusion of the lost blood and after infusion of equivalent volumes of plasma substitutes (dextran and modified gelatins). After infusion of these preparations in normovolaemic rats noradrenaline concentration increased significantly in the myocardium. It was found also that restoration of normal blood volume by infusion of plasma substitutes prevented changes in catecholamine concentrations induced by hypovolaemia in the brain but not in the adrenals.