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.     

THE EFFECTS OF PRECURSOR LOADING IN THE CEREBRAL METABOLISM OF 5-HYDROXYINDOLES

—Using either tryptophan or 5-hydroxytryptophan as the precursor, and examining the metabolites in whole rat brain and in brain regions of dog, the pattern of metabolites resembled that found under physiological conditions only after tryptophan administration. From these and other observations on the cerebral 5-hydroxyindoles the main conclusions are firstly, that there are regional differences within brain in storage, turnover or metabolic fate of 5-HT. Secondly, that the normal pathway appears to be well localized biochemically with linking of its succeeding steps, and thirdly, that turnover through the system is normally controlled by intracerebral tryptophan 5-hydroxylase in both rats and dogs although there are differences between the species in the cerebral metabolism of 5-HT.     

BRAIN TISSUE AND PLASMA ASSAY OF L-DOPA AND α-METHYLDOPA METABOLITES BY HIGH PERFORMANCE LIQUID CHROMATOGRAPHY WITH ELECTROCHEMICAL DETECTION

Using reverse phase high-performance liquid chromatography and electrochemical detection with mobile phases composed of simple acids, we have developed an assay technique to measure multiple catecholamines and their catechol metabolites in plasma or brain tissue with sensitivity to the picomole level. Ion-pairing chromatography with nitric or trichloroacetic acid as the mobile phase permits separation and quantitation of norepinephrine, α-methylnorepinephrine, epinephrine, dopamine, α-methyldopamine, l -DOPA, α-methyldopa, carbidopa, and DOPAC. Alumina extraction selectively isolates catechols which are then separated on a reverse-phase column and measured by a commercially available electrochemical detector. This method has been applied to measurement of L-DOPA metabolites in patients with Parkinson's disease treated with L-DOPA and carbidopa and to measurement of catecholamines in rat hypothalamus in the course of studies on L-DOPA and α-methyldopa metabolism. Dihydroxybenzylamine is added as an internal standard and standard curves are linear over two orders of magnitude in concentration with coefficients of variation averaging 3.1%. Quantitation is routinely done to 20 pmol with absolute sensitivity possible to 0.5 pmol.     

THE REGIONAL AND SUBCELLULAR DISTRIBUTION OF CATECHOL-O-METHYL TRANSFERASE IN THE RAT BRAIN

Catechol-O-methyl transferase (COMT) activities determined in different regions of rat brain showed small variations. Highest activities were found in the hypothalamus and corpora quadrigemina, and lowest activities in the hippocampus and corpus striatum. The regional distribution of COMT was thus at variance with the distribution of DOPA decar- boxylase in this study and with the distribution of catecholamines and tyrosine hydroxylase reported in the literature. Determinations of the subcellular distribution of COMT in rat forebrain showed that 50 per cent of the activity was recovered in the high speed supernatant fluid and about 33 per cent in the crude mitochondrial fraction. Further separation of the latter by discontinuous sucrose gradients showed that the particulate COMT was found in the synaptosomal fraction in an occluded form. Full enzyme activity was only obtained after treatment with a detergent or after resuspension in water. After hypo-osmotic rupture of the crude mitochondrial fraction, COMT was recovered in the cytoplasmic fraction. The subcellular distribution of COMT was very similar to the ones of lactate dehydrogenase and DOPA decarboxylase. The proportions of soluble COMT obtained from homogenates of various regions of the brain differed from that of choline acetyl transferase and DOPA decarboxylase but were similar to that of lactate dehydrogenase. In conclusion, COMT is a cytoplasmic enzyme almost evenly distributed in the CNS. Its distribution does not resemble the distributions of the catecholamines or of the enzymes participating in the synthesis of catecholamines.     

MASS FRAGMENTOGRAPHIC DETERMINATION OF SOME ACIDIC AND ALCOHOLIC METABOLITES OF BIOGENIC AMINES IN THE RAT BRAIN

—A mass fragmentographic procedure is described for the simultaneous quantification of a number of deaminated metabolites derived from tyramine, octopamine, dopamine, and norepinephrine. With this method, several of the metabolites were measured in normal rat brain. The results support the central nervous system origin of tyramine, octopamine and their metabolites. The concentration of the dopamine metabolite, homovanillic acid, in the rat brain was found to be about 15% higher than that of dihydroxyphenylacetic acid. As for the metabolites of norepinephrine, vanilmandelic acid concentration was found to be about 5% that of 3-methoxy-4-hydroxyphenylglycol. The possible role of vanilmandelic acid in the CNS metabolism of norephrine is discussed.     

FREEZE-BLOWING: A NEW TECHNIQUE FOR THE STUDY OF BRAIN IN VIVO

Abstract— A new apparatus is described which removes and freezes brains of conscious rats more rapidly than was heretofore possible. The apparatus consists of two probes which are driven simultaneously into the cranial vault of the rat immobilized in a specially constructed restraining cage. When in position, air under pressure enters through one probe and blows the supratentorial portion of the brain tissue (situated between the olfactory bulbs and the superior colliculi) out the other probe and into a thin chamber previously cooled in liquid N₂. This method stops brain tissue metabolism more rapidly than the previously-described methods of microwave irradiation, decapitation into liquid N₂, or whole-animal immersion into liquid N₂, as evidenced by the measurement of labile metabolites and redox states. Thus, samples of freeze-blown brain had higher levels of a-oxoglutarate, creatine phosphate, pyruvate, glucose and glucose-6-phosphate and lower levels of lactate, malate and AMP than brain tissue obtained by the other methods. The free cytoplasmic [NAD⁺]/[NADH₂], [NADP⁺]/[NADPH₂] and [ATP]/[ADP] [HPO₄^2-] ratios were higher in freeze-blown samples. These data indicate that more extensive anoxic metabolism occurred when methods other than freeze-blowing were used. We conclude that the levels of metabolites measured in brain obtained with the freeze-blowing technique more closely resemble those which occur in vivo.     

THE EFFECT OF MORPHINE ON THE TRANSPORT AND METABOLISM OF INTRACISTERNALLY-INJECTED LEUCINE IN THE RAT

—Intracisternally injected l or d-[¹⁴C]leucine was retained longer in the brains of morphine-treated rats than in saline-injected control animals. This resulted in higher levels of the labelled leucine and of labelled metabolites of the l-isomer in free pools of brain tissue. However, the absolute levels of brain amino acids and the relative distribution of radioactivity among l-leucine metabolites in brain were unaffected by treatment with morphine, indicating that no disturbance of leucine oxidation through the citric acid cycle was produced by the drug. The inhibition of protein synthesis caused by acute administration of morphine was calculated to be greater than previously reported since morphine treatment increased the specific radioactivity of the free pool of leucine in brain following the intracisternal injection of the labelled amino acid. Possible mechanisms responsible for these morphine effects are discussed.     

噪声对鼠脑内5-羟色胺(5-HT)代谢的影响

本文分析了静适应和不同类型的噪声对615鼠和小白鼠脑内5-HT代谢的影响.静适应可引起大多数615鼠脑内5-HT代谢显著性下降15.1%和19.6%.连续脉冲噪声可使其脑内5-HT代谢显著性增高10.2%和22.5%.静适应和连续脉冲噪声对大多数小白鼠脑内5-HT的代谢无显著性影响.但是优势频率为125-250Hz的低频杂乱噪声和粉红噪声都可引起静适应小白鼠脑内5-HT代谢显著性增高,分别增高29.0-39.7%和28.0-32.7%.     

INHIBITION OF RAT BRAIN PHENOL SULPHOTRANSFERASE IN VITRO BY NORADRENALINE and DOPAMINE METABOLITES1

Abstract— Kinetic parameters of the sulphotransferase reaction in rat brain were investigated in vitro at pH 7.4. Evidence is presented that the enzyme phenol sulphotransferase (EC 2.8.2.1) can be assayed with 4-methylumbelliferone or 3-methoxy-4-hydroxyphenylethyleneglycol as the substrate. Both assays give identical V_max values, whereas K_m values are 0.026 mm and 0.039 mm , respectively. Normetanephrine, metanephrine and the catecholamines adrenaline and dopamine, having a positive charge on the side chain at pH 7.4, do not inhibit 4-methylumbelliferone and 3-methoxy-4-hydroxyphenylethy-leneglycol sulphotransferase at this pH. Their deaminated metabolites 3,4-dihydroxyphenylethyleneglycol, 3,4-dihydroxymandelic acid, 3,4-dihydroxyphenylacetic acid, 3-methoxy-4-hydroxyphenylethylene glycol, 3-methoxy-4-hydroxyphenethanol and 3-methoxy-4-hydroxyphenylacetic acid inhibit both the enzyme activities. The type of inhibition is noncompetitive with the exception of 3-methoxy-4-hydroxy-phenylethyleneglycol, which is a competitive inhibitor of 4-methylumbelliferone sulphation. 3-Methoxy-4-hydroxy-mandelic acid does not inhibit the enzyme activities. It is concluded that the catecholamines themselves are not sulphated by rat brain in vitro at pH 7.4.     

EFFECT OF VITAMIN B6 ON PHENYLALANINE METABOLISM IN THE BRAIN OF NORMAL AND p-CHLOROPHENYLALANINE-TREATED RATS

Abstract— A phenylketonuria-like state was produced in the preweanling rat, and the metabolism of phenylalanine in the normal and phenylketonuric brain was compared. The effect of B₆ vitamers on the disposition of phenylalanine was also investigated. Phenylalanine was metabolized mainly by transamination and to a lesser extent by decarboxylation in both the normal and phenylketonuric-like brain. Small amounts of amine were detected in all the brains throughout the experimental period. More than 95 percent of the metabolized amino acid appeared as aromatic acids, which steadily accumulated and remained in the brain for the duration of the experiment. No change in the metabolic pattern was produced by pyridoxol. In striking contrast, pyridoxamine prevented the accumulation of acidic metabolites in the brains of all animals tested. We suggest that pyridoxamine phosphate and/or pyridoxamine is actively associated with the removal of excess keto acids and aldehydes from the brain.     

ALTERATIONS IN THE TURNOVER OF BRAIN NOREPINEPHRINE AND DOPAMINE IN ALCOHOL-DEPENDENT RATS

Abstract— The turnover of brain norepinephrine (NE) and dopamine (DA) was studied in five groups of male Sprague-Dawley rats under different conditions of alcohol treatment: no treatment, acute treatment while intoxicated, acute treatment subsequent to elimination of alcohol from the blood, alcohol-dependence while still intoxicated and alcohol-dependence during a withdrawal syndrome. Turnover was determined from the rate of depletion of brain catecholamine levels after inhibition of tyrosine hydroxylase. In rats given a single dose of alcohol, NE turnover was increased, while DA turnover was unaffected during the few first hours after treatment. After that time the turnover of both NE and DA was reduced. In alcohol-dependent rats, whether intoxicated or undergoing a withdrawal syndrome, the turnover of NE was increased, while that of DA was decreased. These data suggest that catecholamines may mediate some of the symptoms of the alcohol withdrawal syndrome in the rat.     

THE EFFECTS OF INTOXICATING DOSES OF ETHANOL UPON INTERMEDIARY METABOLISM IN RAT BRAIN

Abstract— The effect of acute (8-min) and prolonged (13-h) exposures to high doses of ethanol upon the intermediary metabolites of rat brain has been studied, with the use of a new freezing technique which minimizes post-mortem changes. Injection of ethanol (80 mmol/kg body wt) produced general anaesthesia within 8 min after administration. At this time there were increases in the brain contents of glucose, glucose-6-phosphate and citrate; there was no change in arterial pCO₂. Rats under ethanol anaesthesia for 13 h showed increases in brain contents of glycogen, glucose and glucose 6-phosphate; and decreases in lactate, pyruvate, α-oxoglutarate and malate. Under similar experimental conditions, arterial pCO₂, increased from 37 to 51 Torr. The changes in levels of metabolites after injection of ethanol were similar to those after administration of many volatile anaesthetic agents or elevation of brain CO₂ by other means. Although brain levels of malate and α-oxoglutarate decreased after prolonged exposure to ethanol, the mitochondrial redox state was maintained. Accordingly, the levels of glutamate and aspartate fell in accordance with the law of mass action. The maintenance of the cytoplasmic and mitochondrial redox states in the brain during ethanol intoxication was in marked contrast to the effects on the liver. We suggest that the different effects observed in brain and liver result from the action of ethanol upon the nerve cell membrane in brain, whereas the primary target in liver is alcohol dehydrogenase.     

CHEMICAL SPECIFICITY OF DOPAMINE TRANSPORT IN THE NIGRO-NEOSTRIATAL PROJECTION

Axoplasmic transport of dopamine in the nigro-neostriatal system has previously been shown by the specific accumulation of labelled dopamine in the striatum following injections of labelled DOPA or dopamine into the substantia nigra. To test the specificity, 17 different labelled materials (pipecolic acid, inulin, taurine, GABA, glycine, histidine, histamine, serotonin, 5-HTP, D-amphetamine, 3-methoxytyramine, dopamine, tyramine, norepinephrine, octopamine and high and low specificity activity DOPA) were injected into the substantia nigra and the distribution of radioactivity in the brain studied after 6 and 24 h. Only the catecholamines and octopamine gave evidence of specific accumulation in the ipsilateral striatum although some of the other compounds caused diffuse labelling of the striatum along with other brain areas.     

Composite Technique for Regional Neurochemical Studies: Measurement of Energy and Neurotransmitter Metabolites in Single Tissue Sample

A combined method is described for the determination of various metabolites from a single tissue sample of the brain. It comprises a quick inactivation of cerebral enzymes by microwave irradiation, easy separation of the desired brain regions, and perchloric acid extraction of tissue substances, which are assayed either by specific enzymatic techniques or by HPLC with electrochemical detection. The obtained values of most energy and neurotransmitter metabolites in the brain are in agreement with those reported using other methods. However, this technique, in contrast to the brain freezing in vitro or freeze-blowing, provides a more efficient procedure for rapid arrest of cerebral metabolism even in the deep brain structures and is therefore suitable for detection of early changes particularly those occurring in experimental pathological conditions such as ischemia.     

THE LEVELS OF LABILE INTERMEDIARY METABOLITES IN MOUSE BRAIN FOLLOWING RAPID TISSUE FIXATION WITH MICROWAVE IRRADIATION1

The levels of several labile glycolytic and organic phosphate metabolites in mouse brain were determined following rapid inactivation with 2450 MHz microwave irradiation. The levels of ATP in mouse brain following a 0·25 s exposure in a 6 kW microwave oven was found to be 2·416 ± 0·061. Whole brain levels of 8 labile intermediary metabolites in 0·4 s irradiated samples were comparable to those reported using the previously-described methods of freeze-blowing or whole-animal immersion. Analysis of these same metabolites in 4 gross areas of brain did not reveal any anoxic changes betwen superficial and deeper brain areas. The advantages of the mcrowave irradiation inactivation technique for regional brain studies of labile intermediary metabolites is discussed.     

REGIONAL CHANGES IN BRAIN CATECHOLAMINES AFTER PROTON IRRADIATION OF THE STRIATE CORTEX IN THE SQUIRREL MONKEY

To establish possible functional relationships between anatomically distinct cortical centres in primates, we compared changes in visual acuity, nucleic acids, protein, enzymes and catecholamines in cortical and subcortical areas six months after 10,000 and 20,000 rd of proton irradiation of striate area 17 of the visual cortex of the squirrel monkey. Minimum separable acuity was reduced from 1 minute of arc in controls to 4 minutes in the 20,000-rd group. DNA, RNA and protein contents were not altered, but the activity of acetylcholinesterase was increased significantly in area 17. A decrease of norepinephrine occurred in the hypothalamus, hippocampus, caudate nucleus, putamen and brain stem of the irradiated brains. Since no ultrastructural basis has been found to account for these changes, we assume that a sustained chemical change occurred at the irradiated site and that the effect was transmitted to non-irradiated regions of the brain.     

THE EFFECTS OF 4-HYDROXYBUTYRIC ACID ON THE BIOSYNTHESIS OF AMINO ACIDS IN THE CENTRAL NERVOUS SYSTEM

—The effect of 4-hydroxybutyrate (GHB) on cerebral glucose metabolism has been studied. GHB increases the glucose level, decreases the lactate concentration and diminishes the incorporation of glucose carbon into glutamic acid, glutamine, aspartic acid and GABA in the brain of the rat in a state of general anaesthesia. The data reported here suggest that GHB interferes in the metabolism of glucose in brain.     

THE INFLUENCE OF PORTOCAVAL ANASTOMOSIS ON THE METABOLISM OF LABELLED OCTANOATE, BUTYRATE AND LEUCINE IN RAT BRAIN

Rats were given a portocaval anastomosis and 3 weeks later, when the only ultrastructural change in the CNS is watery swelling of astrocytes, several aspects of brain metabolism were studied. The uptake of leucine by the brain, its incorporation into protein and its oxidation were followed after the simultaneous injection of a mixture of L-[1¹⁴C]leucine and L-[4,5-³H]leucine. The concentration of leucine in blood was lowered in the operated animals whereas in brain it was increased. The specific radioactivity of leucine in the brain was comparable to values in control animals and there was no evidence of a decrease in incorporation of [1-¹⁴C]leucine into brain proteins over the short experimental time period studied. The only difference from the controls in the oxidation of [4,5-³H]leucine was a greater accumulation in glutamine. The amount of glutamine in the brains of the operated animals had increased 4-fold at the time of the metabolic studies. From dual-labelled experiments in which a mixture containing [1-¹⁴C]butyrate and L-[4,5-³H]leucine was injected intravenously, it was shown that, in both control and operated animals, the pools of brain glutamate and glutamine labelled from butyrate were metabolically distinct from those labelled from leucine. The total radioactivity appearing in brain from [1-¹⁴C]butyrate was markedly reduced in operated animals, but the radioactivity from L-[4,5-³H]leucine was not. The metabolism of [1-¹⁴C]octanoate was compared with that of [1-¹⁴C]butyrate. In control animals the labelling of metabolites was almost identical with either precursor. In operated animals there was no reduction in the uptake of [1-¹⁴C]octanoate into the brain. There was evidence that the size of the glutamine pool labelled, relative to glutamate, was increased but that it had a slower fractional turnover coefficient. A link between astroglial changes and an impairment to the carrier mechanism for transport of short chain monocarboxylic acids across the blood-brain barrier is suggested.     

Column chromatographic separation of acidic and neutral and basic metabolites of tyrosine and dihydroxyphenylalanine

Liquid column chromatographic techniques for separation of tyrosine; dihydroxyphenylalanine; and acidic, neutral, and basic metabolites of tyrosine and catecholamines are described. These techniques permitted simultaneous separation of a wide spectrum of acidic and neutral metabolites of tyrosine and dihydroxyphenylalanine on one column. Rapid and complete separation of basic metabolites was carried out on a second column.     

THE EFFECT OF LIMB ISCHAEMIA ON THE TURNOVER OF NORADRENALINE IN THE HYPOTHALAMUS AND BRAIN STEM OF THE RAT

The effect of ischaemic limb injury on the turnover of noradrenaline in the hypothalamus and brain stem has been studied in rats. There are theoretical reasons for thinking that these regions are activated in trauma and previous work showed that during limb-ischaemia the concentration of noradrenaline in the hypothalamus decreased by 27 per cent. The tourniquets were applied to both hind-limbs 1 h after the injection of [¹⁴C]-tyrosine when the labelling of the noradrenaline was maximal. During 4 h limb ischaemia the endogenous tyrosine concentration in the plasma decreased while that in the hypothalamus first rose and then fell. Changes in a similar direction in the brain stem were not statistically significant. Limb ischaemia did not affect the decline in the specific activity of the plasma or tissue tyrosine. It was concluded that the injury increased the utilization of tyrosine by the body. During the 4 h bilateral hind-limb ischaemia the rate of decline of [¹⁴C]noradrenaline was significantly increased in the brain stem but not in the hypothalamus. Conditions in the brain stem were sufficiently close to ‘steady-state’ to be able to conclude that the injury increased the metabolism of noradrenaline in the brain stem. Conditions in the hypothalamus were too complicated for definite conclusions to be drawn. The possible reasons for this and the limitations of this method for studying noradrenaline turnover are discussed.