METABOLISM OF THE ASPARTYL MOIETY OF N-ACETYL-l-ASPARTIC ACID IN THE RAT BRAIN

The metabolism of N-acetyl-l -aspartic acid (NAA) was studied in rat brain. [Aspartyl-U-¹⁴C]NAA was metabolized predominantly by deacylation. Studies of NAA biosynthesis from l -[U-¹⁴C]aspartic acid have confirmed previous reports that NAA turns over slowly in rat brain. However, intracerebrally-injected N-acetyl-l -[U-¹⁴C]asparticacid was rapidly metabolized. Exogenous NAA appears to be taken up rapidly into a small, metabolically-active pool. This pool serves as substrate for a tricarboxylic acid cycle associated with the production of glutamate for the biosynthesis of glutamine. The bulk of the NAA content in brain appears to be relatively inactive metabolically.     

METABOLISM OF MALONIC ACID IN RAT BRAIN AFTER INTRACEREBRAL INJECTION

Labeled malonic acid ([1-¹⁴C] and [2-¹⁴C]) was injected into the left cerebral hemisphere of anesthetized adult rats in order to determine the metabolic fate of this dicarboxylic acid in central nervous tissue. The animals were allowed to survive for 2, 5, 10. 15 or 30min. Blood was sampled from the torcular during the experimental period and labeled metabolites were extracted from the brain after intracardiac perfusion. There was a very rapid efflux of unreacted malonate in the cerebral venous blood. Labeled CO₂ was recovered from the venous blood and the respired air after the injection of [1-¹⁴C]malonate but not after [2-¹⁴C]malonate. The tissue extracts prepared from the brain showed only minimal labeling of fatty acids and sterols. Much higher radioactivity was present in glutamate, glutamine, aspartate, and GABA. The relative specific activities (RSA) of glutamine never rose above 1.00. Aspartate was labeled very rapidly and revealed evidence of ¹⁴CO₂ fixation in addition to labeling through the Krebs cycle. GABA revealed higher RSA after [1-¹⁴C]malonate than after [2-¹⁴C]malonate. Sequential degradations of glutamate and aspartate proved that labeling of these amino acids occurred from [1-¹⁴C] acetyl-CoA and [2-¹⁴C] acetyl-CoA, respectively, via the Krebs cycle. Malonate activation and malonyl-CoA decarboxylation in vivo were similar to experiments with isolated mitochondria. However, labeled malonate was not incorporated into the amino acids of free mitochondria. The results were compared to data obtained after intracerebral injection of [1-¹⁴C]acetate and [2-¹⁴C]acetate.     

THE METABOLISM OF PALMITIC ACID IN THE PHOSPHOLIPIDS, NEUTRAL GLYCERIDES AND GALACTOLIPIDS OF MOUSE BRAIN

Abstract— Following intracerebral injection, [¹⁴C]palmitic acid was rapidly incorporated into a variety of brain lipids. After 12 hr, 78 per cent of the lipid radioactivity was in phospholipids, 15 per cent was in triacylglycerols, 1 per cent each was in free fatty acids and galactolipids, and the remainder was in other neutral glycerides. Over 65 per cent of the phospholipid radioactivity was found in the choline phosphoglycerides but this proportion decreased substantially with time. At later times, increasing portions of the radioactivity were present in the monounsaturated acyl groups and the alkenyl groups but no radioactivity was detected in cholesterol or polyunsaturated acyl groups. These results indicate that most of the extensive recycling of radioactivity took place without oxidative degradation of the palmitoyl groups. The relative rates of incorporation of radioactivity were compared at 12 hr after injection. The specific radioactivities of the serine, ethanolamine, and choline phosphoglycerides had ratios of 6:3:2 based on the palmitoyl group content and 1:2:4 based on their phosphorus content. The specific radioactivities of galactolipids with O -acyl groups were higher than the specific radioactivitiesof cerebrosides or cerebroside sulphates. A new solvent mixture for thin-layer chromatography of brain galactolipids was described (chloroform-acetone-methanol-water, 60:20:20:1, by vol.).     

THE MEASUREMENT OF TRIGLYCERIDE IN BRAIN AND THE METABOLISM OF BRAIN TRIGLYCERIDE IN VITRO

Abstract—

• 1 Triglyceride has been isolated from brain by thin-layer chromatography and determined by absorption of the carbonyl group at 1740 cm^?1. The means of yields from whole mouse brain, whole rat brain, rat brain grey matter, rat brain stem, and incubated slices of rat brain cortex were 0.15–0.17 μmole/g tissue.
• 2 The distribution of fatty esters varied from preparation to preparation. Palmitate, stearate and oleate usually occurred in greatest amounts. Hydrolysis of a preparation of triglyceride from whole rat brain with pancreatic lipase indicated that palmitate was equally distributed between the α and β esters.
• 3 [1-¹⁴C]Acetate was rapidly incorporated into triglyceride of slices of incubated rat brain cortex. When the resulting triglyceride was hydrolysed with pancreatic lipase the distribution of radioactivity amongst the hydrolysis products was consistent with both the α and β esters of the triglyceride having been radioactively labelled.

     

THYMIDINE METABOLISM AND DEOXYRIBONUCLEIC ACID SYNTHESIS IN THE DEVELOPING RAT BRAIN

—In growing rat brain, the specific activity of DNA at 12 h after the subcutaneous injection of [³H]thymidine underwent a sharp rise during the first 6 days of life, dropping just as precipitously by 15 days, thereafter continuing to decrease with increasing age. When [³H]thymidine was given to 6-day-old rats, a considerable amount was taken up immediately into the brain. Thymidine taken up into the acid-soluble fraction was readily phosphorylated to its nucleotides, thymidine mono-, di-, and triphosphate (TMP, TDP and TTP) within only 30 min following injection. The highest specific activity was found in TTP. The incorporation of of [3H]thymidine into DNA took place over a longer period of time after injection.     

METABOLISM OF THE PHOSPHOINOSITIDES IN GUINEA-PIG BRAIN SYNAPTOSOMES

Abstract— The subcellular distribution of a number of enzymes concerned with inositol lipid metabolism has been studied in sub-fractions of disrupted guinea-pig brain synaptosomes. The enzymes were CDP-diglyceride: inositol phosphatidate transferase, phospha-tidylinositol kinase, diphosphoinositide kinase, diphosphoinositide phosphomonoesterase and diphosphoinositide diesterase. The distribution of phosphatidylinositol kinase in sub-fractions from water-treated synaptosomes was compared with that of other plasma membrane enzymes. After partial solubilization of synaptosomes by Triton X-100 the activities of phosphatidylinositol kinase and several other enzymes were examined.
Distribution of phosphatidylinositol kinase closely resembled that of acetylcholinesterase in sub-fractions of synaptosomes. Both enzymes appeared to be localised in the outer membrane of the synaptosome. CDP-diglyceride: inositol phosphatidate transferase was present in all types of synaptosomal membrane. All three enzymes concerned with diphosphoinositide metabolism were found in the cytoplasm of the synaptosome.     

THE EFFECTS OF PHENYLALANINE ON AMINO ACID METABOLISM AND PROTEIN SYNTHESIS IN BRAIN CELLS IN VITRO1

Incubation of brain cell suspensions with 14 mM-phenylalanine resulted in rapid alterations of amino acid metabolism and protein synthesis. Both thc rate of uptake and the final intracellular concentration of several radioactively-labelled amino acids were decreased by high concentrations oi phenylalanine. By prelabelling cells with radioactive amino acids, phenylalanine was also shown to effect a rapid loss of the labelled amino acids from brain cells. Amino acid analysis after the incubation of the cells with phenylalanine indicated that several amino acids were decreased in their intracellular concentrations with effects similar to those measured with radioisotopic experiments (large neutral > small and large basic > small neutral > acidic amino acids). Although amino acid uptake and efflux were altered by the presence of 14 mwphenylalanine, little or no alteration was detected in the resulting specific activity of the intracellular amino acids. High levels of phenylalanine did not significantly altcr cellular catabolism of either alanine, lysine, leucine or isoleucine. As determined by the isolation of labcllcd aminoacyl-tRNA from cells incubated with and without phenylalanine, there was little or no alteration in the level of this precursor for radioactive alanine and lysine. There was, however, a detectable decrease in thc labelling of aminoacyl-tRNA for leucine and isoleucine. Only aftcr correcting for the changes of the specific activity of the precursors and thcir availability to translational events, could the effects of phenylalanine on protein synthesis be established. An inhibition of the incorporation into protein for each amino acid was approximately 20%.     

PASSAGE OF 5-HYDROXYTRYPTAMINE THROUGH THE BLOOD-BRAIN BARRIER, ITS METABOLISM IN THE BRAIN AND ELIMINATION OF 5-HYDROXYINDO-LEACETIC ACID FROM THE BRAIN TISSUE

Abstract— 5-HT was injected intravenously in rats (10 mg/kg) and a marked increase in brain 5-HT and 5-HIAA was observed. For the first 10 min after injection the penetration of 5-HT into the brain and formation of 5-HIAA is evident. After 10 min degradation of exogenous 5-HT and elimination of 5-HIAA are prominent. Metabolism of exogenous 5-HT in the brain is very fast (half-life between 5 and 10 min; completely metabolized in approximately 80 min). The importance of these results in explaining the permeability of blood-brain barrier to 5-HT is discussed. Experiments on brain slices show that 5-HT is more readily metabolized in brain tissue than eliminated into incubation medium. In contrast, 5-HIAA very easily leaves brain tissue.     

ALTERATION OF TRICARBOXYLIC ACID CYCLE METABOLISM IN RAT BRAIN SLICES BY HALOTHANE

Abstract—

• 1 Metabolism of [2-¹⁴C]pyruvate, [1-¹⁴C]acetate and [5-¹⁴C]citrate in the rat cerebral cortex slices was studied in the presence of halothane. Metabolites assayed include acetylcholine (ACh), citrate, glutamate, glutamine, γ-aminobutyrate (GABA) and aspartate. The trichloroacetic acid soluble extract, the trichloroacetic acid insoluble precipitate and its lipid extract were also studied.
• 2 In control experiments, pyruvate preferentially labelled ACh, citrate, glutamate, GABA and aspartate. Acetate labeled ACh, but to a lesser extent than pyruvate. Acetate also labeled lipids and glutamine. Citrate labeled lipids but not ACh and served as a preferential precursor for glutamine. These data support a three-compartment model for cerebral tricarboxylic acid cycle metabolism.
• 3 Halothane caused increases in GABA and aspartate contents and a decrease in ACh content. It has no effect on the contents of citrate, glutamate and glutamine.
• 4 Halothane preferentially inhibited the metabolic transfer of radioactivity from pyruvate into almost all metabolites, an effect probably not related to pyruvate permeability. This is interpreted as halothane depression of the‘large metabolic compartment’ which includes the nerve endings.
• 5 Halothane increased the metabolic transfer of radioactivity from acetate into lipids but did not alter such a transfer into the trichloracetic acid extract.
• 6 Halothane increased the metabolic transfer of radioactivity from citrate into the trichloroacetic acid precipitate, lipids and especially glutamine. Transfer of citrate radioactivity into GABA was somewhat decreased.
• 7 The differential effects of halothane on acetate and citrate utilization suggest that the ‘small metabolic compartment’ should be subdivided. Therefore, at least three metabolic compartments are demonstrated.
• 8 Halothane did not interfere with the dicarboxylic acid portion of the tricarboxylic acid cycle.

     

AMINO ACID METABOLISM AND AMMONIA FORMATION IN BRAIN SLICES

The formation of ammonia and changes in the contents of free amino acids have been investigated in slices of guinea pig cerebral cortex incubated under the following conditions: (1) aerobically in glucose-free saline; (2) aerobically in glucose-free saline containing 10 mM-bromofuroic acid, an inhibitor of glutamate dehydrogenase (EC 1.4.1.2); (3) aerobically in saline containing 11-1 mM-glucose and (4) anaerobically in glucose-free saline. Ammonia was formed at a steady rate aerobically in glucose-free medium. The formation of ammonia was largely suppressed in the absence of oxygen or in the presence of glucose whereas the inhibitor of glutamate dehydrogenase produced about 50 per cent inhibition. Other inhibitors of glutamate dehydrogenase exerted a similar effect. Ammonia formation was also inhibited by some inhibitors of aminotransferases but not by others. Inhibition was generally more pronounced during the second and third hour of incubation. With the exception of glutamine which decreased slightly, the contents of all amino acids increased markedly during the anaerobic incubation. During aerobic incubation in a glucose-free medium, there was an almost complete disappearance of glutamic acid and GABA. Glutamine also decreased, but to a relatively smaller extent. The content of all other amino acids increased during aerobic incubation in glucose-free medium, although to a lesser extent than under anaerobic conditions. The greater increase of amino acids appearing anaerobically in comparison to the increase or decrease occurring under aerobic conditions corresponded closely to the greater amount of ammonia formed aerobically over that formed anaerobically. This finding is interpreted as indicating a similar degree of proteolysis under anaerobic and aerobic conditions; aerobically, the amino acids are partly metabolized with the concomitant liberation of ammonia. In glucose-supplemented medium, the content of glutamine was markedly increased. The content of glutamate and aspartate remained unchanged, whereas that of some other amino acids increased but to a lesser extent than in the absence of glucose. Proteolysis in the presence of glucose was estimated at about 65 per cent of that in its absence. In the presence of bromofuroate the rate of disappearance of glutamate was unchanged, but there was a larger increase in the content of aspartate and a smaller decrease of GABA and glutamine. Other changes did not differ significantly from those observed in the absence of bromofuroate. We conclude that the metabolism of amino acids in general and of glutamic acid in particular differs according to whether they are already present within the brain slice or are added to the incubation medium. Only the endogenous amino acids appear to be able to serve as precursors of ammonia and as substrates for energy production.     

LYSINE METABOLISM IN THE RAT BRAIN: BLOOD—BRAIN BARRIER TRANSPORT, FORMATION OF PIPECOLIC ACID AND HUMAN HYPERPIPECOLATEMIA

Through the use of intravenous pulse injection of L-[U-¹⁴C] lysine, the blood-brain barrier transport of L-lysine was studied. The uptake of L-lysine plus metabolites in the brain remained essentially unchanged at approx 0.002–0.005 nmol/g in the low dose (3μg per kg body weight) injection, and 20–40 nmol/g in the high dose (30 mg/kg) injection throughout the time intervals of up to 60 min. The uptake of L-lysine plus metabolites in the heart, however, decreased substantially from 0.03 to 0.003 nmol/g in the low dose injection and from 320 to 62 nmol/g in the high dose injection. The plasma to heart uptake ratio only decreased slightly through the 60 min period: from 6 to 2 in either the low or high dose L-lysine injection. The plasma to brain uptake ratio, however, decreased rapidly from a high of 62 to a low of about 4 in either the low or high dose injection throughout the 60-min time course. Study of labeled L-pipecolate formation in the plasma and individual organs indicates that this compound was formed only in the brain to a significant level within 0.5 min of ¹⁴C-L-lysine intravenous pulse injection. Labeled pipecolate was recovered from heart, liver, kidney and plasma in significant quantities only at 2 min or later after pulse-injection. It is concluded that the blood-brain barrier of L-lysine in the rat is not particularly strong and that the rat brain may be primarily responsible for L-pipecolate synthesis from L-lysine. The possible etiology of human hyperpipecolatemia is also discussed in light of the current findings.     

OCCURRENCE OF N-ACETYL-l-GLUTAMIC ACID IN THE HUMAN BRAIN

A substance apparently identical with N-acetyl-l -glutamic acid was isolated from an aqueous extract from human brain by a combination of paper and ion exchange chromatography. The isolated substance does not react with ninhydrin reagent but yields glutamic acid upon acid hydrolysis. Acetyl hydrazide was identified by paper chromatography of hydrazinolysates of the isolated substance and N-acetyl-l -glutamic acid. The configuration was determined with l -specific hog kidney acylase.     

SOME EFFECTS OF MONOAMINE OXIDASE INHIBITORS ON THE METABOLISM OF γ-AMINOBUTYRIC ACID IN RAT BRAIN

(1) The inhibitor of γ-aminobutyrate transaminase (GABA-T), amino-oxyacetic acid (AOAA), drastically reduced the activity of GABA-T to 30 per cent of the control value, with a corresponding increase of brain GABA, but had no effect on the activity of glutamate decarboxylase (GAD). (2) The monoamine oxidase (MAO) inhibitors phenelzine, phenylpropylhydrazine and phenylvalerylhydrazine, lowered GABA-T activity to 58, 49 and 48 per cent, respectively; this was associated with a marked elevation of brain GABA. (3) The action of phenelzine and phenylpropylhydrazine in vivo and in vitro could be abolished by pre-treatment of the tissue with the structurally related MAO inhibitors phenylisopropylhydrazine and trans-2-phenylcyclopropylamine. These had no action on the GABA system in vivo, either on the GABA content or on the GABA-T activity. These latter drugs, however, were unable to influence the effects of AOAA either on GABA or on GABA-T. (4) The possible mechanism of action on GABA and the enzyme activities of the GABA system is discussed.     

CHANGES IN GLUTAMIC ACID AND GLUTAMINE METABOLISM IN THE RAT BRAIN AFTER WHOLE BODY X-IRRADIATION

After whole body irradiation with X-rays, an increase in the free ammonia concentration in the rat brain was observed. Parallel to this increase, evidence was found of a strong activation of glutaminase. Incubation increased the endogenous ammonia-forming capacity of brain homogenates to a much greater extent in irradiated rats than in normal rats. Glutamine synthetase activity decreased within the first 2 h after irradiation but remained unchanged at 24 and 96 h after irradiation. On the other hand, at 48 h after irradiation, glutamate dehydrogenase activity in the brain had fallen by 75 per cent in comparison with the initial activity. It is concluded that metabolic systems other than the glutamine-glutamic acid system contribute to the ammonia formation in the brain after irradiation.