Utilization in vivo of glucose and volatile fatty acids by sheep brain for the synthesis of acidic amino acids

1. Free glutamic acid, aspartic acid, glutamic acid from glutamine and, in some instances, the glutamic acid from glutathione and the aspartic acid from N-acetyl-aspartic acid were isolated from the brains of sheep and assayed for radioactivity after intravenous injection of [2-¹⁴C]glucose, [1-¹⁴C]acetate, [1-¹⁴C]butyrate or [2-¹⁴C]propionate. These brain components were also isolated and analysed from rats that had been given [2-¹⁴C]propionate. The results indicate that, as in rat brain, glucose is by far the best precursor of the free amino acids of sheep brain. 2. Degradation of the glutamate of brain yielded labelling patterns consistent with the proposal that the major route of pyruvate metabolism in brain is via acetyl-CoA, and that the short-chain fatty acids enter the brain without prior metabolism by other tissue and are metabolized in brain via the tricarboxylic acid cycle. 3. When labelled glucose was used as a precursor, glutamate always had a higher specific activity than glutamine; when labelled fatty acids were used, the reverse was true. These findings add support and complexity to the concept of the metabolic `compartmentation' of the free amino acids of brain. 4. The results from experiments with labelled propionate strongly suggest that brain metabolizes propionate via succinate and that this metabolic route may be a limited but important source of dicarboxylic acids in the brain.     

ISOLATION AND CHARACTERIZATION OF A SOLUBLE GLUCOSE-CONTAINING SIALOGLYCOPROTEIN FROM THE CORTICAL GREY MATTER OF CALF BRAIN

A sialoglycoprotein has been isolated from the cortical grey matter of calf brain after homogenization in 0.32 M-sucrose or in 0.15 M-NaCl. The sialoglycoprotein is present in the supernatant obtained after centrifugation at 100,000 g for 60 min. It is designated GP-350 on account of its elution with 350 mM-NaCl on a DEAE-cellulose column. From DEAE-cellulose chromatography it is evident that compounds comparable to GP-350 occur in the brain of calf and sheep, whereas they seem to be absent in calf liver and kidney. After purification, with polyacrylamide gel electrophoresis only one band can be shown both at pH 8.9 and 7.5. GP-350 consists of about 83 percent of protein and about 17 per cent of carbohydrate. The polypeptide core has an acidic character: amino acid analysis gives 26 per cent for glutamic acid plus aspartic acid and their amides, with a ratio of acidic to basic amino acids of 3.3. The carbohydrate moiety contains 2.4% sialic acid, 5.5 % hexosamine and 9.4% hexose. It is remarkable that this brain sialoglycoprotein comprises 4% glucose. Care was taken to prevent contamination with glucose-containing materials during the purification procedure of GP-350. The complete absence of other glucose-containing compounds which occur in brain, Le. glycogen and gangliosides, was demonstrated. GP-350 accounts for at least 3 per cent of the total saline-extractable protein and about 20 per cent of the total saline-extractable protein-bound sialic acid of the cortical grey matter of calf brain. These percentages correspond to 390 pg of protein and to 14 μg of sialic acid per g wet weight. GP-350 remains soluble when the pH is brought to 3.9 or when ethanol is added to 70 % (v/v).     

Regional distribution of homocarnosine and other ninhydrin-positive substances in brains of malnourished monkeys

—Eight male monkeys (Macaca nemestrina) aged 6–9 months were divided into two groups and fed either an adequate protein diet (20% casein) or a protein deficient diet (2% casein). After 3- 5 months of receiving the low protein diet, the malnourished monkeys showed extensive fatty metamorphosis of the liver cells, distorted patterns of plasma and hepatic free amino acid pools, and other features consistent with the diagnosis of protein-calorie malnutrition. Examination of the cerebrum, cerebellum and brain stem in the malnourished animals revealed profound accumulation of 3-methylhistidine, histidine and homocarnosine in all three regions. For histidine, the cerebral, cerebellar and brain stem levels in the protein deficient animals increased by 145, 104 and 101 per cent over levels observed in corresponding regions of the brain in well-fed monkeys. Similarly, there were significant elevations in homocarnosine contents of the cerebrum (+ 99 per cent), cerebellum (+ 140 per cent) and brain stem (+ 146 per cent) in comparison to levels in control animals. In contrast, the levels of valine, serine and aspartic acid were markedly reduced in all three brain areas in the malnourished animals. Protein-calorie deficiency also produced reductions in the brain levels of taurine, glutamic acid, isoleucine, leucine and threonine which varied in magnitude in the three major regions of the brain examined. These biochemical alterations which may in part underlie some of the psychomotor changes often observed in protein-calorie malnutrition, were discussed not only in relation to the role of amino acids as precursors for the synthesis of neuroregulatory substances but also with due regard to the possibility that some of these ninhydrin-positive substances such as GABA, homocarnosine, glycine and the dicarboxylic amino acids may possess neuroexcitatory or inhibitory properties in various parts of the central nervous system.     

Effect of coordinated addition of specific amino acids on the synthesis of recombinant glucose isomerase

The amplified expression of a recombinant protein is known to lead to an intracellular depletion of specific amino acid pools which in turn may affect the production of the desired protein. In order to counteract and overcome such a situation during the fermentation of the recombinant Escherichia coli (PMSG27) containing the glucose isomerase (GI) gene from Streptomyces sp. NCIM 2730, the effect of addition of different amino acids on the specific activity of GI was studied. The amino acid composition of GI from Streptomyces sp. NCIM 2730 reveals predominantly aspartic acid, glutamic acid, and glycine; therefore, in the present paper, the effect of coordinated addition of the assorted combinations of these three amino acids on the synthesis of recombinant GI was studied. The results were analyzed using a 2³ factorial design. The following conclusions were derived from the analysis of two-factor interactions of the three amino acids: (i) The interaction between the aspartic and glutamic acid is independent of aspartic acid concentration but is affected by the increasing concentrations of glutamic acid, (ii) The effect of aspartic acid concentration is more than that of glycine, and (iii) During the interaction of glutamic acid and glycine, the effect of glutamic acid is more prominent than that of glycine. The three-factor interaction analyses reveal that the effect of the three amino acids is in the order aspartic acid > glutamic acid > glycine.     

Free alanine,aspartic acid,or glutamic acid reduce the glycation of human lens proteins

The amino acids lysine and glycine are reported to react with glucose at physiological pH and temperature and undergo non-enzymic glycation. Three other amino acids present in relatively larger amounts in the lens i.e. alanine, aspartic acid and glutamic acid were also found to undergo non-enzymic glycation as found by incorporation of uniformly labelled (U-[¹⁴C]) glucose into the amino acids. The glucose incorporation was 1.6 to 2.5% for alanine, 35 to 50% for aspartic acid and 2.3 to 3.3% for glutamic acid. Each amino acid of varying concentrations lowered the extent ofin vitro glycation of lens proteins significantly in glucose-treated homogenates of normal lens from humans. The decrease in glycation for alanine was between 32 and 69%, that for aspartate was between 18 and 74%, and for glutamate was between 52 to 74%. Decreased glycation was greater for higher concentrations of glucose. Scavenging of intracellular glucose and decreasing the extent of glycation of lens proteins could be the mechanism of action by which the amino acids alanine, aspartic acid and glutamic acid could exercise a beneficial effect on cataract and diabetic retinopathy.     

DISTRIBUTION OF AMINO ACIDS AND OF EXO- AND ENDOPEPTIDASES ALONG VERTEBRATE AND INVERTEBRATE NERVES

Abstract— The proximo-distal gradients for representative peptidases, peptidylpeptide hydrolases, and amino acids were measured in segments of peripheral nerve from invertebrates and vertebrates and in the lobster brain and ventral cord.
Crustacean nerve was characterized by a large pool of free amino acids totaling 100–200 μmoles/g wet wt. In lobster nerve, the principal free amino acid was aspartic acid which comprised 55 per cent of the free pool, whereas in the rat sciatic nerve it comprised only 5 per cent. The principal free amino acid in rat sciatic nerve was taurine (32 per cent of the pool) and in lobster brain glycine comprised 30 per cent of the pool. No consistent patterns emerged for the gradients along the nerves for amino acids and hydrolytic enzymes. In the leg nerve of the lobster, concentrations of aspartic acid and arginine were higher in the proximal region, and concentrations of proline and alanine were higher in the distal region. Concentrations of most amino acids were higher in the proximal regions of crab nerve, of lobster brain and ventral cord, and of rat sciatic nerve.
Rat sciatic nerve exhibited a pronounced proximo-distal increase in activity of aminopeptidase (Leu-Gly-Gly). In lobster leg nerve, activity of neutral proteinase was higher in the proximal segment, whereas activity of acid proteinase was higher in the distal segment. The best examples of proximo-distal gradients were found in lobster brain and ventral cord; activities of endopeptidases, arylamidases (Leu- and Arg-βNA), and aminopeptidase were higher in the supra-esophageal ganglia or cephalothorax segments than in the distal regions.     

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.     

End products of glucose and glutamine metabolism by L929 cells

Products of glucose and glutamine metabolism by L929 cells were detected and quantitated by gas chromatography and mass spectrometry of the oxime-trimethylsilyl derivatives. This method allowed detection and identification of all major carboxylic and amino acids produced in the system. Although lactic acid was expected to be the major product, alanine, citric, glutamic, aspartic, and pyruvic acids were also released into the culture medium at significant rates. Incorporation of labeled carbon from D-[U-13C]glucose showed that the alanine, lactic, and pyruvic acids were derived from glucose as was one-third of the citric acid carbon. The rate of glucose utilization for production of these end products was 29-fold greater than the rate of glucose oxidation to CO2, and calculated ATP production from alanine and pyruvate synthesis exceeded that from lactate synthesis by nearly 2-fold. Utilization of glutamine for synthesis of aspartic, glutamic, and citric acids also exceeded the rate of glutamine oxidation, thereby making end-product synthesis from glucose and glutamine the dominant cellular metabolic activity. In the absence of glucose, synthesis and intracellular levels of aspartic and glutamic acids increased, whereas synthesis and cell content of the other acids decreased markedly. This response is consistent with the metabolic pattern proposed by Moreadith and Lehninger (Moreadith, R.W., and Lehninger, A.L. (1984) J. Biol. Chem. 259, 6215-6221) in which much of the glutamine used by these cells is converted to aspartate in the absence of a pyruvate source and to aspartate or citrate in the presence of pyruvate.     

METABOLISM OF GLUTAMIC ACID AND RELATED AMINO ACIDS IN THE BRAIN STUDIED WITH 14C-LABELLED GLUCOSE, BUTYRIC ACID AND GLUTAMIC ACID IN HYPERCAPNIC RATS

Abstract— The influence of hypercapnia on the metabolism of glutamic acid, aspartic acid, glutamine and GABA in rat brain was studied using three different precursors. Acute hypercapnia induced a fall in the concentration of glutamic and aspartic acid, and a rise in the concentration of glutamine and GABA. Acute hypercapnia had a profound effect on the relative specific radioactivity of glutamine indicating that the excess glutamine, present in the brain in hypercapnia, was synthetized from glutamic acid in the compartment where it could become quickly labelled from butyric and glutamic acid, but not from glucose. This effect was maintained in chronic hypercapnia.     

Characterization of a glycoprotein in the cyst fluid of Cysticercus tenuicollis from the goat

Dixon S. N., Gibbons R., Parker Janice and Sellwood R. 1973. Characterization of a glycoprotein in the cyst fluid of Cysticercus tenuicollis from the goat. International Journal for Parasitology3:419–424. In the fluids of two tapeworm cysts from goats a prominent periodic acid- Schiff reagent staining protein was found on gel electrophoretograms. In one case serum proteins from the host were also observed. The glycoprotein has been isolated and found to contain about 7·7 per cent heterosaccharide consisting of glucose, galactose, mannose, fucose, neuraminic acid, glucosamine and an unidentified component. The amino acid portion is extremely rich in glutamic acid, aspartic acid, lysine and arginine. Its molecular weight is approximately 90,000. A small degree of heterogeneity was demonstrated by ultra-centrifugal analysis; this may be due to the presence of about 3 per cent of a glycosaminoglycan. In view of the high proportion of charged amino acids it is suggested that this glycoprotein, which appears to be derived from the parasite, functions as the osmotically active macromolecule in the cyst fluid maintaining the turgidity of the cyst.     

Amino Acid Transport into Cultured Tobacco Cells: I. LYSINE TRANSPORT

Lysine transport into suspension-cultured Wisconsin-38 tobacco cells was observed. Uptake was linear (up to 90 minutes) with respect to time and amount of tissue only after 4 to 6 hours preincubation in calcium-containing medium. The observed cellular accumulation of lysine was against a concentration gradient and not due to exchange diffusion. Transport was stimulated by low pH and characterized by a biphasic uptake isotherm with two K(m) values for lysine. System I (K(m) approximately 5 x 10(-6) molar; V(max) approximately 180 nanomoles per gram fresh weight per hour) and system II (K(m) approximately 10(-4) molar; V(max) approximately 1900 nanomoles per gram fresh weight per hour) were inhibited by N-ethylmaleimide and a variety of respiratory inhibitors. This inhibition was not due to increased efflux. In antagonism experiments, system I was inhibited most effectively by basic amino acids, followed by the sulfur amino acids. System I was only slightly inhibited by the neutral and aromatic amino acids and was not inhibited by the acidic amino acids aspartic and glutamic acids. Transport by system II was inhibited by all of the tested amino acids (including aspartic and glutamic acids) and analogs; however, this system was not inhibited by d-arginine. Neither system was strongly inhibited by d-lysine or the lysine analog S-2-aminoethyl-l-cysteine. Arginine was shown to be a competitive inhibitor of both systems with values for K(i) similar to the respective K(m) values.These studies suggest the presence of at least two amino acid permeases in W-38 tobacco cells.     

Carbon Translocation in the Tomato: Carbon Import and Fruit Growth

The rates of carbon import by fruits were measured over 48 has the sum of the change in the total organic carbon contentof the fruit and the respiratory loss of carbon. Over a rangeof fruit sizes from 20–90 per cent of the maximum volumethe smaller fruits imported carbon at an absolute rate (mgCfruit^–1 h^–1) nearly twice that of the larger fruits.The imported leaf assimilates, identified as the ¹⁴C-compoundsalong the pathway between a ¹⁴CO₂-fed leaf and a young fruit,comprised 90 per cent sucrose and 10 per cent glutamic acid,aspartic acid and malic acid. Within the fruit the imported¹⁴C-sucrose was hydrolysed into hexoses. The changes in thelevels of starch and insoluble residue in the fruit were positivelycorrelated with the carbon import rates. In the largest fruitswith the lowest import rates, there was breakdown of insolubleresidue and less accumulation of starch, but a significant increasein the level of sucrose. The sink strength of a tomato fruitis dependent more on sink activity than on sink size.     

Effect of vitamins and various amino acids on glucose isomerase biosynthesis by Streptomyces albogriseolus culture

The effect of vitamins (B1, B2, B3, B6, B12, H, PP and folic acid) and amino acids (glutamic and aspartic acids) on glucose isomerase biosynthesis was studied in Streptomyces albogriseolus. These compounds were added either alone or in combinations to different growth media (synthetic and complex). The results were processed using mathematical methods, and the following mixture of vitamins and amino acids was proposed to be added to the complex fermentation medium: B2, 10 micrograms/L; B6, 10 micrograms/L; H, 1 microgram/L; aspartic acid, 0.01 microM. The production of glucose isomerase rose more than 1.5 times after such additions.     

Accumulation of histidine, 3-methylhistidine, and homocarnosine in the brains of protein-calorie deficient monkeys

Abstract— Seventeen monkeys (M. nemestrina and M. fascicularis) aged 10 months to about 5 yr were divided into two groups and fed either an adequate protein diet (20% casein) or a low-protein diet (2% casein). The diets were supplied to the animals in restricted amount (200 g/animal in two daily rations). In one experiment, the malnourished animals were initially fed a diet containiing 8 per cent protein and the protein content of the diet was gradually reduced over a period of 9 months, to 2 per cent. After about 3 months on the 2 per cent protein diet, the malnourished monkeys showed growth failure, severe anorexia, peri-ocular oedema, tremors of the head and limbs, atrophy of several visceral organs, fatty liver, hypoalbuminaemia, and depressed serum levels of many essential amino acids with an elevation of the ratio of non-essential to essential amino acids. These features are consistent with protein-calorie malnutrition. Examination of the brains revealed significant alterations in the levels of glycerophosphoethanolamine (—40 per cent), glutamic acid (—25 per cent), histidine (+230 per cent), homocamosine (+185 per cent), 3-methyl-histidine (+147 per cent), lysine (+55 per cent), phenylalanine (+33 per cent) and tyrosine (+26 per cent) in comparison to findings on the well-fed monkeys. The possible implications of elevated cerebral contents of homocarnosine in malnourished monkeys are discussed in the light of several reported human cases in whom neurological disorders are associated with increased histidine-containing dipeptides in the brain, CSF, blood and urine.     

METABOLIC COMPARTMENTATION IN THE BRAIN: EFFECTS OF A CENTRAL NERVOUS SYSTEM DEPRESSANT, 1-HYDROXY-3-AMINO-PYRROLIDONE-2

—The effect of 1-hydroxy-3-aminopyrrolidone-2(HA-966), a CNS depressant, was studied on the metabolism of [¹⁴C]glucose and [³H]acetate in the brain in mice. HA-966 had a marked effect on glucose metabolism. The conversion of glucose carbon into amino acids associated with the tricarboxylic acid cycle (‘cycle’) was severely reduced, while the concentration of brain glucose was approximately doubled. Relative to the specific radioactivity of glucose in the brain, the specific radioactivity of alanine was 60–70 per cent of the control, indicating a reduction in the rate of glycolysis, and those of the‘cycle’amino acids were also lowered. A reduction in‘cycle’flux of 30–35 per cent was estimated. It was established that the depressed glucose utilization flux was not due to either impaired uptake of glucose from blood to brain or to hypothermia. In contrast to [¹⁴C]glucose, there was no change in the labelling of the amino acid fraction from [³H]acetate, which is preferentially metabolized in the 'small’compartment believed to be associated with glia. Thus it seems that CNS depression caused by HA-966 resulted in a selective decrease in energy production in the‘large’metabolic compartment where glucose is oxidized preferentially and which is believed to be associated with neuronal structures. The results also suggested that communication between the metabolic compartments mediated via glutamine and GABA was reduced, since the labelling from [³H]acetate of glutamine was increased and that of GABA decreased by HA-966.     

FREE AMINO ACIDS AND RELATED COMPOUNDS IN BIOPSIES OF HUMAN BRAIN

Abstract— Contents (μmol/g wet wt.) of 35 free amino acids and related compounds were measured in biopsies of human brain from ten patients. Brain specimens were frozen in liquid nitrogen within 10 sec of their removal at neurosurgery; thus, the values found should approximate those which occur in living brain.
Levels in free pools of biopsied cerebral cortex of most of the amino acids that are constituents of proteins were only 20-50 per cent of those found in autopsied cortex. The content of cystine and ethanolamine was much lower in biopsied than in autopsied cortex. Concentrations of GABA in biopsied cortex were only 20 per cent as high as those found in autopsied cortex, and levels of γ-aminobutyryl dipeptides were also significantly lower in biopsied cortex. Amounts of cystathionine in biopsied cortex varied markedly, but averaged much higher than in autopsied cortex; a single biopsy specimen of cerebellar grey matter had a cystathionine content 36-fold greater than the mean found in autopsied cerebellum.
Appreciable variability in contents among cortical biopsies was found for glycerophosphoethanolamine, phosphoethanolamine, ethanolamine, taurine, aspartic acid, glutamic acid, glutamine, and GABA, as well as for cystathionine. Whether this variability occurred between different subjects, or between different cortical areas, was not clear, although the former possibility was suggested by findings in multiple cortical biopsies from one patient.     

The effect of sugar,amino acid,metal ion,and NaCl on model Maillard reaction under pH control

Summary. The color intensities was determined of Maillard reaction products (MRPs) prepared by heating each of five sugars (maltose, fructose, glucose, arabinose, and xylose) with each of 12 amino acids (aspartic acid, glutamic acid, alanine, leucine, isoleucine, valine, proline, serine, cysteine, phenylalanine, arginine, and lysine). The remaining percentages of glucose and rate of change of color intensity due to the addition of a metal ion and NaCl were monitored for nine MRPs that had been formed between glucose and each of nine amino acids (aspartic acid, glutamic acid, alanine, valine, serine, cysteine, phenylalanine, arginine, and lysine). Model MRPs were prepared in a block heater at 100°C for 1–12h with the pH value controlled at 6.5. The resulting color intensity of each MRPs formed from the basic amino acids was greater due to the higher reactivity than those from the acidic amino acids. The remaining percentage of glucose in each MRPs from the basic amino acids was lower than those from the acidic amino acids. The MRPs from the nonpolar amino acids showed an intermediate color intensity and remaining percentages of glucose between those formed from the basic and acidic amino acids. Browning tended to be accelerated in the presence of metal ions, especially Fe²⁺ and Cu²⁺, although it was affected by the property of the amino acid and heating time as well as by the type of metal ion. On the other hand, browning was greatly inhibited by a high concentration of NaCl.     

Effect of nicotine on the level of extracellular amino acids in the hippocampus of rat

Using microdialysis, we compared intracerebral and subcutaneous administration of nicotine for the effect on the levels of extracellular amino acids in the hippocampus of anesthetized rats. Administration by microdialysis of 10 mM nicotine, resulting in a nicotine concentration of 0.134 μmol/g in the hippocampus, increased the extracellular levels of aspartic acid, glutamic acid, and serine by 26–60%. At 50 mM nicotine the increases in the levels of aspartic acid, glutamic acid, serine, glycine, and glutamine were between 76% and 141%. Subcutaneous administration of nicotine at a dose of 6 μmol/kg caused a 57% increase in the extracellular level of glutamic acid. After a dose of 12 μmol/kg that resulted in a nicotine level of 0.015 μmol/kg in the hippocampus, the extracellular level of glutamic acid was increased by 100%, and that of aspartic acid by 24%. Thus, higher cerebral nicotine levels were needed with intracerebral than with subcutaneous administration to obtain similar amino acid changes. Prior administration of mecamylamine or L-kynurenine prevented the subcutaneous nicotine-induced elevation of the extracellular levels of aspartic acid and glutamic acid. Our results indicate that receptor interactions modulate nicotine effects and that both nicotinic cholinergic and NMDA/glycine glutamatergic receptors participate in the action of nicotine in increasing extracellular amino acid levels.     

The role of amino acid catabolism in the formation of the tricarboxylic acid cycle intermediates and ammonia in anoxic rat heart

Amino acid catabolism, the tricarboxylic acid cycle intermediates and ammonia formation were studied in isolated perfused rat heart under anoxia. The total net anaplerosis due to amino acid degradation in anoxia was equal to that in oxygenation (6.29 and 6.09 mumol/g dry weight per h, respectively) as a result of the increased transamination of glutamic and aspartic acids. During anoxic perfusion, the rate of catabolism of glutamic and aspartic acids was 1.5-times higher than in normoxia, while depletion of branched-chain amino acids, lysine, proline, arginine and methionine, was inhibited. Alanine was the product of excessive degradation of glutamic and aspartic acids. Under anaerobic conditions, in spite of inhibition of amino acid deamination, ammonia formation was increased 2.7-fold as compared to oxygenation. The principal amount of ammonia (96%) was produced at degradation of adenine nucleotides. A 2.5-fold increase in the pool of the tricarboxylic acid cycle intermediates under anoxia was associated mainly with accumulation of succinate. The data suggest that the coupling of alanine- and aspartate amino transferases is a mechanism controlling the tricarboxylic acid cycle pool size in anoxic heart.     

Elevation of cerebral levels of nonessential amino acids in vivo by administration of large doses

Taurine, aspartic acid, glutamic acid, glycine, and GABA were administered either intragastrically or in liquid diets to mice and rats. This resulted in a great increase in the plasma concentration of the administered amino acid, with plasma levels remaining elevated for several days.The prolonged increase in plasma levels resulted in significant increases in brain levels. Under these experimental conditions, taurine, aspartic acid, and glutamic acid were increased 30–60%; glycine and GABA 100%. During these experiments, plasma levels of taurine, aspartate, and glutamate were below brain levels; those of glycine and GABA were above.The findings show that even slowly penetrating amino acid levels can be increased in brain after parenteral administration of large doses.