Transport of gamma-glutamyl amino acids: role of glutathione and gamma-glutamyl transpeptidase.

This work relates to the hypothesis that one of the mechanisms that mediates amino acid translocation across cell membranes involves the action of membrane-bound gamma-glutamyl transpeptidase on intracellular glutathione and extracellular amino acids to form gamma-glutamyl amino acids. According to this idea, the latter are translocated into the cell where the gamma-glutamyl moiety is removed to yield free amino acids. Previous studies in this laboratory showed that intracellular glutathione is translocated out of many cells. We have now directly examined the transport of gamma-glutamyl amino acids into tissues in the mouse by use of the model substrate L-gamma-glutamyl-L-[14C]methionine sulfone. Of 11 tissues examined, only the kidney showed strong and preferential uptake of the substrate. A substantial amount of the administered L-gamma-glutamyl-L-[14C]methionine sulfone was found intact in the kidney; the total uptake of this compound was greater (by about 2-fold) than that of free L-methionine sulfone. Studies with a number of other gamma-glutamyl amino acids and gamma-glutamyl compounds indicate that the kidney has a relatively specific transport system for gamma-glutamyl amino acids. Small but significant amounts of gamma-glutamylmethionine sulfone were found in the liver and pancreas, suggesting that other tissues may also have this system. Transport of gamma-glutamylmethionine sulfone into the kidney was inhibited by inhibitors of glutathione synthesis and of gamma-glutamyl transpeptidase. The results suggest that both the transpeptidase and glutathione may be involved in transport of gamma-glutamyl amino acids.     

Amino acids and control of nucleolar size, the activity of RNA polymerase I, and DNA synthesis in liver.

The volume of nucleolar material per nucleus and the activity of RNA polymerase I (RNA nucleotidyltransferase I) become doubled in the liver cells of rats that are fed for several days a diet that lacks essential amino acids. Omission of methionine from a fully supplemented diet is equivalent to leaving out all the amino acids, and the responses to a deficiency of tryptophan are about 40% as great. Deprivation of one of the remaining essential amino acids gives either small responses or none at all. Supplementation of the methionine-free diet with cystine blocks the nucleolar enlargement and the enhancement of the polymerase activity that would otherwise take place, but the dispensable amino acid does not affect the responses to a deprivation of one of the other essential amino acids. After deprivation of all the essential amino acids or only methionine, hepatocytes make DNA when the rat is fed a meal with protein. A preparatory diet lacking in tryptophan is much less effective; a deficiency in any of the other indispensable compounds tested fails to prepare the liver for DNA synthesis. The results give hope that elucidation of the means by which methionine deprivation affects the nucleolus will also provide information on the regulation of nuclear DNA replication in liver. One attractive possibility is that the amino acid deficiency acts by producing some imbalance in protein metabolism.     

Serum amino acids in hepatic encephalopathy--effects of branched chain amino acid infusion on serum aminogram

Encephalopathic patients with cirrhosis of the liver consistently showed elevated levels of the aromatic amino acids, phenylalanine, tyrosine and free tryptophan as well as methionine in serum, whereas levels of the branched chain amino acids, valine, leucine and isoleucine, were depressed. Comatose patients with fulminant hepatitis had markedly elevated levels of all amino acids, the results being greatly different from those of cirrhotic patients. Molar ratios of (valine + leucine + isoleucine)/(phenylalanine + tyrosine) decreased both in cirrhotics with and without encephalopathy and in cases with fulminant hepatitis. Infusion of a commercially available L-amino acid solution in a cirrhotic patient induced a strikingly abnormal aminogram documented in hepatic encephalopathy. Therefore, effects of branched chain amino acid infusion on the deranged amino acid pattern were primarily studied for the purpose of improvement in hepatic encephalopathy by normalization of serum amino acid patterns. Elevated levels of the aromatic amino acids and methionine could be apparently depressed in a cirrhotic patient by this type of infusion but not in a case of fulminant hepatitis probably because of the poor utilization of these amino acids in severely impaired liver.     

Evidence of Inter-organ Amino-Acid Transport by Blood Cells in Humans

To evaluate the contribution of blood cellular elements to inter-organ transport of amino acids, net exchange across the leg and splanchnic bed of 17 amino acids was determined in seven healthy postabsorptive subjects by use of both whole blood and plasma for analysis. Arterial-portal venous differences were measured in five additional subjects undergoing elective cholecystectomy. By use of whole blood, significant net release of amino acids was noted from the leg and gut, while a consistent uptake was observed by the splanchnic bed. The output of alanine from the leg and gut and the uptake of this amino acid by the splanchnic bed exceeded that of all other amino acids and accounted for 35-40% of total amino-acid exchange. Transport by way of plasma could not account for total tissue release or uptake of alanine, threonine, serine, glutamine, methionine, leucine, isoleucine, tyrosine, and citrulline. For each of these amino acids, significant tissue exchange was calculated to occur by way of the blood cellular elements, the direction of which generally paralleled the net shifts occurring in plasma. For alanine, 30% of its output from the leg and gut and 22% of its uptake by the splanchnic area occurred by way of blood cells. We conclude that the blood cellular elements, presumably erythrocytes, contribute substantially to the net flux of amino acids from muscle and gut to liver in normal postabsorptive humans. Alanine predominates in the inter-organ transfer of amino acids occurring by way of blood cells as well as plasma.     

Amino acid uptake in arterio-venous serum of normal and cancerous colon tissues

AIM: To investigate the difference of amino acid uptake between normal and cancerous colon tissues. METHODS: Sixteen patients with colon cancer were enrolled in our study. Blood samples were taken during operations, serum amino acid concentrations of blood from cancerous or normal colon were analyzed. Amino acid uptake rate was calculated by the A-V difference and evaluated statistically. RESULTS: Except for methionine, the uptake rate of amino acids in cancer was higher than that in normal colon (25.01% vs -2.29%, P<0.01). The amino acid uptake rate did not correlate to the size of tumor mass (P>0.05). There was no statistical significance in the amino acid uptake rate according to the Dukes stage, though it was higher in patients with Dukes stage C or D than that with Dukes stage B (P>0.05). CONCLUSION: Abnormal synthetic metabolism of colon cancer may contribute to its higher amino acid uptake rate than that of normal colon.     

Uptake of aspartic and glutamic acid by photoreceptors in goldfish retina.

The uptake of acidic amino acids by goldfish photoreceptors was investigated by light microscope autoradiography. Isolated retinas were incubated in media containing micromolar amounts of L-[3H]aspartate, L-[3H]glutamate, and D-[3H]aspartate. We have four major observations. (i) Rods accumulate L-[3H]glutamate with a high-affinity transport system; they exhibit a glutamate-to-aspartate selectivity ratio of 30:1. When incubated in 1-10 microM L-[3H]glutamate, rods label more densely than cones. A unit area of rod membrane transports glutamate 30 times better than a unit area of cone membrane. (ii) Red-sensitive and green-sensitive cones show accumulation of L-[3H]aspartate, D-[3H]aspartate, and L-[3H]glutamate, apparently with high affinity, but with little selectivity. Because rods have poor aspartate uptake, red-sensitive and green-sensitive cones may be preferentially labeled with L-[3H]aspartate or D-[3H]aspartate, (iii) Blue-sensitive cones show no uptake of L-[3H]aspartate, D-[3H]aspartate, or L-[3H]glutamate other than that attributable to low-affinity transport. (iv) Various cell types in the goldfish retina can clearly discriminate between glutamate and aspartate, unlike acidic amino acid transport systems described in mammalian brain.     

Effect of topical application of amino acids on gastric pepsin secretion in the rat. Part III: effect of L- and D-isomers of amino acids on gastric secretion in reperfusion system

This study was undertaken to compare the potency of each L- and D-isomers of 5 amino acids in stimulating gastric acid and pepsin secretion by the intragastric reperfusion preparation in rats. Gastric basal and glycine-stimulated secretions in this preparation were lower than those Ghosh-Lai preparation, but not to a statistically significant extent. All D- and L-isomers of amino acids tested were found to markedly stimulate pepsin secretion, but to only slightly stimulate acid secretion. Pepsin stimulatory response to each D and L-isomer of amino acid was similar. The stimulatory effects of amino acids thus seem to be unrelated to the optical stereoisomeric configuration.     

Inhibition by colchicine of changes in amino acid transport and initiation of DNA synthesis in regenerating rat liver.

The uptake of amino acids (measured with alpha-aminoisobutyric acid) by hepatocytes stimulated to proliferate by partial hepatectomy followed a biphasic pattern, with an initial peak 8-10 hr after surgery followed by a release of amino acids between 10 and 16 hr and a further increase between 16 and 20 hr after the operation. The second period of increased uptake coincided with the increase in DNA synthesis by the hepatocytes. Colchicine, and other microtubule disrupters administered at the time of partial hepatectomy, abolished the first period of increased amino acid uptake and prevented the cells from initiating DNA synthesis. Pulse-labeling experiments with alpha-aminoisobutyric acid revealed that colchicine did not inhibit amino acid transport per se, but prevented the increased capacity for amino acid transport induced by partial hepatectomy. An injection of colchicine 14 hr after hepatectomy prevented the release of amino acids by the liver and also substantially reduced the initiation of DNA synthesis. The data suggest that the microtubules may play a role in proliferative activation and also in the initiation of DNA synthesis of hepatocytes in vivo and that changes in amino acid transport are linked to these microtubule-requiring processes.     

Characterization of a common precursor to corticotropin and beta-lipotropin: identification of beta-lipotropin peptides and their arrangement relative to corticotropin in the precursor synthesized in a cell-free system.

Radioactive proteins synthesized in an mRNA-dependent reticulocyte cell-free system under the direction of mRNA from AtT-20/D-16v mouse cells were isolated by specific immunoprecipitation using antiserum to either alpha(1-24) corticotropin or beta-endorphin [beta(61-91) lipotropin]. Each immunoprecipitate was fractionated by sodium dodecyl sulfate/polyacrylamide gel electrophoresis and shown to contain only one labeled protein with an apparent molecular weight of 28,500. Tryptic peptide analysis of the Mr 28,500 corticotropin and beta-lipotropin molecules isolated from the gels demonstrated that the two proteins had the same lysine, methionine, and tryptophan peptides. Four tryptic peptides from the cell-free product exhibited the same electrophoretic and chromatographic mobilities as marker tryptic peptides from bovine beta-melanotropin and porcine beta-endorphin. The identification of these peptides was confirmed by amino acid composition studies with a variety of labeled amino acids. The beta-lipotropin tryptic peptides were also shown to be located carboxy terminal to the corticotropin tryptic peptides.     

Methionine-sensitive glycolysis in transformed cells.

Glycolysis in several tumor cell lines grown in tissue culture was inhibited by methionine. Kirsten murine sarcoma virus-transformed rat kidney cells (K-NRK) were inhibited 60-75% by 10 mM methionine, whereas normal rat kidney (NRK-49F) cells showed little or no inhibition. Inhibition of glycolysis in K-NRK cells was manifest 2-4 hr after exposure to the amino acid. Glycolysis in a chemically transformed cell line of Madin-Darby canine kidney cells was also sensitive to methionine, but maximal inhibition (75%) required 18-24 hr of incubation with the amino acid. Under the same conditions glycolysis in the nontransformed canine cells was less than 20% inhibited by methionine. In Ehrlich ascites tumor cells grown in tissue culture, 10 mM methionine inhibited glycolysis by about 50%. Inhibition of glycolysis, even by 50 mM methionine, was rapidly reversible. Within 2 hr after removal of methionine the rate of glycolytic activity was restored to that observed in control cells. Furthermore, inhibition by methionine required a minimum level (7%) of serum in the growth medium and inhibition was not sensitive to cycloheximide. Only amino acids that are transported by system A (including the nonmetabolized analogue methylaminoisobutyric acid) specifically inhibited glycolysis in tumor cells. The only exception was phenylalanine, which was toxic to both transformed and normal cell lines.     

Characterization of several amino acid transports and glutamine metabolism in MOLT4 human T4 leukemia cells

The transport system responsible for glutamine, alanine and glutamate in MOLT4 human T4 leukemia cell line were characterized. Kinetic studies of sodium-dependent glutamine and alanine transport exhibited a single saturable high-affinity carrier with a Michaelis constant of 152 +/- 26 microm and 203 +/- 36 microm and a maximal transport velocity of 960 +/- 165 and 1096 +/- 208 nmol/10(9)cells/min, respectively. Glutamate uptake was less than one-tenth of glutamine and alanine, and linearly increased with glutamate concentration which was mediated by diffusion. 4-acetamido-4'-isothiocyanatostilbene-2,2'-disulfonic acid (SITS), known as anion channel blockers, inhibited the sodium-dependent glutamine and alanine transport by 40% at 10 microm. Cellular contents of these amino acids in MOLT4 cells revealed glutamate to be the highest among them despite low glutamate influx. A glutamine metabolism study using whole cells indicated this high conversion rate from glutamine to glutamate, but no conversion to another amino acid. Based on these results, the high glutamate concentration in MOLT4 was speculated to be synthesized from transported glutamine by active glutaminase.     

Effect of leucine on amino acid and glucose metabolism in humans.

Leucine has been reported to be an important regulator of protein metabolism. We investigated the effect of intravenous infusion of L-leucine versus saline on amino acid metabolism in eight healthy human subjects. Plasma concentrations of amino acids were measured and protein turnover was estimated using L-(1-13C)lysine and L-(3,3,3,-2H3)leucine as tracers. Glucose kinetics were measured using D-(6,6-2H2)glucose as a tracer. Leucine infusion increased the plasma leucine concentration from 103 +/- 8 to 377 +/- 35 mumol/L (P less than .01). Plasma concentrations of essential amino acids, including threonine, methionine, isoleucine, valine, tyrosine, and phenylalanine were significantly decreased by leucine infusion. Leucine infusion did not change lysine flux significantly (108 +/- 4 during saline v 101 +/- 4 mumol/kg/h-1 during leucine infusion), but decreased lysine oxidation (13.2 +/- 0.9 v 10.7 +/- 1 mumol/kg/h, P less than .05) and endogenous leucine flux (from 128 +/- 4 to 113 +/- 7 mumol/kg/h, P less than .05) when plasma (2H3) ketoisocaproate (KIC) was used for calculation. During leucine infusion, the (2H3) KIC to (2H3) leucine plasma enrichment ratio increased from 0.76 +/- 0.02 to 0.88 +/- 0.01 (P less than .001), while estimation of leucine flux using plasma (2H3) leucine showed no change in endogenous leucine flux. Leucine infusion decreased hepatic glucose production and metabolic clearance of glucose, but did not change plasma concentrations of glucose, insulin, C-peptide, glucagon, epinephrine, norepinephrine, or free fatty acids. We conclude that leucine spares glucose and lysine catabolism and decreases plasma concentrations of essential amino acids.(ABSTRACT TRUNCATED AT 250 WORDS)     

克山病区与非病区主粮中氨基酸含量对比分析

本文通过对克山病区及非病区主粮小麦、玉米中氨基酸的对比分析,探讨氨基酸含量与克山病的发病关系。从所测的17种氨基酸结果表明:小麦及玉米中的氨基酸含量,病区均低于非病区;小麦中以蛋氨酸含量最低、半胱氨酸次之,玉米中以半胱氨酸含量最低,蛋氨酸次之,这说明进入生物体内含硒氨基酸(蛋氨酸、半胱氨酸)是缺乏的。还证实粮中氨基酸含量多寡受产地生态环境的影响。病区人体从食物链中摄取需要的氨基酸及其营养物含量不足与克山病的发病有密切关系。     

感染食蟹猴疟原虫的大劣按蚊血淋巴和胃水解物氨基酸分析

大劣按蚊感染食蟹猴疟原虫B株后第10d,血淋巴内的蛋氨酸、异亮氨酸、亮氨酸、鸟氨酸、赖氨酸含量均较对照组低。第9d蚊胃水解物分析结果表明,感染蚊胃中的多数氨基酸含量增加,其中缬氨酸、蛋氨酸、酪氨酸的含量是对照组3倍以上,氨基酸的总量比对照组高70％以上。     

Analysis of amino acids in hemolymph and acid hydrolysates of midguts of Anopheles dirus infected with Plasmodium cynomolgi

Quantitative determinations of free amino acids in hemolymph and acid hydrolysates of midguts of female Anopheles dirus infected with Plasmodium cynomolgi bastianellii were carried out and the results were compared with those of noninfected mosquitoes. On day 10 after infected blood meal, the contents of methionine, isoleucine, leucine, ornithine, lysine in the hemolymph of infected mosquitoes markedly decreased as compared with those in the controls. However, the quantitative analysis of the amino acids of the acid hydrolysates of the midguts from infected mosquitoes on day 9 after an infected blood meal showed that the content of their total amino acids was 70% more than that in the controls, with special reference to aspartic acid, glutamic acid, valine, methionine, isoleucine, leucine, phenylalanine, tryptophan.     

Increased amino acid clearance and urea synthesis in a patient with glucagonoma.

Fasting concentrations, clearance of exogenous infused amino acids, and lean body mass were studied in a patient with glucagonoma syndrome (fasting glucagon = 380 pmol/l, normal range 15-45 pmol). The fasting concentrations of all amino acids were reduced. The clearances of alanine, arginine, glycine, isoleucine, leucine, lysine, methionine, proline, serine, threonine, and tyrosine were increased. The urea synthesis rate during amino acid infusion was 27 mumols/kg per minute (normal range 20-24 mumols/kg per minute). The lean body mass of the patients was reduced to 59% of the expected value. It is suggested that the weight loss of patients with glucagonoma syndrome is partly due to increased hepatic conversion of amino acid nitrogen to urea nitrogen, resulting in decreased blood amino acid concentration, and secondary to this, organ protein catabolism, as shown by the decreased lean body mass.     

Nutrient-hormone interaction in the ovine liver: methionine supply selectively modulates growth hormone-induced IGF-I gene expression

This study tested the hypothesis that specific amino acids are responsible for modulating the insulin-like growth factor-I (IGF-I) response to growth hormone (GH) in ovine hepatocytes. Cells were grown in media of defined amino acid composition, based on physiological concentrations (P.C.) of amino acids in sheep plasma. Relative to culture in 5 x P.C., amino acid limitation to 0.2 x P.C. had inhibitory effects on IGF-I RNA expression, peptide release and p70 S6 kinase phosphorylation (P<0.01 in each case). Limitation of methionine levels to 0.2 x P.C. against a background of 5 x P.C. for the other amino acids blocked GH-stimulated IGF-I peptide release and RNA expression, although basal expression was unaffected. In contrast, limitation of the other amino acids present in the culture medium had no effect on basal or GH-stimulated IGF-I expression. Selective methionine limitation to 0.2xP.C. levels had no effect on cellular or secretory protein synthesis rates relative to cells grown in complete 5 x P.C. medium but did cause a partial reduction in p70 S6 kinase phosphorylation, which was also observed when medium was selectively limited for other essential amino acids. The addition of rapamycin (5 ng/ml) to cells grown in 5xP.C. media completely abolished p70 S6 kinase phosphorylation (P<0.001), implicating mTOR in the response of S6 kinase phosphorylation to changing amino acid supply. By contrast, inclusion of rapamycin (100 ng/ml) had no effect on levels of IGF-I gene expression. These results indicate that methionine is the key limiting amino acid involved in the modulation of IGF-I expression in the ovine liver. This nutrient-hormone interaction is a highly selective phenomenon, occurring against a background of modest effects on general protein synthetic control. The partial inhibitory effects of methionine on mTOR activity are not sufficient to account for this selectivity of action.     

Stimulus-secretion coupling of arginine-induced insulin release. Uptake of metabolized and nonmetabolized cationic amino acids by pancreatic islets

In order to assess the possible role of L-arginine accumulation in islet cells as a determinant of its insulinotropic action, the uptake of L-arginine and other cationic amino acids (L-ornithine, L-homoarginine, D,L-alpha-methylornithine, D,L-alpha-difluoromethylornithine) by rat pancreatic islets was compared to the ionic and secretory responses of the islets to the same amino acids. A tight correlation was found between the net uptake of these amino acids and their capacity to stimulate 86Rb efflux, 45Ca uptake and efflux, and insulin release. In the latter respect, there was little difference between metabolized and nonmetabolized amino acids. Thus, although L-homoarginine and 4-amino-1-guanylpiperidine-4-carboxylic acid failed to act as a substrate for either arginase or amino acid aminotransferase in islet homogenates, they both stimulated 86Rb efflux, 45Ca uptake and efflux, and insulin secretion in intact islets. These findings are compatible with the view that the accumulation of these positively charged amino acids in islet cells represents an essential determinant of their secretory action. Hence, the release of insulin evoked by these amino acids could be due to depolarization of the plasma membrane with subsequent gating of voltage-sensitive Ca2+ channels and/or to some other biophysical effect, as suggested by the persistence of a sizeable secretory response to L-arginine or L-ornithine in islets perifused at a high concentrations of extracellular K+ (50 mM).     

Metabolic fuel and amino acid transport into the brain in experimental hypothyroidism

The effect of hypothyroidism in the adult rat on blood-brain barrier and muscle transport of hexoses, neutral amino acids, basic amino acids, monocarboxylic acids, and ketone bodies was examined using single arterial injection-tissue sampling technique. The cerebral blood flow and brain extraction of 3H2O (internal reference substance) was not altered in 3-month-old hypothyroid rats maintained on methimazole, 0.025% in the drinking water, for 7 weeks. The brain uptake index of D-beta-hydroxybutyrate was significantly reduced in hypothyroid rats (2.4 +/- 0.3 vs 4.6 +/- 0.6% p less than 0.001). Hypothyroid rats given thyroid hormone replacement therapy had normal brain uptake of D-beta-hydroxybutyrate (4.4 +/- 0.8%). The brain uptake index of butyrate was also significantly reduced in hypothyroid rats (39.3 +/- 2.1 vs 47.2 +/- 0.74%, p less than 0.001). The brain uptake index of other test substances and muscle uptake of nutrients examined were not altered in hypothyroid rats. These studies indicate that of the four transport systems examined in two tissues, the blood-brain barrier monocarboxylic acid transport system is most susceptible to the hypothyroidism-induced changes.