The amino acid glutamine has important and unique metabolic functions. It is the most abundant free amino acid in the circulation and in intracellular pools and a precursor for the synthesis of amino acids, proteins, nucleotides, and many other biologically important molecules. It is the most important precursor for ammoniagenesis in the kidney, the major end product of ammonia-trapping pathways in the liver, a substrate for gluconeogenesis, and an oxidative fuel in rapidly proliferating cells and tissues. Glutamine also may have a number of important regulatory roles, increasing protein synthesis and decreasing protein degradation in skeletal muscle and stimulating glycogen synthesis in the liver. The demonstration that glutamine concentrations decrease and tissue glutamine metabolism increases markedly in many catabolic, stressful disease states has led to a reconsideration of the classification of glutamine as a nonessential amino acid and to the alternative hypothesis that glutamine may be a conditionally essential nutrient. This hypothesis has been supported by recent studies that have shown trophic effects of glutamine-supplemented diets on the growth of specific tissues and on total body nitrogen balance. These observations form the basis for current efforts to define the clinical usefulness of glutamine-supplemented nutrition. (Journal of Parenteral and Enteral Nutrition14:40S-44S, 1990)
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References
1.
Hlasiwetz H. , Habermann J.: Ueber die Proteinstoffe. Ann Chem169:150-166, 1873
2.
Schulze E., Bosshard E.: Ueber das Glutamin. Landwirtsch Vers Sta29:295-307, 1883
3.
Damodaran M. , Jaaback G., Chibnall AC: The isolation of glutamine from an enzymic digest of gliadin. Biochem J26:1704-1713, 1932
4.
Krebs HA: Metabolism of amino acids. IV. The synthesis of glutamine from glutamic acid and ammonia, and the enzymic hydrolysis of glutamine in animal tissues . Biochem J33:1951-1969, 1935
5.
Rose WC: The nutritive significance of the amino acids. Physiol Rev18:109-136, 1938
6.
Meister A.: Catalytic mechanism of glutamine synthetase: Overview of glutamine metabolism . IN Glutamine: Metabolism, Enzymology, and Regulation , Mora J, Palacios R (eds). Academic Press, New York, 1980, pp 1-40
7.
Krebs H.: Glutamine metabolism in the animal body. IN Glutamine: Metabolism, Enzymology, and Regulation, Mora J, Palacios R (eds). Academic Press, New York, 1980, pp 319-329
8.
Eagle H.: Nutrition needs of mammalian cells in tissue cultures. Science122:501-504, 1955
9.
Eagle H., Oyama VI, Levy M., et al: The growth response of mammalian cells in tissue culture to L-glutamine and L-glutamic acid. J Biol Chem218:607-617, 1955
10.
Zielke HR, Ozand PT, Tildon JT, et al: Reciprocal regulation of glucose and glutamine utilization by cultured human diploid fibroblasts. J Cell Physiol95:41-48, 1978
11.
Reitzer LJ, Wice BM, Kennell D.: Evidence that glutamine, not sugar, is the major energy source for cultured HeLa cells. J Biol Chem254:2669-2676, 1979
12.
McKeehan WL : Glycolysis, glutaminolysis and cell proliferation . Cell Biol Int Rep6:635-650, 1982
13.
Scriver CR, Rosenberg LE: Amino Acid Metabolism and Its Disorders. WB Saunders , Philadelphia, 1973, p 42
14.
Linder-Horowitz M., Knox WE, Morris HP: Glutaminase activities and growth rates of rat hepatomas. Cancer Res29:1195-1199, 1969
15.
Prajda N., Katunuma N.Morris HP, et al: Imbalance of purine metabolism in hepatomas of different growth rates as expressed in behavior of glutamine-phosphoribosylpyrophosphate amidotransferase (amidophosphoribosyltransferase, EC 2.4.2.14). Cancer Res35:3061-3068, 1975
16.
Sebolt JS, Weber G.: Negative correlation of L-glutamine concentration with proliferation rate in rat hepatomas. Life Sci3.1:301-306, 1984
17.
Kvamme E., Svenneby G.: The effect of glucose on glutamine utilization by Ehrlich ascites tumor cells . Cancer Res21:92-98, 1961
18.
Knox WEHorowitz ML, Friedell GH: The proportionality of glutaminase content to growth rate and morphology of rat neoplasms. Cancer Res29:669-680. 1969
19.
Levintow L.Eagle H., Piez KA: The role of glutamine in protein biosynthesis in tissue culture. J Biol Chem227:929-941, 1957
20.
Donnelly M. , Scheffler IE: Energy metabolism in respiration-deficient and wild type Chinese hamster fibroblasts. J Cell Physiol89:39-52, 1976
21.
Newsholme EA , Crabtree B., Ardawi MSM: The role of high rates of glycolysis and glutamine utilization in rapidly dividing cells. Biosci Rep5:393-400, 1985
22.
Pitts RF: Renal production and excretion of ammonia. Am J Med36:720-742, 1964
23.
Ross BD, Hems R., Krebs HA: The rate of gluconeogenesis from various precursors in the perfused rat liver . Biochem J102:942-951, 1967
24.
Haussinger D. , Meijer AJ, Gerok W., et al: Hepatic nitrogen metabolism and acid-base homeostasis. IN pH Homeostasis, Haussinger D (ed). Academic Press, London, 1988, pp 337-377
25.
Meister A.: Metabolism of glutamine. Physiol Rev36:103-127, 1956
26.
Hartman SC: Glutaminases and γ-glutamyltransferases. IN The Enzymes , Vol IV, Boyer PD (ed). Academic Press, New York, 1971, pp 79-100
27.
Meister A.: Glutamine synthetase of mammals. IN The Enzymes, Vol X, Boyer PD (ed). Academic Press, New York, 1974, pp 699-754
28.
Stein WH, Moore S.: The free amino acids of human blood plasma. J Biol Chem211:915-926, 1954
29.
Marliss EB, Aoki TT, Pozefsky T., et al: Muscle and splanchnic glutamine and glutamate metabolism in postabsorptive and starved man. J Clin Invest50:814-817, 1971
30.
Windmueller HG: Glutamine utilization by the small intestine . Adv Enzymol53:201-237, 1982
31.
Askanazi J. , Carpentier YA, Michelsen CB, et al: Muscle and plasma amino acids following injury: Influence of intercurrent infection. Ann Surg192:78-85, 1980
32.
Bergstrom J. , Furst P., Noree L-O., et al: Intracellular free amino acid concentration in human muscle tissue. J Appl Physiol36:693-697, 1974
33.
Rennie MJ, Hundal HS, Babij P., et al: Characteristics of a glutamine carrier in skeletal muscle have important consequences for nitrogen loss in injury, infection, and chronic disease. Lancet2:1008-1012, 1986
34.
Jepson MM, Bates PC, Broadbent P., et al: Relationship between glutamine concentration and protein synthesis in rat skeletal muscle. Am J Physiol255:E166-E172, 1988
35.
Smith RJ: Regulation of protein degradation in differentiated skeletal muscle cells in monolayer culture. IN Intracellular Protein Catabolism , Progress in Clinical and Biological Research, Vol 180 , Khairallah EA, Bond JS, Bird JWC (eds). Alan R Liss, New York, 1984, pp 633-635
36.
MacLennan PA , Brown RA, Rennie MJ: A positive relationship between protein synthetic rate and intracellular glutamine concentration in perfused rat skeletal muscle . FEBS Lett215:187-191, 1987
37.
Katz J., Golden S., Wals PA: Stimulation of hepatic glycogen synthesis by amino acids. Proc Natl Acad Sci USA73:3433-3437, 1976
38.
Newsholme EA , Crabtree B., Ardawi MSM: Glutamine metabolism in lymphocytes: Its biochemical, physiological and clinical importance. Q J Exp Physiol70:473-489, 1985
39.
Roth E., Funovics J., Muhlbacher F., et al: Metabolic disorders in severe abdominal sepsis: Glutamine deficiency in skeletal muscle. Clin Nutr1:25-41, 1982
40.
Muhlbacher F., Kapadia CR, Colpoys MF, et al: Effects of glucocorticoids on glutamine metabolism in skeletal muscle. Am J Physiol247:E75-E83, 1984
41.
Souba WW, Smith RJ, Wilmore DW: Effects of glucocorticoids on glutamine metabolism in visceral organs . Metabolism34:450-456, 1985
42.
Johnson DJ, Jiang ZMColpoys M. et al: Branched chain amino acid uptake and muscle free amino acid concentrations predict postoperative muscle nitrogen balance. Ann Surg204:513-523, 1986
43.
Fox ADKripke SADePaula J. et al: Effect of a glutamine-supplemented enteral diet on methotrexate-induced enterocolitis. JPEN12:325-331. 1988
44.
O'Dwyer ST , Smith RJHwang TL, et al: Maintenance of small bowel mucosa with glutamine-enriched parenteral nutrition. JPEN13:579-585, 1989
45.
Stehle P., Mertes N., Puchstein CH, et al: Effect of parenteral glutamine peptide supplements on muscle glutamine loss and nitrogen balance after major surgery. Lancet1:231-233, 1989
46.
Hammarqvist F., Wernerman J., Ali R., et al: Addition of glutamine to total parenteral nutrition after elective abdominal surgery spares free glutamine in muscle, counteracts the fall in muscle protein synthesis, and improves nitrogen balance . Ann Surg209:455-461, 1989
