Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0038187 (starvation)
24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The metabolism of alanine and several other gluconegoneic substrates was studied in anesthtized fed and fasted rats, i.e., rats with low and high rates of gluconeogenesis. Glutamine was released by the hindquarter (muscle) in both groups, whereas lactate, pyruvate, and alanine were taken up in fed rats and were released during starvation. Despite this, blood levels of alanine, lactate, and pyruvate were diminished in fasting rats, suggesting increased extraction by liver. Treatment of fasted rats for 24 h with phloridzin caused glycosuria and secondarily led to hypoglycemia and an intensification of the chargesobserved with fasting, i.e., hyperketonemia, hyperglucagonemia, and increased gluconeogenesis (assessed by urea N excretion). Blood alanine was decreased, even though the release of alanine from muscle was increased. Pretreatment with triamcinolone and administration of exogenous alanine both attenuated the hypoglycemia and ketosis, It is concluded that 1) in states of heightened gluconeogenesis, alanine release from muscle may not keep pace with extraction by liver and blood alanine decreases; 2) the release of alanine, lactate, and pyruvate from muscle parallel each other suggesting common control factors; and 3) in the red state muscle is an important site of lactate disposition.
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PMID:Alanine metabolism and gluconeogenesis in the rat. 96 15

In isolated hepatocytes from 24 h-starved rats, no glycogen synthesis was observed in the presence of glutamine. By contrast, glutamine was the best gluconeogenic substrate to induce glycogen synthesis in isolated hepatocytes from 72 h-starved rats. The effect of glutamine on glycogen synthesis was not accompanied by parallel changes in glucose or lactate production. Glutamine activated glycogen synthase independently of the starvation period; however, the extent of synthase activation was 2-fold higher in isolated hepatocytes from 72 h-starved rats than in hepatocytes from 24 h-starved rats. This increase in synthase activation was associated with increased cell swelling. The rate of glutamine transport was not significantly different in hepatocytes from 24 h- and 72 h-starved rats. By contrast, the intracellular glutamate concentration was 1.5-fold higher after 3 days of starvation in hepatocytes incubated with 5 mM-glutamine. We propose that glutamine may play a key role in the glycogen synthesis observed in vivo after 3 days of starvation.
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PMID:Glutamine is a good substrate for glycogen synthesis in isolated hepatocytes from 72 h-starved rats, but not from 24 h- or 48 h-starved rats. 147 95

The activities of alanine and aspartate transaminases, adenylate deaminase, glutamine synthetase and glutamate and xanthine dehydrogenases have been measured in liver, yolk sac membrane, intestine and breast and leg muscle of domestic fowl hatchlings receiving for 3 or 5 days either a standard diet or hard boiled eggwhite as well as in 3 or 5 days starved animals. The patterns of activation of amino acid metabolism enzymes were fully comparable in protein-fed and starved groups with respect to fed controls; the differences with respect to the latter became more marked in 5- than in 3-days old chicks. In 5-days old chicks intestine alanine transaminase activity increased in parallel to that of liver in protein-fed animals but not in those starved, in agreement with an enhanced alanine transfer between both organs under this situation. Both, starvation and protein-feeding, induced a general decrease in the amino acid metabolizing ability of muscle. Glutamine (but not alanine) synthetizing capabilities were enhanced.
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PMID:Effect of starvation and a protein diet on the amino acid metabolism enzyme activities of the organs of domestic fowl hatchlings. 287 42

The intestinal tract plays a central role in the protein catabolic response after injury and infection. The mucosa utilizes glutamine and thus spares glucose--presumably sparing this essential fuel source for tissues with an obligate glucose requirement. With inadequate nutritional support or prolonged stress, glutamine levels decrease in both the plasma and the tissue pools, which suggests that glutamine deficiency occurs. This is associated in time with atrophy of the gastrointestinal mucosa. This provision of dietary glutamine results in correction of the abnormally low glutamine concentrations and increased cellularity of the gut mucosa. The derangements in the intestinal mucosa associated with starvation, injury, infection, immunosuppression, chemotherapy, lack of enteral feedings, and other stresses are associated with a breakdown in the barrier function of the gut. Both bacteria and their toxins may enter the host from the intestinal lumen. Through interaction with the reticuloendothelial system, cytokines are produced, which stimulate the pituitary-adrenal axis and thus contribute to the stress response. The elaboration of glucocorticoids facilitates proteolysis, thus increasing glutamine release from skeletal muscle for gut repair. Although this homeostatic mechanism appears to aid mucosal repair and support immunologic responses, severe injury or prolonged glutamine deficits do not adequately support intestinal recovery and allow this cycle to become self-perpetuating (Fig 3). Adequate enteral feedings initiated early in the course of a disease appear to maintain adequate gut barrier function. In the frequent circumstance when feeding by this route is inadequate or impossible, glutamine-containing parenteral feedings offer an appropriate alternative therapy for bowel and immunologic support. Glutamine-containing parenteral feedings are associated with increased mucosal cellularity and improved survival after gut injury. Specific hormones also stimulate mucosal growth, and it is anticipated that a combination of hormones and specific nutrients will provide optimal support of the gut mucosa in the severely ill patient.
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PMID:The gut: a central organ after surgical stress. 305 97

1. The effect of starvation on the metabolism of gut glutamine and ketone-bodies of peak lactating, non-lactating and virgin rats was investigated. 2. The arterial blood ketone-body concentration was increased by approximately 7-, 6- and 13-fold in 48 h-starved virgin, non-lactating and lactating rats, respectively. 3. The arterial blood glutamine concentration was decreased by approximately 32% in 48 h-starved lactating rats (p less than 0.001). 4. The maximal activity of phosphate-dependent glutaminase was increased or decreased in the small intestine of fed or 48 h-starved peak-lactating rats, respectively. 5. Portal drained viscera blood flow increased by approximately 25% in peak-lactating rats. 6. Arteriovenous difference measurements for ketone-bodies across the gut of 48 h-starved rats showed an increase in net uptake of ketone-bodies by approximately 10-, 17- and 29-fold in virgin, non-lactating and lactating rats, respectively. 7. Glutamine was extracted by the gut of peak-lactating rats at a rate of 487 nmol/100 g of body wt. which was greater by approximately 33% (p less than 0.001) than that of virgin or non-lactating animals. In peak lactating rats, 48 h-starvation resulted in marked decreases in the rates of glutamine removal from the circulation (p less than 0.001) which was accompanied by decreased rates of release of glutamate, alanine and ammonia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Glutamine and ketone-body metabolism in the small intestine of starved peak-lactating rats. 313 91

Measurement of the arteriovenous differences for free amino acids across rat kidney reveals that glycine and citrulline are removed and serine and arginine are added to the circulation. In addition, glutamine is taken up in large quantities by kidneys of animals that need to excrete large quantities of acid (e.g., diabetic animals, NH4Cl-fed animals, and animals fed a high protein diet). Glutamine is the major precursor of urinary ammonia and thus renal glutamine metabolism plays a key role in acid-base homeostasis. This process occurs primarily in the cells of the convoluted proximal tubule. Glutamine carbon is converted to glucose in acidotic rats and is totally oxidized in dogs. Regulation of glutamine metabolism occurs at two levels: acute regulation and chronic regulation. Acute regulation is, in part, mediated through a fall in intracellular [H+]. This activates alpha-ketoglutarate dehydrogenase and, ultimately, glutaminase. Chronic regulation involves induction of key enzymes, including, in the rat, glutaminase, glutamate dehydrogenase, and phosphoenolpyruvate carboxykinase. During the acidosis of prolonged starvation, the kidneys' requirement for glutamine must be met from muscle proteolysis and thus becomes a drain on lean body mass. Serine synthesis occurs by two separate pathways: from glycine by the combined actions of the glycine cleavage enzyme and serine hydroxymethyltransferase and from gluconeogenic precursors using the phosphorylated-intermediate pathway. Both pathways are located in the cells of the proximal tubule. Conversion of glycine to serine is ammoniagenic and the activity of the glycine cleavage enzyme is increased in acidosis. The function of serine synthesis by the phosphorylated-intermediate pathway is not apparent.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The 1986 Borden award lecture. The role of the kidney in amino acid metabolism and nutrition. 332 68

In incubated colonocytes isolated from rat colons, the rates of utilization O2, glucose or glutamine were linear with respect to time for over 30 min, and the concentrations of adenine nucleotides plus the ATP/ADP or ATP/AMP concentration ratios remained approximately constant for 30 min. Glutamine, n-butyrate or ketone bodies were the only substrates that caused increases in O2 consumption by isolated incubated colonocytes. The maximum activity of hexokinase in colonic mucosa is similar to that of 6-phosphofructokinase. Starvation of the donor animal decreased the activities of hexokinase and 6-phosphofructokinase, whereas it increased those of glucose-6-phosphatase and fructose-bisphosphatase. Isolated incubated colonocytes utilized glucose at about 6.8 mumol/min per g dry wt., with lactate accounting for 83% of glucose removed. These rates were not affected by the addition of glutamine, acetoacetate or n-butyrate, and starvation of the donor animal. Isolated incubated colonocytes utilized glutamine at about 5.5 mumol/min per g dry wt., which is about 21% of the maximum activity of glutaminase. The major end-products of glutamine metabolism were glutamate, aspartate, alanine and ammonia. Starvation of the donor animal decreased the rate of glutamine utilization by colonocytes, which is accompanied by a decrease in glutamate formation and in the maximum activity of glutaminase. Isolated incubated colonocytes utilized acetoacetate at about 3.5 mumol/min per g dry wt. This rate was not markedly affected by addition of glucose or by starvation of the donor animal. When colonocytes were incubated with n-butyrate, both acetoacetate and 3-hydroxybutyrate were formed, with the latter accounting for only about 19% of total ketones produced.
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PMID:Fuel utilization in colonocytes of the rat. 407 34

11 normal obese subjects were fasted for 33 days. In five, who served as controls, urine urea nitrogen excretion remained constant for 2 wk thereafter. The other six were given seven daily infusions containing 6-8 mmol each of the alpha-keto-analogues of valine, leucine, isoleucine, phenylalanine, and methionine (as sodium salts) plus 3-4 mmol each of the remaining essential amino acids (lysine, threonine, tryptophan, and histidine). Rapid amination of the infused ketoacids occurred, as indicated by significant increases in plasma concentrations of valine, leucine, isoleucine, alloisoleucine, phenylalanine, and methionine. Glutamine, glycine, serine, glutamate, and taurine fell significantly. Blood glucose, ketone bodies, plasma free fatty acids, and serum immunoreactive insulin concentrations were unaltered. Urine urea nitrogen fell from 1.46 to 0.89 g/day on the last day of infusions; 5 days later it was still lower (0.63 g/day) and in two subjects studied for 9 and 17 days postinfusion it remained below preinfusion control values. Urine ammonia, creatinine, and uric acid were unaltered. Nitrogen balance became less negative during and after infusions. The results indicate that this mixture of essential amino acids and their keto-analogues facilitates nitrogen sparing during prolonged starvation, in part by conversion of the ketoacids to amino acids and in part by altering mechanisms of nitrogen conservation. The latter effect persists after the ketoacids are metabolized.
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PMID:Nitrogen sparing induced by a mixture of essential amino acids given chiefly as their keto-analogues during prolonged starvation in obese subjects. 443 Jul 27

Regulation of hexose transport in NIL hamster fibroblasts has been studied in confluent cultures preconditioned for 24 hr in media deprived of glutamine or of serum or of both. Cultures maintained in media containing dialyzed fetal calf serum and 4 mM glutamine accumulated up to 72 nmol of glutamine per mg of cell protein; in contrast, cells deprived of glutamine contained less than 1 nmol/mg of cell protein. Glutamine elicited a general enhancement of hexose transport compared with transport in glutamine-deprived cultures. This enhancement was particularly pronounced in glucose-fed cultures which in the absence of glutamine showed conspicuously low transport activity. When maintained in glucose media, cultures deprived of serum also showed a marked loss of hexose transport which, in this case, was not compensated for by addition of glutamine. However, regardless of the presence or absence of glutamine, these cultures were able to develop the usual transport enhancement response to glucose starvation. Moreover, 2,4-dinitrophenol was also able to elicit a pronounced enhancement of hexose transport in the glucose-fed cultures; this effect surpassed even the transport derepression observed in the glucose-starved cultures. In polyoma-transformed cultures maintained in serum-free media, hexose transport remained relatively high, even in the presence of glucose. However, addition of glutamine brought about an enhancement in both the presence and absence of serum. The various phenomena are discussed in regard to protein turnover in general and more specifically the turnover of hexose transport carriers.
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PMID:Effects of combined glutamine and serum deprivation on glucose control of hexose transport in mammalian fibroblast cultures. 625 70

The utilization of amino acids and glucose by ascites tumour cells has been studied in order to elucidate which are their relative roles as energy substrates or building blocks for biosynthetic purposes, as well as the quantitative contribution of the different metabolic pathways involved. 1. Glucose is utilized at a rate of 1.1 mumol x min-1 x g cells-1. 93% is transformed into lactate, 0.7% used by the pentose phosphate pathway, 1.5% by the tricarboxylic acid cycle and 2% is for lipid synthesis. 2. ATP production is derived: 78% from glucose conversion into lactate, 1% from glucose oxidation and 19% from glutamine oxidation. 3. Glucose starvation, in the presence of all amino acids, leads to a 70% decrease in the rate of protein synthesis, due to the drop in ATP levels. 4. Pentose phosphate pathway flux increases by 75% when glycolysing cells are incubated in the presence of all amino acids. 5. Pyruvate is decarboxylated at a rate of 66 nmol x min-1 x g cells-1, 45-80% of it is incorporated into lipids instead of being oxidized, depending on the incubation conditions. 6. Non-essential amino acids (aspartate and glutamate) are oxidized at a low rate. Glutamine is oxidized at a rate 20-times and 35-times that of glucose and glutamate respectively. Glutamine can not replace glucose as the main energy source. 7. Leucine utilization, 28 nmol x min-1 x g cells-1, is very high compared with normal cells, due to the high rate of lipid and protein synthesis. Its oxidation is similar to that of non-tumoural cells. 8. Sterols account for 80% of the lipids synthesized either from leucine or glucose.
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PMID:Amino acids and glucose utilization by different metabolic pathways in ascites-tumour cells. 679 Feb 81


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