Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:4.1.1.32 (phosphoenolpyruvate carboxykinase)
 4,204 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The effects of starvation on the acid-base status of the rat and on the glucoeogenic and ammoniagenic capacity of rat renal-cortical slices were examined. Starvation for 48 or 72 hr did not affect acid-base status, and urinary ammonia production did not change. Kidney cortical slices from starved as compared to fed rats showed increased gluconeogenic capacity when incubated with the substrated pyruvate, succinate, fumarate, malate, 2-oxyoglutarate, glutamine and glutamate. Renal cortical tissue from starved rats also had increased activity of the gluconeogenic enzyme phosphoenolpyruvate carboxykinase. Renal cortical slices from starved rats did not differ from those from fed rats in the ability to produce ammonia from glutamine or glutamate, nor was there any difference inhe activity of glutaminase between these groups. These results show that renal gluconeogenic capacity is increased in starved rats in the absence of systemic acidosis, and starvation does not lead to an increase in urinary ammonia excretion or renal ammoniagenic capacity.
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PMID:Effect of starvation on renal metabolism in the rat. 24 54

The purpose of this study was to investigate factors which may regulate ammoniagenesis in the kidney cortex. Emphasis was placed on the segment of the pathway by which the carbons derived from glutamine must exit from the mitochondrion. These pathways were compared in the rat with high rates of ammoniagenesis and the rabbit which has a low rate of ammoniagenesis. The dicarboxylate transporter, which is essential for ammoniagenesis, has a maximum velocity which was much lower in the rabbit. The malate concentration required for half-maximal rates of transport was 14 nmol/mg mitochondrial protein and similar in both species. There was no effect of chronic metabolic acidosis on dicarboxylate transporter activity. The tricarboxylate transporter activity with phosphoenol pyruvate as substrate also had a low activity in the rabbit kidney-cortex mitochondria. The maximum velocity of phosphate dependent glutaminase, glutamate dehydrogenase and phosphoenolpyruvate carboxykinase were all much greater than the maximal rate of ammoniagenesis observed in vivo in the rabbit. Therefore, the low rates of ammoniagenesis and the failure to adapt to acidosis in the rabbit are best explained by factors influencing the dicarboxylate transporter.
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PMID:Role of the mitochondrial anion transporters in the regulation of ammoniagenesis in renal cortex mitochondria of the rabbit and rat. 49 11

The influence of protein intake on acid excretion and renal glutamine metabolism was investigated and compared to the effects of NH4Cl-induced metabolic acidosis. Rats fed a diet containing 55% casein excreted more ammonia, phosphate, sulphate, and chloride than did rats fed a 13% casein diet, but, when they were given an 0.1 M NaHCO3 solution to drink, ammonia excretion was no longer elevated. Renal phosphate-dependent glutaminase and phosphoenolpyruvate carboxykinase activities, ammoniagenesis by isolated mitochondria, and the rate of renal gluconeogenesis were all elevated in the rats fed the high-protein diet but not if these rats also drank the sodium bicarbonate solution. Increased glutaminase and phosphoenolpyruvate carboxykinase activities, mitochondrial ammoniagenesis, and gluconeogenesis were all evident in rats made acidotic with NH4Cl. It is concluded that these metabolic adaptations evident in the kidneys of rats fed the high-protein diet are due to the acidogenic effects of increased protein intake.
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PMID:Renal glutamine metabolism in rats fed high-protein diets. 69 20

Experiments were carried out on rats to evaluate the possible regulatory roles of renal glutaminase activity, mitochondrial permeability to glutamine, phosphoenolpyruvate carboxykinase activity and systemic acid-base changes in the control of renal ammonia (NH(3) plus NH(4) (+)) production. Acidosis was induced by drinking NH(4)Cl solution ad libitum. A pronounced metabolic acidosis without respiratory compensation [pH=7.25; HCO(3) (-)=16.9mequiv./litre; pCO(2)=40.7mmHg (5.41kPa)] was evident for the first 2 days, but thereafter acid-base status returned towards normal. This improvement in acid-base status was accompanied by the attainment of maximal rates of ammonia excretion (onset phase) after about 2 days. A steady rate of ammonia excretion was then maintained (plateau phase) until the rats were supplied with tap water in place of the NH(4)Cl solution, whereupon pCO(2) and HCO(3) (-) became elevated [55.4mmHg (7.37kPa) and 35.5mequiv./litre] and renal ammonia excretion returned to control values within 1 day (recovery phase). Renal arteriovenous differences for glutamine always paralleled rates of ammonia excretion. Phosphate-dependent glutaminase and phosphoenolpyruvate carboxykinase activities and the rate of glutamine metabolism (NH(3) production and O(2) consumption) by isolated kidney mitochondria all increased during the onset phase. The increases in glutaminase and in mitochondrial metabolism continued into the plateau phase, whereas the increase in the carboxykinase reached a plateau at the same time as did ammonia excretion. During the recovery phase a rapid decrease in carboxykinase activity accompanied the decrease in ammonia excretion, whereas glutaminase and mitochondrial glutamine metabolism in vitro remained elevated. The metabolism of glutamine by kidney-cortex slices (ammonia, glutamate and glucose production) paralleled the metabolism of glutamine in vivo during recovery, i.e. it returned to control values. The results indicate that the adaptations in mitochondrial glutamine metabolism must be regulated by extra-mitochondrial factors, since glutamine metabolism in vivo and in slices returns to control values during recovery, whereas the mitochondrial metabolism of glutamine remains elevated.
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PMID:Glutamine metabolism in the kidney during induction of, and recovery from, metabolic acidosis in the rat. 70 90

During chronic acidosis, the levels of the rat renal mRNAs that encode the mitochondrial glutaminase (GA) and cytosolic phosphoenolpyruvate carboxykinase (PCK) are increased 6-fold. Following acute recovery of chronic acidosis, the levels of the two mRNAs are rapidly and coordinately decreased, returning to normal within 13-17 h. In contrast, the increases in GA and PCK mRNAs during acute onset of acidosis occur with very different kinetics. The increase in PCK mRNA occurs rapidly and reaches a maximum within 7 h, whereas the GA mRNA is increased after a 4-7-h lag and then plateaus at 14-17 h. Treatment with dexamethasone or with cAMP analogs significantly increases the level of renal PCK mRNA but has no effect on the level of GA mRNA. Nuclear run-on experiments indicate that the acute induction of PCK mRNA is primarily due to an increased rate of transcription. However, transcription of GA mRNA is unaffected by acute acidosis. Therefore, the changes in the two mRNAs are temporally coordinated but occur through different mechanisms. Furthermore, the inductive effects of acidosis are not mediated solely through glucocorticoid or cAMP regulatory elements.
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PMID:Effect of acute alterations in acid-base balance on rat renal glutaminase and phosphoenolpyruvate carboxykinase gene expression. 170 37

A gluconeogenic strain of renal epithelial cells (LLC-PK1-F+) was used to characterize the effect of pH and bicarbonate concentration on the levels of phosphoenolpyruvate carboxykinase (PCK) and glutaminase (GA) mRNAs. The levels of both mRNAs are markedly dependent upon medium glucose concentration. The level of PCK mRNA is increased with increasing glucose concentration from 0 to 40 mM, whereas the level of GA mRNA is maximal between 3 and 5 mM glucose. When LLC-PK1-F+ cells are grown with 5 mM glucose and then subjected to an acute decrease in pH (from 7.4 to 6.9) and bicarbonate concentration (from 25 to 10 mM), the level of PCK mRNA exhibits a biphasic response. The PCK mRNA is initially increased 4-fold within 3 h, then decreases slightly and subsequently increases between 10 and 20 h to a level that is 17-fold greater than normal. Only the initial increase parallels the changes observed in vivo. In contrast, after onset of acidosis, the level of GA mRNA initially remains unchanged, is then increased 8-fold between 10 and 16 h, and then decreases slightly. This response closely mimics the results obtained in vivo. A decrease in media pH at constant bicarbonate causes a marked increase in both mRNAs. However, the levels of the two mRNAs are also elevated by decreasing bicarbonate at a constant pH. Thus, both parameters independently affect the level of the two mRNAs. The use of actinomycin D to measure the half-lives of PCK and GA mRNAs at pH 7.4 and 6.9 indicates that stabilization may fully account for the induction of GA mRNA and contributes to the inductive effects of decreased pH and/or bicarbonate on PCK mRNA. Following recovery from acidic conditions, the two mRNAs exhibit a rapid and coordinate decrease (t1/2 approximately 20 min). Dexamethasone had no effect on the level of either mRNA, whereas cAMP increased only PCK mRNA. The latter effect was additive with the increase caused by decreased pH and/or bicarbonate and was reversed by incubating in alkalotic media. Thus, the induction of PCK and GA mRNAs during acidosis is initiated in direct response to a decrease in extracellular pH and/or bicarbonate.
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PMID:Effect of pH and bicarbonate on phosphoenolpyruvate carboxykinase and glutaminase mRNA levels in cultured renal epithelial cells. 185 45

Increased rat renal ammoniagenesis is sustained during chronic metabolic acidosis by the cell-specific induction of the regulatory enzymes of glutamine catabolism and of gluconeogenesis. A glutaminase-specific cDNA hybridizes to 6.0- and 3.4-kb mRNAs that are contained in total or poly(A)+ RNA isolated from rat kidney. When translated in a rabbit reticulocyte lysate, each of the fractionated mRNAs produces the 72-kDa precursor of the mitochondrial glutaminase. The levels of both mRNAs are increased 5-fold within 1 day following onset of chronic acidosis and reach a maximum (8-fold) after 5 days. During recovery from chronic acidosis, the levels of the glutaminase mRNAs are returned to normal within 1 day. The observed changes in mRNA levels correlate with equivalent changes in the relative levels of translatable glutaminase mRNA. Nuclear run-on assays indicate that the rate of transcription of the renal phosphoenolpyruvate carboxykinase gene is increased and decreased in response to onset and recovery from chronic acidosis, respectively. In contrast, the rates of transcription of the glutaminase and beta-actin genes are unaffected by alterations in acid-base balance. Thus, the increase in renal glutaminase activity during chronic acidosis results from an equivalent increase in the levels of total and translatable glutaminase mRNAs which apparently results from an increased stability of the glutaminase mRNA.
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PMID:Mechanism of altered renal glutaminase gene expression in response to chronic acidosis. 185 51

Perivenous and periportal hepatocytes were isolated by the digitonin/collagenase perfusion technique. The specific activity of phosphate-activated glutaminase was 2.33-fold higher in periportal cells than in perivenous cells. Similarly, the relative abundance of glutaminase mRNA was 2.6-fold higher in samples from periportal cells. The distribution of glutaminase activity and mRNA was compared with those for glutamine synthetase (predominantly perivenous) and phosphoenolpyruvate carboxykinase (predominantly periportal). The results suggest that phosphate-activated glutaminase is predominantly expressed in the periportal zone of the liver acinus.
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PMID:Distribution of hepatic glutaminase activity and mRNA in perivenous and periportal rat hepatocytes. 197 Feb 42

Katz et al. [Katz, J., Golden, S. & Wals, P.A. (1976) Proc. Natl Acad. Sci. USA 73, 3433-3437] were the first to report that in hepatocytes isolated from fasted rats and incubated with either dihydroxyacetone, glucose or other sugars, glycogen synthesis was greatly accelerated by addition of amino acids. We have looked for possible mediators responsible for this effect and have tested the effect of alanine, proline, asparagine, glutamine or a combination of ammonia with either pyruvate or lactate in activating glycogen synthesis from dihydroxyacetone. The following observations were made. 1. Stimulation of glycogen synthesis by alanine, proline or asparagine does not require production of glutamine since the effect also occurs in periportal hepatocytes which lack glutamine synthetase. 2. Under various conditions, stimulation of glycogen synthesis by added amino acids directly correlated with increases in the intracellular content of amino acids, expressed in osmotic equivalents. 3. 3-Mercaptopicolinic acid, the inhibitor of phosphoenolpyruvate carboxykinase, further enhances stimulation of glycogen synthesis by amino acids because it increases the intracellular accumulation of aspartate and glutamate. 4. The previously reported enhancement by leucine of the stimulation of glycogen synthesis by glutamine [Chen. K. S. & Lardy, H. A. (1985) J. Biol. Chem. 260, 14683-14688] can be ascribed to inhibition of urea synthesis by leucine which results in accumulation of glutamate and of ammonia, the essential activator of glutaminase. It is concluded that activation of glycogen synthesis by added amino acids is due to an increase in intracellular osmolarity following their uptake and the accumulation of intracellular catabolites. This results in an increase in hepatic volume which stimulates glycogen synthesis [Baquet, A., Hue, L., Meijer, A. J., van Woerkom, G. M. & Plomp, P. J. A. M. (1990) J. Biol. Chem. 265, 955-959].
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PMID:Stimulation of glycogen synthesis in hepatocytes by added amino acids is related to the total intracellular content of amino acids. 237 2

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


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