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Query: EC:1.4.1.2 (
glutamate dehydrogenase
)
4,380
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We studied mechanism(s) by which adaptations of renal TCA cycle metabolism abet ammoniagenesis from glutamine in altered acid-base states. Renal tubules from control, acidotic, or alkalotic rats were incubated at pH 7.4 with 1 mM [3-13C,5-15N]glutamine or 2 mM [3-13C]pyruvate. In acidosis there was a significantly higher flux through glutaminase and through glutamate, 2-oxoglutarate, succinate and malate dehydrogenases as well as markedly enhanced 13C-glucose formation.
Alkalosis
was associated with little change in 13C flux from glutamine to TCA cycle intermediates compared with control but production of 15NH3 and 13C glucose was significantly diminished. The current studies indicate that renal ammoniagenesis might be regulated at the sites of citrate synthetase (CS) and/or alpha-ketoglutarate dehydrogenase (KGDH). Thus, in chronic metabolic acidosis decreased flux through CS and increased flux through KGDH resulted in enhanced flux through
glutamate dehydrogenase
and glutaminase pathway. The opposite occurred in
alkalosis
. The data suggest that in various acid-base states the rate of renal gluconeogenesis is linearly correlated with malate efflux from the mitochondria. In renal tissue, inhibition occurs at one site of the TCA cycle there is an augmentation of fluxes through pathways beyond that site in order to maintain the respiratory process and the redox state in the mitochondria.
...
PMID:Adaptation of renal tricarboxylic acid cycle metabolism to various acid-base states: study with [3-13C,5-15N]glutamine. 177 Sep 13
The relative significance of the flux through the glutamine aminotransferase (glutaminase II) pathway to renal ammoniagenesis is poorly understood. A basic and unresolved question is whether 2-oxoglutaramate (2-OGM), a product of the glutaminase II reaction, is deamidated to yield 2-oxoglutarate and NH3, or whether 2-OGM accumulates as an unreactive lactam, depending on the environmental pH. In the current studies we utilized 13C n.m.r. as well as 15N n.m.r. as well as 15N n.m.r. to demonstrate that 2-OGM occurs as a lactam, i.e. 5-hydroxypyroglutamate, regardless of the environmental pH. Our additional aims were to determine whether human kidney cells (HK cells) in culture can produce 2-OGM and to ascertain a pH-dependent relationship between NH3 and 2-OGM production from glutamine. We therefore developed an isotope dilution assay for 2-OGM utilizing 5-hydroxy[4-13C,1-15N]pyroglutamate as the labelled species. Incubations of HK cells in minimal essential medium supplemented with 1 mM-[2-15N]glutamine demonstrated significantly higher production of 2-OGM at pH 6.8 and lower production at pH 7.6 compared with pH 7.4. Similarly both 15NH3 and [15N]alanine formation were significantly higher in acute acidosis (pH 6.8) and lower in acute
alkalosis
(pH 7.6) compared with that at physiological pH. Addition of 1 mM-amino-oxyacetate to the incubation medium at pH 7.4 significantly diminished [15N]alanine and 2-OGM production, but the production of 15NH3 via the
glutamate dehydrogenase
pathway was significantly stimulated. The current observations indicate that the glutaminase II pathway plays a minor role and that flux through
glutamate dehydrogenase
is the predominant site for regulation of ammoniagenesis in human kidney.
...
PMID:Analysis and physiological implications of renal 2-oxoglutaramate metabolism. 185 45
The renal proximal tubule contains a variety of biochemical pathways, which can metabolize glutamine, the major substrate for renal ammoniagenesis. The intramitochondrially located phosphate-dependent glutaminase (PDG) pathway, rather than the various cytosolic pathways, appears to play the predominant role in regulating the rate of renal NH3 production. Acute acidosis stimulates NH3 production by activating alpha-ketoglutarate dehydrogenase and secondarily
glutamate dehydrogenase
; whereas the adaptation to chronic metabolic acidosis results primarily from enhanced glutamine transport into the mitochondria and possibly increased activity of PDG. There is no adaptation of ammoniagenesis to chronic respiratory acidosis, because the proximal tubular intracellular pH is not decreased.
Alkalosis
suppresses NH3 formation but the precise mechanism is not clarified. Ammoniagenesis can be modulated independent of acid-base status by a variety of factors including potassium homeostasis, TCA cycle intermediates, hormones which increase cAMP, prostaglandin F2 alpha, insulin, growth hormone, angiotensin II, corticosteroids, aldosterone, and tubular flow rate.
...
PMID:Biochemical pathways and modulators of renal ammoniagenesis. 228 87
To determine if activity of the renal
glutamate dehydrogenase
(GD) pathway changes during chronic acidosis in intact dogs, we assessed the deamination of glutamate formed within renal cells during glutamine and alanine infusions. Infusing glutamine into chronically acidotic, normal and acutely alkalotic dogs enhanced renal ammonia production; more was formed as glutamine loading increased. In 4 acidotic dogs, the ratio of ammonia produced to glutamine extracted by the kidneys during exogenous glutamine loading was 1.93 compared with 0.99 for 5 alkalotic dogs and 1.23 for 2 control dogs. Little glutamate and alanine were released into the renal vein in acidotic dogs, whereas over 50% of the exogenous glutamine extracted in acutely alkalotic dogs could be accounted for as glutamate and alanine released into the renal vein. Renal glutamate concentrations were not elevated in acidosis compared with
alkalosis
despite greater deamidation. When glutamine infusions increased renal ammoniagenesis in acutely alkalotic and control dogs to levels seen in chronically acidotic dogs receiving no exogenous glutamine, approximately 4 to 6 times more glutamate was released from the kidneys. Infusing alanine into 7 chronically acidotic dogs enhanced ammoniagenesis significantly (p less than 0.01), but lesser augmentation was seen in 3 control dogs and no augmentation was seen in 6 acutely alkalotic dogs. The increases were secondary to enhanced glutamate deamination, not secondary to any changes in glutamine extraction and/or transaminase activity. We conclude that the
glutamate dehydrogenase
pathway is more active in intact acidotic dogs than it is in control and alkalotic dogs.
...
PMID:Evidence of activation of the renal glutamate dehydrogenase pathway in intact acidotic dogs. 724 88
The precise mechanism(s) of action of PTH, insulin or glucagon in the regulation of renal glutamine and ammonia metabolism is unknown. Our aim was to delineate the effects and the site(s) of action of these hormones on renal glutamine metabolism. Experiments were carried out using OK cells as a model system. Cell cultures were incubated for three hours in a bicarbonate buffer of pH 7.4 supplemented with either 1 mM [2-15N] or [5-15N] glutamine and 10(-7) M PTH, insulin or glucagon. Comparative studies were performed at pH 6.8, 7.4 or 7.6 without hormone. PTH and acute acidosis significantly stimulated glutamine metabolism via both the phosphate-dependent glutaminase (PDG) and
glutamate dehydrogenase
(GLDH) pathways. The opposite was observed at pH 7.6. Insulin augmented flux via PDG with little effect on the GLDH pathway. Glucagon had insignificant effects on either PDG or GLDH pathways. Intracellular [15N] glutamate formed from [2-15N] glutamine was removed partially by transamination to alanine, aspartate and serine and partially by translocation to an extracellular compartment. Acidosis, PTH and insulin enhanced the formation of [15N] alanine with little effect on [15N] aspartate. PTH, insulin and glucagon significantly stimulated the production of [15N]serine, whereas acidosis had little effect. The translocation of intracellular glutamate was significantly increased by acidosis, PTH and insulin and decreased by acute
alkalosis
. The data indicate that: (a) PTH mimicks the effect of acute acidosis on renal glutamine metabolism, that is, augmented glutamine metabolism through both PDG and GLDH pathways and stimulated the output of intracellular glutamate. This effect might be mediated via decreased activity of the Na(+)-H+ exchanger associated with cellular acidification and/or through a second messenger; (b) insulin, but not glucagon, increased glutamine uptake and metabolism, and simultaneously enhanced output of intracellular glutamate sufficiently to stimulate the PDG pathway; and (c) overall, glucagon had little effect on glutamine metabolism by OK cells compared with either PTH or insulin.
...
PMID:Hormonal regulation of glutamine metabolism by OK cells. 773 Nov 75
In horses with hepatic necrosis, lipidosis, neoplasia and cirrhosis, progression of the disease was studied by serial measurements of total serum bile acid concentrations and of plasma
glutamate dehydrogenase
(GD) and gamma glutamyl transferase (gamma GT) and by liver biopsy. Plasma ammonia concentrations were significantly elevated compared to clinically normal horses, but such changes were not always accompanied by a decline in plasma urea concentration. A fall in plasma glucose concentration carried a guarded prognosis. These were all invaluable aids in early diagnosis and throughout the disease course. The study suggests that other factors, such as hypokalaemia,
alkalosis
, short chain volatile fatty acids, false and true neurotransmitters, may be important in the pathogenesis of hepatic coma in the horse.
...
PMID:Clinical and pathological studies in horses with hepatic disease. 870 47
In cattle with hepatic lipidosis, hepatic abscessation, leptospirosis, biliary calculi or fasciolosis, the progression of the disease was studied by serial measurements of serum total bile acid concentrations, plasma
glutamate dehydrogenase
, gamma-glutamyltransferase, 5'-nucleotidase and leucine aminopeptidase activities Terminalia avicennioides and by liver biopsy. Regardless of the cause of the hepatic disease, weight loss, anorexia, dullness and depression were consistent features. Signs of hepatic encephalopathy, such as blindness, head pressing, excitability, ataxia and weakness were less common and, together with pyrexia and jaundice, were grave prognostic signs. Plasma ammonia concentrations were significantly elevated compared to clinically normal cattle, but such changes were not always accompanied by a decline in plasma urea concentrations. In normal, healthy cattle, the plasma ammonia:urea concentration ratio is 9:1 and the plasma ammonia:glucose concentration is 11:1. In hepatic disease, a plasma ammonia:glucose ratio > 40:1 or plasma ammonia:urea ratio > 30:1, particularly with a rising total ketone body concentration and a declining glucose concentration, carried a guarded prognosis. The study suggested that other factors, such as hypokalaemia,
alkalosis
, short-chain volatile fatty acids, and false and true neuro-transmitters, may be important in the pathogenesis of hepatic coma in cattle.
...
PMID:Clinical and pathological studies in cattle with hepatic disease. 909 45
Exposure to hyperoxia (500-600 torr) or low pH (4.5) for 72 h or NaHCO(3) infusion for 48 h were used to create chronic respiratory (RA) or metabolic acidosis (MA) or metabolic alkalosis in freshwater rainbow trout. During
alkalosis
, urine pH increased, and [titratable acidity (TA) - HCO(-)(3)] and net H(+) excretion became negative (net base excretion) with unchanged NH(+)(4) efflux. During RA, urine pH did not change, but net H(+) excretion increased as a result of a modest rise in NH(+)(4) and substantial elevation in [TA - HCO(-)(3)] efflux accompanied by a large increase in inorganic phosphate excretion. However, during MA, urine pH fell, and net H(+) excretion was 3.3-fold greater than during RA, reflecting a similar increase in [TA - HCO(-)(3)] and a smaller elevation in phosphate but a sevenfold greater increase in NH(+)(4) efflux. In urine samples of the same pH, [TA - HCO(-)(3)] was greater during RA (reflecting phosphate secretion), and [NH(+)(4)] was greater during MA (reflecting renal ammoniagenesis). Renal activities of potential ammoniagenic enzymes (phosphate-dependent glutaminase,
glutamate dehydrogenase
, alpha-ketoglutarate dehydrogenase, alanine aminotransferase, phosphoenolpyruvate carboxykinase) and plasma levels of cortisol, phosphate, ammonia, and most amino acids (including glutamine and alanine) increased during MA but not during RA, when only alanine aminotransferase increased. The differential responses to RA vs. MA parallel those in mammals; in fish they may be keyed to activation of phosphate secretion by RA and cortisol mobilization by MA.
...
PMID:Renal responses of trout to chronic respiratory and metabolic acidoses and metabolic alkalosis. 1044 55
This review focuses on the role of acute pH changes in the regulation of Gln/Glu metabolism in the kidney, liver, and brain. Alterations of proton concentration ([H(+)]) profoundly affect flux through phosphate-dependent glutaminase (PDG) or
glutamate dehydrogenase
(
GDH
), the primary enzymes responsible for mitochondrial metabolism of glutamine and glutamate, respectively. In the kidney, acute acidosis stimulates Gln uptake and its metabolism via the PDG pathway. The Glu formed from Gln can be removed via 1) oxidative deamination through the
GDH
reaction, 2) transamination reactions, and 3) transport of Glu from intracellular to extracellular compartment, thereby diminishing the intramitochondrial pool of glutamate sufficiently to stimulate flux through the PDG pathway. Converse changes may occur with increased pH. In the liver, acidosis diminishes the rate of Gln and Glu metabolism via the PDG and
GDH
pathways, but stimulates glutamine synthesis (i.e., glutamine recycling).
Alkalosis
has little effect. Hepatic Gln metabolism via the PDG pathway has a central role in ureagenesis via 1) supplementation of nitrogen for the synthesis of carbamyl phosphate, and 2) providing glutamate for N-acetylglutamate synthesis. In the brain, Gln/Glu metabolism links ammonia detoxification and energy metabolism via 1) detoxification of ammonia and excess glutamate by glutamine synthesis in astrocytes, 2) formation and export of glutamine to neurons where it is metabolized to glutamate and GABA, and 3) production of alpha-ketoglutarate and lactate from Glu and their transport to neurons. Changes in intracellular pH associated with changes in cellular [K(+)] may have a key role in the regulation of these processes of glial-neuronal metabolism of Gln/Glu metabolism.
...
PMID:Newer aspects of glutamine/glutamate metabolism: the role of acute pH changes. 1051 71
Free ammonium ions are produced and consumed during cell metabolism. Glutamine synthetase utilizes free ammonium ions to produce glutamine in the cytosol whereas glutaminase and
glutamate dehydrogenase
generate free ammonium ions in the mitochondria from glutamine and glutamate, respectively. Ammonia and bicarbonate are condensed in the liver mitochondria to yield carbamoylphosphate initiating the urea cycle, the major mechanism of ammonium removal in humans. Healthy kidney produces ammonium which may be released into the systemic circulation or excreted into the urine depending predominantly on acid-base status, so that metabolic acidosis increases urinary ammonium excretion while metabolic alkalosis induces the opposite effect. Brain and skeletal muscle neither remove nor produce ammonium in normal conditions, but they are able to seize ammonium during hyperammonemia, releasing glutamine. Ammonia in gas phase has been detected in exhaled breath and skin, denoting that these organs may participate in nitrogen elimination. Ammonium homeostasis is profoundly altered in liver failure resulting in hyperammonemia due to the deficient ammonium clearance by the diseased liver and to the development of portal collateral circulation that diverts portal blood with high ammonium content to the systemic blood stream. Although blood ammonium concentration is usually elevated in liver disease, a substantial role of ammonium causing hepatic encephalopathy has not been demonstrated in human clinical studies. Hyperammonemia is also produced in urea cycle disorders and other situations leading to either defective ammonium removal or overproduction of ammonium that overcomes liver clearance capacity. Most diseases resulting in hyperammonemia and cerebral edema are preceded by hyperventilation and respiratory
alkalosis
of unclear origin that may be caused by the intracellular acidosis occurring in these conditions.
...
PMID:Ammonium metabolism in humans. 2292 46
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