EC:1.4.1.2 - FACTA Search

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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)

Xenopus laevis was adapted stepwise to 600 m osmolar sodium chloride. After adaptation, the level of argininosuccinate lyase was raised 9-fold, carbamoylphosphate synthetase 6-fold, and ornithine carbamoyltransferase and arginase 3-fold. Liver glutamate dehydrogenase was also raised 5-fold; kidney glutamate dehydrogenase was unchanged. In Bufo viridis similarly adapted, there was a 5-fold increase in argininosuccinate lyase. When Xenopus laevis was adapted to 600 m osmolar sucrose, there was only an increase in argininosuccinate lyase, and that was only 2.4-fold. This indicates that the increases in urea cycle enzymes are at least in part responses to sodium chloride rather than just to osmotic stress.
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PMID:Urea cycle enzymes and glutamate dehydrogenase in Xenopus laevis and Bufo viridis adapted to high salinity. 709 81

Rainbow trout acclimatized to 9 degrees C were subjected to a temperature increase (up to 17 degrees C) for 16 hrs. During the period of acclimatization to 17 degrees C, we studied blood ammonia and urea and the hepatic activity of glutamate dehydrogenase, glutaminase, uricase and arginase. The daily mean rates of blood ammonia and urea did not differ significantly at 9 and 17 degrees C. However, the pattern of these two parameters during the circadian cycle was not the same at 9 degrees C as after 23 days at 17 degrees C. The enzymatic activities rose after one day at 17 degrees C and remained unchanged, except for arginase which showed perfect thermal compensation. During the circadian cycle, there was some similitude between glutaminase activity and blood ammonia at 9 degrees C and after 23 days at 17 degrees C, as well as between arginase activity and blood urea.
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PMID:[Effect of temperature increase on some aspects of nitrogen catabolism in rainbow trout (Salmo gairdneri Rich.)]. 715 5

Ornithine metabolism is coupled to oxidative phosphorylation in isolated rat liver mitochondria. The pathway involving ornithine: alpha-ketoglutarate transaminase (OKT), glutamic semialdehyde dehydrogenase (GSDH), and glutamate dehydrogenase (GDH) with cycling of alpha-ketoglutarate-glutamate at the OKT reaction appears to be involved. Ornithine may be utilized by this pathway to sustain ATP levels during mitochondrial energy-deficiency states with resultant decreased urea-cycle flux and increased ammonia production. This pathophysiologic mechanism suggests that hyperammonemia is a consequence of an energy-deficiency state. Therapy directed toward alleviating the energy-deficiency state may be more beneficial than efforts to reduce ammonia levels.
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PMID:Urea cycle regulation: I. Coupling of ornithine metabolism to mitochondrial oxidative phosphorylation. 718 96

The purpose of this paper is to investigate the specific metabolism of the protein and amino acid during pregnancy from a standpoint of urea nitrogen recycling hydrolyzed by intestinal bacterial urease of pregnant rat. For this purpose, the activity of urease of the intestinal flora, and L-glutamate dehydrogenase (GDH) in liver mitochondria, the concentration of free ammonia and urea in the intestinal tract, portal vein and right ventricle of the rat were discussed. The results were: 1) The activity of urease moderately increased during pregnancy with the peak on 19th gestational day. 2) The concentration of free ammonia in the intestinal tract elevated slightly, and markedly elevated in portal vein, but seemed to be no specific change in right ventricle. The peak showed on 19th gestational day. 3) The activity of GDH increased markedly during pregnancy, and the protein synthesis was thought to be accelerated. 4) Urea concentration in intestinal tract and blood stream seemed somewhat increased. This results revealed that the urea recycling system and protein synthesis accelerated during pregnancy because of high urease and GDH activity. This phenomenon adapted the pregnant to nutrient of the fetus for growing and development, and introduced a new concept of maternal-fetal unit of nutrition, especially in protein metabolism.
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PMID:[Studies on entero hepatic circulation of urea nitrogen in pregnant rat (author's transl)]. 724 Aug 47

The numerous physiological and nutritional factors which influence the concentration of serum calcium are considered. The causes of hypercalcaemia and hypocalcaemia are briefly discussed, with particular reference to the clinical symptoms and pathology. The effect of the acid-base status on the serum-ionized calcium level is stressed. The causes of changes in the serum concentrations of phosphorus and magnesium are briefly reviewed, along with the abnormalities of lactate, pyruvate, and hydrogen ion concentrations. The kidney function tests, blood urea nitrogen, serum creatinine, and the renal clearance tests are discussed, with emphasis placed on correlating their results with the findings from repeated urinalyses. The important physiologic influences and pathological processes which result in changes in the concentrations of these parameters are delineated. The causes of increases in the serum enzymes, alkaline phosphatase, alanine transaminase, asparate transaminase, lactic dehydrogenase, sorbitol dehydrogenase, glutamic dehydrogenase, gamma glutamyl transpeptidase, creatinine phosphokinase, amylase and lipase are discussed. The changes in serum bilirubin concentration and its components are fully described, with emphasis placed on the correlation of the findings with urinalysis data and the complexities resulting from the numerous pathologic conditions causing jaundice. These conditions are listed for each of the domestic animals. The other liver function tests, bromosulphthalein dye retention or excretion, serum uric acid and blood ammonia concentration are briefly considered. All the tests described are very useful, and frequently essential, in aiding the veterinary practitioner to arrive at a diagnosis and prognosis, but they never replace clinical acumen.
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PMID:Correlation of changes in blood chemistry with pathological changes in the animal's body: II Electrolytes, kidney function tests, serum enzymes, and liver function tests. 727 79

The effects of short- and long-term ethanol administration on the hepatic content of free proline and on the activity of hepatic enzymes that catalyze the formation and degradation of proline were determined in the rat. The short-term oral administration of ethanol in a dose of 5.5 gm/kg body weight resulted in no changes in hepatic free proline content or in hepatic proline oxidase activity. By contrast, the feeding of ethanol for a period of 1 month resulted in an increase in the total hepatic content of free proline. The hepatic activity of proline exidase was also increased by long-term ethanol feeding while the activities of arginase, ornithine aminotransferase, delta 1-pyrroline-5-carboxylate reductase, delta 1-pyrroline-5-dehydrogenase, and glutamate dehydrogenase remained unchanged. The increase in the hepatic pool of free proline in association with an increase in proline oxidase activity suggests that long-term ethanol administration results in an increased turnover of proline in the liver, in which the increase in synthesis is greater than the increase in degradation. An effect of long-term ethanol feeding in increasing proline degradation mya be a cause for the increased oxygen consumption and urea production found in the liver after long-term ethanol ingestion.
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PMID:Effect of ethanol on hepatic proline-metabolizing enzymes in the rat. 729 45

The authors compared three urea nitrogen methods using six instruments: (1) the diacetyl monoxime method used with a continuous flow analyzer Sequential Multiple Analyzer Model 4 + 2; (2) the diacetyl monoxime method used with an older continuous flow analyzer (Sequential Multiple Analyzer Model 6/60; (3) the diacetyl monoxime method used with a third continuous flow system, AutoAnalyzer Model I; (4) the urease-conductivity method performed on the Beckman System I; (5) the urease-glutamate dehydrogenase method performed on the DuPont Automatic Clinical Analyzer; (6) the urease-glutamate dehydrogenase method done on a centrifugal analyzer, CentrifiChem. We evaluated each method for the following: (1) within-run precision; (2) between-day precision; (3) linearity of the relationship between concentration and instrument output; (4) specificity; (5) carry-over; (6) comparison of urea nitrogen values for samples from patients.
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PMID:Evaluation of three methods for the measurement of urea nitrogen in serum as used on six instruments. 736 15

We describe a coupled-enzyme equilibrium method for measuring urea in serum, which is performed on supernates prepared by treating each specimen with Ba(OH)2 and ZnSO4 (Somogyi reagent). Analytical recovery of [14C]urea added to a variety of matrices was essentially complete (mean, 100.6%) for the supernates after precipitation. Nine variables were univariately examined in arriving at the reaction conditions for the method: glutamate dehydrogenase, urease, 2-oxoglutarate, ADP, Tris . HCI, NADH, EDTA, pH, and temperature. The reagent is stable for at least 48 days at--20 degrees C and for 23 days at 4 degrees C. Mean analytical recovery of urea (14 mmol/L) added to seven different specimens (three different matrices) was 100.8%. The analytical linear range of the method extends to 30 mmol of urea per liter. Of 22 potential interferents, only bilirubin at 1 mmol/L (580 mg/L), hemoglobin at 10 g/L, and hydroxyurea at 6 mmol/L showed more than 2% interference. We discuss precision and effects of specimen dilution, and compare results for 100 human serum specimens with those measured for the same specimens with four other urea methods. We examined the effects of measuring a blank, consisting of sample and reagent without urease, with each specimen.
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PMID:A coupled-enzyme equilibrium method for measuring urea in serum: optimization and evaluation of the AACC study group on urea candidate reference method. 737 2

Exposure of rabbits to hashish smoke every other day for a period of one month resulted in a marked increase in blood ammonia. This increase is not probably due to any hepatic damage since there was no concomitant increase in the number of serum enzymes known to be elevated during hepatic damage. It might be related to the inhibitory effect of hashish on incorporation of amino acids into proteins resulting in an increased availability of amino acids to the catabolic pathways coupled with an increase in the glutamate dehydrogenase activity. These factors could also account for the increased blood urea concentrations in these animals.
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PMID:Effect of hashish smoke on some blood and serum parameters in rabbits. 740 46

Urea-induced effects in clostridial glutamate dehydrogenase (GDH, EC 1.4.1.2) were studied by spectrophotometry, circular dichroism, FPLC, affinity chromatography and PAGE. Denaturation of enzyme occurred over a narrow range of urea concentrations (2.5-3.5 M), accompanied by inactivation of enzyme with a similar rate constant. The contribution of instantaneous inhibition by urea was also ascertained. FPLC studies of urea-treated GDH gave no evidence for dissociated oligomeric fragments of the hexamer in the presence of subdenaturing concentrations of urea. Likewise a mixture of fully 5,5'-dithiobis-(2-nitrobenzoic acid)-modified GDH hexamers and unmodified enzyme in 2 M urea failed to give rise to hybrid molecules. Exposure of unmodified GDH to high concentrations of urea led to the dissociation of hexamers to denatured monomers followed by association to form non-specific high-M(r) aggregates. This conclusion was confirmed by native gradient PAGE experiments. Various specific ligands stabilized the enzyme against urea-induced inactivation, succinate and 2-oxoglutarate being particularly effective. This protection of the native state was enhanced in ternary complexes, and the complex most resistant to urea-induced inactivation was the productive ternary complex GDH-NADH-2-oxoglutarate. Native gradient PAGE experiments indicate that these protecting ligands preserve the native hexameric structure of GDH.
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PMID:Urea-induced inactivation and denaturation of clostridial glutamate dehydrogenase: the absence of stable dimeric or trimeric intermediates. 748 49

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