Gene/Protein
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Enzyme
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Target Concepts:
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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)
Carbamoylphosphate
synthase and glutamine synthase show a complementary distribution in the liver lobule of the rat. In the human liver lobule, which is approximately 2-fold larger than that of the rat, an intermediate, 'empty' zone is present between the periportal carbamoylphosphate synthase-positive and the pericentral glutamine synthase-positive zone. To investigate whether these differences in gene expression can be attributed to the size of the liver lobule, we investigated the patterns of expression of carbamoylphosphate synthase, glutamine synthase and
glutamate dehydrogenase
during postnatal development of the pig, a species in which the total number of lobules does not increase after birth. We demonstrate that lobular size increases 3-fold between 1 week and 8 months after birth. In the same developmental period the number of hepatocytes on the porto-central axis increases 2-fold, resulting in a 3-fold increase in cellular volume. However, the lobular patterns of expression of carbamoylphosphate synthase,
glutamate dehydrogenase
and glutamine synthase do not change anymore after 1 month, i.e., when lobular diameter is comparable to that in rat liver, showing that lobular size is not a major determinant of the heterogeneous patterns of expression of these enzymes. The adult patterns of expression of glutamine synthase,
glutamate dehydrogenase
and, in particular carbamoylphosphate synthase in the porcine liver resemble those of man. Changes in the enzyme activities of
glutamate dehydrogenase
and carbamoylphosphate synthase are not related to the lobular size. However, the 70% decrease of GS activity in the 8-month-old pigs corresponds with the gradual 2-3-fold decrease in the size of the GS-positive compartment during postnatal development. During adulthood GS activity increases again to values observed 1 week after birth demonstrating a 2-fold increase in cellular glutamine synthase content. The present data show that the pig is an excellent model to study the regulation and functional implication of zonation of gene expression in the human liver.
...
PMID:Lobular patterns of expression and enzyme activities of glutamine synthase, carbamoylphosphate synthase and glutamate dehydrogenase during postnatal development of the porcine liver. 791 41
This study examines the role of glucagon and insulin in the incorporation of (15)N derived from (15)N-labeled glutamine into aspartate, citrulline and, thereby, [(15)N]urea isotopomers. Rat livers were perfused, in the nonrecirculating mode, with 0.3 mM NH(4)Cl and either 2-(15)N- or 5-(15)N-labeled glutamine (1 mM). The isotopic enrichment of the two nitrogenous precursor pools (ammonia and aspartate) involved in urea synthesis as well as the production of [(15)N]urea isotopomers were determined using gas chromatography-mass spectrometry. This information was used to examine the hypothesis that 5-N of glutamine is directly channeled to
carbamyl phosphate
(CP) synthesis. The results indicate that the predominant metabolic fate of [2-(15)N] and [5-(15)N]glutamine is incorporation into urea. Glucagon significantly stimulated the uptake of (15)N-labeled glutamine and its metabolism via phosphate-dependent glutaminase (PDG) to form U(m+1) and U(m+2) (urea containing one or two atoms of (15)N). However, insulin had little effect compared with control. The [5-(15)N]glutamine primarily entered into urea via ammonia incorporation into CP, whereas the [2-(15)N]glutamine was predominantly incorporated via aspartate. This is evident from the relative enrichments of aspartate and of citrulline generated from each substrate. Furthermore, the data indicate that the (15)NH(3) that was generated in the mitochondria by either PDG (from 5-(15)N) or
glutamate dehydrogenase
(from 2-(15)N) enjoys the same partition between incorporation into CP or exit from the mitochondria. Thus, there is no evidence for preferential access for ammonia that arises by the action of PDG to
carbamyl-phosphate
synthetase. To the contrary, we provide strong evidence that such ammonia is metabolized without any such metabolic channeling. The glucagon-induced increase in [(15)N]urea synthesis was associated with a significant elevation in hepatic N-acetylglutamate concentration. Therefore, the hormonal regulation of [(15)N]urea isotopomer production depends upon the coordinate action of the mitochondrial PDG pathway and the synthesis of N-acetylglutamate (an obligatory activator of CP). The current study may provide the theoretical and methodological foundations for in vivo investigations of the relationship between the hepatic urea cycle enzyme activities, the flux of (15)N-labeled glutamine into the urea cycle, and the production of urea isotopomers.
...
PMID:Studies of hepatic glutamine metabolism in the perfused rat liver with (15)N-labeled glutamine. 1050 42
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
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