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Query: UMLS:C0011849 (
diabetes
)
277,896
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
1. Liver possesses a unique isozyme of phosphate activated
glutaminase
which is subject to long-term regulation. 2. In the rat streptozotocin-
diabetes
results in a 4-fold increase in the rate of transcription of the rat hepatic
glutaminase
gene. 3. This is consistent with previous reports from this laboratory of increases, of similar magnitude, in the relative abundance of hepatic
glutaminase
mRNA (Smith and Watford (1990) J. Biol. Chem. 265, 10631-10636), and enzyme activity (Watford, et al. (1984) Biochem. J. 224, 207-214). 4. The work establishes that, in contrast to the regulation of renal
glutaminase
where mRNA stability plays an important role, the predominant site of long-term regulation of hepatic
glutaminase
is at the level of gene transcription.
...
PMID:Transcriptional regulation of the hepatic glutaminase gene in the streptozotocin-diabetic rat. 817 61
Glutamine functions as a major transport form of nitrogen and carbon within the body. In the liver, glutamine is hydrolyzed by a unique liver-type, phosphate-activated glutaminase, and the end products of hepatic glutamine catabolism are glucose and urea. Other tissues possess a different, kidney-type,
glutaminase
isozyme. The predicted amino acid sequences for the two glutaminases show a high degree of identity, indicating that they are products of different but related genes. Hepatic
glutaminase
activity is increased during
diabetes
, starvation, and on feeding high-protein diets, and decreased on feeding low-protein diets, whereas renal
glutaminase
appears to be regulated only by changes in acid-base status. Changes in the rate of gene transcription are the principal mechanism responsible for the long-term regulation of hepatic
glutaminase
, but the renal enzyme is regulated at the level of mRNA turnover. The pattern of regulation of hepatic
glutaminase
parallels that seen for genes encoding key enzymes of gluconeogenesis and urea synthesis, and indicates coordinate regulation of expression in keeping with the role of hepatic glutamine catabolism in these pathways.
...
PMID:Hepatic glutaminase expression: relationship to kidney-type glutaminase and to the urea cycle. 826 31
Glutamine is synthesized primarily in skeletal muscle, lungs, and adipose tissue. Plasma glutamine plays an important role as a carrier of nitrogen, carbon, and energy between organs and is used for hepatic urea synthesis, for renal ammoniagenesis, for gluconeogenesis in both liver and kidney, and as a major respiratory fuel for many cells. The catabolism of glutamine is initiated by either of two isoforms of the mitochondrial
glutaminase
. Liver-type
glutaminase
is expressed only in periportal hepatocytes of the postnatal liver, where it effectively couples ammonia production with urea synthesis. Kidney-type
glutaminase
is abundant in kidney, brain, intestine, fetal liver, lymphocytes, and transformed cells, where the resulting ammonia is released without further metabolism. The two isoenzymes have different structural and kinetic properties that contribute to their function and short-term regulation. Although there is a high degree of identity in amino acid sequences, the two glutaminases are the products of different but related genes. The two isoenzymes are also subject to long-term regulation. Hepatic
glutaminase
is increased during starvation,
diabetes
, and feeding a high-protein diet, whereas kidney-type
glutaminase
is increased only in kidney in response to metabolic acidosis. The adaptations in hepatic
glutaminase
are mediated by changes in the rate of transcription, whereas kidney-type
glutaminase
is regulated at a posttranscriptional level.
...
PMID:Regulation of glutaminase activity and glutamine metabolism. 852 15
The liver of diabetic animals removes increased quantities of glutamine. We therefore examined factors that affect hepatic
glutaminase
activity in hepatocytes and mitochondria. Glutamine use, through
glutaminase
, was measured in isolated rat hepatocytes by monitoring the production of 14CO2 from [1-(14)C]glutamine. Hepatocytes from streptozotocin-induced diabetic rats use glutamine more rapidly than do hepatocytes from normal or insulin-maintained diabetic rats. Glutamine use in all of these hepatocytes was stimulated by glucagon and epinephrine. Glutaminase activity, assayed in broken mitochondrial membranes, was increased approximately 2.5-fold in diabetic rats. The sensitivity of
glutaminase
, measured in intact liver mitochondria, to phosphate was markedly left-shifted in mitochondria from diabetic rats compared with those from controls. In fact,
glutaminase
was increased 10-fold at 2.5 mmol/l phosphate compared with controls. This increased sensitivity of
glutaminase
to physiological concentrations of phosphate is characteristic of its hormonal activation. Therefore, activation of
glutaminase
plays a major role in
diabetes
and is as important as increases in its total enzyme amount in determining the increased glutamine uptake in
diabetes
.
Diabetes
1997 Dec
PMID:Regulation of hepatic glutaminase in the streptozotocin-induced diabetic rat. 939 78
The liver shows net glutamine uptake after a protein-containing meal, during uncontrolled
diabetes
, sepsis and short-term starvation, but changes to net release during long-term starvation and metabolic acidosis. Some studies report a small net release of glutamate by the liver. The differential expression of glutamine synthetase (perivenous) and
glutaminase
(periportal) within the liver indicates that glutamine is used for urea synthesis in periportal cells, whereas glutamine synthesis serves to detoxify any residual ammonia in perivenous cells. Experiments in vivo suggest that changes in net hepatic glutamine balance are due predominantly to regulation of
glutaminase
activity, with the flux through glutamine synthetase being relatively constant.
...
PMID:Glutamine and glutamate metabolism across the liver sinusoid. 1073 66
Whether on the scale of a single cell, organ or organism, glutamine homeostasis is to a large extent determined by the activities of
glutaminase
(GA,
EC 3.5.1.2
) and glutamine synthetase (GS, EC 6.3.1.2), the two enzymes that are the focus of this report. GA and GS each provide examples of regulation of gene expression at many different levels. In the case of GA, two different genes (hepatic- and kidney-type GA) encode isoforms of this enzyme. The expression of hepatic GA mRNA is increased during starvation,
diabetes
and high protein diet through a mechanism involving increased gene transcription. In contrast, the expression of kidney GA mRNA is increased post-transcriptionally by a mechanism that increases mRNA stability during acidosis. We found recently that several isoforms of rat and human kidney-type GA are formed by tissue-specific alternative RNA splicing. Although the implications of this post-transcriptional processing mechanism for GA activity are not yet clear, it allows for the expression of different GA isoforms in different tissues and may limit the expression of GA activity in muscle tissues by diverting primary RNA transcripts to a spliceform that produces a nonfunctional translation product. The expression of GS enzyme is also regulated by both transcriptional and post-transcriptional mechanisms. For example, the GS gene is transcriptionally activated by glucocorticoid hormones in a tissue-specific fashion. This hormonal response allows GS mRNA levels to increase in selected organs during catabolic states. However, the ultimate level of GS enzyme expression is further governed by a post-transcriptional mechanism regulating GS protein stability. In a unique form of product feedback, GS protein turnover is increased by glutamine. This mechanism appears to provide a means to index the production of glutamine to its intracellular concentration and, therefore, to its systemic demand. Herein, we also provide experimental evidence that GS protein turnover is dependent upon the activity of the 26S proteosome.
...
PMID:Mechanisms governing the expression of the enzymes of glutamine metabolism--glutaminase and glutamine synthetase. 1153 95
Expression of high activities of both glutamine synthetase and
glutaminase
allows the liver to play a major role in the regulation of glutamine homeostasis. The liver shows net glutamine output in metabolic acidosis, in prolonged starvation and animals bearing tumors, net glutamine uptake in the postabsorptive state, on consuming high protein diets, and in uncontrolled
diabetes
or sepsis. Liver glutamine synthetase is expressed only in a small population of perivenous cells that allows it to salvage any ammonia not incorporated into urea in periportal cells. Hepatic
glutaminase
is a unique isozyme found only in periportal liver parenchymal cells where it provides glutamate and ammonia for the urea cycle. Control of hepatic glutamine metabolism occurs almost exclusively through changes in the activity of
glutaminase
, with no change in glutamine synthetase flux.
...
PMID:Hepatic glutamine metabolism. 1193 40
We studied in rats the expression of genes involved in gluconeogenesis from glutamine and glycerol in the small intestine (SI) during fasting and
diabetes
. From Northern blot and enzymatic studies, we report that only phosphoenolpyruvate carboxykinase (PEPCK) activity is induced at 24 h of fasting, whereas glucose-6-phosphatase (G-6-Pase) activity is induced only from 48 h. Both genes then plateau, whereas
glutaminase
and glycerokinase strikingly rebound between 48 and 72 h. The two latter genes are fully expressed in streptozotocin-diabetic rats. From arteriovenous balance and isotopic techniques, we show that the SI does not release glucose at 24 h of fasting and that SI gluconeogenesis contributes to 35% of total glucose production in 72-h-fasted rats. The new findings are that 1) the SI can quantitatively account for up to one-third of glucose production in prolonged fasting; 2) the induction of PEPCK is not sufficient by itself to trigger SI gluconeogenesis; 3) G-6-Pase likely plays a crucial role in this process; and 4)
glutaminase
and glycerokinase may play a key potentiating role in the latest times of fasting and in
diabetes
.
...
PMID:Induction of control genes in intestinal gluconeogenesis is sequential during fasting and maximal in diabetes. 1455 23
Frank metabolic acidosis is known to promote renal excretion of hydrogen ion by induction of
glutaminase
and other enzymes in the renal tubules. This induction, at least in part, reflects an increase in pituitary output of ACTH and a consequent increased production of cortisol and aldosterone; these latter hormones act on the renal tubules to promote generation of ammonia, which expedites renal acid excretion. Recent evidence suggests that the moderate metabolic acidosis associated with a protein-rich diet low in organic potassium salts - quantifiable by net acid output in daily urine - can likewise evoke a modest increase in cortisol production. Since cortisol promotes development of visceral obesity, and has a direct negative impact on insulin function throughout the body, even a modest sustained up-regulation of cortisol production may have the potential to increase risk for insulin resistance syndrome and type 2 diabetes. This thesis appears to be consistent with previous epidemiological reports correlating high potassium consumption, or a high intake of fruits and vegetables, with reduced risk for
diabetes
and coronary disease. Future prospective epidemiology should assess whether the estimated acid-base balance of habitual diets - calculated from the ratio of dietary protein and potassium - correlates with risk for insulin resistance syndrome and
diabetes
.
...
PMID:Acid-base balance may influence risk for insulin resistance syndrome by modulating cortisol output. 1560 73
Several studies have shown impairment of neutrophil function, a disorder that contributes to the high incidence of infections in
diabetes
. Since glucose and glutamine play a key role in neutrophil function, we investigated their metabolism in neutrophils obtained from the peritoneal cavity of streptozotocin-induced diabetic rats. The activities of hexokinase, glucose-6-phosphate dehydrogenase (G6PDH), phosphofructokinase (PFK), citrate synthase, phosphate-dependent glutaminase, NAD+-linked and NADP+-linked isocitrate dehydrogenase were assayed. Glucose, glutamine, lactate, glutamate and aspartate, and the decarboxylation of [U-14C], [1-14C] and [6-14C]glucose; [U-14C]palmitic acid; and [U-14C]glutamine were measured in 1-h incubated neutrophils. Phagocytosis capacity and hydrogen peroxide (H2O2) production were also determined. All measurements were carried out in neutrophils from control, diabetic and insulin-treated (2-4 IU/day) diabetic rats. Phagocytosis and phorbol myristate acetate (PMA)-stimulated H2O2 production were decreased in neutrophils from diabetic rats. The activities of G6PDH and
glutaminase
were decreased, whereas that of PFK was raised by the diabetic state. The activities of the remaining enzymes were not changed.
Diabetes
decreased the decarboxylation of [1-14C]glucose and [U-14C]glutamine; however, [6-14C]glucose and [U-14C]palmitic acid decarboxylation was increased. These observations indicate that changes in metabolism may play an important role in the impaired neutrophil function observed in
diabetes
. The treatment with insulin abolished the changes induced by the diabetic state even with no marked change in glycemia. Therefore, insulin may have a direct effect on neutrophil metabolism and function.
...
PMID:Diabetes causes marked changes in function and metabolism of rat neutrophils. 1646 55
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