Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0038187 (starvation)
24,951 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Factors contributing to modifications in the capability for enzyme adaptation as an expression of aging are reviewed. Specific examples of altered enzyme adaptations during aging include the responses of hepatic glucokinase activity to glucose and hepatic tyrosine aminotransferase activity to starvation in Sprague-Dawley rats. These impaired enzyme adaptations apparently are not the consequence of alterations in hepatic function during aging. Instead, they reflect disturbances in extrahepatic hormonal regulatory mechanisms. Specific examples include modifications in the control of circulating levels of insulin glucagon, corticosteroids, and thyroid hormones. Age-dependent changes in the regulation of circulating levels of insulin probably originate within the impaired ability of pancreatic islets of Langerhans to secrete the hormone in response to glucose. The rationale for exploiting this experimental approach as a means to understand biological aging is discussed.
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PMID:Loss of adaptive mechanisms during aging. 3 73

The conversion of glucose into glucose 6-phosphate in an extract of isolated rat hepatocytes incubated in the presence of MgATP was studied spectrophotometrically at 340nm and also by a radiochemical procedure based on the release of (3)H from [2-(3)H]glucose. Both methods gave similar results. The glucose-saturation curve was sigmoidal and the shape of this curve was not influenced by the ionic composition of the incubation medium. The activity at 0.5mm-glucose was only 1-2% of V(max.), indicating a virtual absence of low-K(m) hexokinase in the preparation. The radiochemical method was also used for the determination of glucose phosphorylation by intact hepatocytes. The glucose-saturation curve was also markedly sigmoidal, but the s(0.5) (substrate concentration at half-maximal velocity) and the Hill coefficient were larger than in extracts of hepatocytes. These two parameters became smaller when cells were incubated in a medium in which Na(+) ions were replaced by K(+) ions. The increased rate of phosphorylation at low glucose concentration in a K(+) medium was accompanied by an increased rate of metabolite recycling between glucose and glucose 6-phosphate and also by an increased uptake of glucose. In both media phosphorylation of glucose was inhibited co-operatively by N-acetylglucosamine. Calculations indicate that this inhibition would reach 100% at saturation of the inhibitor, although at lower concentrations of N-acetylglucosamine it was smaller than expected from the known K(i) of N-acetylglucosamine for glucokinase. The rate of phosphorylation of glucose was proportional to the amount of glucokinase in hepatocytes from newborn rats and in conditions such as starvation and diabetes in which the total amount of glucokinase in the liver is decreased. In the same conditions, glucose 6-phosphatase activity was either normal or increased. It is concluded that the phosphorylation of glucose in isolated hepatocytes follows sigmoidal kinetics, which can be explained by the activity of glucokinase alone with no participation of low-K(m) hexokinase or of glucose 6-phosphatase.
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PMID:Phosphorylation of glucose in isolated rat hepatocytes. Sigmoidal kinetics explained by the activity of glucokinase alone. 21 56

We have cloned a full-length cDNA for rat-liver-type phosphofructokinase. The similarities of the rat liver-type phosphofructokinase mRNA to the human and mouse counterparts were 94% and 99% in their amino acid sequences and 88% and 94% in the nucleotide sequences of their coding regions, respectively. Rat liver-type phosphofructokinase mRNA was expressed in all tissues examined, but its level was regulated tissue-specifically. The nutritional and hormonal regulations of the mRNA in the liver were examined in comparison with those of two other key glycolytic enzymes, glucokinase and L-type pyruvate kinase. The level of liver-type phosphofructokinase mRNA was essentially unchanged by starvation (72 h) or diabetes. The mRNA level also did not change significantly on refeeding starved rats on a high carbohydrate diet, or treating diabetic ones with insulin. These results suggested that rat liver-type phosphofructokinase mRNA in the liver was not under control of diet or insulin, in contrast to glucokinase and L-type pyruvate kinase.
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PMID:Rat-liver-type phosphofructokinase mRNA. Structure, tissue distribution and regulation. 183 95

Glucokinase (EC 2.7.1.2) is the signal-recognition enzyme in pancreatic B-cells for initiation of glucose-induced insulin secretion. We show here that both the glucokinase and glucose-transporter GLUT-2 genes are regulated physiologically. Fasting decreased B-cell glucokinase and glucose-transporter GLUT-2 mRNA in pancreatic B-cells as well as in liver, whereas refeeding induced expression of both genes. In pancreatic B-cells a approximately 4.4 kb glucokinase-related mRNA was detectable, in addition to the 2.8 kb form. This approximately 4.4 kb glucokinase transcript was drastically decreased during refeeding. The 2.8 kb mRNA, which is typical for pancreatic B-cells, was accompanied after refeeding by a 2.4 kb mRNA species typical for liver glucokinase. Starvation primarily decreased the 2.8 kb pancreatic B-cell glucokinase mRNA species. The concordant regulation of both genes may represent the basis for the physiological regulation of glucose-induced insulin secretion at a transcriptional level.
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PMID:Regulation of glucokinase and GLUT-2 glucose-transporter gene expression in pancreatic B-cells. 195 86

In the liver postmicrosomal supernatant of starved rats, the high-Km glucose-phosphorylating enzymic activity, presumably attributable to glucokinase, is not solely decreased but also displays an apparently lower affinity and less pronounced temperature dependency than in fed rats. In the presence of exogenous D-glucose 6-phosphate and D-fructose 6-phosphate, the rate of D-glucose phosphorylation is enhanced by D-fructose 1-phosphate at low (10 mM) but not high (90 mM) hexose concentration and at high (30-37 degrees C) but not low (10 degrees C) temperature. The responsiveness of glucokinase to D-fructose 1-phosphate is apparently decreased in starved animals. Nevertheless, the latter ester does not suppress the starvation-induced alteration in both the apparent affinity and temperature dependency of liver glucokinase. It is proposed, therefore, that such an alteration may reflect changes in the intrinsic properties of the high-Km hepatic enzyme.
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PMID:Kinetic behaviour of liver glucokinase in insulinopenic situations: effect of fructose 1-phosphate in fed and starved rats. 207 89

Thyroid hormones act at the transcriptional level in the induction of the important hepatic glucoregulatory enzyme PEP-carboxykinase and glucokinase (Fig. 1 and Fig. 2). They have no significant effect on the degradation of both enzymes, nor on the degradation of the specific mRNAs. A T3-receptor interaction is essential for their effect. Suggestions have been made for a thyroid hormone regulatory element in the promotor region of T3-dependent genes (for a review see [18]). Thyroid hormones probably do not determine the direction of the metabolic flux; however, they significantly enhance in a permissive way the transition from one state, e.g. starvation, to another, e.g. refeeding. And by enhancing significantly the activity of important regulatory enzymes, they enhance the flux of metabolites under different metabolic conditions, such as in starvation or after refeeding.
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PMID:Role of thyroid hormones in the regulation of hepatic glucokinase and phosphoenolpyruvate-carboxykinase gene expression during the starvation-refeeding transition. 208 92

Food intake, plasma glucose, insulin (I) and glucagon (G), hepatic glycogen and fructose 2,6-bisphosphate (F-2, 6-P2) and liver glucokinase, glucose 6-phosphatase (G6-Pase), 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase (6-PF-2 kinase/F-2, 6-P2ase), pyruvate kinase (PK-L) and phosphoenolpyruvate carboxykinase (PEPCK) activities were measured in 2 and 22-month-old rats before 3 d starvation and after 2, 4, 6, 24 and 48 h refeeding a high carbohydrate (HC, 74% w/w) diet. Expressed per 100 g of body weight, the food intake of old rats was 55% lower than that of young rats and the amount of carbohydrate absorbed hourly during the first 6 h of refeeding was 2.4-fold higher in young than in old rats. During the first 6 h of refeeding plasma glucose increased 2-fold and returned to normal values after 24 h in young rats, while plasma glucose did not change during refeeding in old rats. In young rats [I] fell by 85% after starvation and returned to normal values 2 h after refeeding. [I] was higher in old than in young rats; it decreased by 40% after starvation and returned to the basal value 4 h after refeeding. No marked changes were observed in plasma [G] in both groups. No difference was observed in hepatic glycogen in the two groups, while F-2, 6-P2 was higher in old than in young rats. In young rats, the opposite changes in liver glucokinase and G6-Pase activities occurring after starvation and during refeeding were
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PMID:Age-dependent glycolysis and gluconeogenesis enzyme activities in starved-refed rats. 208 82

Thyroid hormones contribute to the regulation of blood sugar by accelerating the turnover of glucose. The mechanism by which thyroid hormones stimulate the rate of glucose utilization in the liver was determined by investigating the effect of different thyroid states on the expression of the glucokinase gene, a key enzyme of glycolysis. In euthyroid rats the mass of glucokinase mRNA increased 8-fold during the first 4 h of refeeding a high carbohydrate diet to 48-h starved rats. In hypothyroid rats under the same conditions only a 2-fold induction was observed. In euthyroid rats a 5-fold increase was obtained 1 h after refeeding, while hypothyroid rats displayed no significant response in glucokinase mRNA within this time. Basal levels of glucokinase mRNA in starved rats were the same observed in eu- and hypothyroid rats. Injection of 3,3',5-triiodothyronine (T3) into hypothyroid rats restored the mRNA levels of refed hypothyroid rats to euthyroid levels within 24 h. However, a 3-fold increase over untreated animals was already observed 3 h after T3 administration. Even subphysiological doses of T3 (0.1 microgram/100 g body weight) led to an significant increase in glucokinase mRNA levels (1.5-fold, p less than 0.05) in hypothyroid rats, whereas higher doses (100 micrograms/100 g body weight) restored the mRNA levels to those of euthyroid controls. Parallel increases in the cytosolic mRNA levels and rate of glucokinase gene transcription were detected when hypo- and euthyroid fasted rats were compared after 4 h of refeeding. It is concluded that thyroid hormones are permissive for the induction of glucokinase during refeeding but have no effect during starvation. They rapidly enhance the rate of gene transcription within the range of their physiologically circulating concentrations. The results suggest a major importance of thyroid hormones in regulating glucose utilization.
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PMID:Effect of thyroid hormones on glucokinase gene transcription in rat liver. 258 35

During refeeding after a brief period of starvation, glucose carbon is deposited into hepatic glycogen by both a direct and an indirect route. In the indirect route glucose is first metabolized to 3-carbon precursors, which then transverse the gluconeogenic pathway before being deposited into glycogen. Recent studies have yielded widely different estimates of the percentage of glucose carbon that follows the indirect route. Work summarized here demonstrates that the relative contributions of glucose carbon to hepatic glycogen formation by the indirect and direct pathways are greatly dependent on experimental design, and at least in vitro, are possibly dependent on the extent of glycogen/glucose 1-P recycling. Under physiological refeeding conditions in vivo, both pathways are used, each contributing approximately 50% of the amount of carbon appearing in glycogen. The level of glucokinase activity does not appear to be responsible for poor glucose utilization in liver. Poor glucose utilization in isolated liver preparations may result from the absence of a neurophysiological feedback loop that senses the arterial/portal glucose gradient and then regulates whole liver glucose uptake.
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PMID:Indirect versus direct routes of hepatic glycogen synthesis. 267 99

The liver is the "glucostat" of the organism and serves at the same time as an "ammonia-sink and pH stat". The key enzymes involved in glucose uptake and release and in urea and glutamine formation are reciprocally distributed over the liver parenchyma: The glucogenic enzymes phosphoenolpyruvate carboxykinase (PEPCK), fructosebisphosphatase (FBPase) and glucose-6-phosphatase (G6Pase) as well as the ureagenic enzyme carbamoylphosphate synthetase (CAPS) are predominant in the periportal zone. The glycolytic enzymes glucokinase (GK) and pyruvate kinase type L (PKL) as well as the glutaminogenic enzyme glutamine synthetase (GluNS) are prevalent in the perivenous zone. This heterogeneity appears to be a prerequisite for the normal "glucostat, ammonia-sink and pH-stat" function of the liver. After birth the liver is a gluconeogenic organ, only with weaning it becomes a "glycolytic/gluconeogenic" glucostat. In the rat zonation of PEPCK, G6Pase and CAPS developed gradually after birth and was completed before weaning, i.e. before it would be functionally required. After 2/3 partial hepatectomy the liver looses its normal glucostat function and becomes a gluconeogenic organ. With this change the zonation of PEPCK and PKL were also lost; it was restored only during the second week after operation. During starvation the liver also looses its glucostat function to become the major glucose supplier of the organism. Zonation of PEPCK and PKL were diminished to such an extent that the major function of the perivenous zone was altered from glucose uptake to release. In diabetes the liver does not loose its glucostat function; however, the function is severely impaired. Zonation of PEPCK was increased and that of PKL decreased in such a manner that the major function of the perivenous zone, glucose uptake, was not entirely changed but only diminished. It can be concluded that in the various physiological states studied the zonation of enzymes correlated well with the glucostat function of the liver.
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PMID:Dynamics of zonal hepatocyte heterogeneity. Perinatal development and adaptive alterations during regeneration after partial hepatectomy, starvation and diabetes. 301 Mar 76


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