EC:3.1.3.9 - FACTA Search

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Query: EC:3.1.3.9 (glucose-6-phosphatase)
3,081 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Substrate cycles (SC) are formed by a 'forward pathway' (FP) and a 'backward pathway' (BP), the difference between FP and BP forming the 'metabolic flux' (MF) through the route of which the cycle is part. SC modulate regulatory effects, i.e. amplify or reduce the % change in MF compared to the % change in FP and BP, thus affecting the sensitivity to regulatory factors, including hormones. A formula is given to calculate (with an approximation of +/- 0.5) the 'flux response index' (FRI), i.e. the factor by which the % change in FP plus the % change in BP must be multiplied to obtain the % change in metabolic flux, when FP and BP undergo opposite, non-unidirectional changes (as is often the case in metabolic regulation). The formula is: FRI = [( FP + BP)/(FP-BP)]/2. By this formula we evaluated the hepatic activities of glucose-6-phosphatase and glucokinase (which roughly reflect hepatic glucose production and uptake, respectively), i.e. the two enzymes that catalyze the cycle between glucose-6-phosphate (glucose-6-P) and glucose. Based on data obtained in normal, nonobese diabetic and obese diabetic subjects as well as in normal, streptozotocin-diabetic, and obese diabetic (ob/ob) mice, we found that FRI was reduced in non-obese diabetic humans and animals whereas it was increased in obese-diabetic humans and mice, compared to normal controls. Thus, diabetes without obesity decreases, and obesity with diabetes increases, the sensitivity of the glucose-6-P/glucose cycle to regulatory agents.
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PMID:A formula for quantifying the effects of substrate cycles (futile cycles) on metabolic regulation. Its application to glucose futile cycle in liver as studied by glucose-6-phosphatase/glucokinase determinations. 215 82

Effects of pioglitazone (5-[4-[2-(5-etyl-2-pyridyl)ethoxy] benzyl]-2,4-thiazolidinedione, AD-4833, also known as U-72, 107E) on peripheral and hepatic insulin resistance were examined using genetically obese-hyperglycemic rats, Wistar fatty. Pioglitazone was administered to fatty rats (3 mg/kg/d) and lean rats (10 mg/kg/d) for 6 days. Pioglitazone decreased hyperglycemia and hypertriglyceridemia without affecting hyperinsulinemia in the fatty rats, and significantly reduced plasma levels of triglyceride and insulin without altering normoglycemia in the lean rats. The same rats were subjected to an isotopic method combined with a euglycemic clamp technique for assessing insulin sensitivity in hepatic glucose production (HGP) and peripheral glucose utilization (PGU). HGP decreased and PGU increased in response to infused insulin in the lean rats but did not in the fatty rats, indicating that insulin resistance was present in the liver and peripheral tissues of the fatty rats. Treatment with pioglitazone restored the responses of HGP and PGU to infused insulin in the fatty rats, but did not produce any changes in the lean rats. When the same levels of glycemia and insulinemia were established by 480 mU/h of insulin in both treated and control fatty groups, PGU was 1.5-fold higher and HGP was 3-fold lower in the pioglitazone treated group. Pioglitazone also corrected the abnormality in hepatic enzyme regulation by insulin of the fatty rats: glucose-6-phosphatase decreased and glucokinase increased, suggesting the increased response of the liver to insulin and the resultant suppression of HGP. Therefore, pioglitazone is expected to be useful for treating abnormal glucose and lipid metabolism in non-insulin-dependent diabetes mellitus through reducing insulin resistance of the peripheral tissues and liver.
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PMID:Effects of pioglitazone on hepatic and peripheral insulin resistance in Wistar fatty rats. 219 15

We established that measurement of glucose fluxes through glucose-6-phosphatase (G-6-Pase; hepatic total glucose output, HTGO), glucose cycling (GC), and glucose production (HGP), reveals early diabetogenic changes in liver metabolism. To elucidate the mechanism of the diabetogenic effect of glucocorticoids, we treated eight healthy subjects with oral dexamethasone (DEX; 15 mg over 48 h) and measured HTGO with [2-3H]glucose and HGP with [6-3H]glucose postabsorptively and during a 2-h glucose infusion (11.1 mumol.kg-1.min-1). [2-3H]- minus [6-3H]glucose equals GC. DEX significantly increased plasma glucose, insulin, C peptide, and HTGO, while HGP was unchanged. In controls and DEX, glucose infusion suppressed HTGO (82 vs. 78%) and HGP (87 vs. 91%). DEX increased GC postabsorptively (three-fold) P less than 0.005 and during glucose infusion (P less than 0.05) but decreased metabolic clearance and glucose uptake (Rd), which eventually normalized, however. Because DEX increased HTGO (G-6-Pase) and not HGP (glycogenolysis + gluconeogenesis), we assume that DEX increases HTGO and GC in humans by activating G-6-Pase directly, rather than by expanding the glucose 6-phosphate pool. Hyperglycemia caused by peripheral effects of DEX can also contribute to an increase in GC by activating glucokinase. Therefore, measurement of glucose fluxes through G-6-Pase and GC revealed significant early effects of DEX on hepatic glucose metabolism, which are not yet reflected in HGP.
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PMID:Dexamethasone increases glucose cycling, but not glucose production, in healthy subjects. 224 Feb 1

To determine the diabetogenic effect(s) of thyroid hormones, we simultaneously measured glucose turnover in six hyperthyroid patients and six normal subjects. All had normal fasting blood glucose concentration and oral glucose tolerance test values. We determined hepatic total glucose output (HTGO) and total glucose phosphorylation with [2-3H]glucose and hepatic glucose production (HGP) and irreversible glucose uptake using [6-3H]glucose. The difference between the two turnover rates indicates the extent of hepatic glucose cycling (glucose in equilibrium glucose-6-phosphate). Measurements were made both in the postabsorptive steady state and during a 2-h glucose infusion (11.1 mumol/kg.min). The postabsorptive HTGO and total glucose phosphorylation were increased in the hyperthyroid patients [13.5 +/- 0.8 (+/- SE) vs. 11.3 +/- 0.4 mumol/kg.min; P less than 0.05]. HGP and irreversible glucose uptake also were slightly but not significantly higher. During the glucose infusion, HTGO and HGP were less suppressed in the hyperthyroid patients than in the normal subjects, while the increments in peripheral glucose uptake were normal. In hyperthyroidism, glucose cycling was increased both postabsorptively (2.35 +/- 0.27 vs. 1.17 +/- 0.25 mumol/kg.min; P less than 0.025) and during glucose infusion (2.57 +/- 0.34 vs. 1.31 +/- 0.35 mumol/kg.min; P less than 0.05). We conclude that increases in HTGO and HGP are important features of hyperthyroidism, especially during glucose infusion. The increase in GC indicates increased activities of both glucokinase and glucose-6-phosphatase. The diabetogenic effect of hyperthyroidism, as revealed most markedly by [2-3H]glucose, could be accounted for by augmented glucose production, possibly due to increased glucose-6-phosphatase activity.
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PMID:Glucose turnover in hyperthyroid patients with normal glucose tolerance. 253 42

The present studies were designed to clarify the contribution of the liver to the development of hyperglycemia in Wistar fatty rats. The hepatic activities of insulin-inducible enzymes involved in glycolysis (glucokinase; GK and pyruvate kinase) and lipogenesis (glucose-6-phosphate dehydrogenase), were higher in fatty rats than in lean rats at 4 and 8 weeks of age because of the higher insulin levels in the former. Thereafter, the GK activities of fatty rats decreased slightly in spite of severe hyperinsulinemia, and did not differ from those of lean rats. In addition, fatty rats had higher levels of insulin-suppressible gluconeogenic enzymes, glucose-6-phosphatase (G6Pase) and fructose-1, 6-diphosphatase. These findings indicate that the hepatic enzymes of fatty rats are resistant to insulin. This postulation was supported by the fact that the hepatic enzyme activities of fatty rats showed a lower response to changes in plasma insulin levels produced by fasting and refeeding. The G6Pase/GK ratio, which indicates net glucose handling in the liver, increased in fatty rats and decreased in lean rats with advancing age, suggesting that hepatic glucose production in fatty rats becomes dominant with advancing age. The changes in hepatic glycolytic intermediates supported this suggestion; the glycolytic steps both from glucose to glucose-6-phosphate and from phospho-enolpyruvate to pyruvate in fatty rats were accelerated at 5 weeks of age, but suppressed at 12 weeks of age. These results indicate that insulin resistance in the hepatic enzyme regulation may contribute to the development of hyperglycemia in Wistar fatty rats.
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PMID:Pathogenesis of hyperglycemia in genetically obese-hyperglycemic rats, Wistar fatty: presence of hepatic insulin resistance. 254 49

In mice with streptozotocin-induced diabetes of 3 days' duration, the hexokinase/glucose-6-phosphatase (HK/G6Pase) ratio in the kidney was enhanced by 52% (mean +/- SEM: 0.40 +/- 0.04 vs. 0.26 +/- 0.03; p less than 0.02) compared to control mice as a result of a 25% increase of HK (16.68 +/- 0.93 vs. 13.31 +/- 1.04 nmol/min/mg protein; p = 0.05) and a 17% decrease of G6Pase (42.51 +/- 2.75 vs. 51.25 +/- 1.89; p less than 0.05). In contrast, as expected, the corresponding ratio (HK + glucokinase/G6Pase) was strikingly reduced in the liver. In 9-day diabetic mice, the kidney enzyme changes were much smaller; however, in a chronic disease such as diabetes, even minimal deviations from the normal may lead to significant metabolic changes with time. The enhanced HK/G6Pase ratio in the diabetic kidney suggests an increase in glucose utilization. This may contribute to the increased synthesis of glycogen, glycoproteins (including basement membrane) and RNA (via provision of ribose-phosphate) occurring in the diabetic kidney and supports the view that the kidney (as opposed to other tissues) shows an 'anabolic response' to diabetes.
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PMID:Increased hexokinase/glucose-6-phosphatase ratio in the diabetic kidney as index of glucose overutilization. 255 19

Aconitan A did not affect plasma insulin levels in normal, glucose-loaded and alloxan-induced hyperglycemic mice and gave no influence on insulin binding to isolated adipocytes. Aconitan A exerted no effect on the activities of hepatic hexokinase, glucokinase, glucose-6-phosphatase and glucose-6-phosphate dehydrogenase, whereas it significantly increased hepatic phosphofructokinase activity. Although the activity of hepatic glycogen synthetase showed a tendency to increase, the activity of liver phosphorylase and glycogen content were unchanged by aconitan A. Aconitan A did not change the total cholesterol and triglyceride contents of plasma and liver.
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PMID:Mechanisms of hypoglycemic activity of aconitan A, a glycan from Aconitum carmichaeli roots. 266 53

Eight-week-old, female Wistar fatty rats and their lean littermates were given a 30% sucrose solution in addition to a laboratory chow diet and water for 7 weeks. The fatty rats were hyperinsulinemic and hyperlipidemic, but normoglycemic when they drank only water. The hepatic activities of insulin-inducible glucokinase (GK), pyruvate kinase (PK), and malic enzyme (ME) were higher in the fatty rats than in the lean rats, whereas the insulin-suppressible glucose-6-phosphatase (G6Pase) activity was similar in both types of rats, indicating the normal response of hepatic enzymes to hyperinsulinemia in the fatty rats. When they drank the sucrose solution, the fatty rats, but not the lean rats, developed hyperglycemia over 200 mg/dl. Plasma insulin and triglyceride concentrations increased in both types of rats. Although the hepatic activities of GK, PK, and ME in the lean rats, and PK and ME in the fatty rats increased in response to the increase in plasma insulin, GK activity decreased in the fatty rats. On the other hand, G6Pase activity increased in both types of rats. As a result, the G6Pase/GK ratio, which may reflect net glucose handling in the liver, increased twofold in the fatty rats, but did not alter in the lean rats. From these findings, we conclude that sucrose ingestion induces an increase in hepatic glucose production through derangement of the hepatic enzyme profile and that the resultant decrease in hepatic glucose handling may be one of the pathogenic factors participating in the development of hyperglycemia in Wistar fatty rats.
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PMID:Derangement in hepatic enzymes caused by sucrose-drinking and its implication for the development of hyperglycemia in female Wistar fatty rats. 267 49

Glucose and lipid metabolism in the brain, liver and in a transplanted tumour were found to be variously altered within 2 to 3 h of administering single doses of the radiosensitizer Ro-03-8799 to normal and tumour-bearing mice. Hepatic lactate and glycerol-3-phosphate (G3P) levels were decreased but those of the ketone body beta-hydroxybutyrate (beta-HOBu) were raised. However, in the tumour, these levels were all enhanced. The lactate levels in brain remained relatively constant but both beta-HOBu and G3P levels were altered in a manner similar to that in the liver. The levels of glucose were approximately doubled in blood, brain and tumour, but whereas tumour G6P levels increased, those in the brain were lowered to below the limits of detection. Hepatic glucose levels were significantly decreased after 1 h but G6P levels were not affected. These changes could neither be related to inhibitory effects on hepatic glucokinase or brain hexokinase activity nor to limiting amounts of ATP in both tissues. However, the activity of glucose-6-phosphatase (G6P'ase) was distinctly raised in the liver and the hepatic glycogen stores were also rapidly lowered. Overall, the results suggest that Ro-03-8799 exerts a stimulatory effect on glucose production in the liver. In both liver and brain the levels of free fatty acids and phospholipids were increased whereas those of esterified fatty acids were lowered. Most importantly, the changes in metabolite levels affect the cellular redox couples; those of the cytosol (lactate/pyruvate; G3P/dihydroxyacetone phosphate (DAP] are directed towards the oxidised state in the liver but to a more reduced state in the tumour. The mitochondrial couple (beta-HOBu/acetoacetate (AcAc)) in both tissues is shifted towards the reduced state. These metabolic changes may result in an increase in the degree of hypoxia in the tumour and may well play an important role in the development of neuropathies.
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PMID:Effects on intermediary metabolism in mouse tissues by Ro-03-8799. 282 72

The aim of this study was to investigate the metabolic effects of short-term fasting in obese diabetic patients and to correlate the observed changes with the activity of hepatic key enzymes in an animal model of obesity-associated diabetes (ob/ob mice, C57BL/6J strain). In obese diabetic patients (ODP), a 72-h fast (causing slight change in body weight) decreased fasting glycemia by 3.82 +/- 0.79 mmoles/l and significantly improved glucose tolerance (OGTT) while reducing basal and stimulated insulinemia, whereas in obese non-diabetic patients (ONDP) only a small decrease in fasting glycemia (1.24 +/- 0.51 mmoles/l) occurred. This suggests that in ODP hyperphagia is a factor contributing to maintain hyperglycaemia and glucose intolerance (in the face of hyperinsulinaemia, indicating insulin resistance). In fed obese hyperglycaemic mice (OHM), which are a good model of the human obesity-associated diabetes, hepatic fructose-1,6-diphosphatase (F16Pase) and glucose-6-phosphatase (G6Pase), involved in glucose production, showed increased activity (+52 and +200 per cent, respectively) compared to control mice (CM), and the ratios of F16Pase and G6Pase to the opposing enzymes phosphofructokinase (PFK1) and glucokinase (GK), i.e. the F16Pase/PFK1 and G6Pase/GK ratios, were increased by 38 and 101 per cent, respectively, suggesting increase in gluconeogenesis and perhaps in glycogenolysis. In the 48-h fasted OHM, F16Pase activity was decreased (-30 per cent) compared to the fed animals, while the activity of G6Pase showed a smaller and statistically not significant change (-22 per cent). In contrast, in the CM a 48-h fasting was associated with a trend toward increased F16Pase (+22 per cent) and G6Pase (+173 per cent). However, since PFK1 and GK decreased to a similar extent in OHM and CM, the F16Pase/PFK1 and G6Pase/GK ratios, basally elevated in the OHM, did not change with fasting, whereas in the CM they showed a striking elevation (+71 and +274 per cent, respectively). The basally elevated F16Pase/PFK1 and G6Pase/GK ratios (functionally linked to glucose production) in the OHM may contribute to maintain hyperglycaemia; in these mice, the lack of further increase in the glucose production-related F16Pase/PFK1 and G6Pase/GK ratios (which occurs in CM) with fasting might allow that the interruption of the afflux of dietary carbohydrates ameliorates the glycaemic level. Similar mechanisms might occur also in the ODP.
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PMID:Metabolic effects of short-term fasting in obese hyperglycaemic humans and mice. 283 Nov 63

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