Showing papers on "Phosphofructokinase activity published in 1994"

Nitric oxide opens ATP-sensitive K+ channels through suppression of phosphofructokinase activity and inhibits glucose-induced insulin release in pancreatic beta cells.

Abstract: Nitric oxide (NO) is known to be a potent messenger in the intracellular signal transduction system in many tissues. In pancreatic beta cells, NO has been reported to be formed from L-arginine through NO synthase. To elucidate the effect of NO on insulin secretion and to investigate the intracellular mechanism of its effect, we have used sodium nitroprusside (SNP) as a NO donor. SNP inhibited glucose-induced insulin secretion in a dose-dependent manner, and its effect was reversed by hemoglobin, a known NO scavenger. However, glyceraldehyde-induced insulin secretion was not affected by SNP. Since the closure of ATP-sensitive K+ channels (KATP channel) has been established as a key step in glucose-induced insulin secretion, we have directly assessed the effect of SNP on KATP channel activity using the patch clamp technique. The KATP channel activity reduced by glucose was found to be reversibly activated by the addition of SNP, and this activation was able to be similarly reproduced by applying S-Nitroso-N-acetyl-DL-penicillamine (SNAP), another NO generator. Furthermore, these activating effects were completely eliminated by hemoglobin, in accordance with the reversibility in inhibition of glucose-induced insulin release. However, SNP could not affect the KATP channel suppression by ATP applied to the inside of the plasma membrane. The activation of the KATP channel by NO, therefore, seems to be due to the decreased ATP production attributable to impairment of glucose metabolism in beta cells. Since SNP exhibited no effect on glyceraldehyde-induced KATP channel inhibition, NO may disturb a glycolytic step before glyceraldehyde-3-phosphate. The KATP channel activation by 2-deoxyglucose through presumable ATP consumption due to its phosphorylation by glucokinase was, however, not affected even in the presence of SNP. But in the permeabilized beta cells made by exposure to a low concentration (0.02 U/ml) of streptolysin O (open cell-attached configuration), SNP reopens KATP channels which have been eliminated by fructose-6-phosphate, while this effect was not observed in the KATP channels inhibited by fructose-1,6-bisphosphate. On the other hand, in rat ventricular myocyte KATP channels were not activated by SNP even under a low concentration of glucose. From these observations, the inhibition of phosphofructokinase activity is probably the site responsible for the impairment of glucose metabolism induced by NO in pancreatic beta cells. NO, therefore, seems to be a factor in the deterioration of glucose-induced insulin secretion from pancreatic beta cells through a unique intracellular mechanism.

Overexpression of liver-type phosphofructokinase (PFKL) in transgenic-PFKL mice: implication for gene dosage in trisomy 21

Abstract: The human liver-type subunit of the key glycolytic enzyme, phosphofructokinase (PFKL), is encoded by a gene residing on chromosome 21. This chromosome, when triplicated, causes the phenotypic expression of Down's syndrome (trisomy 21). Increased phosphofructokinase activity, a result of gene dosage, is commonly found in erythrocytes and fibroblasts from Down's syndrome patients. We describe the construction of transgenic mice overexpressing PFKL for use as a well-defined model system, in which the effects of PFKL overexpression in various tissues, and throughout development, can be studied. Mice transgenic for a murine PFKL 'gene cDNA' hybrid construct were found to overexpress PFKL in a tissue-specific manner resembling that of the endogenous enzyme. Although unchanged in adult brain, PFK specific activity was found to have been almost doubled in brains of embryonic transgenic-PFKL mice, suggesting that the extra copies of the PFKL gene are expressed during the developmental period. This pattern of overexpression of PFKL in brains of transgenic-PFKL mice suggests that gene-dosage effects may be temporally separated from some of their consequences, adding an additional layer of complexity to the analysis of gene dosage in trisomy 21.

Alterations in the myocardial creatine kinase system during chronic anaemic hypoxia

Abstract: Objective: The aim was to use a model of chronic anaemia in the rat, in which there is an increase in cardiac mitochondrial creatine kinase activity (mito-CK) per mitochondrion, to test the hypothesis that creatine stimulated respiration in saponin skinned fibres is correlated with mito-CK activity. In order to discuss the altered regulation of mitochondrial respiratory rate in the context of other metabolic alterations, steady state metabolite concentrations and maximum extracted activities of regulatory enzymes in glycolysis were also investigated. Methods: Weanling male Wistar Albino rats were randomly distributed into two experimental groups. One group received a powdered diet deficient in iron (5–7 mg iron·kg−1) while the second group was placed on a standard laboratory chow diet (109 mg iron·kg−1) for 4–8 weeks. Results: Total cardiac creatine kinase activity was unchanged in anaemic rats; however, a 25% increase in nascent or functional mito-CK activity per mitochondrion was detected [0.969(SEM 0.005), control group and 1.203(0.040), anaemic group, p<0.001]. The sensitivity of creatine (40 mM creatine, VCr) and ADP (0.1 mM ADP, V0.1) stimulated respiration, as a percentage of maximum respiratory rate (2.0 mM ADP, V2.0), was increased by 48% and 52% respectively in the anaemic skinned cardiac fibres. An increase in basal respiration with glutamate and malate as substrates was detected in the anaemic group compared to the control group, at 6.77(0.74) v 4.58(0.35) ng O·min−1·mg−1 dry weight (p< 0.025). Cytosolic ATP was decreased in isolated perfused hearts from anaemic animals, at 35.18(3.11) μmol·g−1 dry weight in control hearts versus 23.66(1.42) in anaemic hearts (p<0.01). A significant increase in myocardial glycolytic capacity was detected in anaemic cardiac tissue, as evidenced by a 20% increase in phosphofructokinase activity (p<0.01). Phosphorylase activity was unaltered in anaemic hearts, indicating that the increased glucose requirement originated from exogenous sources. Lactate dehydrogenase (LDH) was increased by 30% in anaemic hearts (p< 0.001). The LDH isozyme profile was shifted in favour of lactate and NAD+ production, thus supporting anaerobic glycolysis. Conclusions: In support of the phosphocreatine circuit model, the increased mito-CK per mitochondrion in the anaemic skinned fibre preparation was associated with an increase in creatine stimulated respiration. In addition, the sensitivity of mitochondrial respiratory rate to ADP and the maximum glycolytic capacity were increased in anaemic fibres. Although the net effect of these changes in metabolic capacity and regulation on in vivo high energy phosphate flux is unknown, it is likely that they are adaptive alterations that compensate for the lower steady state cytosolic nucleotide concentration. Cardiovascular Research 1994; 28 :86-91

Glutamine synthesis from glucose and ammonium chloride by guinea-pig kidney tubules.

Abstract: 1. At a physiological concentration (5 mM), glucose was found to be metabolized by isolated kidney cortex tubules prepared from fed guinea pigs. 2. The release of 14CO2 from [U-14C]glucose indicated that oxidation of the glucose carbon skeleton represented about 50% of the glucose removed; significant amounts of lactate and glutamine also accumulated. 3. Addition of 0.1-10 mM NH4Cl led to a dose-dependent stimulation of glucose metabolism which was accompanied by a large increase in lactate and glutamine accumulation and, to a lesser extent, in glucose oxidation. 4. Comparison of the release of 14CO2 from [1-14C]- and [6-14C]glucose indicates that, in both the absence and the presence of NH4Cl, the pentose phosphate shunt was only a minor pathway of glucose metabolism. 5. The central role of pyruvate carboxylase in the conversion of glucose carbon into glutamine carbon was demonstrated by using a bicarbonate-free medium and measuring the fixation of 14CO2 from [14C]bicarbonate, which was recovered mostly at C-1 of glutamine plus glutamate. 6. The NH4Cl-induced stimulation of glucose removal was secondary not only to increased glutamine synthesis, as shown by the effect of methionine sulphoximine, an inhibitor of glutamine synthetase, but also to the stimulation of phosphofructokinase activity by NH4Cl. 7. Renal arterio-venous difference measurements revealed that, in vivo, the guinea-pig kidney removed glucose from the circulating blood, which suggests that glucose carbon may contribute to the carbon skeleton of the glutamine released by this organ.

Phosphofructokinase activity as a measure of maturation of rat oocytes developed in vivo and in vitro.

Abstract: We determined the activity of phosphofructokinase (PFK), a rate-limiting enzyme of glycolysis, in the rat oocyte during maturation either by luteinizing hormone stimulation in vivo or by cultivation u