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Query: EC:3.6.3.14 (ATP synthase)
 7,042 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nutrient-stimulated insulin secretion is dependent upon the generation of metabolic coupling factors in the mitochondria of the pancreatic B cell. To investigate the role of Ca2+ in mitochondrial function, insulin secretion from INS-1 cells stably expressing the Ca2+-sensitive photoprotein aequorin in the appropriate compartments was correlated with changes in cytosolic calcium ([Ca2+]c) and mitochondrial calcium ([Ca2+]m). Glucose and KCl, which depolarize the cell membrane, as well as the Ca2+-mobilizing agonist, carbachol (CCh), cause substantial increases in [Ca2+]m which are associated with smaller rises in [Ca2+]c. The L-type Ca2+-channel blocker, SR7037, abolished the effects of glucose and KCl while attenuating the CCh response. Glucose-induced increases in [Ca2+]m, [Ca2+]c, and insulin secretion all demonstrate a pronounced initial peak followed by a sustained plateau. All three parameters are increased synergistically when glucose and CCh are combined. Finally, [Ca2+]m, [Ca2+]c, and insulin secretion also display desensitization phenomena following repeated additions of the three stimuli. The high sensitivity of [Ca2+]m to Ca2+ influx and the desensitization-resensitization effects can be explained by a model in which the mitochondria of INS-1 cells are strategically located to sense Ca2+ influx through plasma membrane Ca2+ channels. In conclusion, the correlation of [Ca2+]m and [Ca2+]c with insulin secretion may indicate a fundamental role for Ca2+ in the adaptation of oxidative metabolism to the generation of metabolic coupling factors and the energy requirements of exocytosis.
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PMID:Glucose-stimulated insulin secretion correlates with changes in mitochondrial and cytosolic Ca2+ in aequorin-expressing INS-1 cells. 895 15

Glucose metabolism and its relationship with glucose-induced insulin release were studied in beta HC9 and beta TC3 cells to identify and characterize key factors controlling the intermediary metabolism of glucose and glucose-induced insulin release. The beta HC9 cell line, derived from pancreatic islets with beta-cell hyperplasia, is characterized by a normal concentration-dependency curve for glucose-stimulated insulin release, whereas the beta TC3 cell line, derived from pancreatic beta-cell tumors, shows a marked leftward shift of this curve. Maximum velocity and the Michaelis-Menten constant of glucose uptake in beta HC9 and beta TC3 cells were similar, even though GLUT-2 expression in these two cell lines differed. In both cell lines, the kinetic characteristics of glucose usage, glucose oxidation, and glucose-induced oxygen consumption were similar to those of glucose phosphorylation, indicating that the kinetics of glucose metabolism from the glucose phosphorylation step in the cytosol to the mitochondrial process of oxidative phosphorylation are determined by the glucose-phosphorylating enzyme, that is, by glucokinase in beta HC9 cells and by hexokinase in beta TC3 cells. Thus beta HC9 cells provide an opportunity for the quantitative analysis of glucose metabolism, the associated generation of coupling factors, and other essential beta-cell functions involved in glucose sensing and insulin secretion.
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PMID:Glucose metabolism and insulin release in mouse beta HC9 cells, as model for wild-type pancreatic beta-cells. 896 74

In rat pancreatic islets, D-fructose causes a concentration-related shift to the left of the sigmoidal relationship between insulin release and D-glucose concentration. For instance, when D-fructose is tested at a 80 mM concentration, which is close to the threshold value for stimulation of insulin release by the ketohexose in the absence of D-glucose, a close-to-maximal secretory response is recorded in islets concomitantly exposed to as little as 6.0 to 8.3 mM D-glucose. Under these conditions, however, D-fructose fails to affect the utilization of D-[5-3H]glucose, the oxidation of D-[U-14C]glucose, or its conversion to either 14C-labeled acidic metabolites or amino acids. Under the same experimental conditions, the oxidation of D-[U-14C]fructose and its conversion to 14C-labeled amino acids represent no more than 80-85% of the corresponding values found with 6 mM D-[U-14C]glucose. Actually, the total output of 14CO2 attributable to the oxidation of both D-[U-14C]glucose (6 mM) and D-[U-14C]fructose (80 mM) remains lower than that found in the sole presence of 8.3 mM D-[U-14C]glucose, despite the much higher rate of insulin secretion found in the former compared to the latter situation. These findings suggest that the insulinotropic action of D-fructose cannot be fully accounted for by its capacity to act as a fuel in islet cells, as if it were to involve the generation of a second messenger distinct from those coupling factors currently implied in the process of nutrient-stimulated insulin release.
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PMID:Hexose metabolism in pancreatic islets: apparent dissociation between the secretory and metabolic effects of D-fructose. 898 42

The knowledge of the mechanism whereby glucose and other fuel stimuli promote the release of insulin by the pancreatic beta cell remains fragmentary. The closure of metabolically sensitive K+ channels and a rise in cytosolic free Ca2+ are key features of beta-cell metabolic signal transduction. However, these two signalling events do not account for the dose dependence of glucose-induced insulin secretion. In fact, recent evidence indicates that there are KATP channel and Ca2+ independent pathway(s) of beta-cell activation which remain to be defined. In this review, we have limited our attention to the recent developments in our understanding of the mode of action of nutrient secretagogues. A particular emphasis is placed in summarising the evidence in support of two new concepts: 1) oscillations in the glycolytic pathway and beta-cell metabolism contribute to the oscillatory nature of beta-cell ionic events and insulin secretion; 2) malonyl-CoA and long chain acyl-CoA esters may act as metabolic coupling factors in beta-cell signalling. Finally, we propose that the altered expression of genes encoding enzymes in the pathway of malonyl-CoA formation and fatty acid oxidation contributes to the beta-cell insensitivity to glucose in some patients with non-insulin-dependent diabetes mellitus.
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PMID:Signal transduction mechanisms in nutrient-induced insulin secretion. 924 99

Recent acquisitions concerning the physiology, pathology and pharmacology of insulin secretion are reviewed. In terms of physiology, emphasis is placed on new information concerning the role of glucokinase and the identity of coupling factors in the process of glucose-stimulated insulin release. Pathological considerations concern mainly the possible participation of an inherited or acquired defect of FAD-linked mitochondrial glycerophosphate dehydrogenase in the impairment of insulin release in non-insulin-dependent diabetes. Although experimental approaches to correct such a site-specific defect have so far been unsuccessful, new therapeutic tools, especially the esters of certain nutrients, may soon be available for stimulation of proinsulin biosynthesis as well as insulin release in the diseased B cell.
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PMID:Physiology, pathology and pharmacology of insulin secretion: recent acquisitions. 934 37

The regulation of proinsulin biosynthesis in pancreatic beta-cells is vital for maintaining optimal insulin stores for glucose-induced insulin release. The majority of nutrient fuels that induce insulin release also stimulate proinsulin biosynthesis, but since insulin exocytosis and proinsulin synthesis involve different cellular mechanisms, a point of divergence in the respective metabolic stimulus-response coupling pathways must exist. A parallel examination of the metabolic regulation of proinsulin biosynthesis and insulin secretion was undertaken in the same beta-cells. In MIN6 cells, glucose-induced proinsulin biosynthesis and insulin release shared a requirement for glycolysis to generate stimulus-coupling signals. Pyruvate stimulated both proinsulin synthesis (threshold 0.13-0.2 mM) and insulin release (threshold 0.2-0.3 mM) in MIN6 cells, which was eliminated by an inhibitor of pyruvate transport (1 mM alpha-cyano-4-hydroxycinnamate). A combination of alpha-oxoisohexanoate and glutamine also stimulated proinsulin biosynthesis and insulin release in MIN6 cells, which, together with the effect of pyruvate, indicated that anaplerosis was necessary for instigating secondary metabolic stimulus-coupling signals in the beta-cell. A consequence of increased anaplerosis in beta-cells is a marked increase in malonyl-CoA, which in turn inhibits beta-oxidation and elevates cytosolic fatty acyl-CoA levels. In the beta-cell, long-chain fatty acyl moieties have been strongly implicated as metabolic stimulus-coupling signals for regulating insulin exocytosis. Indeed, it was found in MIN6 cells and isolated rat pancreatic islets that exogenous oleate, palmitate and 2-bromopalmitate all markedly potentiated glucose-induced insulin release. However, in the very same beta-cells, these fatty acids in contrast inhibited glucose-induced proinsulin biosynthesis. This implies that neither fatty acyl moieties nor beta-oxidation are required for the metabolic stimulus-response coupling pathway specific for proinsulin biosynthesis, and represent an early point of divergence of the two signalling pathways for metabolic regulation of proinsulin biosynthesis and insulin release. Therefore alternative metabolic stimulus-coupling factors for the specific control of proinsulin biosynthesis at the translational level were considered. One possibility examined was an increase in glycerophosphate shuttle activity and change in cytosolic redox state of the beta-cell, as reflected by changes in the ratio of alpha-glycerophosphate to dihydroxyacetone phosphate. Although 16.7 mM glucose produced a significant rise in the alpha-glycerophosphate/dihydroxyacetone phosphate ratio, 1 mM pyruvate did not. It follows that the cytosolic redox state and fatty acyl moieties are not necessarily involved as secondary metabolic stimulus-coupling factors for regulation of proinsulin biosynthesis. However, the results indicate that glycolysis and the subsequent increase in anaplerosis are indeed necessary for this signalling pathway, and therefore an extramitochondrial product of beta-cell pyruvate metabolism (that is upstream of the increased cytosolic fatty acyl-CoA) acts as a key intracellular secondary signal for specific control of proinsulin biosynthesis by glucose at the level of translation.
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PMID:A distinct difference in the metabolic stimulus-response coupling pathways for regulating proinsulin biosynthesis and insulin secretion that lies at the level of a requirement for fatty acyl moieties. 953 97

To identify molecules that contribute to insulin resistance, we compared the patterns of gene expression in skeletal muscle of the obese ob/ob mouse, a genetic model of obesity and severe insulin resistance, with that of its thin littermate (ob/+) using the mRNA differential display method. From about 9,000 cDNAs displayed, we found 12 differentially expressed in ob/ob mice skeletal muscle that could be recovered from the differential display gels and confirmed by Northern blot analysis and sequenced. Eight mRNAs were overexpressed in ob/ob muscle: Id2 (a negative regulator of the basic helix-loop-helix family of transcription factors), fast skeletal muscle troponin T, ribosomal protein L3, the integral protein of the peroxisomal membrane 22PMP, the mammalian homolog of geranylgeranyl pyrophosphate synthase, an mRNA related to phosphatidylinositol-glycan-specific phospholipase D, and two unknown mRNAs. The level of overexpression of these mRNAs in skeletal muscle varied from a 500% increase to as little as a 25% increase. Two mRNAs were underexpressed 20-35%, including the f-subunit of mitochondrial ATP synthase and a retrovirus-related DNA. Two proteins with multiple transcripts, skeletal muscle alpha-tropomyosin and one for a repetitive sequence, showed a change in mRNA pattern of expression in the muscle of the ob/ob mouse. Because the primary genetic defect in the ob/ob mouse is known to be in the leptin gene, these data indicate how acquired alterations in gene expression of multiple classes of proteins may play a role in the complex pathogenesis of insulin resistance in obesity and diabetes.
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PMID:Alterations in skeletal muscle gene expression of ob/ob mice by mRNA differential display. 972 34

Recent advances in bioenergetics consist of discoveries related to rotational coupling in ATP synthase (FoF(1)), uncoupling proteins (UCP), reactive oxygen species (ROS) and mitochondrial DNA (mtDNA). As shown in cloned sheep, mammalian genomes are composed of both nuclear DNA (nDNA) and maternal mtDNA. Oxidative phosphorylation (oxphos) varies greatly depending on cellular activities, and is regulated by both gene expression and the electrochemical potential difference of H(+) (Delta muH(+)). The expression of both mtDNA (by mtTFA) and nDNA for oxphos and UCP (by NRFs, etc.) is coordinated by a factor called PGC-1. The Delta muH(+) rotates an axis in FoF(1) that is regulated by inhibitors and ATP-sensitive K(+)-channels. We cultured human rho(o) cells (cells without mtDNA) in synthetic media and elucidated relationships among mtDNA, nDNA, Delta muH(+), UCPs, ROS, and apoptosis. These cells lack oxphos-dependent ROS formation and survive under conditions of high O(2). Cells cultured in the absence of ROS scavengers have proliferated for 40 years. UCPs lower Delta muH(+) and prevent ROS formation and resulting apoptosis. These results were applied to diabetology and gerontology. The pancreatic rho(o) cells did not secrete insulin, and mtDNA mutations caused diabetes, owing to the deficient Delta muH(+). Insulin resistance was closely related to UCPs and other energy regulators. The resulting high-glucose environment caused glycation of proteins and ROS-mediated apoptosis in vascular cells involved in diabetic complications. Telomeres, oxphos, and ROS are determinants in cellular aging. Cell division and ROS shortened telomeres and accelerated aging. In aged cells, Delta muH(+) was reduced by the slow respiration, and this change induced apoptosis. Cybrids made from aged cytoplasts and rho(o) cells showed that both decreased expression of nDNA, and somatic mutations of mtDNA are involved in the slowing of respiration in aged cells.
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PMID:Regulation of energy metabolism in human cells in aging and diabetes: FoF(1), mtDNA, UCP, and ROS. 1060 4

Glucose prevents the development of diabetes induced by alloxan. In the present study, the protective mechanism of glucose against alloxan-induced beta-cell damage was investigated using HIT-T 15 cell, a Syrian hamster transformed beta-cell line. Alloxan caused beta-cell damages with DNA fragmentation, inhibition of glucose-stimulated insulin release, and decrease of cellular ATP level, but all of these beta-cell damages by alloxan were prevented by the presence of 20 mM glucose. Oligomycin, a specific inhibitor of ATP synthase, completely abolished the protective effects of glucose against alloxan-induced cell damage. Furthermore, treatment of nuclei isolated from HIT-T15 cells with ATP significantly prevented the DNA fragmentation induced by Ca2+. The results indicate that ATP produced during glucose metabolism plays a pivotal role in the protection of glucose against alloxan-induced beta-cell damage.
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PMID:Protective mechanism of glucose against alloxan-induced beta-cell damage: pivotal role of ATP. 1076 56

Insulin is stored in secretory granules in the beta-cell and is secreted by exocytosis. This process is precisely controlled to achieve blood glucose homeostasis. Many forms of diabetes mellitus display impaired glucose-induced insulin secretion. This has been shown to be the primary cause of the disease in the various forms of maturity-onset diabetes of the young (MODY) and has also been implicated in adult-onset Type II (non-insulin-dependent) diabetes mellitus. Glucose generates ATP and other metabolic coupling factors in the beta-cell mitochondria. By plasma membrane depolarisation ATP promotes Ca2+ influx, which raises cytosolic Ca2+ and triggers insulin exocytosis. Through hyperpolarisation of the mitochondrial membrane glucose also increases the Ca2+ concentration in the mitochondrial matrix activating Ca(2+)-sensitive dehydrogenases in the tricarboxylic acid cycle. The resulting generation of glutamate participates in Ca(2+)-stimulated exocytosis. Mitochondrial DNA (mtDNA) encodes some of the polypeptides of the respiratory chain enzyme complexes. Mutations in mtDNA lead to maternally inherited diabetes mellitus characterised by impaired insulin secretion. The impact of altered mtDNA on insulin secretion has been shown in mtDNA-deficient beta-cell lines which have lost glucose-stimulated insulin secretion but retain a Ca(2+)-induced insulin secretion. A cellular model of MODY3 expressing dominant-negative hepatocyte nuclear factor-1 alpha (HNF-1 alpha) also displayed deletion of glucose-induced but not Ca(2+)-induced insulin secretion. Reduced mitochondrial metabolism explains this secretory pattern. Thus, genetically manipulated beta-cell lines are essential tools in the investigation of the molecular basis of beta-cell dysfunction in diabetes and should explain the role of other transcription factors in the disease.
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PMID:Beta-cell mitochondria in the regulation of insulin secretion: a new culprit in type II diabetes. 1076 87


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