Effects of Glucose and Amino Acids on Free ADP in βHC9 Insulin-Secreting Cells

Ronner, Peter; Naumann, Christin; Friel, Edward

doi:10.2337/diabetes.50.2.291

Cited by 31 publications

(41 citation statements)

References 57 publications

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Section: Fig 4 Calibration Of Absorption Data After Each Experimenmentioning

confidence: 84%

“…This provides good estimates of free ATP but not of free ADP because 95% of cellular ADP is bound or sequestered (30,31). Accordingly, only small increases in ATP/ADP have been seen in response to glucose (32,33).…”

Section: Fig 4 Calibration Of Absorption Data After Each Experimenmentioning

confidence: 99%

“…By identifying a large stable pool of nucleotides in islet secretory granules, an approximate fourfold increase in ATP/ADP was seen in response to glucose stimulation (34,35). However, even these estimates are ϳ10-fold higher than estimates of free ADP level based on calculations that assume that the creatine kinase reaction that buffers ATP and ADP levels is in equilibrium (30,31). Given the importance of free ATP and ADP to islet cells and the difficulty of measuring free ADP, we have suggested a new, albeit indirect, method for a continuous noninvasive measure of these key metabolic variables.…”

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confidence: 99%

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Regulation of ATP/ADP in Pancreatic Islets

et al. 2004

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ATP and ADP levels are critical regulators of glucosestimulated insulin secretion. In many aerobic cell types, the phosphorylation potential (ATP/ADP/P i ) is controlled by sensing mechanisms inherent in mitochondrial metabolism that feed back and induce compensatory changes in electron transport. To determine whether such regulation may contribute to stimulus-secretion coupling in islet cells, we used a recently developed flow culture system to continuously and noninvasively measure cytochrome c redox state and oxygen consumption as indexes of electron transport in perifused isolated rat islets. Increasing substrate availability by increasing glucose increased cytochrome c reduction and oxygen consumption, whereas increasing metabolic demand with glibenclamide increased oxygen consumption but not cytochrome c reduction. The data were analyzed using a kinetic model of the dual control of electron transport and oxygen consumption by substrate availability and energy demand, and ATP/ADP/P i was estimated as a function of time. ATP/ADP/P i increased in response to glucose and decreased in response to glibenclamide, consistent with what is known about the effects of these agents on energy state. Therefore, a simple model representing the hypothesized role of mitochondrial coupling in governing phosphorylation potential correctly predicted the directional changes in ATP/ADP/P i . Thus, the data support the notion that mitochondrial-coupling mechanisms, by virtue of their role in establishing ATP and ADP levels, may play a role in mediating nutrient-stimulated insulin secretion. Our results also offer a new method for continuous noninvasive measures of islet cell phosphorylation potential, a critical metabolic variable that controls insulin secretion by ATP-sensitive K ؉ -dependent and -independent mechanisms. Diabetes 53: [401][402][403][404][405][406][407][408][409] 2004 F ree ATP and ADP levels are understood to couple glucose metabolism with the closing of ATPsensitive K ϩ (K ATP ) channels and the ionic events leading to the exocytosis of insulin (1,2). Furthermore, the phosphorylation potential (ATP/ADP/P i ) may augment insulin secretion beyond that mediated by K ATP channels (3). Although it is well established that the critical ATP and ADP levels depend on islet substrate metabolism and mitochondrial electron transport (4 -6), it is less broadly appreciated that ADP stimulates electron transport and ATP production (7,8) as a feedback regulator of ATP/ADP/P i (9,10). Thus, mitochondrial ATP production, the ATP/ADP/P i , and ultimately the insulin secretory rate depend dually on both substrate supply as well as energy demand.Although the mechanisms by which mitochondria sense ADP levels and control ATP/ADP/P i are not fully established, a likely candidate is cytochrome c oxidase, the rate-limiting step in the electron transport chain (11). Wilson et al. (11,12) validated a mathematical model correlating substrate supply and energy demand (i.e., as phosphorylation potential) to the redox state and oxygen cons...

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Section: Fig 4 Calibration Of Absorption Data After Each Experimenmentioning

confidence: 84%

Section: Fig 4 Calibration Of Absorption Data After Each Experimenmentioning

confidence: 99%

mentioning

confidence: 99%

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Regulation of ATP/ADP in Pancreatic Islets

et al. 2004

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“…2. are involved in the generation of anti-apoptotic signals from glucose. Whether anti-apoptotic signaling by glucose is mediated by an altered ADP:ATP ratio, by glutamine or by glucokinase signaling (Isihara & Wollheim 2000, Moley & Mueckler 2000, Ronner et al 2001 remains to be elucidated. It seems likely that the availability of ATP in cytosolic compartments may be the decisive factor for the kinase activity of anti-apoptotic signaling cascades, which may imitate a second messenger effect.…”

Section: Discussionmentioning

confidence: 99%

Mechanisms of mitogenic and anti-apoptotic signaling by glucose-dependent insulinotropic polypeptide in beta(INS-1)-cells

Trümper

K²,

Hörsch³

2002

Journal of Endocrinology

182

101

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Glucose-dependent insulinotropic polypeptide (GIP) acts as a glucose-dependent growth factor for -cells. Here we show that GIP and glucose also act synergistically as anti-apoptotic factors for -cells, using the welldifferentiated -cell line, INS-1. Mitogenic and anti-apoptotic signaling of GIP were dependent upon pleiotropic activation of protein kinase A (PKA)/cAMP regulatory element binder (CREB), mitogen-activated protein kinase (MAPK) and phosphatidylinositol 3-kinase (PI3-kinase)/PKB signaling modules. The signaling modules activated by GIP were dependent on glucose metabolism and calcium influx and were tightly linked by multiple activating and inhibiting cross-talk. These interactions included: (i) a central role of tyrosine phosphorylation for stimulation of PKA/CREB, MAPK and PI3-kinase/PKB, (ii) inhibition of PKA/CREB by the MAPK pathway at the level of MAPK kinase-1 or downstream, (iii) activation of MAPK signaling by PI3-kinase and PKA at the level of extracellular-signal regulated kinase 1/2 or upstream, and (iv) activation of PKB by MAPK and PKA signaling at the level of PKB or upstream. Furthermore, we demonstrated inhibition of CREB signaling by Ca 2+ / calmodulin kinase I/IV. These results indicated that GIP acts as a mitogenic and anti-apoptotic factor for -cells by pleiotropic activation of tightly linked signaling pathways in -cells.

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“…Mitochondrial metabolism increases the ATP/ ADP ratio (17). The increase in cytosolic ATP (18,19) and/or the decrease in free ADP (5,20) promotes the closure of ATP-sensitive K ϩ channels (K ATP channels) and depolarization of the plasma membrane (21). As a consequence, cytosolic Ca 2ϩ ([Ca 2ϩ ] c ) is raised by the opening of voltage-sensitive Ca 2ϩ channels (21,22).…”

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confidence: 99%

β-Cell Mitochondria and Insulin Secretion

Wollheim¹,

Maechler²

2002

Diabetes

107

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The ␤-cell mitochondria are known to generate metabolic coupling factors, or messengers, that mediate plasma membrane depolarization and the increase in cytosolic Ca 2؉ , the triggering event in glucose-stimulated insulin secretion. Accordingly, ATP closes nucleotide-sensitive K ؉ channels necessary for the opening of voltage-gated Ca 2؉ channels. ATP also exerts a permissive action on insulin exocytosis. In contrast, GTP directly stimulates the exocytotic process. cAMP is considered to have a dual function: on the one hand, it renders the ␤-cell more responsive to glucose; on the other, it mediates the effect of glucagon and other hormones that potentiate insulin secretion. Mitochondrial shuttles contribute to the formation of pyridine nucleotides, which may also participate in insulin exocytosis. Among the metabolic factors generated by glucose, citrate-derived malonyl-CoA has been endorsed, but recent results have questioned its role. We have proposed that glutamate, which is also formed by mitochondrial metabolism, stimulates insulin exocytosis in conditions of permissive, clamped cytosolic Ca 2؉ concentrations. The evidence for the implication of these and other putative messengers in metabolism-secretion coupling is discussed in this review. Diabetes 51 (Suppl.

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Effects of Glucose and Amino Acids on Free ADP in βHC9 Insulin-Secreting Cells

Cited by 31 publications

References 57 publications

Regulation of ATP/ADP in Pancreatic Islets

Regulation of ATP/ADP in Pancreatic Islets

Mechanisms of mitogenic and anti-apoptotic signaling by glucose-dependent insulinotropic polypeptide in beta(INS-1)-cells

β-Cell Mitochondria and Insulin Secretion

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