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Glycine transformation of Ca^2^+ oscillations into a sustained increase parallels potentiation of insulin release

Tengholm, A. ; McClenaghan, N. ; Grapengiesser, E. ; [et al.]

Amsterdam : Elsevier

Biochimica et Biophysica Acta (BBA)/Molecular Cell Research 1137 (1992), S. 243-247

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ISSN: 0167-4889

Keywords: Cytoplasmic calcium ; Glucose ; Glycine ; Insulin ; Oscillation ; Secretion

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Biology , Chemistry and Pharmacology , Medicine , Physics

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1016/0167-4889(92)90143-Y

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Glucose induces oscillatory Ca2+ signalling and insulin release in human pancreatic beta cells (1994)

Hellman, B. ; Gylfe, E. ; Bergsten, P. ; [et al.]

Springer

Diabetologia 37 (1994), S. S11

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ISSN: 1432-0428

Keywords: Ca2+ signalling ; diabetes mellitus ; glucose insulin secretion ; islets of Langerhans ; oscillations pancreatic beta cells

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Mechanisms of pulsatile insulin release in man were explored by studying the induction of oscillatory Ca2+ signals in individual beta cells and islets isolated from the human pancreas. Evidence was provided for a glucose-induced closure of ATP-regulated K+ channels, resulting in voltage-dependent entry of Ca2+. The observation of step-wise increases of capacitance in response to depolarizing pulses suggests that an enhanced influx of Ca2+ is an effective means of stimulating the secretory activity of the isolated human beta cell. Activation of muscarinic receptors (1–10 μmol/l carbachol) and of purinergic P2 receptors (0.01–1 μmol/l ATP) resulted in repetitive transients followed by sustained elevation of the cytoplasmic Ca2+ concentration ([Ca2+]i). Periodic mobilisation of intracellular calcium was seen also when injecting 100 μmol/l GTP-γ-S into beta cells hyperpolarized to −70 mV. Individual beta cells responded to glucose and tolbutamide with increases of [Ca2+]i, manifested either as large amplitude oscillations (frequency 0.1–0.5/min) or as a sustained elevation. Glucose regulation was based on sudden transitions between the basal and the two alternative states of raised [Ca2+]i at threshold concentrations of the sugar characteristic for the individual beta cells. The oscillatory characteristics of coupled cells were determined collectively rather than by particular pacemaker cells. In intact pancreatic islets the glucose induction of well-synchronized [Ca2+]i oscillations had its counterpart in 2–5 min pulses of insulin. Each of these pulses could be resolved into regularly occurring short insulin transients. It is concluded that glucose stimulation of insulin release in man is determined by the number of beta cells entering into a state with Ca2+-induced secretory pulses.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00400821

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Submembrane ATP and Ca2+ kinetics in {alpha}-cells: unexpected signaling for glucagon secretion [Research Communication] (2015)

Li, J., Yu, Q., Ahooghalandari, P., Gribble, F. M., Reimann, F., Tengholm, A., Gylfe, E.

The Federation of American Societies for Experimental Biology (FASEB)

In: FASEB Journal

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Publication Date: 2015-08-01

Description: Cytoplasmic ATP and Ca 2+ are implicated in current models of glucose’s control of glucagon and insulin secretion from pancreatic α- and β-cells, respectively, but little is known about ATP and its relation to Ca 2+ in α-cells. We therefore expressed the fluorescent ATP biosensor Perceval in mouse pancreatic islets and loaded them with a Ca 2+ indicator. With total internal reflection fluorescence microscopy, we recorded subplasma membrane concentrations of Ca 2+ and ATP ([Ca 2+ ] pm ; [ATP] pm ) in superficial α- and β-cells of intact islets and related signaling to glucagon and insulin secretion by immunoassay. Consistent with ATP’s controlling glucagon and insulin secretion during hypo- and hyperglycemia, respectively, the dose-response relationship for glucose-induced [ATP] pm generation was left shifted in α-cells compared to β-cells. Both cell types showed [Ca 2+ ] pm and [ATP] pm oscillations in opposite phase, probably reflecting energy-consuming Ca 2+ transport. Although pulsatile insulin and glucagon release are in opposite phase, [Ca 2+ ] pm synchronized in the same phase between α- and β-cells. This paradox can be explained by the overriding of Ca 2+ stimulation by paracrine inhibition, because somatostatin receptor blockade potently stimulated glucagon release with little effect on Ca 2+ . The data indicate that an α-cell-intrinsic mechanism controls glucagon in hypoglycemia and that paracrine factors shape pulsatile secretion in hyperglycemia.—Li, J., Yu, Q., Ahooghalandari, P., Gribble, F. M., Reimann, F., Tengholm, A., Gylfe, E. Submembrane ATP and Ca 2+ kinetics in α-cells: unexpected signaling for glucagon secretion.

Print ISSN: 0892-6638

Electronic ISSN: 1530-6860

Topics: Biology

Published by The Federation of American Societies for Experimental Biology (FASEB)

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PKC Dynamics in {beta} Cells [Cell Biology] (2016)

Wuttke, A., Yu, Q., Tengholm, A.

The American Society for Biochemistry and Molecular Biology (ASBMB)

In: Journal of Biological Chemistry

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Publication Date: 2016-07-16

Description: PKC signaling has been implicated in the regulation of many cell functions, including metabolism, cell death, proliferation, and secretion. Activation of conventional and novel PKC isoforms is associated with their Ca2+- and/or diacylglycerol (DAG)-dependent translocation to the plasma membrane. In β cells, exocytosis of insulin granules evokes brief (

Print ISSN: 0021-9258

Electronic ISSN: 1083-351X

Topics: Biology , Chemistry and Pharmacology

Published by The American Society for Biochemistry and Molecular Biology (ASBMB)

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P2Y1 receptor-dependent diacylglycerol signaling microdomains in {beta} cells promote insulin secretion [Research Communications] (2013)

Wuttke, A., Idevall-Hagren, O., Tengholm, A.

The Federation of American Societies for Experimental Biology (FASEB)

In: FASEB Journal

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Publication Date: 2013-04-02

Description: Diacylglycerol (DAG) controls numerous cell functions by regulating the localization of C1-domain-containing proteins, including protein kinase C (PKC), but little is known about the spatiotemporal dynamics of the lipid. Here, we explored plasma membrane DAG dynamics in pancreatic β cells and determined whether DAG signaling is involved in secretagogue-induced pulsatile release of insulin. Single MIN6 cells, primary mouse β cells, and human β cells within intact islets were transfected with translocation biosensors for DAG, PKC activity, or insulin secretion and imaged with total internal reflection fluorescence microscopy. Muscarinic receptor stimulation triggered stable, homogenous DAG elevations, whereas glucose induced short-lived (7.1±0.4 s) but high-amplitude elevations (up to 109±10% fluorescence increase) in spatially confined membrane regions. The spiking was mimicked by membrane depolarization and suppressed after inhibition of exocytosis or of purinergic P2Y 1 , but not P2X receptors, reflecting involvement of autocrine purinoceptor activation after exocytotic release of ATP. Each DAG spike caused local PKC activation with resulting dissociation of its substrate protein MARCKS from the plasma membrane. Inhibition of spiking reduced glucose-induced pulsatile insulin secretion. Thus, stimulus-specific DAG signaling patterns appear in the plasma membrane, including distinct microdomains, which have implications for the kinetic control of exocytosis and other membrane-associated processes.—Wuttke, A., Idevall-Hagren, O., Tengholm, A. P2Y 1 receptor-dependent diacylglycerol signaling microdomains in β cells promote insulin secretion.

Print ISSN: 0892-6638

Electronic ISSN: 1530-6860

Topics: Biology

Published by The Federation of American Societies for Experimental Biology (FASEB)

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Neuropeptide S inhibits gastrointestinal motility and increases mucosal permeability through nitric oxide (2015)

Wan Saudi, W. S., Halim, M. A., Rudholm-Feldreich, T., Gillberg, L., Rosenqvist, E., Tengholm, A., Sundbom, M., Karlbom, U., Naslund, E., Webb, D.-L., Sjoblom, M., Hellstrom, P. M.

The American Physiological Society (APS)

In: American Journal of Physiology: Gastrointestinal and Liver Physiology

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Publication Date: 2015-10-16

Description: Neuropeptide S (NPS) receptor (NPSR1) polymorphisms are associated with enteral dysmotility and inflammatory bowel disease (IBD). This study investigated the role of NPS in conjunction with nitrergic mechanisms in the regulation of intestinal motility and mucosal permeability. In rats, small intestinal myoelectric activity and luminal pressure changes in small intestine and colon, along with duodenal permeability, were studied. In human intestine, NPS and NPSR1 were localized by immunostaining. Pre- and postprandial plasma NPS was measured by ELISA in healthy and active IBD humans. Effects and mechanisms of NPS were studied in human intestinal muscle strips. In rats, NPS 100-4,000 pmol·kg –1 ·min –1 had effects on the small intestine and colon. Low doses of NPS increased myoelectric spiking ( P 〈 0.05). Higher doses reduced spiking and prolonged the cycle length of the migrating myoelectric complex, reduced intraluminal pressures ( P 〈 0.05-0.01), and increased permeability ( P 〈 0.01) through NO-dependent mechanisms. In human intestine, NPS localized at myenteric nerve cell bodies and fibers. NPSR1 was confined to nerve cell bodies. Circulating NPS in humans was tenfold below the ~0.3 nmol/l dissociation constant ( K d ) of NPSR1, with no difference between healthy and IBD subjects. In human intestinal muscle strips precontracted by bethanechol, NPS 1–1,000 nmol/l induced NO-dependent muscle relaxation ( P 〈 0.05) that was sensitive also to tetrodotoxin ( P 〈 0.01). In conclusion, NPS inhibits motility and increases permeability in neurocrine fashion acting through NO in the myenteric plexus in rats and humans. Aberrant signaling and upregulation of NPSR1 could potentially exacerbate dysmotility and hyperpermeability by local mechanisms in gastrointestinal functional and inflammatory reactions.

Print ISSN: 0193-1857

Electronic ISSN: 1522-1547

Topics: Medicine

Published by The American Physiological Society (APS)

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