Emergence of organized bursting in clusters of pancreatic beta-cells by channel sharing

Sherman, Arthur; Rinzel, John; Keizer, Joel

doi:10.1016/s0006-3495(88)82975-8

Cited by 277 publications

(310 citation statements)

References 37 publications

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“…These bursts of action potentials are likely to underlie the intracellular Ca 2+ concentration [Ca 2+ ] i oscillations reported in delta cells [11,12,21,22], although the frequency of the [Ca 2+ ] i oscillations was slightly lower (<1/min) than that of the electrical bursts observed here (2-5/min). It has been proposed, based on both experimental and theoretical considerations, that oscillatory electrical activity in mouse beta cells depends on cell coupling [23,24]. However, the finding that high-frequency bursts of action potentials can be recorded from individual human delta cells suggests that cell coupling is not required for such electrical activity to occur.…”

Section: Discussionmentioning

confidence: 99%

Somatostatin release, electrical activity, membrane currents and exocytosis in human pancreatic delta cells

et al. 2009

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Aims/hypothesis The aim of this study was to characterise electrical activity, ion channels, exocytosis and somatostatin release in human delta cells/pancreatic islets. Methods Glucose-stimulated somatostatin release was measured from intact human islets. Membrane potential, currents and changes in membrane capacitance (reflecting exocytosis) were recorded from individual human delta cells identified by immunocytochemistry. Results Somatostatin secretion from human islets was stimulated by glucose and tolbutamide and inhibited by diazoxide. Human delta cells generated bursting or sporadic electrical activity, which was enhanced by tolbutamide but unaffected by glucose. Delta cells contained a tolbutamide-insensitive, Ba 2+ -sensitive inwardly rectifying K + current and two types of voltagegated K + currents, sensitive to tetraethylammonium/ stromatoxin (delayed rectifying, Kv2.1/2.2) and 4-aminopyridine (A current). Voltage-gated tetrodotoxin (TTX)-sensitive Na + currents contributed to the action potential upstroke but TTX had no effect on somatostatin release. Delta cells are equipped with Ca 2+ channels blocked by isradipine (L), ω-agatoxin (P/Q) and NNC 55-0396 (T). Blockade of any of these channels interferes with delta cell electrical activity and abolishes glucose-stimulated somatostatin release. Capacitance measurements revealed a slow component of depolarisation-evoked exocytosis sensitive to ω-agatoxin. Conclusions/interpretation Action potential firing in delta cells is modulated by ATP-sensitive K + -channel activity. The membrane potential is stabilised by Ba 2+ -sensitive inwardly rectifying K + channels. Voltage-gated L-and T-type Ca 2+ channels are required for electrical activity, whereas Na + currents and P/Q-type Ca 2+ channels contribute to (but are not necessary for) the upstroke of the action potential. Action potential repolarisation is mediated by A-type and Kv2.1/2.2 K + channels. Exocytosis is tightly linked to Ca 2+ -influx via P/Q-type Ca 2+ channels. Glucose stimulation of somatostatin secretion involves both K ATP channel-dependent and -independent processes.

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Section: Discussionmentioning

confidence: 99%

Somatostatin release, electrical activity, membrane currents and exocytosis in human pancreatic delta cells

et al. 2009

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“…Some more complete models for glycolytic oscillations include those by Smolen (Smolen, 1995), Tornheim (1979), and Westermark and Lansner (2003). More recent models of bursting in b-cells include those by Chay (1996), Keizer and Smolen (1989), and Sherman et al (1988). In one recent b-cell model, the Phantom Bursting Model (PBM), bursting is driven by the interaction of more than one slow variable Goforth et al, 2002).…”

Section: Discussionmentioning

confidence: 99%

“…Several models have been developed for bursting in pancreatic b-cells Chay, 1996;Chay and Keizer, 1983;Goforth et al, 2002;Keizer and Smolen, 1991;Sherman et al, 1988). These models differ primarily in the slow process responsible for driving the bursting.…”

Section: Model For Electrical Burstingmentioning

confidence: 99%

Complex bursting in pancreatic islets: a potential glycolytic mechanism

Wierschem

Bertram

2004

Journal of Theoretical Biology

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The electrical activity of insulin-secreting pancreatic islets of Langerhans is characterized by bursts of action potentials. Most often this bursting is periodic, but in some cases it is modulated by an underlying slower rhythm. We suggest that the modulatory rhythm for this complex bursting pattern is due to oscillations in glycolysis, while the bursting itself is generated by some other slow process. To demonstrate this hypothesis, we couple a minimal model of glycolytic oscillations to a minimal model for activitydependent bursting in islets. We show that the combined model can reproduce several complex bursting patterns from mouse islets published in the literature, and we illustrate how these complex oscillations are produced through the use of a fast/slow analysis. r

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“…According to the first, in isolated cells, noise from stochastic channel fluctuations shortens or eliminates the bursts by causing premature transitions between silent and active phases. In large populations, on the other hand, the fluctuations are damped, allowing the underlying burst dynamics to become manifest (Sherman et al, 1988). The second hypothesis emphasizes heterogeneity: single cell properties are very variable (Kinard et al, 1999), and individual cells may fall outside the narrow parameter regime required for bursting.…”

Section: Introductionmentioning

confidence: 99%

From Spikers to Bursters Via Coupling: Help From Heterogeneity

Vries

Sherman

2001

Bulletin of Mathematical Biology

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It has been shown previously that identical spiking cells, incapable of bursting by themselves, may burst under weak diffusive coupling conditions. With stronger coupling, the coupled system reverts to bursting can be recovered by introducing heterogeneity in the model parameters. For a two-cell system, we explain the phenomenon with bifurcation analysis. For larger clusters of coupled cells, we demonstrate by numerical simulation that the phenomenon carries over. In addition, we use a perturbation analysis to deduce the dependence of the heterogeneity parameter used in the bifurcation analysis on the original heterogeneity parameters and the coupling strength. Implications of the phenomenon of emergent bursting are discussed in the context of electrical activity in pancreatic beta cells.

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Emergence of organized bursting in clusters of pancreatic beta-cells by channel sharing

Cited by 277 publications

References 37 publications

Somatostatin release, electrical activity, membrane currents and exocytosis in human pancreatic delta cells

Somatostatin release, electrical activity, membrane currents and exocytosis in human pancreatic delta cells

Complex bursting in pancreatic islets: a potential glycolytic mechanism

From Spikers to Bursters Via Coupling: Help From Heterogeneity

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