Tolbutamide Controls Glucagon Release From Mouse Islets Differently Than Glucose

Cheng-Xue, Rui; Gómez-Ruiz, Ana; Antoine, Nancy; Noël, Laura A.; Chae, Heeyoung; Ravier, Magalie A.; Chimienti, Fabrice; Schuit, Frans; Gilon, Patrick

doi:10.2337/db12-0347

Cited by 81 publications

(116 citation statements)

References 51 publications

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“…However, Tamaki et al did not observe any difference in glucagon secretion in the Slc30a8-KO mice. Together with prior studies (8), these data suggest that the Zn 2+ cosecreted with insulin is not responsible for the suppressive effect of insulin secretion on glucagon secretion.…”

Section: Differing Phenotypessupporting

confidence: 49%

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Zinc, insulin, and the liver: a ménage à trois

O’Halloran¹,

Kebede²,

Philips³

et al. 2013

J. Clin. Invest.

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Section: Differing Phenotypessupporting

confidence: 49%

“…Slc30a8 deletion in mice decreases DCV Zn 2+ content (4,(7)(8)(9). A role for decreased Zn 2+ in DCV functional defects is not obvious, because some species (e.g., guinea pig) produce insulin molecules that do not bind to Zn 2+ but still maintain normal insulin secretion.…”

Section: Differing Phenotypesmentioning

confidence: 99%

Zinc, insulin, and the liver: a ménage à trois

O’Halloran¹,

Kebede²,

Philips³

et al. 2013

J. Clin. Invest.

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“…In two articles recently published in Diabetes, emphasis was placed on the modulation of glucagon secretion attributable to a paracrine effect of somatostatin under selected experimental conditions (1,2). In the present review, attention is drawn to prior publications compatible with such a view, but not cited in the two recent articles.…”

Section: Introductionmentioning

confidence: 97%

Paracrine control of glucagon release by somatostatin (Review)

Malaisse

2013

International Journal of Molecular Medicine

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Abstract. Emphasis was recently placed on the modulation of glucagon secretion attributable to a paracrine effect of somatostatin. This review draws attention to prior findings related to such a view. The effects of nutrient secretagogues upon insulin, somatostatin and glucagon release by the perfused pancreas are first considered. Three examples of paradoxical secretory responses of insulin-and glucagon-producing cells are then given. Further experiments dealing with the possible role of somatostatin upon glucagon release and the relevance of pancreatic compartmentation are also presented. It is concluded that these prior findings provide, within limits, support to the postulated paracrine role of somatostatin in the control of glucagon secretion. Contents

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“…The findings that glucose remains capable of inhibiting glucagon secretion in somatostatin-deficient islets [19] and in the presence of somatostatin receptor antagonists [20] also suggest that somatostatin released by the delta cells does not function as a 'switch-off' signal for glucagon release. Collectively, these data provide little evidence of a paracrine regulation of glucagon secretion by insulin at glucose concentrations at or below the threshold for stimulation of insulin or somatostatin release (6 mmol/l).…”

Section: Introductionmentioning

confidence: 99%

ATP-regulated potassium channels and voltage-gated calcium channels in pancreatic alpha and beta cells: similar functions but reciprocal effects on secretion

et al. 2014

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Closure of ATP-regulated K + channels (K ATP channels) plays a central role in glucose-stimulated insulin secretion in beta cells. K ATP channels are also highly expressed in glucagon-producing alpha cells, where their function remains unresolved. Under hypoglycaemic conditions, K ATP channels are open in alpha cells but their activity is low and only~1% of that in beta cells. Like beta cells, alpha cells respond to hyperglycaemia with K ATP channel closure, membrane depolarisation and stimulation of action potential firing. Yet, hyperglycaemia reciprocally regulates glucagon (inhibition) and insulin secretion (stimulation). Here we discuss how this conundrum can be resolved and how reduced K ATP channel activity, via membrane depolarisation, paradoxically reduces alpha cell Ca 2+ entry and glucagon exocytosis. Finally, we consider whether the glucagon secretory defects associated with diabetes can be attributed to impaired K ATP channel regulation and discuss the potential for remedial pharmacological intervention using sulfonylureas.

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Tolbutamide Controls Glucagon Release From Mouse Islets Differently Than Glucose

Cited by 81 publications

References 51 publications

Zinc, insulin, and the liver: a ménage à trois

Zinc, insulin, and the liver: a ménage à trois

Paracrine control of glucagon release by somatostatin (Review)

ATP-regulated potassium channels and voltage-gated calcium channels in pancreatic alpha and beta cells: similar functions but reciprocal effects on secretion

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