A novel GPR40 agonist, CNX-011-67, suppresses glucagon secretion in pancreatic islets under chronic glucolipotoxic conditions in vitro

Orexin-A (OXA) regulates food intake and energy homeostasis. It increases insulin secretion in vivo and in vitro, although controversial effects of OXA on plasma glucagon are reported. We characterized the effects of OXA on glucagon secretion and identify intracellular target molecules in glucagon-producing cells. Glucagon secretion from in situ perfused rat pancreas, isolated rat pancreatic islets, and clonal pancreatic A-cells (InR1-G9) were measured by RIA. The expression of orexin receptor 1 (OXR1) was detected by Western blot and immunofluorescence. The effects of OXA on cAMP, adenylate-cyclase-kinase (AKT), phosphoinositide-dependent kinase (PDK)-1, forkhead box O-1 (Foxo1), and cAMP response element-binding protein were measured by ELISA and Western blot. Intracellular calcium (Ca2+i) concentration was detected by fura-2and glucagon expression by real-time PCR. Foxo1 was silenced in InR1-G9 cells by transfecting cells with short interfering RNA. OXR1 was expressed on pancreatic A and InR1-G9 cells. OXA reduced glucagon secretion from perfused rat pancreas, isolated rat pancreatic islets, and InR1-G9 cells. OXA inhibited proglucagon gene expression via the phosphatidylinositol 3-kinase-dependent pathway. OXA decreased cAMP and Ca2+i concentration and increased AKT, PDK-1, and Foxo1 phosphorylation. Silencing of Foxo1 caused a reversal of the inhibitory effect of OXA on proglucagon gene expression. Our study provides the first in vitro evidence for the interaction of OXA with pancreatic A cells. OXA inhibits glucagon secretion and reduces intracellular cAMP and Ca2+i concentration. OXA increases AKT/PDK-1 phosphorylation and inhibits proglucagon expression via phosphatidylinositol 3-kinase- and Foxo-1-dependent pathways. As a physiological inhibitor of glucagon secretion, OXA may have a therapeutic potential to reduce hyperglucagonemia in type 2 diabetes.

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Regulation of insulin and glucagon secretion from rat pancreatic islets in vitro by somatostatin analogues

Regulatory Peptides ◽

10.1016/j.regpep.2006.07.006 ◽

2007 ◽

Vol 138 (1) ◽

pp. 1-9 ◽

Cited By ~ 19

Author(s):

E. Ludvigsen ◽

M. Stridsberg ◽

J.E. Taylor ◽

M.D. Culler ◽

K. Öberg ◽

...

Keyword(s):

Pancreatic Islets ◽

Glucagon Secretion ◽

Somatostatin Analogues ◽

Rat Pancreatic Islets ◽

Insulin And Glucagon Secretion

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Somatostatin Inhibits Insulin and Glucagon Secretion via Two Receptor Subtypes: An in Vitro Study of Pancreatic Islets from Somatostatin Receptor 2 Knockout Mice*

Endocrinology ◽

10.1210/endo.141.1.7263 ◽

2000 ◽

Vol 141 (1) ◽

pp. 111-117 ◽

Cited By ~ 132

Author(s):

M. Z. Strowski ◽

R. M. Parmar ◽

A. D. Blake ◽

J. M. Schaeffer

Keyword(s):

Insulin Secretion ◽

Pancreatic Islets ◽

Insulin Release ◽

Somatostatin Receptor ◽

Glucagon Secretion ◽

Endocrine Function ◽

Receptor Subtype ◽

Glucagon Release ◽

Glucagon And Insulin

Abstract Somatostatin (SST) potently inhibits insulin and glucagon release from pancreatic islets. Five distinct membrane receptors (SSTR1–5) for SST are known, and at least two (SSTR2 and SSTR5) have been proposed to regulate pancreatic endocrine function. Our current understanding of SST physiology is limited by the receptor subtype selectivity of peptidyl SST analogs, making it difficult to assign a physiological function to an identified SST receptor subtype. To better understand the physiology of SSTRs we studied the in vitro effects of potent subtype-selective nonpeptidyl SST analogs on the regulation of pancreatic glucagon and insulin secretion in wild-type (WT) and in somatostatin receptor 2 knockout (SSTR2KO) mice. There was no difference in basal glucagon and insulin secretion between islets isolated from SSTR2KO and WT mice; however, potassium/arginine-stimulated glucagon secretion was approximately 2-fold higher in islets isolated from SSTR2KO mice. Neither SST nor any SSTR-selective agonist inhibited basal glucagon or insulin release. SST-14 potently inhibited stimulated glucagon secretion in islets from WT mice and much less effectively in islets from SSTR2KO mice. The SSTR2 selective analog L-779,976 inhibited glucagon secretion in islets from WT, but was inactive in islets from SSTR2KO mice. L-817,818, an SSTR5 selective analog, slightly reduced glucagon release in both animal groups, whereas SSTR1, -3, and -4 selective analogs were inactive. SST and L-817,818 inhibited glucose stimulated insulin release in islets from WT and SSTR2KO mice. L-779,976 much less potently reduced insulin secretion from WT islets. In conclusion, our data demonstrate that SST inhibition of glucagon release in mouse islets is primarily mediated via SSTR2, whereas insulin secretion is regulated primarily via SSTR5.

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Characterization of Somatostatin Receptor Subtype-Specific Regulation of Insulin and Glucagon Secretion: An in Vitro Study on Isolated Human Pancreatic Islets

The Journal of Clinical Endocrinology & Metabolism ◽

10.1210/jc.2006-1578 ◽

2006 ◽

Vol 92 (2) ◽

pp. 673-680 ◽

Cited By ~ 65

Author(s):

Vandana Singh ◽

Mathias D. Brendel ◽

Sylvia Zacharias ◽

Stefan Mergler ◽

Henning Jahr ◽

...

Keyword(s):

Pancreatic Islets ◽

Somatostatin Receptor ◽

In Vitro Study ◽

Glucagon Secretion ◽

Receptor Subtype ◽

Human Pancreatic Islets ◽

Insulin And Glucagon Secretion ◽

Specific Regulation

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In pancreatic islets from type 2 diabetes patients, the dampened circadian oscillators lead to reduced insulin and glucagon exocytosis

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1916539117 ◽

2020 ◽

Vol 117 (5) ◽

pp. 2484-2495 ◽

Cited By ~ 12

Author(s):

Volodymyr Petrenko ◽

Nikhil R. Gandasi ◽

Daniel Sage ◽

Anders Tengholm ◽

Sebastian Barg ◽

...

Keyword(s):

Type 2 Diabetes ◽

Insulin Secretion ◽

Pancreatic Islets ◽

Islet Cell ◽

Glucagon Secretion ◽

Molecular Clocks ◽

Clock Proteins ◽

Temporal Profiles

Circadian clocks operative in pancreatic islets participate in the regulation of insulin secretion in humans and, if compromised, in the development of type 2 diabetes (T2D) in rodents. Here we demonstrate that human islet α- and β-cells that bear attenuated clocks exhibit strongly disrupted insulin and glucagon granule docking and exocytosis. To examine whether compromised clocks play a role in the pathogenesis of T2D in humans, we quantified parameters of molecular clocks operative in human T2D islets at population, single islet, and single islet cell levels. Strikingly, our experiments reveal that islets from T2D patients contain clocks with diminished circadian amplitudes and reduced in vitro synchronization capacity compared to their nondiabetic counterparts. Moreover, our data suggest that islet clocks orchestrate temporal profiles of insulin and glucagon secretion in a physiological context. This regulation was disrupted in T2D subjects, implying a role for the islet cell-autonomous clocks in T2D progression. Finally, Nobiletin, an agonist of the core-clock proteins RORα/γ, boosted both circadian amplitude of T2D islet clocks and insulin secretion by these islets. Our study emphasizes a link between the circadian clockwork and T2D and proposes that clock modulators hold promise as putative therapeutic agents for this frequent disorder.

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339-LB: Modulation of Insulin and Glucagon Secretion by Optogenetic Control of Delta-Cell Electrical Activity in Pancreatic Islets

Diabetes ◽

10.2337/db19-339-lb ◽

2019 ◽

Vol 68 (Supplement 1) ◽

pp. 339-LB

Author(s):

HAIQIANG DOU ◽

CAROLINE A. MIRANDA ◽

QUAN ZHANG ◽

PATRIK RORSMAN ◽

JOHAN TOLö

Keyword(s):

Electrical Activity ◽

Pancreatic Islets ◽

Glucagon Secretion ◽

Insulin And Glucagon Secretion ◽

Delta Cell ◽

Optogenetic Control

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Inhibition of glucagon secretion by diazoxide in vitro

Diabetes ◽

10.2337/diabetes.28.1.26 ◽

1979 ◽

Vol 28 (1) ◽

pp. 26-31 ◽

Cited By ~ 8

Author(s):

E. Urdanivia ◽

S. Pek ◽

J. C. Santiago

Keyword(s):

Glucagon Secretion

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Development of a Bioartificial Vascular Pancreas

Journal of Tissue Engineering ◽

10.1177/20417314211027714 ◽

2021 ◽

Vol 12 ◽

pp. 204173142110277

Author(s):

Edward X Han ◽

Juan Wang ◽

Mehmet Kural ◽

Bo Jiang ◽

Katherine L Leiby ◽

...

Keyword(s):

Type 1 Diabetes ◽

Pancreatic Islets ◽

Vascular Graft ◽

Term Treatment ◽

Diffusion Limitations ◽

Human Scale ◽

Arterial Blood ◽

Long Term Treatment

Transplantation of pancreatic islets has been shown to be effective, in some patients, for the long-term treatment of type 1 diabetes. However, transplantation of islets into either the portal vein or the subcutaneous space can be limited by insufficient oxygen transfer, leading to islet loss. Furthermore, oxygen diffusion limitations can be magnified when islet numbers are increased dramatically, as in translating from rodent studies to human-scale treatments. To address these limitations, an islet transplantation approach using an acellular vascular graft as a vascular scaffold has been developed, termed the BioVascular Pancreas (BVP). To create the BVP, islets are seeded as an outer coating on the surface of an acellular vascular graft, using fibrin as a hydrogel carrier. The BVP can then be anastomosed as an arterial (or arteriovenous) graft, which allows fully oxygenated arterial blood with a pO2 of roughly 100 mmHg to flow through the graft lumen and thereby supply oxygen to the islets. In silico simulations and in vitro bioreactor experiments show that the BVP design provides adequate survivability for islets and helps avoid islet hypoxia. When implanted as end-to-end abdominal aorta grafts in nude rats, BVPs were able to restore near-normoglycemia durably for 90 days and developed robust microvascular infiltration from the host. Furthermore, pilot implantations in pigs were performed, which demonstrated the scalability of the technology. Given the potential benefits provided by the BVP, this tissue design may eventually serve as a solution for transplantation of pancreatic islets to treat or cure type 1 diabetes.

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Somatostatin and insulin mediate glucose-inhibited glucagon secretion in the pancreatic α-cell by lowering cAMP

AJP Endocrinology and Metabolism ◽

10.1152/ajpendo.00344.2014 ◽

2015 ◽

Vol 308 (2) ◽

pp. E130-E143 ◽

Cited By ~ 40

Author(s):

Amicia D. Elliott ◽

Alessandro Ustione ◽

David W. Piston

Keyword(s):

Metabolic Disease ◽

Pancreatic Islets ◽

Insulin Signaling ◽

Glucagon Secretion ◽

Critical Component ◽

Signaling Mechanisms ◽

Independent Mechanism ◽

Glucagon Suppression ◽

Phosphodiesterase 3B ◽

And Function

The dysregulation of glucose-inhibited glucagon secretion from the pancreatic islet α-cell is a critical component of diabetes pathology and metabolic disease. We show a previously uncharacterized [Ca2+]i-independent mechanism of glucagon suppression in human and murine pancreatic islets whereby cAMP and PKA signaling are decreased. This decrease is driven by the combination of somatostatin, which inhibits adenylyl cyclase production of cAMP via the Gαi subunit of the SSTR2, and insulin, which acts via its receptor to activate phosphodiesterase 3B and degrade cytosolic cAMP. Our data indicate that both somatostatin and insulin signaling are required to suppress cAMP/PKA and glucagon secretion from both human and murine α-cells, and the combination of these two signaling mechanisms is sufficient to reduce glucagon secretion from isolated α-cells as well as islets. Thus, we conclude that somatostatin and insulin together are critical paracrine mediators of glucose-inhibited glucagon secretion and function by lowering cAMP/PKA signaling with increasing glucose.

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