Somatostatin receptor subtype-2-deficient mice with diet-induced obesity have hyperglycemia, nonfasting hyperglucagonemia, and decreased hepatic glycogen deposition.

Hypersecretion of glucagon contributes to abnormally increased hepatic glucose output in type 2 diabetes. Somatostatin (SST) inhibits murine glucagon secretion from isolated pancreatic islets via somatostatin receptor subtype-2 (sst2). Here, we characterize the role of sst2 in controlling glucose homeostasis in mice with diet-induced obesity. Sst2-deficient (sst2(-/-)) and control mice were fed high-fat diet for 14 wk, and the parameters of glucose homeostasis were monitored. Hepatic glycogen and lipid contents were quantified enzymatically and visualized histomorphologically. Enzymes regulating glycogen and lipid synthesis and breakdown were measured by real-time PCR and/or Western blot. Gluconeogenesis and glycogenolysis were determined from isolated primary hepatocytes and glucagon or insulin secretion from isolated pancreatic islets. Nonfasting glucose, glucagon, and fasting nonesterified fatty acids of sst2(-/-) mice were increased. Inhibition of glucagon secretion from sst2-deficient pancreatic islets by glucose or somatostatin was impaired. Insulin less potently reduced blood glucose concentration in sst2-deficient mice as compared with wild-type mice. Sst2-deficient mice had decreased nonfasting hepatic glycogen and lipid content. The activity/expression of enzymes controlling hepatic glycogen synthesis of sst2(-/-) mice was decreased, whereas enzymes facilitating glycogenolysis and lipolysis were increased. Somatostatin and an sst2-selective agonist decreased glucagon-induced glycogenolysis, without influencing de novo glucose production using cultured primary hepatocytes. This study demonstrates that ablation of sst2 leads to hyperglucagonemia. Increased glucagon concentration is associated with impaired glucose control in sst2(-/-) mice, resulting from decreased hepatic glucose storage, increased glycogen breakdown, and reduced lipid accumulation. Sst2 may constitute a therapeutic target to lower hyperglucagonemia in type 2 diabetes.

Characterization of somatostatin receptor subtype-specific regulation of insulin and glucagon secretion: an in vitro study on isolated human pancreatic islets.

INTRODUCTION: Pancreatic A- and B-cells express somatostatin receptors (SSTRs). Five pharmacologically distinct SSTR subtypes are known (SSTR1-SSTR5). In rodents, SSTR2 inhibits glucagon secretion, whereas SSTR5 suppresses the release of insulin. Human pancreatic A- and B-cells express SSTR1-3 and SSTR5; however, their contribution to the regulation of glucagon and insulin secretion is not well known. AIM OF THE STUDY: The goal of this study was to characterize the role of individual SSTR subtypes in regulating human glucagon and insulin secretion in vitro. METHODS: Human pancreatic islets were isolated from healthy donors and incubated with somatostatin, SSTR1-3-selective and SSTR5-selective agonists, or an SSTR2-selective antagonist (DC-41-33). Stimulation of insulin secretion was induced by glucose (10, 20 mm) alone or in combination with 10 nm exendin-4 or 10 mm L-arginine. Glucagon secretion was induced by 20 mm L-arginine. Basal secretion of insulin and glucagon was measured at 2.8 or 3.3 mm glucose. RESULTS: SSTR1-, SSTR2-, and SSTR5-selective agonists inhibited insulin secretion with the following order of potency: SSTR2 (EC50, 0.08 nm) > SSTR5 (EC50, 5.3 nm) > SSTR1 (EC50, 35 nm). Glucagon secretion was inhibited by SSTR-selective agonists with the following order of potency: SSTR2 (EC50, 0.05 nm) > SSTR1 (EC50, 1.8 nm) > SSTR5 (EC50, 28 nm). DC-41-33 dose-dependently reversed the effects of the SSTR2-selective agonist on insulin and glucagon secretion. CONCLUSION: Our study demonstrates that SSTR2-agonist is the most potent inhibitor of insulin and glucagon secretion from isolated human pancreatic islets. Furthermore, we identify SSTR1- and SSTR5-selective agonists as additional inhibitors of insulin and glucagon secretion from human pancreas.