Glucagon Deficiency

About: Glucagon Deficiency is a research topic. Over the lifetime, 111 publications have been published within this topic receiving 6990 citations.

Lower blood glucose, hyperglucagonemia, and pancreatic α cell hyperplasia in glucagon receptor knockout mice

Abstract: Glucagon, the counter-regulatory hormone to insulin, is secreted from pancreatic α cells in response to low blood glucose. To examine the role of glucagon in glucose homeostasis, mice were generated with a null mutation of the glucagon receptor (Gcgr−/−). These mice display lower blood glucose levels throughout the day and improved glucose tolerance but similar insulin levels compared with control animals. Gcgr−/− mice displayed supraphysiological glucagon levels associated with postnatal enlargement of the pancreas and hyperplasia of islets due predominantly to α cell, and to a lesser extent, δ cell proliferation. In addition, increased proglucagon expression and processing resulted in increased pancreatic glucogen-like peptide 1 (GLP-1) (1–37) and GLP-1 amide (1–36 amide) content and a 3- to 10-fold increase in circulating GLP-1 amide. Gcgr−/− mice also displayed reduced adiposity and leptin levels but normal body weight, food intake, and energy expenditure. These data indicate that glucagon is essential for maintenance of normal glycemia and postnatal regulation of islet and α and δ cell numbers. Furthermore, the lean phenotype of Gcgr−/− mice suggests glucagon action may be involved in the regulation of whole body composition.

Role of Glucagon, Catecholamines, and Growth Hormone in Human Glucose Counterregulation: EFFECTS OF SOMATOSTATIN AND COMBINED α- AND β-ADRENERGIC BLOCKADE ON PLASMA GLUCOSE RECOVERY AND GLUCOSE FLUX RATES AFTER INSULIN-INDUCED HYPOGLYCEMIA

Abstract: To further characterize mechanisms of glucose counterregulation in man, the effects of pharmacologically inducd deficiencies of glucagon, growth hormone, and catecholamines (alone and in combination) on recovery of plasma glucose from insulin-induced hypoglycemia and attendant changes in isotopically ([3-(3)H]glucose) determined glucose fluxes were studied in 13 normal subjects. In control studies, recovery of plasma glucose from hypoglycemia was primarily due to a compensatory increase in glucose production; the temporal relationship of glucagon, epinephrine, cortisol, and growth hormone responses with the compensatory increase in glucose appearance was compatible with potential participation of all these hormones in acute glucose counterregulation. Infusion of somatostatin (combined deficiency of glucagon and growth hormone) accentuated insulin-induced hypoglycemia (plasma glucose nadir: 36+/-2 ng/dl during infusion of somatostatin vs. 47+/-2 mg/dl in control studies, P < 0.01) and impaired restoration of normoglycemia (plasma glucose at min 90: 73+/-3 mg/dl at end of somatostatin infusion vs. 92+/-3 mg/dl in control studies, P<0.01). This impaired recovery of plasma glucose was due to blunting of the compensatory increase in glucose appearance since glucose disappearance was not augmented, and was attributable to suppression of glucagon secretion rather than growth hormone secretion since these effects of somatostatin were not observed during simultaneous infusion of somatostatin and glucagon whereas infusion of growth hormone along with somatostatin did not prevent the effect of somatostatin. The attenuated recovery of plasma glucose from hypoglycemia observed during somatostatin-induced glucagon deficiency was associated with plasma epinephrine levels twice those observed in control studies. Infusion of phentolamine plus propranolol (combined alpha-and beta-adrenergic blockade) had no effect on plasma glucose or glucose fluxes after insulin administration. However, infusion of somatostatin along with both phentolamine and propranolol further impaired recovery of plasma glucose from hypoglycemia compared to that observed with somatostatin alone (plasma glucose at end of infusions: 52+/-6 mg/dl for somatostatin-phentolamine-propranolol vs. 72+/-5 mg/dl for somatostatin alone, P < 0.01); this was due to further suppression of the compensatory increase in glucose appearance (maximal values: 1.93+/-0.41 mg/kg per min for somatostatin-phentolamine-propranolol vs. 2.86+/-0.32 mg/kg per min for somatostatin alone, P < 0.05). These results indicate that in man (a) restoration of normoglycemia after insulin-induced hypoglycemia is primarily due to a compensatory increase in glucose production; (b) intact glucagon secretion, but not growth hormone secretion, is necessary for normal glucose counterregulation, and (c) adrenergic mechanisms do not normally play an essential role in this process but become critical to recovery from hypoglycemia when glucagon secretion is impaired.

Prevention of human diabetic ketoacidosis by somatostatin. Evidence for an essential role of glucagon

Abstract: To evaluate the role of glucagon in the pathogenesis of diabetic ketoacidosis in man, we studied the effect of suppression of glucagon secretion by somatostatin on changes in plasma beta-hydroxybutyrate and glucose concentrations (as well as changes in their precursors) after acute withdrawal of insulin from seven patients with juvenile-type diabetes. Suppression of glucagon secretion prevented the development of ketoacidosis for 18 hours after acute insulin withdrawal, whereas in control studies mild ketoacidosis occurred 10 hours after insulin was stopped. Plasma beta-hydroxybutyrate, glucose, free fatty acid, and glycerol levels were all markedly lower during suppression of glucagon secretion (p smaller than 0.001), whereas plasma alanine levels were higher (p smaller than 0.001). These studies indicate that insulin lack per se does not lead to fulminant diabetic ketoacidosis in man and that glucagon, by means of its gluconeogenic, ketogenic, and lipolytic actions, is a prerequisite to the development of this condition.

Role of Hyperglucagonemia in Maintenance of Increased Rates of Hepatic Glucose Output in Type II Diabetics

Abstract: Elevated rates of basal hepatic glucose output (bHGO) are significantly correlated with the fasting serum glucose (FSG) level in subjects with non-insulin-dependent diabetes mellitus (NIDDM). This observation suggests that bHGO is a major determinant of the severity of the diabetic state in these subjects. In addition, basal glucagon levels (bGL) are higher in these diabetics than in control subjects, despite the concurrent basal hyperglycemia and hyperinsulinemia, two factors known to suppress glucagon secretion. Although bGL is responsible for sustaining two-thirds of bHGO in normal humans, its role in sustaining elevated rates of bHGO in NIDDM has not been previously defined. To this end, we have studied 13 normal and 10 NIDDM subjects; mean FSG levels were 90 +/- 2 and 262 +/- 21 mg/dl, respectively (P less than .001). The mean fasting serum insulin and glucagon levels were higher in the diabetics than in the controls: 17 +/- 2 vs. 9 +/- 1 microU/ml (P less than .01) and 208 +/- 37 vs. 104 +/- 15 pg/ml (P less than .01), respectively. On separate days, HGO was assessed isotopically (with 3-[3H]glucose) in the basal state and during infusion of somatostatin (SRIF) (600 micrograms/h) alone and in conjunction with replacement infusions of glucose and insulin. The results demonstrate that bHGO is higher in diabetics than in controls (145 +/- 12 vs. 89 +/- 3 mg X m-2 X min-1, P less than .01); during infusion of SRIF alone, HGO was suppressed by 25% (P less than .05) and 34% (P less than .05) of the basal value in controls and diabetics, respectively; when the studies were repeated with glucose levels held constant at or near the FSG level by the glucose-clamp technique, the pattern and degree of HGO suppression was similar to that obtained by infusion of SRIF alone; during isolated glucagon deficiency (SRIF + insulin, 5 mU X m-2 min-1, with serum glucose maintained at basal level), HGO was suppressed by 71 +/- 8% of the basal value in controls (P less than .001) and by 58 +/- 7% in diabetics (P less than .001); and when isolated glucagon deficiency with similar hyperglycemia was created in control subjects, HGO was suppressed by 87% of the basal value.(ABSTRACT TRUNCATED AT 250 WORDS)

The role of insulin and glucagon in the regulation of basal glucose production in the postabsorptive dog.

Abstract: The aim of the present experiments was to determine the role of insulin and glucagon in the regulation of basal glucose production in dogs fasted overnight. A deficiency of either or both pancreatic hormones was achieved by infusin somatostatin (1 mug/kg per min), a potent inhibitor of both insulin and glucagon secretion, alone or in combination with intraportal replacement infusions of either pancreatic hormone. Infusion of somatostatin alone caused the arterial levels of insulin and glucagon to drop rapidly by 72+/-6 and 81+/-8%, respectively. Intraportal infusion of insulin and glucagon at rates of 400 muU/kg per min and 1 ng/kg per min, respectively, resulted in the maintenance of the basal levels of each hormone. Glucose production was measured using tracer (primed constant infusion of [3-3H]glucose) and arteriovenous difference techniques. Isolated glucagon deficiency resulted in a 35+/-5% (P less than 0.05) rapid and sustained decrease in glucose production which was abolished upon restoration of the plasma glucagon level. Isolated insulin deficiency resulted in a 52+/-16% (P less than 0.01) increase in the rate of glucose production which was abolished when the insulin level was restored. Somatostatin had no effect on glucose production when the changes in the pancreatic hormone levels which it normally induces were prevented by simultaneous intraportal infusion of both insulin and glucagon. In conclusion, in the anesthetized dog fasted overnight; (a) basal glucagon is responsible for at least one-third of basal glucose production, (b) basal insulin prevents the increased glucose production which would result from the unrestrained action of glucagon, and (c) somatostatin has no acute effects on glucose turnover other than those it induces through perturbation of pancreatic hormone secretion. This study indicates that the opposing actions of the two pancreatic hormones are important in the regulation of basal glucose production in the postabsorptive state.