Endogenous islet uncoupling protein-2 expression and loss of glucose homeostasis in ob/ob mice

We hypothesized that the loss of glucose homeostasis in ob/ob mice is associated with upregulation of islet uncoupling protein-2 (UCP2) expression, leading to impaired glucose-stimulated insulin secretion (GSIS). Changes in glucose homeostasis in lean and ob/ob mice from 5 to 16 weeks were assessed by fasting blood glucose, plasma insulin, oral glucose tolerance, and tissue insulin sensitivity. In vitro GSIS and ATP content were assayed in isolated islets, while UCP2 expression was determined by quantitative real-time PCR and immunoblotting. Short-term reduction of UCP2 expression was achieved through transfection of islets with specific small interfering RNA. Insulin resistance was detected in 5-week-old ob/ob mice, but GSIS and blood glucose levels remained normal. By 8 weeks of age, ob/ob mice displayed fasting hyperglycemia, hyperinsulinemia and glucose intolerance, and also had elevated non-esterified fatty acid concentration in plasma. In vitro, GSIS and ATP generation were impaired in ob/ob islets. Islet UCP2 expression was elevated at 5 and 8 weeks of age. Short-term knockdown of islet UCP2 increased GSIS in islets of lean mice, but had no effect in islets from ob/ob mice. Loss of glucose homeostasis and impairment of insulin secretion from isolated islets at 8 weeks in ob/ob mice is preceded by an increase in UCP2 expression in islets. Moreover, the glucolipotoxic conditions observed are predicted to increase UCP2 activity, contributing to lower islet ATP and GSIS.     

Pancreatic islets of obese hyperglycemic mice (ob/ob).

The development of the obesity-associated hyperglycemic syndrome in ob/ob mice, genetically determined, was observed over time by a combined functional and structural study of pancreatic islets. Islet areas increased with advancing age in ob/ob mice from 2 times at 1 month to 30 times at 6 months of age the size of lean mouse islets. Islet areas apparently increased more than pancreatic insulin content in ob/ob mice. Glucose and insulin tolerance tests were performed to study in vivo responses to glucose and insulin, respectively, in 1-, 3-, and 6-month-old mice. With ob/ob mice, glucose tolerance tests revealed more elevation of plasma glucose than in lean mice, the lean mice revealing more elevated plasma insulin than the obese mice. In insulin tolerance tests, lean mice presented marked hypoglycemia, whereas ob/ob mice revealed slightly higher plasma glucose at 1 month of age but three to four times higher amounts than that of lean mice at 6 months of age. Thus, increasing insulin resistance in ob/ob mice older than 3 months is associated with progressively increasing islet area, which contains proportionally less insulin than that of lean mouse pancreas. The data suggest that insulin resistance in ob/ob mice progressively develops up to 6 months of age and that marked islet hyperplasia is likely in response to sustained hyperglycemia, leading to hyperinsulinemia and eventual marked obesity.     

Effects of growth hormone-releasing hormone on the secretion of islet hormones and on glucose homeostasis in lean and genetically obese-diabetic (ob/ob) mice and normal rats

The effect of synthetic human growth hormone-releasing hormone(1-40) (hGHRH-40) on the function of the endocrine pancreas and on glucose homeostasis in lean and genetically obese-diabetic (ob/ob) mice and normal rats has been examined. The addition of 1 mumol hGHRH-40/1 to incubated islets from normal lean mice increased insulin release by 90 and 37% at 5.6 and 16.7 mmol glucose/l respectively. Lower concentrations of hGHRH-40 did not affect insulin release. hGHRH-40 (1 mumol/l) increased pancreatic polypeptide release by 50% at 5.6 mmol glucose/l. A range of concentrations of hGHRH-40 (1 nmol/l-1 mumol/l) reduced glucagon release by 42-73% at 5.6 mmol glucose/l, and by 38-70% at 16.7 mmol glucose/l. Somatostatin release was increased (eightfold) by 1 mumol hGHRH-40/1 at 5.6 mmol glucose/1, but at 1 nmol hGHRH-40/1 somatostatin release was reduced (by greater than 50%). At 16.7 mmol glucose/litre 0.01-1 mumol hGHRH-40/1 increased somatostatin release (three- to fourfold), but 1 nmol hGHRH-40/1 produced a reduction of 50%. In vivo, administration of hGHRH-40 (50 micrograms/kg body weight i.p.) to fasted lean and ob/ob mice did not alter basal plasma concentrations of glucose and insulin, or the glucose and insulin responses to a concomitant i.p. glucose challenge. Intravenous injection of hGHRH-40 (20 micrograms/kg body weight) to anaesthetized rats increased plasma concentrations of insulin in the hepatic portal vein. A lower dose of hGHRH-40 (0.2 micrograms/kg) was ineffective, and neither dose of hGHRH-40 altered plasma glucose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of streptozotocin on glucose metabolism, insulin response, and adiposity in ob/ob mice.

To determine whether hyperglycemia in the obese hyperglycemic (ob/ob) mouse is related to enhanced activity of the pancreatic beta cell, streptozotocin (175 mg/kg) was injected into lean and ob/ob mice at 8 wk of age. The influence of this injection upon glucose metabolism, adipose cellularity, pancreatic morphology and immunoreactive insulin (IRI) release from isolated pancreatic islets was measured. The plasma glucose levels before and after an oral glucose load were elevated in lean and decreased in ob/ob mice 2 wk after treatment with streptozotocin. By 5 wk after this treatment, a reduced pancreatic islet size, beta cell number and a decreased pancreatic islet IRI release were present in both lean and ob/ob mice. At this time, plasma glucose was still elevated in lean, but depressed in ob/ob mice and the insulin responsiveness in muscle and adipocytes was unchanged. Hyperglycemia abates in the ob/ob mouse as hypersecretion of insulin is diminished, but these observations may not be directly related, since streptozotocin affects key metabolic activities of the livers as well as the pancreatic beta cell. The progression of obesity and status of adipose cellularity are not directly related to hyper-insulinemia, since they are not altered following streptozotocin treatment.     

Increased responsiveness to the hyperglycemic, hyperglucagonemic and hyperinsulinemic effects of circulating norepinephrine in ob/ob mice

OBJECTIVE: Several studies have implicated increased sympathetic tone as a contributing factor to the hyperglycemia and hyperglucagonemia of ob/ob mice. However, the responsiveness of plasma glucose, insulin and glucagon to circulating norepinephrine (NE) in ob/ob vs normal lean mice has never been described. Therefore, the present study investigated the effect of a 15 min intravenous NE infusion (1 pmol/min/g) on plasma glucose, insulin and glucagon in anesthetized lean, ob/ob, ob/ob-concurrent yohimbine (alpha(2) antagonist) treated, and ob/ob-chronically sympatholytic dopamine agonist treated (for 14 days prior to infusion) mice. In an effort to gain insight into a possible relation between norepinephrine, hyperglucagonemia and hyperinsulinemia in ob/ob mice, this study also examined the isolated islet responses to NE and glucagon in lean, ob/ob and ob/ob-sympatholytic dopamine agonist treated mice. RESULTS: Basal humoral values of glucose, insulin and glucagon were all elevated in ob/ob vs lean mice (by 63, 1900 and 63%, respectively, P<0.01). However, NE infusion further increased levels of glucose, insulin and glucagon in ob/ob (by 80, 90 and 60%, respectively, P<0.05) but not in lean mice (between group difference for all parameters P<0.05). Acute concurrent yohimbine treatment as well as chronic prior sympatholytic dopamine agonist treatment (bromocriptine plus SKF38393) simultaneously strongly aborgated or abolished all these humoral hypersensitivity responses to intravenous NE in ob/ob mice (P<0.05). Clamping the plasma glucose level in untreated ob/ob mice at a high level (30 mM) established by NE infusion did not significantly alter the plasma insulin level, suggesting that some other influence of NE was responsible for this insulin effect. Direct NE administration at 1 microM to islets from lean and ob/ob mice inhibited 15 mM glucose-stimulated insulin secretion in both groups, but at 0.1 microM it was inhibitory only in islets from ob/ob mice. However, glucagon (10 nM) increased 15 mM glucose-stimulated insulin secretion in ob/ob (by 170%, P<0.05) but not lean mice (between group difference P<0.05). CONCLUSION: These findings suggest that hypersensitivity to circulating NE may potentiate hyperglycemia and hyperglucagonemia in ob/ob mice, and the subsequent hyperglucagonemia coupled with increased islet beta-cell insulin secretory responsiveness to glucagon in ob/ob mice may support hyperinsulinemia, thus explaining the increased plasma insulin level response to intravenous NE in these animals. These findings further support a role for increased peripheral noradrenergic activities in the development and maintenance of the hyperglycemic, hyperglucagonemic and hyperinsulinemic state, characteristic of type 2 diabetes.     

Insulin secretion and the morphological and metabolic characteristics of pancreatic islets of hyperthyroid ob/ob mice.

Thyroxine treatment induced experimental hyperthyroidism in ob/ob mice, inhibited glucose-induced insulin secretion from the isolated perfused ob/ob mouse pancreas, and reduced total pancreas insulin content. In contrast, glucose-induced insulin release from incubated pancreatic islets and insulin content of pancreatic islets from ob/ob mice isolated by freehand microdissection were not reduced after thyroxine treatment when expressed per microgram dry islet. Histological examination of the ob/ob mouse pancreas revealed islets without degenerative lesions of islet cells. Granularity of beta cells was well preserved. The average number of pancreatic islets was unchanged. However, the beta cell area was significantly decreased in relation to the total pancreatic parenchyma after thyroxine treatment. This implies that insulin release and content per pancreatic islet was half of that of the controls. ATP content of islets was slightly reduced. Glucose oxidation and glucose utilization by islets from treated mice were slightly increased. Thyroxine treatment of the animals did not abolish the stimulation of 45Ca2+ uptake by glucose, but it did suppress the potentiating effect of fasting on the stimulatory effect of glucose on 45Ca2+ uptake. The metabolic characteristics of islets from experimentally hyperthyroid mice are those of all hyperthyroid tissues. The results provide no evidence for the view that the effects of thyroxine treatment may be due to disturbed metabolic function or energy deprivation of pancreatic islets. Inhibition of insulin secretion from the pancreas after thyroxine administration is apparently due to a reduction in pancreas insulin content and a diminished pancreatic islet volume. Reduced pancreatic islet volume represents most probably a reduction of individual islet cell volume.     

Long-term leptin treatment of ob/ob mice improves glucose-induced insulin secretion.

OBJECTIVE: Previous studies have demonstrated that leptin inhibits glucose-stimulated insulin secretion from isolated islets, although a lack of leptin effect on insulin secretion has also been reported. The effect of long term in vivo leptin treatment of insulin secretion has, however, not been established. Therefore, in the present study, we have evaluated the effect of long term in vivo treatment of leptin on glucose-induced insulin secretion in ob/ob mice. METHODS: After 7 days' treatment of leptin (100 microg daily s.c.), insulin release was measured in isolated islets by batch incubation followed by radioimmunoassay. Glucose utilization and oxidation were measured by measuring the formation of (3)H(2)O and (14)CO(2) from [5-(3)H] and [U-(14)C] glucose, respectively. Glucose-6-phosphatase activity was measured by measuring the conversion of (14)C-glucose-6-P to (14)C-glucose. In addition, immunohistochemistry of pancreatic specimens was undertaken for study of expression of insulin, GLUT-2 and hormone-sensitive lipase (HSL). RESULTS: Leptin treatment significantly improved insulin secretion both at 5.5 mM (by 15%; P<0.05) and 16.7 mM (by 85%; P<0.001) glucose, compared to vehicle-treated controls. Furthermore, whereas leptin treatment did not affect islet insulin or DNA contents, a significant decrease in islet triglyceride content and glucose-6-phosphatase activity was observed. Moreover, the immunocytochemical data revealed an increased immunostaining for insulin, GLUT-2 and hormone-sensitive lipase (HSL) in islets from leptin-treated ob/ob mice. CONCLUSION: The results suggest that long-term leptin treatment of ob/ob mice improves glucose-stimulated insulin secretion in parallel with reduced glucose-6-phosphatase activity, increased HSL and decreased triglyceride levels in islets. These perturbations may explain the improvement of glucose-stimulated insulin secretion induced by leptin.     

Insulin releasing effects of adrenocorticotropin (ACTH 1-39) and ACTH fragments (1-24 and 18-39) in lean and genetically obese hyperglycaemic (ob/ob) mice

An excessive insulin releasing effect of adrenocorticotropic hormone (ACTH) and ACTH fragments has been considered as a possible factor contributing to the hyperinsulinaemia of genetically obese hyperglycaemic (ob/ob) mice. To investigate this possibility, plasma glucose and insulin responses of 11- to 14-week-old fed lean and ob/ob mice were examined after intraperitoneal administration of ACTH 1-39, ACTH 1-24 and ACTH 18-39, each at a dose of 25 nmol/mouse (50-115 micrograms/mouse). ACTH 1-39 produced a marked and rapid increase of plasma insulin in both lean and ob/ob mice, the effect being much greater in the ob/ob mutant (maximum increases of 5.5 +/- 1.5 and 46.1 +/- 4.1 ng/ml at 10 min in lean and ob/ob mice respectively, P less than 0.001). In lean mice plasma glucose concentrations showed a protracted decreased (maximum decrease of 3.7 +/- 0.5 mmol/l at 120 min), whereas glucose concentrations were increased (maximum increase of 4.2 +/- 1.3 mmol/l at 60 min) in ob/ob mice. ACTH 1-24 produced qualitatively similar but generally smaller effects than ACTH 1-39, while ACTH 18-39 did not significantly affect glucose and insulin concentrations. In 24 h fasted mice, ACTH 1-39 produced similar but generally smaller effects than in fed mice. The results suggest that the effects of ACTH on glucose and insulin homoeostasis are conferred by the N-terminal 1-24 sequence, and ACTH may exert acute effects which contribute to the hyperinsulinaemia and hyperglycaemia of ob/ob mice.     

Effects of dexamethasone on glucose transport by skeletal muscles of obese (ob/ob) mice

Adrenalectomy normalized basal and insulin-stimulated glucose transport in the perfused hindquarter of the obese (ob/ob) mouse. Dexamethasone treatment of adrenalectomized obese mice for 9 days significantly reduced both the basal and insulin-stimulated uptake of (3H)-2-deoxy-D-glucose in hindlimbs of adrenalectomized mice to levels similar to those of intact ob/ob mice. Five hours after injection of dexamethasone in vivo and following 5 hours of perfusion in vitro there was a 10 percent reduction in basal 2-deoxy-D-glucose uptake in both groups. In muscles perfused with dexamethasone in vitro, the stimulation of 2-deoxy-D-glucose uptake by insulin was greater than in those muscles perfused with vehicle alone. Five hours of treatment in vivo also resulted in a significant increase in liver tyrosine aminotransferase activity, and a decrease in muscle glycogen synthetase activity ratio. These data suggest that the effect of glucocorticoids on lowering glucose transport in the skeletal muscle of obese ob/ob mice is a direct one.     

Metabolic basis for the diabetogenic action of growth hormone in the obese (ob/ob) mouse

The ob/ob mouse responds predictably to chronic treatment with large doses of pituitary GH with marked hyperglycemia and decreased glucose tolerance. The purpose of the present study was to characterize the metabolic alterations produced by GH that lead to this diabetogenic response in the ob/ob mouse in order to determine whether this animal might serve as a useful model for the study of the cellular mechanisms involved in the diabetogenic action of GH. Female ob/ob mice were treated sc for 3 days with either saline or 200 micrograms/day S-carboxymethylated human GH (RCM-hGH), a diabetogenic GH derivative lacking significant growth-promoting or insulin-like activities. Six hours before the start of the experiment, the animals were given a sc injection of 2 micrograms dexamethasone and deprived of food. RCM-hGH treatment produced marked increases in fasting blood glucose and plasma insulin concentrations, but had no effect on plasma glucagon or serum insulin-like growth factor I levels. It had no effect on liver glycogen level or in vitro hepatic glucose production in the absence or presence of pyruvate and lactate added to the incubation medium. By contrast, the in vitro stimulatory effects of insulin on [14C] glucose oxidation by isolated soleus muscle or segments of parametrial fat were greatly attenuated by RCM-hGH treatment, without changes in rates of basal glucose oxidation. This change in peripheral tissue responsiveness to insulin does not appear to involve glucose transport, since the in vitro stimulation by insulin of 3-O-[14C]methylglucose transport into isolated diaphragm muscle was not altered by RCM-hGH treatment. Moreover, the RCM-hGH-induced reduction in adipose tissue responsiveness to insulin does not appear to be mediated by a reduction in insulin binding, since [125I]iodoinsulin binding to adipocytes isolated from RCM-hGH-treated mice was similar to that to cells from saline-treated animals. Interestingly, the reduction in responsiveness to insulin seen with segments of adipose tissue from RCM-hGH-treated animals was not found with isolated adipocytes prepared from such tissue by collagenase digestion. These results suggest that the hyperglycemia and glucose intolerance produced in ob/ob mice by chronic GH treatment result primarily from increased peripheral tissue insulin resistance. Therefore, the ob/ob mouse provides a useful model to elucidate the cellular mechanism(s) of this aspect of the diabetogenic action of GH.     

Chronic treatment with exendin(9-39)amide indicates a minor role for endogenous glucagon-like peptide-1 in metabolic abnormalities of obesity-related diabetes in ob/ob mice

Glucagon-like peptide-1 (GLP-1) is a potent insulinotropic hormone proposed to play a role in both the pathophysiology and treatment of type 2 diabetes. This study has employed the GLP-1 receptor antagonist, exendin-4(9-39)amide (Ex(9-39)) to evaluate the role of endogenous GLP-1 in genetic obesity-related diabetes and related metabolic abnormalities using ob/ob and normal mice. Acute in vivo antagonistic potency of Ex(9-39) was confirmed in ob/ob mice by blockade of the insulin-releasing and anti-hyperglycaemic actions of intraperitoneal GLP-1. In longer term studies, ob/ob mice were given once daily injections of Ex(9-39) or vehicle for 11 days. Feeding activity, body weight, and both basal and glucose-stimulated insulin secretion were not significantly affected by chronic Ex(9-39) treatment. However, significantly elevated basal glucose concentrations and impaired glucose tolerance were evident at 11 days. These disturbances in glucose homeostasis were independent of changes of insulin sensitivity and reversed by discontinuation of the Ex(9-39) for 9 days. Similar treatment of normal mice did not affect any of the parameters measured. These findings illustrate the physiological extrapancreatic glucose-lowering actions of GLP-1 in ob/ob mice and suggest that the endogenous hormone plays a minor role in the metabolic abnormalities associated with obesity-related diabetes.     

A method for the simultaneous measurement of insulin release and B cell membrane potential in single mouse islets of langerhans

Summary A method has been developed for the simultaneous measurement of insulin release and electrical activity in single micro-dissected mouse islets of Langerhans. The effects of D-glucose have been studied in individual islets. Each islet was exposed to 0, 5.6, 11.1, 16.7, 22.2, 27.8 and 33.3 mmol/l glucose in a stepwise fashion. The minimum glucose concentration required to elicit spike activity is lower than that required to stimulate insulin release above basal levels and the maximum spike frequency occurs at a lower glucose concentration than does maximum insulin release. Following a reduction in glucose from 27.8 (or 33.3) to 5.6 mmol/l, membrane potentials returned to resting values within 2 min whereas insulin returned to basal values after 20 min. Increasing glucose from 5.6 to 27.8 mmol/l induced spike activity within 10 s; the insulin response was detected within 40 s. Thus, it is possible to use the single mouse islet for simultaneous measurements of insulin release and electrical activity.     

Effects of leucine on insulin secretion and beta cell membrane potential in mouse islets of Langerhans

Leucine is known to enhance insulin secretion from islets of Langerhans, and insulin promotes leucine uptake in peripheral tissues. The present studies were designed to elucidate the effects of leucine on glucose responsiveness and stimulus secretion coupling in mouse islets of Langerhans. The effects of 20 mM leucine on insulin secretion and membrane potential were studied over a range of glucose concentrations (0-27.7 mM). Microdissected, perifused pancreatic islets from normal adult mice were used for both studies of insulin secretion and electrophysiology in order to make a close comparison between these measurements. Leucine enhanced the insulin secretion in the presence of 5.6, 11.1, and 22.2 mM glucose. In the presence of leucine, 27 mM glucose inhibited insulin secretion. In the absence of glucose-leucine did not induce electrical activity of the beta cell membrane, whereas in the presence of 5.6, 11.1, and 22.2 mM glucose leucine increased spike frequency. Thus, leucine shifts both the glucose-dependent insulin secretion and electrical activity toward lower glucose concentrations. It is concluded that leucine and glucose share a common metabolic pathway (citric acid cycle) for stimulatory effects. Leucine is deaminated to form 2-ketoisocaproic acid (KIC) and produce NH4+. We propose that in the absence of glucose this increases cytosolic pH, which in turn increases K+ permeability, and inhibits electrical activity and insulin secretion.     

Plasma immunoreactive gastric inhibitory polypeptide in obese hyperglycaemic (ob/ob) mice

Gastric inhibitory polypeptide (GIP), a recognized component of the enteroinsular axis, is raised in the plasma and intestine of obese hyperglycaemic (ob/ob) mice. To evaluate the control of plasma GIP and its role in the hyperinsulinaemia of the ob/ob syndrome, GIP and insulin were determined at different ages in fed mice, and at 10-12 weeks of age after fasting/refeeding and administration of GIP, different nutrients and insulin to mice fasted for 18 h. Plasma GIP and insulin were raised in adult (10- and 20-week-old) compared with younger (3- and 5-week-old) mice, although GIP was not increased in the presence of hyperinsulinaemia at 3 weeks of age. Fasting suppressed and refeeding promptly restored plasma GIP and insulin concentrations. Administration of GIP to mimic postprandial concentrations evoked a marked but transient insulin response which was protracted in the presence of rising hyperglycaemia. Orally administered fat, glucose and amino acids raised GIP concentrations with fat having a particularly strong effect. Glucose and amino acids also evoked prominent increases of insulin, but fat produced only a small rise in insulin in the absence of increasing glucose concentrations. Consistent with glucose-potentiation, a mixture of all three nutrients greatly augmented the insulin response without further increase of plasma GIP. Glucose-induced increase in endogenous insulin and doses of exogenous insulin up to 100 units/kg did not suppress basal, fat-stimulated or glucose-stimulated GIP release. The results indicate that raised GIP concentrations make an important contribution to the hyperinsulinaemia and related metabolic abnormalities of the ob/ob syndrome.     

Ciglitazone, a hypoglycemic agent: early effects on the pancreatic islets of ob/ob mice

Chronic administration of ciglitazone (5-4[1-methyl-cyclohexylmethoxy)-benzyl]-thiazolidine-2,4 dione) decreased both plasma glucose and insulin concentrations in ob/ob mice. When given as an admixture to the feed, blood glucose levels were reduced as early as 12 hours after initiation of treatment. Concomitant with the decrease in circulating insulin, there was an increased hormone content in the beta-cells as judged by RIA and aldehyde-fuchsin staining. Acute oral dosing with ciglitazone produced a 41% reduction in circulating insulin at a time when glucose concentrations were as yet unaffected. Ciglitazone also inhibited glucose-stimulated insulin secretion in vitro. The results suggest that the hypoglycemic agent, ciglitazone, may reduce plasma glucose and insulin concentrations at least partially as the result of independent mechanisms.     

Systemic treatment with sympatholytic dopamine agonists improves aberrant beta-cell hyperplasia and GLUT2, glucokinase, and insulin immunoreactive levels in ob/ob mice.

Sympatholytic dopamine agonist treatment utilizing bromocriptine and SKF38393 (BC/SKF) significantly lowers basal plasma insulin levels and normalizes basal and glucose-induced insulin secretion of the pancreatic beta cell in ob/ob mice. While BC/SKF has no significant effect on pancreatic islet cells directly, drug action is mediated via alterations in the hypothalamic-neuroendocrine axis, which drives metabolic changes in peripheral tissues leading to a marked reduction in hyperglycemia and hyperlipidemia and corrects autonomic control of islet function. To elucidate the nature of the functional response of islets to systemic BC/SKF treatment in ob/ob mice, we investigated the relative changes in the levels of functionally important beta-cell proteins in situ, as well as differences in the beta-cell turnover rate, following a 2-week drug treatment. Isolated islets from treated mice exhibit a 3.5-fold increase in insulin content (P <.01) that correlated with a 51% reduction in basal plasma insulin levels (P <.01) compared with vehicle-treated controls. Using quantitative immunofluorescence microscopy on pancreatic tissue sections, insulin and GLUT2 immunoreactivity of islet beta cells of BC/SKF-treated mice were significantly increased (approximately 2.3-fold and approximately 4.4-fold, respectively; P <.002) to the levels observed in islets of their lean littermates. Glucokinase (GK) immunoreactivity was greatly (75%) reduced in beta cells from ob/ob versus lean mice (P <.0001). A modest increase in GK immunoreactivity in beta cells of drug-treated mice was observed (approximately 1.6-fold; P <.05). Isolated islets from BC/SKF-treated mice exhibit a 42% reduction in DNA content compared with vehicle-treated controls (P <.01) to levels observed in lean mice, but without notable differences in islet size. In situ assays for mitosis and apoptosis, using 5-bromodeoxyuridine (BrdU) and terminal deoxyribotransferase (TdT)-UTP nick end labeling (TUNEL) staining techniques, respectively, were performed in pancreas of these mice to determine if beta cells show a reduction in hyperplasia following BC/SKF treatment. Accordingly, a pronounced decrease in replicating, BrdU-positive beta cells in the drug-treated mice compared with the control group was observed, but without differences in their TUNEL-staining patterns. Collectively, these data suggest that systemic sympatholytic dopaminergic therapy that attenuates hyperglycemia and hyperlipidemia improves islet function in ob/ob mice by improving aberrations in the beta cell's glucose-sensing apparatus, enhancing insulin storage and/or retention, and stabilizing hyperplasia, thus reducing basal insulin levels.     

Regulation of plasma immunoreactive glucagon in obese hyperglycaemic (ob/ob) mice

This study examines the role of glucagon in the pathogenesis of the obese hyperglycaemic (ob/ob) syndrome in mice. Plasma C-terminal immunoreactive glucagon concentrations were measured in fed and fasted ob/ob mice at different ages between 5-40 weeks, and in 20-week-old mice after the administration of established stimulators and inhibitors of glucagon secretion. Plasma glucagon concentrations were inappropriately raised irrespective of age, nutritional status and the accompanying prominent changes in plasma glucose and insulin concentrations. Glucose suppressed plasma glucagon in the fed but not the fasted state, suggesting a dependence on the marked hyperinsulinaemia associated with feeding. Administration of 0.25 units insulin/kg to fasted mice failed to affect plasma glucagon and glucose concentrations. Increasing the dose to 100 units/kg restored the normal suppressive actions of insulin. Fasted mice showed an exaggerated glucagon response to arginine but not to the parasympathomimetic agent pilocarpine. Fed mice displayed normal plasma glucagon responses to the sympathomimetic agents noradrenaline and adrenaline. Administration of insulin antiserum or 2-deoxy-D-glucose raised plasma glucagon concentrations of fed mice. Contrary to the lack of suppression by glucose in the fasted state, heparin-induced increase in free fatty acids reduced plasma glucagon concentrations. This study demonstrates inappropriate hyperglucagonaemia and defective A-cell function in ob/ob mice. The extent of the abnormality is exacerbated by fasting and appears to result from insensitivity of the A-cell to the normal suppressive action of insulin.     

Influence of the pituitary gland on insulin secretion in the genetically obese (ob/ob) mouse.

The influence of the pituitary gland of lean and genetically obese (ob/ob) mice on insulin secretion from microdissected pancreatic islets of lean and ob/ob mice has been studied by perifusing the pituitaries of these animals in series with the isolated islets and measuring insulin secretion at 5-min intervals over a period of 60 min. It has been shown that the pituitary perifusate of both lean and obese mice stimulate insulin secretion from lean mouse islets but not from obese mouse islets. The maximum stimulation occurs in the first 10 min and with the lean mouse pituitaries returns to the basal level in about 20 min, whereas with the obese mouse pituitaries insulin secretion is about double that from the control islets even after 40 min. A concentration of pure porcine ACTH equivalent to about three times the amount released from the pituitary gland under the experimental conditions used, caused only a small stimulation of insulin release. Possible interpretations of these findings and further lines of investigation are discussed.     

Sources of plasma glucose and liver glycogen in fasted ob/ob mice

Abstract Alterations in intrahepatic carbohydrate fluxes in ob/ob mice and the effects of acute leptin administration were studied in vivo by use of a dual-isotope tracer infusion. Metabolic sources of plasma glucose (gluconeogenesis (GNG) and glycogenolysis) and hepatic glycogen (GNG, direct synthesis and pre-existing) were determined in 20-h-fasted mice infused with [2-13C1]glycerol and [U13C6]glucose for 3 h. Total glucose output (TGO) and the rate of appearance (Ra) of plasma glycerol were measured by isotope dilution. GNG, the direct pathway of hepatic glycogen synthesis and hepatic triose-phosphate flux were determined by mass isotopomer distribution analysis (MIDA). Serum glucose, insulin, leptin and liver glycogen concentrations were also measured. After a 24-h fast, ob/ob mice had 2-fold higher TGO, 2.5-fold elevated liver glycogen content and markedly higher glycogenolytic flux to glucose, absolute GNG and direct glycogen synthesis rates (10-fold increased) compared to the control group. Ob/ob mice also had elevated triose-phosphate flux compared to controls (40 vs. 22 mg/kg lean body mass/min). A model of intrahepatic flux distributions in control and ob/ob mice is presented. In summary, elevated fasting plasma glucose concentrations are due to increased TGO in ob/ob mice, which is maintained by both increased GNG and increased glycogenolysis. Furthermore, the ob/ob mice have major alterations in fasting hepatic carbohydrate fluxes into triose-phosphate pools and glycogen. We support the model that actions of leptin on hepatic glucose metabolism require insulin or other factors.     

Abnormal plasma glucose and insulin responses in heterozygous lean (ob/+) mice

Summary To investigate the effect of the ob gene in the heterozygous condition, plasma glucose and insulin responses of adult heterozygous lean (ob/+) mice were compared with mice of the homozygous lean (+/+) and homozygous obese (ob/ob) genotypes. The ob/+ mice consumed 24% more food than +/+ mice although body weights were similar. Plasma glucose and insulin concentrations were respectively 16% and 176% higher in ob/+ mice than +/+ mice in the freely fed state, and 44% and 88% higher during glucose tolerance tests. In 24 hour fasted ob/+ mice, plasma glucose concentrations were 23% higher than +/+ mice but plasma insulin concentrations were not significantly different. Arginine produced a greater insulin response (172%) and a greater fall in glycaemia (200%) in ob/ + mice. A significant difference in the hypoglycaemic effect of insulin in ob/+ and +/+ mice was not observed. These results demonstrate an effect of the ob gene on glucose homeostasis in heterozygous lean (ob/+) mice. The abnormalities were qualitatively similar but considerably less severe than those in ob/ob mice, suggesting that ob/+ mice might prove useful to study factors predisposing to inappropriate hyperglycaemia.