The influence of K(+)-induced membrane depolarization on insulin secretion in islets of lean and obese (ob/ob) mice

The present study was undertaken to determine whether factors that affect K+ permeability produce differences in insulin secretion in the islets of obese versus lean mice. At basal glucose (3 mM), the obese islets secreted more insulin for a given increment in depolarizing K+ concentration and responded to a wider range of K+ concentrations (5-45 mM) than the lean islets (5-25 mM). In contrast, the membrane potential changes induced by increments in pK+ were not significantly different in the two types of islets. The islets of lean and obese mice treated with pertussis toxin showed a qualitatively similar response to glucose and to epinephrine, but only the control and pertussis toxin treated obese islets responded to K+ depolarization when deprived of calcium. Abnormal responses to quinine and apamin were identified in the islets of obese mice. These findings show that the abnormal insulin secretory response of the obese islet is due, at least in part, to a defect independent of glucose metabolism. This is best explained by an altered sensitivity of voltage-dependent events, most likely the result of differential effects of an intracellular element acting on ATP-sensitive and Ca2(+)-activated K+ channels, both of which are implicated in membrane repolarization.     

Glucoregulatory effects of bombesin in lean and genetically obese hyperglycaemic (ob/ob) mice

1. Plasma glucose and insulin responses to bombesin were examined in 12-15-week-old 12 hr fasted lean and genetically obese hyperglycaemic (ob/ob) mice. 2. Bombesin (1 mg/kg ip) produced a prompt but transient increase of plasma insulin in lean mice (maximum increase of 50% at 5 min), and a more slowly generated but protracted insulin response in ob/ob mice (maximum increase of 80% at 30 min). Plasma glucose concentrations of both groups of mice were increased by bombesin (maximum increases of 40 and 48% respectively in lean and ob/ob mice at 15 min). 3. When administered with glucose (2 g/kg ip), bombesin (1 mg/kg ip) rapidly increased insulin concentrations of lean and ob/ob mice (maximum increases of 39 and 63% respectively at 5 min). Bombesin did not significantly alter the rise of plasma glucose after exogenous glucose administration to these mice. 4. The results indicate that bombesin exerts an insulin-releasing effect in lean and ob/ob mice. The greater insulin-releasing effect in ob/ob mice renders bombesin a possible component of the overactive entero-insular axis in the ob/ob mutant, especially if it acts within the islets as a neurotransmitter or paracrine agent.     

Mitochondrial Ca2+ transport in lean and genetically obese (ob/ob) mice.

Isolated mitochondria from liver or brown adipose tissue of obese ob/ob mice demonstrated increased rates of Ca2+ uptake and release compared with those of lean mice. This enhanced transport activity was not found in mitochondria from kidney or skeletal muscle. Respiration-induced membrane potential was the same in mitochondria from lean and ob/ob mice. It is therefore concluded that the increased Ca2+ uptake rates reflect an activation of the Ca2+ uniporter rather than a change in the electrophoretic driving force. As mitochondria from pre-obese ob/ob mice did not show elevated rates of Ca2+ transport, the activated transport in the obese animals was thus a consequence of the state of obesity rather than being a direct effect of the ob/ob genotype. It is suggested that the enhanced activity of the Ca2+-transport pathways in liver and brown adipose tissue may alter metabolic functions in these tissues by modifying cytoplasmic or intramitochondrial Ca2+ concentrations.     

Effects of zinc supplementation on the plasma glucose level and insulin activity in genetically obese (ob/ob) mice

The effects of zinc supplementation (20 mM ZnCl₂ from the drinking water for eight weeks) on plasma glucose and insulin levels, as well as its in vitro effect on lipogenesis and lipolysis in adipocytes were studied in genetically obese (ob/ob) mice and their lean controls (+/?). Zinc supplementation reduced the fasting plasma glucose levels in both obese and lean mice by 21 and 25%, respectively (p < 0.05). Fasting plasma insulin levels were significantly decreased by 42% in obese mice after zinc treatment. In obese mice, zinc supplementation also attenuated the glycemic response by 34% after the glucose load. The insulin-like effect of zinc on lipogenesis in adipocytes was significantly increased by 80% in lean mice. However, the increment of 74% on lipogenesis in obese mice was observed only when the zinc plus insulin treatment was given. This study reveals that zinc supplementation alleviated the hyperglycemia of ob/ob mice, which may be related to its effect on the enhancement of insulin activity.     

Anorectic effect of fenfluramine, cholecystokinin and neurotensin in genetically obese (ob/ob) mice

To investigate the satiety defect of hyperphagic genetically obese (ob/ob) mice, acute feeding responses to three differently acting anorectic agents were determined in 7-9 weeks old lean (+/+) and ob/ob mice habituated to a restricted (0900-1230 hr) daily feeding routine. Fenfluramine (10 mg/kg), cholecystokinin (100 U/kg) and neurotensin (500 micrograms/kg), administered intraperitoneally 15 min before feeding, each produced a rapid but transient suppression of food consumption in ob/ob mice, similar to lean controls. The results suggest that neural satiety mechanisms triggered via serotoninergic pathways (fenfluramine), vagal afferents (cholecystokinin) and the hypothalamic paraventricular nucleus (neurotensin) are functional in ob/ob mice, supporting the view that the satiety defect of ob/ob mice resides outside of the nervous system.     

Different insulin-secretory responses to calcium-channel blockers in islets of lean and obese (ob/ob) mice.

The purpose of these experiments was to determine whether the activity of the voltage-dependent Ca2+ channel was modulated in the same manner in islets of the ob/ob mouse as in islets of homozygous lean mice of the same strain. The effect of agents that are known to alter the concentrations and movements of intracellular Ca2+ were investigated in relation to glucose-stimulated insulin secretion and in relation to the effect of forskolin. In islets of obese mice, verapamil and nifedipine both inhibited glucose-induced insulin release, nifedipine being the more potent inhibitor. Forskolin-stimulated secretion was inhibited either not at all (verapamil) or much less (nifedipine) in islets of the ob/ob mouse compared with those of lean mice. At basal glucose concentrations, verapamil initiated insulin secretion in islets of the ob/ob mouse and acted synergistically with forskolin to evoke a secretory activity that was 3-fold greater than that evoked by 20 mM-glucose. Nifedipine also initiated secretion at basal glucose concentrations and acted synergistically with forskolin, but its effect was considerably smaller than that of verapamil. A comparison of the effect of forskolin in the presence of Ca2+-channel blockers and in the absence of Ca2+ suggests that, in the obese mouse, the operation of the voltage-dependent Ca2+ channel is impaired.     

Arrhenius plot characteristics of adipocyte-plasma-membrane adenylate cyclase activity in lean and genetically obese (ob/ob) mice

Arrhenius plots of fluoride- and guanine-nucleotide-stimulated adenylate cyclase activity were linear in adipocyte plasma membranes from lean and obese (ob/ob) mice . Arrhenius plots of isoprenaline-stimulated adenylate cyclase activity in hepatic plasma membranes biphasic in both groups. The results were biphasic in membranes from Jean mice but linear in membranes from obese mice. In contrast, Arrhenius plots of glucagon-stimulated adenylate cyclase activity in hepatic plasma membranes were biphasic in both groups. The results suggest that the coupling between the -receptor and the regulatory unit of adenylate cyclase, which has been observed to be defective in adipocyte plasma membranes from obese mice, is influenced by a different lipid environment in membranes from obese animals.     

Role of adrenal glands in the development of abnormal glucose and insulin homeostasis in genetically obese (ob/ob) mice

This study evaluates the role of adrenal hormones in the development of hyperinsulinaemia and impaired glucose homeostasis in genetically obese hyperglycaemic C57BL/6J ob/ob mice. Lean (+/?) and obese mice were bilaterally adrenalectomised or sham operated at 5 weeks of age, and glucose tolerance was examined after 7 and 14 days. Adrenalectomy temporarily reduced food intake and body weight gain in lean mice, and improved glucose tolerance without a significant change in plasma insulin concentrations at both intervals studied. In obese mice adrenalectomy permanently reduced body weight gain and food intake to values comparable with lean mice. Glucose tolerance was improved in adrenalectomised obese mice at both intervals studied, resulting in plasma glucose concentrations similar to adrenalectomised lean mice. Plasma insulin concentrations during the tolerance tests were reduced in adrenalectomised obese mice, but remained higher than in lean mice. Adrenalectomy did not improve the poor insulin response to parenteral glucose in obese mice. The results indicate that adrenal hormones play an important role in the development of glucose intolerance and contribute to the hyperinsulinaemia in obese (ob/ob) mice, in part by promoting hyperphagia.     

Glucose tolerance in aging obese (ob/ob) and lean mice

Examination of the glucose tolerance in younger (3 month) and older (6 month) obese mice revealed that most of their postinjection hyperglycemia arises from the disproportionately large glucose responses to the injection/bleeding procedures rather than from the added glucose. Simultaneous measurements of circulating glucagon, corticosterone and insulin indicated that simple differences in the levels of these hormones, in their circulating ratios, or in the magnitude of the hormone responses to stimulation did not fully account for the "stress"-induced hyperglycemia.     

Hepatic delta 6-desaturase activity in lean and genetically obese ob/ob mice.

Hepatic delta 6-desaturase activity is primarily located in the mitochondrial fraction in mice. Both delta 6- and delta 5-desaturase activities are increased in the liver of young (6-week-old) obese mice. The increase in hepatic delta 6-desaturase activity in obese mice does not occur until weaning. Neither restriction of food intake nor hyperinsulinaemia normalize hepatic delta 6-desaturase activity of obese mice. Both cold acclimation and tri-iodothyronine (30 micrograms/day per kg) decreased hepatic delta 6-desaturase activity of obese mice to levels observed in lean mice, whereas the increase in activity in obese mice was still maintained after the induction of hypothyroidism.     

Effects of insulin on lipolysis and lipogenesis in adipocytes from genetically obese (ob/ob) mice.

A method for the preparation of isolated adipocytes from obese mice is described. Similar yields of adipocytes (50--60%), as judged by several criteria, are obtained from obese mice and lean controls. Few fat-globules and no free nuclei were observed in cell preparations, which are metabolically active, respond to hormonal control and appear to be representative of intact adipose tissue. Noradrenaline-stimulated lipolysis was inhibited by insulin, equally in adipocytes from lean and obese mice. Inhibition in obese cells required exogenous glucose, and the insulin dose--response curve was shifted to the right. Basal lipogenesis from glucose was higher in adipocytes from obese mice, and the stimulatory effect of insulin was greater in cells from obese mice compared with lean controls. A rightward shift in the insulin dose--response curve was again observed with cells from obese animals. This suggests that adipose tissue from obese mice is insulin-sensitive at the high blood insulin concentrations found in vivo. The resistance of obese mice to the hypoglycaemic effect of exogenous insulin and their impaired tolerance to glucose loading appear to be associated with an impaired insulin response by muscle rather than by adipose tissue.     

Dual action of beta-endorphin on insulin release in genetically obese and lean mice

Intraperitoneal administration of beta-endorphin (1 mg/kg) to ob/ob mice doubled fasting plasma insulin concentrations within 30 min, while plasma glucose concentrations were unaltered. In lean mice, beta-endorphin failed to alter plasma insulin or glucose responses. In glucose-loaded ob/ob mice, beta-endorphin (1 mg/kg) reduced insulin levels at 40 min, and delayed glucose disposal. A lower dose of beta-endorphin (0.1 mg/kg) decreased plasma insulin at 90 min, with no effect on plasma glucose disposal. In lean mice, only the higher dose of beta-endorphin suppressed the glucose-stimulated rise in plasma insulin concentrations, without affecting plasma glucose. Beta-endorphin's actions were blocked by naltrexone and could not be mimicked by N-acetyl-beta-endorphin. Beta-endorphin (10(-8)M) enhanced insulin release from isolated ob/ob and lean mouse islets incubated in medium containing 6 mM glucose, but inhibited release when 20 mM glucose was present. These effects were naloxone reversible. The results indicate that 1) ob/ob mice display a greater magnitude of response in vivo to beta-endorphin's actions on insulin release compared with lean mice, 2) high concentrations of beta-endorphin exacerbate glucose disposal in ob/ob mice. 3) the prevailing glucose concentration is an important determinant of whether beta-endorphin's effects on insulin release will be stimulatory or inhibitory and 4) these actions are mediated via opiate receptors.     

Development of glucose intolerance and impaired plasma insulin response to glucose in obese hyperglycaemic (ob/ob) mice

The development of glucose intolerance in Aston ob/ob mice showed a gross exaggeration of the age-related changes of glucose tolerance in lean (+/+) mice. Intraperitoneal glucose tolerance in ob/ob mice was poor at 5 weeks, improved by 10 weeks, but markedly worsened by 20 weeks. A 24 hour fast further exaggerated the glucose intolerance of ob/ob mice. Unlike lean mice, tolerance improved in ob/ob mice at 40 weeks. Alterations of insulin sensitivity and the plasma insulin response to glucose accounted in part for these observations. Insulin sensitivity deteriorated until 20 weeks, but improved at 40 weeks in both fed and 24 hour fasted ob/ob mice. A positive plasma insulin response to glucose was lost after 5 weeks in fed ob/ob mice. The severity of this abnormality corresponded with the extent of the basal hyperinsulinaemia. A 24 hour fast reduced plasma insulin concentrations and restored a positive plasma insulin response to glucose in ob/ob mice. The results suggest that the plasma insulin response to glucose in ob/ob mice is related to the secretory activity of the B-cells prior to stimulation. Furthermore, it is evident that factors in addition to insulin insensitivity and the impaired plasma insulin response to glucose contribute to the development of glucose intolerance in these mice.     

Blood glucose and serum insulin levels in lean and genetically obese mice.

Fed and 24 hour fasted lean and genetically obese mice (ob/ob) were given a fixed glucose load per gm body weight by intraperitoneal and intragastric administration. Intraperitoneal glucose injection into the obese mice produced a prolonged elevated blood glucose level with a concomitant significant decrease of circulating insulin. Possible interpretations of this observation are discussed. In those obese animals in which glucose was administered intragastrically the fed obese mice had a blood glucose concentration of 450-500 mg% for a period of one hour but there was no increase in circulating insulin, however, in the fasted obese mice in which the glucose concentration was about 350 mg% for one hour, there was a significant increase in the circulating insulin levels. The fed and fasted lean mice showed normal glucose tolerance curves and the expected increase in circulating insulin following either intraperitoneal orintragastric glucose loads. It is concluded that hyperglycaemia in the ob/ob mice is unlikely to be the principal cause of hyperinsulinaemia.     

The influence of GDP on Ca2+ uptake by mitochondria of brown adipose tissue from lean and genetically obese (ob/ob) mice.

The specific binding capacity for purine nucleotides in brown-adipose-tissue mitochondria is thought to indicate the capacity of the proton-conductance pathway which leads to uncoupled respiration. This functional relationship was investigated in studies measuring initial Ca2+-uptake rates and membrane potential in the presence or absence of GDP in brown-adipose-tissue mitochondria with different GDP-binding capacities. The mitochondria from pre-obese and obese ob/ob mice were less able than those from lean control mice to dissipate membrane potential in the absence of GDP. Mitochondria from the obese animals also maintained a higher Ca2+-uptake rate without GDP in comparison with the rate found with mitochondria from the lean mice. The GDP-dependence of Ca2+ uptake was greater in brown-adipose-tissue mitochondria from cold-adapted animals than in those from animals kept at 22 degrees C or at thermoneutrality (33 degrees C). It is concluded that Ca2+-uptake rate and membrane-potential values are depressed in the absence of GDP and indicate indirectly the influence of purine nucleotides on maintaining the proton electrochemical gradient in brown-adipose-tissue mitochondria. It is also apparent that the lower GDP-binding capacity in mitochondria from ob/ob mice is related to a decreased ability to dissipate the proton electrochemical gradient.     

Islet cell surface antibodies in genetically obese hyperglycaemic (ob/ob) mice

A quantitative method for circulating islet cell surface antibodies (ICSA), based on the binding of¹²⁵I-protein A to insulin-producing RINm5F cells, was used to evaluate ICSA in plasma of 4- to 40-week-old Aston obese hyperglycaemic (ob/ob) mice and normal control (+/+) mice. RINm5F cells bound 2502±l196 c.p.m.¹²⁵I-protein A per l0⁵ cells (mean±S.D.,n=54) after incubation with +/+ plasma. ICSA positive plasma (defined as¹²⁵I-protein A binding, mean±2 S.D. of +/+ plasma) was detected in 3 out of 54+/+ mice and 3 out of 54 ob/ob mice. ICSA were not observed in ob/ob mice before the onset of diabetes (7 weeks of age), but were detected at 9, 20 and 40 weeks. At 20 weeks¹²⁵I-protein A binding produced by ob/ob plasma was 35% greater than +/+ plasma (P<0.05). The low occurrence of ICSA in ob/ob mice (6%) suggests that factors other than ICSA are responsible for B-cell dysfunction and eventual islet degeneration observed in Aston ob/ob mice.     

Developmental changes in fatty acid synthesis in interscapular brown adipose tissue of lean and genetically obese (ob/ob) mice.

Fatty acid synthesis was measured in vivo with 3H2O in interscapular brown adipose tissue of lean and genetically obese (ob/ob) mice. At 26 days of age, before the development of hyperphagia, synthesis in brown adipose tissue was higher in the obese than in the lean mice; synthesis was also elevated in the liver, white adipose tissue and carcass of the obese mice. At 8 weeks of age, when hyperphagia was well established, synthesis remained elevated in all tissues of the obese mice, with the exception of brown adipose tissue. Elevated synthesis rates were not apparent in brown adipose tissue of the obese mice at 14 days of age, nor at 35 days of age. These results demonstrate that brown adipose tissue in ob/ob mice has a transitory hyperlipogenesis at, and just after, weaning on to a low-fat/high-carbohydrate diet. Once hyperphagia has developed, by week 5 of life, brown adipose tissue is the only major lipogenic tissue in the obese mice not to exhibit elevated rates of fatty acid synthesis; this suggests that insulin resistance develops much more rapidly in brown adipose tissue than in other lipogenic tissues of the ob/ob mouse.