Insulin Release In Pancreatic Islets Research Articles

A Microfluidic Hanging-Drop-Based Islet Perifusion System for Studying Glucose-Stimulated Insulin Secretion From Multiple Individual Pancreatic Islets.

Islet perifusion systems can be used to monitor the highly dynamic insulin release of pancreatic islets in glucose-stimulated insulin secretion (GSIS) assays. Here, we present a new generation of the microfluidic hanging-drop-based islet perifusion platform that was developed to study the alterations in insulin secretion dynamics from single pancreatic islet microtissues at high temporal resolution. The platform was completely redesigned to increase experimental throughput and to reduce operational complexity. The experimental throughput was increased fourfold by implementing a network of interconnected hanging drops, which allows for performing GSIS assays with four individual islet microtissues in parallel with a sampling interval of 30 s. We introduced a self-regulating drop-height mechanism that enables continuous flow and maintains a constant liquid volume in the chip, which enables simple and robust operation. Upon glucose stimulation, reproducible biphasic insulin release was simultaneously observed from all islets in the system. The measured insulin concentrations showed low sample-to-sample variation as a consequence of precise liquid handling with stable drop volumes, equal flow rates in the channels, and accurately controlled sampling volumes in all four drops. The presented device will be a valuable tool in islet and diabetes research for studying dynamic insulin secretion from individual pancreatic islets.

YIL counteracts ghrelin-inhibited insulin release in pancreatic islets of langerhans

Ghrelin is a peptide hormone that is produced mainly from the stomach. Ghrelin is reported to have many biological functions, such as modulating feeding behavior, energy balance, and glucose homeostasis. This study aimed to examine whether YIL, a ghrelin receptor antagonist, could counteract the effect of ghrelin-inhibited insulin release in the pancreatic islet of Langerhans. This study is experimental research using wild-type C57BL/6J mice [8-10 weeks old]. Islet of Langerhans was isolated by collagenase digestion and the insulin release [ng/islet/h] from the islet is examined by the ELISA method. Data represent means ± SEM and is analyzed by one-way ANOVA. The result showed that 8.3 mM glucose concentration increase insulin release compared to 2.8 mM glucose, respectively [0,393 ± 0,025 vs 0,219 ± 0,022 ng/islet/h]. In the presence of 8.3 mM glucose, ghrelin 1 nM showed a decrease in insulin release significantly compared to 8.3 mM glucose only [0,283 ± 0,001 vs 0,393 ± 0,025, p < 0,01]. In contrast, in the presence of 8.3 mM glucose and ghrelin 1 nM, YIL 1 μM induced insulin secretion [0,386 ± 0,012 vs 0,283 ± 0,001, p < 0,01]. In conclusion, YIL is significantly counteracted ghrelin-inhibited insulin release in pancreatic islets of Langerhans. Furthermore, YIL is one of the candidates for the treatment of type 2 diabetes.

Predicting Insulin Secretion Profiles for Immunoisolating Devices with Transplanted Islets

Avascular islets or stem cells transplanted under immunoisolating conditions offer considerable hope in overcoming the challenges of islet transplantation; however, because of diffusional limitations, implants face long-term viability and efficiency-of-response problems. To quantitatively characterize the glucose-stimulated insulin release of pancreatic islets, we conducted parallel dynamic perifusion experiments with free and hydrogel encapsulated islets. Perifused human islets secreted less insulin than murine islets per unit mass (IEQ) and had a less pronounced first-phase peak. The data was used to develop a computational model of insulin secretion. Our model couples hormone secretion and nutrient consumption kinetics with diffusive and convective transport, fits well the experimental data, and can be used to predict insulin release profiles for arbitrary geometries and glucose challenges. We found that larger diffusion distances (larger capsules) unavoidably dampen the first-phase insulin response, resulting in a sustained-release type insulin secretion that sluggishly responds to changes in glucose concentration. Hence, bioartificial pancreas devices can provide long-term and physiologically desirable solutions only if immunoisolation and biocompatibility considerations are considered together with optimized nutrient diffusion and insulin release characteristics. Disclosure P. Buchwald: None. A.A. Tomei: Consultant; Self; EyePharma. Research Support; Self; Semma Therapeutics, Inc.. Stock/Shareholder; Self; Converge Biotech Pvt. Ltd.. C.L. Stabler: None.

Experimental evaluation and computational modeling of the effects of encapsulation on the time-profile of glucose-stimulated insulin release of pancreatic islets.

BackgroundIn type 1 diabetic patients, who have lost their ability to produce insulin, transplantation of pancreatic islet cells can normalize metabolic control in a manner that is not achievable with exogenous insulin. To be successful, this procedure has to address the problems caused by the immune and autoimmune responses to the graft. Islet encapsulation using various techniques and materials has been and is being extensively explored as a possible approach. Within this framework, it is of considerable interest to characterize the effect encapsulation has on the insulin response of pancreatic islets.MethodsTo improve our ability to quantitatively describe the glucose-stimulated insulin release (GSIR) of pancreatic islets in general and of micro-encapsulated islets in particular, we performed dynamic perifusion experiments with frequent sampling. We used unencapsulated and microencapsulated murine islets in parallel and fitted the results with a complex local concentration-based finite element method (FEM) computational model.ResultsThe high-resolution dynamic perifusion experiments allowed good characterization of the first-phase and second-phase insulin secretion, and we observed a slightly delayed and blunted first-phase insulin response for microencapsulated islets when compared to free islets. Insulin secretion profiles of both free and encapsulated islets could be fitted well by a COMSOL Multiphysics model that couples hormone secretion and nutrient consumption kinetics with diffusive and convective transport. This model, which was further validated and calibrated here, can be used for arbitrary geometries and glucose stimulation sequences and is well suited for the quantitative characterization of the insulin response of cultured, perifused, transplanted, or encapsulated islets.ConclusionsThe present high-resolution GSIR experiments allowed for direct characterization of the effect microencapsulation has on the time-profile of insulin secretion. The multiphysics model, further validated here with the help of these experimental results, can be used to increase our understanding of the challenges that have to be faced in the design of bioartificial pancreas-type devices and to advance their further optimization.Electronic supplementary materialThe online version of this article (doi:10.1186/s12938-015-0021-9) contains supplementary material, which is available to authorized users.

Syntaxin 4 Up-Regulation Increases Efficiency of Insulin Release in Pancreatic Islets From Humans With and Without Type 2 Diabetes Mellitus

Evidence suggests that dysfunctional β-cell insulin release precedes type 1 and type 2 diabetes (T1D and T2D, respectively) and that enhancing the efficiency of insulin release from pancreatic islet β-cells may delay/prevent these diseases. We took advantage of the rare opportunity to test this paradigm using islets from human type 2 diabetic individuals. Insulin release capacity is limited by the abundance of fusogenic soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins. Because enrichment of Syntaxin 4, a plasma membrane soluble N-ethylmaleimide-sensitive factor attachment protein receptor protein, enhances β-cell function in mice, we investigated its potential to restore functional insulin secretion to human diabetic islets. Human islets from type 2 diabetic and healthy individuals transduced to overexpress Syntaxin 4 were examined by perifusion analysis. Streptozotocin-induced diabetic recipient mice transplanted with Syntaxin 4-enriched or normal islets were assessed for rescue of diabetes in vivo. Syntaxin 4 up-regulation in human islets enhanced β-cell function by approximately 2-fold in each phase of secretion. Syntaxin 4 abundance in type 2 diabetes islets was approximately 70% reduced, and replenishment significantly improved insulin secretion. Islets from Syntaxin 4 overexpressing transgenic mice more effectively attenuated streptozotocin-induced diabetes than did control islets. These data show that the addition of just Syntaxin 4 is sufficient to significantly improve insulin secretory function to human type 2 diabetes islets retaining low levels of residual function and provide proof of concept that by building a more efficient β-cell with up-regulated Syntaxin 4, fewer islets may be required per patient, clearing a major barrier in transplantation therapy.

Decrease of glucose-induced insulin secretion of pancreatic rat islets after irradiation in vitro.

Irradiation of pancreatic rat islets up to a dose of 2.5 Gy did neither alter glucose-nor IBMX-induced insulin secretion studied in vitro. The insulin as well as glucagon content of irradiated islets were similar as in the control tissue. This was also true in islets irradiated with 25 Gy which were characterized by a decreased insulin secretion in the presence of glucose and IBMX, respectively. Since we did not find indications of an enhanced hormone output in the radiation medium, we want to suggest that higher irradiation doses affect insulin release of pancreatic islets in vitro. This observation has to be taken into account for application of radioimmunosuppression for transplantation.

Opposite effects of d-fructose on total versus cytosolic ATP/ADP ratio in pancreatic islet cells

d-fructose (10 mM) augments, in rat pancreatic islets, insulin release evoked by 10 mM d-glucose. Even in the absence of d-glucose, d-fructose (100 mM) displays a positive insulinotropic action. It was now examined whether the insulinotropic action of d-fructose could be attributed to an increase in the ATP content of islet cells. After 30–60 min incubation in the presence of d-glucose and/or d-fructose, the ATP and ADP content was measured by bioluminescence in either rat isolated pancreatic islets (total ATP and ADP) or the supernatant of dispersed rat pancreatic islet cells exposed for 30 s to digitonine (cytosolic ATP and ADP). d-fructose (10 and 100 mM) was found to cause a concentration-related decrease in the total ATP and ADP content and ATP/ADP ratio below the basal values found in islets deprived of exogenous nutrient. Moreover, in the presence of 10 mM d-glucose, which augmented both the total ATP content and ATP/ADP ratio above basal value, d-fructose (10 mM) also lowered these two parameters. The cytosolic ATP/ADP ratio, however, was increased in the presence of d-glucose and/or d-fructose. Under the present experimental conditions, a sigmoidal relationship was found between such a cytosolic ATP/ADP ratio and either 86Rb net uptake by dispersed islet cells or insulin release from isolated islets. These data provide, to our knowledge, the first example of a dramatic dissociation between changes in total ATP content or ATP/ADP ratio and insulin release in pancreatic islets exposed to a nutrient secretagogue. Nevertheless, the cationic and insulinotropic actions of d-glucose and/or d-fructose were tightly related to the cytosolic ATP/ADP ratio.

Cholinergic regulation of fuel-induced hormone secretion and respiration of SUR1−/− mouse islets

Neural and endocrine factors (i.e., Ach and GLP-1) restore defective glucose-stimulated insulin release in pancreatic islets lacking sulfonylurea type 1 receptors (SUR1(-/-)) (Doliba NM, Qin W, Vatamaniuk MZ, Li C, Zelent D, Najafi H, Buettger CW, Collins HW, Carr RD, Magnuson MA, and Matschinsky FM. Am J Physiol Endocrinol Metab 286: E834-E843, 2004). The goal of the present study was to assess fuel-induced respiration in SUR1(-/-) islets and to correlate it with changes in intracellular Ca(2+), insulin, and glucagon secretion. By use of a method based on O(2) quenching of phosphorescence, the O(2) consumption rate (OCR) of isolated islets was measured online in a perifusion system. Basal insulin release (IR) was 7-10 times higher in SUR1(-/-) compared with control (CON) islets, but the OCR was comparable. The effect of high glucose (16.7 mM) on IR and OCR was markedly reduced in SUR1(-/-) islets compared with CON. Ach (0.5 microM) in the presence of 16.7 mM glucose caused a large burst of IR in CON and SUR1(-/-) islets with minor changes in OCR in both groups of islets. In SUR1(-/-) islets, high glucose failed to inhibit glucagon secretion during stimulation with amino acids or Ach. We conclude that 1) reduced glucose responsiveness of SUR1(-/-) islets may be in part due to impaired energetics, as evidenced by significant decrease in glucose-stimulated OCR; 2) elevated intracellular Ca(2+) levels may contribute to altered insulin and glucagon secretion in SUR1(-/-) islets; and 3) The amplitudes of the changes in OCR during glucose and Ach stimulation do not correlate with IR in normal and SUR1(-/-) islets suggesting that the energy requirements for exocytosis are minor compared with other ATP-consuming reactions.

Amiloride derivatives enhance insulin release in pancreatic islets from diabetic mice

BackgroundAmiloride derivatives, commonly used for their diuretic and antihypertensive properties, can also cause a sustained but reversible decrease of intracellular pH (pHi). Using dimethyl amiloride (DMA) on normal rodent pancreatic islets, we previously demonstrated the critical influence of islet pHi on insulin secretion. Nutrient-stimulated insulin secretion (NSIS) requires a specific pHi-range, and is dramatically enhanced by forced intracellular acidification with DMA. Furthermore, DMA can enable certain non-secretagogues to stimulate insulin secretion, and induce time-dependent potentiation (TDP) of insulin release in mouse islets where this function is normally absent. The present study was performed to determine whether pHi-manipulation could correct the secretory defect in islets isolated from mice with type 2 diabetes.MethodsUsing two mouse models of type 2 diabetes, we compared a) pHi-regulation, and b) NSIS with and without treatment with amiloride derivatives, in islets isolated from diabetic mice and wild type mice.ResultsA majority of the islets from the diabetic mice showed a slightly elevated basal pHi and/or poor recovery from acid/base load. DMA treatment produced a significant increase of NSIS in islets from the diabetic models. DMA also enabled glucose to induce TDP in the islets from diabetic mice, albeit to a lesser degree than in normal islets.ConclusionIslets from diabetic mice show some mis-regulation of intracellular pH, and their secretory capacity is consistently enhanced by DMA/amiloride. Thus, amiloride derivatives show promise as potential therapeutic agents for type 2 diabetes.

Ghrelin-regulated glucose homeostasis via inhibition of glucose-induced insulin release in pancreatic islets

Ghrelin-regulated glucose homeostasis via inhibition of glucose-induced insulin release in pancreatic islets

Effect of annexin I on insulin secretion through surface binding sites in rat pancreatic islets

This study investigates the effect of extracellular annexin I (Anx I) on regulating insulin secretion in isolated rat pancreatic islets. Results show that Anx I stimulates insulin release in pancreatic islets regardless of the presence or absence of extracellular Ca 2+. In particular, confocal microscopy shows that Anx I binds to the surface of islet cells in the absence of extracellular Ca 2+. However, insulin secretion through Anx I significantly decreases in trypsin-treated islets. Likewise, there is minimal binding of Anx I to the surface of trypsin-treated islets. Anti-Anx I polyclonal antibody also inhibits the stimulating effect of Anx I on insulin secretion. These results indicate that Anx I is capable of binding to the cell surface receptor, in order to regulate the stimulation of insulin release in rat pancreatic islets.

Type 1 11β-Hydroxysteroid Dehydrogenase Mediates Glucocorticoid Activation and Insulin Release in Pancreatic Islets

Metabolic transformation of glucocorticoid hormones constitutes a determinant of their cell-specific effects. The most important reaction for this class of steroids is the reversible C11 keto/beta-hydroxyl conversion between receptor-binding 11beta-OH steroids and the nonbinding 11-oxo compounds, carried out by 11beta-hydroxysteroid dehydrogenases (11beta-HSDs). In this study, we determined the role of glucocorticoid conversion by 11beta-HSD in pancreatic islets and its function in the regulation of insulin release. Pancreatic islets isolated from ob/ob mice display type 1 11beta-hydroxysteroid dehydrogenase activity, i.e. in intact cells the reductive reaction prevails, leading from dehydrocorticosterone to corticosterone. Expression of type 1 11beta-HSD mRNA was detected by reverse transcriptase-polymerase chain reaction in islets isolated from ob/ob mice and also from human tissue. Incubation of beta-cells in the presence of 11-dehydrocorticosterone leads to a dose-dependent inhibition of insulin release, indicating cellular activation of 11-dehydrocorticosterone to the receptor ligand, further confirmed by reporter gene assays. Inhibition of 11beta-HSD activity by carbenoxolone reverses inhibition of insulin release. The presence of 11beta-HSD in islets supports the concept that reactivation of inert circulating hormone precursors in a cell-specific manner plays a major role in glucocorticoid physiology in rodents and man.

Characteristics of the biotin enhancement of glucose-induced insulin release in pancreatic islets of the rat.

Perifused isolated rat islets were used to show that biotin plus 16.5 mM glucose evoked more insulin secretion than 16.5 mM glucose alone. Whether or not this reinforcement of glucose-induced insulin secretion by biotin is unique was studied by using perifused islets stimulated with 16.5 mM glucose plus 100 microM of one of various components of the vitamin B group. No effect of any of these vitamins was found on glucose-induced insulin secretion. These results indicate that biotin is unique among the members of the vitamin B group in enhancing glucose-induced insulin secretion. Static incubation experiments showed that biotin did not potentiate insulin release when the islets were incubated with an experimental solution containing either no or 2.8 mM glucose. The addition of biotin to 27.7 mM glucose, which is the maximal concentration for stimulating insulin release, did not significantly enhance the effect of the glucose on insulin release (although it did at 16.5 mM glucose). These findings indicate that biotin, by itself, does not stimulate insulin secretion, and does not enhance glucose-induced insulin secretion beyond the ability of glucose itself to stimulate insulin secretion.

Inhibition of human pancreatic islet insulin release by receptor-selective somatostatin analogs directed to somatostatin receptor subtype 5

Somatostatin (SS)-14 and SS28 are produced by pancreatic D cells and gut mucosa and inhibit pancreatic islet insulin and glucagon release. There are five distinct SS receptor (SSTR) subtypes, namely SSTR1–5, which show different affinities for SS14 and SS28. In order to identify the subtype responsible for inhibition of insulin release by human B cells, SSTR-selective SS analogs were tested in isolated human islets. Glucose-stimulated insulin secretion in human islets incubated for 1 hr at 20 mM glucose, and in islets cultured for 24 hr at a near-physiological (6.1 mM) glucose concentration, was inhibited (<50% of the control) by SSTR5-specific analogs and by SS14 and SS28. SS14, SS28, and different SSTR5 preferential analogs also inhibited islet amyloid polypeptide release during the 24-hr culture. On the other hand, a group of SSTR2-selective analogs failed to inhibit insulin release. Analysis by reverse transcription-polymerase chain reaction indicated that human islets express similar amounts of SSTR2 and SSTR5 mRNAs, while human pancreatic ductal cells express much lower levels of these mRNAs. In conclusion, our data suggest that SSTR5 is an important mediator of the insulin inhibitory action of SS in cultured human islets.

Effects of Dehydroepiandrosterone in Rats Injected with Streptozotocin during the Neonatal Period

Control rats and diabetic animals injected with streptozotocin during the neonatal period were either maintained on a standard diet or given access to food supplemented with dehydroepiandrosterone (DHEA, 0.2%) for 11 days before sacrifice. In both control and diabetic rats, DHEA feeding augmented the activity of the mitochondrial FAD-linked glycerophosphate dehydrogenase and cytosolic NADP-linked malate dehydrogenase in liver, but not so in either the parotid gland or pancreatic islets. DHEA lowered, in both control and diabetic rats, the ratio betweend-glucose oxidation and utilization and the rate of insulin release in pancreatic islets exposed to a high concentration ofd-glucose, as well as the insulin concentration and insulin/glucose ratio in plasma. These findings support the view that, in diabetes, DHEA, by increasing sensitivity to insulin, may allow islet B-cells to avoid the otherwise unfavorable consequences of chronic hyperactivity.

Modulatory role of 1,25 dihydroxyvitamin D3 on pancreatic islet insulin release via the cyclic AMP pathway in the rat.

1. Previous studies have shown that vitamin D3 deficiency impairs the insulin response to glucose via an alteration of signal transduction pathways, such as Ca2+ handling and the phosphoinositide pathway. In the present study the adenylyl cyclase pathway was examined in islets from 3 independent groups: normal rats, 4 weeks-vitamin D3 deficient rats and one week-1,25 dihydroxyvitamin D3 (1,25(OH)2D3) treated rats. 2. We found that the very low rate of insulin release observed in vitamin D3 deficient rats could be restored in vitamin D3 deficient islets only with high concentrations of dioctanoyl-cyclic AMP (DO-cyclic AMP), whereas 1,25(OH)2D3 improved the sensitivity of the islets to this exogenous cyclic AMP analogue. 3. The beneficial effect of 1,25(OH)2D3 observed with or without DO-cyclic AMP was protein kinase A-dependent, since the addition of N-[2-(p-bromocinnamylamino) ethyl]-5-isoquinolinesulphonamide (H-89), a specific inhibitor of cyclic AMP-dependent protein kinases, decreased the insulin release of treated rats back to the level seen in vitamin D3 deficient islets. 4. The low rate of insulin release could not be consistently related to an alteration in cyclic AMP content of the islets. Indeed, low insulin response to a barium+theophylline stimulus observed in vitamin D3 deficient islets was paradoxically associated with a supranormal cyclic AMP content in the islets. 5. This paradoxical increase in cyclic AMP observed in these conditions could not be attributed to a lower total phosphodiesterase (PDE) activity, although the portion of Ca(2+)-calmodulin-independent PDE was predominant in islets from vitamin D3 deficient rats. 6. On the other hand, the higher cyclic AMP content of vitamin D3 deficient islets could be related to an increase in glucagon-induced cyclic AMP synthesis in relation to the hyperglucagonaemia previously observed in vitamin D3 deficient rats. Since higher concentrations of exogenous glucagon and higher endogenous cyclic AMP concentrations were required in vitro to restore insulin release to normal values, the cyclic AMP-dependent pathways that usually potentiate insulin secretion appeared to be less efficient in relation to an alteration in the post cyclic AMP effector system. 7. 1,25(OH)2D3 exerted a stimulating effect on insulin release via protein kinase A activation but reduced the supranormal cyclic AMP synthesis, thus exerting a differential modulatory influence on biochemical disturbances in islets induced by vitamin D3 deficiency.

Effect of a glucokinase inhibitor on energy production and insulin release in pancreatic islets.

Glucokinase has exclusively high control strength on glucose usage in the pancreatic beta-cell. However, glucokinase also has extraordinarily high control strength on insulin secretion, which is linked to the phosphate potential, [ATP]/([ADP][Pi]) (F.M. Matschinsky, Y.Liang, P. Kesavan, L. Wang, P. Froguel, G. Velho, D. Cohen, M.A. Permutt, Y. Tanizawa, T.L. Jetton, K. Niswender, and M.A. Magnuson. J. Clin. Invest. 92: 2092-2098, 1993). We propose that the ATP produced via the tricarboxylic acid cycle is approximately constant, irrespective of the glucose level. Furthermore, the component of ATP production that is derived from glycolysis and glycolytically derived NADH, which is shuttled into the mitochondria, is a critical signal controlling the ionic events leading to insulin secretion, as suggested previously (M. J. MacDonald. Diabetes 39: 1461-1466, 1990 and I.D. Dukes, M.S. McIntyre, R.J. Mertz, L.H. Philipson, M.W. Roe, B. Spencer, and J.F. Worley III. J. Biol. Chem. 269: 10979-10982, 1994). To test this hypothesis, glucose usage, oxidation, and insulin secretion were measured in cultured rat islets over a wide range of concentrations of glucose and mannoheptulose, an inhibitor of glucokinase. These data were fit to a mathematical model that predicts that glucokinase will govern the rate of glucose usage and ATP production and will also have a strong, but not complete, control over the rate of glucose oxidation, the phosphate potential, and insulin release. Mannoheptulose caused an inhibition of all three fluxes. The estimates of the mechanistic parameters of the model [maximal velocity (Vmax) and Michaelis constant for glucokinase, Vmax for hexokinase and glucose transport, and the inhibition constant of mannoheptulose to glucokinase] were similar to those obtained in vitro. Thus the data are consistent with a model in which the primary importance of glycolysis in transducing the glucose signal into changes of the phosphate potential imparts to glucokinase a high control strength on glucose-induced insulin secretion.

Neonatal rat dietary carbohydrate affects pancreatic islet insulin secretion in adults and progeny

Neonatal rat pups were artificially reared on isocaloric diets high in carbohydrate (HC) or high in fat (HF) or were naturally reared on mother's milk (MF). The HC adult rats were hyperinsulinemic, normoglycemic, and obese. This study investigates pancreatic islet insulin release (IR) of the adult first-generation (1-) diet-regulated animals and their second-generation (2-) progeny. Male rat 1-HC islets had higher basal IR than either 1-MF or 1-HF control groups. In addition, glucose (17 mM) failed to increase IR above basal values in 1-HC islets, whereas it stimulated IR in 1-MF and 1-HF islets. Similar secretory responses were evoked by 2-ketoisocaproic acid (2-KIC). Female rat 1-MF and 1-HF islets also had higher glucose-stimulated IR compared with 1-HC islets. Male rat 2-HC islets had higher basal IR and reduced sensitivity to glucose and 2-KIC compared with 2-MF islets, which coincided with hyperinsulinemia. Glyceraldehyde-3-phosphate dehydrogenase activity in 1-HC and 2-HC islets was higher than in MF islets. These data suggest that basal IR is higher in islets isolated from animals reared as neonates on a diet high in carbohydrate. Alterations in beta-cell metabolism and secretion probably contribute to the hyperinsulinemia, reduced glucose sensitivity, and glucose intolerance characteristic of this rat model.

Glucocorticoid increases glucose cycling and inhibits insulin release in pancreatic islets of ob/ob mice.

Normoglycemic ob/ob mice were treated for 24 or 48 h with either 25 micrograms/day of dexamethasone or saline. After an overnight fast, the animals were killed and pancreatic islets were incubated with 3H2O or [U-14C]glucose or [5-3H]glucose at 5.5 and 16.7 mM glucose. Incorporation of 3H from 3H2O into carbon 2 of medium glucose and the yield of 14CO2 from [U-14C]glucose and 3H2O from [5-3H]glucose were measured. Dexamethasone treatment for 48 h significantly increased the rate of dephosphorylation of glucose in islets both at 5.5 mM (24 vs. 16%) and 16.7 mM (56 vs. 36%) glucose, whereas glucose oxidation and utilization were unaffected. Dexamethasone treatment also inhibited insulin release by approximately 60% at 5.5 and 16.7 mM glucose, either in the presence or absence of 10 mM arginine, but had no effect when insulin release was stimulated by 1 mM 3-isobutyl-1-methylxanthine. Moreover, 24-h treatment with dexamethasone significantly increased glucose cycling at low and high glucose concentrations in the medium and inhibited insulin responsiveness to glucose and arginine. In conclusion, short-term dexamethasone treatment increases glucose flux through glucose-6-phosphatase in islets from ob/ob mice. This effect may contribute to the decreased insulin response to glucose and arginine found in animals treated with dexamethasone.

Concordant glucose induction of glucokinase, glucose usage, and glucose-stimulated insulin release in pancreatic islets maintained in organ culture.

Using cultured islets as the experimental system, this study established dosage-response and time-dependency curves of the inductive glucose effect on glucose-stimulated insulin release, glucose usage, and glucokinase activity. Glucose-stimulated insulin release in islets cultured for 1, 2, or 7 days was increased as a function of glucose concentration in the culture medium and as a function of time. Glucose usage in the cultured islets showed a close relationship with glucose concentration in the culture medium at both 2 and 7 days of culture. Glucokinase activity increased in islets cultured for 1, 2, or 7 days as a function of increasing glucose concentrations in the culture medium and as a function of time. The V(max) of glucokinase in islets cultured for 7 days in medium containing 30 mM glucose was twice the value of freshly isolated islets and was almost fivefold higher than that in islets cultured for 7 days in 3 mM glucose. The glucose induction of glucose-stimulated insulin release, of glucose usage, and of glucokinase activity were tightly correlated. The biochemical mechanisms of glucose induction of islet glucokinase were further studied. Immunoblotting with an antibody against C-terminal peptide of glucokinase showed that densities of a 52,000-kD protein band from tissue extracts of islets cultured for 7 days in 3, 12, and 30 mM glucose were 25, 44, and 270% compared with that of extract from freshly isolated islets (100%). RNA blot analysis of glucokinase mRNA demonstrated virtually the same levels in fresh islets and islets after 7 days of culture in 3 or 30 mM glucose. The adaptive response of glucokinase to glucose appears therefore to be occurring at a translational or posttranslational site in cultured islets. These data greatly strengthen the concept that glucose is the regulator that induces the activity of glucokinase, which in turn determines the rate change of glucose usage as well as glucose-stimulated insulin release from beta-cells. Thus, the hypothesis that glucokinase is the glucose sensor of beta-cells is strengthened further.