Mitochondrial oxidative stress contributes differently to rat pancreatic islet cell apoptosis and insulin secretory defects after prolonged culture in a low non-stimulating glucose concentration.

AIMS/HYPOTHESIS: Pancreatic beta cells chronically exposed to low glucose concentrations show signs of oxidative stress, loss of glucose-stimulated insulin secretion (GSIS) and increased apoptosis. Our aim was to confirm the role of mitochondrial oxidative stress in rat islet cell apoptosis under these culture conditions and to evaluate whether its reduction similarly improves survival and GSIS. METHODS: Apoptosis, oxidative stress-response gene mRNA expression and glucose-induced stimulation of mitochondrial metabolism, intracellular Ca(2+) concentration and insulin secretion were measured in male Wistar rat islets cultured for 1 week in RPMI medium containing 5-10 mmol/l glucose with or without manganese(III)tetrakis(4-benzoic acid)porphyrin (MnTBAP) or N-acetyl-L-: cysteine (NAC). Oxidative stress was measured in islet cell clusters cultured under similar conditions using cytosolic and mitochondrial redox-sensitive green fluorescent protein (roGFP1/mt-roGFP1). RESULTS: Prolonged culture in 5 vs 10 mmol/l glucose increased mt-roGFP1 (but not roGFP1) oxidation followed by beta cell apoptosis and loss of GSIS resulting from reduced insulin content, mitochondrial metabolism, Ca(2+) influx and Ca(2+)-induced secretion. Tolbutamide-induced, but not high K(+)-induced, Ca(2+) influx was also suppressed. Under these conditions, MnTBAP, but not NAC, triggered parallel ~50-70% reductions in mt-roGFP1 oxidation and beta cell apoptosis, but failed to protect against the loss of GSIS despite significant improvement in glucose-induced and tolbutamide-induced Ca(2+) influx. CONCLUSIONS/INTERPRETATION: Mitochondrial oxidative stress contributes differently to rat pancreatic islet cell apoptosis and insulin secretory defects during culture in a low glucose concentration. Thus, targeting beta cell survival may not be sufficient to restore insulin secretion when beta cells suffer from prolonged mitochondrial oxidative stress, e.g. in the context of reduced glucose metabolism.

Adenylyl cyclase 8 is central to glucagon-like peptide 1 signalling and effects of chronically elevated glucose in rat and human pancreatic beta cells.

AIMS/HYPOTHESIS: Glucose and incretins regulate beta cell function, gene expression and insulin exocytosis via calcium and cAMP. Prolonged exposure to elevated glucose (also termed glucotoxicity) disturbs calcium homeostasis, but little is known about cAMP signalling. We therefore investigated long-term effects of glucose on this pathway with special regard to the incretin glucagon-like peptide 1 (GLP-1). METHODS: We exposed INS-1E cells and rat or human islets to different levels of glucose for 3 days and determined functional responses in terms of second messengers (cAMP, Ca(2+)), transcription profiles, activation of cAMP-responsive element (CRE) and secretion by measuring membrane capacitance. Moreover, we modulated directly the abundance of a calcium-sensitive adenylyl cyclase (ADCY8) and GLP-1 receptor (GLP1R). RESULTS: GLP-1- or forskolin-mediated increases in cytosolic calcium, cAMP-levels or insulin secretion were largely reduced in INS-1E cells cultured at elevated glucose (>5.5 mmol/l). Statistical analysis of transcription profiles identified cAMP pathways as major targets regulated by glucose. Quantitative PCR confirmed these findings and unravelled marked downregulation of the calcium-sensitive adenylyl cyclase ADCY8 also in rat and in human islets. Re-expression of ADCY8, but not of the GLP1R, recovered GLP-1 signalling in glucotoxicity in INS-1E cells and in rat islets. Moreover, knockdown of this adenylyl cyclase showed that GLP-1-induced cAMP generation, calcium signalling, activation of the downstream target CRE and direct amplification of exocytosis by cAMP-raising agents (evaluated by capacitance measurement) proceeds via ADCY8. CONCLUSIONS/INTERPRETATION: cAMP-mediated pathways are modelled by glucose, and downregulation of the calcium-sensitive ADCY8 plays a central role herein, including signalling via the GLP1R.

Effects of fructosamine-3-kinase deficiency on function and survival of mouse pancreatic islets after prolonged culture in high glucose or ribose concentrations.

Due to their high glucose permeability, insulin-secreting pancreatic beta-cells likely undergo strong intracellular protein glycation at high glucose concentrations. They may, however, be partly protected from the glucotoxic alterations of their survival and function by fructosamine-3-kinase (FN3K), a ubiquitous enzyme that initiates deglycation of intracellular proteins. To test that hypothesis, we cultured pancreatic islets from Fn3k-knockout (Fn3k(-/-)) mice and their wild-type (WT) littermates for 1-3 wk in the presence of 10 or 30 mmol/l glucose (G10 or G30, respectively) and measured protein glycation, apoptosis, preproinsulin gene expression, and Ca(2+) and insulin secretory responses to acute glucose stimulation. The more potent glycating agent d-ribose (25 mmol/l) was used as positive control for protein glycation. In WT islets, a 1-wk culture in G30 significantly increased the amount of soluble intracellular protein-bound fructose-epsilon-lysines and the glucose sensitivity of beta-cells for changes in Ca(2+) and insulin secretion, whereas it decreased the islet insulin content. After 3 wk, culture in G30 also strongly decreased beta-cell glucose responsiveness and preproinsulin mRNA levels, whereas it increased islet cell apoptosis. Although protein-bound fructose-epsilon-lysines were more abundant in Fn3k(-/-) vs. WT islets, islet cell survival and function and their glucotoxic alterations were almost identical in both types of islets, except for a lower level of apoptosis in Fn3k(-/-) islets cultured for 3 wk in G30. In comparison, d-ribose (1 wk) similarly decreased preproinsulin expression and beta-cell glucose responsiveness in both types of islets, whereas it increased apoptosis to a larger extent in Fn3k(-/-) vs. WT islets. We conclude that, despite its ability to reduce the glycation of intracellular islet proteins, FN3K is neither required for the maintenance of beta-cell survival and function under control conditions nor involved in protection against beta-cell glucotoxicity. The latter, therefore, occurs independently from the associated increase in the level of intracellular fructose-epsilon-lysines.

Cluster analysis of rat pancreatic islet gene mRNA levels after culture in low-, intermediate- and high-glucose concentrations.

AIMS/HYPOTHESIS: Survival and function of insulin-secreting pancreatic beta cells are markedly altered by changes in nutrient availability. In vitro, culture in 10 rather than 2 mmol/l glucose improves rodent beta cell survival and function, whereas glucose concentrations above 10 mmol/l are deleterious. METHODS: To identify the mechanisms of such beta cell plasticity, we tested the effects of 18 h culture at 2, 5, 10 and 30 mmol/l glucose on the transcriptome of rat islets pre-cultured for 1 week at 10 mmol/l glucose using Affymetrix Rat 230 2.0 arrays. RESULTS: Culture in either 2-5 or 30 mmol/l instead of 10 mmol/l glucose markedly impaired beta cell function, while little affecting cell survival. Of about 16,000 probe-sets reliably detected in islets, some 5,000 were significantly up- or downregulated at least 1.4-fold by glucose. Analysis of these probe-sets with GeneCluster software identified ten mRNA profiles with unidirectional up- or downregulation between 2 and 10, 2 and 30, 5 and 10, 5 and 30 or 10 and 30 mmol/l glucose. It also identified eight complex V-shaped or inverse V-shaped profiles with a nadir or peak level of expression in 5 or 10 mmol/l glucose. Analysis of genes belonging to these various clusters using Onto-express and GenMAPP software revealed several signalling and metabolic pathways that may contribute to induction of beta cell dysfunction and apoptosis after culture in low- or high- vs intermediate-glucose concentration. CONCLUSIONS/INTERPRETATION: We have identified 18 distinct mRNA profiles of glucose-induced changes in islet gene mRNA levels that should help understand the mechanisms by which glucose affects beta cell survival and function under states of chronic hypo- or hyperglycaemia.

Glucose regulation of islet stress responses and beta-cell failure in type 2 diabetes.

Pancreatic beta-cells exposed to high glucose concentrations display altered gene expression, function, survival and growth that may contribute to the slow deterioration of the functional beta-cell mass in type 2 diabetes. These glucotoxic alterations may result from various types of stress imposed by the hyperglycaemic environment, including oxidative stress, endoplasmic reticulum stress, cytokine-induced apoptosis and hypoxia. The glucose regulation of oxidative stress-response and integrated stress-response genes in cultured rat islets follows an asymmetric V-shaped profile parallel to that of beta-cell apoptosis, with a large increase at low glucose and a moderate increase at high vs. intermediate glucose concentrations. These observations suggest that both types of stress could play a role in the alteration of the functional beta-cell mass under states of prolonged hypoglycaemia and hyperglycaemia. In addition, beta-cell demise under glucotoxic conditions may also result from beta-cell hypoxia and, in vivo, from their exposure to inflammatory cytokines released locally by non-endocrine islet cells. A better understanding of the relative contribution of each type of stress to beta-cell glucotoxicity and of their pathophysiological cause in vivo may lead to new therapeutic strategies to prevent the slow deterioration of the functional beta-cell mass in glucose intolerant and type 2 diabetic patients.

Possible links between glucose-induced changes in the energy state of pancreatic B cells and insulin release. Unmasking by decreasing a stable pool of adenine nucleotides in mouse islets.

Whether adenine nucleotides in pancreatic B cells serve as second messengers during glucose stimulation of insulin secretion remains disputed. Our hypothesis was that the actual changes in ATP and ADP are obscured by the large pool of adenine nucleotides (ATP/ADP ratio close to 1) in insulin granules. Therefore, mouse islets were degranulated acutely with a cocktail of glucose, KCl, forskolin, and phorbol ester or during overnight culture in RPMI-1640 medium containing 10 mM glucose. When these islets were then incubated in 0 glucose + azide (to minimize cytoplasmic and mitochondrial adenine nucleotides), their content in ATP + ADP + AMP was decreased in proportion to the decrease in insulin stores. After incubation in 10 mM glucose (no azide), the ATP/ADP ratio increased from 2.4 to > 8 in cultured islets, and only from 2 to < 4 in fresh islets. These differences were not explained by changes in glucose oxidation. The glucose dependency (0-30 mM) of the changes in insulin secretion and in the ATP/ADP ratio were then compared in the same islets. In nondegranulated, fresh islets, the ATP/ADP ratio increased between 0 and 10 mM glucose and then stabilized although insulin release kept increasing. In degranulated islets, the ATP/ADP ratio also increased between 0 and 10 mM glucose, but a further increase still occurred between 10 and 20 mM glucose, in parallel with the stimulation of insulin release. In conclusion, decreasing the granular pool of ATP and ADP unmasks large changes in the ATP/ADP ratio and a glucose dependency which persists within the range of stimulatory concentrations. The ATP/ADP ratio might thus serve as a coupling factor between glucose metabolism and insulin release.

Effect of disruption of actin filaments by Clostridium botulinum C2 toxin on insulin secretion in HIT-T15 cells and pancreatic islets.

To examine their role in insulin secretion, actin filaments (AFs) were disrupted by Clostridium botulinum C2 toxin that ADP-ribosylates G-actin. Ribosylation also prevents polymerization of G-actin to F-actin and inhibits AF assembly by capping the fast-growing end of F-actin. Pretreatment of HIT-T15 cells with the toxin inhibited stimulated insulin secretion in a time- and dose-dependent manner. The toxin did not affect cellular insulin content or nonstimulated secretion. In static incubation, toxin treatment caused 45-50% inhibition of secretion induced by nutrients alone (10 mM glucose + 5 mM glutamine + 5 mM leucine) or combined with bombesin (phospholipase C-activator) and 20% reduction of that potentiated by forskolin (stimulator of adenylyl cyclase). In perifusion, the stimulated secretion during the first phase was marginally diminished, whereas the second phase was inhibited by approximately 80%. Pretreatment of HIT cells with wartmannin, a myosin light chain kinase inhibitor, caused a similar pattern of inhibition of the biphasic insulin release as C2 toxin. Nutrient metabolism and bombesin-evoked rise in cytosolic free Ca2+ were not affected by C2 toxin, indicating that nutrient recognition and the coupling between receptor activation and second messenger generation was not changed. In the toxin-treated cells, the AF web beneath the plasma membrane and the diffuse cytoplasmic F-actin fibers disappeared, as shown both by staining with an antibody against G- and F-actin and by staining F-actin with fluorescent phallacidin. C2 toxin dose-dependently reduced cellular F-actin content. Stimulation of insulin secretion was not associated with changes in F-actin content and organization. Treatment of cells with cytochalasin E and B, which shorten AFs, inhibited the stimulated insulin release by 30-50% although differing in their effects on F-actin content. In contrast to HIT-T15 cells, insulin secretion was potentiated in isolated rat islets after disruption of microfilaments with C2 toxin, most notably during the first phase. This effect was, however, diminished, and the second phase became slightly inhibited when the islets were degranulated. These results indicate an important role for AFs in insulin secretion. In the poorly granulated HIT-T15 cells actin-myosin interactions may participate in the recruitment of secretory granules to the releasable pool. In native islet beta-cells the predominant function of AFs appears to be the limitation of the access of granules to the plasma membrane.

Prenylcysteine analogs mimicking the C-terminus of GTP-binding proteins stimulate exocytosis from permeabilized HIT-T15 cells: comparison with the effect of Rab3AL peptide.

Most guanine nucleotide binding proteins (G-proteins) possess an S-prenylated C-terminal cysteine whose carboxyl group can be reversibly methylated. The prenylcysteine analog N-acetyl-S-geranylgeranyl-cysteine (AGGC) (50 microM), a competitive inhibitor of prenylcysteine methyl transferases, introduced into streptolysin-O permeabilized HIT-T15 cells doubled the rate of basal (0.1 microM Ca2+) and of stimulated (10 microM Ca2+ or 100 microM GTP gamma S) insulin secretion in a reversible and ATP-dependent manner. N-acetyl-S-farnesylcysteine (AFC) was less potent while N-acetyl-S-geranyl-cysteine was inactive. Prenylcysteine action on exocytosis did not involve inhibition of G-protein methylation, since (1) the methyl ester derivative of AFC, an inefficient inhibitor of methyltransferases in HIT-T15 cell fractions, was as potent as AGGC in stimulating exocytosis; (2) S-adenosyl-homocysteine, a general inhibitor of methylation reactions, did not alter basal or GTP gamma S-triggered secretion while inhibiting Ca(2+)-induced insulin release. The binding of G-proteins to Rab/GDP-dissociation inhibitor, Rab3A/GTPase activating protein or rabphilin-3A was not affected by the prenylcysteine analogs. AGGC or AFC had the same effect on insulin release as a synthetic peptide mimicking the amino acid residues 52-67 of the G-protein Rab3A (Rab3AL). Moreover, the action on secretion of the combination of Rab3AL and prenylcysteines was not additive. We propose that the prenylcysteines and the Rab3AL peptide influence exocytosis by affecting the association of Rab3A with different proteins of the exocytotic machinery of insulin-secreting cells.

Temporal and quantitative correlations between insulin secretion and stably elevated or oscillatory cytoplasmic Ca2+ in mouse pancreatic beta-cells.

An increase in cytoplasmic Ca2+ in beta-cells is a key step in glucose-induced insulin secretion. However, whether changes in cytoplasmic free Ca2+ ([Ca2+]i) directly regulate secretion remains disputed. This question was addressed by investigating the temporal and quantitative relationships between [Ca2+]i and insulin secretion. Both events were measured simultaneously in single mouse islets loaded with fura-PE3 and perifused with a medium containing diazoxide (to prevent any effect of glucose on the membrane potential) and either 4.8 or 30 mmol/l K+. Continuous depolarization with 30 mmol/l K+ in the presence of 15 mmol/l glucose induced a sustained rise in [Ca2+]i and insulin release. No oscillations of secretion were detected even after mathematical analysis of the data (pulse, spectral and sample distribution analysis). In contrast, alternating between 30 and 4.8 mmol/l K+ (1 min/2 min or 2.5 min/5 min) triggered synchronous [Ca2+]i and insulin oscillations of regular amplitude in each islet. A good correlation was found between [Ca2+]i and insulin secretion, and it was independent of the presence or absence of oscillations. This quantitative correlation between [Ca2+]i and insulin secretion was confirmed by experiments in which extracellular Ca2+ was increased or decreased (0.1-2.5 mmol/l) stepwise in the presence of 30 mmol/l K+. This resulted in parallel stepwise increases or decreases in [Ca2+]i and insulin secretion. However, while the successive [Ca2+]i levels were unaffected by glucose, each plateau of secretion was much higher in 20 than in 3 mmol/l glucose. In conclusion, in our preparation of normal mouse islets, insulin secretion oscillates only when [Ca2+]i oscillates in beta-cells. This close temporal relationship between insulin secretion and [Ca2+]i changes attests of the regulatory role of Ca2+. There also exists a quantitative relationship that is markedly influenced by the concentration of glucose.

Stable and diffusible pools of nucleotides in pancreatic islet cells.

Adenine nucleotides are thought to serve as second messengers in the control of beta-cell function by glucose, e.g. by regulating the activity of ATP-dependent K+ channels. However, their localization in different intracellular pools may mask the biologically relevant changes and complicate the interpretation of measurements in whole cells. The plasma membrane of mouse islet cells was selectively permeabilized by the alpha-toxin from Staphylococcus aureus to allow diffusion of cytoplasmic nucleotides. After permeabilization of cells from freshly isolated islets, approximately 68% of ATP, 45% of ADP, and 52% of AMP rapidly diffused out of the cells, whereas the insulin content hardly varied. The nondiffusible pool of nucleotides was stable for at least 90 min at 4 C, which suggests that it is contained in cellular organelles. The size of this nondiffusible pool decreased proportionally to insulin stores when these were lowered by stimulating secretion to different degrees during culture before permeabilization. From these results, it can be calculated that nondiffusible nucleotides are mainly contained in insulin secretory granules, with a small proportion in another, probably mitochondrial, compartment. Approximately 80% GTP and 30% GDP were present in the diffusible pool, and their relative proportions in the granular pool were only about 20% that of adenine nucleotides. Incubation of the cells in 20 instead of 2 mM glucose before permeabilization did not affect the nondiffusible pool, which indicates that the increase in the ATP/ADP ratio measured in intact cells occurred in the diffusible pool. Cytoplasmic nucleotide levels could be evaluated by subtracting the nondiffusible pool from the measurements in intact cells. It emerges that glucose induces large changes in the ATP/ADP ratio in the cytoplasmic pool, and that these changes are largely due to a fall in ADP.

Glucose regulates expression of inositol 1,4,5-trisphosphate receptor isoforms in isolated rat pancreatic islets.

Isolated rat pancreatic islets were studied to determine the dynamic regulatory effects of glucose stimulation on the expression of messenger RNA (mRNA) and protein levels for inositol 1,4,5-trisphosphate (IP3) receptor (IP3R) isoforms I, II, and III. The relative isoform abundance was: IP3R-III > IP3R-II approximately IP3R-I. Culture of islets with glucose (G; 20 mM) or alpha-ketoisocaproic acid for 30 min increased only IP3R-III mRNA expression above control (5.5 mM glucose). 2-Deoxyglucose was without effect. Islet culture for 2 h with G (20 mM) or alpha-ketoisocaproic acid reduced IP3R-III mRNA expression levels below control, and cycloheximide blocked the response. Culturing islets for 1 day or 7 days with G (11 mM) reduced the expression of IP3R-III mRNA but increased the expression of IP3R-II mRNA in a time-dependent manner. Cytosine arabinoside lowered cultured islet IP3R-II and -III mRNA levels, but glucose effects remained evident. IP3R-II mRNA levels were also significantly higher in islets from hyperglycemic 90% partial pancreatectomized rats, compared with sham animals. Islet IP3R mRNA expression also showed osmotic sensitivity. Islet IP3R-III protein levels increased after 2 h islet culture at 20 mM G, were unchanged after 1 day culture at 11 mM G, and were lower than control after 7 days culture at 11 mM G. In contrast, IP3R-II levels increased after 1 day and 7 days culture at 11 mM G, whereas IP3R-I protein levels remained unchanged. Thus, G stimulation rapidly increases transcription and expression of IP3R-III mRNA and protein levels in rat islets. However, chronic G stimulation up-regulates IP3R-II mRNA in cultured islets and in islets from partial pancreatectomized rats. Metabolic regulation of IP3R-II and III expression may mediate beta-cell IP3-responsive Ca2+ mobilization and insulin secretion.

Gene expression of VEGF and its receptors Flk-1/KDR and Flt-1 in cultured and transplanted rat islets.

BACKGROUND: Vascular endothelial growth factor (VEGF) and its two receptor tyrosine kinases, Flk-1/KDR and Flt-1, may play an important role in mediating the revascularization of transplanted pancreatic islets. METHODS: Using semiquantitative multiplex reverse-transcribed polymerase chain reaction we determined the gene expression of VEGF and its receptors in cultured and transplanted rat islets. RESULTS: After exposure of islet cells to hypoxia in vitro, increases were found in the gene expression of the VEGF120 and VEGF164 isoforms, with simultaneous increases in VE-cadherin, Flk-1/KDR, and Flt-1. In vivo studies consisted of analysis of islet grafts transplanted into both normal and diabetic recipients. Expression of both VEGF120 and VEGF164 in grafts was up-regulated for the first 2-3 days after transplantation, with the response being more prolonged in the diabetic rats. These increases were followed by reduced expression of VEGF on days 5, 7, and 9. Increases in the expression of VE-cadherin in islet grafts in normal and diabetic recipients tended to parallel VEGF expression, with the increases in both probably being caused by hypoxia. The early increases of VEGF expression were followed by a rise in the expression of VEGF receptors, which probably represents the early stages of angiogenesis. Graft expression of Flk-1/KDR and Flt-1 was enhanced at 3 and 5 days in the normoglycemic recipients, while in the diabetic recipients increases were found later on days 5, 7, and 14. CONCLUSIONS: The delayed expression of VEGF receptors in the diabetic recipients could reflect impaired angiogenesis caused by the diabetic milieu; this delay could contribute to the less outcomes of grafts transplanted into a hyperglycemic environment.

Clonidine inhibits ATP-sensitive K+ channels in mouse pancreatic beta-cells.

1. The effects of clonidine and adrenaline on adenosine 5'-triphosphate (ATP)-sensitive K+ channels were studied in pancreatic beta-cells from normal mice. 2. When perifused with a medium containing 1 mM glucose, many of the ATP-sensitive K+ channels in the beta-cell membrane are open. Under these conditions, clonidine (5-100 microM) reversibly decreased 86Rb efflux from the islets, whereas adrenaline was ineffective at concentrations up to 100 microM. 3. In 6 mM glucose, most of the ATP-sensitive K+ channels in the beta-cell membrane are closed. Opening these channels by diazoxide (100 microM) caused a marked acceleration of 86Rb efflux from the islets, which was attenuated by 100 microM clonidine. 4. ATP-sensitive K+ currents were measured in single beta-cells by the whole cell mode of the patch-clamp technique. At concentrations above 4 microM, clonidine reversibly inhibited the ATP-sensitive K+ current in a dose-dependent manner. 5. Voltage-sensitive K+ currents were unaffected by 20 microM but decreased slightly by 100 microM clonidine. 6. Calcium currents, measured by the whole cell or perforated patch technique, were unaffected by clonidine at concentrations up to 100 microM. 7. It is concluded that high concentrations of the alpha 2-adrenoceptor agonist clonidine, but not of adrenaline, can inhibit ATP-sensitive K+ channels in pancreatic beta-cells. Other ionic channels are only slightly affected or unaffected.

Imidazoline antagonists of alpha 2-adrenoceptors increase insulin release in vitro by inhibiting ATP-sensitive K+ channels in pancreatic beta-cells.

1. Islets from normal mice were used to study the mechanisms by which imidazoline antagonists of alpha 2-adrenoceptors increase insulin release in vitro. 2. Alinidine, antazoline, phentolamine and tolazoline inhibited 86Rb efflux from islets perifused with a medium containing 3 mM glucose, i.e. under conditions where many adenosine 5'-triphosphate (ATP)-sensitive K+ channels are open in the beta-cell membrane. They also reduced the acceleration of 86Rb efflux caused by diazoxide, an opener of ATP-sensitive K+ channels. 3. ATP-sensitive and voltage-sensitive K+ currents were measured in single beta-cells by the whole-cell mode of the patch-clamp technique. Antazoline more markedly inhibited the ATP-sensitive than the voltage-sensitive current, an effect previously observed with phentolamine. Alinidine and tolazoline partially decreased the ATP-sensitive K+ current. 4. The four imidazolines reversed the inhibition of insulin release caused by diazoxide (through opening of ATP-sensitive K+ channels) or by clonidine (through activation of alpha 2-adrenoceptors) in a concentration-dependent manner. Only the former effect correlated with the ability of each drug to increase control insulin release stimulated by 15 mM glucose alone. 5. It is concluded that the ability of imidazoline antagonists of alpha 2-adrenoceptors to increase insulin release in vitro can be ascribed to their blockade of ATP-sensitive K+ channels in beta-cells rather than to their interaction with the adrenoceptor.

Multiple effects and stimulation of insulin secretion by the tyrosine kinase inhibitor genistein in normal mouse islets.

1. Islets from normal mice were used to test the acute effects of genistein, a potent tyrosine kinase inhibitor, on stimulus-secretion coupling in pancreatic beta-cells. 2. Genistein produced a concentration-dependent (10-100 microM), reversible, increase of insulin release. This effect was marginal on basal release or in the presence of non-metabolized secretagogues, and much larger in the presence of glucose or other nutrients. The increase in insulin release caused by 100 microM genistein was abolished by adrenaline or omission of extracellular Ca2+. It was not accompanied by any rise of cyclic AMP, inositol phosphate or adenine nucleotide levels. 3. Although genistein slightly inhibited ATP-sensitive K+ channels, as shown by 86Rb efflux and patch-clamp experiments, this effect could not explain the action of the drug on insulin release because the latter persisted when ATP-sensitive K+ channels were all blocked by maximally effective concentrations of glucose and tolbutamide. Genistein was also effective when ATP-sensitive K+ channels were opened by diazoxide and the beta-cell membrane depolarized by 30 mM K, but ineffective in the presence of diazoxide and normal extracellular K. 4. Genistein paradoxically decreased Ca2+ influx in beta-cells, as shown by the inhibition of glucose-induced electrical activity, by the inhibition of Ca2+ currents (perforated patches) and by the lowering of cytosolic [Ca2+]i (fura-2 technique). Genistein thus increases insulin release in spite of a lowering of [Ca2+]i in beta-cells. 5. Daidzein, an analogue of genistein reported not to affect tyrosine kinases, was slightly less potent than genistein on K+ and Ca2+ channels, but increased insulin secretion in a similar way. Three other tyrosine kinase inhibitors, tyrphostin A47, herbimycin A and an analogue of erbstatin variably affected insulin secretion.6. Genistein exerts a number of heretofore unrecognized effects. The unusual mechanisms, by which genistein increases insulin release in spite of a decrease in beta-cell [Ca2+]i and without activating known signalling pathways, do not seem to result from an inhibition of tyrosine kinases.

The imidazoline SL 84.0418 shows stereoselectivity in blocking alpha 2-adrenoceptors but not ATP-sensitive K+ channels in pancreatic B-cells.

The novel alpha 2-adrenoceptor antagonist SL 84.0418 (2-(4,5-dihydro-1H-imidazol-2-yl)-1,2,4,5-tetrahydro-2-propyl-pyrrolo[3, 2,1- hi]-indole hydrochloride) is a racemic mixture of a (-) enantiomer (SL 86.0714) and a (+) enantiomer (SL 86.0715 or deriglidole). It was recently reported to inhibit alpha 2-adrenoceptors and ATP-sensitive K+ channels in mouse pancreatic B-cells, and to increase insulin release. We have now studied the stereospecificity of these responses with isolated mouse islets. Both enantiomers were equipotent in potentiating insulin release induced by 15 mM glucose alone. SL 86.0714 and deriglidole were also equally effective in inhibiting 86Rb efflux from islets perifused with a low-glucose medium, and in reversing the inhibition of glucose-induced insulin release caused by the opening of ATP-sensitive K+ channels with diazoxide. In contrast, deriglidole was approximately 100-fold more potent than SL 86.0714 in reversing the inhibition of insulin release caused by the activation of alpha 2-adrenoceptors with clonidine. The effects of SL 84.0418 are thus stereoselective on alpha 2-adrenoceptors, but not on ATP-sensitive K+ channels of pancreatic B-cells.

In vitro stimulation of insulin release by SL 84.0418, a new alpha 2-adrenoceptor antagonist.

SL 84.0418 (2-(4,5-dihydro-1H-imidazol-2-yl)-1,2,4,5-tetrahydro-2-propyl-pyrrolo[3, 2,1- hi]-indole hydrocholoride) is a novel alpha 2-adrenoceptor antagonist which possesses anti-hyperglycaemic properties in vitro study, we tested its effects on insulin release from isolated mouse islets. In the presence of 15 mM glucose, SL 84.0418 produced a concentration-dependent (0.1-100 microM) increase of insulin release with a slightly higher potency than tolbutamide. SL 84.0418 antagonized the inhibition of glucose-induced insulin release caused either by the alpha 2-adrenoceptor agonist clonidine or by diazoxide, a selective opener of ATP-sensitive K+ channels in the beta-cell membrane. Its potency was greater on the inhibition by clonidine than on that by diazoxide, complete antagonism of the inhibition being achieved by 0.9 microM and 6 microM SL 84.0418 respectively. When alpha 2-adrenoceptors were blocked by the antagonist idazoxan, the low concentrations of SL 84.0418 (0.1-0.3 microM) no longer increased insulin release, whereas the effect of higher concentrations (> or = 1 microM) was not affected. SL 84.0418 (> or = 1 microM) inhibited 86Rb efflux from islets perifused with a medium containing 3 mM glucose, i.e. under conditions where many ATP-sensitive K+ channels are open. It also reduced the acceleration of 86Rb efflux that diazoxide caused in the presence of 6 mM glucose. Moreover, SL 84.0418 directly inhibited ATP-sensitive K+ currents measured in single beta-cells by the whole-cell mode of the patch-clamp technique.(ABSTRACT TRUNCATED AT 250 WORDS)

Sulphonylureas do not increase insulin secretion by a mechanism other than a rise in cytoplasmic Ca2+ in pancreatic B-cells.

The following sequence of events is thought to underlie the stimulation of insulin release by hypoglycaemic sulphonylureas. Interaction of the drugs with a high-affinity binding site (sulphonylurea receptor) in the B-cell membrane leads to closure of ATP-sensitive K+ channels, depolarization, opening of voltage-dependent Ca2+ channels, Ca2+ influx and rise in cytoplasmic [Ca2+]i. Recent experiments using permeabilized islet cells or measuring changes in B-cell membrane capacitance have suggested that sulphonylureas can increase insulin release by a mechanism independent of a change in [Ca2+]i. This provocative hypothesis was tested here with intact mouse islets. When B-cells were strongly depolarized by 60 mM K+, [Ca2+]i was increased and insulin secretion stimulated. Under these conditions, tolbutamide did not further increase [Ca2+]i or insulin release, whether it was applied before or after high K+, and whether the concentration of glucose was 3 or 15 mM. This contrasts with the ability of forskolin and phorbol 12-myristate 13-acetate (PMA) to increase release in the presence of high K+. Tolbutamide also failed to increase insulin release from islets depolarized with barium (substituted for extracellular Ca2+) or with arginine in the presence of high glucose. Glibenclamide and its non-sulphonylurea moiety meglitinide were also without effect on insulin release from already depolarized B-cells. In the absence of extracellular Ca2+, acetylcholine induced monophasic peaks of [Ca2+]i and insulin secretion which were both unaffected by tolbutamide. Insulin release from permeabilized islet cells was stimulated by raising free Ca2+ (between 0.1 and 23 microM). This effect was not affected by tolbutamide and inconsistently increased by glibenclamide. In conclusion, the present study does not support the proposal that hypoglycaemic sulphonylureas can increase insulin release even when they do not also raise [Ca2+]i in B-cells.

Functional significance of Ca2+ oscillations in pancreatic beta cells.

Several aspects of pancreatic beta cell function display marked oscillations even during continuous stimulation with a stable glucose concentration. This review article focuses on the characteristics, mechanisms and potential roles of the oscillations of cytoplasmic Ca2+ concentration [(Ca2+]i) in beta cells. These oscillations result from an intermittent influx of Ca2+ through voltage-dependent Ca2+ channels activated by periodic depolarizations of the plasma membrane. In each islet, [Ca2+]i oscillations are synchronous in all beta cells and trigger similar oscillations of insulin secretion. Changes in [Ca2+]i are thought to play a minute-to-minute regulatory role in secretion, but the effectiveness of Ca2+ on the secretory process is markedly influenced by various amplification mechanisms. It is still unclear whether the oscillations of [Ca2+]i reflect functional advantages for the beta cell itself or are simply necessary to ensure oscillations of plasma insulin levels through pulsatile secretion of the hormone.

[Potential role of the early response gene c-Myc in the loss of differentiation and function of pancreatic beta cells submitted to chronic hyperglycemia]. / Rôle possible du gène de réponse précoce c-Myc dans la perte de différenciation et de fonction des cellules beta pancréatiques soumises à une hyperglycémie chronique.

Chronic hyperglycemia exerts deleterious effects on glucose-induced insulin secretion by pancreatic beta cells. In 90% pancreatectomized rats, chronic hyperglycemia induces beta cell hypertrophy and loss of differentiation associated with increased expression of the early response gene c-Myc. Hyperglycemia also stimulates c-Myc expression in vivo in islets from glucose-infused rats and in vitro in cultured rat islets. This effect requires the elevation of cytosolic Ca2+ concentration produced by glucose. Our results suggest that overstimulation of c-Myc expression by chronic hyperglycemia may be the cause of beta cell hypertrophy and loss of differentiation and function observed in animal models of type 2 diabetes.