Multiple effector pathways regulate the insulin secretory response to the imidazoline RX871024 in isolated rat pancreatic islets.

When isolated rat islets were cultured for 18 h prior to use, the putative imidazoline binding site ligand, RX871024 caused a dose-dependent increase in insulin secretion at both 6 mM and 20 mM glucose. By contrast, a second ligand, efaroxan, was ineffective at 20 mM glucose whereas it did stimulate insulin secretion in response to 6 mM glucose. Exposure of islets to RX871024 (50 microM) for 18 h, resulted in loss of responsiveness to this reagent upon subsequent re-exposure. However, islets that were unresponsive to RX871024 still responded normally to efaroxan. The imidazoline antagonist, KU14R, blocked the insulin secretory response to efaroxan, but failed to prevent the stimulatory response to RX871024. By contrast with its effects in cultured islets, RX871024 inhibited glucose-induced insulin release from freshly isolated islets. Efaroxan did not inhibit insulin secretion under any conditions studied. In freshly isolated islets, the effects of RX871024 on insulin secretion could be converted from inhibitory to stimulatory, by starvation of the animals. Inhibition of insulin secretion by RX871024 in freshly isolated islets was prevented by the cyclo-oxygenase inhibitors indomethacin or flurbiprofen. Consistent with this, RX871024 caused a marked increase in islet PGE2 formation. Efaroxan did not alter islet PGE2 levels. The results suggest that RX871024 exerts multiple effects in the pancreatic beta-cell and that its effects on insulin secretion cannot be ascribed only to interaction with a putative imidazoline binding site.     

Stimulation of insulin secretion by efaroxan may involve interaction with potassium channels

The imidazoline alpha 2-antagonist efaroxan was found to stimulate insulin secretion from isolated rat pancreatic islets incubated in glucose concentrations between 4 and 12 mM. This response could not be attributed to interaction of efaroxan with either classical alpha 2-receptors or with a B-cell 'imidazoline receptor', since the effect was not reproduced by the structural analogue idazoxan. Stimulation of insulin secretion by efaroxan correlated with the ability of the drug to reverse the inhibition of secretion mediated by the potassium channel agonist diazoxide. The data suggest that the capacity of efaroxan to stimulate insulin secretion may be related to an interaction with potassium channels in the pancreatic B-cell.     

Stimulation of insulin secretion by imidazoline compounds is not due to interaction with non-adrenoceptor idazoxan binding sites.

1. The potency of interaction of several imidazoline compounds with non-adrenoceptor idazoxan binding sites (NAIBS) in rat liver membranes was compared with their ability to alter insulin secretion from rat pancreatic islets. 2. NAIBS could be labelled specifically with [3H]-idazoxan in both rat liver membranes and in rat islet homogenates. Liver binding sites exhibited a KD for [3H]-idazoxan of 24 nM and a Bmax of 264 fmol mg-1 protein. 3. Binding of [3H]-idazoxan to NAIBS in rat liver membranes was displaced effectively by unlabelled idazoxan (IC50 0.1 microM) and by UK14304 (IC50 0.5 microM). However, two other imidazoline compounds efaroxan and RX821002, which are related in structure to idazoxan, were much less effective as displacers. 4. In insulin secretion experiments, the ATP-sensitive potassium channel agonist diazoxide (250 microM) was able to suppress the rise in insulin secretion induced by 20 mM glucose. Both efaroxan and RX821002 (100 microM) antagonized the inhibitory effect of diazoxide on glucose-induced insulin secretion. By contrast, neither idazoxan (100 microM) nor UK14304 (50 microM), was able to overcome significantly the inhibitory effect of diazoxide. 5. The ability of 100 microM efaroxan to antagonize the suppression of insulin secretion mediated by diazoxide, was not prevented by idazoxan (up to 100 microM) or by UK14304 (up to 50 microM). 6. The results indicate that the stimulatory effects of imidazoline compounds on insulin secretion are not due to interaction with NAIBS similar to those present in rat liver.     

Elevation of cytosolic calcium by imidazolines in mouse islets of Langerhans: implications for stimulus-response coupling of insulin release.

1. Microfluorimetry techniques with fura-2 were used to characterize the effects of efaroxan (200 microM), phenotolamine (200-500 microM) and idazoxan (200-500 microM) on the intracellular free Ca2+ concentration ([Ca2+]i) in mouse isolated islets of Langerhans. 2. The imidazoline receptor agonists efaroxan and phentolamine consistently elevated cytosolic Ca2+ by mechanisms that were dependent upon Ca2+ influx across the plasma membrane; there was no rise in [Ca2+]i when Ca2+ was removed from outside of the islets and diazoxide (100-250 microM) attenuated the responses. 3. Modulation of cytosolic [Ca2+]i by efaroxan and phentolamine was augmented by glucose (5-10 mM) which both potentiated the magnitude of the response and reduced the onset time of imidazoline-induced rises in [Ca2+]i. 4. Efaroxan- and phentolamine-evoked increases in [Ca2+]i were unaffected by overnight pretreatment of islets with the imidazolines. Idazoxan failed to increase [Ca2+]i under any experimental condition tested. 5. The putative endogenous ligand of imidazoline receptors, agmatine (1 microM-1 mM), blocked KATP channels in isolated patches of beta-cell membrane, but effects upon [Ca2+]i could not be further investigated since agmatine disrupts fura-2 fluorescence. 6. In conclusion, the present study shows that imidazolines will evoke rises in [Ca2+]i in intact islets, and this provides an explanation to account for the previously described effects of imidazolines on KATP channels, the cell membrane potential and insulin secretion in pancreatic beta-cells.     

Antagonism of the stimulatory effects of efaroxan and glibenclamide in rat pancreatic islets by the imidazoline, RX801080.

1. The imidazoline alpha 2-adrenoceptor antagonist, efaroxan, stimulates insulin secretion from rat isolated islets and antagonizes the ability of diazoxide to inhibit glucose-induced insulin secretion. These effects result from closure of ATP-sensitive potassium channels although the mechanisms involved have not been elucidated. 2. In the present work, we have examined the effects of a close structural analogue of efaroxan, RX801080, in rat isolated islets of Langerhans. RX801080 was found to be ineffective as a stimulator of insulin secretion and did not prevent the inhibition of insulin secretion mediated by diazoxide. 3. RX801080 acted as an antagonist of the actions of several imidazolines (efaroxan, phentolamine and midaglizole) in rat islets. It dose-dependently inhibited the ability of efaroxan to antagonize the effects of diazoxide in islets and also completely inhibited the direct stimulation of insulin secretion mediated by efaroxan. 4. RX801080 also antagonized the effects of the non-imidazoline, ATP-sensitive potassium channel blocker, glibenclamide, in rat islets. It inhibited both the capacity of glibenclamide to stimulate insulin secretion and the ability of glibenclamide to overcome the inhibitory effects of diazoxide in rat islets. 5. Antagonism of glibenclamide responses by RX801080 was not due to inhibition of binding of the sulphonylurea to its receptor on the pancreatic beta-cell. 6. The results suggest that imidazoline compounds and sulphonylureas interact with distinct binding sites on islet cells, but that these sites can interact functionally to control islet cell ATP-sensitive potassium channel activity and insulin secretion.     

The imidazoline site involved in control of insulin secretion: characteristics that distinguish it from I1- and I2-sites.

1. The nature of the binding site mediating the insulin secretagogue activity of certain imidazoline compounds remains unclear and the pharmacology of the I1- and I2-imidazoline sites, described in many tissues, does not correlate with the observed responses to imidazolines in islets. In the present paper, we describe further results which support the concept that the islet imidazoline site may represent a novel subtype of imidazoline receptor. 2. Culture of rat isolated islets in the presence of imidazoline secretagogues (either efaroxan or phentolamine) resulted in loss of responsiveness on subsequent re-exposure to these agents. However, culture of islets with either idazoxan or UK14,304 (imidazoline ligands that do not stimulate insulin secretion) did not lead to any loss of response when the islets were subsequently exposed to efaroxan. By contrast, islets cultured with UK14,304 (a potent alpha 2-adrenoceptor agonist), displayed loss of sensitivity to noradrenaline, consistent with down-regulation of alpha 2-adrenoceptors. 3. In order to characterize the imidazoline site further, radioligand binding studies were performed in membranes from RINm5F insulinoma cells using [3H]-RX821002, an imidazoline insulin secretagogue that does not interact significantly with imidazoline sites in other tissues. [3H]-RX821002 labelled alpha 2-adrenoceptors with high affinity (2.01 +/- 0.7 nM) but also labelled a second, non-adrenoceptor site with much lower affinity. 4. Under conditions of alpha 2-adrenoceptor blockade (in the presence of adrenaline), efaroxan displaced [3H]-RX821002 binding to the low affinity site, in a dose-dependent manner.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effector systems involved in the insulin secretory responses to efaroxan and RX871024 in rat islets of Langerhans

One component of the mechanism by which imidazoline compounds promote insulin secretion involves closure of ATP-sensitive K⁺ channels in the β-cell plasma membrane. Recently, however, it has also been proposed that these compounds may exert important effects on more distal effector systems. In the present work, we have investigated the contribution played by protein kinases A and C to the insulin secretory responses of isolated rat islets of Langerhans treated with efaroxan and RX871024 (1-phenyl-2-(imidazolin-2-yl) benzimidazole). Removal of extracellular Ca²⁺ or blockade of voltage-sensitive Ca²⁺ channels prevented stimulation of insulin secretion by efaroxan, confirming a critical role for increased Ca²⁺ influx in the secretory response. By contrast, inhibition of protein kinases A or C failed to alter efaroxan-induced insulin secretion. RX871024 dose-dependently increased insulin secretion from cultured islets incubated with 20 mM glucose. This effect was unaffected by modulation of protein kinase C, but was significantly attenuated by a selective inhibitor of protein kinase A (Rp-cAMPs). Measurements of cAMP revealed that RX871024 increased the islet cAMP content by more than 3-fold; reaching values similar in magnitude to those elicited by 50 μM 3-isobutyl-1-methyl xanthine. The results reveal that neither protein kinase A nor protein kinase C is obligatory for stimulation of insulin secretion by imidazolines. However, they suggest that a rise in cAMP may contribute to the amplified secretory response observed when cultured islets are incubated with RX871024 in the presence of a stimulatory glucose concentration.     

Imidazoline NNC77-0074 stimulates insulin secretion and inhibits glucagon release by control of Ca(2+)-dependent exocytosis in pancreatic alpha- and beta-cells

We have investigated the effects of the novel imidazoline compound (+)-2-(2-(4,5-dihydro-1H-imidazol-2-yl)-thiopene-2-yl-ethyl)-pyridine (NNC77-0074) on stimulus-secretion coupling in isolated pancreatic alpha- and beta-cells. NNC77-0074 stimulated glucose-dependent insulin secretion in intact mouse pancreatic islets. No effect was observed at 相似文献   

Induced desensitization of the insulinotropic effects of antidiabetic drugs, BTS 67 582 and tolbutamide

Acute and chronic mechanisms of action of novel insulinotropic antidiabetic drug, BTS 67 582 (1, 1-dimethyl-2-(2-morpholinophenyl)guanidine fumarate), were examined in the stable cultured BRIN-BD11 cell line. BTS 67 582 (100 - 400 microM) stimulated a concentration-dependent increase (P<0.01) in insulin release at both non-stimulatory (1.1 mM) and stimulatory (8. 4 mM) glucose. Long-term exposure (3 - 18 h) to 100 microM BTS 67 582 in culture time-dependently decreased subsequent responsiveness to acute challenge with 200 microM BTS 67 582 or 200 microM tolbutamide at 12 - 18 h (P<0.001). Similarly 3 - 18 h culture with the sulphonylurea, tolbutamide (100 microM), also effectively suppressed subsequent insulinotropic responses to both BTS 67 582 and tolbutamide. Culture with 100 microM BTS 67 582 or 100 microM tolbutamide did not affect basal insulin secretion, cellular insulin content, or cell viability and exerted no influence on the secretory responsiveness to 200 microM of the imidazoline, efaroxan. While 18 h BTS 67 582 culture did not affect the insulin-releasing actions (P<0.001) of 16.7 mM glucose, 10 mM arginine, 30 mM KCl, 25 microM forskolin or 10 nM phorbol-12-myristate 13-acetate (PMA), significant inhibition (P<0.001) of the insulinotropic effects of 10 mM 2-ketoisocaproic acid (KIC) and 10 mM alanine were observed. These data suggest that BTS 67 582 shares a common signalling pathway to sulphonylurea but not imidazoline drugs. Desensitization of drug action may provide an important approach to dissect sites of action of novel and established insulinotropic antidiabetic agents.     

Glucose-induced insulin secretion is potentiated by a new imidazoline compound

Sulfonylureas stimulate insulin secretion independent of the blood glucose concentration. This can lead to hypoglycaemia in type 2 diabetic patients. Over the last years a number of imidazoline derivatives have been identified that stimulate insulin secretion in a more glucose-dependent way. In agreement with this, our aim was to generate imidazoline derivatives with a potential for the treatment of type 2 diabetic patients. We developed the compound 2-[4-(4-chlorophenyl)-3-(2-methoxyethoxy)-2-naphthalenyl]-4,5-dihydro-1-H-imidazole monohydrochloride (LY389382) with an imidazoline moiety and investigated its effects on glucose-dependent insulin secretion in a beta-cell line, isolated rat islets and in vivo. We could demonstrate that LY389382 induces insulin secretion in MIN6 cells and rat islets in a glucose-dependent manner (EC50=1.1 microM and 0.3 microM, respectively). Furthermore during hyperglycaemia LY389382 increased insulin secretion in a dose-dependent manner in healthy rats, whereas the compound had no effect at euglycemia in a tenfold higher dosage. After 7 days of treatment of Zucker Diabetic Fatty [ZDF/ (Gmi/fa)] rats with LY389382 with a dose of 15 mg/kg twice daily the blood glucose concentration was reduced from 22.7 +/- 1.7 mM to 16.6 +/- 2.3 mM. During the same time period the glucose concentration increased from 21.7+/-1.7 mM to 28.9 +/- 1.3 mM in the vehicle-treated group (P<0.05). The drop of the insulin level was also inhibited by LY389382 in ZDF rats. In contrast to other well-characterised imidazolines that have been shown to induce a glucose-dependent insulin secretion only within a limited range of concentrations, LY389382 stimulates insulin secretion over a concentration range of at least two log units in a glucose-dependent manner. These data suggest that this imidazoline compound has a potential for the treatment of type 2 diabetes.     

σ Receptor ligands and imidazoline secretagogues mediate their insulin secretory effects by activating distinct receptor systems in isolated islets

The effects of two potent σ receptor agonists (+)-3-PPP ((R)-3-(3-hydroxyphenyl)-N-(1-propyl)piperidine) and DTG (N,N′-di-(o-tolyl)guanidine) on the insulin secretory responses in rat islets of Langerhans were investigated. Both σ receptor ligands were able to potentiate the insulin secretory response of islets incubated at 6 mM glucose, in a dose-dependent manner and were also able to reverse the effects of diazoxide on insulin release. When islets were treated with efaroxan, a well-characterised imidazoline insulin secretagogue, and either (+)-3-PPP or DTG together, there was an unexpected and profound absence of stimulation of insulin release as compared to when islets were incubated with each compound alone. Experiments performed with islets where there was desensitization of DTG/σ receptor or efaroxan/imidazoline binding site mediated responses suggest that at least two distinct receptor systems appear to be involved. The complex interactions of these two classes of drug require further investigation.     

Harmane produces hypotension following microinjection into the RVLM: possible role of I(1)-imidazoline receptors

The beta-carboline, harmane (0.1 - 1.0 nmol) produces dose dependent hypotension when microinjected unilaterally into the rostral ventrolateral medulla (RVLM) of the anaesthetized rat. The potency of harmane on blood pressure is similar to that of the imidazoline, clonidine. The hypotensive effects of both clonidine and harmane are reversed by microinjection of the relatively I(1)-receptor selective antagonist efaroxan (20 nmol). These results are consistent with harmane acting at an I(1)-receptor in the RVLM. This is the first report of an endogenous ligand for I(1)-receptors that has central effects on blood pressure.     

The effect of the putative endogenous imidazoline receptor ligand,clonidine-displacing substance,on insulin secretion from rat and human islets of Langerhans

1. The effects of a rat brain extract containing clonidine-displacing substance (CDS), a putative endogenous imidazoline receptor ligand, on insulin release from rat and human isolated islets of Langerhans were investigated.
2. CDS was able to potentiate the insulin secretory response of rat islets incubated at 6 mM glucose, in a dose-dependent manner. The magnitude of this effect was similar to that in response to the well-characterized imidazoline secretagogue, efaroxan.
3. CDS, like other imidazoline secretagogues, was also able to reverse the inhibitory action of diazoxide on glucose-induced insulin release, in both rat and human islets.
4. These effects of CDS on secretion were reversed by the imidazoline secretagogue antagonists, RX801080 and the newly defined KU14R, providing the first evidence that imidazoline-mediated actions of CDS can be blocked by specific imidazoline antagonists.
5. The effects of CDS on insulin secretion were unaffected when the method of preparation involved centri-filtration through a 3,000 Da cut-off membrane or when the extract was treated with protease. These results confirm that the active principle is of low molecular weight and is not a peptide.
6. Overall, the data suggest that CDS behaves as a potent endogenous insulin secretagogue acting at the islet imidazoline receptor.

     

Heterogeneous characteristics of imidazoline-induced insulin secretion

Imidazolines are regarded as a pharmacological group of insulin secretagogues with one uniform mechanism of action, namely closure of ATP-dependent K⁺ channels (K_ATP channels) and, in consequence, depolarization of the plasma membrane, Ca²⁺ influx and stimulation of secretion. This assumption was investigated by measuring insulin secretion from perifused pancreatic islets in response to three imidazoline compounds and comparing the characteristics of secretion with changes in membrane potential and cytosolic Ca²⁺ concentration [Ca²⁺]_i of single β-cells. Phentolamine (32 μM) stimulated insulin secretion from perifused mouse islets in the presence of stimulatory (10 mM and 30 mM) and substimulatory (5 mM) glucose concentrations and even in the absence of glucose. Idazoxan in concentrations up to 500 μM was virtually ineffective in the presence of 5 mM glucose. At 10 mM glucose, there was a moderate but significant increase of secretion by idazoxan, 20 μM being nearly as effective as 100 μM. The effect of phentolamine was of slow onset and irreversible in the time frame of the experiments, while the effect of idazoxan was of fast onset and reversible. Alinidine also stimulated secretion in the presence of 10 mM glucose with fast and reversible kinetics, but in contrast to idazoxan, 100 μM was clearly more effective than 20 μM. These heterogeneous characteristics of secretion were reflected by changes of [Ca²⁺]_i: the increase of [Ca²⁺]_i by phentolamine was slow and only partially reversible, whereas idazoxan led to a smaller, but faster and reversible response. The increase of [Ca²⁺]_i by phentolamine and idazoxan was abolished by the Ca²⁺ channel blocker D 600. Surprisingly, all three compounds depolarized the β-cell plasma membrane from a resting potential of –71 mV to about –36 mV. Again, the effect of phentolamine was slow and that of idazoxan and alinidine fast. Thus, the characteristics of phentolamine-induced secretion appear to be attributable to the consequences of K_ATP channel closure. It is unclear, however, why all three test compounds achieved the same degree of depolarization in spite of their known different efficiency to close K_ATP channels. Apparently, there are additional mechanisms involved in the action of idazoxan and alinidine, which may contribute to the obvious differences in the characteristics of secretion. Received: 2 October 1998 / Accepted: 21 December 1998     

Specific desensitization of sulfonylurea- but not imidazoline-induced insulin release after prolonged tolbutamide exposure

Functional effects of prolonged exposure to the sulfonylurea, tolbutamide, were examined in the clonal electrofusion-derived BRIN-BD11 cell line. In acute 20-min incubations, 50-400 microM tolbutamide stimulated a dose-dependent increase (P < 0.01) in insulin release at both non-stimulatory (1.1 mM) and stimulatory (8.4 mM) glucose. Culture with 100 microM tolbutamide (18 hr) caused a marked (67%) decrease in subsequent insulin-secretory responsiveness to acute challenge with 200 microM tolbutamide, though notably, tolbutamide culture exerted no influence on 200 microM efaroxan-induced insulin secretion. Duration of exposure (3-18 hr) to 100 microM tolbutamide in culture also time-dependently influenced subsequent responsiveness to acute tolbutamide challenge, with progressive 47-58% decreases from 6-18 hr (P < 0.001). Similarly, 6- to 18-hr culture with 100 microM efaroxan specifically desensitized efaroxan-induced insulin release. Tolbutamide- and efaroxan-induced desensitization exhibited a time-dependent reversibility, with a sustained return to full insulin-secretory responsiveness by 12 hr. Notably, 18-hr culture with tolbutamide or efaroxan did not significantly affect insulinotropic responses to 16.7 mM glucose, 10 mM 2-ketoisocaproic acid, 10 mM alanine, 10 mM arginine, or 30 mM KCl. Diverse inhibitory actions of tolbutamide or efaroxan culture on late events in stimulus-secretion coupling reveal that drug desensitization is both a specific and important phenomenon. As such, the model system described could prove an important tool in determining the complex modes of action of established and novel clinically useful insulinotropic compounds.     

Effects of the imidazoline ligands efaroxan and KU14R on blood glucose homeostasis in the mouse

The putative imidazoline I(3) receptor antagonist 2-(2-ethyl-2,3-dihydrobenzo[b]furan-2-yl)-1H-imidazole (KU14R) has been shown to block the effects of the atypical I(3) agonist efaroxan at the level of the ATP-sensitive K(+) (K(ATP)) channel in isolated pancreatic islet beta cells, but its effects in vivo are not known. We have therefore investigated the effects of KU14R on blood glucose and insulin level in vivo. When KU14R was administered before or after a hypoglycaemic dose of efaroxan, the fall in blood glucose was at least additive. When the antihyperglycaemic imidazoline ligand S22068 was administered after a dose of KU14R, it did not alter the hypoglycaemic response. In the mouse isolated vas deferens preparation, neither rauwolscine (at concentrations which competitively antagonised the inhibitory response to 5-bromo-6-(2-imidazolin-2-ylamino)-quinoxaline (UK14304)) nor KU14R affected inhibition produced by S22068. At 10(-4) M, KU14R had weak alpha(2)-adrenoceptor antagonist activity. We conclude that KU14R does not act as an antagonist of either efaroxan or S22068 at an imidazoline site in vivo.     

Desensitization of insulin secretory response to imidazolines, tolbutamide, and quinine. I. Secretory and morphological studies.

The desensitization of pancreatic B-cells against stimulation by insulin secretagogues that inhibit ATP-dependent K(+) channels (K(ATP) channels) was investigated by measuring insulin secretion of perifused pancreatic islets. Additionally, the islet insulin content and the number of secretory granules per B-cell were determined. Prior to the measurement of secretion, islets were cultured for 18 h in the presence or absence of the test agents in a cell-culture medium containing 5 mM glucose. The effects of three imidazolines, phentolamine, alinidine, and idazoxan (100 microM each) were compared with those of the well-characterized sulfonylurea, tolbutamide (500 microM), and those of the ion channel-blocking alkaloid, quinine (100 microM). Insulin secretion was strongly reduced upon re-exposure to phentolamine, alinidine, tolbutamide, and quinine, whereas idazoxan, which stimulated secretion only weakly, had no significant effect. The imidazoline secretagogues phentolamine and alinidine induced a cross-desensitization against the stimulatory effect of tolbutamide and quinine. A long-term depolarization with 40 mM KCl was also able to induce a significant reduction of the secretory response to all of the above secretagogues. The insulin content of cultured islets was moderately, but significantly reduced by alinidine, whereas the reduction by phentolamine, tolbutamide, and quinine was not significant. In contrast to these observations, the ultrastructural examination revealed that tolbutamide-treated B-cells had a high degree of degranulation, whereas the other test agents and 40 mM KCl produced only a partial degranulation, except for phentolamine, which produced no significant degranulation at all. These results suggest that the desensitization of insulin secretion is a common property of all agents that stimulate insulin secretion by depolarisation of the plasma membrane. Depending on the specific secretagogue, additional mechanisms, proximal and distal to Ca(2+) influx, appear to contribute to the desensitization (see Rustenbeck et al., pages 1695-1703, this issue).     

Investigation of morin‐induced insulin secretion in cultured pancreatic cells

Morin is a flavonoid contained in guava that is known to reduce hyperglycemia in diabetes. Insulin secretion has been demonstrated to increase following the administration of morin. The present study is designed to investigate the potential mechanism(s) of morin‐induced insulin secretion in the MIN6 cell line. First, we identified that morin induced a dose‐dependent increase in insulin secretion and intracellular calcium content in MIN6 cells. Morin potentiated glucose‐stimulated insulin secretion (GSIS). Additionally, we used siRNA for the ablation of imidazoline receptor protein (NISCH) expression in MIN6 cells. Interestingly, the effects of increased insulin secretion by morin and canavanine were markedly reduced in Si‐NISCH cells. Moreover, we used KU14R to block imidazoline I₃ receptor (I‐3R) that is known to enhance insulin release from the pancreatic β‐cells. Without influence on the basal insulin secretion, KU14R dose‐dependently inhibited the increased insulin secretion induced by morin or efaroxan in MIN6 cells. Additionally, effects of increased insulin secretion by morin or efaroxan were reduced by diazoxide at the dose sufficient to open K_ATP channels and attenuated by nifedipine at the dose used to inhibit L‐type calcium channels. Otherwise, phospholipase C (PLC) is introduced to couple with imidazoline receptor (I‐R). The PLC inhibitor dose‐dependently inhibited the effects of morin in MIN6 cells. Similar blockade was also observed in protein kinase C (PKC) inhibitor‐treated cells. Taken together, we found that morin increases insulin secretion via the activation of I‐R in pancreatic cells. Therefore, morin would be useful to develop in the research and treatment of diabetic disorders.     

The insulinotropic mechanism of the novel hypoglycaemic agent JTT-608: direct enhancement of Ca(2+) efficacy and increase of Ca(2+) influx by phosphodiesterase inhibition

We examined the effects of the novel hypoglycaemic agent JTT-608 [trans-4-(4-methylcyclohexyl)-4-oxobutyric acid] on insulin secretion using rat pancreatic islets, and analysed the mechanism of its effect. JTT-608 augmented 8.3 mM glucose-induced insulin secretion dose-dependently, and there was a stimulatory effect of 100 microM JTT-608 at both moderate and high concentrations (8.3, 11. 1 and 16.7 mM) of glucose, but not at low concentrations (3.3 and 5. 5 mM). In perifusion experiments, both phases of insulin release were enhanced, and the effect was eliminated 10 min after withdrawal of the agent. In the presence of 200 microM diazoxide and a depolarizing concentration (30 mM) of K(+), there was an augmentation of insulin secretion by 100 microM JTT-608, not only under high levels of glucose but also under low levels, and the effects were abolished by 10 microM nitrendipine. JTT-608 augmented insulin secretion from electrically permeabilized islets in the presence of stimulatory concentrations (0.3 and 1.0 microM) of Ca(2+), and the intracellular Ca(2+) concentration ([Ca(2+)](i)) response under 16.7 mM glucose, 200 microM diazoxide, and 30 mM K(+) was also increased. The cyclic AMP content in the islets was increased by 100 microM JTT-608, and an additive effect to 1 microM forskolin was observed, but not to 50 microM 3-isobutyl-1-methylxanthine (IBMX). JTT-608 inhibited phosphodiesterase (PDE) activity dose-dependently. We conclude that JTT-608 augments insulin secretion by enhancing Ca(2+) efficacy and by increasing Ca(2+) influx. This appears to be a result of the increased intracellular cyclic AMP concentration due to PDE inhibition.