P2 receptor agonists stimulate insulin release from human pancreatic islets.

Although P2 receptors for adenosine 5'-triphosphate (ATP) and/or adenosine 5'-diphosphate (ADP) have been characterized in mammalian pancreatic beta cells, no evidence for an insulin-secreting effect of P2 receptor agonists has been reported as yet in humans. The present study aimed at investigating whether P2 receptor agonists could stimulate insulin release in human pancreatic islets obtained from brain-dead organ donors. Experiments were performed using different glucose concentrations and insulin was measured by radioimmunoassay. When the glucose concentration (8.3 mmol/L) was slightly stimulating for insulin release, alpha,beta-methylene ATP (200 micromol/L) and ADPbetaS (50 micromol/L) similarly amplified insulin secretion: both compounds induced a threefold increase in insulin response. In the presence of a nonstimulating glucose concentration (3.0 mmol/L), only alpha,beta-methylene ATP could induce a significant 1.4-fold increase in insulin release, ADPbetaS being completely ineffective. These results give evidence that P2 receptor agonists are effective in stimulating insulin release in humans, the effect of the P2Y agonist being essentially glucose dependent.

[Involvement of P2X and P2U receptors in the constrictor effect of ATP on the pancreatic vascular bed]. / Implication de récepteurs P2X et P2U dans l'effet constricteur de l'ATP sur le lit vasculaire pancréatique.

The effects of ATP on the pancreatic vascular bed were studied on the isolated rat pancreas perfused at a constant pressure so as any change in the vascular tone induces a modification in the flow rate. This study was performed in two different experimental conditions: 1) In the presence of indomethacin, inhibiting the cyclo-oxygenase and prostacyclin (PGI2) synthesis, ATP (which acts on vasodilatator P2Y receptors and vasoconstrictor P2X and P2U receptors) was used at a concentration (165 microM) which did not modify per se the vascular flow rate. With indomethacin, ATP induced a slight but significant and long lasting decrease in the flow rate. This effect is different from that induced by the stimulation of P2X receptors; it is comparable to that induced by the activation of P2U receptors. 2) In the presence of 2,2'pyridylisatogen tosilate (PIT) used at two different concentrations, the first (5 microM) inhibiting the P2Y effects on insulin secreting B cells and pancreatic vessels, the second (25 microM) inhibiting the P2X effects on pancreatic vessels. The effects of ATP are different according to the concentration of PIT. In both cases, ATP induced only a vasoconstriction. However, the kinetics of the flow rate is totally different: in the presence of 5 microM PIT, an immediate and drastic vasoconstriction was observed, followed by a long lasting vasoconstriction of lesser magnitude, which can be ascribed to P2X and P2U receptor activation, respectively. This hypothesis was confirmed by the results in the presence of PIT at 25 microM. At this concentration this compound completely suppressed the drastic and transient vasoconstriction, so that only a progressive and long lasting vasoconstriction of the P2U type could be observed. From these results, it can be concluded that: 1) PGI2 plays a part in the vasodilatator effects of ATP. 2) At the concentrations used, PIT does not block the vasoconstriction induced by P2U receptors. 3) The effects of ATP on pancreatic vessels is dependent on the balance between its vasodilator effect due to the activation of P2Y receptors and its vasoconstrictor effect which involves two types of receptors: P2X and P2U.

Evidence for two different types of P2 receptors stimulating insulin secretion from pancreatic B cell.

Adenine nucleotides have been shown to stimulate insulin secretion by acting on P2 receptors of the P2Y type. Since there have been some discrepancies in the insulin response of different analogues of ATP and ADP, we investigated whether two different types of P2 receptors exist on pancreatic B cells. The effects of alpha,beta-methylene ATP, which is more specific for the P2X subtype, were studied in vitro in pancreatic islets and isolated perfused pancreas from rats, in comparison with the potent P2Y receptor agonist ADPbetaS. In isolated islets, incubated with a slightly stimulating glucose concentration (8.3 mM), alpha,beta-me ATP (200 microM) and ADPbetaS (50 microM) similarly stimulated insulin secretion; by contrast, under a non stimulating glucose concentration (3 mM), alpha,beta-me ATP was still effective whereas ADPbetaS was not. In the same way, in islets perifused with 3 mM glucose, alpha,beta-me ATP but not ADPbetaS induced a partial but significant reduction in the peak 86Rb efflux induced by the ATP-dependent potassium channel opener diazoxide. In the isolated pancreas, perfused with a non stimulating glucose concentration (4.2 mM), ADPbetaS and alpha,beta-me ATP (5-50 microM), administered for 10 min, induced an immediate, transient and concentration-dependent increase in the insulin secretion; their relative potency was not significantly different. In contrast, with a slightly stimulating glucose concentration (8.3 mM), ADPbetaS was previously shown to be 100 fold more potent than alpha,beta-me ATP. Furthermore, at 4.2 mM glucose a second administration of alpha,beta-me ATP was ineffective. In the same way, ADPbetaS was also able to desensitize its own insulin response. At 3 mM glucose, alpha,beta-me ATP as well as ADPbetaS (50 microM) induced a transient stimulation of insulin secretion and down regulated the action of each other. These results give evidence that pancreatic B cells, in addition to P2Y receptors, which potentiate glucose-induced insulin secretion, are provided with P2X receptors, which transiently stimulate insulin release at low non-stimulating glucose concentration and slightly affect the potassium conductance of the membrane.

Involvement of K+ channel permeability changes in the L-NAME and indomethacin resistant part of adenosine-5'-O-(2-thiodiphosphate)-induced relaxation of pancreatic vascular bed.

1. We have previously demonstrated that adenosine-5'-O-(2-thiodiphosphate) (ADPbetaS), a potent P2Y-purinoceptor agonist, relaxed pancreatic vasculature not only through prostacyclin (PGI2) and nitric oxide (NO) release from the endothelium but also through other mechanism(s). In this study, we investigated the effects of an inhibitor of the Na+/K+ pump, of ATP-sensitive K+ (K(ATP)) channels and of small (SK(Ca)) or large (BK(Ca)) conductance Ca2+-activated K+ channels. Experiments were performed at basal tone and during the inhibition of NO synthase and cyclo-oxygenase. 2. In control conditions, ADPbetaS (15 microM) induced an initial transient vasoconstriction followed by a progressive and sustained vasodilatation. In the presence of N(omega)-nitro-L-arginine methyl ester (L-NAME, 200 microM) the transient vasoconstriction was reversed into a one minute vasodilator effect, which was then followed by a progressive and sustained vasodilatation similar to that observed with ADPbetaS alone. The addition of indomethacin (10 microM) did not significantly modify the profile of ADPbetaS-induced vasodilatation. 3. Ouabain (100 microM) decreased basal pancreatic flow rate and did not modify ADPbetaS-induced relaxation. This inhibitor of the Na+/K+ pump increased the pancreatic vasoconstriction induced by L-NAME or by the co-administration of L-NAME and indomethacin. Ouabain did not modify either the L-NAME or the L-NAME/indomethacin resistant part of the ADPbetaS vasodilatation. 4. The K(ATP) inhibitor tolbutamide (185 microM) did not significantly modify basal pancreatic flow rate and ADPbetaS-induced relaxation. This inhibitor which did not change L-NAME-induced vasoconstriction, significantly diminished the L-NAME resistant part of ADPbetaS-induced vasodilatation. Tolbutamide intensified the vasoconstriction induced by the co-administration of L-NAME and indomethacin. In contrast, the L-NAME/indomethacin resistant part of ADPbetaS vasodilatation was not changed by the closure of K(ATP). 5. The SK(Ca) inhibitor apamin (0.1 microM) did not significantly change pancreatic vascular resistance whatever the experimental conditions (in the absence or in presence of L-NAME or L-NAME/indomethacin). In the presence of L-NAME, the closure of SK(Ca) channels changed the one minute vasodilator effect of ADPbetaS into a potent vasoconstriction and thereafter modified only the beginning of the second part of the L-NAME-resistant part of the ADPbetaS-induced vasodilatation. In contrast, the L-NAME/indomethacin resistant part of ADPbetaS-induced relaxation remained unchanged in the presence of apamin. 6. Charybdotoxin (0.2 microM), an inhibitor of BK(Ca), increased pancreatic vascular resistance in the presence of L-NAME/indomethacin. In the presence of L-NAME, the closure of BK(Ca) channels reversed the one minute vasodilator effect of ADPbetaS into a potent vasoconstriction and drastically diminished the sustained vasodilatation. In contrast the L-NAME/indomethacin resistant part of ADPbetaS-induced relaxation was not modified by the presence of charybdotoxin. Under L-NAME/indomethacin/charybdotoxin/apamin infusions, ADPbetaS evoked a drastic and transient vasoconstriction reaching a maximum at the second minute, which was followed by a sustained increase in the flow rate throughout the ADPbetaS infusion. The maximal vasodilator effect of ADPbetaS observed was not modified by the addition of apamin. 7. The results suggest that the L-NAME-resistant relaxation induced by ADPbetaS in the pancreatic vascular bed involves activation of BK(Ca), K(ATP) and to a lesser extent of SK(Ca) channels, but the L-NAME/indomethacin resistant part of ADPbetaS-induced relaxation is insensitive to the closure of K(ATP), SK(Ca) and BK(Ca) channels.

Effects of homocysteine on acetylcholine- and adenosine-induced vasodilatation of pancreatic vascular bed in rats.

1. Epidemiological and experimental data have shown that homocysteine may provoke vascular lesions and that moderate homocysteinaemia may constitute an independent risk factor for vascular disease. It is now documented that homocysteine damages human endothelial cells in culture, possibly by producing hydrogen peroxide in an oxygen-dependent reaction. 2. In this study, we have examined the direct effect of this sulphur amino acid on pancreatic vascular resistance. Experiments were performed on the vascular bed of the rat isolated pancreas perfused at constant pressure; thus, any change in pancreatic vascular resistance resulted in a change in the flow rate. D,L-Homocysteine perfused for one hour at three different concentrations (200 microM, 2 mM, 20 mM) did not induce any significant change in the flow rate per se. Homocysteine infusion for 30 min at a concentration of 200 microM or 2 mM abolished the endothelium-dependent vasodilatation induced by acetylcholine (0.05 microM), but did not modify adenosine (1.5 microM)-induced vasodilatation. 3. The effect of D,L-homocysteine (200 microM or 2 mM) cannot be ascribed to a direct antimuscarinic effect since 30 min pretreatment of rat ileum with these concentrations did not significantly change the contractile effect of increasing concentrations of acetylcholine (0.015-15 microM). 4. Preincubation of human umbilical vein endothelial cells with D,L-homocysteine (0.2-5.0 mM) had no significant effect on overall cell number or viability during 18 h of incubation; the endothelial cells exposed to concentrations up to 5 mM exhibited a spindle-shaped, whirled pattern. This pattern was reversed 48 h after the removal of homocysteine. A cytotoxic effect was seen after 18 h incubation in 10 mM D,L-homocysteine. 5. In conclusion, an acute infusion of homocysteine altered acetylcholine endothelium-induced vasodilation, whereas the adenosine vasodilatator effect was insensitive to the deleterious action of homocysteine in vitro.

Antazoline increases insulin secretion and improves glucose tolerance in rats and dogs.

In vivo effects of an imidazoline devoid of alpha2-adrenoceptor antagonistic properties, antazoline, on insulin secretion and glycemia were investigated both in fasted rats and dogs. In both species, antazoline (1.5 mg/kg i.v.) transiently increased insulinemia without affecting basal plasma glucose levels. In contrast, during an i.v. glucose tolerance test, antazoline markedly potentiated insulin release and thus increased the glucose disappearance rate. In rats, during an oral glucose tolerance test, the intragastric administration of antazoline (1.5 mg/kg) clearly enhanced insulin secretion and reduced hyperglycemia. In dogs provided with a venous pancreatico-duodenal bypass, antazoline (0.5 mg/kg i.v.) induced an immediate and transient increase in insulin and somatostatin but not in glucagon pancreatico-duodenal outputs. In conclusion, intravenously and orally administered, the imidazoline antazoline is able to stimulate insulin secretion in vivo and improve glucose tolerance. The imidazoline compounds could therefore have a potential therapeutic relevance as new antihyperglycemic insulinotropic agents.

Comparative effects of adenosine-5'-triphosphate and related analogues on insulin secretion from the rat pancreas.

Adenosine tri- and diphosphate (ATP and ADP) and their structural analogues stimulate insulin secretion from the isolated perfused rat pancreas, an effect mediated by P2Y-purinoceptor activation. Concerning the base moiety of the nucleotide, it was previously shown that purine but not pyrimidine nucleoside triphosphates were active and that substitution on purine C2 with the 2-methylthio group greatly enhanced the potency. In this study, we further analyze the consequences of ribose and polyphosphate chain modifications. Modifications in 2' and 3' position on the ribose led to a decrease in insulin response when bulky substitutions were made: indeed, 2'-deoxy ATP was similar in activity to ATP, whereas arylazido-aminopropionyl ATP (ANAPP3) was weakly effective and trinitrophenyl ATP (TNP-ATP) was inactive. Substitution on the gamma phosphorus of the triphosphate chain led to a decrease (gamma-anilide ATP) or no change (gamma-azido ATP) in potency; the replacement of the bridging oxygen between beta and gamma phosphorus by a peroxide group did not significantly change the activity, whereas substitution by a methylene group completely abolished stimulation of insulin secretion. As for the phosphorothioate analogues, adenosine-5'-O-(3-thiotriphosphate) (ATP gamma S) induced an insulin response similar to that produced by ATP, whereas adenosine-5'-O-(2-thiodiphosphate) (ADP beta S) was about 100-fold more potent than ATP, as previously shown. In conclusion, two structural features seem to have a strategic importance for increasing the insulin secretory activity of ATP analogues: substitution at the C2 position on the adenine ring of ATP and modifications of the polyphosphate chain at the level of the beta phosphorus.

Agmatine is not a good candidate as endogenous ligand for imidazoline sites of pancreatic B cells and vascular bed.

In order to determine whether agmatine could be a putative endogenous ligand for imidazoline receptors mediating insulin secretion and vasoconstriction, we compared its effects with those of the imidazoline, efaroxan. Agmatine exhibited a much lower potency and efficacy than efaroxan on insulin secretion from rat pancreas perfused with 8.3 mM glucose. On the other hand, in contrast to efaroxan (100 microM), agmatine (3 mM) did not increase arginine-induced insulin release. In addition, agmatine failed to reproduce the vasoconstrictor effect of efaroxan on pancreatic vessels. These results show that agmatine does not behave like efaroxan, an agonist for the imidazoline receptors mediating insulin secretion or vasoconstriction in the pancreas.

Adenosine inhibitory effect on enhanced growth of aortic smooth muscle cells from streptozotocin-induced diabetic rats.

1. There is evidence to suggest that adenosine may regulate arterial smooth muscle cell (SMC) growth and proliferation, which is a key event in atherogenesis. This regulation may be mediated via adenylate cyclase. As diabetes is a known risk factor for atherosclerosis, we investigated the growth of aortic SMC from diabetic rats in primary culture and their sensitivity to adenosine and to adenylate cyclase activity. 2. Diabetes was induced with streptozotocin (STZ, 66 mg kg-1, i.p.) Aortic SMC primary cultures were prepared from STZ-diabetic and age-matched rats 5 weeks after the STZ injection. 3. SMC from STZ-diabetic rats grew faster and reached greater densities at confluence than those from non-diabetic animals. 4. Adenosine inhibited growth in both control and diabetic SMC. However, cells from STZ-diabetic rats were apparently more sensitive to adenosine. 5. Direct activation of adenylate cyclase by forskolin induced a dose-dependent growth inhibition, similar in both groups of cells. 6. Cholera toxin, an activator of stimulatory GTP-binding protein (Gs), induced a similar growth inhibitory response in non-diabetic and diabetic SMC. Pertussis toxin (PTX), an inactivator of inhibitory GTP-binding protein (Gi), did not itself affect SMC growth. However, PTX increased dose-dependently the growth inhibition induced by adenosine in SMC from non-diabetic rats but not in SMC from diabetic rats. 7. These findings suggest a functional abnormality in Gi activity in SMC from diabetic rats, that would explain the increased sensitivity to the nucleoside. This impaired inhibitory pathway may reflect changes in the growth regulation of SMC in experimental diabetic states.

Study of the mechanisms involved in adenosine-5'-O-(2-thiodiphosphate) induced relaxation of rat thoracic aorta and pancreatic vascular bed.

1. The endothelium-dependent relaxation of blood vessels induced by P2Y-purinoceptor activation has often been shown to involve prostacyclin and/or nitric oxide (NO) release. In this work, we have investigated the mechanisms involved in the relaxant effect of the P2Y agonist, adenosine -5'-O-(2-thiodiphosphate) (ADP beta S) using two complementary preparations: rat pancreatic vascular bed and aortic ring. 2. On the pancreatic vascular bed, ADP beta S (1.5 and 15 microM) infused for 30 min induced a concentration-dependent vasodilatation; it was progressive during the first 10 min (first period) and sustained from 10 to 30 min (second period). Indomethacin (10 microM) delayed ADP beta S-induced vasodilatation (1.5 and 15 microM) by about 6 min. N omega-nitro-L-arginine methyl ester (L-NAME) (200 microM) suppressed the relaxation for about 5 min but thereafter ADP beta S at the two concentrations progressively induced an increase in the flow rate. Even the co-administration of L-NAME and indomethacin did not abolish the ADP beta S-induced vasorelaxation. 3. On 5-hydroxy tryptamine (5-HT) precontracted rings mounted in isometric conditions in organ baths, we observed that ADP beta S induced a concentration-dependent relaxation of rings with a functional endothelium; this effect was stable for 25 min. The ADP beta S relaxant effect was strongly inhibited by Reactive Blue 2 (30 microM) and was suppressed by pretreatment of rings with saponin (0.05 mg ml-1 for 30 min), which also abolished the acetylcholine-induced relaxation. 4. ADP beta S-induced relaxation of 5-HT precontracted rings is largely inhibited by indomethacin (100 or 10 microM) or L-NAME (100 microM). 5. We conclude that: the ADP beta S-induced relaxation is endothelium-dependent, mediated by P2Y-purinoceptors, and at least in part linked to NO and prostacyclin release, depending on the preparation used. Furthermore, on the pancreatic vascular bed, (an)other mechanism(s) than prostacyclin and NO releases may be involved in ADP beta S-induced vasodilatation.

Comparative effects of PACAP and VIP on pancreatic endocrine secretions and vascular resistance in rat.

1. The effects of pituitary adenylate cyclase-activating polypeptide (PACAP), vasoactive intestinal peptide (VIP) and secretin on pancreatic endocrine secretions and vascular resistance were investigated and compared in the isolated perfused pancreas of the rat. The PACAP/VIP receptor types involved have been characterized. 2. On insulin secretion, in the range 10(-11) to 10(-8) M, PACAP and VIP elicited a concentration-dependent biphasic response from pancreas perfused with 8.3 mM glucose; the peptides were equipotent. In contrast, secretin was ineffective in the range 10(-11) to 10(-9) M; at 10(-8) and 10(-7) M, it induced only low and transient insulin responses. On the other hand, the peptides did not modify the basal insulin release in the presence of a non stimulating glucose concentration (2.8 mM). 3. On glucagon secretion, PACAP and VIP (10(-11) to 10(-8) M) but also secretin (10(-9) to 10(-7) M) caused a concentration-dependent peak shaped response from pancreas perfused with 2.8 mM glucose; PACAP and VIP were equipotent and 20 times more potent then secretin. On the other hand, the peptides did not affect the glucagon release in the presence of 8.3 mM glucose. 4. On pancreatic vessels, in the range 10(-11) to 10(-9) M, the three peptides were equipotent in inducing a concentration-dependent sustained increase in pancreatic flow rate. On the other hand, at the high concentration of 10(-7) M PACAP but not VIP provoked a transient decrease of flow rate. 5. This study provides evidence for PACAP/VIP type II receptors mediating insulin and glucagon secretion as well as vasodilatation in rat pancreas. In addition, the different efficacies of secretin suggest that these effects are mediated by different PACAP/VIP type II receptor subtypes.

Glutamate stimulates insulin secretion and improves glucose tolerance in rats.

We previously showed in vitro that glutamate stimulates insulin release via an alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptor. Here we address a more physiological question concerning the in vivo effect of intravenously or orally administered glutamate on insulinemia and glycemia in fed and fasted rats. In anesthetized fed rats, the intravenous administration of glutamate at 9 and 30 mg/kg transiently increased insulinemia in a dose-dependent manner. The insulin-secretory effect of glutamate (9 mg/kg) was blocked by an antagonist of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors. In anesthetized fasted rats, glutamate at 9 mg/kg was ineffective, but during an intravenous glucose tolerance test (0.5 g/kg), glutamate markedly potentiated insulin release and increased the glucose disappearance rate. In conscious rats, the intragastric administration of glutamate at 200 mg/kg elicited a transient insulin response in fed animals and had no effect in fasted animals but, during an oral glucose tolerance test (1 g/kg), enhanced insulin secretion and reduced the hyperglycemia. Glutamate was effective at plasma concentrations of 200-300 microM. In conclusion, intravenously and orally administered glutamate stimulates insulin secretion in vivo via an excitatory amino acid receptor and improves glucose tolerance.

Evidence for two different imidazoline sites on pancreatic B cells and vascular bed in rat.

The relative potencies of imidazoline compounds to induce insulin secretion and vascular resistance were compared in the isolated perfused rat pancreas. On insulin secretion, only the two imidazolines, antazoline and efaroxan, induced a concentration-dependent response, antazoline being 10 times more potent than efaroxan. In contrast, idazoxan, a blocker of imidazoline I1 sites, at concentrations up to 30 microM, antagonized the insulin response to 10 microM efaroxan (IC50 approximately equal to 14 +/- 2 microM) without affecting that to 3 microM tolbutamide. On pancreatic vessels, not only antazoline and efaroxan but also idazoxan induced a concentration-dependent vasoconstriction; the rank order of agonist potency was antazoline > efaroxan > idazoxan. In addition, cimetidine, an imidazole known to bind imidazoline I1 sites, ineffective per se, partially reversed the insulin stimulatory effect of efaroxan without affecting its vasoconstrictor effect. This study demonstrates that the insulin secretory and vasoconstrictor actions of imidazolines involve different imidazoline sites in rat pancreas. The results provide evidence for an I1 type mediating insulin secretion on B cells and an I2 type mediating vasoconstriction in vessels.

[Vasoconstrictor effect of uridine triphosphate on pancreatic vascular bed]. / Effet vasoconstricteur de l'uridine triphosphate sur le lit vasculaire pancréatique.

Purinoceptors have been classified according to their sensitivity to structural analogues of purines. In addition to the well established and widely distributed P2 purinoceptor subtypes (P2X and P2Y), the existence of "pyrimidine" or "nucleotide" receptors was proposed, which are sensitive to the pyrimidine nucleotide, uridine triphosphate (UTP). Recently, this class of receptor has been included in the P2 purinoceptor classification as a P2U subtype. We have previously shown that pancreatic vascular resistance was modulated by the activation of P2Y and P2X purinoceptors, inducing vasodilation and vasoconstriction respectively. In this study, we investigated the effect of pyrimidine nucleotides on pancreatic vessels. The experiments were performed on isolated rat pancreas perfused at a constant pressure, which was selected to obtain a stable flow rate of 2.5 ml/min before drug administration; thus, any change in pancreatic vascular resistance resulted in a change in the flow rate. UTP induced a decrease in the flow rate at all concentrations tested, but the kinetics differed according to the concentration. The lowest concentration used (16.5 microM) induced a delayed, progressive and long lasting vasoconstriction. Ten times and one hundred times higher concentrations (165 and 1,650 microM) induced an immediate, more pronounced and also long lasting vasoconstriction. In contrast, the other pyrimidine nucleotide cytosine triphosphate (16.5 and 165 microM) did not significantly modify the pancreatic flow rate. This study suggests the presence of a P2U purinoceptor on rat pancreatic vessels; this P2U receptor differs from the P2X receptor since the activation of this latter elicits only a transient vasoconstriction.

In vivo and in vitro effects of adenosine-5'-O-(2-thiodiphosphate) on pancreatic hormones in dogs.

Adenosine-5'-O-(2-thiodiphosphate) (ADP beta S), a P2y purinergic agonist, has been shown to be a potent insulin secretagogue on the isolated rat pancreas. In the present work the effects of ADP beta S on insulin somatostatin, and glucagon secretions were investigated in dogs. In vivo, in anesthetized fasted dogs, i.v. ADP beta S (0.1 mg kg-1) induced an immediate increase in insulin and somatostatin-like immunoreactivity (SLI) but not in glucagon pancreaticoduodenal outputs. In conscious fasted dogs, i.v. ADP beta S (0.1 mg kg-1) produced an immediate and transient augmentation in plasma insulin levels but not in plasma SLI and glucagon levels. In vitro, the effects of ADP beta S were investigated on the isolated uncinate process of dog pancreas, from normal and alloxan-diabetic animals. In normal uncinate process, in presence of 8.3 mM glucose, ADP beta S (1 microM) stimulated insulin and SLI releases but not glucagon release. On uncinate process from diabetic animals, ADP beta S (1 microM) retained its stimulating effects but the responses were impaired as compared with normal dogs: Insulin response was drastically diminished and SLI response strongly enhanced. In conclusion, ADP beta S is a potent insulin secretory agent in dog. This P2y purinoceptor agonist, which exerts a direct stimulatory effect on pancreatic SLI, is interestingly devoid of direct glucagonotropic properties.

Effects of imidazolines and derivatives on insulin secretion and vascular resistance in perfused rat pancreas.

The effects of imidazolines and derivatives were studied on insulin secretion and vascular resistance in the isolated perfused rat pancreas. On insulin secretion, two imidazoline alpha 2-adrenoceptor antagonists, efaroxan (1-100 microM) and RX821002 (10 microM), had a stimulating response; however, idazoxan, like the non-imidazoline alpha 2-adrenoceptor antagonist yohimbine, was ineffective at 10 microM. The oxazoline rilmenidine with alpha 2-adrenergic activity at 10 microM), an imidazoline devoid of alpha 2-adrenergic activity, also had an insulin-releasing effect. On pancreatic vessels, all imidazolines tested (efaroxan, RX821002, antazoline and idazoxan), in contrast to yohimbine, induced vasoconstriction. Rilmenidine did not have a vasoconstrictor effect after blockade of alpha 2-adrenoceptors. Furthermore, the efaroxan-induced insulin release or vasoconstriction was not affected by the blockade of alpha 2- and alpha 1-adrenoceptors. This study shows that imidazolines and derivatives are able to stimulate insulin release and induce vasoconstriction in the rat pancreas. These effects cannot be ascribed to an interaction with alpha-adrenoceptors but may involve different types of imidazoline sites.

Purinergic receptors on insulin-secreting cells.

The insulin secreting B cell is fitted with the two types of purinergic receptors: P2 (for ATP and/or ADP) and P1 (for adenosine). The activation of P2 purinoceptors by ATP or ADP evokes a biphasic stimulation of insulin secretion from isolated perfused rat pancreas; this stimulation is dose-dependent between 10(-6) and 10(-4) M. Non hydrolysable structural analogues are also effective, and the relative potency of various agonists (2-methylthio ATP >> ATP = ADP = alpha, beta-methylene ATP >> AMP) gave evidence for a P2y purinoceptor subtype. Proposed mechanisms include both an increased Ca2+ uptake and an increased intracellular Ca2+ mobilization via the hydrolysis of polyphosphoinositides. ATP (or ADP) potentiates physiological insulin-secreting agents (glucose and acetylcholine) and P2 purinoceptors could play a physiological role in the stimulation of insulin secretion. The activation of P1 purinoceptors (adenosine receptors) decreases insulin secretion. Using structural analogues of adenosine, the receptor was characterized as an A1 subtype; it is coupled to a pertussis toxin sensitive G protein and it inhibits adenylate cyclase. It is of physiological relevance that the B cell has the two types of purinoceptors with opposite effects. Recently, a metabolically stable structural analogue of ADP, adenosine-5'-0-(2-thiodiphosphate) or ADP beta S, has been described as a potent secretory agent, effective at nanomolar concentrations on isolated perfused rat pancreas. In vivo, this substance is able to increase insulin secretion and to improve glucose tolerance after IV administration in rats and oral administration in dogs. Furthermore in streptozotocin-induced diabetes. ADP beta S retains its insulin secreting effects. These results suggest that P2y purinoceptors could be a new target for antidiabetic drugs.

Prior glucose deprivation increases the first phase of glucose-induced insulin response: possible involvement of endogenous ATP and (or) ADP.

A possible implication of endogenously released ATP and (or) ADP in insulin response to glucose stimulation was investigated in the isolated rat pancreas. The first phase of insulin response to the same glucose concentration (8.3 mM) was much higher in pancreas previously perfused in the absence of glucose than in pancreas previously perfused with 4.2 mM glucose. A P2 purinoceptor antagonist, 2,2'-pyridylisatogen tosylate, strongly reduced the higher first phase resulting from glucose deprivation; similarly, it reduced exogenous ATP-potentiated insulin response to a glucose increase from 4.2 to 8.3 mM. In contrast, 2,2'-pyridylisatogen tosylate did not modify the first phase of insulin response to 8.3 or 12.5 mM glucose in pancreas previously perfused with 4.2 mM glucose. Our results suggest that endogenous ATP and (or) ADP released in pancreatic islets in the absence of glucose could activate P2 purinoceptors and increase the magnitude of the first phase of insulin response to a glucose stimulation.

Glutamate stimulates glucagon secretion via an excitatory amino acid receptor of the AMPA subtype in rat pancreas.

The effect of L-glutamate was studied on glucagon secretion from rat isolated pancreas perfused with 2.8 mM glucose. L-Glutamate (3.10(-5)-10(-4)M) induced an immediate, transient and concentration-dependent glucagon release. The three non-N-methyl-D-aspartate (NMDA) receptor agonists, kainate (3.10(-5)-3.10(-3)M), alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) (3.10(-5)-10(-4)M) and quisqualate (3.10(-6)-10(-5)M), all elicited a peak-shaped glucagon response. Compared to glutamate, AMPA and quisqualate exhibited a similar efficacy, whereas kainate caused a 4-fold higher maximal glucagon response. In contrast, NMDA (10(-3)M) was ineffective. The selective antagonist of non-NMDA receptors, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 5.10(-5)M), totally prevented the glucagon response to 10(-4) M glutamate (IC50 congruent to 0.8 +/- 0.3 10(-6)M) and 3.10(-4)M kainate. Furthermore, quisqualate at a maximal effective concentration (3.10(-4)M) inhibited the response to kainate (10(-3)M). This study showed that L-glutamate stimulates glucagon release in rat pancreas by activating a receptor of the AMPA subtype.

Stimulation of insulin secretion and improvement of glucose tolerance in rat and dog by the P2y-purinoceptor agonist, adenosine-5'-O-(2-thiodiphosphate).

1. In vivo effect of a P2y-purinoceptor agonist, adenosine-5'-O-(2-thiodiphosphate) (ADP beta S), on insulin secretion and glycaemia were studied both in rats and dogs. 2. In anaesthetized rats, i.v. administered ADP beta S (0.2 mg kg-1) produced an insulin response dependent on the nutritional state of the animals, since we observed only a transient increase in overnight-fasted rats and a sustained insulin secretion followed by a reduction in plasma glucose levels in fed rats. During an i.v. glucose tolerance test, ADP beta S enhanced insulin release and thus increased the glucose disappearance rate. 3. In anaesthetized fasted dogs, i.v. administered ADP beta S (0.1 mg kg-1) increased pancreaticoduodenal insulin output and slightly decreased blood glucose levels. 4. In conscious fasted dogs, orally administered ADP beta S (0.1 mg kg-1) transiently increased insulinemia and punctually reduced glycaemia. Furthermore, during an oral glucose tolerance test, orally administered ADP beta S at the same dose markedly enhanced insulin secretion and consequently reduced the hyperglycaemia. 5. In conclusion, the P2y-agonist, ADP beta S, is a potent insulin secretagogue in vivo, improves glucose tolerance and is effective after oral administration. Thus, the P2y-purinoceptors of the beta cell may be a target for new antidiabetic drugs.