Characterization of oxytocin receptors on isolated rat fat cells.

The binding of 3H-labelled neurohypophyseal nonapeptide hormone, oxytocin, to isolated rat fat cells has been measured under conditions where this compound elicits the known activation of glucose oxidation by these cells, called "insulin-like" action. Uptake by the cells of the [3H]peptide as a function of various concentrations of the hormone in the medium indicated the presence of two classes of binding sites with different apparent affinities and capacities. The sites of the first type exhibit a rather high affinity, but low capacity, for oxytocin (5 nM; 3 X 10(4) sited per cell) and appear to be saturable under a reversible process. Evaluation of dose-response relationships suggest that they may be directly related to the measured biological response (i.e. activation of the glucose to 14CO2 conversion). Competition experiments show that [3H]oxytocin binding to the cells remains constant within a large range of insulin concentrations. The apparent capacity of different hormone analogs to compete with oxytocin for binding to this class of receptors has been evaluated and compared with the measured insulin-like activity of these different compounds. The sites of the second category have significantly lower affinity, but higher capacity for oxytocin, and were found to be not saturable under the experimental conditions. [3H]Oxytocin uptake by ghosts prepared from the isolated fat cells showed striking similarities to the binding process described for whole cells, although the affinity and total capacity of the former were found to be slightly lower. The basal and adrenalin-stimulated adenylate cyclase of these fractions appeared to be unaffected by various concentrations of oxytocin. It is concluded that there may exist on the rat fat cell membranes a discrete number of oxytocin receptors possessing high specificity for oxytocin and exhibiting affinities and kinetic behaviour similar to those of other characterized oxytocin receptors. They are believed to be independent of the other hormonal receptors of the rat fact cells.     

Homologous pancreastatin inhibits insulin secretion without affecting glucagon and somatostatin release in the perfused rat pancreas.

The identification of pancreastatin in pancreatic extracts prompted the investigation of its effects on islet cell function. However, in most of the investigations to date, pig pancreastatin was tested in heterologous species. Since there is great interspecies variability in the amino acid sequence of pancreastatin, we have investigated the influence of rat pancreastatin on insulin, glucagon and somatostatin secretion in a homologous animal model, namely the perfused rat pancreas. During 5.5 mM glucose infusion, pancreastatin (40 nM) inhibited insulin secretion (ca. 40%, P less than 0.025) as well as the insulin responses to 10 mM arginine (ca. 50%, P less than 0.025) and to 1 nM vasoactive intestinal polypeptide (ca. 50%; P less than 0.05). Pancreastatin failed to significantly modify glucagon or somatostatin release under any of the above experimental conditions. In addition, a lower pancreastatin concentration (15.7 nM) markedly suppressed the insulin release evoked by 11 mM glucose (ca. 85%, P less than 0.05). Our present observations reinforce the concept that pancreastatin is an effective inhibitor of insulin secretion, influencing the B-cell function directly and not through an A-cell or D-cell paracrine effect.     

Inhibitory effect of rat amylin on the insulin responses to glucose and arginine in the perfused rat pancreas

Amylin, a 37-amino acid polypeptide, is the main component of amyloid deposits in the islets of Langerhans, and has been identified in the B-cell secretory granules. We have investigated the effect of rat amylin on the insulin and glucagon release by the isolated, perfused rat pancreas. Amylin infusion at 750 nM, markedly reduced unstimulated insulin release (ca. 50%, P less than 0.025), whereas it did not modify glucagon output. At the same concentration, amylin also blocked the insulin response to 9 mM glucose (ca. 80%, P less than 0.025) without affecting the suppressor effect of glucose on glucagon release. The inhibitory effect of amylin on glucose-induced insulin secretion was confirmed by lowering the amylin concentration (500 nM) and increasing the glucose stimulus (11 mM); again, no effect of amylin on glucagon release was observed. Finally, amylin, at 500 nM, reduced the insulin response to 3.5 mM arginine (ca. 40%, P less than 0.025) without modifying the secretion of glucagon elicited by this amino acid. It can be concluded that, in the rat pancreas, the inhibitory effect of homologous amylin on unstimulated insulin secretion, as well as on the insulin responses to metabolic substrates (glucose and arginine), favours the concept of this novel peptide as a potential diabetogenic agent.     

Effects of neuromedin B on insulin and glucagon release from the isolated perfused rat pancreas

The effect of neuromedin B (NMB) on insulin and glucagon release was studied in isolated perfused rat pancreas. Infusion of NMB (10 nM, 100 nM and 1 microM) did not affect the insulin release under the perusate conditions of 5.5 mM glucose plus 10 mM arginine and 11 mM glucose plus 10 mM arginine, although 10 nM NMB tended to slightly suppress it under the perfusate condition of 5.5 mM glucose alone. The degree of stimulation of insulin release provoked by the addition of 5.5 mM glucose to the perfusate was not affected by the presence of 10 nM NMB. The glucagon release was slightly stimulated by the infusion of 100 nM and 1 microM NMB but not by 10 nM NMB under the perfusate condition of 5.5 mM glucose plus 10 mM arginine. The effect of C-terminal decapeptide of gastrin releasing peptide (GRP-10) was also examined and similar results were obtained; 10 nM and 100 nM GRP-10 did not affect insulin release and 100 nM GRP-10 stimulated glucagon release under the perfusate condition of 5.5 mM glucose plus 10 mM arginine. The present results concerning glucagon release are consistent with the previous results obtained with isolated perfused canine and porcine pancreas. However, the results regarding insulin release are not. Species differences in insulin release are also evident with other neuropeptides such as substance P and the mechanism of such differences remains for be clarified.     

Insulin and glucagon release from the ventral and dorsal parts of the perfused pancreas of the rat. Effects of glucose, arginine, glucagon and carbamylcholine

The ventral and the dorsal parts of the rat pancreas were perfused separately via either the superior mesenteric artery (0.6 ml/min) or the coeliac artery (1.4 ml/min). Control perfusions were performed via both arteries (2 ml/min). Expressed relative to the weight of tissue, the insulin content was comparable in the ventral and dorsal parts whereas the glucagon content was 2.5 times lower in the ventral than dorsal part. In comparison to the dorsal or total pancreas, the insulin secretory activity of the ventral pancreas was markedly decreased in response to either an elevation of the glucose concentration or the administration of carbamylcholine or arginine. The difference between the ventral and dorsal response was less marked at low glucose concentrations (3.3 or 7.0 mmol/l) and, possibly, in response to glucagon. In the case of glucagon release, a decreased response of the ventral pancreas was only observed when glucagon output was fully stimulated by the administration of arginine at a low glucose concentration. These results indicate that the B cell in the ventral pancreas responds poorly to several stimuli. There was little evidence to support the involvement of endogenous glucagon in the diminished sensitivity of the ventral B cells.     

Stimulation by prostaglandin E2 of glucagon and insulin release from isolated rat pancreas.

To ascertain whether prostaglandins (PG) may play a role in the secretion of glucagon and in an attempt to elucidate the conflicting observations on the effects of PG on insulin release, the isolated intact rat pancreas was perfused with solutions containing 1.1 x 10(-9) to 1.8 x 10(-5)m PGE2. In the presence of 5.6 mM glucose significant increments in portal venous effluent levels of glucagon and insulin were observed in response to minimal concentrations of 2.8 X 10(-8) and 1.4 X 10(-7) PGE2, respectively; a dose-response relationship was evident for both hormones at higher concentrations of PGE2. When administered over 60 seconds, 1.4 X 10(-6)M PGE2 resulted in a significant increase in glucagon levels within 24 seconds and in insulin within 48 seconds. Ten-minute perfusions of 1.4 X 10(-6)M PGE2 elicited biphasic release of both islet hormones; Phase I glucagon release preceded that of insulin. Both phases of the biphasic glucagon and insulin release which occurred in response to 15-minute perfusions of 10 mM arginine were augmented by PGE2. These observations indicate that PGE2 can evoke glucagon and insulin release at concentrations close to those observed by others in the extracts of rat pancreas. We conclude that PG may be involved in the regulation of secretion of glucagon and insulin and may mediate and/or modify the pancreatic islet hormone response to other secretagogues.     

Effect of glucagon antiserum on somatostatin,glucagon and insulin release from the isolated perfused rat pancreas

In order to elucidate the effect of glucagon antiserum on the endocrine pancreas, the release of somatostatin, glucagon, and insulin from the isolated perfused rat pancreas was studied following the infusion of arginine both with and without pretreatment by glucagon antiserum. Various concentrations of arginine in the presence of 5.5 mM glucose stimulated both somatostatin and glucagon secretion. However, the responses of somatostatin and glucagon were different at different doses of arginine. The infusion of glucagon antiserum strongly stimulated basal secretion in the perfusate total glucagon (free + antibody bound glucagon) and also enhanced its response to arginine, but free glucagon was undetectable in the perfusate during the infusion. On the other hand, the glucagon antiserum had no significant effect on either insulin or somatostatin secretion. Moreover, electron microscopic study revealed degrannulation and vacuolization in the cytoplasm of the A cells after exposure to glucagon antiserum, suggesting a hypersecretion of glucagon, but no significant change was found in the B cells or the D cells. We conclude that in a single pass perfusion system glucagon antiserum does not affect somatostatin or insulin secretion, although it enhances glucagon secretion.     

Localization of the oxytocin receptor in the plasma membrane of rat myometrium.

The distribution of [3H]oxytocin binding sites among various subcellular fractions of rat myometrium paralleled the distribution of 5'-nucleotidase, a plasma membrane marker enzyme, but not of NADPH-cytochrome c reductase or succinate-cytochrome c reductase, which are endoplasmic reticulum and mitochondrial marker enzymes respectively. [3H]Oxytocin binding to the most enriched plasma membrane fraction showed the degree of selectivity with respect to hormone analogues that is expected for the oxytocin receptor. The binding of oxytocin to this fraction showed an apparent Kd of 1.98 X 10(-9) M and a capacity of 1.28 pmol mg-1. It is concluded that the oxytocin receptor is located on the plasma membrane of the smooth muscle cells of the rat uterus.     

Combined administration of sodium chloro-2-propionate and insulin on the secretion of glucagon by the pancreas in the diabetic rat

This work was designed to study the effects of sodium 2-chloropropionate (2CP) alone or combined with insulin, in vitro, on glucagon secretion from pancreas isolated from rats, made diabetic by streptozotocin (66 mg/kg i.p.). The pancreata were perfused with a physiological solution containing 2.8 mM glucose (0.5 g/l) and glucagon secretion was stimulated by an arginine infusion (5 mM) for 30 min. When 2CP (1 mM) and/or insulin (4 IU/l) were applied, they were infused from the start of the organ perfusion. In the presence of glucose alone, a marked decrease in glucagon output was observed in diabetic rat pancreas. The arginine perfusion induced a biphasic glucagon secretion both in normal and diabetic rat pancreas; this response was however clearly reduced in diabetic rat pancreas. In diabetic rat pancreas, the infusion of either 2CP or insulin had no effect on glucagon output in presence of glucose alone, nor did it modify the response to arginine. In contrast, the combined infusion of insulin and 2CP induced different effects depending on the conditions: whereas in presence of glucose alone it restored a glucagon output close to that recorded in normal rat pancreas, it did not modify the response to arginine.     

Effect of exercise training on insulin and glucagon release from perfused rat pancreas

The effect of physical training on insulin and glucagon release in perfused rat pancreas was examined in the spontaneously exercised group running in a wheel cage an average of 1.4 km/day for 3 weeks and in the sedentary control group kept in the cage whose rotatory wheel was fixed on purpose. Pancreatic immunoreactive insulin (IRI) responses to glucose and arginine were reduced by 28% and 47.8% respectively in trained rats compared with untrained rats, while IRI content of the pancreas was similar in these two groups. The demonstrated decrease in insulin secretion of the beta-cell of the trained rats, in response to the glucose and arginine stimulations, may be functional in nature. On the other hand, neither pancreatic glucagon immunoreactivity (GI) response to glucose and arginine nor GI content of the pancreas was modified by exercise training. These results demonstrate that exercise training reduces IRI responses to glucose as well as to arginine stimulations, but does not modify any secretory response of pancreatic GI.     

Glucose regulation of arginine-induced pancreatic somatostatin release from the isolated perfused rat pancreas

The effects of glucose alone, combinations of glucose with arginine or tolbutamide and either arginine or tolbutamide alone, on somatostatin, insulin, and glucagon secretion were investigated using the isolated perfused rat pancreas. When glucose alone was raised in graded increments at 15-min intervals from an initial concentration of 0 mM to a maximum of 16.7 mM, somatostatin as well as insulin in the perfusate increased with the glucose, while glucagon decreased. The similarity of the glucose stimulated somatostatin and insulin release was especially evident when the perfusate glucose was increased from an initial dose of 4.4 mM rather than 0 mM to 8.8 mM or 16.7 mM. In addition, glucose at concentrations varying from 4.4 mM to 11 mM dose-dependently enhanced arginine-induced somatostatin and insulin release and suppressed glucagon release dose-dependently as before. Arginine in the absence of glucose was not capable of stimulating somatostatin secretion whereas tolbutamide, in contrast, was capable of stimulating somatostatin secretion even in the absence of glucose.     

The role of leucine-enkephalin on insulin and glucagon secretion from pancreatic tissue fragments of normal and diabetic rats

Leucine-enkephalin (Leu-Enk) has been shown to be present in endocrine cells of the rat pancreas and may play a role in the modulation of hormone secretion from the islets of Langerhans. Since little is known about the effect of Leu-Enk on insulin and glucagon secretion, it was the aim of this study to determine the role of Leu-Enk on insulin and glucagon secretion from the isolated pancreatic tissue fragments of normal and diabetic rats. Pancreatic tissue fragments of normal and streptozotocin-induced diabetic rats were incubated for 1 h with different concentrations of Leu-Enk (10(-12)-10(-6)M) alone or in combination with either atropine or yohimbine or naloxone. After the incubation period the supernatant was assayed for insulin and glucagon using radioimmunoassay techniques. Leu-Enk (10(-12 )-10(-6)M) evoked large and significant increases in insulin secretion from the pancreas of normal rats. This Leu-Enk-evoked insulin release was significantly (p < 0.05) blocked by atropine, naloxone and yohimbine (all at 10(-6)M). In the same way, Leu-Enk at concentrations of 10(-12)M and 10(-9)M induced significant (p < 0.05) increases in glucagon release from the pancreas of normal rats. Atropine, yohimbine but not naloxone significantly (p < 0.05) inhibited Leu-Enk-evoked glucagon release from normal rat pancreas. In contrast, Leu-Enk failed to significantly stimulate insulin and glucagon secretion from the pancreas of diabetic rats. In conclusion, Leu-Enk stimulates insulin and glucagon secretion from the pancreas of normal rat through the cholinergic, alpha-2 adrenergic and opioid receptor pathways.     

Effects of porcine diazepam-binding inhibitor on insulin and glucagon secretion in vitro from the rat endocrine pancreas.

Porcine diazepam-binding inhibitor (pDBI) is a novel peptide that has been isolated from the small bowel of the pig, and that occurs also in the islet D-cells. We have studied its effects on hormone release in vitro from the endocrine pancreas of the rat. In isolated islets, pDBI (10(-9)-10(-6)M) did not affect basal insulin release at 3.3 mM glucose, whereas stimulated release at 8.3 mM glucose was dose-dependently suppressed by 32-69% (P less than 0.01). Furthermore, insulin secretion stimulated by either 16.7 mM glucose or 1 mM IBMX (3-isobutyl-1-methylxanthine) or 1 micrograms/ml glibenclamide was suppressed by pDBI at 10(-8) M (by 28-30%, P less than 0.05) and 10(-7) M (by 43-47%, P less than 0.01). In contrast, islet insulin secretion induced by 20 mM arginine was unaffected by these concentrations of pDBI. In the perfused rat pancreas, pDBI (10(-8) M) enhanced by 30% (P less than 0.05) the first phase (0-5 min) of arginine-stimulated insulin release, whereas the second phase (5-20 min) was unchanged. Moreover, pDBI suppressed by 28% (P less than 0.05) the second phase of arginine-induced glucagon release. Arginine-induced somatostatin release was not significantly affected by the peptide. Since pDBI immunoreactivity has been localized also to islet D-cells, the present results suggest that pDBI may act as a local modulator of islet hormone release.     

Failure of parathormone to affect insulin and glucagon release from the perfused rat pancreas.

Parathormone (0.15 U/ml) failed to affect the rate of glucagon and insulin release by the perfused rat pancreas exposed to glucose in either low (3.3 mM) or high (8.3 mM) concentration. Parathormone also failed to interfere with the suppressive effect of glucose (16.6mM) upon glucagon release and its stimulatory action upon insulin secretion. Likewise, the biphasic release of both glucagon and insulin evoked by arginine (10.0 mM) in the presence of glucose (8.3 mM) was unaffected by parathormone. These findings suggest that the endocrine pancreas may not be a target organ for any direct and immediate action of parathormone.     

Potentiation of arginine-induced glucagon secretion by adenosine

Adenosine and the synthetic adenosine agonists 2-chloroadenosine and N⁶-(L-2-phenylisopropyl)-adenosine were tested for effects on hormone secretion from the rat isolated perfused pancreas. These nucleosides, at concentrations of 5 μM, markedly potentiated both phases of arginine-induced glucagon release; the two synthetic agonists were more effective than adenosine. In the absence of arginine, each of the nucleosides induced a transient burst of glucagon. In contrast, adenosine and both synthetic agonists inhibited arginine-induced insulin secretion to varying degrees and caused only negligible insulin release when perfused without arginine. The adenosine antagonist 8-($\text{p}$-sulfophenyl)-theophylline prevented the actions of adenosine on hormone release from the pancreas. Our data suggest that adenosine potentiation of arginine-induced glucagon release may be mediated via adenosine receptors on alpha cell membranes; such a mechanism could provide an important endogenous control over glucagon secretion.     

Effect of beta-hydroxybutyrate and acetoacetate on insulin and glucagon secretion from perfused rat pancreas

To elucidate the physiological significance of ketone bodies on insulin and glucagon secretion, the direct effects of beta-hydroxybutyrate (BOHB) and acetoacetate (AcAc) infusion on insulin and glucagon release from perfused rat pancreas were investigated. The BOHB or AcAc was administered at concentrations of 10, 1, or 0.1 mM for 30 min at 4.0 ml/min. High-concentration infusions of BOHB and AcAc (10 mM) produced significant increases in insulin release in the presence of 4.4 mM glucose, but low-concentration infusions of BOHB and AcAc (1 and 0.1 mM) caused no significant changes in insulin secretion from perfused rat pancreas. BOHB (10, 1, and 0.1 mM) and AcAc (10 and 1 mM) infusion significantly inhibited glucagon secretion from perfused rat pancreas. These results suggest that physiological concentrations of ketone bodies have no direct effect on insulin release but have a direct inhibitory effect on glucagon secretion from perfused rat pancreas.     

The biosynthesis of glucagon in perfused rat pancreas

The biosynthesis of glucagon was studied by using the recirculated, isolated perfused rat pancreas. [³H]Tryptophan was initially incorporated into acid–ethanol-extractable protein, which on gel filtration was eluted with a molecular weight of about 9000 and contained a small amount of glucagon immunoreactivity. With longer incubation [³H]tryptophan incorporation into a second peak was obtained in an identical position with that of the majority of rat glucagon immunoreactivity. This peak of labelled protein exhibited migration characteristics on polyacrylamide-gel electrophoresis identical with those of rat glucagon and was identified as newly synthesized glucagon by demonstration of specific binding and dissociation behaviour with glucagon antibodies. The incorporation of [³H]tryptophan into acid–ethanol-extractable protein was inhibited by cycloheximide. High concentrations of glucose increased [³H]tryptophan incorporation into high-molecular-weight protein but decreased incorporation into proteins smaller than cytochrome c. The pattern of [³H]leucine incorporation into protein was similar to that of [³H]tryptophan.     

Stimulation by prostaglandin E2 of glucagon and insulin release from isolated rat pancreas

To ascertain whether prostaglandins (PG) may play a role in the secretion of glucagon and in an attempt to elucidate the conflicting observations on the effects of PG on insulin release, the isolated intact rat pancreas was perfused with solutions containing 1.1 × 10⁻⁹ to 1.8 × 10⁻⁵M PGE₂. In the presence of 5.6 mM glucose significant increments in portal venous effluent levels of glucagon and insulin were observed in response to minimal concentrations of 2.8 × 10⁻⁸ and 1.4 × 10⁻⁷M PGE₂, respectively; a dose-response relationship was evident for both hormones at higher concentrations of PGE₂. When administered over 60 seconds, 1.4 × 10⁻⁶M PGE₂ resulted in a significant increase in glucagon levels within 24 seconds and in insulin within 48 seconds. Ten-minute perfusions of 1.4 × 10⁻⁶M PGE₂ elicited biphasic release of both islet hormones; Phase I glucagon release preceded that of insulin. Both phases of the biphasic glucagon and insulin release which occurred in response to 15-minute perfusions of 10 mM arginine were augmented by PGE₂. These observations indicate that PGE₂ can evoke glucagon and insulin release at concentrations close to those observed by others in the extracts of rat pancreas. We conclude that PG may be involved in the regulation of secretion of glucagon and insulin and may mediate and/or modify the pancreatic islet hormone response to other secretagogues.     

Studies on the biosynthesis of pancreatic glucagon in the pigeon (Columba livia).

The biosynthesis of glucagon was studied in microdissected pigeon pancreatic, islets. [3H]-Tryotophan and [3H]leucine were incorporated into big and little glucagon. No precursor-product relationship was evident between big and little glucagon after radioactive pulsechase and immunoreactive chase incubations. Radioactive and immunoreactive little glucagon and immunoreactive big glucagon were actively secreted and the synthesis of both glucagons was inhibited by high concentrations of glucose. [3H]Tryptophan and [3H]leucine were incorporated into an islet protein of about 20000mol.wt. Gel filtration of extracts of turkey pancreas revealed the presence of an immunoreactive peak of mol.wt. approx. 20000. This glucagon-immunoreactive component was also present in dog and ox pancreas and was stable to chaotropic agents and elution at various pH values. A similar-sized glucagon-immunoreactive species was present in the dog circulation. These results are discussed in the light of the presently accepted mechanisms of glucagon biosynthesis.     

Photoaffinity labelling of the oxytocin receptor in plasma membranes from rat mammary gland

Plasma membranes from rat mammary gland containing a high concentration of [3H]oxytocin binding sites (2.8 pmol/mg protein) were used for photoaffinity labelling experiments. Competitive binding experiments show that these receptors bind with high affinity the specific oxytocin agonist [Thr4, Sar7]oxytocin and the analogue of 1-deamino-[8-lysine]vasopressin containing a photoreactive azidobenzoyl group (Abz) at the side chain of lysine. The tritium-labelled (50 Ci/mol) photoreactive analogue incorporated into a membrane protein with an apparent relative molecular mass of 65,000 +/- 3000 Da (n = 16). The labelling of this protein was completely suppressed by an excess of oxytocin.