Localization of insulin, glucagon and somatostatin in the pancreas of the adult newt, Notophthalmus viridescens

The current study is designed to demonstrate the presence of immunoreactive insulin (IRI), glucagon and somatostatin in the adult pancreas. Methods include aldehyde fuchsin (AF) staining and peroxidase anti-peroxidase (PAP) immunochemical localization for light microscopy as well as protein A gold (PAG) staining for scanning electron microscopy (SEM) in conjunction with backscattered electron imaging (BEI). Our results show the presence of large clusters of AF-positive cells within networks of highly vascularized pancreatic acinar tissue. PAP immunochemistry of pancreas serial sections exhibit positive immunoreactivity to the same AF-positive structure, thus demonstrating the presence of IRI. This immunoreactivity is found in a high percentage of cells in the islet-like structures. These cells tend to be centrally located within the cluster. Antibody specificity controls, including homologous antigen immunoabsorbance, as well as incubation of sections in normal guinea pig serum give negative immunoreactivity. Immunoreactive glucagon-containing cells and somatostatin-containing cells are distributed around the periphery of the central core of IRI-containing cells. SEM in conjunction with BEI confirm the presence of PAG within these cell clusters. We conclude that: (a) newt pancreatic IRI reacts in a specific manner with bovine antibody, suggesting a partial structural similarity to mammalian antigen; (b) IRI is localized within within pancreatic islet-like cell clusters and these IRI-containing cells form a central mass which is surrounded by glucagon and somatostatin-containing cells; this cellular distribution is similar to that found in many mammals. PAG conjugated insulin antibody is detectable by SEM in conjunction with BEI in islet cells of the newt pancreas.     

The presence and actions of NPY in the canine endocrine pancreas

Immunofluorescent staining for neuropeptide Y (NPY) in canine pancreatic tissue was performed together with an evaluation of the effects of synthetic NPY on the release of insulin (IRI), glucagon (IRG) and somatostatin (SLI) from the duodenal lobe of the canine pancreas in situ. NPY-like immunoreactivity was localized in perivascular nerve fibers throughout the acinar tissue. NPY-immunoreactive fibers were also demonstrated in the islets, usually surrounding blood vessels but also occasionally in fibers associated with endocrine cells, primarily at the periphery of islets. In addition, the ganglia dispersed in the pancreatic parenchyma were densely innervated by NPY-immunoreactive fibers, and these ganglia regularly contained cell bodies staining for NPY. Direct infusion of NPY into the pancreatic artery (p.a.) produced a dose-dependent decrease of pancreatic SLI output and of pancreatic venous blood flow. Low-dose p.a. infusion of NPY (50 pmol/min) had no effect on basal IRI or IRG output or on the islet response to glucose (5-g bolus, i.v.). High-dose p.a. infusion of NPY (500 pmol/min) transiently stimulated IRI output and modestly increased IRG output. However, the comparatively sparse innervation of canine islets with NPY-like immunoreactive fibers and the relatively minor effects of large doses of synthetic NPY on pancreatic hormone release lead us to conclude that this peptide is not an important neuromodulator of islet function in the dog.     

A case with glucagonoma syndrome--heterogeneity of glucagon and insulin

The heterogeneity of glucagon and insulin in plasma and tissue extracts from a 57-year-old female with glucagonoma syndrome with surgically and autopsy verified islet-cell tumors was studied by Bio-Gel P-10 filtration. The preoperative plasma immunoreactive glucagon (IRG) level was 20.2 ng/ml, and plasma glucagon-like immunoreactivity(GLI) 25.8 ng/ml. The column chromatography of the preoperative plasma revealed three or four IRG components and four GLI components. Among these, peak II, the large glucagon immunoreactivity (LGI) peak, considered a candidate for proglucagon, was prominent, along with peak III. The resected metastatic liver tumor contained an enormous amount of IRG and an appreciable amount of immunoreactive insulin (IRI), indicating that the elevated plasma IRG was mainly of tumor origin. The IRG pattern of the tumor tissue extract revealed a small quantity of IRG in peaks I and II, and a large amount in peak III; control pancreatic tissue extract manifested a similar elution pattern. The IRI elution pattern of the tumor tissue extract revealed two major IRI peaks which migrated close to the elution volume of cytochrome C and insulin, respectively. This is a quite different pattern from the control pancreatic tissue extract in which the RI peak was localized in the elution volume of the insulin. We conclude that the present metastatic liver tumor produced not only enormous amounts of glucagon but heterogeneous peptides which contained immunological insulin determinants within their.     

Lack of effect of thyrotropin-releasing hormone (TRH) on the peripheral plasma levels of pancreatic glucagon in man

Based on the fact that human pancreas has thyrotropin-releasing hormone (TRH) immunoreactivity and bioactivity, we studied the effect of TRH on peripheral plasma levels of pancreatic glucagon (IRG) and insulin (IRI) in healthy subjects. During the infusion of 400 micrograms TRH for 120 min basal plasma IRI and IRG levels did not change significantly. In addition, intravenous infusion of 400 micrograms TRH did not affect the increments in the plasma IRG levels and the decrements in the blood glucose during insulin hypoglycemia.     

Increase by somatostatin of the arginine induced rise in blood glucose in untreated insulin requiring diabetics.

We have demonstrated previously that cyclic somatostatin (GH-RIH) exerts a diabetogenic action in healthy subjects. To further examine the impact of this phenomenon studies of blood glucose (BG), immunoreactive insulin (IRI), glucagon (IRG) and growth hormone (GH) were performed in insulin requiring diabetics (n = 6) receiving i.v. arginine (0.5 g/kg) both in the absence and presence of i.v. GH-RIH (500 microgram/h). The infusion of GH-RIH-resulted in a persistent diminution in plasma IRI, IRG and GH. BG fell during i.v. GH-RIH during the initial 30 min and was below control values up to 45 min after initiation of i.v. arginine, but subsequently exceeded control levels (p less than 0.05 - less than 0.025). The excess rise in BG occurred in spite of suppression by somatostatin of the ariginine induced release of IRG, IRI and GH. A fall in BG was seen following cessation of i.v. GH-RIH and during a rebound of insulin release with glucagon levels remaining in the basal range. These findings indicate a diabetogenic action of somatostatin also in insulin requiring diabetics as long as some residual capacity for insulin release is retained.     

Effects of serotonin, of its biosynthetic precursors and of the anti-serotonin agent metergoline on the release of glucagon and insulin from rat pancreas.

We have evaluated the effect of serotonin (5-HT) and of its biosynthetic precursors 5-Hydroxytryptophan (5-HTP) and tryptophan (TRP) on the release of immunoreactive glucagon (IRG) and insulin (IRI) from isolated islets and pieces of pancrease of the rat. In isolated islets, 5-HT inhibited the IRI response to a high glucose concentration (3.0 mg/ml), without affecting the IRG response to either a low (0.5 mg/ml) or a high glucose concentration; TRP stimulated the IRG and IRI response to the low glucose concentration, while 5-HTP was ineffective. When pieces of pancreas were used, 5-HT and 5-HTP inhibited IRG response to both glucose concentrations, while IRI release was inhibited only by 5-HT. The anti-5-HT agent metergoline enhanced the release of IRG and IRI by pieces of pancreas at both glucose concentrations. The results indicate that exogenous and endogenous 5-HT inhibit basal as well as glucose-mediated IRG and IRI release; that isolated islets are less sensitive than pieces of pancreas to the inhibitory effect of 5-HT and that TRP acts as an amino acid and not as a precursor of 5-HT.     

Effects of histamine, of histidine and of anti-histaminic agents on the release of glucagon and insulin from the rat pancreas.

We have studied the effect of histamine (HA) and histidine (HIS) on the release of immunoreactive glucagon (IRG) and insulin (IRI) by isolated rat islets and pieces of pancreas. In isolated islets, HA and HIS stimulated IRG release at a glucose concentration of 3.0 mg/ml and IRI release at a glucose concentration of 0.5 mg/ml. In pieces of pancreas incubated in the presence of glucose (3.0 mg/ml), HA at a 2mM concentration stimulated IRG release and had no effect on the release of IRI; however, when the concentration of HA was doubled (4 mM), an inhibition of IRI release could also be demonstrated. HIS was ineffective. Perphenazine and dexchlorpheniramine, two anti-histaminic agents, inhibited IRG and stimulated IRI release. These results indicate that histamine, whether endogenous or exogenous, directly stimulated IRG and inhibits IRI release and suggest that some of the in vivo effects of histamine, such as hyperglycemia and lipid mobilization, may be mediated, at least in part, by these endocrinologic effects.     

Glucagon and insulin relationships in genetically diabetic (db/db) and in streptozotocin-induced diabetic mice.

An inappropriate molar ratio of circulating insulin to glucagon is frequently associated with the metabolic alterations accompanying diabetes mellitus. Plasma immunoreactive insulin (IRI) and immunoreactive glucagon (IRG) levels were determined and the IRG:IRI ratio calculated at various intervals in overt diabetes in genetically diabetic (db/db) and in streptozotocin-treated mice. Plasma IRI levels in genetic mutants are elevated at nine weeks of age, but are comparable to values found in lean littermates by 21 weeks. The presence of a prevailing hyperglucagonemia is established for the first time in the intact db/db mice. Streptozotocin diabetics are found to have characteristically low plasma IRI and high plasma IRG values. The hormonal imbalance present in these two experimental animal models is accentuated when the data are expressed as the IRG:IRI ratio, which is seen to increase with the progression of diabetes.     

The effect of long-distance running on plasma immunoreactive glucagon levels

Twelve highly conditioned long-distance runners were studied to determine the effects of marathon (42 km) and 10,000 m running on plasma immunoreactive glucagon (IRG), serum immunoreactive insulin (IRI), and serum glucose (G) levels. Blood samples were drawn just prior to and immediately upon completion of the run. Marathon running resulted in no significant change in G, IRI, or IRG levels. After running 10,000 m, plasma IRG levels did not change significantly, while IRI and G increased significantly. In evaluating the pooled data from both runs, a significant inverse correlation was observed between delta G and delta IRG. This relationship between delta G and delta IRG suggests that glucagon plays a role in maintaining normal blood glucose levels during strenuous exercise.     

Pharmacokinetics and effects of intravenous infusion of somatostatin in normal subjects--a two-compartment open model

A direct radioimmunoassay of plasma somatostatin-like immunoreactivity (SRIF-LI) was developed and validated. The sensitivity was 16.0 pg/ml, and the specificity was good. The recovery of plasma SRIF-LI was 98.8 +/- 6.3%. The Scatchard plot of the antiserum binding data revealed a straight line, with a binding affinity of 3.52 X 10(-12) M and a binding capacity 4.06 X 10(-10) M. Synthetic SRIF (Stilamin), 250 micrograms, was infused intravenously over a 30-min period in 9 healthy volunteers. Plasma glucose, insulin (IRI), glucagon (IRG) and SRIF-LI were measured. A two-compartment open model was adopted to analyze the pharmacokinetic data of SRIF-LI. The results showed that plasma SRIF-LI rose from 192.2 +/- 16.2 pg/ml to a plateau of 2,129.8 +/- 288.2 pg/ml within 5-10 min after starting the infusion. The half disappearance time from plasma (Ta1/2) was 1.36 +/- 0.18 min, the half disappearance time from the 'remote' compartment (Tb1/2) was 49.6 +/- 10.9 min and the net half disappearance time from the two compartments together (Tn1/2) was 9.19 +/- 1.49 min. The metabolic clearance rate was 50.3 +/- 7.0 ml/kg/min. The plasma IRI, IRG and the IRI/IRG molar ratio were all suppressed during the infusion period. The recovery time of plasma IRG was mildly delayed in comparison to that of IRI. This indicates that there are dissociations between IRI and IRG in the extent and the duration of suppression caused by somatostatin infusion.     

Islet-activating protein (IAP)-induced adrenergic modulation of pancreatic A and B cell in dogs

Islet-activating protein (IAP) is a substance purified from the culture medium of Bordetella pertussis, and its main action is characterized by the enhancement of secretory response to glucose and other stimuli in pancreatic islet. In this experiment, the effect of IAP on epinephrine-induced secretion of immunoreactive insulin (IRI) and glucagon (IRG) was investigated in normal dogs. Epinephrine suppressed IRI secretion and it had a little increment to IRG secretion in control group, while IRI and IRG secretions were significantly increased by epinephrine in IAP pretreated group. Using beta-blocker (Propranolol) with epinephrine, these increments of IRI and IRG secretions in IAP pretreated group were abolished. However, using alpha-blocker (Phentolamine) with epinephrine, these secretions of IRI and IRG in IAP pretreated group were much more increased than epinephrine alone induced secretions. Blood glucose levels were lower in IAP pretreated group than in control group throughout the loading tests in all of the experiments. These findings suggest that (1) IAP decreases blood glucose level and (2) IAP enhances epinephrine-induced secretion of insulin and glucagon by acceleration of beta-adrenergic effect and by reduction of alpha-adrenergic suppression in dogs.     

Effect of subcutaneous pancreatic tissue transplants on streptozotocin-induced diabetes in rats. II. Endocrine and metabolic functions.

The present study examines the effect of subcutaneous pancreatic tissue grafts (SPTG) on endocrine and metabolic functions in streptozotocin (STZ)-induced diabetic rats using radioimmunoassay and biochemical techniques. SPTG survived even after 15 weeks of transplantation and significantly improved the weight of STZ-diabetic rats over a 15-week period. Although blood glucose-, cholesterol-, and glycosylated-haemoglobin (GHb) levels were not significantly lower in STZ-diabetic rats treated with SPTG, the values of these biochemical parameters were lower than those in untreated diabetic rats. Plasma and pancreatic immunoreactive C-peptide (IRCP) levels did not improve after SPTG (IRCP expressed as mean +/- standard deviation were 0.22 +/- 0.07, 0.072 +/- 0.02 and 0.08 +/- 0.03 pg ml-1 in the plasma non-diabetic diabetic and treated rats respectively, while IRCP levels in the pancreas of the non-diabetic, diabetic and treated rats were 433.8 +/- 0.1, 22.9 +/- 0.01 and 10.4 +/- 0.01 pg mg tissue-1 respectively). SPTG, however, improved plasma immunoreactive insulin (IRI) levels in both plasma and pancreas. IRI values in plasma were 54.7 +/- 13.6, 18.0 +/- 5.0 and 22.1 +/- 4.3 microUI ml-1 in non-diabetic, diabetic and treated rats respectively and were 277.3 +/- 37.1, 14.7 +/- 1.8 and 30.3 +/- 15.9 microIU micrograms tissue-1 in the pancreas of non-diabetic, diabetic and treated rats respectively. There was improvement in immunoreactive glucagon (IRG) levels after SPTG. IRG values in the plasma of non-diabetic, diabetic and treated rats were 147.0 +/- 10.7, 408.0 +/- 76.5 and 247.7 +/- 3 pg ml-1 respectively whereas, IRG measured in the pancreas was 1642.25 +/- 424.23, 1899.0 +/- 290.4 and 1714.1 +/- 301.98 pg micrograms tissue-1 in non-diabetic, diabetic and treated rats, respectively. The pancreas:plasma ratio of pancreatic hormones was deranged in untreated diabetes but improved after SPTG. In conclusion, SPTG significantly improved the weight gain, pancreatic insulin content, plasma IRG and pancreas: plasma ratio of IRCP, IRI and IRG. It also reduced blood glucose-, cholesterol-, and glycosylated-hemoglobin levels in STZ-diabetic rats.     

Response of plasma somatostatin-like immunoreactivity to the administration of alloxan in dogs.

The present study was designed to examine the effects of intravenously injected alloxan (75 mg/kg) upon plasma somatostatin-like immunoreactivity (SLI), glucagon (IRG), insulin (IRI) and glucose levels in 6 dogs. Within 2 hours of the injection of alloxan, SLI and IRI levels decreased significantly below their respective baselines, while IRG and plasma glucose concentrations increased. At 8 hours SLI levels had increased significantly by 55 pg/ml, together with a rise in IRI and a decrease in IRG and glucose concentrations. After 24 hours, marked hyperglycemia and hyperglucagonemia had developed whereas SLI levels were not different from preinjection values.     

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.     

Immunocytochemical study of the distribuition of endocrine cells in the pancreas of the Brazilian sparrow species Zonotrichia Capensis Subtorquata (Swaison, 1837).

In the present study, we investigated types of pancreatic endocrine cells and its respective peptides in the Brazilian sparrow species using immunocytochemistry. The use of polyclonal specific antisera for somatostatin, glucagon, avian pancreatic polypeptide (APP), YY polypeptide (PYY) and insulin, revealed a diversified distribution in the pancreas. All these types of immunoreactive cells were observed in the pancreas with different amounts. Insulin-Immunoreactive cells to (B cells) were most numerous, preferably occupying the central place in the pancreatic islets. Somatostatin, PPA, PYY and glucagon immunoreactive cells occurred in a lower frequency in the periphery of pancreatic islets.     

MONOLAYER CULTURES DERIVED FROM NEONATAL HAMSTER PANCREAS : Light and Electron Microscopy

Cells derived by trypsinization of neonatal golden hamster pancreas were cultured in modified Eagle's medium for 120 h in the presence of glucose (0.8 mg/ml) and for an additional 48 h in medium containing glucose (0.8 or 3.1 mg/ml) or tolbutamide (1,000 µg/ml) plus glucose (0.8 mg/ml). At day 7, cultures were stained differentially for light microscopy or examined by electron microscopy. Immunoreactive insulin (IRI) and immunoreactive glucagon (IRG) in the culture medium were measured by standard immunoassay procedures. Staining properties and ultrastructural appearance of cultured cells were comparable to those of the intact neonatal hamster pancreas. Cultures consisted predominantly of cells possessing aldehyde fuchsin positive (AF⁺) cytoplasmic granules resembling ultrastructurally those of the intact neonatal pancreatic beta cells and additionally, those of fibroblastoid, acinar, acino-insular, and aldehyde fuchsin negative (AF^-) argyrophilic cells. IRI release rate by the cultured cells was increased in the presence of elevated glucose or tolbutamide which paralleled the loss of AF⁺ granulation, but IRG release rate was suppressed by elevated glucose concentration. These findings indicate that these monolayer cultures consist of most of the cell types occurring in the neonatal pancreas, including endocrinologically competent islet cells.     

A light-microscopic immunocytochemical study of the endocrine pancreas in the Australian brush-tailed possum (Trichosurus vulpecula).

The endocrine pancreas of the Australian brush-tailed possum (Trichosurus vulpecula) was investigated by means of immunocytochemistry using the avidin-biotin-peroxidase technique. This was a light microscopic study using this established technique. Serial paraffin sections were stained individually with primary antibodies for glucagon, insulin, somatostatin, and pancreatic polypeptide (PP), showing the same islet. Cells immunoreactive to glucagon, insulin, somatostatin and PP were found in endocrine islets. PP cells appear to be scattered amidst the exocrine portion also. Insulin immunoreactive cells were located in the central region of islet, glucagon in the periphery, somatostatin in periphery and had elongated processes. PP cells were more sparse and located both in the periphery of islet and amidst the exocrine tissue. These results can then be related to a similar study in the same marsupial, but using the immunofluorescence technique and to studies in other marsupials such as grey kangaroo (Macropus fuliginosus) fat-tailed dunnart (Sminthopsis crasicaudata) and the American opossum (Didelphis virginiana). These investigations are part of a study in Australian mammals.     

Immunohistochemical study of the developing endocrine pancreas of the opossum (Didelphis virginiana)

Cells immunoreactive for insulin, glucagon, somatostatin, bovine pancreatic polypeptide and 5-hydroxytryptamine are found in the pancreas of the newborn opossum and of all later stages examined. All immunoreactive cell types are present in primary and secondary islets and within elements of the exocrine pancreas. Cells immunoreactive for glucagon, bovine pancreatic polypeptide, somatostatin and 5-hydroxytryptamine generally are confined to the periphery of secondary (intralobular) islets, whereas insulin-immunoreactive cells occupy the central region. Endocrine cells within primary (interlobular) islets are randomly scattered. A small number of pancreatic-polypeptide-immunoreactive cells are reactive for the amine 5-hydroxytryptamine also, but the reverse is not observed. The endocrine pancreas continues to differentiate and develop throughout postnatal life and into adulthood. Little difference was observed between the head and tail regions of the opossum pancreas for the measurements made.     

Effect of pinealectomy on plasma glucose, insulin and glucagon levels in the rat

In an attempt to know the role of the pineal gland on glucose homeostasis, the blood plasma concentrations of glucose, insulin and glucagon under basal conditions or after the administration of nutrients were studied in the jugular vein of conscious pinealectomized (Pn), melatonin-treated pinealectomized (Pn + Mel) and control (C) rats. Glucose levels were smaller in C than in Pn rats, while immunoreactive insulin (IRI) concentrations were significantly greater in C than in Pn rats. Contrary to this, immunoreactive glucagon (IRG) levels were significantly greater in Pn than in C animals. Melatonin treatment of Pn rats induces an increase of IRI concentrations and a reduction in IRG levels. Similar changes were obtained when hormonal determinations were carried out in portal blood plasma. Although ether anesthesia increases circulating glucagon levels in the porta and cava veins, the qualitative changes of plasma insulin and glucagon in Pn and Pn + Mel were similar to those found in conscious rats. To determine the effects of nutrients on pancreatic hormone release, intravenous arginine or oral glucose were administered to the animals of the three experimental groups. In C rats, both glucose and IRI levels reached a peak 30 minutes after glucose ingestion, decreasing thereafter. However, in Pn rats a glucose intolerance was observed, with maximum glucose and insulin concentrations at 60 minutes, while in Pn + Mel animals, glucose and IRI concentrations were in between the data obtained with the other two groups. Furthermore, glucose ingestion induced a significant reduction of IRG levels in all the groups.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pancreatic glucagon secretion during a short period of hemorrhage in anesthetized dogs

Glucagon has been implicated in the hormonal metabolic response to hemorrhage. However, evidence for this has been obtained largely from observations of circulating plasma glucagon concentration. A clear increase in the pancreatic glucagon secretion remains to be demonstrated. Plasma concentrations of pancreatic immunoreactive glucagon (IRG) and insulin (IRI) were determined in portal venous and aortic blood, and plasma glucose in aortic blood. Dogs were bled (approximately 15 mL/kg) until aortic systolic blood pressure dropped to approximately 50% (70.5 +/- 8.1 mmHg, n = 7) (1 mmHg = 133.32 Pa) of its control value (135 +/- 7.1 mmHg, n = 7), and the hemorrhagic hypotension was maintained for 10 min. The net portal venous IRG delivery rate rose significantly and continued to increase during the hemorrhagic hypotension despite a significant fall in the portal venous blood flow. Aortic IRG increased significantly along with the increase in portal venous IRG delivery rate (r = 0.838, n = 42, p less than 0.01). The portal venous delivery rate of IRI decreased significantly in response to hemorrhage. The aortic IRG/IRI concentration ratio increased significantly during the hemorrhage-induced hypotension. Aortic glucose concentration increased significantly 5 min after hemorrhage and continued to rise until the end of the hemorrhagic hypotension. The present study demonstrates that the secretion of pancreatic glucagon actually increases during the early phase of hemorrhage. The results also indicate that the increase in aortic IRG during the hemorrhagic hypotension is due to the increased pancreatic glucagon secretion. It is suggested that the pancreatic glucagon may be involved in the early hyperglycemic response to hemorrhage.