The effect of insulin-induced hypoglycaemia on the secretion of glucagon and hepatic glucose production in pancreatectomized dogs

The concentration of plasma glucose in insulin deprived pancreatectomized dogs was decreased from the basal 385 +/- 44 to 65 +/- 12 mg/dL by the infusion of 7 mU X kg-1 X min-1 insulin. During the infusion, the plasma concentration of immunoreactive glucagon (IRG) did not change and hepatic glucose production was decreased. This is in contrast to earlier findings in alloxan diabetic dogs in which plasma IRG decreased in hypoglycaemia. The hypothesis is put forward that, in contrast to pancreatic alpha cells in which the effect of insulin prevails, neither insulin nor a decrease in the ambient concentration of glucose exerts any effect on the secretion of glucagon from extrapancreatic alpha cells.     

Neural pathways regulating Brunner's gland secretion in guinea pig duodenum in vitro

This study examined the neural pathways innervating Brunner's glands using a novel in vitro model of acinar secretion from Brunner's glands in submucosal preparations from the guinea pig duodenum. Neural pathways were activated by focal electrical stimulation and excitatory agonists, and videomicroscopy was used to monitor dilation of acinar lumen. Electrical stimulation of perivascular nerves evoked large dilations that were blocked by TTX (1 microM) or the muscarinic receptor antagonist 4-diphenylacetoxy-N-(2-chloroethyl)-piperidine hydrochloride (1 microM). The nicotinic agonist 1,1-dimethyl-4-phenylpiperazinium iodide (100 microM) had no effect, and the nerve-evoked responses were not inhibited by hexamethonium (200 microM). Dilations were abolished in preparations from chronically vagotomized animals. Activation of submucosal ganglia significantly dilated submucosal arterioles but not Brunner's glands. Effects of electrical stimulation of perivascular and submucosal nerves were not altered by guanethidine. Capsaicin and substance P also dilated arterioles but had no effect on Brunner's glands. Cholinergic (choline acetyltransferase-immunoreactive) nerve fibers were found in Brunner's glands. These findings demonstrate that Brunner's glands are innervated by cholinergic vagal fibers but not by capsaicin-sensitive or intrinsic enteric nerves.     

A novel in vitro model of Brunner's gland secretion in the guinea pig duodenum

A novel in vitro model that combined functional and morphological techniques was employed to directly examine pathways regulating Brunner's gland secretion in isolation from epithelium. In vitro submucosal preparations were dissected from guinea pig duodenum. A videomicroscopy technique was used to measure changes in luminal diameter of glandular acini as an index of activation of secretion. Carbachol elicited concentration-dependent dilations of the lumen (EC(50) = 2 microM) by activating muscarinic receptors on acinar cells. Ultrastructural and histological analyses demonstrated that dilation was accompanied by single and compound exocytosis of mucin-containing granules and the accumulation of mucoid material within the lumen. Inflammatory mediators (histamine, PGE(1), PGE(2)) and intestinal hormones (CCK, gastrin, vasoactive intestinal polypeptide, secretin) also stimulated glandular secretion, whereas activation of submucosal secretomotor neurons by 5-hydroxytryptamine did not. This study directly demonstrates that multiple hormonal, inflammatory, and neurocrine agents activate Brunner's glands, whereas many have dissimilar effects on the epithelium. This suggests that Brunner's glands are regulated by pathways that act both in parallel to and in isolation from those controlling epithelial secretion.     

The effect of hypophysectomy and hypophysis-transplantation on the secretion of gut glucagon immunoreactivity and gut glucagon-like immunoreactivity in depancreatized dogs

The role of hypophysis in the regulation mechanism of the secretion of gut glucagon immunoreactivity (gut GI) that was measured using C-terminal specific glucagon antiserum after pancreatectomy, and gut glucagon-like immunoreactivity (gut GLI) that was obtained by subtracting GI from total glucagon-like immunoreactivity (total GLI) which was measured using non-specific glucagon antiserum, was investigated in depancreatized dogs. Plasma glucose, gut GI and gut GLI levels were found to increase in totally depancreatized dogs. The former two showed a significant decrease after hypophysectomy, and were reversed by the hypophysis-transplantation, while gut GLI was not affected either by hypophysectomy or hypophysis-transplantation. Intramuscular injections of human growth hormone (HGH) or adrenocorticotropic hormone-Z (ACTH-Z) to depancreatized-hypophysectomized dogs had no effect on plasma glucose level or gut GI. It is concluded that hypophysis may promote the secretion of gut GI after pancreatectomy, but not of gut GLI. Gut GI seems to regulate plasma glucose level after pancreatectomy. However, the precise regulation mechanism of gut GI by the hypophysial hormone after pancreatectomy is not clarified yet.     

Stimulation of gastric glucagon secretion by epinephrine administration in dogs

To determine the response of gastric A-cells to adrenergic substances, immunoreactive glucagon was determined simultaneously in the jugular vein and in the left gastroepiploic vein of totally depancreatized dogs. Under basal conditions a significant gradient of glucagon concentrations between the jugular and gastric veins was observed, whereas plasma insulin values were almost undetectable. Intravenous administration of epinephrine elicits a prompt and significant increase in glucagon concentrations in the gastric vein which persist during the time of hormone infusion. To ensure adequate adrenergic blockade, blockers were infused before epinephrine administration. Accordingly, after phentolamine, the infusion of epinephrine failed to increase gastric glucagon concentrations, while after propranolol, epinephrine induced a significant release of gastric glucagon. These results indicate that epinephrine stimulates gastric glucagon secretion and that this effect is mediated through alpha-adrenergic receptors.     

The effect of cyclosporine A on bile secretion in dogs

Cyclosporine A is reported to cause cholestasis, but the evidence is confounded by anesthesia and surgery used in acute experiments. To better investigate the effect of cyclosporine on the liver, bile output was directly measured in three cholecystectomized dogs by cannulating the common duct through a chronic duodenal fistula. Control studies were done 1 month after surgery. Cyclosporine in oral doses of 5, 15, and 50 mg.kg-1.d-1 was then given for consecutive 1-week periods. Twice during each study period, bile output was measured for 5 h in fasted, awake animals: 3 h to establish basal conditions, followed by 2 h of taurocholate infusions at 1 and then 2 mumols.kg-1.min-1. Under basal conditions, bile flow rose with each dose of cyclosporine, increasing 63, 127, and 179% above control with cyclosporine 5, 15, and 50 mg.kg-1,d-1, respectively. Bile flow increased similarly during taurocholic acid stimulation. Cyclosporine had no effect on bile salt or bilirubin secretion. In this chronic dog model isolated from other causes of cholestasis, cyclosporine did not induce cholestasis but rather caused a dose-related choleresis without any change in bile salt secretion.     

Effects of glucosamine on insulin and glucagon secretion in dogs and ducks.

The effects of infusion of glucosamine on immunoreactive glucagon (IRG) and insulin (IRI) secretion were studied in dogs and ducks. During systemic infusion of glucosamine, hyperglycemia developed and insulin secretion was inhibited in both species. An immediate and sustained elevation of peripheral IRG levels was induced in ducks but a transient rise, detectable only in the pancreatic vein blood, was provoked in dogs. Suppression of insulin release and stimulation of glucagon release may be mediated by the inhibition of glucose utilization in beta- and alpha-cells. The very prompt response of IRG in ducks may imply that glucosamine has a specific stimulating effect on the alpha-cells of ducks. Intrapancreatic administration of glucosamine in dogs, however, failed to elicit the rise of IRG, although insulin secretion was inhibited. Thus, it is suggested that the systemic administration of glucosamine in dogs may stimulate IRG secretion by some indirect effect. In one dog, however, a sustained rise of the pancreatic vein IRG was observed. Thus, the possibility cannot be ruled out that the difference in IRG response to glucosamine in dogs and ducks is quantitative rather than qualitative. Glucagon release by glucosamine may provide an additional factor to the hyperglycemic effect of glucosamine, in addition to its effect to suppress insulin release as well as its direct inhibitory effect on glucose utilization in tissues.     

Oxytocin increases extrapancreatic glucagon secretion and glucose production in pancreatectomized dogs

Infusion of oxytocin into normal dogs increases plasma levels of insulin and glucagon and glucose production and uptake. To determine whether infused oxytocin also increases glucagon secretion from extrapancreatic sites, pancreatectomized dogs, off insulin for 18 hr, were infused with oxytocin and plasma glucagon, and glucose production and uptake were measured using the [6-3H]glucose primer-infusion technique. The diabetic dogs, in the control period, had elevated plasma glucose and glucagon levels, an increased rate of glucose production, and a relative decrease in glucose uptake (decreased clearance). Infusion of oxytocin (500 microU/kg/min) caused a rise in plasma glucagon and glucose levels, increased glucose production, and further decreased glucose clearance. It is concluded that oxytocin can stimulate secretion of extrapancreatic glucagon, which contributes to the increased glucose production.     

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.     

Postembedding staining of Brunner's gland with lectin-ferritin conjugates

Postembedding staining of intracellular carbohydrates of rat Brunner's gland cells embedded in Epon and acrylamide was carried out with Ricinus communis agglutinin-ferritin, concanavalin A-ferritin, and wheat germ agglutinin-ferritin conjugates. Th Golgi vacuoles and mucous granules were stained with these conjugates. In each staining, the tissues embedded in acrylamide were stained more strongly than those embedded in Epon. The staining intensity of wheat germ agglutinin-ferritin was the strongest among the three conjugates and the staining intensity of Ricinus communis agglutinin-ferritin was stronger than that of concanavalin A-ferritin in both embedding methods. Free ferritin showed almost no binding to these structures and staining with the conjugates was inhibited by the addition of appropriate competitive sugars to the staining solutions. Osmium-postfixed tissues were not stained well with the conjugates. Washing of the sections with bovine serum albumin solution after staining was an essential step in the present method to reduce the nonspecific adsorption of the conjugates. The present method was very simple and had good reproducibility.     

The effect of glucagon on N-acetylglutamate-synthetase

The effect of glucagon and the protein content of the diet on the activity of N-acetylglutamate synthetase was studied. The activity of N-acetylglutamate synthetase depended on the protein content of the diet. Glucagon increased the activity of N-acetylglutamate synthetase and reduced the stimulatory effect of arginine. The enzyme of glucose-fed animals became arginine independent. It was concluded that glucagon induced some kind of covalent modification of the synthetase.     

The effect of glucagon on glomerular filtration rate in dogs during reduction of renal blood flow.

Glucagon in small intravenous (i.v.) doses markedly increases glomerular filtration rate (GFR) in normal anesthetized dogs. In this study, the effects of glucagon 5 mug/min (i.v.) on renal hemodynamics was tested in four canine models of acute pre-renal failure (hemorrhage, barbiturate overdose; renal arterial clamping and renal arterial infusions of noradrenaline) and in a model of unilateral acute tubular necrosis at 4 h and 6-7 days following completion of the ischemic insult. Following hemorrhage and barbiturate excess, with arterial blood pressure maintained at 65-70 mm Hg, whole-kidney GFR and clearance rate of p-aminohippurate decreased by 50-70%. During this reduction of perfusion pressure, the subsequent infusion of glucagon increased GFR by 90-130%. In models where arterial pressure was normal during the period of ischemia (clamping and noradrenaline infusion), not only did glucagon significantly increase renal perfusion, but the ischemic kidney proved to be far more sensitive to the hemodynamic effects of glucagon (delta GFR - 120-160%) than the contralateral control (deltaGFR = 30-40%). In three dogs completely anuric following renal arterial clamping, glucagon was able to improve blood flow and restart urine formation. Glucagon, but not dopamine, was able to simulate the beneficial effects of hypertonic mannitol on renal function in dogs with hemorrhagic hypotension. Glucagon was without effect in established acute tubular necrosis. This study, therefore, indicates that, during renal ischemia, glucagon may be quite effective in preserving urine output and perfusion of the kidneys.