UNIPROT:P01275 - FACTA Search

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The main hormones involved in ketone-body metabolism are the anabolic hormone insulin and the primarily catabolic hormones, glucagon, cortisol, catecholamines and growth hormone. These hormones may regulate ketone-body metabolism at three sites: adipose tissue, by regulating fatty acid supply to the liver; the liver itself, by determining the relative activities of the re-esterification and fatty acid oxidation pathways; and the periphery, by influencing the rate of extrahepatic utilization of ketone bodies. The first two are quantitatively the most important. Insulin acts on all three regulatory sites. In adipose tissue lipolysis is inhibited and re-esterification enhanced with consequent decrease of fatty acid release. Both these processes are extremely insulin-sensitive. In the liver insulin increases fatty acid synthesis and esterification. At the same time malonyl-CoA formation is increased, which inhibits the acylcarnitine transferase system and thus decreases the transport of fatty acids into mitochondria and hence fatty acid oxidation and ketogenesis. Insulin also has a small stimulatory effect on extrahepatic ketone-body utilization. The effects of glucagon depend on whether insulin is present. In normal man glucagon stimulates insulin secretion and the predominant effect is that of insulin, i.e. decreased ketogenesis. In insulin deficiency glucagon has a mild stimulatory effect on lipolysis, increasing fatty acid supply to the liver. The main effects of glucagon are, however, on the liver. It activates the carnitine acyltransferase system through inhibition of malonyl-CoA synthesis. Fatty acid oxidation is increased and ketogenesis enhanced. The overall effect on the liver depends on the relative amounts of insulin and glucagon present. Studies with somatostatin show that glucagon can increase ketogenesis acutely when insulin secretion is inhibited in normal man, but the effects are short-lived. Cortisol has similar effects to glucagon. In the presence of insulin there is a small increase in fatty acid mobilization from adipose tissue, secondary to impaired glucose entry, and perhaps a small effect on lipolysis itself. This fatty acid is, however, directed to triacylglycerol in the liver. In insulin deficiency, again demonstrated by somatostatin infusion, the incoming fatty acidstone-body formation. The mechanism remains obscure. Catecholamines, in contrast, have their most potent effects on adipose tissue, stimulating lipolysis and fatty acid release even in the presence of insulin. They thus act mainly by enhancing precursor supply and have only minor effects on liver and no effect on peripheral utilization. Growth hormone, like glucagon, has little effect in the presence of insulin, but can enhance ketogenesis in insulin deficiency, although again the mechanism is unknown. Thus in normally fed man the effects of insulin will be overriding and little ketogenesis occurs because of limited fatty acid availability in the liver...
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PMID:Hormonal regulation of ketone-body metabolism in man. 74 14

Most forms of liver disease are probably associated with impaired gluconeogenesis, although hypoglycaemia is rarely an important clinical feature. Blood concentrations of the gluconeogenic precursors, lactate, glycerol and alanine are elevated although, in certain situations, alanine levels may be decreased. Abnormal glucose tolerance is present in both acute and chronic liver disease, but is usually not of clinical importance. The mechanism of glucose intolerance remains uncertain, with diminished hepatocyte mass, portal diversion and insulin resistance the major postulates. Indeed, the importance of the liver in disposing of an oral glucose load, is still questioned. Both hyperinsulinism and hypoinsulinism are found in liver disease, with hyperinsulinism common in cirrhosis and acute viral hepatitis. This is accompanied by insulin resistance. The hyperinsulinism is probably due to defective hepatic clearance of insulin rather that to over-production. The cause of the insulin resistance remains to be established. Glucagon levels are raised and may contribute to this resistance. Growth hormone levels are also increased but are associated with low somatomedin levels and the role of growth hormone in insulin resistance is therefore questionable. Future developments include use of new animal models, studies of biopsy specimens and studies of hepatic hormone receptors.
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PMID:Carbohydrate metabolism in liver disease. 79 84

Growth hormone (GH) responses to L-dopa, 2-Br-alpha-ergocryptine (CB-154), thyrotropine-releasing hormone (TRH), luteinizing hormone-releasing hormone (LH-RH), glucagon and glucose were investigated in six patients with active acromegaly. The following results were obtained. 1) Subcutaneous injection of 1 mg glucagon caused a clear-cut decrease in plasma GH levels in 5 out of 6 active acromegalic patients at 30 minutes after the injection. In 2 out of 6 patients a rebound of plasma GH was observed. 2) In three out of six patients with active acromegaly, oral administration of 0.5 g L-dopa caused a significant suppression of plasma GH levels. 3) CB-154 (2.5mg) administered orally elicited a marked decrease in plasma GH levels in the same three patients who showed a significant suppressive GH reponse to L-dopa, and the inhibitory effect of CB-154 on GH secretion lasted for 6 hours. These patients who had a GH response to L-dopa or CB-154 were named "responders". 4) Intravenous administration of TRH resulted in a significant increase in plasma GH in 4 patients 3 of whom were responders and the other a non-responder. 5) Pretreatment with CB-154 did not modify the TRH-induced GH increase in all patients who had a positive response to TRH. 6) A significant increase in plasma GH was elicited by the intravenous injection of 100 mug LH-RH in 3 out of 6 patients with acromegaly. 7) When oral administration of CB-154 had been given 2 hours before LH-RH, the GH response to LH-RH was blunted in two of three patients who had a LH-RH-induced increase in plasma GH levels.
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PMID:[Comparison with growth hormone responses to various drugs or substances in patients with active acromegaly (author's transl)]. 82 92

Insulin is the key hormone of carbohydrate metabolism, it also influences the metabolism of fat and proteins. It lowers blood glucose by increasing glucose transport in muscle and adipose tissue and stimulates the synthesis of glycogen, fat, and protein. The anabolic action of insulin is antagonized by the catabolic action of glucagon. This hormone stimulates glycogenolysis and gluconeogenesis. The molar insulin: glucagon ratio is a parameter for an anabolic or a catabolic situation. Epinephrine also antagonizes insulin action. Like glucagon it stimulates glycogenolysis. In addition it reduces the insulin sensitivity of peripheral tissues and inhibits the release of insulin. Growth hormone decreases glucose uptake in muscle and adipose tissue gluconeogenesis in liver. In the presence of insulin, growth hormone stimulates protein synthesis. The net metabolic effects of a single hormone are directly related to the activity of other synergistic or antagonistic hormones.
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PMID:Hormonal interactions in carbohydrate metabolism. 82 93

In 24 normal and 24 obese subjects of both sexes circulating substrates (blood sugar, free fatty acids, ketone bodies) and hormones (insulin, growth hormone, pancreatic glucagon) were determined during 6 days of total fast. In normals the blood sugar fell to lower levels than in the obese. Plasma free fatty acids and ketone concentrations rose faster in normal than in obese subjects, and faster in females than in males. Plasma insulin concentrations declined to a greater extent in obese than in normal subjects. In all groups studied a significant increase of the pancreatic glucagon level within 1-3 days of fasting was observed, however, its rise occurred faster in normal females than in males. Growth hormone (GH) rose significantly in normal males but not in obese males. Following high overnight fasting values in some normal females showed no significant increase in GH levels but significantly higher GH values than obese females after 1-6 days of fasting. After summarizing starvation-induced metabolic changes common to all study groups the respective differences found between males and females and between normal and obese subjects are discussed.
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PMID:[Metabolic differences between males and females and between normal and obese subjects during total fast]. 93 57

The secretion of insulin, glucagon and growth hormone was determined in the serum of patients with recently diagnosed juvenile-type diabetes (10 patients) during stimulation by intravenous infusion of L-arginine and was compared with the results found in a group of five healthy persons. The value of the insulinemia was significantly lower in the diabetics as compared with the healthy controls. Serum glucagon levels were higher in all diabetics when fasting and after L-arginine administration as compared with the controls but a significant difference was observed only at the peck of secretion (5 min after L-arginine administration). Growth hormone concentration was slightly higher in the diabetics after secretory stimulation than in the controls, particularly at the peak of secretion (30 and 45 min) but the difference was statistically no significant.
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PMID:Serum insulin, pancreatic glucagon and growth hormone levels in response to intravenous infusion of L-arginine in patients with recently detected juvenile diabetes. 95 42

Adult rat hepatocytes have been previously isolated and maintained in monolayer culture, but attempts to stimulate DNA synthesis have been unsuccessful. Hormonal conditions are now described which induce DNA synthesis in cultured hepatocytes from partially hepatectomized rats. DNA synthesis was determined autoradiographically by the incorporation of [3H]thymidine into nuclei of morphologically distinct hepatocytes. Insulin (4-4000 nM) or epidermal growth factor (10 ng/ml) alone caused significant increases in the labeling index. The two hormones together acted synergistically to produce labeling indices of 35-50% on the third day of culture, compared with 2-7% in control cultures. The addition of glucagon (400 nM) further increased the labeling indes. Dexamethasone (80 ng/ml) inhibited DNA synthesis but, under certain conditions, enhanced cell attachment. Growth hormone and triiodothyronine had no significant effect on DNA synthesis. The mixture of epidermal growth factor, insulin, and glucagon also stimulated incorporation of [3H]thymidine into phenol-extracted DNA. Although DNA synthesis was stimulated, cell division occurred infrequently. These data suggest a prominent role for epidermal growth factor in promoting hepatic DNA synthesis by acting in concert with insulin and glucagon.
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PMID:Hormonal stimulation of DNA synthesis in primary cultures of adult rat hepatocytes. 106 71

The association of hypoglycemia and microphallus in the male neonate is presumptive evidence of congenital hypopituitarism. This was observed in four male infants with normal birth weight and length, optic discs, and intelligence, and without gross central nervous system malformations. Plasma and urinary cortisol values were low. Stimulation with metyrapone and insulin hypoglycemia failed to elicit a rise in plasma corticoids, but multiple doses of ACTH evoked a response. Growth hormone responses to arginine, insulin, sleep, L-dopa, and glucagon were uniformly less than 2.5 ng/ml. In three patients, however, length remained within 2 SD of the mean until two years of age; in one, there was a sharp decrease in growth by three months. Two patients had low plasma TSH and thyroxine concentrations within the first month of life. In the other two patients, whose thyroxine levels were measurable, intravenous administration of thyrotropin-releasing factor evoked a normal rise in plasma TSH; serum thyroxine decreased into the hypothyroid range in one after GH therapy was initiated. Plasma prolactin was normal in the first two patients receiving thyroxine replacement therapy. The other two patients had elevated baseline prolactin levels and had an augmented rise in plasma prolactin after administration of TRF. Human chorionic gonadotropin induced a 10- to 15-fold rise in plasma testosterone in the two patients tested. The changes in plasma FSH and LH after luteinizing hormone-releasing factor were either low or in the prepubertal range. In three patients, treated with testosterone enanthate intramuscularly, phallic growth occurred. In addition, all three had a transient increase in height but no acceleration of skeletal maturation. The data suggest a deficiency of hypothalamic hypophysiotropic hormones rather than a primary pituitary defect. Early recognition of this syndrome complex is critical for prompt treatment of the life-threatening cortisol deficiency. The diagnosis is more difficult in affected females because their external genitals are normal. The microphallus is a remediable manifestation of hypopituitarism.
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PMID:Congenital hypopituitarism associated with neonatal hypoglycemia and microphallus: four cases secondary to hypothalamic hormone deficiencies. 118 16

Plasma concentrations of glucose, insulin, glucagon, cortisol, growth hormone and prolactin were measured repeatedly in ten females undergoing abdominal hysterectomy during general anaesthesia. In addition to general anaesthesia five of the patients had continuous epidural analgesia effective for the first 26 postoperative hours. Plasma glucose was elevated during surgery and postoperatively, but not in patients having epidural analgesia. Insulin was low and unchanged in both groups. Glucagon was unchanged and similar in both groups. Cortisol was lower during surgery in the epidural group, but not postoperatively. Growth hormone increased during surgery in four of five patients receiving general anaesthesia alone, but no changes were observed in the epidural group. Prolactin was greatly elevated in all patients immediately after induction of anaesthesia and then fell rapidly during surgery, similarly in both groups. It is concluded that epidural analgesia can inhibit the hyperglycaemic response to surgical stress, but this effect cannot be uniformly correlated to changes in peripheral plasma levels of insulin, glucagon, cortisol, growth hormone or prolactin.
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PMID:Effect of epidural analgesia on the glycoregulatory endocrine response to surgery. 126 58

The work was designed to study the effects of a meat meal on glomerular filtration rate (GFR), renal plasma flow (RPF), and plasma concentrations of glucagon, insulin, growth hormone, renin, aldosterone, total amino acids, and NH3 in healthy humans (H) as well as in patients with Child A liver cirrhosis (LC). The meat meal produced renal hyperaemia and hyperfiltration without changes in the filtration fraction. Fractional Na excretion in urine increased significantly after the meat meal only in LC. Hyperinsulinaemia and hyperglucagonaemia were seen at baseline in LC and were not affected by the meat meal, whereas in H glucagon concentration increased significantly over baseline within 30 min from the meat meal and insulin within 60 min. Growth hormone concentration was normal at baseline in LC and increased significantly 120-180 min after the meal, whereas it was not affected in H. Renin and aldosterone were stable in both H and LC. Plasma amino acid concentration began to increase 60 min after the meat meal, when hyperfiltration was present. The data indicate that in human Child A cirrhosis of the liver renal haemodynamic response to a meat meal is independent of changes in glucagon.
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PMID:Glucagon-independent renal hyperaemia and hyperfiltration after an oral protein load in Child A liver cirrhosis. 155 40

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