UNIPROT:P01275 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The diabetic state, as well as elevated culture media glucose level (950 mg D-glucose/dL) per se, significantly retards in vitro development of mouse pre-implantation embryos from a two-cell stage to blastocyst stage; maternal insulin therapy to diabetic mice reverses this impairment. This study was undertaken to assess (1) whether less extreme elevation of the media glucose concentration would also impair development, and (2) whether elevated culture media insulin or glucagon levels would alter development. Two-cell pre-embryos were recovered from B6C3F1 mice that had been stimulated with pregnant mare serum gonadotropin (PMSG) and human chorionic gonadotropin (hGG), mated, and killed 48 hours later. Pre-embryos were observed in culture at 24-hour intervals for a total of 72 hours at four glucose levels: 110 (n = 108), 220 (n = 101), 440 (n = 65), and 950 (n = 106) mg D-glucose/dL. Impairment in progression of development was noted at each time period; compared with development in 110 mg glucose/dL, the distribution of development was significantly different at 24 hours (chi 2 = 60.1, P less than .001), at 48 hours (chi 2 = 36.7, P less than .001), and at 72 hours (chi 2 = 45.1, P less than .001). Rate of development as assessed by ANOVA was also significantly reduced at increasing glucose levels (P less than .0001), with Duncan Multiple Range test demonstrating differences between development at higher glucose levels in the comparison of development in 110 mg/dL versus 440 mg/dL and 950 mg/dL, and at 220 mg/dL versus 950 mg/dL.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Dose-response effects of glucose, insulin, and glucagon on mouse pre-embryo development. 186 20

Infusion of total parenteral nutrition (TPN) with excess carbohydrate calories leads to hepatic steatosis in rats that is associated with an elevated portal insulin/glucagon molar ratio. Previously we have shown that adding glucagon to TPN prevents hepatic steatosis in rats. In this study we attempted to reverse the steatosis by adding glucagon to TPN after 1 week of TPN alone. Adult rats (n = 28) received internal jugular catheters: Group 1 (n = 7), saline (3 cc/h) and chow ad libitum; Group 2 (n = 7), 25% dextrose base TPN solution for 1 week; Group 3 (n = 7), 25% dextrose base TPN for 2 weeks; Group 4 (n = 7), 25% dextrose base TPN for 1 week and then glucagon (15 micrograms/100 g/day) added to TPN for the second week. The infusion rate of TPN was 1.2 ml/100 g/hr (40% kcal greater than control). At 7 days (Group 2) and 14 days (Groups 1, 3, and 4) portal and peripheral venous blood levels were drawn for insulin and glucagon radioimmunoassay, blood glucose determination, and liver function tests; livers were removed for histology and lipid content determination. Blood glucose was equivalent among all groups. Liver function tests were within normal limits. Panlobular vacuolization of the hepatocytes was noted on histology in Groups 2 and 3. Hepatic lipid content was significantly elevated in Group 3. The portal insulin/glucagon molar ratio was increased because of excessive portal venous insulin in Groups 2 and 3 (P less than 0.05 by ANOVA). In contrast, portal venous insulin and the insulin/glucagon molar ratio did not increase in Group 4 and hepatic lipid infiltration was absent when glucagon was added to the TPN solution after 1 week of TPN solution alone. The results suggest that the addition of glucagon to hypertonic dextrose TPN is not only protective in preventing hepatic steatosis, but may reverse steatosis, possibly by increasing hepatic lipid export.
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PMID:Reversal of hepatic steatosis in rats by addition of glucagon to total parenteral nutrition (TPN). 249 33

The purpose of this study was to examine the effects of ingesting water (P), a glucose solution (GL), a maltodextrin solution (Md), a glucose solution with 8% guar gum (GL+G), and a maltodextrin solution with 8% guar gum (Md+G), on the hormonal and metabolite responses during cycling, and on subsequent time to exhaustion. Five male subjects undertook five 90 min rides on a bicycle ergometer at an exercise intensity corresponding to 65% VO2max after having ingested 1 g.kg-1 body weight of the test product in 400 ml of water immediately before the exercise. Blood samples were taken during the trials for analyses of adrenaline, noradrenaline, insulin, glucagon, glucose, lactate and non-esterified fatty acids (NEFA). Respiratory measures were also undertaken during the trials for the determination of oxygen consumption (VO2) and respiratory exchange ratio (RER), from which the carbohydrate oxidation rates were calculated. Rates of perceived exertion (RPE) were also assessed. Ten minutes after the 90 min ride, subjects exercised to volitional exhaustion at an exercise intensity of 75% VO2max. ANOVA revealed that there were significant differences between the treatments for adrenaline (p < 0.01), insulin (p < 0.05), glucose (p < 0.01), lactate (p < 0.01), NEFA (p < 0.01), RER (p < 0.001) and carbohydrate oxidation rate (p < 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Hormonal and metabolite responses to glucose and maltodextrin ingestion with or without the addition of guar gum. 789 Apr 59

To determine the effects of hyperglycemia and hyperinsulinemia on atrial natriuretic peptide (ANP) levels in man, we studied normotensive nondiabetic volunteers (aged 25 to 63 years) during infusion of insulin and/or 20% dextrose (glucose clamp technique) to achieve three different states of "glycemia/hyperinsulinemia," as follows: (1) euglycemia for 2 hours during infusion of insulin (80 mU.m-2.min-1), resulting in plasma insulin levels of approximately 1,200 pmol/L (n = 9); (2) moderate stable hyperglycemia at a level of 11 mmol/L (198 mg/dL) for 2 hours, with infusion of glucagon-like peptide-1 (7-37) amide (GLP-1) during the second hour, which increased endogenous insulin responses to approximately 2,100 pmol/L (n = 9); and (3) marked stable hyperglycemia at a level of 18.5 mmol/L (330 mg/dL) for 2 hours, with endogenous insulin responses of approximately 720 pmol/L (n = 9). In addition, six patients with non-insulin-dependent diabetes mellitus were studied with the GLP-1 protocol at a hyperglycemic level of 14.5 mmol/L (261 mg/dL). In normal subjects, plasma ANP levels increased significantly from 3.0 +/- 0.4 to 4.6 +/- 0.8 pmol/L during marked hyperglycemia, but did not change during euglycemia or moderate hyperglycemia despite higher insulin levels (P < .01, ANOVA). Sodium excretion rates were also highest during the marked hyperglycemic study (125 +/- 14 v 91 +/- 7 v 74 +/- 10 mumol/min, P < .05, marked v moderate hyperglycemia v euglycemia). In diabetic subjects, ANP levels increased significantly from 12.5 +/- 4.1 to 21.1 +/- 5.0 pmol/L during hyperglycemia.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effect of glucose, insulin, and hypertonicity on atrial natriuretic peptide levels in man. 847 20

Previous studies have suggested that glucagon-like peptide-1 (GLP-1) (7-36 amide) may have the direct effect of increasing insulin sensitivity in healthy man. To evaluate this hypothesis we infused GLP-1 in seven lean healthy men during a hyper insulinaemic (0.8 mU.kg-1.min-1), euglycaemic (5 mmol/l) clamp. Somatostatin (450 micrograms/h was infused to suppress endogenous insulin secretion, and growth hormone (3 ng.kg-1.min-1) and glucagon (0.8 ng.kg-1.min-1) were infused to maintain basal levels. GLP-1 (50 pmol.kg-1.h-1) or 154 mmol/l NaCl (placebo) was infused after 3 h of equilibration, i.e. from 180-360 min. GLP-1 infusion resulted in GLP-1 levels of approximately 40 pmol/l. Plasma glucose, insulin, growth hormone, and glucagon levels were similar throughout the clamps. The rate of glucose infusion required to maintain euglycaemia was similar with or without GLP-1 infusion (7.69 +/- 1.17 vs 7.76 +/- 0.95 mg kg-1.min-1 at 150-180 min and 8.56 +/- 1.13 vs 8.55 +/- 0.68 mg.kg-1.min-1 at 330-360 min) and there was no difference in isotopically determined hepatic glucose production rates (-0.30 +/- 0.23 vs -0.16 +/- 0.22 mg.kg-1.min-1 at 330-360 min). Furthermore, arteriovenous glucose differences across the forearm were similar with or without GLP-1 infusion (1.43 +/- 0.23 vs 1.8 +/- 0.29 mmol/l), (ANOVA; p > 0.60, in all instances). In conclusion, GLP-1 (7-36 amide) administered for 3 h, leading to circulating levels within the physiological range, does not affect insulin sensitivity in healthy man.
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PMID:GLP-1 does not not acutely affect insulin sensitivity in healthy man. 889 12

Intravenous glucagon-like peptide (GLP)-1 [7-36 amide] can normalize plasma glucose in non-insulin-dependent diabetic (NIDDM) patients. Since this is no form for routine therapeutic administration, effects of subcutaneous GLP-1 at a high dose (1.5 nmol/kg body weight) were examined. Three groups of 8, 9 and 7 patients (61 +/- 7, 61 +/- 9, 50 +/- 11 years; BMI 29.5 +/- 2.5, 26.1 +/- 2.3, 28.0 +/- 4.2 kg/m2; HbA1c 11.3 +/- 1.5, 9.9 +/- 1.0, 10.6 +/- 0.7%) were examined: after a single subcutaneous injection of 1.5 nmol/kg GLP [7-36 amide]; after repeated subcutaneous injections (0 and 120 min) in fasting patients; after a single, subcutaneous injection 30 min before a liquid test meal (amino acids 8%, and sucrose 50 g in 400 ml), all compared with a placebo. Glucose (glucose oxidase), insulin, C-peptide, GLP-1 and glucagon (specific immunoassays) were measured. Gastric emptying was assessed with the indicator-dilution method and phenol red. Repeated measures ANOVA was used for statistical analysis. GLP-1 injection led to a short-lived increment in GLP-1 concentrations (peak at 30-60 min, then return to basal levels after 90-120 min). Each GLP-1 injection stimulated insulin (insulin, C-peptide, p < 0.0001, respectively) and inhibited glucagon secretion (p < 0.0001). In fasting patients the repeated administration of GLP-1 normalized plasma glucose (5.8 +/- 0.4 mmol/l after 240 min vs 8.2 +/- 0.7 mmol/l after a single dose, p = 0.0065). With the meal, subcutaneous GLP-1 led to a complete cessation of gastric emptying for 30-45 min (p < 0.0001 statistically different from placebo) followed by emptying at a normal rate. As a consequence, integrated incremental glucose responses were reduced by 40% (p = 0.051). In conclusion, subcutaneous GLP-1 [7-36 amide] has similar effects in NIDDM patients as an intravenous infusion. Preparations with retarded release of GLP-1 would appear more suitable for therapeutic purposes because elevation of GLP-1 concentrations for 4 rather than 2 h (repeated doses) normalized fasting plasma glucose better. In the short term, there appears to be no tachyphylaxis, since insulin stimulation and glucagon suppression were similar upon repeated administrations of GLP-1 [7-36 amide]. It may be easier to influence fasting hyperglycaemia by GLP-1 than to reduce meal-related increments in glycaemia.
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PMID:Effects of subcutaneous glucagon-like peptide 1 (GLP-1 [7-36 amide]) in patients with NIDDM. 896 Aug 41

Verapamil poisoning is known to produce hyperglycemia and metabolic acidosis in humans. The purpose of this study was to elucidate mechanisms of verapamil-induced hyperglycemia in awake dogs. Mongrel canines were chronically instrumented to permit studies in the conscious state. In six healthy dogs, steady-state glucose infusion requirement after 1 hr of insulin infusion at 1000 mU/min was 19 +/- 1 mg/kg/min. In six separate dogs, verapamil toxicity was induced via verapamil infusion in the portal vein; during verapamil toxicity, the glucose infusion requirement with an insulin infusion rate of 1000 mU/min was significantly decreased (3 +/- 1 mg/kg/min; p < 0.05, unpaired t test). Eleven other verapamil-toxic dogs were also treated with either saline (n = 6, 3.0 ml/kg/hr) or glucagon (n = 5, 10 microg/kg/min). Insulin concentrations were not changed vs basal concentrations in either group. Catecholamine concentrations increased at least 15-fold in all groups (from 458 +/- 169 to 6973 +/- 480 pg/L in the saline-treated group). Glucose concentrations increased in saline-treated animals from 3.7 +/- 0.3 to 11.2 +/- 1.0 micromol/L, and with glucagon treatment, increased from 3.3 +/- 0.3 to 16.1 +/- 1.6 micromol/L (p < 0.05 vs saline, ANOVA). Verapamil poisoning appears to produce hyperglycemia by inducing systemic insulin resistance, blocking insulin release, together with an intact stress hormone response and glucogenic capacity.
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PMID:The diabetogenic effects of acute verapamil poisoning. 926 9

Glucagon-like peptide 1 [7-36 amide] (GLP-1) and the obese gene product (leptin) are thought to be involved in the central regulation of feeding. Both may act from the peripheral circulation to influence brain function. To study potential interactions, GLP-1 ([7-36 amide]: 0.4, 0.8 pmol kg-1 min-1 or placebo on separate occasions) was infused intravenously (from -30 to 240 min) into nine healthy volunteers [age 26 +/- 3 years, body mass index: 22.9 +/- 1.6 kg/m2, glycated haemoglobin HbA1c: 5.0% +/- 0.2% (normal: 4.0%-6.2%), creatinine: 1.1 +/- 0.1 mg/dl], and (at 0 min) a liquid test meal (50 g sucrose in 400 ml 8% amino acid, total amino acids 80 g/l) was administered via a nasogastric tube. Plasma leptin (radioimmunoassay, RIA), glucose, insulin (microparticle enzyme immunoassay), C-peptide (enzyme-linked immunosorbent assay) and GLP-1 (RIA) were measured, and statistical analysis was done with repeated-measures ANOVA and Student's t-test. Plasma leptin concentrations were 31 +/- 6 pmol/l in the basal state. They did not change within 240 min after meal ingestion nor in response to the infusion of exogenous GLP-1 [7-36 amide] (P = 0.99 for the interaction of experiment and time) leading to GLP-1 mean plasma levels of 25 +/- 2 and 36 +/- 3 (basal 6 +/- 1) pmol/l. On the other hand, glucose (from basal 4.7 +/- 0.1 to 6.0 +/- 0.2 mmol/l at 15 min, P < 0.05) and insulin (from basal 28 +/- 2 to 325 +/- 78 pmol/l at 45 min, P < 0.05) increased clearly after the meal with placebo. In conclusion, (1) plasma leptin levels in normal human subjects show no short-term changes after feeding a liquid mixed meal and (2) do not appear to be directly influenced by physiological and pharmacological elevations in plasma GLP-1 [7-36 amide] concentrations. This does not exclude interactions at the cerebral (hypothalamic) level or on more long-term temporal scales.
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PMID:A liquid mixed meal or exogenous glucagon-like peptide 1 (GLP-1) do not alter plasma leptin concentrations in healthy volunteers. 940 46

In patients with acromegaly, clinical improvement has been reported after octreotide (OCT) treatment, even in cases of only a moderate suppression of growth hormone (GH) levels. In rats, OCT suppresses IGF-I mRNA expression and generation of serum and tissue IGF-I levels. A direct effect of OCT on the IGF system could have therapeutical implications in diabetes mellitus, cardiovascular disease, and certain malignancies in which IGF-I might be involved. The aim of this study was to examine possible GH-independent effects of OCT on IGF components in humans. Six GH-deficient (GHD) patients were studied for 24 h after each of the following treatment regimens (each of 1 weeks duration): (a) daily s.c. GH injection (2 IU/m(2)); (b) as (a) + continuous s.c. infusion of OCT (200 microg/24 h) by means of a portable pump (Nordic Infuser); (c) no treatment. Serum GH binding protein (GHBP) levels tended to be lower after GH and OCT than after GH alone (P =0.10). OCT reduced the GH induced increase in serum IGF-I levels (P<0.05, ANOVA). Mean integrated levels (microg/l) were 359.1+/-49.6 (GH), and 301.6+/-58.9 (GH+OCT). OCT did not significantly reduce serum IGFBP-3 levels (microg/l) [3460+/-270 (GH), and 3112+/-435 (GH+/-OCT);P =0.14]. Serum levels of free IGF-I (P =0.39), IGF-II (P =0.54), and of the acid-labile subunit (ALS) of the ternary complex (P =0.50) were similar during GH+/-OCT as compared with GH alone. After 1 week off GH treatment, significantly lower levels of IGF-I, IGF-II, IGFBP-3, and ALS were recorded (P<0.001). Serum IGFBP-1 levels were significantly higher after GH+OCT than after GH alone (P<0.0001), and levels were even higher without GH. Serum insulin levels (pmol/l) were significantly higher after GH alone as compared with no GH (P<0.05, ANOVA), whereas OCT partly suppressed the insulinotropic effect of GH (P<0. 05) [mean: 114.5+/-33.0 (GH), 91.3+/-29.6 (GH+OCT), 65.9+/-22.5 (no GH)]. This was also reflected in higher blood glucose levels during GH+OCT. Finally, GH+OCT reduced glucagon levels significantly as compared with GH alone (P =0.02). In conclusion, 7 days' administration of OCT to GH-treated GHD patients slightly attenuated serum IGF-I generation, and tended to decrease levels of the other components of the 150 kDa ternary complex. Whether these effects are mediated directly by OCT or indirectly via the accompanying changes in insulin levels remains to be investigated.
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PMID:Effects of a 7-day continuous infusion of octreotide on circulating levels of growth factors and binding proteins in growth hormone (GH)-treated GH-deficient patients. 1062 66

In intense exercise (>80% maximal oxygen consumption [VO2 max]), the 7- to 8-fold increase in glucose production (Ra) is tightly correlated with the greater than 14-fold increase in plasma norepinephrine (NE) and epinephrine (EPI). To distinguish the relative roles of alpha- and beta-adrenergic receptors, the responses of 12 control (C) lean, healthy, fit young male subjects to 87% VO2 max cycle ergometer exercise were compared with those of 7 subjects (at 83% VO2max) receiving intravenous phentolamine (Ph). The Ph group received a 70-microg/kg bolus and then 7 microg/kg/min from -30 minutes, during exercise and for 60 minutes of recovery. The data were analyzed by comparing exercise responses to exhaustion in Ph subjects (11.4 +/- 0.6 min) with those at both 12 minutes and at exhaustion in C subjects (14.6 +/- 0.3 min) and during recovery. There were no significant differences between groups in the plasma glucose response during exercise, but values were higher in C versus Ph subjects during the first 40 minutes of postexercise "recovery." The Ra response during the first 12 minutes of exercise was not different by repeated-measures ANOVA, reaching 10.6 +/- 1.3 mg/kg/min in C and 9.6 +/- 1.5 in Ph subjects at 12 minutes. However, in C subjects, Ra increased significantly to 14.1 +/- 1.2 mg/kg/min by exhaustion, and remained higher versus Ph subjects until 15 minutes of recovery. The Rd during recovery was not different between groups; thus, the higher Ra in C subjects in early recovery was responsible for the greater hyperglycemia observed in C subjects. Ph subjects showed a more rapid, marked increment (P = .002) in both plasma NE (to 64 v38 nmol/L) and EPI at exhaustion, and catecholamine concentrations remained higher in Ph versus C subjects during recovery. Whereas plasma insulin (IRI) declined in the C group, it increased 3-fold (P = .001) in the Ph group during exercise and until 15 minutes of recovery. Ph had no effect on glucagon (IRG). Thus, the glucagon to insulin ratio decreased in Ph subjects from baseline levels during exercise and early recovery, but increased in C subjects. The increase in Ra among Ph subjects despite the decrease in the glucagon to insulin ratio supports our earlier evidence that these hormones are not principal regulators of the Ra in intense exercise. The shorter time to exhaustion and markedly higher catecholamine levels in Ph subjects limited our ability to isolate the effects of alpha-adrenergic receptors on the Ra.alpha-Adrenergic receptors appear to have little influence on the Rd.
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PMID:Glucoregulation during and after intense exercise: effects of alpha-adrenergic blockade. 1072 19

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