Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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 physiological significance of the hyperglucagonemia that occurs in patients with many catabolic conditions is unclear. The effect of hyperglucagonemia on resting metabolic rate (RMR) was studied in six normal subjects. Infusion of somatostatin (SRIH; 500 micrograms/h for 210 min) resulted in a 5-fold decrease in plasma C-peptide and a 2-fold decrease in plasma insulin and glucagon concentrations, but did not change RMR significantly. When glucagon (0.2 micrograms/kg X h), was infused with SRIH (500 micrograms/h for 210 min), the decreases in plasma C-peptide and insulin were similar to that during the infusion of SRIH alone, but plasma glucagon increased from 160 +/- 24 (+/- SEM) to 560 +/- 80 pg/mL (P less than 0.001). There was a significant increase in RMR during the entire period (210 min) of glucagon infusion (P less than 0.01). During the last hour of the glucagon plus SRIH infusion, the RMR was 1.38 +/- 0.10 Cal/min, which was 15% higher than the preinfusion RMR (1.19 +/- 0.10 Cal/min; P less than 0.01) and 14% higher than the RMR during the same period when SRIH alone was infused (1.21 +/- 0.11 Cal/min; P less than 0.01). When SRIH and glucagon were infused, protein oxidation (calculated from urinary nitrogen loss) was 52 +/- 5 mg/min, 29% higher than when SRIH alone was infused (40 +/- 5 mg/min; P less than 0.05). These results indicate that hyperglucagonemia during insulin deficiency results in an increase in energy expenditure, which may contribute to the catabolic state in many conditions.
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PMID:Hyperglucagonemia increases resting metabolic rate in man during insulin deficiency. 288 43

1. Liver glycogen levels and plasma levels of insulin and glucagon were measured in fed and in food- and water-deprived prairie dogs. 2. Liver glycogen values decreased from 45.5 to 12.4 mg/g (73%) after 21 days of food and water deprivation, while a 24-hr fast resulted in a liver glycogen value of 47.5 mg/g. 3. Rat liver glycogen values decreased from 45.6 to 2.3 mg/g (95%) after a 24-hr fast. 4. Prairie dog plasma insulin values were 69.2, 15.8 and 25.4 microU/ml in fed, and in 24-hr and 32-day food- and water-deprived animals, respectively. 5. Prairie dog plasma glucagon levels were 57.0 and 38.4 microU/ml in fed and in 32-day food- and water-deprived animals. 6. Plasma values for glucose, urea nitrogen, acetone and triglyceride agreed with previously published results. 7. We conclude that it is possible that the maintenance of liver glycogen levels in food- and water-deprived prairie dogs may be correlated with a smaller decrease in plasma insulin levels, relative to other species, and with a decrease in plasma glucagon levels.
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PMID:Liver glycogen and plasma insulin and glucagon levels in food- and water-deprived black-tailed prairie dogs (Cynomys ludovicianus). 289 10

Crude fresh membranes from rat liver and membranes from rat heart obtained according to Snyder and Drummond were tested for adenylate cyclase activation by glucagon (Gn) and seven glucagon analogs including (Ala2)-, (Arg12)-, (Des-His1, Arg12), (Phe1, Arg12)-, (N-Ac-His1, Arg12)-, (1-Me-His1, Arg12)-, and (3-Me-His1, Arg12)-glucagon. (Des-His1, Arg12)-glucagon acted as a competitive antagonist in heart membranes and as a partial agonist in liver membranes. Results obtained with analogs where His1 was modified suggest that the size of the imidazole ring and the charge of its nitrogen 1, but not the charge of the free amino group of histidine, played a major role in biological activity. When comparing functional glucagon receptors in liver and heart membranes, it appears that the first receptors were more sensitive to the hormone and more efficiently coupled to adenylate cyclase.
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PMID:Comparative efficacy of seven synthetic glucagon analogs, modified in position 1, 2 and/or 12, on liver and heart adenylate cyclase from rat. 301 88

Rats weighing 220 g were injected sc with zinc protamin glucagon 20 micrograms once daily (recurrent hyperglucagonemia) and zinc protamin glucagon 60 micrograms three times daily (chronic hyperglucagonemia); the controls received the vehicle three times daily. In the first group blood glucagon rose to above 200 ng/liter for 5 h every day; in the second group it constantly stayed above 600 ng/liter. After both 2 (n = 5) and 14 (n = 5) days treatment the control total blood alpha-amino-nitrogen (AAN) concentration was 4.3 +/- 0.1 mmol/liter, and the urea nitrogen synthesis rate was 4.9 +/- 0.4 mumol/(min.100 g BW) (mean +/- SEM) in controls. In recurrent hyperglucagonemic rats, treated for both 2 (n = 5) and 14 (n = 5) days, total AAN was 3.6 +/- 0.2 mmol/liter (P less than 0.05 vs. control) and urea nitrogen synthesis rate 4.5 +/- 0.8 mumol/(min.100 g BW). In chronic hyperglucagonemic, treated for both 2 (n = 5) and 14 (n = 5) days, total AAN was 2.2 +/- 0.1 mmol/liter (P less than 0.05 vs. control) and UNSR 7.9 +/- 0.8 mumol/(min.100g BW) (P less than 0.05 vs. control). The urea excretion was identical in controls and during recurrent hyperglucagonemia, but it was increased by 50% during chronic hyperglucagonemia. Food intake was the same in all groups. N Balances decreased from 10 mmol/24 h to 5 mmol/24 h (P less than 0.05) by chronic hyperglucagonemia. The total organ N content did not change by recurrent hyperglucagonemia, but in chronic hyperglucagonemia it decreased to 65-85% (P less than 0.01) in carcass, intestines, liver, and kidneys. In conclusion chronic but not recurrent hyperglucagonemia increases the rate of urea synthesis and decreases the blood amino acid concentration. This is suggested to be a reason for the loss of N from organs by chronic hyperglucagonemia.
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PMID:Loss of nitrogen from organs in rats induced by exogenous glucagon. 304 48

We previously have shown that ingested beef protein is just as potent as glucose in stimulating a rise in insulin concentration in type II diabetic patients. A synergistic effect was seen when given with glucose. Therefore, we considered it important to determine if other common dietary proteins also strongly stimulate an increase in insulin concentration when given with glucose. Seventeen type II (non-insulin-dependent) untreated diabetic subjects were given single breakfast meals consisting of 50 g glucose, or 50 g glucose plus 25 g protein in the form of lean beef, turkey, gelatin, egg white, cottage cheese, fish, or soy. The peripheral plasma concentrations of glucose, insulin, glucagon, alpha amino nitrogen, urea nitrogen, free fatty acids, and triglycerides were measured. Following ingestion of the meals containing protein, the plasma insulin concentration was increased further and remained elevated longer compared with the meal containing glucose alone. The relative area under the insulin response curve was greatest following ingestion of the meal containing cottage cheese (360%) and was least with egg white (190%) compared with that following glucose alone (100%). The glucose response was diminished following ingestion of the meals containing protein with the exception of the egg white meals. The peripheral glucagon concentration was decreased following ingestion of glucose alone and increased following all the meals containing protein. The alpha amino nitrogen concentration varied considerably. It was decreased after glucose alone, was unchanged after egg white ingestion, and was greatest after ingestion of gelatin. The free fatty acid concentration decrease was 4- to 8-fold greater after the ingestion of protein with glucose compared with ingestion of glucose alone.
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PMID:The insulin and glucose responses to meals of glucose plus various proteins in type II diabetic subjects. 305 32

Phosphorus is the sixth most abundant element in the body after oxygen, hydrogen, carbon, nitrogen, and calcium. It comprises about 1% of the total body weight of humans. Eighty-five percent of it is stored in the bone in the form of hydroxyapatite crystal; 14% is in the soft tissues in the form of energy-storing bonds with nucleotides (ATP, GTP), nucleic acids in chromosomes and ribosomes, 2,3-DPG in the red blood cells, and phospholipids in the cells' membranes. Less than 1% is in the extracellular fluids. Phosphate balance is maintained by multiple systems. The gut is responsible for the absorption of two thirds of the 4-30 mg/kg/day of phosphate intake. Absorption sites are all along the gut; in humans the most active site is the jejunum. The kidney filters 90% of the plasma phosphate and reabsorbs it in the tubuli. In states of hypophosphatemia the kidney can reabsorb the filtered phosphates very efficiently, reducing the amount excreted in the urine virtually to zero. The healthy kidney can excrete high loads of phosphate and rid the body of phosphate overload. Through the vitamin D-PTH axis the endocrine system regulates the phosphate balance by influencing the kidney, gut, and bone. Other hormones, including thyroid, insulin, glucagon, glucocorticosteroid, and thyrocalcitonin, play a lesser role in regulation of phosphate metabolism. Because of the complex control of phosphate homeostasis, various clinical conditions may lead to hypophosphatemia. These include nutritional repletion, gastrointestinal malabsorption, use of phosphate binders, starvation, diabetes mellitus, and increased urinary losses due to tubular dysfunction. The clinical picture of phosphate depletion is manifested in different organs and is due mainly to the fall in intracellular levels of ATP and decreased availability of oxygen to the tissues, secondary to 2,3-DPG depletion. The various manifestations of phosphate depletion are listed in Table 2. The treatment of hypophosphatemia consists of administering enteral or parenteral phosphate salts. An important aspect of dealing with the potentially serious effects of phosphate depletion is to prevent the depletion from happening in the first place. Hyperphosphatemia can occur in renal failure, hemolysis, tumor lysis syndrome, and rhabdomyolysis. The treatment of hyperphosphatemia usually consists of fluid administration (in the absence of kidney failure). In chronic hyperphosphatemia, phosphate binders such as aluminum and magnesium salts can reduce the phosphate load. The use of these phosphate binders is limited by their potential side effects.
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PMID:Consequences of phosphate imbalance. 306 Jan 61

To see what effect intraluminal amino acids would have on glicentin secretion, we put a mixture of 10 amino acids (1 g/kg) into the duodenum of five normal, conscious piglets. Their plasma nitrogen rose, as did insulin and glucagon measured with C-terminal-specific antiserum. Plasma total immunoreactive glucagon, determined with non-specific antiserum, rose from 2753 +/- 460 pg/ml to a peak of 4434 +/- 1352 pg/ml at 30 min. Plasma glicentin, determined with R 64 antiserum, rose from a fasting level of 297 +/- 70 pmol/l to a peak of 702 +/- 167 pmol/l at 45 min. We also gave oral arginine to 6 pancreatectomized dogs to investigate why the plasma glicentin rises after amino acid ingestion. Arginine raised the plasma total immunoreactive glucagon from 1120 +/- 214 pg/ml to a peak of 2266 +/- 512 pg/ml at 45 min. We conclude that intraluminally administered amino acids enhance glicentin secretion from the gut.
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PMID:Effect of intraluminal administration of amino acids upon plasma glicentin. 306 8

In order to study the effect of hyperglucagonaemia on nitrogen metabolism in diabetes, zinc protamine glucagon 60 micrograms was injected subcutaneously 3 times daily for 4 weeks into streptozotocin diabetic rats (n = 5), adequately treated with long acting insulin. This raised the plasma concentration of glucagon to 725 +/- 125 (mean +/- SEM), which is not different from that found in portal blood of uncontrolled diabetic rats: 400 +/- 75 ng/l. The controls were 5 diabetic rats treated with insulin alone and 5 non-diabetic rats. Compared with control rats the nitrogen balance was reduced (p less than 0.05) and the nitrogen contents of carcass, heart, intestines, and kidneys were reduced by 15-30% (p less than 0.05) in the glucagon treated rats. The hepatic capacity of urea synthesis and the alanine elimination rate were determined in the 3 above-mentioned groups, and confirmed in 3 identical groups followed for only 2 weeks; and in addition in a group of glucagon treated diabetic rats, where the long acting glucagon was substituted by neutral insulin the last two days before investigation.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Exogenous hyperglucagonaemia in insulin controlled diabetic rats increases urea excretion and nitrogen loss from organs. 306 29

The existence of a co-ordinated response to stress of a variety of causes has clearly been established. Basically, this consists of an elevation in energy expenditure and an increased breakdown of skeletal muscle protein. In addition, glucose level in the plasma increases as a result of increased synthesis and decreased uptake of glucose into cells. Release of fatty acid into the plasma is also increased, and an elevation in the proportion of energy derived from oxidation of fatty acids is observed. This response is qualitatively very different from that seen in simple starvation, where a progressive reduction in energy expenditure and a reduction in the synthesis of glucose allows fat to become the major energy-producing substrate and also allows sparing of body protein stores. The mechanisms responsible for this altered pattern of metabolism are probably primarily hormonal in nature, with adrenaline, cortisol and glucagon being the major catabolic stimulants. Some evidence exists, however, for alteration in intracellular pathway metabolism. Within the past decade a new class of mediators of the stress response, the cytokines, has been recognized. These substances are protein products of circulating monocytes and the way in which they integrate into the control of the stress response has not been completely elucidated. At present there is evidence that they can stimulate production of catabolic hormones, and also they may well have direct effects in enhancing protein catabolism in muscle. At present the main method for modification of the stress response remains the provision of energy and amino acid, either intravenously or enterally. In the present state of our knowledge, 30-40 kcal kg-1 day-1 would appear to be adequate for most patients, with half provided as fat. Amino acids 3 g kg-1 day-1 will provide adequate nitrogen. It must be said, however, that the most effective method of modifying the stress response is removal of the source of stress by surgery, antibiotics or other primary therapy.
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PMID:The metabolic and nutritional effects of injury and sepsis. 307 81

Several new problems in obesitology were pointed out in this book and commented with respect to experiments and experiences of our working group. The problem of the low triiodothyronine (T3) syndrome was treated in chapter 2. The decrease of serum T3 and increase of serum reverse T3 in obese subjects was induced by several factors, namely by fasting. A resistance to administered thyroxine and triiodothyronine was observed in these patients. This energy saving mechanism is at variance with slimming regimens. The prevention and treatment of this awkward complication was discussed. The next chapter (3) is concerned with the hormonal and metabolic effects of diet and motor activity in the course of slimming regimens. The different effects of diet and motor activity on epinephrine and norepinephrine in obese subjects were similar to those obtained by other investigators in nonobese humans. A great importance was attributed to an increased plasma level of cortisol in obese and nonobese subjects in the course of different forms of motor activity and related to a different intensity of exercise. Parallel to several of these experiments, beta-endorphin, thyroid hormones and glucagon were also estimated. It was suggested that motor activity for exercising subjects should not lead to an enhanced secretion of cortisol in view of the health deteriorating effects of increased cortisolemia and in view of an already stimulated secretion of this hormone in obese subjects on basal conditions. Vice versa, a decreased cortisolemia should be obtained in obese subjects treated with an appropriate motor activity and diet. It has been shown that diet without motor activity reduced the level of plasma androgens but in cooperation with motor activity, the level of androgens remained unaltered in the course of the reducing regimen. The conservation of a normal or even higher level of androgens is probably prerequisite for a positive nitrogen balance observed in the course of a combined slimming regimen, while diet without motor activity led in the studied conditions to a negative nitrogen balance. Chapter 4 was devoted to the role of motor activity in slimming regimens. In view of the metabolic effects of motor activity and the clinical late effects of obesity (osteoarthritis of the knees, hips and spine, arterial hypertension, overload of the cardiovascular system, diabetes mellitus etc.), a selection of motor activities was proposed. According to our long experience, we do not recommend jogging, running, jumping and all sports leading to collisions of players.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:New trends in obesitology. 307 25


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