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)

In healthy subjects intravenous glucagon administration induces a prompt (at 1 h) fall in serum T3 concentration and a later (at 4 h) rise in biologically inactive rT3. Since high levels of plasma glucagon have frequently been found in some patients with severe chronic illnesses, together with an anomalous thyroid condition (low serum T3, high serum rT3), it has been supposed that hyperglucagonemia could play a pathogenetic role in causing selective T3 deficiency. In the present study fasting plasma glucagon concentration was measured in 48 patients with low T3 and severe nonthyroidal illnesses: hepatic cirrhosis in 16 cases, chronic non-A non-B hepatitis in 4 cases, uncontrolled type II diabetes mellitus in 5 cases, renal failure in 12 cases, congestive heart failure in 5 cases, tumor in 16 cases. In comparison with a group of 21 healthy controls fasting plasma glucagon concentration was significantly higher in the patients (198.75 +/- 13.20 pg/ml vs. 127 +/- 6.80 pg/ml; p less than 0.001). However, only 29 patients (60.4%) had elevated plasma glucagon levels, whereas 19 (39.5%) had abnormal plasma glucagon levels. Furthermore, no significant difference was found between the thyroid hormone pattern of the patients with hyperglucagonemia and of the patients with normal glucagonemia. On the other hand, a significant correlation between plasma glucagon concentrations and serum T3 and rT3 concentrations was not found. All these findings indicate that in patients with severe chronic illnesses the fall in circulating T3 cannot be due to hyperglucagonemia only which, therefore, might simply be a contributory factor together with other as yet unidentified disorders.
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PMID:[Role of high blood glucagon in the reduction of serum levels of triiodothyronine in severe non-thyroid diseases]. 263 98

Hypoglycemia associated with renal failure is more common than generally thought. Its occurrence is often a marker of multisystem failure and has an ominous prognostic implication. Its pathogenesis is frequently complex and involves one or several mechanisms. In the evaluation of uremic hypoglycemia, the first step should be the exclusion of obvious causes such as insulin, oral hypoglycemic agent therapy, and the use of drugs known to cause hypoglycemia. Propranolol, salicylates, and disopyramide are among the most commonly implicated agents. Additional triggering events are alcohol consumption, sepsis, chronic malnutrition, acute caloric deprivation, concomitant liver disease, congestive heart failure, and an associated endocrine deficiency. When no obvious cause can be demonstrated, the hypoglycemia is referred to as spontaneous. Spontaneous uremic hypoglycemia has been attributed to deficiency of precursors of gluconeogenesis, that is, alanine, deficient gluconeogenesis, impaired glycogenolysis, diminished renal gluconeogenesis and impaired renal insulin degradation and clearance, poor nutrition, and, in a few cases, deficiency in an immediate counterregulatory hormone such as catecholamine and glucagon. However, the mechanism(s) seems to differ from one patient to the other. Dialysis also predisposes to hypoglycemia in uremia, possibly because of the chronic state of malnutrition. Postdialysis hypoglycemia is secondary to glucose-induced hyperinsulinemia, which is caused by the high glucose content in the dialysate. In uremic hypoglycemia, neuroglycopenic manifestations predominate because of frequent autonomic nervous system dysfunction and lack of catecholamine release in response to hypoglycemia. Its severity and duration are variable. Hypoglycemia should be suspected in any patient with renal failure who exhibits any change in mental or neurologic status. Detection of hypoglycemia should rely on frequent and careful glucose determinations in any patient with uremia.
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PMID:Hypoglycemia associated with renal failure. 264 22

A 36-year-old man with ankylosing spondylitis, amyloidosis and chronic renal failure on maintenance hemodialysis developed severe hypoglycemia while being treated with propoxyphene. Upon discontinuation of the drug blood glucose levels returned to normal and hypoglycemia did not recur. Simultaneously with hypoglycemia, plasma glucagon and growth hormone levels were appropriately raised and serum insulin levels were adequately suppressed, thus ruling out hyperinsulinemia as the cause of hypoglycemia. A review of the literature disclosed four similar cases of propoxyphene-induced hypoglycemia, two of them with renal dysfunction. Propoxyphene should be remembered as a potential cause of hypoglycemia, particularly in patients with renal failure.
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PMID:Propoxyphene-induced hypoglycemia in a patient with chronic renal failure. 279 48

Derangements in leukocyte function occur in patients with primary hyperparathyroidism and in those with uremia, which is a state of secondary hyperparathyroidism, suggesting that parathyroid hormone (PTH) may affect leukocyte function. We examined the interaction between PTH and random migration of human polymorphonuclear leukocytes (PMNL) utilizing a modified Boyden chamber. Intact 1-84 PTH but not its amino-terminal (1-34 PTH) or its carboxy-terminal (53-84 PTH) fragments produced marked and significant (p less than 0.01) stimulation of random migration in a dose-dependent manner. Inactivation of 1-84 PTH abolished its effect and other peptide hormones (calcitonin, glucagon, insulin and vasopressin) did not stimulate migration of PMNL. The effect of PTH on migration was not due to action of the hormone on chemotaxis. PTH did not enhance cAMP or cGMP production by PMNL. The stimulation of PMNL motility by PTH was independent of calcium concentration in media, was not mimicked by calcium ionophore and was not blocked by verapamil. Quinidine also produced significant (p less than 0.01) increase in random migration of PMNL and this effect was not additive to that of PTH. Prolonged exposure to PTH (16-20 h) was associated with significant inhibition of random migration of PMNL. The migration of PMNL from patients with advanced renal failure was significantly (p less than 0.01) reduced and there was a significant (p less than 0.01) inverse relationship between random migration of PMNL and serum levels of PTH. Also PTH produced only modest stimulation of random migration of PMNL in most patients with renal failure.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effect of parathyroid hormone on random migration of human polymorphonuclear leukocytes. 285 73

The glucagonoma syndrome is characterized by a necrolytic migratory erythematous rash, angular stomatitis, painful glossitis, a normochromic normocytic anemia, mild diabetes mellitus, weight loss, a tendency to thrombosis, and neuropsychiatric disturbances. The diagnosis is made by finding a high plasma glucagon concentration in the absence of any other cause, such as renal failure or severe stress. A pancreatic alpha-cell tumor can be identified and stained by immunocytochemistry with glucagon antibodies. Optimal treatment is surgical removal, but approximately 50 percent of the tumors have metastasized by the time of diagnosis. Since the tumor is slow-growing, remission can be obtained by hepatic artery embolization to shrink hepatic secondaries or by shrinkage, in about 10 percent of patients, with the combination chemotherapeutic regimen of 5-fluorouracil and streptozotocin. The rash frequently responds to administration of zinc, a high-protein diet, and control of the diabetes with insulin. Alongside the alpha cell in the islets of Langerhans is the D-cell, which produces somatostatin and may well act physiologically as a paracrine inhibitor of glucagon release. A newly developed, long-acting somatostatin analogue, SMS 201-995, which the patient can self-administer as a subcutaneous injection, has proven effective in suppressing glucagon secretion from glucagonomas and, in some cases, causing remission of clinical symptoms.
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PMID:Glucagonoma syndrome. 288 77

In 72 patients with end-stage renal failure and 70 healthy subjects, the influence of blockade of opioid receptors by naloxone on secretion of prolactin, lutropin (LH), follitropin (FSH), adrenocorticotropin (ACTH), somatotropin (HGH), insulin (IRI), glucagon (IR-G), parathyroid hormone (PTH) and calcitonin (CT) was studied. Administration of naloxone stimulated luliberin-induced LH and FSH secretion quantitatively equally in patients and controls. Blockade of opioid receptors was followed by a less marked suppression of chlorpromazine-induced prolactin secretion but by a higher response of hypoglycemia-induced ACTH secretion in uremic patients than in controls. In addition, a less marked suppressive effect of naloxone was noted on hypoglycemia-induced HGH secretion in chronic renal failure as compared with controls. Blockade of opioid receptors improved significantly glucose tolerance and glucose-induced insulin secretion in uremic patients and suppressed nearly completely glucagon secretion response during the second phase of a glucose tolerance test. Finally, administration of naloxone was followed by a blunted response of Ca-induced CT secretion and suppression of PTH. Data presented in this paper suggest the existence of hyperendorphinism in end-stage renal failure.
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PMID:Effects of naloxone administration on endocrine abnormalities in chronic renal failure. 303 7

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

Forty percent of patients with insulin-dependent diabetes will develop nephropathy during the course of their disease, thus being the most important single disorder leading to end-stage renal failure (ESRF). Intensive metabolic control delays onset of diabetic nephropathy, the first omen of which is appearance of subclinical albuminuria, also termed microalbuminuria. Moreover, it is now established that intensive treatment of hypertension reduces rate of decline in GFR and thus postpones ESRF. When uremia eventually sets in, a range of biochemical and endocrine abnormalities can be included among those characteristics of diabetes mellitus per se. These include elevated plasma levels of growth hormone, glucagon and free fatty acids, which may participate in the uremic insulin resistance superimposed on the preexisting diabetic carbohydrate intolerance. Hemodialysis (HD) and continuous ambulatory peritoneal dialysis (CAPD) are two established modalities of renal replacement therapy in diabetes mellitus. Controlled clinical trials for comparison of CAPD versus HD treatment of diabetics are, however, still needed. The survival rate is approximately 80 and 65-95% in insulin-dependent diabetic patients at 1 year during treatment with HD and CAPD, respectively. However, it is general experience that diabetics on CAPD exhibit a glycemic control, superior to that attained during HD. It has not been proved that patient survival after cadaveric renal transplantation is better than on dialysis. The degree of vascular heart disease seems to be the major determinant for survival of kidney-transplanted diabetic patients.
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PMID:End-state renal failure in diabetic nephropathy: pathophysiology and treatment. 391 47

The aim of the present study was to evaluate the insulin and glucagon responses to various stimuli in patients following pancreatic transplantation. Four Type 1 (insulin-dependent) diabetic patients with end-stage renal failure who had received a cadaveric segmental, neoprene-injected, pancreas transplant, in association with kidney transplantation, were investigated. Free-insulin, pancreatic glucagon, and growth hormone concentrations were measured after both oral and intravenous glucose tolerance tests, and following tolbutamide, arginine and arginine plus somatostatin infusions. Tests were performed 1 month (three cases) and 30 months (one case) after surgery, when no insulin administration was required. Four non-diabetic kidney grafted patients, matched for duration of graft survival and immunosuppressive treatment (steroids, azathioprine and anti-lymphocyte-globulins), served as control subjects. Impaired glucose tolerance was present in all diabetic and control patients. This was possibly related to immunosuppressive treatment. In comparison with control subjects, insulin release was normal in response to arginine and tolbutamide but was reduced in response to oral and intravenous glucose, while glucagon and growth hormone release were similar in both groups. Somatostatin was less effective in diabetic patients than in control subjects in suppressing insulin and glucagon release.
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PMID:Endocrine responses of type 1 (insulin-dependent) diabetic patients following successful pancreas transplantation. 613 51

The role of glucagon in the pathogenesis of abnormalities of glucose metabolism associated with renal failure remains undefined. We have evaluated glucagon-stimulated glucose and cyclic AMP output and amino acid uptake in isolated perfused livers of rats with experimentally-induced ARF and sham-operated controls. ARF animals exhibited azotemia, hyperglycemia, hyperinsulinemia, and hyperglucagonemia. During stimulation with physiologic (3 X 10-10M) or supraphysiologic (3 X 10-8M) glucagon concentrations, glucose output was lower in livers of ARF rats than in those of controls, whereas cyclic AMP responses were similar or exceeded those of controls. Hepatic glycogen content was lower in rats with ARF and the stores were exhausted at the end of perfusions. Additional studies in livers of fasted animals revealed no significant differences in glucose output or amino acid uptake between ARF and control livers perfused with physiologic levels of glucagon. These experiments suggest that the decreased glucagon-stimulated glucose output in isolated perfused livers in acutely uremic rats is due primarily to glycogen depletion rather than to impaired gluconeogenesis. Normal or increased cyclic AMP responses to glucagon suggests intactness of the hormone receptor-adenylate cyclase.
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PMID:Impaired glucagon-stimulated glucose output in livers of acutely uremic rats. 627 48


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