UMLS:C0028754 - FACTA Search

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Query: UMLS:C0028754 (obesity)
124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Rates of absorption of leucine, glycylleucine, and glucose, and rates of hydrolysis of maltose were determined in the jejunum of a group of obese persons before and at intervals (between 2 and 20 montsh) after jejunoileal bypass for the treatment of obesity. The leucine absorption rate was significantly reduced after the bypass, but the absorption rates of glycylleucine and glucose as well as the hydrolysis rate of maltose were unchanged. Light microscopic investigation of the jejunal mucosa, obtained by a peroral biopsy technique before and at 7 months after by bypass operation, did not reveal any change in the histological appearance of this tissue. The plasma aminograms of all 7 patients were compared before and at intervals after the bypass operation; all exhibited a constant pattern of change that was characterized by significant decreases in the concentrations of serine and glycine and by significant decreases in the concentrations of valine, isoleucine, leucine, tyrosine, and phenylalanine. This pattern of change, which is characteristic of protein depletion, persisted during the entire period of observation. Two of these 7 patients developed laboratory evidence of hepatic dysfunction. It is concluded that (1) protein depletion is common to all patients with jejunoileal bypass with or without hepatic dysfunction; and (2) protein depletion results in a sustained reduction in free amino acid absorption in the jejunum.
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PMID:Absorptive and digestive function of the jejunum after jejunoileal bypass for treatment of human obesity. 96 65

The entry of glucose into muscle cells is achieved primarily via a carrier-mediated system consisting of protein transport molecules. GLUT-1 transporter isoform is normally found in the sarcolemmal (SL) membrane and is thought to be involved in glucose transport under basal conditions. With insulin stimulation, glucose transport is accelerated by translocating GLUT-4 transporters from an intracellular pool out to the T-tubule and SL membranes. Activation of transporters to increase the turnover number may also be involved, but the evidence is far from conclusive. When insulin binds to its receptor, it autophosphorylates tyrosine and serine residues on the beta-subunit of the receptor. The tyrosine residues are thought to activate tyrosine kinases, which in turn phosphorylate/activate as yet unknown second messengers. Insulin receptor antibodies, however, have been reported to increase glucose transport without increasing kinase activity. Insulin resistance in skeletal muscle is a major characteristic of obesity and diabetes mellitus, especially NIDDM. A decrease in the number of insulin receptors and the ability of insulin to activate receptor tyrosine kinase has been documented in muscle from NIDDM patients. Most studies report no change in the intracellular pool of GLUT-4 transporters available for translocation to the SL. Both the quality and quantity of food consumed can regulate insulin sensitivity. A high-fat, refined sugar diet, similar to the typical U.S. diet, causes insulin resistance when compared with a low-fat, complex-carbohydrate diet. On the other hand, exercise increases insulin sensitivity. After an acute bout of exercise, glucose transport in muscle increases to the same level as with maximum insulin stimulation. Although the number of GLUT-4 transporters in the sarcolemma increases with exercise, neither insulin or its receptor is involved. After an initial acute phase, which may involve calcium as the activator, a secondary phase of increased insulin sensitivity can last for up to a day after exercise. The mechanism responsible for the increased insulin sensitivity with exercise is unknown. Regular exercise training also increases insulin sensitivity, which can be documented several days after the final bout of exercise, and again the mechanism is unknown. An increase in the muscle content of GLUT-4 transporters with training has recently been reported. Even though significant progress has been made in the past few years in understanding glucose transport in skeletal muscle, the mechanisms involved in regulating transport are far from being understood.
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PMID:Regulation of glucose transport in skeletal muscle. 142 62

The effect of okadaic acid, an inhibitor of protein phosphatases-1 and -2A, was studied on glucose transport and metabolism in soleus muscles isolated from lean and insulin-resistant obese mice. In muscles from lean mice, the uptake of 2-deoxyglucose, an index of glucose transport and phosphorylation, was increased by okadaic acid in a concentration-dependent manner. At 5 microM, okadaic acid was as efficient as a maximally effective insulin concentration. Glucose metabolism (glycolysis and glycogen synthesis) was also measured. Whereas glycolysis was stimulated by okadaic acid, glycogen synthesis was unchanged. When okadaic acid and insulin were added together in the incubation medium, the rates of glucose transport, glycolysis, and glycogen synthesis were similar to those obtained with insulin alone, whether maximal or submaximal insulin concentrations were used. Furthermore, okadaic acid did not activate the kinase activity of the insulin receptor studied in an acellular system or in intact muscles. These results indicate that a step in the insulin-induced stimulation of muscle glucose transport involves a serine/threonine phosphorylation event that is regulated by protein phosphatases-1 and/or -2A. In muscles of insulin-resistant obese mice, the absolute values of deoxyglucose uptake stimulated by okadaic acid were lower than in muscles from lean mice. However, the okadaic acid effect, expressed as a fold stimulation, was normal. These observations suggest that in the insulin-resistant state linked to obesity, the serine/threonine phosphorylation event is likely occurring normally, but a defect at the level of the glucose transporter itself would prevent a normal response to insulin or okadaic acid.
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PMID:Effects of okadaic acid, an inhibitor of protein phosphatases-1 and -2A, on glucose transport and metabolism in skeletal muscle. 184 12

Tetrahydrolipstatin (THL) is a selective inhibitor of fat absorption. In animal models, it has anti-obesity and anti-hypercholesterolemic activity and is presently in clinical trials for these indications. THL binds covalently to pancreatic lipase. Complete inhibition of lipolytic activity is obtained concomitant with the incorporation of 1 mol of THL/mol of enzyme. Pancreatic lipase is the best studied lipase, but published results concerning its catalytic mechanism are still controversial. In order to learn more about the inhibitory mechanism of THL, a selective lipase inhibitor interacting at or near the catalytic site, and therefore, to obtain more information on the catalytic mechanism of lipase, we have determined the amino acid residue to which THL is bound. After proteolytic degradation of porcine pancreatic lipase inhibited with radioactively labeled THL, the labeled peptides were isolated and analyzed by quantitative amino acid analysis, N-terminal sequencing, and by mass spectrometry with fast atom bombardment ionization. The data clearly show that THL is bound as an ester to the serine 152 of the lipase.
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PMID:The lipase inhibitor tetrahydrolipstatin binds covalently to the putative active site serine of pancreatic lipase. 189 34

Tumor necrosis factor-alpha (TNF) has been suggested to be the mediator of insulin resistance in infection, tumor cachexia, and obesity. We have previously shown that TNF diminishes insulin-induced tyrosine phosphorylation of insulin receptor substrate 1 (IRS-1). The current work examines potential mechanisms that mediate this event. TNF effect on IRS-1 in Fao hepatoma cells was not associated with a significant reduction in insulin receptor tyrosine kinase activity as measured in vitro but impaired the association of IRS-1 with phosphatidylinositol 3-kinase, localizing TNF impact to IRS-1. TNF did not increase protein-tyrosine phosphatase activity and protein-tyrosine phosphatase inhibition by vanadate did not change TNF effect on IRS-1 tyrosine phosphorylation, suggesting that protein-tyrosine phosphatases are not involved in this TNF effect. In contrast, TNF increased IRS-1 phosphorylation on serine residues, leading to a decrease in its electrophoretic mobility. TNF effect on IRS-1 tyrosine phosphorylation was not abolished by inhibiting protein kinase C using staurosporine, while inactivation of Ser/Thr phosphatases by calyculin A and okadaic acid mimicked it. Our data suggest that TNF induces serine phosphorylation of IRS-1 through inhibition of serine phosphatases or activation of serine kinases other than protein kinase C. This increased serine phosphorylation interferes with insulin-induced tyrosine phosphorylation of IRS-1 and impairs insulin action.
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PMID:Tumor necrosis factor alpha-induced phosphorylation of insulin receptor substrate-1 (IRS-1). Possible mechanism for suppression of insulin-stimulated tyrosine phosphorylation of IRS-1. 755 52

The insulin resistance of skeletal muscle plays an important role in the pathogenesis of the metabolic endocrine syndrome and diabetes mellitus Type II. Impairment of the signal transmission from the insulin receptor to glycogen synthase and the glucose transport system was shown in insulin resistant subjects. A reduced receptor activation contributes also to insulin resistance. We investigated the mechanisms of modulation of receptor function in isolated cell systems which are transfected with human insulin receptor. Action of TNF alpha and acute hyperglycaemic effects were studied in particular. Acute hyperglycaemia gives rise, in the isolated cell system, to inhibition of the tyrosine kinase activity of the insulin receptor within a few minutes. This inhibitory effect seems to be mediated by translocation and activation of various isoforms of protein kinase C. Activation of protein kinase C probably leads to phosphorylation of the beta-subunit of the insulin receptor at serine residues. The domains of the insulin receptor, which are responsible for the inhibitory effect of hyperglycaemia do not seem to be localized either in the C terminus or in the juxtamembranary region of the insulin receptor. The hyperglycaemic effect can be antagonized in the isolated cell system both by protein kinase C inhibitors and so-called insulin sensitizers such as thiazolidindiones. Similar inhibitory effects, as induced by hyperglycaemia, can also be mediated by administration of the cytokine TNF alpha. As TNF alpha is probably increasingly expressed in obesity, the modulation of receptor kinase activity by TNF alpha could be an important factor for insulin resistance in obesity.
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PMID:Pathogenesis of insulin resistance: modulation of the insulin signal at receptor level. 852 11

Tumor necrosis factor-alpha (TNF-alpha) is an important mediator of insulin resistance in obesity and diabetes through its ability to decrease the tyrosine kinase activity of the insulin receptor (IR). Treatment of cultured murine adipocytes with TNF-alpha was shown to induce serine phosphorylation of insulin receptor substrate 1 (IRS-1) and convert IRS-1 into an inhibitor of the IR tyrosine kinase activity in vitro. Myeloid 32D cells, which lack endogenous IRS-1, were resistant to TNF-alpha-mediated inhibition of IR signaling, whereas transfected 32D cells that express IRS-1 were very sensitive to this effect of TNF-alpha. An inhibitory form of IRS-1 was observed in muscle and fat tissues from obese rats. These results indicate that TNF-alpha induces insulin resistance through an unexpected action of IRS-1 to attenuate insulin receptor signaling.
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PMID:IRS-1-mediated inhibition of insulin receptor tyrosine kinase activity in TNF-alpha- and obesity-induced insulin resistance. 857 Nov 33

Tumor necrosis factor (TNF)-alpha plays a central role in the state of insulin resistance associated with obesity. It has previously been shown that one important mechanism by which TNF-alpha interferes with insulin signaling is through the serine phosphorylation of insulin receptor substrate-1 (IRS-1), which can then function as an inhibitor of the tyrosine kinase activity of the insulin receptor (IR). However, the receptors and the signaling pathway used by TNF-alpha that mediate the inhibition of IR activity are unknown. We show here that human TNF-alpha, which binds only to the murine p55 TNF receptor (TNFR), is as effective at inhibiting insulin-dependent tyrosine phosphorylation of IR and IRS-1 in adipocytes and myeloid 32D cells as murine TNF-alpha, which binds to both p55 TNFR and p75 TNFR. Likewise, antibodies that are specific agonists for p55 TNFR or p75 TNFR demonstrate that stimulation of p55 TNFR is sufficient to inhibit insulin signaling, though a small effect can also be seen with antibodies to p75 TNFR. Exogenous sphingomyelinase and ceramides, known to be formed by activation of p55 TNFR, inhibit IR and IRS-1 tyrosine phosphorylation and convert IRS-1 into an inhibitor of IR tyrosine kinase in vitro. Myeloid 32D cells expressing IR and IRS-1 are sensitive to this inhibition, but cells expressing IR and IRS-2 are resistant, pointing to an important difference in the biological function between IRS-1 and IRS-2. These data strongly suggest that TNF-alpha inhibits insulin signaling via stimulation of p55 TNFR and sphingomyelinase activity, which results in the production of an inhibitory form of IRS-1.
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PMID:Tumor necrosis factor (TNF)-alpha inhibits insulin signaling through stimulation of the p55 TNF receptor and activation of sphingomyelinase. 866 83

The hormone insulin remains the cornerstone of diabetic therapy since it is required for almost all cases of Type 1 and many cases of Type 2 diabetes. Since the discovery of insulin in 1921, much has been learned about its chemistry, structure and action as well as its production in the beta cell. Insulin is formed through a series of precursors, beginning with preproinsulin, the protein encoded in the insulin gene. These precursors direct the prohormone into the secretory pathway and ultimately into the secretory granules where it is converted into insulin and C-peptide. These products are stored and secreted together in a highly regulated manner in response to glucose and other stimuli. This review focuses on the recently discovered prohormone convertases, PC2 and PC3 (PC1), the enzymes responsible for the endoproteolytic processing of proinsulin to insulin and C-peptide in the beta cell as well as for the selective processing of proglucagon to glucagon in the alpha cell or GLP1 in intestinal L-cells. PC2 and PC3 are calcium-dependent serine proteases related to the bacterial enzyme subtilisin. They cleave selectively at Lys-Arg or Arg-Arg sites in precursors, generating products with C-terminal basic residues that are then removed by carboxypeptidase E, an exopeptidase. All 3 enzymes are expressed mainly in secretory granules of neuroendocrine cells throughout the body and in the brain. Inherited defects affecting the prohormone-processing enzymes have recently been found in association with unusual syndromes of obesity and other metabolic disorders.
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PMID:The role of prohormone convertases in insulin biosynthesis: evidence for inherited defects in their action in man and experimental animals. 879 89

Studies involving genetically and nutritionally induced diabetes in animals indicate that early hyperinsulinaemia is the causative factor of tissue insulin resistance, leading to compensatory insulin oversecretion and pancreatic beta-cell dysfunction. The models for this syndrome, which occurs in association with obesity (thus termed "diabesity" here), concern either species with a sturdy pancreas, capable of long-lasting oversecretion, or those with labile beta cells which cannot sustain the initial oversecretion due to genomic modifiers enhancing gluco- or lipotoxicity. Examples of the latter are db/db mice mutants and desert gerbils susceptible to overnutrition, i.e. Psammomys obesus (sand rats). The latter also comprise spiny mice (Acomys cahirinus) which do not manifest resistance. They are low insulin secretors and accumulate insulin in beta cells which may disintegrate, producing insulin-deficiency. P. obesus is characterised by low insulin-receptor density. On a high energy diet, the capacity of insulin to activate receptor tyrosine kinase (TK) is reduced, concomitant with hyperinsulinaemia. With subsequent hyperglycaemia, a vicious circle of insulinaemia-glycaemia accentuates TK activation failure. This is attributable to multisite phosphorylation, including serine and threonine on the receptor b-subunit, which are inhibitory to TK activity. The compromised TK activation is reversible by diet restriction and normoinsulinaemia restoration. Similar receptor TK malfunction is seen in other animal species with diabesity. Hyperinsulinaemia has also been shown to cause a variety of detrimental effects in vitro and in vivo. The beta-cell response to long-lasting stimulation and the receptor malfunction in diabesity have implications for a similar etiology in human insulin-resistance syndrome and non-insulin-dependent diabetes mellitus, particularly in populations emerging into nutritional abundance. It is postulated that the "thrifty gene" is focused on receptor TK, whose reduced function is the primary phenotypic expression of protracted hyperinsulinaemia.
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PMID:Development and consequences of insulin resistance: lessons from animals with hyperinsulinaemia. 879 92

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