Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0028754 (obesity)
124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To determine whether 1) insulin stimulates pyruvate dehydrogenase (PDH) and glycogen synthase (GS) in isolated human adipocytes and 2) adipocytes from subjects with obesity or noninsulin-dependent diabetes mellitus (NIDDM) are resistant to the effects of insulin, PDH and GS were assayed in adipocytes from 11 control, 8 obese, and 9 NIDDM subjects. Basal PDH activities were 123 +/- 20, 129 +/- 21, and 128 +/- 25 pmol pyruvate oxidized/min per 2 X 10(5) adipocytes in these groups. Insulin stimulated PDH activity to a maximum of 223 +/- 38 pmol/min per 2 X 10(5) in adipocytes from control subjects, but did not significantly increase values from obese subjects. Insulin significantly decreased PDH activity in cells from NIDDM subjects (99 +/- 20 pmol/min per 2 X 10(5) cells, P less than 0.05). PDH activity assayed with high magnesium and calcium concentrations was significantly stimulated by insulin in adipocytes from control, but not obese or NIDDM subjects. GS assayed with 1 mM glucose 6-phosphate did not differ significantly among control, obese, or NIDDM subjects (446 +/- 110, 451 +/- 156, and 291 +/- 35 pmol incorporated into glycogen, respectively). Insulin significantly stimulated glycogen synthase in all three groups (827 +/- 179, 764 +/- 177, and 569 +/- 51 pmol incorporated) to a similar extent. Glycogen synthase assayed with 10 mM glucose 6-phosphate was decreased in NIDDM (1,335 +/- 131 pmol incorporated) compared with obese or control subjects (2,512 +/- 451 and 2,239 +/- 230 pmol incorporated, respectively, P less than 0.01).
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PMID:Adipocyte glycogen synthase and pyruvate dehydrogenase in obese and type II diabetic subjects. 309 77

Obesity and diabetes are epidemic in the Pima Indians of Southwest United States. Recent evidence suggests that a reduced metabolic rate may predispose the obesity and, since metabolic rate appears to be familial, this may predispose to the familial dependence of obesity. Obesity is associated with an increased risk of diabetes. Insulin resistance is associated with obesity, but is also familial, independent of obesity. In this population insulin resistance is a risk factor for the development of diabetes. Diabetes occurs when insulin secretory failure is superimposed on insulin resistance. Reduced glucose storage in muscle, regulated by glycogen synthase, is important in determining insulin resistance especially at high plasma insulin concentrations and it is possible that a specific genetic defect may be the cause of this. Obesity has its major effect on insulin action at lower plasma insulin concentrations and we propose that this may in part be due to abnormalities of insulin action induced by an increased fat-free mass with a consequent enlargement of muscle cells, a reduced capillary supply, and reduced penetration of insulin into muscle in obese subjects. We propose therefore that insulin resistance may be due to a combination of a genetic defect and obesity-induced changes in the biophysical properties of skeletal muscle. These defects, by slightly increasing the plasma glucose concentration and inducing pancreatic glucose insensitivity, may in turn lead to the development of non-insulin-dependent diabetes mellitus.
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PMID:Insulin resistance in Pima Indians. A combined effect of genetic predisposition and obesity-related skeletal muscle cell hypertrophy. 313 99

The effects of obesity, weight reduction, and physical condition on the concentrations of glucose-6-phosphate (G-6-P) and glycogen, and the activities of glycogen synthase (GS) and lactate dehydrogenase (LD) were determined in resting vastus or gastrocnemius muscles of 40 healthy subjects. In obese women the activity of GS was 50% (P less than 0.05) lower than in lean women with similar levels of glycogen and G-6-P, whereas no difference was found in the activity of LD. Calorie restriction induced a 4.5% (P less than 0.05) decrease in body weight from 82.5 kg corresponding to a 3.2% (P less than 0.05) decrease in body mass index from 30.9 kg m-2. The total and fractional activities of glycogen synthase were increased by 50% (P less than 0.05), whereas muscle glycogen content was reduced by 40% (P less than 0.05). The G-6-P concentration and the activity of LD remained unchanged. In well-trained young men the concentrations of G-6-P and glycogen were, respectively, 250% (P less than 0.05) and 50% (P less than 0.05) higher than in non-trained. The fractional and total activities of GS were 90% (P less than 0.05) and 50% (P less than 0.05) higher, respectively, and the total activity of LD was only half (P less than 0.05) that of non-trained subjects. In conclusion, physical training enhances the activity of GS, despite a concomitantly increased glycogen content, and thus seems to exert a more efficient stimulus on glycogen synthase than weight reduction. It is indicated that physical training may provide a clinically important contribution to blood glucose reduction in hyperglycaemic conditions.
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PMID:Glycogen and lactate synthetic pathways in human skeletal muscle in relation to obesity, weight reduction and physical training. 313 28

Skeletal muscle sensitivity and responsiveness to insulin and their relationship to overall glucose disposal and insulin binding were determined in 89 premenopausal women of varying body fat topography (waist/hips girth ratio [WHR] 0.64-1.02) and obesity level (percentage of ideal body weight 92-230). As a marker of insulin action, the percentage of total glycogen synthase present in the I form (glucose-6-phosphate independent) was measured in quadriceps muscle biopsies. The increase in percentage of synthase I 1 h after oral glucose loading was not significantly different between nonobese and obese weight-matched subgroups of increasing WHR, but this response was maintained at the expense of increasing plasma insulin levels as the WHR rose. The increase in percentage of synthase I in response to submaximal steady state plasma insulin (SSPI) of approximately 100 microU/ml achieved by the infusion of somatostatin, insulin, and glucose, however, was significantly lower in obese than in nonobese subjects, and was inversely correlated with WHR. The increase in percentage of synthase I correlated inversely with the steady state plasma glucose (SSPG) concentration, which is an index of the efficiency of overall glucose disposal, and directly with insulin binding to circulating monocytes. Insulin binding also correlated inversely with WHR and with fasting plasma insulin levels. When obese subjects were separated into three weight-matched subgroups on the basis of increasing WHR, significant trends to decreased percentage of synthase I response, increased SSPG, and decreased insulin binding were found. In women with predominantly upper body obesity (WHR greater than 0.85), the increase in percentage of synthase in response to submaximal SSPI was diminished, but there was no impairment of percentage of synthase I responsiveness to supramaximal SSPI of approximately 1,000 microU/ml. At supramaximal SSPI levels, SSPG in four obese women was normal, whereas in five women, SSPG concentrations were markedly increased. Our results suggest that in premenopausal women, impaired skeletal muscle insulin sensitivity that results in decreased glucose storage capacity may contribute to the diminished efficiency of glucose disposal and insulin resistance that are associated with upper body obesity. The impairment in skeletal muscle sensitivity may be overcome in vivo at the expense of increasing plasma insulin levels, with maximal responsiveness remaining unimpaired. This defect may result from a reduction in insulin receptor number which could, in turn, be secondary to persistently elevated fasting plasma insulin levels. In some upper body segment obese women, however, an additional defect affecting other insulin-sensitive pathways may also be present.
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PMID:Relationship between skeletal muscle insulin resistance, insulin-mediated glucose disposal, and insulin binding. Effects of obesity and body fat topography. 614 58

An insulin-sensitive subcellular system was developed from rat adipocytes consisting of plasma membranes and mitochondria. Direct addition of insulin, concanavalin A or anti-insulin receptor antibody to this system resulted in the production of a mediator substance from the plasma membrane that caused dephosphorylation of the alpha subunit of pyruvate dehydrogenase in the mitochondria with concomitant activation of the enzyme. The mediator activated pyruvate dehydrogenase by activating the pyruvate dehydrogenase phosphatase and not by inhibiting the pyruvate dehydrogenase kinase. This was similar to the mechanism by which insulin causes activation of the enzyme in the intact cell. The insulin-sensitive mediator material from the adipocyte plasma membrane was acid-stable with a molecular weight of 1,000 to 1,500. Our laboratory has shown that the mediator that activates pyruvate dehydrogenase was present in intact adipocytes, hepatoma cells, and IM-9 lymphocytes. Insulin altered the amount or activity of the mediator consistent with the effect of the hormone on the cell. Other laboratories have shown similar effects on skeletal muscle and liver. We have shown the mediator to mimic insulin action on the low Km cyclic adenosine monophosphate (AMP) phosphodiesterase and the (calcium++-magnesium++)-adenosine triphosphatase (Ca++-Mg++)-ATPase of adipocyte plasma membranes in addition to pyruvate dehydrogenase. Other laboratories have shown the mediator to activate glycogen synthase. A body of direct and indirect evidence exists that demonstrates that more than one mediator exists. The chemical nature of the mediator is unknown but probably represents a new family of intracellular mediators of hormone action. These mediators may have clinical relevance in postreceptor defects of obesity and type II diabetes (noninsulin-dependent diabetes mellitus).
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PMID:The chemical mediators of insulin action: possible targets for postreceptor defects. 633 85

Impaired glycogen synthesis is present in subjects at risk for developing non-insulin-dependent diabetes mellitus (NIDDM), suggesting that it is a primary defect in NIDDM. To examine whether defects in glycogen metabolism are present at birth in an animal model of NIDDM, glycogen synthase (GS), glycogen phosphorylase (GP), and total glycogen content were measured in liver and quadriceps muscle of 1-day- and 20-week-old insulin-resistant New Zealand Obese (NZO) mice and control (NZC) mice. In livers of both neonatal and adult NZO mice, active GS was reduced by 54% and 36%, respectively, as compared with that in NZC mice (P < .03). Total liver GS activity was the same in neonates, but was 65% higher in adult NZO as compared with NZC mice (P < .02). Liver glycogen was 28% lower at birth in NZO mice (P < .03), but was 49% higher at 20 weeks of age. Active and total GP were the same in NZO and NZC animals, despite hyperinsulinemia in 20-week-old NZO mice. In muscle, active GS was reduced by 41% in both 1-day- and 20-week-old NZO mice (P < .02). Total GS was also lower in NZC mice at 1 day of age (P < .01), but not at 20 weeks. No differences were detected in GP activity or in total glycogen content in muscle. Therefore, reduced GS activity is an early defect present at birth in the insulin-resistant NZO mouse in both liver and muscle. However, it is not the sole determinant of the amount of glycogen deposited in tissues.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Defects in liver and muscle glycogen metabolism in neonatal and adult New Zealand obese mice. 747 88

Visceral obesity in man is followed by several abnormalities in endocrine secretions, including an elevated cortisol secretion as well as hyperandrogenicity in women, and a relative hypogonadism in men, suggesting a central neuroendocrine background. A pronounced insulin resistance is a main symptom of this condition and may be at least partially following these endocrine abnormalities. For example, mimicking hyperandrogenicity in women by administration of testosterone (T) in moderate doses to female rats is followed by severe muscular insulin resistance, as well as a low type I/type II muscle fiber ratio, and a low capillary density in muscle. These findings are identical to those in visceral obese women with hyperandrogenicity and insulin resistance. Studies of details of function and morphology in the muscles in this rat model have revealed that insulin stimulation of glucose transport, glycogen synthesis and the insulin sensitive part of the glycogen synthase is diminished at submaximal insulin concentrations. However, insulin receptor number and function, as well as the total number of glucose transporter 4 appear to be normal, supported by observations that the insulin resistance is overcome by elevated insulin concentrations. These observations suggest that normal cellular mechanisms for glucose metabolism in muscle in this model are under-utilized, and that the explanation to apparent insulin resistance may be found proximal to the machinery of the muscle cell. The histochemical changes of the muscles may provide a clue to the understanding of the mechanism.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Insulin resistance: the consequence of a neuroendocrine disturbance? 755 May 39

A study of glycogen metabolism in the liver has been carried out in gold thioglucose (GTG) injected mice during the development of obesity. In GTG obese mice, overt obesity, hyperglycaemia and hyperinsulinaemia had developed by 6 weeks after the injection of GTG. Beyond 6 weeks after GTG injection, the gain of body weight and increment in serum glucose and insulin levels with age in obese mice were not obvious when compared with those of age-matched control animals. The glycogen concentration, total glycogen storage, activity of glycogen synthase R and activity of phosphorylase a in the liver from GTG obese mice were significantly greater than those in lean mice from 2-4 weeks after GTG injection and remained higher thereafter. These results demonstrate that the increased liver glycogen storage and increased activity of glycogen synthase and phosphorylase occur early in the development of obesity and at a similar time to previously reported increases in pyruvate dehydrogenase activity (Caterson et al. (1987) Biochem. J. 243, 549-553) and lipid synthesis in liver (Cooney et al. (1989) Biochem. J. 259, 651-657). The emergence of these abnormalities in glycogen metabolism early in the development of obesity may contribute to the establishment of glucose intolerance and insulin resistance in this model of obesity which became apparent at approximately the same time after GTG injection.
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PMID:Changes in glycogen metabolism in liver of gold thioglucose injected mice during the development of obesity. 781 17

The requisites for energy expenditure are covered mainly by two major substrates, glucose and free fatty acids (FFA). Their regulation and metabolism differ. After carbohydrate ingestion, glucose is rapidly oxidized or stored in muscles and liver. There is a constant alternance between glucose storage as glycogen after meals and glycogen mobilization in the postabsorptive state when plasma glucose has returned to the basal state. Impairment of this alternance, in particular when glycogen stores are not being used, may lead to glucose intolerance and insulin resistance. Ingestion of lipids is not followed by an immediate increase in lipid oxidation, but FFA are stored as triglycerides in different tissues. Lipolysis occurs in the fasting state from tissue triglycerides and favors lipid oxidation. Lipid oxidation is typically increased in obesity. The preferential use of FFA from triglyceride stores for energy expenditure in obesity is responsible for the decrease in glucose mobilization from glycogen stores. This leads to a negative feedback of muscle and liver glycogen on glycogen synthase activity and consequently on glucose storage. It results in glucose intolerance after carbohydrate ingestion. Diabetes develops in obesity, usually after a long period of glucose intolerance, when glycemia does not return to the basal state. In obesity, glucose intolerance and insulin resistance can be prevented, or if already existing, can be decreased by stimulating glycogen mobilization by exercise, thermogenesis-stimulating drugs, and weight loss, which reduces fat stores and decreases lipid oxidation.
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PMID:Regulation of nutrient metabolism and energy expenditure. 786 36

The relationship between obesity and Type 2 diabetes mellitus is so closely related that it is worth questioning the possibility of obesity being more than just one diabetes risk factor among others but a factor which participates causally to the development of Type 2 Diabetes on a genetic background. In this review, the evolution of normal glucose tolerance towards impaired glucose tolerance corresponds to the development of compensatory metabolic changes. These compensatory mechanisms are hyperinsulinaemia and postprandial hyperglycaemia which prevents a defect in glucose uptake and especially glucose storage. These compensatory responses are overcome with time and diabetes develops in spite of the hyperinsulinaemia and the hyperglycaemia. The capacity for glucose storage is decreased and cannot be overcome at this stage by increases of both glucose and insulinemic responses. Inhibition of glycogen synthase activity by an increased muscle glycogen concentration is probably more powerful than its stimulation by insulin and glucose and the capacity for glucose storage remains decreased. Finally with time insulin secretion gradually decreases as a consequence of chronic hyperglycaemia and results in full pancreatic decompensation. At this stage hepatic glucose production is increased. The most important factor in the evolution from obesity to diabetes reside in the permanence of the increase in lipid oxidation and mainly in the duration of obesity. An important consequence of permanently high lipid oxidation is the chronic resistance to glucose uptake, initially compensated for by increased plasma insulin and glucose concentrations. A vicious circle starts after insulin resistance to glucose uptake appears, followed by hyperglycaemia blocking the glucose storage system and by the lack of storing capacity leading to a rise in glycaemia. In conclusion, all these metabolic phenomena are appearing in a sequential way, progressively adapting to the deteriorating situation, through the stages of normal glucose tolerance, impaired glucose tolerance, hyperinsulinaemic and finally hypoinsulinemic diabetes.
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PMID:Evolution from obesity to diabetes. 805 32


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