HUMANGGP:034761 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: HUMANGGP:034761 (insulin)
211,843 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An assay of lipolytic activity in human adipose tissue is described, in which native homogenates of the adipose tissue yield the enzyme, as well as the triglyceride substrate, and the emulsifying phospholipids. The lipolytic activity in the presence of serum is characterized mainly as lipoprotein lipase activity by a pH-optimum of 8.0, by the fact that serum is necessary for full activity, and that it is inhibited by 1 M NaCl and by protamine. At serum concentrations of higher than 50% a marked inhibition of the lipolysis is observed. Noradrenaline, insulin, and heparin have no effect on the serum-stimulated lipolytic activity.
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PMID:Assay and characterization of serum-stimulated lipolytic activity in homogenates of human adipose tissue. 1 66

The activity of hepatic triglyceride lipase in the rat was reduced by fasting. Withdrawal of insulin from insulin-treated streptozotocin-diabetic rats resulted in a decrease in hepatic triglyceride lipase activity. The behavior of the enzyme in both situations was similar to that of adipose tissue lipoprotein lipase. It is concluded that hepatic triglyceride lipase, like adipose tissue lipoprotein lipase, is under hormonal regulation by insulin.
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PMID:The effects of fasting and streptozotocin diabetes on hepatic triglyceride lipase activity in the rat. 13 56

The conference opened with the clinical presentation of a 50-year-old male with fasting hyperglycemia (296 mg per cent) and hypertriglyceridemia (2736 mg per cent). The discussion began with a summary of current concepts regarding the manner in which chylomicra (intestine) and very low density lipoproteins (intestine and liver) are formed, transported into the plasma, and removed from the circulation. This was followed by a consideration of diabetic hypertriglyceridemia in which this syndrome was subdivided into two categories. The first form is seen in patients with severe fasting hyperglycemia, and is characterized by marked insulin deficiency, decreased very low density lipoprotein production, a fall in the activity of lipoprotein lipase, and hypertriglyceridemia secondary to a defect in removal of lipoproteins from the plasma. In contrast the other form of diabetic hypertriglyceridemia is seen in patients with minimal abnormalities of carbohydrate tolerance, and in this instance insulin resistance, not insulin lack, seems to play the pivotal role. In these patients, the rise in plasma triglyceride levels seems to be secondary to increased production of very low density lipoproteins, presumably as a result of the hyperinsulinemia associated with the insulin resistance. The conference ended with an attempt to relate the patient presented to the models of diabetic hypertriglyceridemia that had been defined.
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PMID:Diabetic hypertriglyceridemia. 16 73

In order to elucidate the mechanism(s) of hyperlipidemia following glucocorticoid administration, dexamethasone (0.125 mg/Kg) was administered daily intramuscularly for 2 wk to male Sprague-Dawley rats and the effects on plasma triglyceride (TG) and cholesterol (Chol), lipoprotein neutral lipids, hepatic triglyceride secretion rates (TGSR; Triton), and epididymal fat lipoprotein lipase (LPL) were determined. Special measures were taken to maintain positive caloric balance and keep the weights of control and dexamethasone-treated animals comparable. Significant increases (p less than 0.001) in TG and very-low density lipoprotein (VLDL) triglyceride associated with no change in Chol and actual reduction in both triglyceride and cholesterol in low density lipoprotein (ldl) were observed in the steroid-treated animals. Dexamethasone treatment was associated with increased basal insulin and glucose levels, an insignificant increment in TGSR, and a highly significant reduction (p less than 0.001) in LPL. These findings suggest that glucocorticoid treatment increases splanchnic triglyceride production rates, but the resulting hypertriglyceridemia is primarily a consequence of impaired VLDL removal due to low adipose tissue LPL activity.
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PMID:Glucocorticoids and triglyceride transport: effects on triglyceride secretion rates, lipoprotein lipase, and plasma lipoproteins in the rat. 17 40

Metabolism of ruminant adipocytes involves the synthesis and mobilization of lipids. Rates of lipid synthesis from the uptake of preformed fatty acids (via lipoprotein lipase) and de novo synthesis of fatty acids are related to the energy balance. Acetate is the major carbon source for fatty acid synthesis with NADPH originating from the pentose cycle and the isocitrate cycle. Ruminant adipose tissue lacks the ability to utilize for lipogenesis those substrates that generate mitochondrial acetyl CoA because of an absence of ATP citrate-lyase and NADP-malate dehydrogenase. Lipid mobilization in ruminant adipocytes is apparently regulated via cAMP levels and a summary of the compounds investigated for lipolytic responses is presented. The control of lipid synthesis and mobilization is interrelated in ruminant adipose tissue. The coordinated manner in which these two functions are regulated is examined with regard to adipocyte responses to insulin and epinephrine. In both lipid synthesis and lipid mobilization, ruminant adipocytes are uniquely different from nonruminant adipose tissue. The physiological significance and possible basis for these species differences in adipose metabolism are discussed.
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PMID:Intermediary metabolism of adipose tissue. 18 55

There are several causes for hyperlipemia in the diabetic: (a) an increase in hepatic synthesis of prebetalipoproteins, and (b) reduced elimination of prebetalipoproteins and chylomicrons from the bloodstream, due to diminished activity of lipoprotein lipase in insulin deficiency. The role of heredity has been put in doubt by the observation that diabetes and hypertriglyceridemia are not transmitted by the same genetic factor. The shortterm and longterm implications of diabetic hyperlipemia are discussed, together with the treatment.
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PMID:[Hyperlipemia and diabetes]. 18 65

The activity of two triglyceride lipases was determined by an immunochemical method in the postheparin plasma of 60 diabetic patients and of 47 age- and sex-matched nondiabetic control subjects. The results were related to the type of diabetes, to plasma triglyceride and insulin concentrations, to removal of exogenous fat from the blood, and to turnover of VLDL-triglycerides . The mean postheparin plasma lipoprotein lipase (LPL) activity was decreased by 44 per cent (p less than 0.001) in patients with untreated ketotic diabetes and by 20 per cent (p less than 0.01) in patients with untreated mild to moderate nonketotic early-onset diabetes. Insulin treatment of ketotic diabetes resulted in a rapid increase in the activity of LPL and decrease in serum triglycerdie level, whereas sulfonylurea treatment of non-insulin-requiring diabetics did not significantly influence the enzyme activity. In insulin-treated chronic diabetics the average postheparin plasma LPL activity was not different from that of nondiabetic controls, but some of these patients had high LPL values. In normolipidemic maturity-onset-type diabetics the LPL activity was within normal range, but in those having hypertriglyceridemia the average LPL value was decreased by an average of 26 per cent (p less than 0.01). The LPL activity showed a significant negative correlation with the logarithm of serum triglyceride concentration (r = -0.62) and a positive correlation with fractional removal of Intralipid (r = +0.64) and fractional turnover of V triglyceride (r = +0.40). The activity of LPL was correlated to basal plasma insulin concen tration in the insulin-deficient diabetes r = +0.34) but not in patients with maturity-onset-type diabetes. The hepatic lipase (HL) activity of postheparin plasma was similar in diabetes and controls, with the exception of hypertriglyceridemic maturity-onset diabetics, who had higher mean HL activity than the corresponding control group (p greater than 0.01). The activity of HL was not related to triglyceride removal but showed a significant correlation to VLDL-triglyceride production rate. On the basis of these results it seems that a deficiency of LPL accounts for a great deal of the elevation of serum triglyceride in insulin-deficient human diabetes but has a smaller role in the pathogenesis of the hypertriglyceridemia that is associated with maturity-onset diabetes. The latter abnormality is caused mainly by an increased secretion of triglycerides into the blood even though a decreased LPL may contribute to development of hyperlipemia in cases with gross elevation of serum triglycerides.
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PMID:Postheparin plasma lipoprotein lipase and hepatic lipase in diabetes mellitus. Relationship to plasma triglyceride metabolism. 18 16

The hypolipidaemic effect of a new drug, gemfibrozil (CI-719), was studied for 20 weeks in 20 patients with primary type IIb, III, IV or V hyperlipoproteinaemia. Baseline recordings of serum cholesterol (9.1 mmol/l), triglyceride (3.79 mmol/l) and ultra-centrifugally isolated lipoproteins were obtained during a six-week pretreatment period with stable diet and body weight. With 800 mg of gemfibrozil per day given in two divided doses, the mean serum triglyceride and cholesterol levels were decreased by 44.6% and 10.5% respectively, during 20 treatment weeks. Only 2 patients were completely resistant to the hypolipidaemic action of the drug. Serum triglyceride was brought down to normal levels in 9 subjects. After 12 weeks of treatment the mean VLDL-triglyceride, VLDL-cholesterol, and LDL-triglyceride were reduced by 48.5%, 57.6%, and 22.7% respectively, while the HDL-cholesterol rose by 16%. The LDL-cholesterol increased slightly but significantly during treatment in type IV patients and decreased in type IIb patients. The change of LDL-cholesterol showed an inverse correlation with the initial LDL-cholesterol level (r=-0.87). The postheparin plasma lipoprotein lipase and hepatic lipase activities, determined separately by an immunochemical method, increased during four weeks of gemfibrozil treatment (+18.1% and +20.6% respectively), but neither of these changes was significantly correlated with the changes in any of the serum lipid or lipoprotein levels. Oral glucose tolerance was not influenced by the treatment, but one-hour plasma insulin increased slightly during administration of the drug. One patient discontinued the drug after eight weeks because of generalized allergic eczema, but no other side effects were recorded. It is concluded that gemfibrozil is highly effective in reducing elevated serum VLDL levels. The simultaneous elevation of LDL in type IV patients needs more attention and study. The mechanism of the hypolipidaemic action of the drug is so far obscure, but it might partly be due to an increased efficiency in VLDL removal by an increased activity of lipoprotein lipase.
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PMID:Gemfibrozil: effect on serum lipids, lipoproteins, postheparin plasma lipase activities and glucose tolerance in primary hypertriglyceridaemia. 19 Jun 8

Primary type V hyperlipoproteinemia was identified in two preadolescent children. The propositus (kindred N) was a 10-year-old girl with severely creamy plasma, lipemia retinalis, hypertriglyceridemia (triglyceridelevel, 6,800 mg/100 ml), and ypercholesterolemia (cholesterol level, 490 mg/100 ml). Her parents and an 8-year-old sister all had endogenous hypertriglyceridemia (type IV hyperlipoproteinemia). In kindred A, an 11-year-old boy had triglyceride levels as high as 1,100 mg/100 ml and recurrent abdominal pain. His father had type V hyperlipoproteinemia; his mother was normal. All three of his older teenage siblings had type IV hyperlipoproteinemia. The enzymatic activities of lipoprotein lipase (LPL), hepatic triglyceride lipase (HTL), and histaminase (H) were studied in postheparin plasma. The LPL level was low in the children and both parents in kindred N. LPL level in kindred A was normal, except for one child with type IV hyperlipoproteinemia. HTL level was normal to above normal in both kindreds. Most patients had a normal H level, but one parent (kindred N) had no preheparin H and very low levels of postheparin H. There was a strong correlation (r = 0.58, significant at less than 1% level) between release of LPL and H but not between HTL and H (r= 0.22). The mean (+/- 1 S.D.) levels of the enzymes were as follows: LPL, 2.8 +/- 0.7 micronmol/ml/hr in kindred N and 5.4 +/- 2.2 micronmol/ml/hr in kindred A; H, 13.4 +/- 6.8 units/ml in kindred N and 22.0 +/- 11.9 units/ml in kindred A; and HTL, 18.0 +/- 7.1 micronmol/ml/hr in kindred N and 14.9 +/- 6.3 micronmol/ml/hr in kindred A. The enzymatic activities of kindreds N and A were significantly different for LPL (P less than .001) and H (.025 less than P less than .05) but not for HTL. All but one child had at least one high insulin level, which was accompanied by hyperglycemia in two children. The hypertriglyceridemia in all but one child was ameliorated on therapeutic diets. These data suggest that the genetic basis of the hypertriglyceridemia in these two families is different and that hyperchylomicronemia in childhood is not confined to the rara type I hyperliporproteinemia.
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PMID:The clinical, biochemical, and familial presentation of type V hyperlipoproteinemia in childhood. 19 90

To identify cells developing into adipocytes by accumulation of triglyceride, rat epididymal fat pad cells from small rats were exposed to (3)H-labeled chylomicron fatty acids in vivo and then liberated with collagenase. Tissue remnants were removed by filtration and mature fat cells by flotation. Aggregating cells were then removed by filtration through a 25- micro m nylon screen. Further purification of cells labeled in vivo was obtained by removing floating cells from those adhering to the bottom of a culture dish. The adhering cells multiplied to a confluent monolayer when cultured in Medium 199 containing serum, glucose, insulin, and a triglyceride emulsion. The cells then gradually enlarged due to granulation of the cytoplasm by a lipid-staining material. After about 2 weeks these granules had coalesced forming mature adipocytes of typical signet-ring appearance. Free adipocytes could then be recovered from the cultures by collagenase treatment. After about 2 weeks of culture these cells had the same size (about 30 micro m) as adipocytes recovered in the original collagenase preparation of the rat epididymal fat pad. They contained triglyceride lipase activity and incorporated glucose into triglycerides to the same extent as cells developed in vivo but had higher lipoprotein lipase activity. In vitro, heparin in a low concentration, prostaglandin E(1), isobutylmethylxanthine, and cholera toxin markedly promoted the development of these cells into adipocytes. This could be shown to occur almost completely indicating that this fraction of cells was homogeneous and consisted of cells with the capacity to form adipocytes. The duplication time was about 2 days and did not change with subculturing. Preadipocytes could be obtained by density gradient centrifugation, isolating triglyceride-containing cells either directly from the pad or after 3 days in culture. All of these cells developed into adipocytes as described above but did not multiply as readily. It was concluded that cells from the epididymal fat pad from small rats can be isolated in a homogenous fraction that develops in culture into cells of identical morphology and function as adipocytes formed in vivo. The differentiation of these cells into adipocytes may be manipulated in vitro.
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PMID:Isolation and characterization of cells from rat adipose tissue developing into adipocytes. 20 38

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