We have examined the onset and duration of the inhibitory effect of an intravenous infusion of lipid/heparin on total body carbohydrate and fat oxidation (by indirect calorimetry) and on glucose disappearance (with 6,6 D2-glucose and gas chromatography-mass spectrometry) in healthy men during euglycemic hyperinsulinemia. Glycogen synthase activity and concentrations of acetyl-CoA, free CoA-SH, citrate, and glucose-6-phosphate were measured in muscle biopsies obtained before and after insulin/lipid and insulin/saline infusions. Lipid increased insulin-inhibited fat oxidation (+40%) and decreased insulinstimulated carbohydrate oxidation (-63%) within 1 h. These changes were associated with an increase (+489%) in the muscle acetyl-CoA/free CoA-SH ratio. Glucose disappearance did not decrease until 24 h later (-55%). This decrease was associated with a decrease in muscle glycogen synthase fractional velocity (-82%). The muscle content of citrate and glucose-6-phosphate did not change. We concluded that, during hyperinsulinemia, lipid promptly replaced carbohydrate as fuel for oxidation in muscle and hours later inhibited glucose uptake, presumably by interfering with muscle glycogen formation. (J.Clin. Invest. 1991. 88:960-966.)
Defects of glucose transport and phosphorylation may underlie insulin resistance in obesity and non-insulin-dependent diabetes mellitus (NIDDM). To test this hypothesis, dynamic imaging of 18 F-2-deoxy-glucose uptake into midthigh muscle was performed using positron emission tomography during basal and insulin-stimulated conditions (40 mU/m 2 per min), in eight lean nondiabetic, eight obese nondiabetic, and eight obese subjects with NIDDM. In additional studies, vastus lateralis muscle was obtained by percutaneous biopsy during basal and insulin-stimulated conditions for assay of hexokinase and citrate synthase, and for immunohistochemical labeling of Glut 4. Quantitative confocal laser scanning microscopy was used to ascertain Glut 4 at the sarcolemma as an index of insulin-regulated translocation. In lean individuals, insulin stimulated a 10-fold increase of 2-deoxy-2[
Amino acids stimulate the release of glucagon and insulin. To assess the role of aminogenic hyperglucagonemia, we have studied, in healthy young males, the effects of basal (less than 100 pg/ml) and high (200-400 pg/ml) plasma glucagon concentrations on amino acid metabolism during intravenous infusion (0.5 g.h-1.4 h) of a mixture of 15 amino acids. Basal plasma glucagon concentrations were obtained by infusion of somatostatin (0.5 mg/h) plus glucagon (0.25 ng.kg-1.min-1) and high plasma glucagon concentrations by infusion of somatostatin plus glucagon (3.0 ng.kg-1.min-1) or by infusion of amino acids alone. All studies were performed under conditions of euglycemic (83-91 mg/dl) hyperinsulinemia (50-80 microU/ml). Hyperglucagonemia significantly increased 1) net amino acid transport from the extracellular into the intracellular space (by approximately 4%), 2) net degradation of amino acids entering the intracellular space (by approximately 40%), and 3) conversion of degraded amino acids into glucose from 0-10% (basal glucagon) to 70-100% (high glucagon). Hyperglucagonemia did not affect the amount of amino acids excreted in the urine (approximately 4%). We conclude that glucagon plays an important role in the disposition of amino acids by increasing their inward transport, their degradation, and their conversion into glucose.
We investigated the effects of infusion of a 20% triglyceride emulsion plus heparin (LH) on carbohydrate (CHO) metabolism during basal insulin and glucose turnover conditions in normal male subjects. In study 1, LH or saline was infused at 0.5 and 1.5 ml/min for 2 h each. Plasma free fatty acids rose from approximately 0.4 to 0.8 mM with the low rate and to between 1.6 and 2.1 mM with the high rate. Similar increases occurred in plasma concentrations of glycerol, acetoacetate, and beta-hydroxybutyrate. LH infusions resulted in significant increases in C-peptide concentrations but had no effects on any of the other measured parameters of CHO metabolism. In study 2, LH or saline was infused as in study 1, but the compensatory insulin release was prevented by intravenous infusion of somatostatin and replacement of basal insulin and glucagon concentrations. This resulted in significant increases in plasma glucose (from 4.5 +/- 0.2 to 7.1 +/- 0.6 mM, P less than 0.001) and hepatic glucose output (from 9.0 +/- 1.5 to 11.3 +/- 1.4 mumol.kg-1.min-1, P less than 0.05) and a decrease in glucose clearance (from 2.32 +/- 0.13 to 1.44 +/- 0.11 ml.kg-1.min-1, P less than 0.05). We conclude that lipids can have adverse effects on CHO metabolism under basal conditions and that healthy individuals can compensate for these effects with additional secretion of insulin.
We have developed a radioimmunoassay for human insulin receptor. Serum from a patient with Type B severe insulin resistance was used as anti-insulin receptor antiserum. Pure human placental insulin receptor was used as reference preparation and 125I labeled pure insulin receptor as trace. The radioimmunoassay was sensitive (limit of detection less than 17 fmol), reproducible (inter and intra-assay coefficients of variation 12.5% and 1.6% respectively) and specific (no crossreactivity with pure placental IGF-1 receptor, insulin and glucagon). The anti-insulin receptor antibody was, however, able to differentiate between insulin receptor from human placenta and from rat liver. To determine the number of insulin binding sites per receptor, we measured insulin binding (by insulin binding assay) and insulin receptor mass (by radioimmunoassay) in solubilized aliquots from 5 human placentas. The molar ratio of insulin binding to receptor mass was 0.86 +/- 0.12 when binding was determined with monoiodinated 125I-Tyr A 14-insulin. It was 1.94 +/- 0.27 when randomly iodinated 125I-insulin was used. In conclusion, using a sensitive, reproducible and specific radioimmunoassay, we have measured insulin receptor mass independent of insulin binding. Our data are most compatible with binding of one insulin molecule per human placental insulin receptor.
METHODS: RESULTS: CONCLUSIONS.
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