Dietary Myoinositol Results in Lower Urine Glucose and in Lower Postprandial Plasma Glucose in Obese Insulin Resistant Rhesus Monkeys.

In a previous study, D-chiroinositol added to a meal (0.5 g/kg) resulted in significantly lower postprandial plasma glucose concentrations without an increase in insulin concentrations in obese insulin-resistant monkeys. The present report describes the effects of another isomer of inositol, myoinositol, on postprandial plasma glucose and insulin concentrations and on urine glucose concentrations in 6 similarly insulin-resistant monkeys. The three 5 day study periods included a control period (liquid diet ad libitum) and 2 experimental periods (liquid diet ad libitum with either 1.5 g/kg/day myoinositol or D-chiroinositol added). Twenty-four hour urine samples were collected during each 5 day period. On the sixth day of each period the monkeys were anesthetized 110 min after completing either the control meal (15 ml/kg) or the experimental meals (1.5 g/kg myoinositol or D-chiroinositol) and plasma samples were obtained at 120, 150,180, 210, 240, 270 and 300 min. The plasma glucose concentration was lower after the meal with myoinositol compared to the control meal at 120, 150 and 180 min (p's<0.05). The plasma insulin concentration was lower after the meal with myoinositol compared to the control meal at 150 and 180 min (p's<0.05). In addition, 24 hour urine glucose concentrations were lower during the myoinositol diet compared to the control diet (p<0.001). The plasma glucose concentration was lower after the meal with D-chiroinositol compared to the control meal at 150, 240, 270 and 300 min (p's≥0.05). In obese insulin-resistant monkeys, myoinositol added to the diet lowers urine glucose concentrations and both myoinositol and D-chiroinositol added to a meal lower postprandial plasma glucose concentrations without increasing postprandial insulin concentrations. Therefore, myoinositol, like D-chiroinositol, may be a useful agent for reducing meal-induced hyperglycemia without inducing hyperinsulinemia in insulin-resistant subjects.     

Receptor-mediated insulin degradation and insulin-stimulated glycogenesis in cultured foetal hepatocytes.

Insulin-stimulated glycogenesis and insulin degradation were studied simultaneously at 37 degrees C in cultured foetal hepatocytes grown for 2-3 days in the presence of cortisol. Degradation of cell-associated insulin, as measured by trichloroacetic acid precipitation, was significant after 4 min in the presence of 1-3 nM-125I-labelled insulin. This process became maximal (30% of insulin degraded) after 20 min, a time when binding-state conditions were achieved. No insulin-degradative activity was detected in a medium that had been exposed to cells. At steady-state, the appearance of insulin degradation products in the medium was linearly dependent on time (1.5 fmol/min per 10(6) cells at 1nM-125I-labelled insulin). Chloroquine (3-50 microM), bacitracin (0.1-10 mM) and NH4Cl (1-10 mM) inhibited insulin degradation as soon as this became detectable and caused an increase in the association of insulin to hepatocytes after 20 min. Lidocaine and dansylcadaverine had similar effects, whereas N-ethylmaleimide, aprotinin, phenylmethanesulphonyl fluoride and leupeptin were found to be ineffective. Chloroquine, and also bacitracin, at concentrations that inhibited insulin degradation, decreased the insulin-stimulated incorporation of [14C]glucose into glycogen over 2 h. This effect of chloroquine was specific, since it did not modify the basal glycogenesis, or the glycogenic effect of a glucose load in the absence of insulin. It therefore appears that the receptor-mediated insulin degradation (or some associated pathway) is functionally related to the glycogenic effect of insulin in foetal hepatocytes.     

Factors influencing glucose flux and the effect of insulin in cultured human cells

Uptake of glucose-³H into cultured HLM cells was measured. Equilibration of intracellular and extracellular pools occurred after 25 min. Glucose influx was determined subsequently by measuring the glucose-³H entering in precisely 1 min. Although saturation kinetics were demonstrated these were not of the simple Michaelis-Menten type. The K_m of the glucose carrier system is probably about 60 mM glucose. Galactose did not compete with glucose. Insulin stimulated glucose flux without increasing the value of V _max. The stimulation was fully demonstrable after 10 min, could be elicited at concentrations of 10^-4 units/ml, and was absent 2–4 hr after removal. Increasing pH had little or no effect in stimulating glucose flux. Increasing osmotic pressure caused a marked increase and reduced the effect of insulin. Glucose influx was unaffected by anoxia. Glucose influx was increased and the effect of insulin abolished in the absence of K⁺. Glucose influx was increased by mercuric chloride, iodoacetate, and fluoride which abolished the effect of insulin. Dinitrophenol decreased the rate of glucose uptake but did not alter the effect of insulin. Phlorizin reduced the rate of glucose uptake and abolished the effect of insulin. ATP and AMP enhanced the rate of glucose uptake. These findings are discussed in relation to the mode of action of insulin.     

Glucose transport into rat skeletal muscle: interaction between exercise and insulin

This study was done to evaluate the effect of insulin on sugar transport into skeletal muscle after exercise. The permeability of rat epitrochlearis muscle to 3-O-methylglucose (3-MG) was measured after exposure to a range of insulin concentrations 30, 60, and 180 min after a bout of exercise. Thirty and 60 min after exercise, the effects of exercise and insulin on 3-MG transport were additive over a wide range of insulin concentrations, with no increase in sensitivity or responsiveness to insulin. After 180 min, when approximately 66% of the exercise-induced increase in sugar transport had worn off, both the responsiveness and sensitivity of the glucose transport process to insulin were increased. These findings appear compatible with the hypothesis that the actions of exercise and insulin result in activation and/or translocation into the plasma membrane of two separate pools of glucose transporters in mammalian skeletal muscle.     

Electron microscopic analysis of glucose-induced endothelial damage in primary culture: possible mechanism and prevention

We previously reported that high glucose treated cultured endothelial cells (ECs) showed intercellular gaps by transmission electron microscopy (TEM). These gaps were abrogated with insulin and/or heparin treatment. Our aims were to assess the severity of injury in ECs treated with high glucose for variable duration, and to further study the protective effects of insulin and/or heparin. Cells were also treated with L-buthionine sulfoximine (BSO), a glutathione inhibitor, to help understand the mechanism of high glucose injury. Primary porcine ECs were treated with high glucose (30 mM) for 2, 6 or 10 days; and glucose plus insulin (1 U/ml), glucose plus heparin (5 microg/ml), glucose plus insulin plus heparin for 6 days. ECs were treated with BSO (0.001-0.05 mM) for 2 days. Pellets from trypsinized cells were processed for TEM. High glucose treatment revealed apoptosis or necrosis showing variable cell size, abnormal nuclei, condensation of nuclear chromatin, few mitochondria, cell membrane disruption and needle-shaped structures. Changes increased with duration of exposure. In high glucose plus heparin or insulin treated cultures at least one-half of the cells appeared normal. Most ECs were intact when treated with high glucose plus insulin plus heparin. BSO treatment showed dose-dependent changes with low doses showing apoptosis whereas higher doses revealed necrosis similar to high glucose treatment for 6 or 10 days. High glucose-induced EC injury increased with duration of exposure. These data demonstrate that high glucose injury resembles that of BSO treatment, suggesting that glutathione depletion may be involved in EC injury. Insulin and/or heparin protect against high glucose-induced injury.     

Recovery of maximal insulin responsiveness and insulin sensitivity after induction of insulin resistance in primary cultured adipocytes

Treatment of primary cultured adipocytes with 50 ng/ml insulin and 20 mM glucose for 0-6 h resulted in a loss of maximal insulin responsiveness (MIR) which was immediate (no lag period), rapid (t1/2 of 3 h), linear, and extensive (80% of that seen at 24 h), whereas loss of insulin sensitivity from 0-24 h was slow (t1/2 = 8 h), extensive (insulin ED50 of 0.3 and 1.45 ng/ml at 2 and 24 h, respectively), and was preceded by an initial 2-h lag. Recovery of MIR and insulin sensitivity was assessed by inducing desensitization for various times from 2-24 h, removing insulin and glucose, and then measuring MIR and insulin sensitivity over a subsequent 1-6-h period. After 2 h, recovery of MIR in desensitized cells was rapid (251 pmol of glucose/3 min/h), whereas after 24 h, recovery was much slower (35 pmol/3 min/h). In contrast, the opposite trend was seen for recovery of insulin sensitivity: at early times recovery of insulin sensitivity was slow (0.05 ng/ml/h) but was rapid after 24 h (0.12 ng/ml/h). Thus, it appears that MIR and insulin sensitivity can be independently regulated since recovery rates for MIR and insulin sensitivity diverged with the progression of insulin resistance. When the effects of insulin and glucose on recovery were examined, we found that insulin alone was unable to block recovery of MIR or insulin sensitivity. Glucose alone, however, was effective in preventing recovery of insulin sensitivity but not recovery of MIR. In the presence of 20 mM glucose, low doses of insulin (treatment EC50 = 0.22-0.46 ng/ml) effectively prevented recovery of both MIR and insulin sensitivity. De novo protein synthesis apparently is not involved in the development of insulin resistance or the reversal of desensitization since inhibition of protein synthesis by cycloheximide had no effect on the loss of MIR and insulin sensitivity or recovery.(ABSTRACT TRUNCATED AT 400 WORDS)     

Insulin release in pancreatic islets by a glycolytic and a Krebs cycle intermediate: contrasting patterns of glyceraldehyde phosphate and succinate

Glyceraldehyde phosphate, a glycolytic intermediate, and succinic acid (as its methyl ester to make it permeable to the cell), a citric acid cycle intermediate, were the only glucose metabolites of many recently tested that stimulated insulin release. The effects of these two "new" insulin secretagogues on several pancreatic islet parameters were compared. Glyceraldehyde phosphate stimulated all of the insulin it released during the first 5 min after islets were exposed to it, and its maximum effect on calcium uptake was observed at 5 min. Monomethyl succinate stimulated insulin release mostly during the last 30 min of a 1-h incubation and its maximum effect on calcium uptake was at 60 min after it was applied to islets. Monomethyl succinate-induced insulin release, but not glyceraldehyde phosphate-induced insulin release, was inhibited by metabolic inhibitors (antimycin A, rotenone, cyanide, FCCP, fluoride, and iodoacetamide). This is consistent with the idea that monomethyl succinate is hydrolyzed to succinate which is metabolized intramitochondrially. The effects of glyceraldehyde suggest that glucose signals the first phase of insulin release by an agonist-like mechanism that originates in the cytosol and requires minimal energy. The effects of monomethyl succinate suggest that the signal for the second phase of glucose-induced insulin release originates in the mitochondrion and requires a large amount of energy.     

Effect of a single bout of resistance exercise on postprandial glucose and insulin response the next day in healthy, strength-trained men

Postprandial blood glucose and insulin levels are both risk factors for developing obesity, type-2 diabetes, and coronary heart diseases. To date, research has shown that a single bout of moderate- to high-intensity aerobic exercise performed 相似文献   

Role of nitric oxide mechanisms in gastric emptying of, and the blood pressure and glycemic responses to, oral glucose in healthy older subjects

The primary aims of this study were to evaluate the effects of the nitric oxide (NO) synthase inhibitor N(G)-nitro-l-arginine methyl ester (l-NAME) on gastric emptying (GE) of, and the blood pressure (BP), glycemic, insulin, and incretin responses to, oral glucose in older subjects. Eight healthy subjects (4 males and 4 females, aged 70.9 +/- 1.3 yr) were studied on two separate days, in double-blind, randomized order. Subjects received an intravenous infusion of either l-NAME (180 mug.kg(-1).h(-1)) or saline (0.9%) at a rate of 3 ml/min for 150 min. Thirty minutes after the commencement of the infusion (0 min), subjects consumed a 300-ml drink containing 50 g glucose labeled with 20 MBq (99m)Tc-sulfur colloid, while sitting in front of a gamma camera. GE, BP (systolic and diastolic), heart rate (HR), blood glucose, plasma insulin, and incretin hormones, glucose-dependant insulinotropic-polypeptide (GIP), and glucagon-like peptide-1 (GLP-1), were measured. l-NAME had no effect on GE, GIP, and GLP-1. Between -30 and 0 min l-NAME had no effect on BP or HR. After the drink (0-60 min), systolic and diastolic BP fell (P < 0.05) and HR increased (P < 0.01) during saline; these effects were attenuated (P < 0.001) by l-NAME. Blood glucose levels between 90 and 150 min were higher (P < 0.001) and plasma insulin were between 15 and 150 min less (P < 0.001) after l-NAME. The fall in BP, increase in HR, and stimulation of insulin secretion by oral glucose in older subjects were mediated by NO mechanisms by an effect unrelated to GE or changes in incretin hormones.     

Rapid translocation of hepatic glucokinase in response to intraduodenal glucose infusion and changes in plasma glucose and insulin in conscious rats

The rate of liver glucokinase (GK) translocation from the nucleus to the cytoplasm in response to intraduodenal glucose infusion and the effect of physiological rises of plasma glucose and/or insulin on GK translocation were examined in 6-h-fasted conscious rats. Intraduodenal glucose infusion (28 mg.kg(-1).min(-1) after a priming dose at 500 mg/kg) elevated blood glucose levels (mg/dl) in the artery and portal vein from 90 +/- 3 and 87 +/- 3 to 154 +/- 4 and 185 +/- 4, respectively, at 10 min. At 120 min, the levels had decreased to 133 +/- 6 and 156 +/- 5, respectively. Plasma insulin levels (ng/ml) in the artery and the portal vein rose from 0.7 +/- 0.1 and 1.8 +/- 0.3 to 11.8 +/- 1.5 and 20.2 +/- 2.0 at 10 min, respectively, and 12.4 +/- 3.1 and 18.0 +/- 4.8 at 30 min, respectively. GK was rapidly exported from the nucleus as determined by measuring the ratio of the nuclear to the cytoplasmic immunofluorescence (N/C) of GK (2.9 +/- 0.3 at 0 min to 1.7 +/- 0.2 at 10 min, 1.5 +/- 0.1 at 20 min, 1.3 +/- 0.1 at 30 min, and 1.3 +/- 0.1 at 120 min). When plasma glucose (arterial; mg/dl) and insulin (arterial; ng/ml) levels were clamped for 30 min at 93 +/- 7 and 0.7 +/- 0.1, 81 +/- 5 and 8.9 +/- 1.3, 175 +/- 5 and 0.7 +/- 0.1, or 162 +/- 5 and 9.2 +/- 1.5, the N/C of GK was 3.0 +/- 0.5, 1.8 +/- 0.1, 1.5 +/- 0.1, and 1.2 +/- 0.1, respectively. The N/C of GK regulatory protein (GKRP) did not change in response to the intraduodenal glucose infusion or the rise in plasma glucose and/or insulin levels. The results suggest that GK but not GKRP translocates rapidly in a manner that corresponds with changes in the hepatic glucose balance in response to glucose ingestion in vivo. Additionally, the translocation of GK is induced by the postprandial rise in plasma glucose and insulin.     

Seven days of aerobic exercise training improves conduit artery blood flow following glucose ingestion in patients with type 2 diabetes

The vasodilatory effects of insulin account for up to 40% of insulin-mediated glucose disposal; however, insulin-stimulated vasodilation is impaired in individuals with type 2 diabetes, limiting perfusion and delivery of glucose and insulin to target tissues. To determine whether exercise training improves conduit artery blood flow following glucose ingestion, a stimulus for increasing circulating insulin, we assessed femoral blood flow (FBF; Doppler ultrasound) during an oral glucose tolerance test (OGTT; 75 g glucose) in 11 overweight or obese (body mass index, 34 ± 1 kg/m2), sedentary (peak oxygen consumption, 23 ± 1 ml·kg?1·min?1) individuals (53 ± 2 yr) with non-insulin-dependent type 2 diabetes (HbA1c, 6.63 ± 0.18%) before and after 7 days of supervised treadmill and cycling exercise (60 min/day, 60-75% heart rate reserve). Fasting glucose, insulin, and FBF were not significantly different after 7 days of exercise, nor were glucose or insulin responses to the OGTT. However, estimates of whole body insulin sensitivity (Matsuda insulin sensitivity index) increased (P < 0.05). Before exercise training, FBF did not change significantly during the OGTT (1 ± 7, -7 ± 5, 0 ± 6, and 0 ± 5% of fasting FBF at 75, 90, 105, and 120 min, respectively). In contrast, after exercise training, FBF increased by 33 ± 9, 39 ± 14, 34 ± 7, and 48 ± 18% above fasting levels at 75, 90, 105, and 120 min, respectively (P < 0.05 vs. corresponding preexercise time points). Additionally, postprandial glucose responses to a standardized breakfast meal consumed under "free-living" conditions decreased during the final 3 days of exercise (P < 0.05). In conclusion, 7 days of aerobic exercise training improves conduit artery blood flow during an OGTT in individuals with type 2 diabetes.     

Endothelial cell injury by high glucose and heparanase is prevented by insulin, heparin and basic fibroblast growth factor

Background

Uncontrolled hyperglycemia is the main risk factor in the development of diabetic vascular complications. The endothelial cells are the first cells targeted by hyperglycemia. The mechanism of endothelial injury by high glucose is still poorly understood. Heparanase production, induced by hyperglycemia, and subsequent degradation of heparan sulfate may contribute to endothelial injury. Little is known about endothelial injury by heparanase and possible means of preventing this injury.

Objectives

To determine if high glucose as well as heparanase cause endothelial cell injury and if insulin, heparin and bFGF protect cells from this injury.

Methods

Cultured porcine aortic endothelial cells were treated with high glucose (30 mM) and/or insulin (1 U/ml) and/or heparin (0.5 μg/ml) and /or basic fibroblast growth factor (bFGF) (1 ng/ml) for seven days. Cells were also treated with heparinase I (0.3 U/ml, the in vitro surrogate heparanase), plus insulin, heparin and bFGF for two days in serum free medium. Endothelial cell injury was evaluated by determining the number of live cells per culture and lactate dehydrogenase (LDH) release into medium expressed as percentage of control.

Results

A significant decrease in live cell number and increase in LDH release was found in endothelial cells treated with high glucose or heparinase I. Insulin and/or heparin and/or bFGF prevented these changes and thus protected cells from injury by high glucose or heparinase I. The protective ability of heparin and bFGF alone or in combination was more evident in cells damaged with heparinase I than high glucose.

Conclusion

Endothelial cells injured by high glucose or heparinase I are protected by a combination of insulin, heparin and bFGF, although protection by heparin and/or bFGF was variable.     

Exercise intensity and glucose tolerance in trained and nontrained subjects

The improved glucose tolerance and increased insulin sensitivity associated with regular exercise appear to be the result, in large part, of the residual effects of the last bout of exercise. To determine the effects of exercise intensity on this response, glucose tolerance and the insulin response to a glucose load were determined in seven well-trained male subjects [maximal O2 uptake (VO2max) = 58 ml.kg-1.min-1] and in seven nontrained male subjects (VO2max = 49 ml.kg-1.min-1) in the morning after an overnight fast 1) 40 h after the last training session (control), 2) 14 h after 40 min of exercise on a cycle ergometer at 40% VO2max, and 3) 14 h after 40 min of exercise at 80% VO2max. Subjects replicated their diets for 3 days before each test and ate a standard meal the evening before the oral glucose tolerance test. No differences in the 3-h insulin or glucose response were observed between the control trial and before exercise at either 40 or 80% VO2max in the trained subjects. In the nontrained subjects the plasma insulin response was decreased by 40% after a single bout of exercise at either 40 or 80% VO2max (7.0 X 10(3) vs. 5.0 X 10(3), P less than 0.05; 3.8 X 10(3) microU.ml-1.180 min-1, P less than 0.01). The insulin response after a single bout of exercise in the nontrained subjects was comparable with the insulin responses found in the trained subjects for the control and exercise trials.(ABSTRACT TRUNCATED AT 250 WORDS)     

Insufficient islet compensation to insulin resistance vs. reduced glucose effectiveness in glucose-intolerant mice

This study evaluated the relative contribution of insulin-dependent mechanisms vs. mechanisms independent on dynamic insulin for glucose intolerance induced by high-fat diet. C57BL/6J mice underwent a frequently sampled intravenous glucose tolerance test (1 g/kg glucose) at 1 wk and 1, 3, and 10 mo after initiation of a high-fat diet (58% fat; control diet 11% fat) to measure glucose effectiveness (S(G)) and disposition index (DI), i.e., insulin sensitivity (S(I)) times early or total insulin secretion. Glucose disappearance (K(G)) and S(I) were reduced in high-fat-fed mice at all time points. Total (50 min) insulin secretion was sufficiently increased at all time points to compensate for the reduced S(I), as judged by normal DI(50) (min). In contrast, early (10 min) insulin secretion was not sufficiently increased; DI(10) (min) was reduced after 1, 3, and 10 mo. S(G) was reduced after 1 wk; the reduction persisted throughout the study period. Thus glucose intolerance induced by high-fat diet is, in early phases, solely explained by reduced glucose effectiveness, whereas insufficient early insulin secretion is of importance after long-term feeding.     

Enhancement of beta-cell sensitivity to glucose by oral fat load.

Recent studies have demonstrated that 6 h infusions of lipid emulsion enhance insulin release, whereas 24 h infusions inhibit insulin secretion. How insulin release is modulated after oral fat loading has not yet been elucidated. 17 healthy fasting volunteers were subjected to 3 experiments in random order: test 1 was a frequently sampled i. v. glucose tolerance test (FSIVGTT, 0.3 g/kg glucose), test 2 began with the ingestion of 50 % sunflower oil (1.5 g/kg) followed by FSIVGTT 4 h later. Test 3 was identical to test 2 with i. v. addition of 100 U/kg heparin prior to FSIVGTT. Glucose and insulin data were analyzed by minimal model assumptions - glucose sensitivity of the beta-cells (Theta1), acute insulin response (AIR) (10 min), 3 h insulin release (Theta2), glucose threshold of insulin secretion (h), insulin degradation rate (n), peripheral insulin sensitivity (S(I)), and glucose-dependent glucose disposal (S(G)). After drinking the fat emulsion, FFAs increased to 0.8 +/- 0.3 mmol/l (test 2) and to 3.0 +/- 0.3 mmol/l (test 3). Moderately increased FFA concentrations were associated with elevation of Theta1 (test 1, control 335 +/- 157 vs. test 2: 859 +/- 612 pM x min x mM(-1), p = 0.030). At high plasma FFA levels and in the presence of heparin (test 3), Theta1 was reduced compared to test 2 and unchanged compared to test 1. Theta2 and h were elevated in both tests 2 and 3 compared to test 1. No changes of n, S(I) and S(G) were found. In conclusion, the ingestion of sunflower oil triglyceride emulsion resulted in a 60 % increase in plasma free fatty acids and enhanced the capacity of beta-cells to secrete insulin. Heparin-induced high levels of FFA further augmented the total insulin release and inhibited parameters of glucose responsiveness.     

Differences in glucose handling by pancreatic A- and B-cells

Glucose exerts opposite effects upon glucagon and insulin release from the endocrine pancreas. Glucose uptake and oxidation were therefore compared in purified A- and B-cells. In purified B-cells, the intracellular concentration of glucose or 3-O-methyl-D-glucose equilibrates within 2 min with the extracellular levels, and, like in intact islets, the rate of glucose oxidation displays a sigmoidal dose-response curve for glucose. In contrast, even after 5 min of incubation, the apparent distribution space of D-glucose or 3-O-methyl-D-glucose in A-cells remains much lower than the intracellular volume. In A-cells, both the rate of 3-O-methyl-D-glucose uptake and glucose oxidation proceed proportional to the hexose concentration up to 10 mM and reach saturation at higher concentrations. Addition of insulin failed to affect 3-O-methyl-D-glucose or D-glucose uptake and glucose oxidation by purified A-cells. Glucose releases 30-fold more insulin from islets than from single B-cells, but this marked difference is not associated with differences in glucose handling. The rate of glucose oxidation is virtually identical in single and reaggregated B-cells and is not altered after addition of glucagon or somatostatin. It is concluded that the dependency of glucose-induced insulin release upon the functional coordination between islet cells is not mediated through changes in glucose metabolism.     

Kinetics of insulin action on protein synthesis in isolated adipocytes. Ability of glucose to selectively desensitize the glucose transport system without altering insulin stimulation of protein synthesis

When adipocytes were exposed to [3H]leucine for times ranging from 5 to 180 s, leucine was found to enter cells rapidly and equilibrate with the cell interior within 5 s. After an additional 15-30 s [3H]leucine was incorporated into nascent protein, and the rate of incorporation was linear for up to 6 h in both control and insulin-treated cells. Since treatment of adipocytes with 10 ng/ml insulin enhanced the rate of leucine incorporation 2-3-fold with minimal or no effect on the rate of protein degradation or leucine uptake, we conclude that the predominant effect of insulin is on enhancement of protein synthesis. To assess the time required for insulin to stimulate protein synthesis, we preincubated cells with 10 ng/ml of insulin for various times from 2 to 30 min and then measured [3H]leucine incorporation into protein during a 4-min assay. These results revealed that the insulin stimulation of protein synthesis is rapid (t 1/2 of 4.4 min), but 9-fold slower than insulin activation of glucose transport (t 1/2 less than 0.5 min under identical conditions). In contrast to the rapidity of insulin activation, we found that deactivation proceeded at much slower rates (t 1/2 of 32 and 21 min for protein synthesis and glucose transport, respectively). Desensitization of the glucose transport system has previously been shown to occur after adipocytes are exposed to high glucose and insulin. To examine the specificity of desensitization, we treated cells for 6 h with 20 mM glucose and 25 ng/ml insulin and then examined insulin sensitivity and maximal insulin responsiveness of both the glucose transport and protein synthesis systems. After treatment, the glucose transport was markedly insulin-resistant (60% loss in maximal insulin responsiveness and a marked loss in insulin sensitivity), whereas the protein synthesis system exhibited neither diminished insulin responsiveness nor loss of insulin sensitivity. In fact, insulin sensitivity actually increased, as indicated by the finding that less insulin was required to stimulate protein synthesis (insulin ED50 values of 0.25 and 18 ng/ml at 0 and 6 h of treatment). From these studies we conclude that desensitization of the glucose transport system by glucose and insulin treatment appears to be specific for this particular effector system and does not reflect a state of generalized cellular insulin resistance.     

Muscarinic receptors in pancreatic islets of the rat. Demonstration and dependence on long-term glucose environment

The presence of muscarinic receptors in islets of Langerhans was assessed by measurement of specific binding of [3H]methylscopolamine. Specific binding was defined as total binding minus binding obtained in the presence of 1000-fold or higher excess of unlabeled methylscopolamine. At 37 degrees C specific binding was significant after 1 min and plateaued after 10 min of incubation. Displacement of label by increasing concentrations of unlabeled methylscopolamine indicated a dissociation constant of 1.5 x 10(-12) M. Effects of methylscopolamine on insulin release were evaluated from the inhibitions of cholinergic-induced insulin release. 4 x 10(-10) M methylscopolamine inhibited acetylcholine (20 microM)-induced insulin release more than 60%. Binding was not influenced by the following variations during binding incubations: changing the glucose concentration from 0 to 8.3 mM, adding rotenon (1 microM) or omitting calcium from the incubation medium. Islets kept in tissue culture exhibited higher binding when cultured at 11.1 than at 3.3 mM glucose for 96 h. It is concluded that islets contain muscarinic receptors, the binding to which can be subject to alteration by the long-term glucose environment.     

Stimulatory role for endogenous opioid peptides on postexercise insulin secretion in rats

Endogenous opioid peptides (EOP) and prior exercise may modulate the stimulatory effect of glucose on insulin secretion. To gain insights into these relationships, we studied male Wistar rats (187-245 g) during sustained hyperglycemia by use of the glucose clamp technique. Four groups of sedentary fed rats (n = 8/group) either ran (Ex) at 24 m/min, 0% grade, or rested (R) for 40 min. Thirty minutes after Ex or R, arterial blood glucose was elevated to and maintained at 11 mM for 2 h by a variable glucose infusion. At the start of Ex or R rats had saline (Sal) or naloxone (Nal, an opioid antagonist) intravenous infusions for 160 min (40 min Ex + 30 min R + 90 min of a 120-min glucose clamp). Steady-state glucose infusion rates (SSGIR) were approximately 55 mg.kg-1.min-1 at the start of the clamp and declined significantly over the 2nd h to approximately 45 mg.kg-1.min-1. No significant differences existed in SSGIR between groups. R-Sal and Ex-Sal groups did not differ in their insulin response to hyperglycemia. In contrast, when all groups were compared at the end of the Nal or Sal infusion, Ex-Nal had the lowest insulin concentration (749 +/- 174 pmol/l), whereas the R-Nal group had the highest (1,581 +/- 216 pmol/l, P less than 0.05). These data suggest a stimulatory role for EOP on insulin secretion that is expressed after a prior stress (Ex). Thus one function of exercise-induced activation of EOP may be to regulate insulin secretion in the immediate postexercise period.     

二甲双胍对多囊卵巢综合征肥胖型患者LH和FSH的影响

目的：探讨二甲双胍对多囊卵巢综合征肥胖型患者血清中胰岛素、LH和FSH水平的影响。方法：将84例PCOS肥胖型患者随机分成44例对照组（克罗米芬）和40例观察组（二甲双胍）,采用放射免疫法测定黄体生成素（LH）和卵泡刺激素（FSH）的水平,分别于服药前（0分钟）和服后60、120分钟经前臂静脉采血,测血糖浓度及血清胰岛素水平。结果：对照组患者治疗前0min、60min及120min的血糖OGTT分别为（4．57±0．25）mmol／L、（8．38±7．05）mmol/L（7.21±0．12）mmol／L。治疗后0min、60min及120min的血糖OGTT无明显变化。观察组患者治疗前0min、60min及120min的血糖OGTT分别为（4．11±0．31）mmol／L、（8．23±6．57）mmol／L及（7．25±0．13）mmol／L,治疗后0min、60min及120min的血糖0GTT明显降低。对照组患者治疗前血清中胰岛素为（47．32±9．52）U／ml,治疗后为（42．25±7．65）U／ml,治疗前后无明显差异。观察组患者治疗前血清中胰岛素为（46．41±6．11）U／ml,治疗后血清胰岛素水平明显降低。对照组患者治疗后血清中LH为（17．22±2．14）mU／ml,FSH为（1．24±0．33）mU／ml,而与对照组相比,观察组患者血清中的LH明显降低,而FSH水平升高。结论：二甲双胍导致多囊卵巢综合征患者血清中胰岛素水平降低,从而减轻了胰岛素对LH的刺激作用,使LH水平下降,FSH升高,进而改善机体的激素紊乱,最终达到治疗PCOS的目的。