Reduced glucose transport and increased binding of insulin in adipocytes from diabetic and fasted rats

1. Animals made diabetic by injection of streptozotocin or animals after 3 days of fasting show decreased insulin levels and a decrease in mean cell diameter of adipocytes from epidydymal fat pads in comparison with cells from normal animals. 2. 14CO2 production from D-[U-14C]glucose is impaired in diabetic and fasted animals both in presence or in absence of a concentration of insulin stimulating 14CO2 production maximally. 3. Insulin binding is increased in adipocytes from diabetic and fasted animals due to changes in affinity. 4. Transport studies show that basal and insulin stimulated 2-deoxy[1-14C]-glucose transport is decreased in absolute terms due to a decrease in V and an increase in Km. 5. The relative stimulatory effect of insulin is impaired in adipocytes of diabetic and fasted animals. 6. A shift of the maximal effect of insulin to lower insulin levels is seen in these cells.     

Sulphonylureas-induced increase in insulin binding and glucose metabolism by isolated rat adipocytes

The effects of oral hypoglycaemic drugs, SPC-703 (n-/p-toluenesulphonyl/-5-methyl-2-pirazoline-1-carbonami de) and tolbutamide on insulin binding and glucose metabolism by isolated adipocytes were studied. After 10 days of administration of both sulphonylurea derivatives, no differences were observed in insulin concentration between both experimental and the control groups of animals, despite a significant fall in blood glucose level. SPC-703 and tolbutamide in concentrations of 1 mM added in vitro to the suspension of adipocytes had no effect on insulin binding or on basal and insulin simulated glucose metabolism. Daily administration of 300 mg/kg body weight of SPC-703 or tolbutamide for 10 days resulted in 48% and 34% increase of specific binding of insulin by adipocytes, respectively. From the Scatchard plot analysis we noted that the increase of binding resulted from increased affinity of insulin receptors for hormone. Simultaneous increase in basal and insulin stimulated glucose metabolism by adipocytes, as measured by 14CO2 production and 14C incorporation into cellular lipids, was observed. The results indicate that hypoglycaemic action of sulphonylureas may be explained by increased affinity of insulin receptors and the stimulating action of these compounds on peripheral glucose metabolism.     

Diet fat alters the structure and function of the nuclear envelope: modulation of membrane fatty acid composition, NTPase activity and binding of triiodothyronine

Mice were fed a diet either high or low in P/S ratio to determine the effect of altering dietary lipid on the fatty acid composition of liver nuclear envelopes and thereby on functions of the nuclear envelope. Mice fed the high P/S diet exhibited higher levels of C18:2 omega 6 and unsaturates in liver nuclear envelopes, higher specific activity of NTPase and specific binding for L-triiodothyronine at 15 degrees C and 22 degrees C compared with the low P/S diet fed group. These observations indicate that diet-induced differences in the fatty acid composition of nuclear envelope lipid affects functions of the nuclear envelope.     

Dietary fat and the diabetic state alter insulin binding and the fatty acyl composition of the adipocyte plasma membrane.

Control and diabetic rats were fed on semi-purified high-fat diets providing a polyunsaturated/saturated fatty acid ratio (P/S) of 1.0 or 0.25, to examine the effect of diet on the fatty acid composition of major phospholipids of the adipocyte plasma membrane. Feeding the high-P/S diet (P/S = 1.0) compared with the low-P/S diet (P/S = 0.25) increased the content of polyunsaturated fatty acids in membrane phospholipids in both control and diabetic animals. The diabetic state decreased the content of polyunsaturated fatty acids, particularly arachidonic acid, in adipocyte membrane phospholipids. The decrease in arachidonic acid in membrane phospholipids of diabetic animals tended to be normalized to within the control values when high-P/S diets were given. For control animals, altered plasma-membrane composition was associated with change in insulin binding, suggesting that change in plasma-membrane composition may have physiological consequences for insulin-stimulated functions in the adipocyte.     

Effect of insulin on glucose metabolism in adipocytes from virgin and late-pregnant rats.

Under basal conditions (zero insulin), paraovarian adipocytes from 19-day-pregnant rats exhibited the same rates of [U-14C]glucose conversion into CO2 and total lipids as did those from age-matched virgin rats. The dose-response curves for insulin stimulation of glucose metabolism were similar in both groups: maximal response (+100% over basal values) and high sensitivity (half-maximal effect at 0.05 nM-insulin). The present results suggest that the insulin resistance in vivo that occurs during late pregnancy may involve circulating factors lost in vitro.     

Dietary fat type alters glucose metabolism in isolated rat hepatocytes

Dietary fat type can influence the regulation of carbohydrate metabolism in multiple tissue types. The influence of feeding high-fat (40% of kilocalories) diets containing either menhaden oil (MO) or coconut oil (CO) on hepatic glycogenolytic and gluconeogenic capacities was studied in isolated rat hepatocytes. Estimates of both glycogenolytic and gluconeogenic capacities were performed on hepatocytes isolated from fed and fasted animals, respectively. In MO-fed animals, both basal and hormone-stimulated rates of glucose production were significantly greater than those in CO-fed animals. However, both groups displayed a similar maximal increase in glucose production above basal for glucagon and epinephrine (2.3- and 1.9-fold, respectively). Basal rates of adenosine 3′,5′-cyclic phosphate (cAMP) production were not different between groups whereas glucagon-stimulated cAMP production was increased twofold in the MO-fed group. In both MO and CO groups, the addition of 10 nM insulin reduced glucose production in fed animals to similar absolute rates. In animals fasted for 24 hours, gluconeogenic capacity was estimated using 10 mM pyruvate, lactate, or glycerol. Glucose production from all substrates was significantly greater in CO-fed animals. In addition to increased gluconeogenic rates, maximal phosphoenolpyruvate carboxykinase (PEPCK) activity was increased in the CO-fed group. Insulin reduced glucose production in both dietary groups, but the absolute rate of glucose production was 28% greater in the CO-fed group relative to the MO-fed group. In summary, dietary fat type can markedly influence the regulation of hepatic glucose metabolism in multiple metabolic pathways. MO feeding promoted glycogenolysis and sensitivity to insulin whereas CO feeding favored gluconeogenesis and reduced insulin sensitivity.     

Effect of purified phospholipases on glucose transport, insulin binding, and insulin action in isolated rat adipocytes

The influence of alterations in phospholipid structure by phospholipase treatment on insulin action and glucose transport in rat adipocytes was studied. It appeared that phospholipase A2 from bee venom caused a breakdown of approximately 50% of phosphotidylcholine without lysis of the cells. Because of this treatment, insulin binding was increased, resulting in an increased sensitivity of glucose transport towards lower insulin concentrations. Moreover, an increased affinity of the transport system for 2-deoxyglucose was observed. Phospholipase C from Clostridium welchii caused complete lysis of adipocytes. Phospholipase A2 from Crotalus adamenteus was without effect.     

Hindlimb suspension increases insulin binding and glucose metabolism

After 28 days of hindlimb-suspension, insulin binding, 2-deoxy-D-glucose (2-DG) uptake, and glucose metabolism (glycolysis and glycogenesis) were determined at various insulin concentrations (0.2-30 nM) in soleus muscle of young (18-day-old) and adult (150-day-old) rats. Compared with age-matched controls the young (YS) and adult suspended (AS) rats had lower soleus and body weights and insulin levels (P less than 0.05). Per milligram of protein, insulin binding, 2-DG uptake, and the rate of glycolysis were increased by approximately 200%, and the rate of glycogenesis was increased approximately 100% in the YS group (P less than 0.05). Except for a reduction in glycogenesis (P less than 0.05) all other parameters also increased in the AS rats (P less than 0.05). On the basis of the whole muscle the rate of glucose metabolism (glycogenesis + glycolysis) was reduced in the YS rats (P less than 0.05), but in the AS rats glucose metabolism was similar to the controls. Thus the increased glucose metabolism (i.e., per milligram of protein) in the YS and AS groups may represent a compensatory response by atrophied muscle to attempt to sustain glucose removal from the circulation. Because greater insulin binding occurred in YS muscle [35% slow-twitch (ST)] than in the control group (70% ST), and greater insulin binding occurred in the AS (81% ST) than in the control group (90% ST), higher insulin binding capacities are not always related to a high proportion of ST muscle fibers. In conclusion, after hindlimb suspension, marked increments in insulin binding and glucose metabolism occur in the soleus muscle.     

A low-protein diet during pregnancy alters glucose metabolism and insulin secretion

In pancreatic islets, glucose metabolism is a key process for insulin secretion, and pregnancy requires an increase in insulin secretion to compensate for the typical insulin resistance at the end of this period. Because a low-protein diet decreases insulin secretion, this type of diet could impair glucose homeostasis, leading to gestational diabetes. In pancreatic islets, we investigated GLUT2, glucokinase and hexokinase expression patterns as well as glucose uptake, utilization and oxidation rates. Adult control non-pregnant (CNP) and control pregnant (CP) rats were fed a normal protein diet (17%), whereas low-protein non-pregnant (LPNP) and low-protein pregnant (LPP) rats were fed a low-protein diet (6%) from days 1 to 15 of pregnancy. The insulin secretion in 2.8 mmol l(-1) of glucose was higher in islets from LPP rats than that in islets from CP, CNP and LPNP rats. Maximal insulin release was obtained at 8.3 and 16.7 mmol l(-1) of glucose in LPP and CP groups, respectively. The glucose dose-response curve from LPNP group was shifted to the right in relation to the CNP group. In the CP group, the concentration-response curve to glucose was shifted to the left compared with the CNP group. The LPP groups exhibited an "inverted U-shape" dose-response curve. The alterations in the GLUT2, glucokinase and hexokinase expression patterns neither impaired glucose metabolism nor correlated with glucose islet sensitivity, suggesting that β-cell sensitivity to glucose requires secondary events other than the observed metabolic/molecular events.     

Effect of lactation on insulin sensitivity of glucose metabolism in rat adipocytes

During lactation glucose metabolism in paraovarian adipocytes is characterized by a 40 and 80% decrease of glucose incorporation into CO2 and fatty acids in the presence of insulin. In contrast with the stimulation by insulin of glucose incorporation into lactate, glycerol remains unchanged. As a result, insulin sensitivity of total glucose metabolism (oxidation and lipid synthesis) is not altered in adipocytes from lactating rats.     

Regulation of glucose utilization and lipogenesis in adipose tissue of diabetic and fat fed animals: Effects of insulin and manganese

In order to evaluate the modulatory effects of manganese, high fat diet fed and alloxan diabetic rats were taken and the changes in the glucose oxidation, glycerol release and effects of manganese on these parameters were measured from adipose tissue. An insulin-mimetic effect of manganese was observed in the adipose tissue in the controls and an additive effect of insulin and manganese on glucose oxidation was seen when Mn²⁺ was addedin vitro. The flux of glucose through the pentose phosphate pathway and glycolysis was significantly decreased in high fat fed animals. Although thein vitro addition of Mn²⁺ was additive with insulin when¹⁴CO2 was measured from control animals, it was found neither in young diabetic animals (6–8 weeks old) nor in the old (16 weeks old). Both insulin and manganese caused an increased oxidation of carbon-1 of glucose and an increase of its incorporation into¹⁴C-lipids in the young control animals; the additive effect of insulin and manganese suggests separate site of action. This effect was decreased in fat fed animals, diabetic animals and old animals. Manganese alone was found to decrease glycerol in both the control and diabetic adipose tissue inin vitro incubations. The results of the effects of glucose oxidation, lipogenesis, and glycerol release in adipose tissue of control and diabetic animals of different ages are presented together with the effect of manganese on adipose tissue from high fat milk diet fed animals.     

Cyclic AMP modulates insulin binding and induces post-receptor insulin resistance of glucose transport in isolated rat adipocytes

The effect of cAMP on insulin binding and insulin stimulation of glucose transport was investigated in isolated rat adipocytes. Preincubation for 30 min in medium containing 16 mmol/l glucose and either db-cAMP or bromo-cAMP in concentrations of 10(-4)-10(-3) M inhibited high affinity binding of insulin by 15 to 30% and glucose transport by 30 to 50%. Preincubation with IBMX (10(-4)-10(-3) M) reduced insulin binding by 25% and glucose transport by 70%. Closer analysis of these data indicated that preincubation with these compounds caused not only a decrease in insulin binding but also a post-receptor resistance. High intracellular cyclic AMP-levels seem therefore to induce insulin resistance at both receptor and post-receptor levels.     

Effect of exercise on insulin binding and glucose transport in adipocytes of normal humans

Acute exercise increases insulin binding to its receptors on blood cells. Whether the enhanced insulin binding explains the exercise-induced increase in glucose uptake is unclear, since insulin binding and glucose uptake have not been measured simultaneously in a target tissue of insulin. In this study, we determined insulin binding and the rate of glucose transport in adipocytes obtained by needle biopsy from 10 healthy men before and after 3 h of cycle-ergometric exercise. During the exercise, plasma glucose (P less than 0.01) and insulin (P less than 0.001) fell and serum free fatty acid level rose 4.3-fold (P less than 0.001). 125I-insulin binding to adipocytes remained unchanged during exercise. The rate of basal glucose transport clearance fell from 28.1 +/- 5.7 fl.cell-1.s-1 to 22.9 +/- 5.6 fl.cell-1.s-1 (P less than 0.005), and the insulin-stimulated increase in glucose transport rate rose from 196 +/- 26 to 279 +/- 33% (P less than 0.025) during the exercise. Thus, in the adipocytes during exercise, the basal glucose transport rate and the responsiveness of glucose transport to insulin changed in the absence of alterations in insulin binding. These data indicate that the exercise-induced changes in insulin binding show tissue specificity and do not always parallel alterations in glucose transport.     

Effects of insulin on glucose metabolism in isolated human fat cells

Isolated fat cells were used for the study of in vitro effects of insulin on glucose metabolism in human and rat adipose tissue. In human subcutaneous fat cells, effects of insulin could be detected at concentrations of glucose in the medium from 1 to 10 micro moles/ml. Cellular responsiveness was inversely proportional to the glucose level. At a constant concentration of 6 micro moles of glucose per ml, the effects of insulin at various concentrations up to 500 micro U/ml were investigated. At the highest concentration, which gave the maximal response, there was a 100% increase in the conversion of glucose-U-(14)C to glyceride-glycerol and a 40% increase in glucose oxidation. The dose-response curve was steepest between 2 and 20 micro U/ml. Rat epididymal fat cells were much more responsive to insulin. Glucose lipogenesis and pentose cycle activity could also be demonstrated in rat cells, whereas these activities could not be shown in fat cells from human omental and subcutaneous tissue. The findings for human cells are attributed to changes in cellular activity during preparation.     

Effects of exercise on insulin binding and glucose metabolism in muscle

To elucidate the mechanism of enhanced insulin sensitivity by muscle after exercise, we studied insulin binding, 2-deoxy-D-[1-14C]glucose (2-DOG) uptake and [5-3H]glucose utilization in glycolysis and glycogenesis in soleus and extensor digitorum longus (EDL) muscles of mice after 60 min of treadmill exercise. In the soleus, glycogenesis was increased after exercise (P less than 0.05) and remained sensitive to the action of insulin. Postexercise insulin-stimulated glycolysis was also increased in the soleus (P less than 0.05). In the EDL, glycogenesis was increased after exercise (P less than 0.05). However, this was already maximal in the absence of insulin and was not further stimulated by insulin (0.1-4 nM). The disposal of glucose occurred primarily via the glycolytic pathway (greater than 60%) in the soleus and EDL at rest and after exercise. The uptake of 2-DOG uptake was not altered in the soleus after exercise (4 h incubation at 18 degrees C). However, with 1-h incubations at 37 degrees C, a marked increase in 2-DOG uptake after exercise was observed in the soleus (P less than 0.05) in the absence (0 nM) and presence of insulin (0.2-4 nM) (P less than 0.05). A similar postexercise increase in 2-DOG uptake occurred in EDL. Despite the marked increase in glucose uptake and metabolism, no changes in insulin binding were apparent in either EDL or soleus at 37 degrees C or 18 degrees C. This study shows that the postexercise increase of glucose disposal does not appear to be directly attributable to increments in insulin binding to slow-twitch and fast-twitch muscles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Increased insulin mediated glucose metabolism in fat cells from I versus C57BL mice

The purpose of this study was to determine whether adipocytes from I strain mice, which are characterized by a greater in vivo glucose tolerance than most other strains, had a higher capacity to utilize glucose in response to physiological concentrations of insulin. Using C57BL mice as a control strain, we examined the effect of insulin on glucose metabolism in epididymal and inguinal adipocytes from 2-month-old male mice. Body weight was only slightly less (7%) for the I mice than for the C57BL mice, but fat pad sizes were 60 and 20% less for epididymal and inguinal depots, respectively, in the I mice. Fat cell size was also smaller in epididymal adipocytes from the I mice than from the C57BL mice. Fat cell size of inguinal adipocytes was similar in the two strains. Without insulin the rates of [U-14C]glucose incorporation into CO2 or lipids were twofold higher in cells from the I mice than in those from the C57BL mice. Maximal insulin concentration (2.5 nM) increased glucose metabolism by 140 and 500% in epididymal and inguinal adipose cells, respectively, in the I mice versus 30 and 50% in the C57BL mice. The maximal effect of insulin was reached at a much higher insulin concentration in the I mice than in the C57BL mice. The activity of fatty acid synthetase was four- to sixfold higher in fat cells from I than in those from C57BL mice. These results demonstrate an increased insulin responsiveness of glucose metabolism in fat cells from the I mice related to an increased lipogenic capacity. Furthermore, they show that adipose tissue in mice exhibits significant regional differences in terms of insulin responsiveness of glucose metabolism.     

Effects of insulin and norepinephrine on glucose transport and metabolism in rat brown adipocytes. Potentiation by insulin of norepinephrine-induced glucose oxidation

Glucose is an important fuel for rat brown adipose tissue in vivo and its utilization is highly sensitive to insulin. In this study, the different glucose metabolic pathways and their regulation by insulin and norepinephrine were examined in isolated rat brown adipocytes, using [6-14C]glucose as a tracer. Glucose utilization was stimulated for insulin concentrations in the range of 40-1000 microU/ml. Furthermore, the addition of adenosine deaminase (200 mU/ml) or adenosine (10 microM) did not alter insulin sensitivity of glucose metabolism. The major effect of insulin (1 mU/ml) was a respective 7-fold and 5-fold stimulation of lipogenesis and lactate synthesis, whereas glucose oxidation remained very low. The 5-fold stimulation of total glucose metabolism by 1 mU/ml of insulin was accompanied by an 8-fold increase in glucose transport. In the presence of norepinephrine (8 microM), total glucose metabolism was increased 2-fold. This was linked to a 7-fold increase of glucose oxidation, whereas lipogenesis was greatly inhibited (by 72%). In addition, norepinephrine alone did not modify glucose transport. The addition of insulin to adipocytes incubated with norepinephrine, induced a potentiation of glucose oxidation, while lipogenesis remained very low. In conclusion, in the presence of insulin and norepinephrine glucose is a oxidative substrate for brown adipose tissue. However the quantitative importance of glucose as oxidative fuel remains to be determined.