Palmitic acid stimulates glucose incorporation in the adipocyte by a mechanism likely involving intracellular calcium

The effect of palmitic acid on basal and insulin-stimulated incorporation of glucose into rat adipocytes was studied. Palmitic acid (2.40 mM) stimulated basal as well as insulin-stimulated glucose incorporation in rat adipocytes three and twofold, respectively. Similar degrees of stimulation of basal glucose oxidation by palmitate were also observed. The ability of palmitic acid to stimulate glucose uptake was additive with respect to the stimulation induced by insulin and was proportional to the palmitic acid concentration between 0.15 mM and 2.40 mM. Stimulation of glucose incorporation by palmitic acid was inhibited by preincubating the cells with quin2-AM, which accumulates intracellularly yielding the trapped chelator form. quin2, which binds intracellular Ca2+.The concentration of quin2-AM required for half-maximal inhibition of palmitic acid stimulated glucose incorporation was 3.8 +/- 1.2 microM (mean +/- SEM). The inhibition of palmitic acid-stimulated glucose incorporation by quin2-AM (10 microM) was overcome by incubating cells with the Ca2+ ionophore, A23187, in the presence of extracellular Ca2+ (2.6 mM). Chelation of extracellular Ca2+ with EGTA did not significantly affect the magnitude of palmitic acid-stimulated glucose incorporation. Dantrolene (12.5-100 microM) failed to affect basal or palmitic acid-stimulated glucose incorporation. These findings suggest that palmitic acid stimulates incorporation of glucose in the adipocyte by a mechanism dependent upon intracellular but not extracellular Ca2+.     

Incorporation of (U-14C)-glucose into glycogen in normal rat pancreatic islets

The incorporation of glucose into glycogen was determined in pancreatic islets isolated from normal rats and incubated with glucose (5 or 20 mM) and compounds known to affect glycogen metabolism in other tissues. Incubation of pancreatic islets with glucose (20 mM) induced a marked increase in radioactive glycogen. Exposure to epinephrine in the presence of glucose (20 mM) slightly increased incorporation of glucose into glycogen. In contrast the incorporation of glucose into glycogen was not affected when isolated islets were exposed to glucagon or insulin, whereas anti-insulin serum in the incubation medium decreased radioactive glycogen formation.     

Glycosyl transferase activity in the brush border membrane of Hymenolepis diminuta

The isolated brush border membrane of Hymenolepis diminuta incorporates radiolabeled glucose when incubated in the presence of uridine diphospho(UDP)-D-(6-3H)glucose. The pH optimum for incorporation was 7.0 to 7.2 regardless of the buffer used. Transferase activity was maximal in 200 mM Tris buffer; 100 mM phosphate buffer inhibited significantly the incorporation of radiolabeled glucose, whereas 50 mM Tris-maleate and 100 mM PIPES resulted in moderate inhibition of activity. Incorporation of labeled glucose was not inhibited by low concentrations (0.01%) of Triton X-100, but activity was inhibited 50% by 0.25% Triton X-100. Addition of divalent cations to the brush border membrane preparation did not activate transferase activity, but addition of chelating agents (i.e., EDTA or EGTA) inhibited transferase activity nearly 90%. Incorporation of labeled glucose was inhibited by UDP, guanosine diphosphate (GDP), UDP- and GDP-activated monosaccharides, and monosaccharides, indicating that the transferase activity lacked substrate specificity.     

The effects of insulin and hyperglycemia on surfactant phospholipid synthesis in organotypic cultures of type II pneumocytes

Organotypic cultures of fetal type II epithelial cells were incubated in media containing insulin at concentrations ranging from 10 to 400 microunits/ml. Exposure to insulin resulted in increased glucose uptake from the media and in the rate of glucose conversion to CO2. Furthermore, both glucose uptake and CO2 production were dependent on the glucose concentration in the media. Surfactant and residual phosphatidylcholine fractions were isolated from the organotypic cultures by sucrose density centrifugation. The presence of low doses of insulin (10-25 microunits/ml) caused a significant increase in the incorporation of glucose into both surfactant and residual phosphatidylcholine. Insulin at levels of 100 microunits/ml or higher resulted in a significant decrease in glucose incorporation into both phosphatidylcholine fractions. Increasing the media glucose concentration from 5.6 to 20 mM caused a 2- to 2.5-fold increase in glucose utilization for surfactant and residual phospholipid synthesis, but did not produce any significant changes in choline incorporation into either surfactant or residual phosphatidylcholine. The addition of 400 microunits/ml of insulin to media containing 20 mM glucose, however, resulted in a 20% decrease in choline incorporation into surfactant phosphatidylcholine but had no effect on choline incorporation into residual phosphatidylcholine. These results suggest that insulin is an important hormone regulating fetal lung maturation and that hyperinsulinemia may be responsible for the delayed lung development in infants of diabetic mothers.     

Stimulation by glucagon of the incorporation of U-14C-labeled substrates into glucose by isolated hepatocytes from fed rats.

The effect of glucagon on the incorporation of U-14C-labeled lactate, pyruvate or alanine into glucose has been studied using isolated hepatocytes from livers of fed rats. Rates of incorporation into glucose were about the same as observed in perfused liver preparations provided precautions were taken to avoid depletion of certain metabolities by the preparative procedures. With each substrate, stimulation of the incorporation into glucose by a maximally effective concentration of glucagon (10 nM) was associated with about a 75% reduction in the substrate concentration required for a half-maximal rate and with about a 30% increase in maximum rate. Consequently, the hormone caused a substantial (2--4-fold) stimulation when any one of the above substrates was present at a near physiological concentration, but brought about only a relatively small stimulation (1.4-fold) when very high substrate concentrations were used. Provision of cytoplasmic reducing equivalents (by ethanol addition), or of precursor for acetyl-coenzyme A formation (by acetate addition)-stimulated incorporation of labeled alanine into glucose and their effects were additive with that of glucagon. This suggested that provision of either of these intermediates was not a means by which the hormone increased the incorporation of labeled substrate into glucose. NH4+ stimulated the incorporation of 20 mM [U-14C] lactate into glucose 2-fold, probably by promoting glutamate synthesis and thus enhancing the transamination of oxaloacetate to aspartate. Evidence was obtained to support the view that glucagon also increases glutamate production (presumably from endogenous protein). However, the stimulation of incorporation into glucose from 20 mM [U-14C] lactate by NH4+ plus glucagon was synergistic. This suggested that glucagon also stimulated the incorporation of labeled substrate into glucose by additional means. Stimulation of the incorporation of [U-14C] alanine into glucose by beta-hydroxybutyrate plus glucagon was also synergistic. This suggested that another action of glucagon may be to provide more intramitochondrial reducing potential.     

Influence of pilocarpine pretreatment on (pro)insulin biosynthesis of isolated islets of rats.

3[H]-Leucine incorporation into (pro)insulin and insulin secretion was investigated using islets prepared by collagenase digestion from pancreata of rats pretreated with the cholimimetic agent pilocarpine or with saline (controls). Under the influence of pilocarpine pretreatment the [3H]-leucine incorporation into islet proteins with insulin immunoreactivity is enhanced at 6 mM glucose in the incubation medium of the islets but the incorporated radioactivity at 18 mM glucose is independent of the pretreatment of the animals. Only small or no changes were found regarding insulin secretion. It is concluded that an influence of pilocarpine pretreatment should be taken into consideration using such islets for studies on the regulation of (pro)insulin biosynthesis.     

Inhibition of intracellular proteolysis by insulin in isolated rat hepatocytes. Possible role of internalized hormone

The mechanism of insulin's action upon intracellular proteolysis in isolated hepatocytes was studied. At 37 degrees C insulin inhibited intracellular degradation of intracellular proteins in a dose-dependent manner. A maximal 40% inhibition of intracellular proteolysis was achieved at an insulin concentration of 500 ng/ml with a half-maximal inhibition observed at 2.5 ng/ml of insulin. Insulin inhibited intracellular proteolysis both in the presence and in the absence of amino acids in the incubation mixture. Low concentrations of trypsin (10 micrograms/ml) mimicked insulin's effect upon glucose incorporation into glycogen, but not on intracellular proteolysis. Four protease inhibitors (phenylmethylsulfonyl fluoride (0.5 mM), p-nitrophenyl-p-guanidinobenzoate (0.25 mM), p-tosyl-L-arginine methyl ester (1 mM), and N alpha-p-tosyl-L-lysine chloromethyl ketone (1 mM) blocked the stimulatory effect of insulin upon [14C]glucose incorporation into glycogen, but did not affect the inhibitory action of insulin upon intracellular proteolysis. These results suggest that the mechanism of insulin's action upon intracellular proteolysis differs from that involved in stimulation of glycogenesis. Low temperature (15 degrees C) and short time exposure (10 min) of the hepatocytes to insulin eliminated the inhibitory effect of insulin on intracellular proteolysis. Similarly, insulin's effect on intracellular proteolysis was eliminated by dansylcadaverine, a transglutaminase inhibitor that blocked insulin internalization. In contrast, dansylcadaverine had no effect on insulin's ability to stimulate [14C]glucose incorporation into glycogen. These experiments strongly suggest the necessity of insulin internalization for its inhibitory effect on endogenous protein degradation.     

Role of PKC and TGF-beta receptor in glucose-induced proliferation of smooth muscle cells

The role of protein kinase C (PKC) and transforming growth factor (TGF)-beta in the proliferation of vascular smooth muscle cells (SMCs) under a high glucose condition was investigated. [3H]-thymidine incorporation under 20 mM glucose was significantly accelerated compared with that under 5.5 mM glucose, and this increase was inhibited by an anti-TGF-beta antibody or a PKC-beta specific inhibitor, LY333531. The amount of active and total TGF-beta1 in the conditioned media did not differ between 5.5 and 20 mM glucose. However, the expression of TGF-beta receptor type II under 20 mM glucose was significantly increased, but that of the TGF-beta receptor type I was not. This increased expression of the TGF-beta receptor type II was prevented by LY333531. These observations suggest that the increased expression of the TGF-beta receptor type II via PKC-beta plays an important role in the accelerated proliferation of SMCs under a high glucose condition, leading to the development of diabetic macroangiopathy.     

Evidence for glucose-responsive and -unresponsive pools of phospholipid in pancreatic islets

The effect of glucose on the metabolism of phospholipids in pancreatic islets was studied with three radioactive phospholipid precursors, [32P]orthophosphate, [3H]myoinositol, and [3H]arachidonic acid, to determine the conditions necessary for studying the breakdown of prelabeled phospholipids. Islets were incubated in the presence of a radioactive precursor for 60 or 90 min and in the presence of either 3.3 or 16.7 mM glucose to prelabel phospholipids. To study the breakdown of prelabeled phospholipid, the unincorporated precursor was removed and the islets were reincubated for 15 or 20 min under conditions that either did or did not stimulate insulin release. Prelabeling in the presence of a noninsulinotropic concentration of glucose (3.3 mM) supported the incorporation of precursors into almost all islet phospholipids studied. Prelabeling in an insulinotropic concentration of glucose (16.7 mM) increased the incorporation of precursors into a number of phospholipids even more; and reincubation in 16.7 mM glucose caused a rapid loss of radioactivity from specific phospholipids (phosphatidylinositol and/or phosphatidylcholine, depending on the precursor). This breakdown was observed only when islets had been prelabeled in 16.7 mM glucose. The amount of radioactivity lost from phospholipid corresponded roughly to the additional amount incorporated during the prelabeling in the high concentration of glucose. Radioactivity in phospholipids in islets prelabeled in 3.3 mM glucose or in nonsecretagogue metabolic fuels, such as malate plus pyruvate, did not decrease when the islets were subsequently exposed to 16.7 mM glucose, nor did it decrease in 3.3 mM glucose when these islets had been prelabeled in 16.7 mM glucose. Glyceraldehyde, an insulin secretagogue, but not galactose or L-glucose which are not insulin secretagogues, stimulated phospholipid breakdown in islets that had been prelabeled in 16.7 mM glucose. Depriving islets of extracellular calcium, a condition that inhibits insulin release, inhibited phospholipid breakdown. The results suggest that pancreatic islets contain a glucose-responsive and a glucose-unresponsive phospholipid pool. The glucose-responsive pool becomes labeled and undergoes rapid turnover only under stimulatory conditions and may play a role in the stimulus-secretion coupling of insulin release.     

Response of sugar interconversion, starch and protein accumulation to supplied metabolites during pod filling in chickpea

Detached chickpea inflorescences bearing pods at 20 days after flowering (DAF) were cultured for 5 days in complete liquid medium supplemented separately with asparate, myo-inositol, alpha-ketoglutarate and phytic acid. Effect of these metabolites on sugar interconvestion and starch and protein accumulation in developing pods was studied. Substituting asparate (62.5 mM) for glutamine in culture medium decreased relative proportion of sucrose in all pod tissues but increased the level of sugars, starch and protein in pod wall and cotyledons. In cotyledons, whereas myo-inositol (75 mM) reduced the accumulation of starch without affecting protein level, alpha-ketoglutarate (44 mM) increased both starch and protein accumulation. Both myo-inositol and alpha-ketoglutarate increased relative proportion of sucrose in cotyledons. Phytic acid (1 mM) decreased in cotyledons 14C incorporation from glucose into EtOH extract (principally constituted by sugars), amino acids and proteins but increased the same into starch. In cotyledons, phytic acid also increased 14C incorporation from glutamate into amino acids but this increase was negatively correlated with protein synthesis. Phytic acid decreased the relative distribution of 14C from glucose and glutamate into sucrose from pod wall but enhanced the same into EtOH extract from embryo. Based on the results, it is suggested that mode of metabolic response to exogenously supplied metabolites widely differs in pod tissues of chickpea.     

Glyceroneogenesis and the supply of glycerol-3-phosphate for glyceride-glycerol synthesis in liver slices of fasted and diabetic rats

The pathways of glycerol-3-phosphate (G3P) generation for glyceride synthesis were examined in precision-cut liver slices of fasted and diabetic rats. The incorporation of 5 mM [U-(14)C]glucose into glyceride-glycerol, used to evaluate G3P generation via glycolysis, was reduced by approximately 26-36% in liver slices of fasted and diabetic rats. The glycolytic flux was reduced by approximately 60% in both groups. The incorporation of 1.0 mM [2-(14)C]pyruvate into glyceride-glycerol (glyceroneogenesis) increased approximately 50% and approximately 36% in slices of fasted and diabetic rats, respectively, which also showed a two-fold increase in the activity phosphoenolpyruvate carboxykinase. The increased incorporation of 1.0 mM [2-(14)C]pyruvate into glyceride-glycerol by slices of fasted rats was not affected by the addition of 5 mM glucose to the incubation medium. The activity of glycerokinase and the incorporation of 1 mM [U-(14)C]glycerol into glyceride-glycerol, evaluators of G3P formation by direct glycerol phosphorylation, did not differ significantly from controls in slices of the two experimental groups. Rates of incorporation of 1 mM [2-(14)C]pyruvate and [U-(14)C]glycerol into glucose of incubation medium (gluconeogenesis) were approximately 140 and approximately 20% higher in fasted and diabetic slices than in control slices. It could be estimated that glyceroneogenesis by liver slices of fasted rats contributed with approximately 20% of G3P generated for glyceride-glycerol synthesis, the glycolytic pathway with approximately 5%, and direct phosphorylation of glycerol by glycerokinase with approximately 75%. Pyruvate contributed with 54% and glycerol with 46% of gluconeogenesis. The present data indicate that glyceroneogenesis has a significant participation in the generation of G3P needed for the increased glyceride-glycerol synthesis in liver during fasting and diabetes.     

Stimulation by glucagon of the incorporation of U-14 C-labeled substrates into glucose by isolated hepatocytes from fed rats

The effect of glucagon on the incorporation of U-¹⁴ C-labeled lactate, pyruvate or alanine into glucose has been studied using isolated hepatocytes from livers of fed rats. Rates of incorporation into glucose were about the same as observed in perfused liver preparations provided precautions were taken to avoid depletion of certain metabolities by the preparative procedures. With each substrate, stimulation of the incorporation into glucose by a maximally effective concentration of glucagon (10 nM) was associated with about a 75% reduction in the substrate concentration required for a half-maximal rate and with about a 30% increase in maximum rate. Consequently, the hormone caused a substantial (2–4-fold) stimulation when any one of the above substrates was present at a near physiological concentration, but brought about only a relatively small stimulation (1.4-fold) when very high substrate concentrations were used. Provision of cytoplasmic reducing equivalents (by ethanol addition), or of precursor for acetyl-coenzyme A formation (by acetate addition)-stimulated incorporation of labeled alanine into glucose and their effects were additive with that of glucagon. This suggested that provision of either of these intermediates was not a means by which the hormone increased the incorporation of labeled substrate into glucose. NH₄⁺ stimulated the incorporation of 20 mM [U-¹⁴ C] lactate into glucose 2-fold, probably by promoting glutamate synthesis and thus enhancing the transamination of oxaloacetate to aspartate. Evidence was obtained to support the view that glucagon also increases glutamate production (presumably from endogenous protein). However, the stimulation of incorporatio into glucose from 20 mM [U-¹⁴ C] lactate by NH₄⁺ plus glucagon was synergistic. This suggested that glucagon also stimulates the incorporation of labeled substrate into glucose by additional means. Stimulation of the incorporation of [U-¹⁴ C] alanine into glucose by β-hydroxybutyrate plus glucagon was also synergistic. This suggested that another action of glucagon may be to provide more intramitochondrial reducing potential.     

Glycogen synthesis by the direct or indirect pathways depends on glucose availability: in vivo studies in frog oocytes

Besides the classic direct route, frog oocytes incorporate glucosyl units into glycogen by the so-called indirect pathway. The operation of both pathways depends on glucose availability. Below 0.5 mM glucose (calculated intracellular concentration), the indirect route accounts for 90% of polysaccharide formation, while the direct pathway supports 70% of total glucose incorporation when administered glucose is above 1.5 mM. A sigmoidal curve was obtained for the direct pathway with n(H)=2.04, and half saturation was reached at 2.6 mM glucose. The curve for the indirect route presented an n(H) of 1.15 and an S(0.5) of 0.9 mM glucose.     

Glycerol as a substrate for phospholipid biosynthesis in type II pneumocytes isolated from streptozotocin-diabetic rats

Glycerol and glucose utilization for phospholipid biosynthesis was examined in type II pneumocytes isolated from normal and streptozotocin-diabetic rats. In cells from diabetic rats, incorporation of [1,3-14C]glycerol into total phosphatidylcholine (PC), disaturated phosphatidylcholine (DSPC), phosphatidylglycerol (PG) and phosphatidylethanolamine (PE) occurred to a greater degree by the glycerol 3-phosphate pathway as opposed to the dihydroxyacetone phosphate pathway. Total incorporation of glycerol into each of the major cellular phospholipids was increased up to 6-fold in cells from diabetic rats, while the total incorporation of glucose into the same lipids was decreased 2-fold. While the percentage of both glucose and glycerol carbons incorporated into the backbone of DSPC was increased in cells from diabetic rats, the percentage of carbons from both substrates incorporated into the fatty acid moieties was decreased. As a measure of DSPC synthesis, choline incorporation into DSPC was significantly decreased in type II cells from diabetic animals if the cells were incubated in the presence of glucose, palmitate and choline but not glycerol. Addition of 0.1 or 0.3 mM glycerol to the incubation medium restored choline incorporation to the control value in cells from diabetic rats, but did not affect the rate of choline incorporation into DSPC in cells from normal rats. These results suggest that exogenous glycerol can compensate for reduced glucose metabolism in type II cells of diabetic animals to maintain a constant rate of DSPC synthesis.     

Glutamine metabolism in isolated incubated adipocytes of the rat.

1. Phosphate-dependent glutaminase activity in the epididymal fat-pad was 15.1 nmol/min per mg of protein. Glutaminase activity demonstrated differences with respect to adipose-tissue sites. Considerable variation was found in different sites of adipose tissue from lean control and Zucker obese animals. 2. Adipocytes incubated in the presence of 2 mM-glutamine utilized glutamine at a rate of 1.8 mumol/h per g dry wt., and glutamate, ammonia, lactate and alanine were produced. Addition of glucose plus insulin increased the rates of glutamine utilization and glutamate, ammonia, lactate and alanine production. Isoprenaline alone or plus glucose further stimulated the rate of glutamine utilization and formation of end products. 3. The rate of incorporation of 14C from glutamine into CO2 was similar to that of glucose, but the rate of incorporation into triacylglycerol was much less. Addition of unlabelled glucose or glucose plus insulin stimulated the rate of incorporation of [14C]glutamine into triacylglycerol, but had no effect on that of 14CO2 formation. Isoprenaline plus glucose increased the rate of incorporation of [14C]glutamine into CO2, but decreased the rate of incorporation into triacylglycerol. 4. In the absence of insulin, the rate of [14C]glutamine incorporation into triacylglycerol was related to the glucose concentration (0-10 mM). However, in the presence of insulin, the rate of incorporation of [14C]glutamine was maximal at 1 mM-glucose.     

An aldose reductase inhibitor prevents the glucose-induced increase in PDGF-beta receptor in cultured rat aortic smooth muscle cells.

To examine the role of platelet-derived growth factor (PDGF) and the polyol pathway in the growth activity of smooth muscle cells (SMCs), [(3)H]-thymidine incorporation, [(125)I]-PDGF-BB binding and expression of PDGF-beta receptor protein were measured in rat aortic SMCs cultured with 5.5 or 20 mM glucose with or without anti-PDGF antibody or an aldose reductase inhibitor, epalrestat. SMCs cultured with 20 mM glucose demonstrated an accelerated thymidine incorporation compared with SMCs cultured with 5.5 mM glucose, which was prevented by anti-PDGF antibody. This acceleration of growth activity by 20 mM glucose was accompanied by an increase in PDGF-BB binding, which was due to the increased number of PDGF-beta receptors and the overexpression of PDGF-beta receptor protein. Epalrestat prevented all these abnormalities. These observations suggest that polyol pathway hyperactivity plays an important role in the proliferation of SMCs which may be mediated through the accelerated expression of PDGF-beta receptor protein.     

High-glucose-induced structural changes in the heparan sulfate proteoglycan, perlecan, of cultured human aortic endothelial cells

Hyperglycemia is an independent risk factor for diabetes-associated cardiovascular disease. One potential mechanism involves hyperglycemia-induced changes in arterial wall extracellular matrix components leading to increased atherosclerosis susceptibility. A decrease in heparan sulfate (HS) glycosaminoglycans (GAG) has been reported in diabetic arteries. The present studies examined the effects of high glucose on in vitro production of proteoglycans (PG) by aortic endothelial cells. Exposure of cells to high glucose (30 vs. 5 mM glucose) resulted in decreased [(35)S] sodium sulfate incorporation specifically into secreted HSPG. Differences were not due to hyperosmolar effects and no changes were observed in CS/DSPG. Enzymatic procedures, immunoprecipitation and Western analyses demonstrated that high glucose induced changes specifically in the HSPG, perlecan. In double-label experiments, lower sulfate incorporation in high-glucose-treated cells was accompanied by lower [(3)H] glucosamine incorporation into GAG but not lower [(3)H] serine incorporation into PG core proteins. Size exclusion chromatography demonstrated that GAG size was unchanged and GAG sulfation was not reduced. These results indicate that the level of regulation of perlecan by high glucose is posttranslational, involving a modification in molecular structure, possibly a decrease in the number of HS GAG chains on the core protein.     

Insulin-stimulated intracellular hydrogen peroxide production in rat epididymal fat cells.

Insulin stimulation of hydrogen peroxide production by rat epididymal fat cells was investigated by studying the oxidation of formate to CO2 by endogenous catalase. Under optimal concentrations of formate (0.1 to 1 mM) and glucose (0.275 mM), insulin stimulated formate oxidation 1.5- to 2.0-fold. Inhibitors of catalase activity, including nitrite and azide, inhibited both basal and insulin-stimulated formate oxidation at concentrations that did not interfere with insulin effects on glucose C-1 oxidation or glucose H-3 incorporation into lipids. The addition of exogenous catalase increased formate oxidation only slightly, while exogenous H2O2 (0.5 mM) stimulated formate oxidation by endogenous catalase strongly. These data indicate that the insulin-stimulated H2O2 production was intracellular. Insulin dose-response curves for formate oxidation were identical with those for glucose H-3 incorporation into lipids. The dependence of relative insulin effects on the logarithm of the glucose concentration was bell-shaped for formate oxidation and correlated highly with the coresponding dependences of glucose C-1 oxidation and glucose H-3 incorporation into lipids. This suggests that insulin stimulation of intracellular H2O2 production is linked to glucose metabolism. Since it is known that extracellular H2O2 can mimic insulin in several respects, these observations suggest that H2O2 may act as a "second messenger" for the observed effects of insulin.     

Insulin stimulation of glucose transport and metabolism in a human Wilms' tumor-derived myoblast-like cell Line: Modulation of hormone effects by glucose deprivation

The effects of insulin and glucose on parameters of metabolism were investigated in myoblast-like (MBL) cells, a human myoblast-like cell line derived from a Wilms' tumor. Insulin responses were studied after 4 hr pre-incubation in serum free media, with or without 5 mM glucose. Insulin was added during the last 2 hr. Glucose starvation markedly increased basal glucose transport (measured as 2-deoxyglucose uptake) as well as the net uptake of [¹⁴C]glucose and [¹⁴C]glucose incorporation into glycogen. Insulin stimulated net glucose uptake and incorporation into glycogen in a dose-dependent manner in glucose-fed and starved cells. These insulin responses were markedly enhanced in glucose-starved cells. Insulin accelerated 2-deoxyglucose transport in glucose-fed cells but did not further stimulate basal glucose transport in glucose-deprived cells. Insulin increased the incorporation of [³H]leucine into protein in glucose-fed or -starved MBL cells equally. The dose of insulin required for half-maximal insulin responses was similar for all parameters studied. Cycloheximide did not prevent the increased basal glucose incorporation in glucose-starved cells, but markedly inhibited the insulin response, while in glucose-fed cells, cycloheximide stimulated basal glucose incorporation. We conclude that MBL cells resemble fibroblasts in their insulin-independent stimulation of glucose transport in response to glucose-deprivation; when provided with glucose, they respond to insulin like fibroblasts. However, after brief glucose-starvation, the stimulated glucose transport system is no longer insulin-responsive in MBL cells, while pathways leading to the synthesis of macromolecules demonstrate preserved or enhanced stimulation by insulin, suggesting that these cells may serve as models to study the regulation of receptor-response coupling by the metabolic milieu.     

Effect of Fructose Supplementation on Sorbitol Accumulation and myolnositol Metabolism in Cultured Neuroblastoma Cells Exposed to Increased Glucose Concentrations

Aldose reductase activity is increased in neuroblastoma cells grown in media containing 30 mM fructose and/or 30 mM glucose. Neuroblastoma cells cultured in media supplemented with increased concentrations of glucose and fructose amass greater amounts of sorbitol than do cells exposed to media containing only high glucose concentrations. The increase in sorbitol content is dependent on the fructose and glucose concentration in the media. The increase in sorbitol content caused by exposing neuroblastoma cells to media containing 30 mM glucose/30 mM fructose is due to a protein synthesis sensitive mechanism and not to an alteration in the redox state. The addition of sorbinil to media containing 30 mM glucose blocks the increase in sorbitol content. In contrast, sorbinil treatment of media containing 30 mM glucose/30 mM fructose does not totally block the increase in sorbitol levels. myo-Inositol accumulation and incorporation into inositol phospholipids and intracellular myo-inositol content are decreased in cells chronically exposed to media containing 30 mM glucose or 30 mM glucose/30 mM fructose compared to cells cultured in unsupplemented media or media containing 30 mM fructose. However, maximal depletion of myo-inositol accumulation and intracellular content occurs earlier in cells exposed to media containing 30 mM glucose/30 mM fructose than in cells exposed to media supplemented with 30 mM glucose. Sorbinil treatment of media containing 30 mM glucose/30 mM fructose maintains cellular myo-inositol accumulation and incorporation into phospholipids at near normal levels. myo-Inositol content in neuroblastoma cells chronically exposed to media containing 30 mM glucose or 30 mM glucose/30 mM fructose recovers within 72 h when the cells are transferred to unsupplemented media or media containing 30 mM fructose. In contrast, the sorbitol content of cells previously exposed to media containing 30 mM glucose or 30 mM glucose/30 mM fructose then transferred into media containing 30 mM fructose remains elevated compared to the sorbitol content of cells transferred into unsupplemented media. These data suggest that fructose may be activating or increasing sorbinil-resistant aldose reductase activity as well as partially blocking sorbitol dehydrogenase activity. The presence of increased concentrations of fructose in combination with increased glucose levels may enhance alterations in cell metabolism and properties due to increased sorbitol levels.