1 Division of Endocrinology, Diabetes and Medical Genetics, Department of Medicine, and 2 Department of Biochemistry and Molecular Biology, Medical University of South Carolina, Charleston, South Carolina 29425
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ABSTRACT |
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3T3-L1 adipocytes develop insulin-resistant glucose transport upon preincubation with high glucose or glucosamine, provided insulin (0.6 nM) is present during preincubation. Insulin receptor substrate-1 (IRS-1)-associated phosphatidylinositol (PI) 3-kinase activity is unaffected (30). Total cellular IRS-1, PI 3-kinase, or Akt concentrations were unchanged. Akt activation in subcellular fractions was assessed by immunoblotting with two phospho-Akt-specific antibodies. Upon acute 100 nM insulin stimulation, plasma membrane (PM)-associated phospho-Akt was highest in cells preincubated in low glucose with no insulin, less in high glucose with no insulin, even less in low glucose+insulin, and lowest in high glucose+insulin. Only high glucose+insulin caused insulin-resistant glucose transport. Acute insulin stimulation increased total PM-Akt about twofold after preincubation without insulin in low or high glucose. Preincubation with 0.6 nM insulin decreased Akt PM translocation by ~25% in low and ~50% in high glucose. Preincubation with glucosamine did not affect Akt phosphorylation or translocation. Conclusions: chronic exposure to high glucose or insulin downregulates acute insulin-stimulated Akt activation, acting synergistically distal to PI 3-kinase. Maximal insulin activates more Akt than required for maximal glucose transport stimulation. Insulin resistance may ensue when PM-associated phospho-Akt decreases below a threshold. High glucose and glucosamine cause insulin resistance by different mechanisms in 3T3-L1 adipocytes.
glucose toxicity; 3T3-L1 adipocytes; Akt activation; glucose transport
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INTRODUCTION |
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INSULIN'S INTERACTION with its receptor (IR) initiates a complex signaling cascade, which regulates cell growth and differentiation, protein synthesis, and glucose and lipid metabolism. The signaling cascades that mediate the transcriptional regulation of protein synthesis diverge early from those mediating short-term metabolic regulation. Insulin-mediated acceleration of glucose transport in skeletal and heart muscle and in adipocytes is a key example of the latter; the precise mechanism is still incompletely understood. Clinically, insulin resistance is defined as the reduced ability of insulin to lower plasma glucose, which reflects, in great part, impaired insulin stimulation of glucose transport and GLUT-4 translocation. It is a positive predictor and hallmark of the development of type 2 diabetes. Indeed, several defects in insulin signaling associated with insulin resistance and type 2 diabetes have been reported and are reviewed in Ref. 33.
Insulin binding to IR stimulates the autophosphorylation of specific
tyrosine residues on the IR -subunit, which increases its intrinsic
tyrosine kinase activity. Substrates of the activated IR tyrosine
kinase include the IR substrates (IRS) 1-4 (47). They
are phosphorylated on specific tyrosine residues and act as docking
motifs for Src homology 2-containing proteins, which include the p85
regulatory subunit of phosphatidylinositol (PI) 3-kinase
(33). Binding of p85 to IRS activates the p110 catalytic subunit of PI 3-kinase, which in turn generates 3-phosphoinositides.
At least two downstream targets are activated by 3-phosphoinositides:
protein kinase (PK) C-/
(5) and Akt/PKB
(46). They are phosphorylated by
phosphoinositide-dependent kinase 1 (PDK-1) and play a role in
insulin-stimulated glucose transport and GLUT-4 translocation. It is
still unclear whether either or both are important in regulating GLUT-4
translocation and glucose transport, but evidence suggests that
PKC-
/
and Akt function parallel to but not downstream of one
another (24).
Three isoforms encoded by different genes have been cloned and
designated as Akt-1/PKB- (12), Akt-2/PKB-
(9), or Akt-3/PKB-
(23). 3T3-L1 adipocytes
express only Akt-1 and Akt-2 (2). PI-3 kinase-dependent
phosphorylation of Akt-1 and Akt-2 on Thr308 and
Ser473 and on Thr309 and Ser474,
respectively, is necessary for insulin-regulated activation of Akt.
PDK-1 phosphorylates Akt-1 and Akt-2 on Thr308 and
Thr309, respectively (1, 38). The
phosphorylation of Ser473 (4) of Akt is
regulated by an as-yet-unidentified PDK-2, which may be Akt itself but
is required for full activation (43). Akt in the basal
state, for the most part, resides in the cytosol. It is recruited to
the inner leaflet of the plasma membrane after insulin stimulation
(4), where 3-phosphoinositides bind with high affinity to
its pleckstrin homology (PH) domain, inducing a conformational change
that renders Thr308 in the activation loop accessible to
the action of PDK-1. This phosphorylation, in turn, facilitates
the phosphorylation of Ser473.
Prolonged hyperglycemia causes insulin resistance in humans and in various animal models of diabetes (35, 48), which led to the concept of "glucose toxicity." Glucose-induced insulin resistance of glucose transport has been demonstrated in tissue culture systems (17, 27, 29, 41), and we have extensively characterized the model in 3T3-L1 adipocytes (30). Preexposure (18 h) to high (25 mM) glucose or to glucosamine (1-2.5 mM) decreased the subsequent response of glucose transport to maximal acute insulin stimulation compared with cells preincubated in low (5 mM) glucose. High glucose or glucosamine induced insulin resistance only if a relatively low dose (0.6 nM) of insulin was included during preincubation. Preexposure to low-dose insulin in the presence of low glucose did not affect the acute insulin stimulation of glucose transport. The expression of glucose transporters (GLUT-4 and GLUT-1) was not affected by the preincubation conditions, and robust acute insulin stimulation of IRS-1-associated PI 3-kinase was maintained under all conditions. However, although both high glucose and glucosamine decreased insulin-stimulated glucose transport to a similar degree, their effects on acute insulin-stimulated GLUT-4 translocation were different, as assessed by the plasma membrane lawn assay. Preincubation with glucosamine in the presence of 5 mM glucose and 0.6 nM insulin inhibited the translocation of GLUT-4 to the plasmalemma upon acute insulin stimulation. Preincubation in high glucose + 0.6 nM insulin did not inhibit GLUT-4 translocation, although both conditions inhibited acute insulin stimulation of glucose transport to a similar degree (~40%). We concluded that glucose-induced insulin resistance may involve impaired glucose transporter activation or impaired docking/fusion of GLUT-4-containing vesicles with the plasma membrane (30). In the present study, we assessed whether preincubation with low-dose insulin and/or high glucose affected the acute insulin-regulated serine/threonine phosphorylation of Akt and its translocation to the plasma membrane and whether preincubation with high glucose or glucosamine exerts different effects on the acute insulin regulation of Akt.
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EXPERIMENTAL PROCEDURES |
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Materials. A polyclonal antibody specific for Akt-1/2 and a monoclonal antibody that recognizes the p85 subunit of PI 3-kinase were purchased from Santa Cruz Biotechnology (Santa Cruz, CA) and Upstate Biotechnology (Lake Placid, NY), respectively. In addition, two phospho-specific polyclonal antibodies purchased from Cell Signaling (Beverly, MA) were used to detect the phosphorylation status of Akt on Ser473 and Thr308. Horseradish peroxidase-conjugated goat anti-rabbit IgG was purchased from Jackson Immunoresearch Laboratories (West Grove, PA), and enhanced chemiluminescence (ECL) reagents were purchased from Pierce (Rockford, IL). Crystalline recombinant human insulin was a gift from Eli Lilly Research Laboratories (Indianapolis, IN). Other reagents were purchased from suppliers, as described in previous publications (30), and were of the highest quality available.
Cell culture and general methods. 3T3-L1 fibroblasts were grown and differentiated into adipocytes in 35-mm culture dishes, as previously described (16, 30), and prepared for experiments as described (30). Briefly, after differentiation, adipocytes were placed into DMEM containing 25 mM glucose and 10% fetal bovine serum until they were used in experiments 10-14 days after initiation of the differentiation protocol, when 90-95% of the cells exhibited the adipocyte morphology.
In typical experiments, cells were preincubated for 18 h in DMEM containing 1% FBS and sugars, as indicated in Figs. 1-7, i.e., 5 or 25 mM glucose or 5 mM glucose + 2.5 mM glucosamine, each with or without 0.6 nM insulin. They were then transferred to identical media without FBS or insulin for 2 h and then acutely stimulated with or without 100 nM insulin for 15 min (30). After being washed twice with HES buffer [20 mM HEPES (pH 7.4), 1 mM EDTA, 255 mM sucrose, 1 mM sodium vanadate, 1 mM sodium fluoride, 1 mM sodium pyrophosphate, 1 µM microcystin, 1 mM phenylmethylsulfonyl fluoride, 10 µg/ml pepstatin A, 10 µg/ml leupeptin, and 10 µg/ml aprotinin] without protease inhibitors, cells were lysed as we will describe in Subcellular fractionation.
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Subcellular fractionation.
Subcellular fractions were generated by differential centrifugation, as
previously described (42). Cells prepared as described above were harvested in HES buffer. Cell lysates were prepared by
shearing cells 10 times through a 22-gauge needle. An aliquot was saved
for analyses of total cell lysates. The remainder was then centrifuged
at 19,000 g for 20 min at 4°C. The resulting supernatant
was centrifuged at 41,000 g for 20 min to yield a low-speed
pellet containing high-density microsomes. That supernatant was
centrifuged for 75 min at 180,000 g to generate a high-speed pellet containing low-density microsomes (LDM) and the cytosol in the
supernatant. Crude plasma membranes (PM) were prepared by resuspending
the pellet from the 19,000-g centrifugation and layering it
onto a 1.12 M sucrose cushion, which was centrifuged at 100,000 g for 60 min. The PM layer was collected and centrifuged at
40,000 g for 20 min. Pellets of the PM and LDM were
resuspended in HES buffer containing 1% Triton X-100 and solubilized
for 1 h at 4°C. They were subsequently centrifuged for 75 min at
200,000 g. The Triton-soluble fractions (TS-PM, TS-LDM) were
collected, and the Triton-insoluble pellets (TI-PM, TI-LDM) were
resuspended in PBS containing 1% SDS and heated for 10 min at 95°C.
Total cell extracts and cell fractions were analyzed by SDS-PAGE and immunoblotted with a polyclonal antibody specific for Akt-1/2. Insulin-stimulated phosphorylation of Akt was detected by immunoblot with two phospho-specific polyclonal antibodies recognizing Akt-1 phosphorylated on Ser473 and Thr308 and Akt-2
and -3 phosphorylated on the corresponding sites. The blots were
developed using the ECL procedure, and the bands were then
quantified using a Molecular Dynamics Personal Laser Densitometer (Amersham Pharmacia Biotech, Piscataway, NJ) equipped with ImageQuant version 3.3 software.
Other analyses. Protein concentrations in cell extracts were measured spectrophotometrically against BSA standards using Coomassie protein assay reagent purchased from Pierce (Rockford, IL).
Statistical analysis. Means ± SE are shown. Where error bars are not indicated in the figures, they are too small for graphical representation, i.e., they fall within the symbol of the mean. The significance of differences between means was evaluated by one-way or two-way ANOVA and Tukey's test for unbalanced design with the Statistica software or by two-tailed unpaired Student's t-test with Statview software. P < 0.05 was considered significant.
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RESULTS |
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High glucose effects on Akt phosphorylation and localization. Because previous studies have implicated altered Akt activation in models of insulin resistance in muscle (26, 37), we tested whether our model of glucose-induced insulin resistance was associated with impaired activation of Akt. After preincubation in media containing either 5 mM or 25 mM glucose in either the absence or presence of 0.6 nM insulin, cells were deprived of insulin and serum for 2 h and then stimulated with or without a maximal dose of insulin (100 nM) for 15 min. Then, subcellular fractions of the adipocytes were prepared as described in EXPERIMENTAL PROCEDURES. Total expression of IRS-1, p85 subunit of PI 3-kinase, or Akt was not affected by any of the preincubation conditions (Fig. 1). Next, we immunoblotted for phosphorylated-Akt (P-Akt) with a phospho-specific antibody that recognizes Akt after it is phosphorylated on Ser473 (Akt-1) or Ser474 (Akt-2). As shown in Fig. 2A, P-Akt was detectable in the TS-PM only after acute insulin stimulation. This acute insulin-responsive phosphorylation of Akt decreased 70% (Fig. 2B, P < 0.02) after preincubation with 0.6 nM insulin in the presence of 5 mM glucose, a condition that did not induce insulin-resistant glucose transport. Compared with control (5 mM glucose without 0.6 nM insulin), P-Akt levels in the TS-PM decreased 30% (Fig. 2B, P < 0.05) and 85% (Fig. 2B, P < 0.02) in cells exposed to 25 mM glucose in the absence or presence of 0.6 nM insulin, respectively. Only the latter was associated with insulin-resistant glucose transport (30). Thus both chronic insulin exposure (P < 0.001) and high glucose concentration (P < 0.05) independently reduced the accumulation of acute insulin-induced P-Akt at the PM without affecting insulin-stimulated glucose transport. However, the effects of preincubation with 25 mM glucose and 0.6 nM insulin were additive, and only when present together did insulin-resistant glucose transport ensue.
In all fractions analyzed (Figs. 2 and 3), P-Akt was detected after acute insulin stimulation but not in the basal state. As reported by others, P-Akt was most abundant in the cytosol (Fig. 3) and was associated in significant amounts with TS-PM (Fig. 2) and the TS- and TI-LDM fractions (Fig. 3). P-Akt was not detected in the TI-PM fraction (not shown). Chronic exposure to low-dose insulin (0.6 nM) significantly decreased P-Akt abundance after acute insulin stimulation in the cytosol and in the TS- and TI-LDM, after preincubation in low or high glucose (P < 0.02, Fig. 3), similar to the effects seen in the TS-PM (Fig. 2). In the TS- and TI-LDM, the downregulation of acute insulin-mediated Akt activation after chronic exposure to low-dose insulin was significantly enhanced in the presence of high glucose compared with low glucose (P < 0.02), but this effect did not reach statistical significance in the cytosol. Preincubation in high glucose in the absence of insulin decreased P-Akt abundance significantly only in the PM (compared with low glucose, P < 0.05, Fig. 2), but not in the cytosol or the TI- or TS-LDM fractions (Fig. 3). Akt is first phosphorylated on Thr308 (Akt-1) or Thr309 (Akt-2) in response to insulin. In an effort to further characterize the phosphorylation defect associated with glucose-induced insulin resistance, total cell lysates, prepared as described in EXPERIMENTAL PROCEDURES, were separated by SDS-PAGE and immunoblotted with either a phospho-Ser-Akt or phospho-Thr-Akt antibody. As shown in Figs. 1 and 4A, total Akt expression was not altered by any preincubation condition. Similar to results shown in Fig. 2, neither Ser- nor Thr-phosphorylated Akt was detected in total cell lysates in the basal state. Acute insulin stimulation markedly increased the phosphorylation of Akt on both residues after preincubation with 5 mM glucoseGlucosamine effects on Akt phosphorylation and localization. Because we previously observed different effects of high glucose or glucosamine preincubation on insulin-stimulated GLUT-4 translocation (30), we tested in a separate series of experiments (Fig. 6) whether preincubation with glucosamine affected Akt phosphorylation and whether the response was different from the effects of preexposure to high glucose. As in previous experiments, Akt phosphorylation was observed only after acute insulin stimulation, and this response was significantly decreased (P < 0.02) by including 0.6 nM insulin with 5 mM glucose during preincubation. In contrast to the effects of high glucose (Fig. 2), the addition of glucosamine during preincubation in the presence or absence of insulin had no effect on subsequent acute insulin-stimulated Akt phosphorylation. The presence of 0.6 nM insulin with glucosamine only decreased Akt phosphorylation by 55% (P < 0.05). This stands in contrast to the effects of high glucose + insulin that downregulated Akt phosphorylation by 85%. In contrast to high glucose preincubation, there was no evidence of a synergistic effect between chronic exposure to low-dose insulin and glucosamine.
Acute insulin stimulation increased Akt levels in the TS-PM ~1.8- to 2-fold (Fig. 7B, P < 0.05, similar to results in Fig. 5). This response was decreased ~25% after preincubation with 0.6 nM insulin and 5 mM glucose. Preincubation with glucosamine had no effect on insulin-stimulated Akt recruitment to TS-PM, regardless of the presence or absence of 0.6 nM insulin (Fig. 7). In contrast, 25 mM glucose and 0.6 nM insulin acted synergistically to downregulate acute insulin-responsive Akt translocation to the PM (Fig. 5, P < 0.05). No significant interactions were detected between preincubation with glucosamine and low-dose insulin on the acute insulin response of Akt translocation to the PM, which again is in contrast to the effects of high glucose (Fig. 5). Thus the ability of high glucose and glucosamine to induce insulin resistance likely represents different effects, at least at the level of acute insulin-mediated Akt activation. ![]() |
DISCUSSION |
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In the model of glucose-induced insulin resistance used here, preincubation in high glucose impairs the subsequent acute insulin stimulation of glucose transport provided that low-dose insulin is also present during preincubation. Because the acute insulin stimulation of IRS-1-associated PI 3-kinase was unaffected, we searched for a defect in insulin's signaling cascade distal to PI 3-kinase. Our data clearly demonstrate that chronic exposure to high glucose (without insulin) or to insulin in low glucose impairs the subsequent acute activation of Akt by insulin by ~30 and ~70%, respectively. The two effects appear to be additive. Exposure to low-dose insulin in high glucose reduced PM-associated P-Akt to one-half of that observed after preincubation with insulin in low glucose. Under these conditions, acute insulin stimulation yielded only 15% of the P-Akt accumulation in the PM observed in controls preincubated in low glucose without insulin. Note that only the combined treatment resulted in insulin-resistant glucose transport in this model. Thus, if we assume that impaired Akt activation is causally related to the development of insulin resistance, these data suggest that, in 3T3-L1 adipocytes, a dose of insulin that maximally stimulates glucose transport results in Akt activation that is far in excess of that needed for maximal acute glucose transport stimulation. Thus a 70% reduction of P-Akt at the PM does not impair maximal insulin stimulation of glucose transport, but when P-Akt falls below a critical level (~20% of maximal), insulin-resistant glucose transport develops. The major role of fat cells is to store energy as lipids, when nutrients, e.g., glucose and insulin, are plentiful. The development of insulin-resistant glucose transport may serve as a "last resort" strategy in normal adipocytes, possibly to prevent excessive oxidative damage from chronically increased glucose flux. However, less drastic decreases in P-Akt may affect other insulin-regulated pathways.
In rat extensor digitorum longus muscles incubated for several hours under different conditions (26), high glucose caused insulin resistance of glucose transport only if insulin was present during preincubation. However, preincubation with high glucose without insulin did impair the acute insulin stimulation of glucose flux into glycogen and lipids. PI 3-kinase activation by insulin was unaffected under these conditions, but Akt activation was impaired. Two other recent papers support the notion that ambient glucose may regulate Akt activation by insulin at steps(s) distal to PI 3-kinase. One involves muscles of a rodent model of type 2 diabetes, the Goto-Kakizaki rat (37), and the other deals with primary adipocytes from patients with type 2 diabetes (7). In the latter model, adipocytes from diabetic patients demonstrated both impaired activation of Akt and diminished Akt translocation to the plasmalemma in response to insulin, similar to our findings in 3T3-L1 adipocytes after preincubation in high glucose in the presence of insulin.
Because in our model a 70% decrease of P-Akt at the PM did not diminish insulin-stimulated glucose transport, the question arises whether Akt activation is required for insulin-stimulated glucose transport. Akt-2 is most highly expressed in insulin-responsive cells and has been specifically implicated in insulin's stimulation of glucose transport (25). Recent work in Akt-2 knockout mice provides strong evidence for Akt-2's participation in insulin-regulated glucose homeostasis (11). Our observations suggesting that a fraction of insulin-activated Akt is sufficient for maximal glucose transport stimulation may explain previous conflicting results concerning Akt's role in insulin signaling by use of dominant-negative mutant technologies (13, 22). In Akt-2 knockout mice, insulin resistance of glucose transport was demonstrable in white (glycolytic) but not red (oxidative) muscles, and the impairment was mild in adipocytes (11). Insulin likely stimulates glucose transport via several parallel pathways, which may act synergistically and may compensate for one another until a critical threshold is reached. In our model, insulin resistance develops when activated Akt falls below ~20% of maximal stimulation.
Glucosamine has been extensively used as a model to elucidate the role of the hexosamine biosynthesis pathway in glucose-induced insulin resistance (6, 8, 18, 19, 21, 29, 30, 32, 34, 36, 44, 45). Previous studies suggested that high glucose and glucosamine may induce insulin resistance of glucose transport by different mechanisms (8, 19, 30, 45). In addition, preexposure to glucosamine caused several metabolic alterations in 3T3-L1 adipocytes that did not mimic the effects of high glucose (19, 30). The data presented here support these conclusions. Whereas preexposure to high glucose significantly inhibited Akt activation in the absence or presence of low-dose insulin during preincubation, glucosamine did not. In vivo, glucosamine coinfusion during a euglycemic insulin clamp causes insulin resistance as assessed by decreased peripheral glucose utilization (6, 21, 32, 36) and impaired translocation of GLUT-4 to the PM in skeletal muscle (6). However, insulin-mediated Akt activation in skeletal muscle was unimpaired, even under conditions in which diminished IRS-1-associated PI 3-kinase activation was detectable (21, 32). Akt activation was impaired after exposure to glucosamine + insulin in the absence of glucose in one study in 3T3-L1 adipocytes (19). The effect was attributed to ATP depletion and was accompanied by impaired activation of IR, IRS-1, and PI 3-kinase, as well as insulin resistance of glucose transport and GLUT-4 translocation. In our model, 3T3-L1 adipocytes were exposed to glucosamine in the presence of 5 mM glucose. Although a decrease in the ATP concentration was detectable, it was much more modest than in the work of Hresko et al. (19), and insulin-mediated IRS-1-associated PI 3-kinase activity was unimpaired (30). Glucosamine may cause insulin resistance of GLUT-4 translocation distal to the action of Akt. A possible mechanism may involve a decreased GTP-to-GDP ratio (30), which may impair the activation of small G proteins involved in the translocation of GLUT-4-containing vesicles (10, 14, 20).
In our experiments, preexposure to high glucose and/or to low-dose insulin decreased the acute insulin-stimulated phosphorylation of Akt on Thr and Ser in parallel. These observations are consistent with those obtained in primary adipocytes from patients with type 2 diabetes (7). Although we have no direct evidence to indicate that the decreased phosphorylation of Ser is secondary to that of Thr, previous observations support this hypothesis, because Thr phosphorylation is required for Ser phosphorylation (43).
Acute insulin stimulation increased PM-associated Akt approximately twofold compared with basal. This response was decreased by ~25-30% after preincubation with low-dose insulin in the presence of low glucose. High glucose + insulin further decreased Akt PM translocation (compared with low glucose + insulin), whereas glucosamine was ineffective. Thus chronic insulin preexposure downregulated the insulin-induced phosphorylation of Akt and its PM translocation. This effect was enhanced by the inclusion of high glucose but not of glucosamine.
The percent decrease in Akt phosphorylation was greater than that observed in PM translocation and was independent of changes in total Akt expression, similar to a study in adipocytes from patients with type 2 diabetes (7). Akt translocation to the PM may be required for its phosphorylation by PDK-1 (4), which is in part constitutively associated with the PM (3, 15). Therefore, the decreased phosphorylation of Akt could reflect, at least in part, its impaired translocation. Basal steady-state levels of Akt in the PM were not different among any of the preincubation conditions. Because the effects of chronic preexposure to high glucose and low-dose insulin appear to be synergistic, they may downregulate Akt activation by different mechanisms. Note that preincubation in high glucose without insulin significantly decreased acute insulin-stimulated Akt phosphorylation on both Thr and Ser, without a detectable impairment of Akt translocation to the PM. Thus the primary effect of sustained exposure to high glucose may be impairment of Akt phosphorylation, whereas chronic exposure to low-dose insulin affects both processes, with the possibility that impaired Akt translocation may be the primary event.
The mechanisms by which chronic exposure to high glucose or to low-dose insulin may downregulate insulin-stimulated Akt activation at a step downstream of PI 3-kinase activation are unknown. Decreased expression or decreased activity of PDK-1 is an obvious candidate. Alternatively, the dephosphorylation of Akt may be accelerated in our model by increased expression or activation of phosphoprotein phosphatases. A particularly attractive candidate may be the tumor suppressor protein PTEN, which acts both as a phosphoprotein phosphatase and a lipid phosphatase. The latter activity entails the specific dephosphorylation of the D3 position of inositol and PI substrates (28). Increased expression and/or activity of PTEN in cells preexposed to high glucose and low-dose insulin could explain the impaired translocation and phosphorylation of Akt. Both PTEN (28) and ceramide (39, 40) have been shown to independently and negatively regulate Akt activation.
The data presented support the concept that high glucose and glucosamine induce insulin resistance by different mechanisms in 3T3-L1 adipocytes. High glucose, but not glucosamine, impairs insulin stimulation of Akt activity. Chronic exposure to low-dose insulin impairs Akt translocation and phosphorylation and acts synergistically as a negative Akt modulator with high glucose but not with glucosamine. As previously discussed, the fact that glucosamine does not mimic the effect of high glucose does not negate the possible role of the hexosamine biosynthesis pathway in glucose-induced insulin resistance, but it suggests that glucosamine may not appropriately model the pathway (30). Preliminary evidence suggests that preexposure to high glucose in the presence of low-dose insulin may affect the appropriate docking/fusion of GLUT-4-containing vesicles with the PM (31). The data presented here raise the possibility that Akt may participate in the regulation of this distal step in insulin's stimulation of glucose transport.
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ACKNOWLEDGEMENTS |
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We thank Lilly Research Laboratories for gifts of recombinant human insulin. We thank Dr. Morris Birnbaum for the gift of 3T3-L1 mouse fibroblasts and Dr. Howard Green, in whose laboratory at Harvard University they were originally developed, for permission.
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FOOTNOTES |
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This work was supported in part by the National Institute of Diabetes and Digestive and Kidney Diseases Research Grant DK-02001 (to M. G. Buse). B. A. Nelson was supported by a Medical Scientist Training Grant (GM-08716) from the National Institute of General Medical Sciences.
Parts of this work were presented at the 2001 National Meetings of the American Diabetes Association.
Address for reprint requests and other correspondence: M. G. Buse, Medical Univ. of South Carolina, Dept. of Medicine, Endocrinology, Diabetes and Medical Genetics Division, 96 Jonathan Lucas St., Suite 323, Charleston, SC 29425 (E-mail: busemg{at}musc.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
10.1152/ajpendo.00438.2001
Received 28 September 2001; accepted in final form 31 October 2001.
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