Epinephrine administration stimulates GLUT4 translocation but reduces glucose transport in muscle.

Epinephrine opposes glucose transport in muscle. Therefore, we investigated the effects of epinephrine administration (25 micrograms/100g body weight) on glucose transport and glucose transporters in rat muscle. Ninety minutes after epinephrine injection 3-O-methyl glucose transport was reduced (approximately 47%) in perfused muscles of the rat hindlimb. Translocation of the insulin-regulatable glucose transporter (GLUT4) in the epinephrine-injected animals was confirmed by the marked increments in the GLUT-4 in the plasma membranes and their concomitant reduction in the intracellular membranes. We speculate a) that it is epinephrine which translocated GLUT4 via a cAMP-linked pathway, and b) that the intrinsic activity reductions are caused either by the glycation of the transporter by the persistent hyperglycemia and/or by epinephrine via the phosphorylation of the GLUT4 transporter protein in muscle.     

Endoproteolytic cleavage of TUG protein regulates GLUT4 glucose transporter translocation

To promote glucose uptake into fat and muscle cells, insulin causes the translocation of GLUT4 glucose transporters from intracellular vesicles to the cell surface. Previous data support a model in which TUG traps GLUT4-containing vesicles and tethers them intracellularly in unstimulated cells and in which insulin mobilizes this pool of vesicles by releasing this tether. Here we show that TUG undergoes site-specific endoproteolytic cleavage, which separates a GLUT4-binding, N-terminal region of TUG from a C-terminal region previously suggested to bind an intracellular anchor. Cleavage is accelerated by insulin stimulation in 3T3-L1 adipocytes and is highly dependent upon adipocyte differentiation. The N-terminal TUG cleavage product has properties of a novel 18-kDa ubiquitin-like modifier, which we call TUGUL. The C-terminal product is observed at the expected size of 42 kDa and also as a 54-kDa form that is released from membranes into the cytosol. In transfected cells, intact TUG links GLUT4 to PIST and also binds Golgin-160 through its C-terminal region. PIST is an effector of TC10α, a GTPase previously shown to transmit an insulin signal required for GLUT4 translocation, and we show using RNAi that TC10α is required for TUG proteolytic processing. Finally, we demonstrate that a cleavage-resistant form of TUG does not support highly insulin-responsive GLUT4 translocation or glucose uptake in 3T3-L1 adipocytes. Together with previous results, these data support a model whereby insulin stimulates TUG cleavage to liberate GLUT4 storage vesicles from the Golgi matrix, which promotes GLUT4 translocation to the cell surface and enhances glucose uptake.     

A role for phospholipase D in GLUT4 glucose transporter translocation

Based on recent studies showing that phospholipase D (PLD)1 is associated with intracellular membranes and promotes membrane budding from the trans-Golgi, we tested its possible role in the membrane trafficking of GLUT4 glucose transporters. Using immunofluorescence confocal microscopy, expressed Myc epitope-tagged PLD1 was found to associate with intracellular vesicular structures by a mechanism that requires its N-terminal pleckstrin homology domain. Partial co-localization with expressed GLUT4 fused to green fluorescent protein in both 3T3-L1 adipocytes and Chinese hamster ovary cells was evident. Furthermore, microinjection of purified PLD into cultured adipocytes markedly potentiated the effect of a submaximal concentration of insulin to stimulate GLUT4 translocation to cell surface membranes. Insulin stimulated PLD activity in cells expressing high levels of insulin receptors but no such insulin effect was detected in 3T3-L1 adipocytes. Taken together, these results are consistent with the hypothesis that PLD1 associated with GLUT4-containing membranes acts in a constitutive manner to promote the mechanism of GLUT4 translocation by insulin.     

Overexpression of the glucose transporter GLUT4 in adipose cells interferes with insulin-stimulated translocation.

In adipose cells, insulin induces the translocation of GLUT4 by stimulating their exocytosis from a basal intracellular compartment to the plasma membrane. Increasing overexpression of a hemagglutinin (HA) epitope-tagged GLUT4 in rat adipose cells results in a roughly proportional increase in cell surface HA-GLUT4 levels in the basal state, accompanied by a marked reduction of the fold HA-GLUT4 translocation in response to insulin. Using biochemical methods and cotransfection experiments with differently epitope-tagged GLUT4, we show that overexpression of GLUT4 does not affect the intracellular sequestration of GLUT4 in the absence of insulin, but rather reduces the relative insulin-stimulated GLUT4 translocation to the plasma membrane. In contrast, overexpression of GLUT1 does not interfere with the targeting of GLUT4 and vice versa. These results suggest that the mechanism involved in the intracellular sequestration of GLUT4 has a high capacity whereas the mechanism for GLUT4 translocation is readily saturated by overexpression of GLUT4, implicating an active translocation machinery in the exocytosis of GLUT4.     

The GLUT4 glucose transporter

Few physiological parameters are more tightly and acutely regulated in humans than blood glucose concentration. The major cellular mechanism that diminishes blood glucose when carbohydrates are ingested is insulin-stimulated glucose transport into skeletal muscle. Skeletal muscle both stores glucose as glycogen and oxidizes it to produce energy following the transport step. The principal glucose transporter protein that mediates this uptake is GLUT4, which plays a key role in regulating whole body glucose homeostasis. This review focuses on recent advances on the biology of GLUT4.     

Palmitate stimulates glucose transport in rat adipocytes by a mechanism involving translocation of the insulin sensitive glucose transporter (GLUT4).

In rat adipocytes, palmitate: a) increases basal 2-deoxyglucose transport 129 +/- 27% (p less than 0.02), b) decreases the insulin sensitive glucose transporter (GLUT4) in low density microsomes and increases GLUT4 in plasma membranes and c) increases the activity of the insulin receptor tyrosine kinase. Palmitate-stimulated glucose transport is not additive with the effect of insulin and is not inhibited by the protein kinase C inhibitors staurosporine and sphingosine. In rat muscle, palmitate: a) does not affect basal glucose transport in either the soleus or epitrochlearis and b) inhibits insulin-stimulated glucose transport by 28% (p less than 0.005) in soleus but not in epitrochlearis muscle. These studies demonstrate a potentially important differential role for fatty acids in the regulation of glucose transport in different insulin target tissues.     

Expression of the glucose transporter isoform GLUT 4 is insufficient to confer insulin-regulatable hexose uptake to cultured muscle cells.

Glucose transporter isoform expression was studied in the skeletal muscle-like cell line, C2C12. Northern and Western blot analysis showed that the insulin-responsive muscle/fat glucose transporter isoform, GLUT 4, was expressed in these cells at very low levels, whereas the erythrocyte isoform, GLUT 1, was expressed at readily detectable levels. Insulin did not stimulate glucose transport in this cultured muscle cell line. The C2C12 cells were then transfected separately with either GLUT 1 or GLUT 4, and stable cell lines expressing high levels of mRNA and protein were isolated. GLUT 1-transfected cells exhibited a 3-fold increase in the amount of the GLUT 1 transporter protein which was accompanied by a 2- to 3-fold increase in the glucose uptake rate. However, despite at least a 10-fold increase in GLUT 4 mRNA and protein detected after GLUT 4 cDNA transfection, the glucose uptake of these cells was unchanged and remained insulin-insensitive. By laser confocal immunofluorescence imaging, it was established that the transfected GLUT 4 protein was localized almost entirely in cytoplasmic compartments. In contrast, the GLUT 1 isoform was detected both at the plasma membrane as well as in intracellular compartments. These results suggest that acute insulin stimulation of glucose transport is not solely dependent on the presence of the insulin receptor and the GLUT 4 protein, and that the presence of some additional protein(s) must be required.     

Intracellular targeting of the insulin-regulatable glucose transporter (GLUT4) is isoform specific and independent of cell type

Insulin stimulates glucose transport in adipocytes via the rapid redistribution of the GLUT1 and GLUT4 glucose transporters from intracellular membrane compartments to the cell surface. Insulin sensitivity is dependent on the proper intracellular trafficking of the glucose transporters in the basal state. The bulk of insulin-sensitive transport in adipocytes appears to be due to the translocation of GLUT4, which is more efficiently sequestered inside the cell and is present in much greater abundance than GLUT1. The cell type and isoform specificity of GLUT4 intracellular targeting were investigated by examining the subcellular distribution of GLUT1 and GLUT4 in cell types that are refractory to the effect of insulin on glucose transport. Rat GLUT4 was expressed in 3T3-L1 fibroblasts and HepG2 hepatoma cells by DNA-mediated transfection. Transfected 3T3-L1 fibroblasts over-expressing human GLUT1 exhibited increased glucose transport, and laser confocal immunofluorescent imaging of GLUT1 in these cells indicated that the protein was concentrated in the plasma membrane. In contrast, 3T3-L1 fibroblasts expressing GLUT4 exhibited no increase in transport activity, and confocal imaging demonstrated that this protein was targeted almost exclusively to cytoplasmic compartments. 3T3-L1 fibroblasts expressing GLUT4 were unresponsive to insulin with respect to transport activity, and no change was observed in the subcellular distribution of the protein after insulin administration. Immunogold labeling of frozen ultrathin sections revealed that GLUT4 was concentrated in tubulo-vesicular elements of the trans-Golgi reticulum in these cells. Sucrose density gradient analysis of 3T3-L1 homogenates was consistent with the presence of GLUT1 and GLUT4 in discrete cytoplasmic compartments. Immunogold labeling of frozen thin sections of HepG2 cells indicated that endogenous GLUT1 was heavily concentrated in the plasma membrane. Sucrose density gradient analysis of homogenates of HepG2 cells expressing rat GLUT4 suggested that GLUT4 is targeted to an intracellular location in these cells. The density of the putative GLUT4-containing cytoplasmic membrane vesicles was very similar in HepG2 cells, 3T3-L1 fibroblasts, 3T3-L1 adipocytes, and rat adipocytes. These data indicate that the intracellular trafficking of GLUT4 is isoform specific. Additionally, these observations support the notion that GLUT4 is targeted to its proper intracellular locale even in cell types that do not exhibit insulin-responsive glucose transport, and suggest that the machinery that regulates the intracellular targeting of GLUT4 is distinct from the factors that regulate insulin-dependent recruitment to the cell surface.     

Activation of the glucose transporter GLUT4 by insulin.

The transport of glucose into cells and tissues is a highly regulated process, mediated by a family of facilitative glucose transporters (GLUTs). Insulin-stimulated glucose uptake is primarily mediated by the transporter isoform GLUT4, which is predominantly expressed in mature skeletal muscle and fat tissues. Our recent work suggests that two separate pathways are initiated in response to insulin: (i) to recruit transporters to the cell surface from intracellular pools and (ii) to increase the intrinsic activity of the transporters. These pathways are differentially inhibited by wortmannin, demonstrating that the two pathways do not operate in series. Conversely, inhibitors of p38 mitogen-activated protein kinase (MAPK) imply that p38 MAPK is involved only in the regulation of the pathway leading to the insulin-stimulated activation of GLUT4. This review discusses the evidence for the divergence of GLUT4 translocation and activity and proposed mechanisms for the regulation of GLUT4.     

Regulated transport of the glucose transporter GLUT4

In muscle and fat cells, insulin stimulates the delivery of the glucose transporter GLUT4 from an intracellular location to the cell surface, where it facilitates the reduction of plasma glucose levels. Understanding the molecular mechanisms that mediate this translocation event involves integrating our knowledge of two fundamental processes--the signal transduction pathways that are triggered when insulin binds to its receptor and the membrane transport events that need to be modified to divert GLUT4 from intracellular storage to an active plasma membrane shuttle service.     

Isoproterenol inhibits cyclic AMP-mediated but not insulin-mediated translocation of the GLUT4 glucose transporter isoform

Isoproterenol is a beta adrenergic agonist whose effects have been attributed to the generation of cAMP. Previous studies have shown that it inhibits glucose transport in adipocytes without changing the number of insulin-responsive glucose transporters (GLUT4) on the cell surface. However, we have shown previously that cAMP stimulates translocation of GLUT4 to the cell surface in adipocytes (Keladaet al. J Biol Chem 267, 7021–7025, 1992). We therefore further investigated the mechanisms involved in isoproterenol regulation of glucose transport. Consistent with the effects of dibutyryl cAMP, we found that a low concentration of isoproterenol (10 nM) stimulated glucose transport and the translocation of GLUT4 from the low density microsomal fraction to the plasma membrane. By contrast, a higher concentration of isoproterenol (1 M) did not stimulate transport or GLUT4 translocation and furthermore inhibited dibutyryl cAMP-stimulated GLUT4 translocation. This inhibitory effect was specific for cAMP since isoproterenol had no effect on insulin-stimulated GLUT4 translocation. We conclude that isoproterenol has a biphasic effect on glucose transport, mediated by acute translocation of GLUT4 at low concentrations and by inhibition of intrinsic activity at high concentration, both of which may be explained by effects of cAMP. It has a further cAMP-independent effect at high concentration to inhibit cAMP-mediated translocation of GLUT4.This work forms portions of the PhD thesis requirements.     

Discovery of novel pyridazine derivatives as glucose transporter type 4 (GLUT4) translocation activators

We report herein the synthesis and structure-activity relationships (SAR) of a series of pyridazine derivatives with the activation of glucose transporter type 4 (GLUT4) translocation. Through a cell-based phenotype screening in L6-GLUT4-myc myoblasts and functional glucose uptake assays, lead compound 1a was identified as a functional small molecule. After further derivatization, the thienopyridazine scaffold as the central ring (B-part) was revealed to have potent GLUT4 translocation activities. Consequently, we obtained promising compound 26b, which showed a significant blood glucose lowering effect in the severe diabetic mice model (10-week aged db/db mice) after oral dosing even at 10 mg/kg, implying that our pyridazine derivatives have potential to become novel therapeutic agents for diabetes mellitus.     

Lipocalin-type prostaglandin D(2) synthase stimulates glucose transport via enhanced GLUT4 translocation

Previously, we demonstrated that lipocalin-type prostaglandin D(2) synthase (L-PGDS) knockout mice become glucose intolerant and display signs of diabetic nephropathy and accelerated atherosclerosis. In the current study we sought to explain the link between L-PGDS and glucose tolerance. Using the insulin-sensitive rat skeletal muscle cell line, L6, we showed that L-PGDS could stimulate glucose transport approximately 2-fold as well as enhance insulin-stimulated glucose transport, as measured by 2-deoxy-[(3)H]-glucose uptake. The increased glucose transport was not attributed to increased GLUT4 production but rather the stimulation of GLUT4 translocation to the plasma membrane, a phenomenon that was lost when cells were cultured under hyperglycemic (20 mM) conditions or pretreated with wortmannin. There was however, an increase in GLUT1 expression as well as a 3-fold increase in hexokinase III expression, which was increased to nearly 5-fold in the presence of insulin, in response to L-PGDS at 20 mM glucose. In addition, adipocytes isolated from L-PGDS knockout mice were significantly less sensitive to insulin-stimulated glucose transport than wild-type. We conclude that L-PGDS, via production of prostaglandin D(2), is an important mediator of muscle and adipose glucose transport which is modulated by glycemic conditions and plays a significant role in the glucose intolerance associated with type 2 diabetes.     

Subcellular compartmentalization and trafficking of the insulin-responsive glucose transporter, GLUT4.

Insulin increases glucose transport into cells of target tissues, primarily striated muscle and adipose. This is accomplished via the insulin-dependent translocation of the facilitative glucose transporter 4 (GLUT4) from intracellular storage sites to the plasma membrane. Insulin binds to the cell-surface insulin receptor and activates its intrinsic tyrosine kinase activity. The subsequent activation of phosphatidylinositol 3-kinase (PI 3-K) is well known to be necessary for the recruitment of GLUT4 to the cell surface. Both protein kinase B (PKB) and the atypical protein kinase C(lambda/zeta) (PKClambda/zeta) appear to function downstream of PI 3-K, but how these effectors influence GLUT4 translocation remains unknown. In addition, emerging evidence suggests that a second signaling cascade that functions independently of the PI 3-K pathway is also required for the insulin-dependent translocation of GLUT4. This second pathway involves the Rho-family GTP binding protein TC10, which functions within the specialized environment of lipid raft microdomains at the plasma membrane. Future work is necessary to identify the downstream effectors that link TC10, PKB, and PKClambda/zeta to GLUT4 translocation. Progress in this area will come from a better understanding of the compartmentalization of GLUT4 within the cell and of the mechanisms responsible for targeting the transporter to specialized insulin-responsive storage compartments. Furthermore, an understanding of how GLUT4 is retained within and released from these compartments will facilitate the identification of downstream signaling molecules that function proximal to the GLUT4 storage sites.     

Aldolase mediates the association of F-actin with the insulin-responsive glucose transporter GLUT4.

To identify potential proteins interacting with the insulin-responsive glucose transporter (GLUT4), we generated fusion proteins of glutathione S-transferase (GST) and the final 30 amino acids from GLUT4 (GST-G4) or GLUT1 (GST-G1). Incubation of these carboxyl-terminal fusion proteins with adipocyte cell extracts revealed a specific interaction of GLUT4 with fructose 1, 6-bisphosphate aldolase. In the presence of aldolase, GST-G4 but not GST-G1 was able to co-pellet with filamentous (F)-actin. This interaction was prevented by incubation with the aldolase substrates, fructose 1,6-bisphosphate or glyceraldehyde 3-phosphate. Immunofluorescence confocal microscopy demonstrated a significant co-localization of aldolase and GLUT4 in intact 3T3L1 adipocytes, which decreased following insulin stimulation. Introduction into permeabilized 3T3L1 adipocytes of fructose 1,6-bisphosphate or the metabolic inhibitor 2-deoxyglucose, two agents that disrupt the interaction between aldolase and actin, inhibited insulin-stimulated GLUT4 exocytosis without affecting GLUT4 endocytosis. Furthermore, microinjection of an aldolase-specific antibody also inhibited insulin-stimulated GLUT4 translocation. These data suggest that aldolase functions as a scaffolding protein for GLUT4 and that glucose metabolism may provide a negative feedback signal for the regulation of glucose transport by insulin.     

Deuterium-depleted water stimulates GLUT4 translocation in the presence of insulin,which leads to decreased blood glucose concentration

Molecular and Cellular Biochemistry - Deuterium (D) is a stable isotope of hydrogen (H) with a mass number of 2. It is present in natural waters in the form of HDO, at a concentration of...     

Discrepancy between GLUT4 translocation and glucose uptake after ischemia

Objective: Low-flow ischemia results in glucose transporter translocation and in increased glucose uptake. After total ischemia in rat heart, we found no increase in glucose uptake. Here we test the hypothesis that total ischemia is associated with decreased activation of GLUT4 despite translocation. Methods: Isolated working hearts (n=70, Sprague–Dawley rats) were perfused for 70 min at physiological workload with Krebs–Henseleit buffer containing [2-³H]glucose (5 mmol/l, 0.05 μCi/ml) with either oleate (0.4 mmol/l, 1%BSA) or pyruvate (5 mmol/l, 1%BSA). After 20 min, hearts were subjected to 15 min of total ischemia followed by 35 min of reperfusion. We measured glucose uptake and intracellular free glucose (IFG) using [2-³H]glucose and [¹⁴C]sucrose, and determined the distribution of GLUT4 by colocalization immunofluorescence with Na–K ATP-ase. Results: Cardiac power was 10.1 ± 0.90 mW before ischemia and did not differ between groups. Recovery was the same in both groups (55.7 ± 24.8$%). Glucose uptake did not differ between groups before ischemia, and did not increase during reperfusion. Despite evidence of GLUT4 translocation after reperfusion in both groups, IFG did not increase compared with before ischemia. Conclusion: We conclude that there is a discrepancy between glucose transporter availability and glucose uptake after ischemia, which may be due to inhibition of GLUT4 in the plasma membrane. (Mol Cell Biochem 278: 129–137, 2005)     

A role for kinesin in insulin-stimulated GLUT4 glucose transporter translocation in 3T3-L1 adipocytes

Insulin regulates glucose uptake in adipocytes and muscle by stimulating the movement of sequestered glucose transporter 4 (GLUT4) proteins from intracellular membranes to the cell surface. Here we report that optimal insulin-mediated GLUT4 translocation is dependent upon both microtubule and actin-based cytoskeletal structures in cultured adipocytes. Depolymerization of microtubules and F-actin in 3T3-L1 adipocytes causes the dispersion of perinuclear GLUT4-containing membranes and abolishes insulin action on GLUT4 movements to the plasma membrane. Furthermore, heterologous expression in 3T3-L1 adipocytes of the microtubule-binding protein hTau40, which impairs kinesin motors that move toward the plus ends of microtubules, markedly delayed the appearance of GLUT4 at the plasma membrane in response to insulin. The hTau40 protein had no detectable effect on microtubule structure or perinuclear GLUT4 localization under these conditions. These results are consistent with the hypothesis that both the actin and microtubule-based cytoskeleton, as well as a kinesin motor, direct the translocation of GLUT4 to the plasma membrane in response to insulin.     

Moving the insulin-regulated glucose transporter GLUT4 into and out of storage

The glucose transporter isoform GLUT4 is unique among the glucose transporter family of proteins in that, in resting cells, it is sequestered very efficiently in a storage compartment. In insulin-sensitive cells, such as fat and muscle, insulin stimulation leads to release of GLUT4 from this reservoir and its translocation to the plasma membrane. This process is crucial for the control of blood and tissue glucose levels. Investigations of the composition and structure of the GLUT4 storage compartment, together with the targeting motifs that direct GLUT4 to this compartment, have been extensive but have been controversial. Recent findings have now provided a clearer consensus of opinion on the mechanisms involved in the formation of this storage compartment. However, another controversy has now emerged, which is unresolved. This concerns the issue of whether the insulin-regulated step occurs at the level of release of GLUT4 from the storage compartment or at the level at which released vesicles fuse with the plasma membrane.