Molecular and biochemical events during differentiation of the HD3 chicken erythroblastic cell line

The chicken erythroblast cell line HD3 is transformed by a temperature-sensitive mutant of avian erythroleukemia virus. Upon shift to the non-permissive temperature in the presence of inducers (hemin and butyric acid), HD3 cells differentiate to an erythrocyte phenotype and provide a model system for analyzing events associated with this process. Expression of some cell surface proteins undergoes drastic changes as cells mature to the erythrocyte stage with a selective loss of membrane proteins that appears to be species-specific. Specific changes also occur in the expression and activities of cytosolic enzymes reflecting alterations of metabolism. HD3 differentiation is characterized by increased transferrin receptor (TFR) expression and increased hemoglobin (Hb) synthesis, a marker for the erythrocyte. In parallel, there is a decrease in glucose transport and an increase in nucleoside transport signifying a switch from glycolytic hexose metabolism to metabolism of pentose from nucleoside. Likewise the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAD) declines while glucose-6-phosphate dehydrogenase (G6PDH) activity remains constant. Commitment to the erythrocyte lineage alters expression of specific genes: TFR mRNA level increases while expression decreases for GLUT1 and GLUT3 glucose transporter mRNAs and GAD mRNA. However, the relationship between GAD activity and GAD mRNA was complex indicating modulation of GAD mRNA and protein half-lives. Serine/threonine and tyrosine phosphorylation and cAMP levels were shown to regulate the level of these messages. In this review, we describe how HD3 differentiation involves changes in plasma membrane composition, metabolism and gene expression that are orchestrated at different levels of control by multiple signaling modalities.     

Erythrocytic differentiation and glyceraldehyde-3-phosphate dehydrogenase expression are regulated by protein phosphorylation and cAMP in HD3 cells

Utilisation of glucose undergoes a marked decline during erythroblastic differentiation in the chicken. Concomitantly there is a reduction in the expression of glucose transporter proteins and in the expression of the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAD). GAD activity declines, after an initial rise, while the level of GAD mRNA decreases rapidly after induction of differentiation. We have employed the temperature-sensitive chicken erythroblast cell line HD3 that differentiates to the erythrocyte phenotype at 42 degrees C in the presence of inducers (hemin and butyric acid). The role of tyrosine and serine/threonine phosphorylation pathways were evaluated with the phosphatase inhibitors sodium vanadate and okadaic acid, respectively. In the presence of phosphatase inhibitors, HD3 cells underwent differentiation and increased their synthesis of hemoglobin which is a marker protein for red blood cells differentiation. The levels of both GAD mRNA and enzymatic activity were increased by phosphatase inhibitors. The role of cAMP in differentiation was also assessed. Differentiation of HD3 cells was associated with an increase in cAMP. However the phosphodiesterase inhibitor IBMX was not a good inducer of hemoglobin synthesis but did induce GAD mRNA and enzymatic activity. Together these results suggest that multiple pathways (including serine/threonine phosphorylation, tyrosine phosphorylation and elevated cAMP) are involved in the regulation of erythroblastic differentiation, hemoglobin synthesis, GAD gene expression and GAD activity in HD3 cells.     

Adult neural stem cells express glucose transporters GLUT1 and GLUT3 and regulate GLUT3 expression

In the brain, glucose is transported by GLUT1 across the blood-brain barrier and into astrocytes, and by GLUT3 into neurons. In the present study, the expression of GLUT1 and GLUT3 mRNA and protein was determined in adult neural stem cells cultured from the subventricular zone of rats. Both mRNAs and proteins were coexpressed, GLUT1 protein being 5-fold higher than GLUT3. Stress induced by hypoxia and/or hyperglycemia increased the expression of GLUT1 and GLUT3 mRNA and of GLUT3 protein. It is concluded that adult neural stem cells can transport glucose by GLUT1 and GLUT3 and can regulate their glucose transporter densities.     

Distinct regulation of glucose transport and GLUT1/GLUT3 transporters by glucose deprivation and IGF-I in chromaffin cells

Effects of prolonged metabolic (glucose deprivation) and hormonal [insulin-like growth factor I (IGF-I)] challenge on regulation of glucose transporter (GLUT) expression, glucose transport rate and possible signaling pathways involved were studied in the neuroendocrine chromaffin cell. The results show that bovine chromaffin cells express both GLUT1 and GLUT3. Glucose deprivation and IGF-I activation led to an elevation of GLUT1 and GLUT3 mRNA, the strongest effect being that of IGF-I on GLUT3 mRNA. Both types of stimulus increased the GLUT1 protein content in a cycloheximide (CHX)-sensitive manner, and the glucose transport rate was elevated by 3- to 4-fold after 48 h under both experimental conditions. IGF-I-induced glucose uptake was totally suppressed by CHX. In contrast, only approximately 50% of transport activation in glucose-deprived cells was sensitive to the protein synthesis inhibitor. Specific inhibitors of mTOR/FRAP and p38 MAPK each partially blocked IGF-I-stimulated glucose transport, but had no effect on transport rate in glucose-deprived cells. The results are consistent with IGF-I-activated transport being completely dependent on new GLUT protein synthesis while the enhanced transport in glucose-deprived cells was partially achieved independent of new synthesis of proteins, suggesting a mechanism relying on preexisting transporters.     

Alteration of phosphotyrosine-containing proteins during differentiation of chicken erythroleukemia cells (HD3)

After treatment of HD3 cells with erythroid-inducing agents (hemin and butyric acid) at 42°C, the profile of phosphotyrosine-containing proteins was altered. Upon induction the overall level of phosphotyrosine-containing proteins increased. To examine the role of protein phosphorylation in HD3 cells differentiation, the cells were treated with specific inhibitors. In the presence of okadaic acid, cell proliferation was arrested and accompanied by a marked increase in haemoglobin synthesis, a differentiation marker of erythroid cells. Okadaic acid caused decrease of the phosphotyrosine-containing proteins, presumably to maintain a balance between phosphorylation/dephosphorylation processes in the cells. Addition of 3-isobutyl-l-methyl-xanthine, an activator of phosphatases, caused a decrease or disappearance of almost all phosphotyrosine-containing proteins and, at the same time, prevented the erythroid differentiation of HD3 cells. Sodium orthovanadate, a specific inhibitor of phosphotyrosine phosphatase, increased the level of phosphotyrosine proteins and induced differentiation of HD3 cells. These results indicate that phosphorylation of cellular proteins is coupled with a reaction(s) which is responsible for triggering the differentiation of HD3 cells. The phosphorylation/dephosphorylation processes are associated with an early event(s) during the differentiation of HD3 cells and may not be connected to tyrosine residues. Copyright © 1998 John Wiley & Sons, Ltd.     

The formation of an insulin-responsive vesicular cargo compartment is an early event in 3T3-L1 adipocyte differentiation

Differentiating 3T3-L1 cells exhibit a dramatic increase in the rate of insulin-stimulated glucose transport during their conversion from proliferating fibroblasts to nonproliferating adipocytes. On day 3 of 3T3-L1 cell differentiation, basal glucose transport and cell surface transferrin binding are markedly diminished. This occurs concomitant with the formation of a distinct insulin-responsive vesicular pool of intracellular glucose transporter 1 (GLUT1) and transferrin receptors as assessed by sucrose velocity gradients. The intracellular distribution of the insulin-responsive aminopeptidase is first readily detectable on day 3, and its gradient profile and response to insulin at this time are identical to that of GLUT1. With further time of differentiation, GLUT4 is expressed and targeted to the same insulin-responsive vesicles as the other three proteins. Our data are consistent with the notion that a distinct insulin-sensitive vesicular cargo compartment forms early during fat call differentiation and its formation precedes GLUT4 expression. The development of this compartment may result from the differentiation-dependent inhibition of constitutive GLUT1 and transferrin receptor trafficking such that there is a large increase in, or the new formation of, a population of postendosomal, insulin-responsive vesicles.     

A GSK-3/TSC2/mTOR pathway regulates glucose uptake and GLUT1 glucose transporter expression

Glucose transport is a highly regulated process and is dependent on a variety of signaling events. Glycogen synthase kinase-3 (GSK-3) has been implicated in various aspects of the regulation of glucose transport, but the mechanisms by which GSK-3 activity affects glucose uptake have not been well defined. We report that basal glycogen synthase kinase-3 (GSK-3) activity regulates glucose transport in several cell types. Chronic inhibition of basal GSK-3 activity (8-24 h) in several cell types, including vascular smooth muscle cells, resulted in an approximately twofold increase in glucose uptake due to a similar increase in protein expression of the facilitative glucose transporter 1 (GLUT1). Conversely, expression of a constitutively active form of GSK-3beta resulted in at least a twofold decrease in GLUT1 expression and glucose uptake. Since GSK-3 can inhibit mammalian target of rapamycin (mTOR) signaling via phosphorylation of the tuberous sclerosis complex subunit 2 (TSC2) tumor suppressor, we investigated whether chronic GSK-3 effects on glucose uptake and GLUT1 expression depended on TSC2 phosphorylation and TSC inhibition of mTOR. We found that absence of functional TSC2 resulted in a 1.5-to 3-fold increase in glucose uptake and GLUT1 expression in multiple cell types. These increases in glucose uptake and GLUT1 levels were prevented by inhibition of mTOR with rapamycin. GSK-3 inhibition had no effect on glucose uptake or GLUT1 expression in TSC2 mutant cells, indicating that GSK-3 effects on GLUT1 and glucose uptake were mediated by a TSC2/mTOR-dependent pathway. The effect of GSK-3 inhibition on GLUT1 expression and glucose uptake was restored in TSC2 mutant cells by transfection of a wild-type TSC2 vector, but not by a TSC2 construct with mutated GSK-3 phosphorylation sites. Thus, TSC2 and rapamycin-sensitive mTOR function downstream of GSK-3 to modulate effects of GSK-3 on glucose uptake and GLUT1 expression. GSK-3 therefore suppresses glucose uptake via TSC2 and mTOR and may serve to match energy substrate utilization to cellular growth.     

Differential regulation of NHE1 phosphorylation and glucose uptake by inhibitors of the ERK pathway and p90RSK in 3T3-L1 adipocytes

Insulin stimulates trafficking of GLUT4 to the cell surface for glucose uptake into target cells, and phosphorylation of Ser703 of the Na⁺/H⁺ exchanger NHE1, which activates proton efflux. The latter has been proposed to facilitate optimal glucose uptake into cardiomyocytes. We found that the insulin-stimulated phosphorylation of Ser703 of NHE1 is mediated by p90RSK but not directly coupled to glucose uptake in 3T3-L1 adipocytes in the short-term. Inhibiting Erk1/2 activation prevented NHE1 phosphorylation but not glucose uptake in 3T3-L1 adipocytes. In contrast, both NHE1 phosphorylation and insulin-stimulated uptake of glucose into 3T3-L1 adipocytes were blocked by inhibitors of the N-terminal kinase domain of p90RSK, namely BI-D1870 and SL0101, but not the FMK inhibitor of the C-terminal kinase domain of p90RSK, though in our hands FMK did not inhibit p90RSK in 3T3-L1 adipocytes. Further experiments were consistent with phosphorylation of AS160 by PKB/Akt mediating insulin-stimulated trafficking of GLUT4 to the plasma membrane. BI-D1870 and SL0101 however, inhibited glucose uptake without blocking GLUT4 translocation. While BI-D1870 partially inhibited insulin-stimulated PKB activation in these cells, this only partially inhibited AS160 phosphorylation and did not block GLUT4 trafficking, suggesting that p90RSK might regulate glucose transport after GLUT4 translocation. Moreover, BI-D1870 also prevented PMA-induced glucose transport in 3T3-L1 adipocytes further suggesting a role for p90RSK in regulating uptake of glucose into the cells. Kinetic experiments are consistent with SL0101 being a direct competitor of 2-deoxyglucose entry into cells, and this compound might also inhibit uptake of glucose into cells via inhibiting p90RSK, as revealed by comparison with the inactive form of the inhibitor. Taken together, we propose that BI-D1870 and SL0101 might exert their inhibitory effects on glucose uptake in 3T3-L1 adipocytes at least partially through a p90RSK dependent step after GLUT4 becomes associated with the plasma membrane.     

A novel role of neuregulin in skeletal muscle. Neuregulin stimulates glucose uptake, glucose transporter translocation, and transporter expression in muscle cells

Neuregulins regulate the expression of acetylcholine receptor genes and induce development of the neuromuscular junction in muscle. In studying whether neuregulins regulate glucose uptake in muscle, we analyzed the effect of a recombinant neuregulin, (r)heregulin-beta1-(177-244) (HRG), on L6E9 muscle cells, which express the neuregulin receptors ErbB2 and ErbB3. L6E9 responded acutely to HRG by a time- and concentration-dependent stimulation of 2-deoxyglucose uptake. HRG-induced stimulation of glucose transport was additive to the effect of insulin. The acute stimulation of the glucose transport induced by HRG was a consequence of the translocation of GLUT4, GLUT1, and GLUT3 glucose carriers to the cell surface. The effect of HRG on glucose transport was dependent on phosphatidylinositol 3-kinase activity. HRG also stimulated glucose transport in the incubated soleus muscle and was additive to the effect of insulin. Chronic exposure of L6E9 cells to HRG potentiated myogenic differentiation, and under these conditions, glucose transport was also stimulated. The activation of glucose transport after chronic HRG exposure was due to enhanced cell content of GLUT1 and GLUT3 and to increased abundance of these carriers at the plasma membrane. However, under these conditions, GLUT4 expression was markedly down-regulated. Muscle denervation is associated with GLUT1 induction and GLUT4 repression. In this connection, muscle denervation caused a marked increase in the content of ErbB2 and ErbB3 receptors, which occurred in the absence of alterations in neuregulin mRNA levels. This fact suggests that neuregulins regulate glucose transporter expression in denervated muscle. We conclude that neuregulins regulate glucose uptake in L6E9 muscle cells by mechanisms involving the recruitment of glucose transporters to the cell surface and modulation of their expression. Neuregulins may also participate in the adaptations in glucose transport that take place in the muscle fiber after denervation.     

Myosin 5a is an insulin-stimulated Akt2 (protein kinase Bbeta) substrate modulating GLUT4 vesicle translocation

Phosphatidylinositol 3-kinase activation of Akt signaling is critical to insulin-stimulated glucose transport and GLUT4 translocation. However, the downstream signaling events following Akt activation which mediate glucose transport stimulation remain relatively unknown. Here we identify an Akt consensus phosphorylation motif in the actin-based motor protein myosin 5a and show that insulin stimulation leads to phosphorylation of myosin 5a at serine 1650. This Akt-mediated phosphorylation event enhances the ability of myosin 5a to interact with the actin cytoskeleton. Small interfering RNA-induced inhibition of myosin 5a and expression of dominant-negative myosin 5a attenuate insulin-stimulated glucose transport and GLUT4 translocation. Furthermore, knockdown of Akt2 or expression of dominant-negative Akt (DN-Akt) abolished insulin-stimulated phosphorylation of myosin 5a, inhibited myosin 5a binding to actin, and blocked insulin-stimulated glucose transport. Taken together, these data indicate that myosin 5a is a newly identified direct substrate of Akt2 and, upon insulin stimulation, phosphorylated myosin 5a facilitates anterograde movement of GLUT4 vesicles along actin to the cell surface.     

Growth factors, mitogens, oncogenes and the regulation of glucose transport

The erythrocyte (or HepG2/brain) type glucose transporter (GLUT 1) was the first of the family of facilitative glucose transporter proteins to be cloned [M. Mueckler et al., Science 229, 941–945, 1985]. GLUT 1 is expressed in most tissue types, all cells lines, transformed cells and tumour cells. It is thought to be responsible for ‘housekeeping’ levels of glucose transport, i.e. the uptake of glucose required for oxidative phosphorylation. The rate of glucose transport via GLUT 1 can be regulated under conditions in which the metabolic rate must be adjusted such as cell division (mitosis and meiosis), differentiation, transformation and nutrient starvation. Here we review the recent literature on the control of glucose transport of mitogens, growth factors and oncogenes, and discuss some of the implications for the integration of cellular signalling pathways and cell growth.     

Endothelin stimulates glucose uptake and GLUT4 translocation via activation of endothelin ETA receptor in 3T3-L1 adipocytes

Endothelin-1 (ET-1) is a 21-amino acid peptide that binds to G-protein-coupled receptors to evoke biological responses. This report studies the effect of ET-1 on regulating glucose transport in 3T3-L1 adipocytes. ET-1, but not angiotensin II, stimulated glucose uptake in a dose-dependent manner with an EC50 value of 0.29 nM and a 2.47-fold stimulation at 100 nM. ET-1 stimulated glucose uptake in differentiated 3T3-L1 cells but had no effect in undifferentiated cells, although ET-1 stimulated phosphatidylinositol hydrolysis to a similar degree in both. The 3T3-L1 cells expressed approximately 560,000 sites/cell of ETA receptor, which was not altered during differentiation. Western blot analysis and immunofluorescence staining show that ET-1 stimulated the translocation of insulin-responsive aminopeptidase and GLUT4 to the plasma membrane. The effect of ET-1 on glucose uptake was blocked by A-216546, an antagonist selective for the ETA receptor. ET-1 treatment did not induce phosphorylation of insulin receptor beta-subunit, insulin receptor substrate-1, or Akt but stimulated the tyrosyl phosphorylation of a 75-kDa protein. Genistein (100 microM), an inhibitor of tyrosine kinases, inhibited ET-1-stimulated glucose uptake. Our results show that ET-1 stimulates GLUT4 translocation and glucose uptake in 3T3-L1 adipocytes via activation of ETA receptor.     

Interleukin-3-mediated cell survival signals include phosphatidylinositol 3-kinase-dependent translocation of the glucose transporter GLUT1 to the cell surface

Maintenance of glucose uptake is a key component in the response of hematopoietic cells to survival factors. To investigate the mechanism of this response we employed the interleukin-3 (IL-3)-dependent murine mast cell line IC2.9. In these cells, hexose uptake decreased markedly upon withdrawal of IL-3, whereas its readdition led to rapid (t(1/2) approximately 10 min) stimulation of transport, associated with an approximately 4-fold increase in Vmax but no change in Km. Immunocytochemistry and photoaffinity labeling revealed that IL-3 caused translocation of intracellular GLUT1 transporters to the cell surface, whereas a second transporter isoform, GLUT3, remained predominantly intracellular. The inhibitory effects of latrunculin B and jasplakinolide, and of nocodazole and colchicine, respectively, revealed a requirement for both the actin and microtubule cytoskeletons in GLUT1 translocation and transport stimulation. Both IL-3 stimulation of transport and GLUT1 translocation were also prevented by the phosphatidylinositol 3-kinase inhibitors wortmannin and LY294002. The time courses for activation of phosphatidylinositol 3-kinase and its downstream target, protein kinase B, by IL-3 were consistent with a role in IL-3-induced transporter translocation and enhanced glucose uptake. We conclude that one component of the survival mechanisms elicited by IL-3 involves the subcellular redistribution of glucose transporters, thus ensuring the supply of a key metabolic substrate.     

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.     

Expression and compartmentalization of caveolin in adipose cells: coordinate regulation with and structural segregation from GLUT4

Native rat adipocytes and the mouse adipocyte cell line, 3T3-L1, possess transport vesicles of apparently uniform composition and size which translocate the tissue-specific glucose transporter isoform, GLUT4, from an intracellular pool to the cell surface in an insulin- sensitive fashion. Caveolin, the presumed structural protein of caveolae, has also been proposed to function in vesicular transport. Thus, we studied the expression and subcellular distribution of caveolin in adipocytes. We found that rat fat cells express the highest level of caveolin protein of any tissue studied, and caveolin is also expressed at high levels in cardiac muscle, another tissue possessing insulin responsive GLUT4 translocation. Both proteins are absent from 3T3-L1 fibroblasts and undergo a dramatic coordinate increase in expression upon differentiation of these cells into adipocytes. However, unlike GLUT4 in rat adipocytes not exposed to insulin, the majority of caveolin is present in the plasma membrane. In native rat adipocytes, intracellular GLUT4 and caveolin reside in vesicles practically indistinguishable by their size and buoyant density in sucrose gradients, and both proteins show insulin-dependent translocation to the cell surface. However, by immunoadsorption of GLUT4-containing vesicles with anti-GLUT4 antibody, we show that these vesicles have no detectable caveolin, and therefore, this protein is present in a distinct vesicle population. Thus, caveolin has no direct structural relation to the organization of the intracellular glucose transporting machinery in fat cells.     

Molecular and cellular regulation of glucose transporter (GLUT) proteins in cancer

Malignant cells are known to have accelerated metabolism, high glucose requirements, and increased glucose uptake. Transport of glucose across the plasma membrane of mammalian cells is the first rate-limiting step for glucose metabolism and is mediated by facilitative glucose transporter (GLUT) proteins. Increased glucose transport in malignant cells has been associated with increased and deregulated expression of glucose transporter proteins, with overexpression of GLUT1 and/or GLUT3 a characteristic feature. Oncogenic transformation of cultured mammalian cells causes a rapid increase of glucose transport and GLUT1 expression via interaction with GLUT1 promoter enhancer elements. In human studies, high levels of GLUT1 expression in tumors have been associated with poor survival. Studies indicate that glucose transport in breast cancer is not fully explained by GLUT1 or GLUT3 expression, suggesting involvement of another glucose transporter. Recently, a novel glucose transporter protein, GLUT12, has been found in breast and prostate cancers. In human breast and prostate tumors and cultured cells, GLUT12 is located intracellularly and at the cell surface. Trafficking of GLUT12 to the plasma membrane could therefore contribute to glucose uptake. Several factors have been implicated in the regulation of glucose transporter expression in breast cancer. Hypoxia can increase GLUT1 levels and glucose uptake. Estradiol and epidermal growth factor, both of which can play a role in breast cancer cell growth, increase glucose consumption. Estradiol and epidermal growth factor also increase GLUT12 protein levels in cultured breast cancer cells. Targeting GLUT12 could provide novel methods for detection and treatment of breast and prostate cancer.