Properties of hexose-transport regulatory mutants isolated from L6 rat myoblasts.

A hexose-transport regulatory mutant (D1/S4) was isolated from L6 rat myoblasts on the basis of its resistance to detachment and cell lysis in the presence of antibody and complement. Growth studies indicated that D1/S4 cells had a slower doubling time (29 h) compared with the parental L6 cells (22 h). Furthermore, after 9 days growth, less than 1% cell fusion was observed with D1/S4 cells, whereas 95% cell fusion was observed with the L6 cells. When the parental L6 cells were starved of glucose or treated with anti-L6 antibody, a significant increase in the Vmax, of 2-deoxy-D-glucose (dGlc) and 3-O-methyl-D-glucose (MeGlc) transport was observed. Although glucose-grown D1/S4 cells possessed normal hexose-transport activity, the above treatments had no effect on dGlc and MeGlc transport in these cells. Electrophoresis and immunoblotting studies revealed that D1/S4 cells possessed decreased amounts of a 112 kDa plasma-membrane protein. It is conceivable that this protein may play a role in triggering the antibody- and glucose-starvation-mediated activation of hexose transport and in myogenic differentiation. Unlike D1/S4, mutant F72, a mutant defective in the high-affinity hexose-transport system, was found to possess normal amounts of the 112 kDa protein. Although glucose starvation has no effect on the hexose-transport activity in this mutant, its hexose transport activity can be increased by antibody treatment. These studies with mutants suggest the involvement of regulatory components in the activation of hexose transport.     

Glucose as a regulator of insulin-sensitive hexose uptake in 3T3 adipocytes

In the present study we examined the role of glucose in the regulation of its own transport activity in the cultured 3T3 fat cell. A regulatory control of glucose became apparent after these cells were cultured in the absence of glucose. Glucose deprivation of the cells was accompanied by a specific time and protein synthesis-dependent increase in dGlc (2-deoxyglucose) uptake (up to 5-fold), which was due to an increase in the apparent Vmax of the transport system. Concomitantly, the stimulatory effect of insulin on hexose uptake almost completely disappeared. Addition of glucose to the glucose-deprived cells rapidly reversed the deprivation effects. Cycloheximide experiments revealed that the glucose deprivation-induced increase in hexose uptake required protein synthesis as well as a protein synthesis-independent response to glucose deprivation that retarded the turnover of hexose transport activity. Taken together, these data indicate that glucose deprivation is accompanied by retardation of the rate of degradation, internalization, or inactivation of hexose transporters while the increase in dGlc uptake requires at least the continuation of protein synthesis-dependent de novo synthesis, insertion, or activation of hexose transporters. Hexose competitively taken up with dGlc, including the nonmetabolizable glucose analogue 3-O-methylglucose, could replace glucose in the process of prevention and reversal of the deprivation effects, indicating that competitive transport but not the metabolism of hexose is a prerequisite for the regulatory effect of glucose on the activity of its own transport system. In conclusion, our results indicate that in cultured 3T3 fat cells glucose itself is involved in the regulation of the activity of its own transport system by influencing the rate of degradation, internalization, or inactivation of hexose transporters by a protein synthesis-independent mechanism.     

Regulation of hexose transport in L8 myocytes by glucose: possible sites of interaction

Previous work demonstrated that glucose controls its own transport rate in rat skeletal muscle: exposure to high glucose levels down-regulates muscle hexose transport, while glucose withdrawal results in elevated transport rates (J. Biol. Chem. 261:16827-16833, 1986). The present study investigates the mechanism of this autoregulatory system. Preincubation of L8 myocytes at 16 mM glucose reduced subsequent 2-deoxy-D-glucose (dGlc) uptake by 40% within 3 h. Cycloheximide (1 microM) mimicked the action of glucose; the effects of glucose and cycloheximide were not additive. At 50 microM, cycloheximide prevented the modulations of glucose transport induced by exposure of muscle cells to high or low glucose concentrations. Inhibition of glycosylation with tunicamycin A1 reduced the basal dGlc uptake, but did not prevent its up-regulation following glucose withdrawal. Inhibition of RNA synthesis by actinomycin D prevented the down-regulatory effect of glucose. These results indicate that continuous protein synthesis and protein glycosylation are required for the maintenance of the steady-state dGlc uptake. We suggest that glucose exerts its autoregulatory effect on hexose transport by modifying the incorporation of active glucose transporters into the plasma membrane rather than changing their rate of degradation. It is hypothesized that this effect is mediated by a non-glycosylated protein involved in the translocation or activation of glucose transporters.     

Use of a genetic variant to study the hexose transport properties of human skin fibroblasts.

Human skin fibroblasts from 'normal' subjects were found to possess at least two hexose transport systems. One system was responsible for the uptake of 2-deoxy-D-glucose (dGlc), D-glucose and D-galactose, whereas the other was responsible primarily for the uptake of 3-O-methyl-D-glucose (MeGlc). The transport of dGlc was the rate-limiting step in the uptake process; over 97% of the internalized dGlc was phosphorylated and the specific activity of hexokinase was several times higher than that for dGlc transport. The dGlc transport system was activated by glucose starvation, and was very sensitive to inhibition by cytochalasin B and energy uncouplers. Fibroblasts isolated from a patient with symptoms of hypoglycaemia were found to differ from their normal counterparts in the dGlc transport system. They exhibited a much higher transport affinity for dGlc, D-glucose and D-galactose, with no change in the respective transport capacity. Transport was not the rate-limiting step in dGlc uptake by these cells. Moreover, the patient's dGlc transport system was no longer sensitive to inhibition by cytochalasin B and energy uncouplers. This suggested that the intrinsic properties of the patient's dGlc transport system were altered. It should be noted that the patient's dGlc transport system could still be activated by glucose starvation. Despite the changes in the dGlc transport system, the MeGlc transport system in the patient's fibroblasts remained unaltered. The observed difference in the properties of the two hexose transport systems in the 'normal' and the patient's fibroblasts strongly suggests that the two transport systems may be coded or regulated by different genes. The present finding provides the first genetic evidence from naturally occurring fibroblasts indicating the presence of two different hexose transport systems.     

Hexose transport in plasma membrane vesicles prepared from L6 rat myoblasts

Hexose transport in plasma membrane vesicles prepared from L6 rat myoblasts was shown to be stereospecific, activated by glucose starvation and occurred by both high and low affinity systems. Transport by the high affinity system was shown to occur by an active transport process. Furthermore, the high affinity system was shown to be defective in vesicles prepared from F72 cells (hexose transport mutant). These results indicate that the high affinity hexose transport system is retained in the plasma membrane vesicles. Thus plasma membrane vesicles could be of value in further characterization of the L6 high affinity hexose transport system, without interference from the various metabolic events occurring in whole cells.     

Hexose and amino acid transport by chicken embryo fibroblasts infected with temperature-sensitive mutant of Rous sarcoma virus. Comparison of transport properties of whole cells and membrane vesicles

The effect of transformation on hexose and amino acid transport has been studied using whole cells and membrane vesicles of chicken embryo fibroblasts infected with the temperature-sensitive mutant of the Rous sarcoma virus, TS-68. In whole cells, TS-68-infected chicken embryo fibroblasts cultured at the permissive temperature (37 degrees C) had a 2-fold higher rate of 2-deoxy-D-glucose uptake than the same cells cultured at the non-permissive temperature (41 degrees C). However, both the non-transformed and transformed cells had comparable rates of alpha-aminoisobutyric acid transport. Membrane vesicles, isolated from TS-68-infected chicken embryo fibroblasts cultured at 41 degrees C or 37 degrees C, displayed carrier-mediated, intravesicular uptake of D-glucose and alpha-aminoisobutyric acid. Membrane vesicles from TS-68-infected chicken embryo fibroblasts cultured at 37 degrees C had an approx. 50% greater initial rate of stereospecific hexose uptake than the membrane vesicles from fibroblasts cultured at 41 degrees C. The two types of membrane vesicle had similar uptake rates of alpha-aminoisobutyric acid. The results of hexose and amino acid uptake by the membrane vesicles correlated well with those observed with the whole cells. Km values for stereospecific D-glucose uptake by the membrane vesicles from TS-68-infected chicken embryo fibroblasts cultured at 41 and 37 degrees C were similar, but the V value was greater for the membrane vesicles from TS-68-infected cells cultured at 37 degrees C. Cytochalasin B competitively inhibited stereospecific hexose uptake in both types of membrane vesicle. These findings suggest that the membrane vesicles retained many of the features of hexose and amino acid transport observed in whole cells, and that the increased rate of hexose transport seen in the virally-transformed chicken embryo fibroblasts was due to an increase in the number or availability of hexose carriers.     

Dissociation of 5' AMP-activated protein kinase activation and glucose uptake stimulation by mitochondrial uncoupling and hyperosmolar stress: differential sensitivities to intracellular Ca2+ and protein kinase C inhibition

2,4-dinitrophenol (DNP) compromises ATP production within the cell by disrupting the mitochondrial electron transport chain. The resulting loss of ATP leads to an increase in glucose uptake for anaerobic generation of ATP. In L6 skeletal muscle cells, DNP increases the rate of glucose uptake by twofold. We previously showed that DNP increases cell surface levels of glucose transporter 4 (GLUT4) and hexose uptake via a Ca2+-sensitive and conventional protein kinase C (cPKC)-dependent mechanism. Recently, 5' AMP-activated protein kinase (AMPK) has been proposed to mediate the stimulation of glucose uptake by energy stressors such as exercise and hypoxia. Changes in Ca2+ and cPKC have also been invoked in the stimulation of glucose uptake by exercise and hypoxia. Here we examine whether changes in cytosolic Ca2+ or cPKC lead to activation of AMPK. We show that treatment of L6 cells with DNP (0.5 mM) or hyperosmolar stress (mannitol, 0.6 M) increased AMPK activity by 3.5-fold. AMPK activation peaked by 10-15 min prior to maximal stimulation of glucose uptake. Intracellular Ca2+ chelation and cPKC inhibition prior to treatment with DNP and hyperosmolarity significantly reduced cell surface GLUT4 levels and hexose uptake but had no effect on AMPK activation. These results illustrate a break in the relationship between AMPK activation and glucose uptake in skeletal muscle cells. Activation of AMPK does not suffice to stimulate glucose uptake in response to DNP and hyperosmolarity.     

Hexose and amino acid transport by chicken embryo fibroblasts infected with temperature-sensitive mutant of rous sarcoma virus: Comparison of transport properties of whole cells and membrane vesicles

The effect of transformation on hexose and amino acid transport has been studied using whole cells and membrane vesicles of chicken embryo fibroblasts infected with the temperature-sensitive mutant of the Rous sarcoma virus, TS-68. In whole cells, TS-68-infected chicken embryo fibroblasts cultured at the permissive temperature (37°C) had a 2-fold higher rate of 2-deoxy-d-glucose uptake than the same cells cultured at the non-permissive temperature (41°C). However, both the non-transformed and transformed cells had comparable rates of α-aminoisobutyric acid transport. Membrane vesicles, isolated from TS-68-infected chicken embryo fibroblasts cultured at 41°C or 37°C, displayed carrier-mediated, intravesicular uptake of d-glucose and α-aminoisobutyric acid. Membrane vesicles from TS-68-infected chicken embryo fibroblasts cultured at 37°C had an approx. 50% greater initial rate of stereospecific hexose uptake than the membrane vesicles from fibroblasts cultured at 41°C. The two types of membrane vesicle had similar uptake rates of α-aminoisobutyric acid. The results of hexose and amino acid uptake by the membrane vesicles correlated well with those observed with the whole cells. K_m values for stereospecific d-glucose uptake by the membrane vesicles from TS-68-infected chicken embryo fibroblasts cultured at 41 and 37°C were similar, but the V value was greater for the membrane vesicles from TS-68-infected cells cultured at 37°C. Cytochalasin B competitively inhibited stereospecific hexose uptake in both types of membrane vesicle. These findings suggest that the membrane vesicles retained many of the features of hexose and amino acid transport observed in whole cells, and that the increased rate of hexose transport seen in the virallytransformed chicken embryo fibroblasts was due to an increase in the number or availability of hexose carriers.     

Protein kinase C is not required for insulin stimulation of hexose uptake in muscle cells in culture.

The L6 skeletal muscle cell line has been identified as a suitable model to study the action of insulin on glucose uptake in muscle [Klip, Li & Logan (1984) Am. J. Physiol. 247, E291-E296]. The signals that transfer information from occupied insulin receptors to glucose transporters remain unknown. Here we report that activation of protein kinase C by exogenous phorbol esters results in stimulation of glucose uptake. Protein C kinase activity was induced to migrate from the cytosolic fraction to the microsomal fraction after 40 min of exposure of intact cells to 4 beta-phorbol 12,13-dibutyrate. In contrast, incubation with insulin did not alter the subcellular distribution of the kinase. Prolonged preincubation of L6 cells with phorbol esters resulted in depletion of kinase C activity, whereas neither the basal rate of glucose uptake nor its stimulation by insulin were affected. This suggests that protein kinase C is expressed in L6 cells, and that insulin stimulation of hexose transport does not involve protein kinase C.     

Hexose transport in L6 rat myoblasts. I. Rate-limiting step, kinetic properties, and evidence for two systems

The hexose transport system of undifferentiated L6 rat myoblasts was investigated. 2-Deoxy-D-glucose (2-DOG) and 2-deoxy-2-fluoro-D-glucose (2FG) were used as analogues to investigate the rate-limiting step of hexose uptake into the cell. Virtually all of the 2-DOG or 2FG taken up into the cell was found to be in the phosphorylated form. No significant pool of intracellular free sugar could be detected. This demonstrates that hexose transport, not phosphorylation, is the rate-limiting step. The inhibitory effect of various glucose analogues on 2-DOG and 3-O-methyl-D-glucose (3-OMG) uptake revealed that these two sugars may be taken up into the cell by different carriers. In addition, kinetics analysis of the transport of both sugars also indicates that two hexose transport systems may be present in L6 cells. 2-DOG is transported by high and low affinity transport systems (Km 0.6 mM and 2.9 mM, respectively), whereas 3-OMG is transported by a low affinity system (Km 3.5 mM). Treatment of cells with ionophores or energy uncouplers results in inactivation of the high affinity system, but not the low affinity system.     

Role of calcium in serum-stimulation of hexose transport in muscle cells

Serum stimulates glucose uptake into several cells in culture. In intact muscle, an increase in cytosolic free Ca2+ has been proposed to mediate the activation of glucose uptake by hormones and other stimuli [Cell Calcium (1980) 1, 311-325]. We report that hexose (2-deoxy-D-glucose) uptake into L6 muscle cells in culture is enhanced several-fold by fetal calf serum. The increase in uptake is due to stimulation of transmembrane transport, since serum also stimulated uptake of the non-metabolizable hexose 3-O-methyl-D-glucose. The role of Ca2+ in this stimulation was assessed: (i) stimulation of transport by serum was independent of the presence of extracellular Ca2+ during the incubation with serum; (ii) the intracellular levels of free Ca2+, measured by the fluorescence of the novel Ca-indicator quin-2, were identical in serum-stimulated and control cells. It is concluded that hexose transport can increase in muscle cells without concomitant changes in cytoplasmic free Ca2+.     

Synergistic activation of 2-deoxy-D-glucose uptake in rat and murine peritoneal macrophages by human macrophage colony-stimulating factor-stimulated coupling between transport and hexokinase activity and phorbol-dependent stimulation of pentose phosphate-shunt activity.

1. Transport and accumulation of 2-deoxy-D-glucose (2dGlc) in rat and murine peritoneal macrophages were investigated by using C-1-3H-labelled and C-2,6-3H-labelled 2dGlc. 2. There was active accumulation of both C-1- and C-2,6-labelled 2dGlc by quiescent rat and murine macrophages via a phloretin-inhibitable transport system. 3. The rate of uptake and accumulation of 2dGlc (C-1 label) was increased by exposure to human macrophage colony-stimulating factor (mCSF-1) (1000 units/ml) in both murine and rat macrophages. This indicates that mCSF-1 enhances coupling between hexokinase activity and glucose transport at the endofacial surface of the transporter. 4. Phorbol 12-myristate 13-acetate ('phorbol') at 40 nM stimulated 2dGlc in rat macrophages entirely by increasing the C-2,6 label uptake. This indicates that phorbol stimulates 2dGlc uptake mainly by increasing the activity of the pentose phosphate pathway. 5. Simultaneous exposure to phorbol and mCSF-1 stimulates 2dGlc uptake to a greater extent than found with either phorbol or mCSF-1 alone. This result is explained by a simultaneous enhancement of pentose phosphate-pathway activity and of hexokinase activity acting at the endofacial surface of the cell membrane. The dual activation of these serial processes coupled to the loss of the reaction products of the pentose phosphate-shunt pathway from the cells in the form of reactive oxygen intermediates, protons and CO2 could explain the synergistic action of phorbol and mCSF-1 in activation of sugar transport in macrophages.     

Dissociation of insulin-stimulated glucose transport from the translocation of glucose carriers in rat adipose cells

Cycloheximide, a potent inhibitor of protein synthesis, has been used to examine the relationship between recruitment of hexose carriers and the activation of glucose transport by insulin in rat adipocytes. Adipocytes were preincubated +/- cycloheximide for 90 min then +/- insulin for a further 30 min. We measured 3-O-methylglucose uptake in intact cells and in isolated plasma membrane vesicles. The concentration of glucose transporters in plasma membranes and low density microsomes was measured using a cytochalasin B binding assay. Cycloheximide had no affect on basal or insulin-stimulated 3-O-methylglucose uptake in intact cells or in plasma membrane vesicles. However, the number of glucose carriers in plasma membranes prepared from cells incubated with cycloheximide and insulin was markedly reduced compared to that from cells incubated with insulin alone (14 and 34 pmol/mg protein, respectively). Incubation of cells with cycloheximide alone did not change the concentration of glucose carriers in either plasma membranes or in low density microsomes compared to control cells. When isolated membranes were analyzed with an antiserum prepared against human erythrocyte glucose transporter, decreased cross-reactivity was observed in plasma membranes prepared from cycloheximide/insulin-treated cells compared to those from insulin cells. The present findings indicate that incubation of adipocytes with cycloheximide greatly reduces the number of hexose carriers in the plasma membrane of insulin-stimulated cells. Despite this reduction, insulin is still able to maximally stimulate glucose uptake. Thus, these data suggest an apparent dissociation between insulin stimulation of glucose transport activity and the recruitment of glucose carriers by the hormone.     

Glucose uptake in human and animal muscle cells in culture

Human muscle cells were grown in culture from satellite cells present in muscle biopsies and fusion-competent clones were identified. Hexose uptake was studied in fused myotubes of human muscle cells in culture and compared with hexose uptake in myotubes of the rat L6 and mouse C2C12 muscle cell lines. Uptake of 2-deoxyglucose was saturable and showed an apparent Km of about 1.5 mM in myotubes of all three cell types. The Vmax of uptake was about 6000 pmol/(min.mg protein) in human cells, 4000 pmol/(min.mg protein) in mouse C2C12 muscle cells, and 500 pmol/(min.mg protein) in L6 cells. Hexose uptake was inhibited approximately 90% by cytochalasin B in human, rat, and mouse muscle cell cultures. Insulin stimulated 2-deoxyglucose uptake in all three cultures. The hormone also stimulated transport of 3-O-methylglucose. The sensitivity to insulin was higher in human and C2C12 mouse myotubes (half-maximal stimulation observed at 3.5 X 10(-9) M) than in rat L6 myotubes (half-maximal stimulation observed at 2.5 X 10(-8) M). However, insulin (10(-6) M) stimulated hexose uptake to a larger extent (2.37-fold) in L6 than in either human (1.58-fold) or mouse (1.39-fold) myotubes. It is concluded that human muscle cells grown in culture display carrier-mediated glucose uptake, with qualitatively similar characteristics to those of other muscle cells, and that insulin stimulates hexose uptake in human cells. These cultures will be instrumental in the study of human insulin resistance and in investigations on the mechanism of action of antidiabetic drugs.     

Genetic evidence indicating the identity of the cytochalasin B photolabelled components in rat myoblasts

While photolabelling with cytochalasin B (CB) has been widely used in the identification of eukaryotic glucose transporters, there is presently no unequivocal evidence indicating that the CB-labelled components are indeed the glucose transporters. A combination of biochemical, physiological and genetic manipulations was used in the present investigation to demonstrate that the plasma membrane hexose transporters can indeed by photolabelled by CB. In this study, plasma membranes from glucose-grown and glucose-starved hexose transport mutant D23 and its parental L6 cells were photolyzed in the presence of 3H-CB. The amount of CB bound to the 40-60 kDa region (CB50) was found to be differentially inhibited by D-glucose, 2-deoxy-D-glucose (dGlc) and 3-O-methyl-glucose (MeGlc). Mutant D23 exhibited not only reduced hexose transport activity but also significantly lower level of CB50. Glucose-starvation resulted not only in elevated hexose transport activity but also increased level of CB50. It should be noted glucose-starvation did not have much effect on the hexose transport activity and on the level of CB50 in mutant D23. The present study provides the first genetic evidence indicating that the CB-labelled component(s) are indeed associated with the hexose transport systems.     

Proline porter II is activated by a hyperosmotic shift in both whole cells and membrane vesicles of Escherichia coli K12

Proline porter II is rapidly activated when nongrowing bacteria are subjected to a hyperosmotic shift (Grothe, S., Krogsrud, R. L., McClellan, D. J., Milner, J. L., and Wood, J. M. (1986) J. Bacteriol. 166, 253-259). Proline porter II was active in membrane vesicles prepared from bacteria grown under optimal conditions, nutritional stress, or osmotic stress. That activity was: (i) dependent on the presence of the energy sources phenazine methosulphate plus ascorbate or D-lactate; (ii) observed only when a hyperosmotic shift accompanied the transport measurement; (iii) inhibited by glycine betaine in a manner analogous to that observed in whole cells; and (iv) eliminated by lesions in proP. Membrane vesicles were able to transport serine but not glutamine and serine transport was reduced by the hyperosmotic shift. In whole cells, proline porter II activity was supported by glucose and by D-lactate in a strain defective for proline porters I and III and the F1F0-ATPase. Glucose energized proline uptake was eliminated by carbonyl cyanide m-chlorophenylhydrazone and KCN as was serine uptake. These results suggested that proline porter II was respiration-dependent and probably ion-linked. Activation of proline porter II in whole cells by sucrose or NaCl was sustained over 30 min, whereas activation by glycerol was transient. Proline porter II was activated by NaCl and sucrose with a half-time of approximately 1 min in both whole cells and membrane vesicles. Thus, activation of proline porter II was reversible. It occurred at a rate comparable to that of K+ influx and much more rapid than the genetic regulatory responses that follow a hyperosmotic shift.     

Isolation and characterization of hexose transport mutants in L6 rat myoblasts

A method for the selection and isolation of hexose transport mutants in undifferentiated rat myoblast L6 cells is reported; 2-deoxy-D-glucose (2-DOG)-and 2-deoxy-2-fluoro-D-glucose (2FG)-resistant mutants were selected after mutagenization of L6 cells with ethyl methanesulfonate. Of these, D18 and D23 (selected with 0.1 mM 2-DOG) and F72 and F76 (selected with 0.1 mM 2FG) exhibited the lowest hexose transport activity. Uptake of 0.06 mM 2-DOG, 2FG, or 3-O-methyl-D-glucose (3-OMG) by mutants grown in fructose medium supplemented with 0.05 mM 2FG was about four- to five-fold lower than the parental L6 cells. These mutants contain normal levels of ATP and glycolytic enzyme activities. They also exhibit normal transport activities for alpha-aminoisobutyric acid and fructose. Furthermore, hexose transport was observed to be decreased in plasma membrane vesicles prepared from these mutants. Kinetic analysis of 2-DOG and 3-OMG transport in mutant F72 demonstrated that the Vmax for 2-DOG uptake was significantly reduced, whereas the Vmax for 3-OMG transport was not affected. In all cases, the affinity for these hexose analogues was unaffected. In addition mutant F72 was found to be only slightly affected by treatment with various energy inhibitors and sulfhydryl reagents. The results suggest that this mutant is defective in, or has low levels of, a plasma membrane component(s) involved in the high-affinity hexose transport system.     

Preconditioning enhanced glucose uptake is mediated by p38 MAP kinase not by phosphatidylinositol 3-kinase

Ischemia is reported to stimulate glucose uptake, but the signaling pathways involved are poorly understood. Modulation of glucose transport could be important for the cardioprotective effects of brief intermittent periods of ischemia and reperfusion, termed ischemic preconditioning. Previous work indicates that preconditioning reduces production of acid and lactate during subsequent sustained ischemia, consistent with decreased glucose utilization. However, there are also data that preconditioning enhances glucose uptake. The present study examines whether preconditioning alters glucose transport and whether this is mediated by either phosphatidylinositol 3-kinase (PI3K) or p38 MAP kinase. Langendorff-perfused rat hearts were preconditioned with 4 cycles of 5 min of ischemia and 5 min of reperfusion, with glucose as substrate. During the last reflow, glucose was replaced with 5 mM acetate and 5 mM 2-deoxyglucose (2DG), and hexose transport was measured from the rate of production of 2-deoxyglucose 6-phosphate (2DG6P), using (31)P nuclear magnetic resonance. Preconditioning stimulated 2DG uptake; after 15 min of perfusion with 2DG, 2DG6P levels were 165% of initial ATP in preconditioned hearts compared with 96% in control hearts (p < 0.05). Wortmannin, an inhibitor of PI3K, did not block the preconditioning induced stimulation of 2DG6P production, but perfusion with SB202190, an inhibitor of p38 MAP kinase, did attenuate 2DG6P accumulation (111% of initial ATP, p < 0. 05 compared with preconditioned hearts). SB202190 had no effect on 2DG6P accumulation in nonpreconditioned hearts. Preconditioning stimulation of translocation of GLUT4 to the plasma membrane was not inhibited by wortmannin. The data demonstrate that ischemic preconditioning increases hexose transport and that this is mediated by p38 MAP kinase and is PI3K-independent.     

Hexose transport in undifferentiated and differentiated BALB/c 3T3 preadipose cells: Effects of 12–0-tetradecanoylphorbol-13-acetate and insulin

The effect of the phorbol diester 12-0-tetradecanoylphorbol-13-acetate (TPA) on hexose transport in undifferentiated and differentiated BALB/c 3T3 preadipose cells was studied. Additon of TPA to undifferentiated or fully differentiated cultures resulted in an increased rate of both 2-deoxyglucose uptake and 3-0-methylglucose transport; the time course and maximal stimulation differed for each type of culture and for each hexose. In confluent, undifferentiated cells, half-maximal stimulation of 2-deoxyglucose uptake occurred at 3 nM TPA, while the half-maximal stimulation of 3–0-methylglucose occurred at 30 nM. Epidermal growth factor and fetal bovine serum increased 2-deoxyglucose uptake in undifferentiated cells, while insulin did not. Insulin did, however, stimulate 3–0-methylglucose transport in differentiated cells. From dose-response curves in differentiated cells, halfmaximally effective concentrations were 0.17 nM for insulin and 30 nM for TPA. At optimal concentrations and incubation times for each, TPA was significantly more effective than insulin in stimulating hexose transport in differentiated cells. It was also shown that insulin could further increase hexose transport in maximally stimulated TPA-treated cells. Cycloheximide inhibited by 75% the increase in hexose transport by TPA in differentiated cells, while having no effect on the response of these cells to insulin. In differentiated cells, chronic exposure to insulin abolished the ability of these cells to respond acutely to insulin addition but they could still respond to TPA. On the other hand, differentiated cells exposed continuously to TPA for 5 days retained the ability to activate 3–0-methylglucose transport after either TPA or insulin addition. These results demonstrate that TPA can stimulate hexose transport directly in both undifferentiated and differentiated 3T3 cells and suggest that TPA and insulin affect transport by different mechanisms.     

Na+ -dependent proline transport in isolated membrane vesicles from the L6 muscle cell line. Stimulation of uptake by intravesicular proline

Membrane vesicles of L6 myoblasts were prepared in order to study the amino acid transport system A. The role of the membrane in the adaptive response of transport to amino acid-supplementation was assessed. The membranes, prepared by N2 cavitation, displayed Na+ (but not K+)-dependent L-proline uptake. An overshoot of L-[3H]proline uptake was observed after exposure of the vesicles to an inward Na+ gradient. Isolated membrane vesicles loaded with 50 microM proline displayed countertransport (stimulation of proline uptake). It is concluded that the adaptive decrease of proline uptake observed in amino acid-supplemented cells cannot be accounted for by trans-inhibition of transport.