High glucose concentrations inhibit glucose phosphorylation, but not glucose transport, in human endothelial cells.

Glucose uptake is autoregulated in a variety of cell types and it is thought that glucose transport is the major step that is subjected to control by sugar availability. Here, we examined the effect of high glucose concentrations on the rate of glucose uptake by human ECV-304 umbilical vein-derived endothelial cells. A rise in the glucose concentration in the medium led a dose-dependent decrease in the rate of 2-deoxyglucose uptake. The effect of high glucose was independent of protein synthesis and the time-course analysis indicated that it was relatively slow. The effect was not due to inhibition of glucose transport since neither the expression nor the subcellular distribution of the major glucose transporter GLUT1, nor the rate of 3-O-methylglucose uptake was affected. The total in vitro assayed hexokinase activity and the expression of hexokinase-I were similar in cells treated or not with high concentrations of glucose. In contrast, exposure of cells to a high glucose concentration caused a marked decrease in phosphorylated 2-deoxyglucose/free 2-deoxyglucose ratio. This suggests the existence of alterations in the rate of in vivo glucose phosphorylation in response to high glucose. In summary, we conclude that ECV304 human endothelial cells reduce glucose utilization in response to enhanced levels of glucose in the medium by inhibiting the rate of glucose phosphorylation, rather than by blocking glucose transport. This suggests a novel metabolic effect of high glucose on cellular glucose utilization.     

Contact-inhibited revertant cell lines isolated from SV40-transformed cells. V. Contact inhibition of sugar transport

The transport of 2-deoxyglucose in BALB/c 3T3 cells, Simian virus 40-transformed BALB/c 3T3 (SVT2) cells, and concanavalin A-selected revertant cells of SVT2 has been measured. Sparsely-seeded BALB/c 3T3 cells transport the sugar at about one-fourth, and sparsely-seeded revertant cells at three-fourths, the rate of SVT2 cells. BALB/c 3T3 cells undergo a dramatic drop in sugar uptake at confluency, transporting sugar at about one-tenth the rate of subconfluent cells. Revertant cells (contact-inhibited variants of transformed cells) are similar in this respect, but the drop is only 5-fold. SVT2 cells show no such change in uptake over wide cell densities. Subconfluent BALB/c 3T3, SVT2, and revertant cells have similar K_m and V_max values for 2-deoxyglucose transport; however, confluent 3T3 and confluent revertant cells show a large increase in K_m and a 5-fold decrease in V_max as compared to their subconfluent counterparts or SVT2 cells—indications of a decreased number of transport sites and a decreased affinity of these sites for sugar when these cells make intimate contacts with each other. These data indicate that extensive changes in the architecture of the cell surface occur when contactinhibited cells are in close apposition with each other, regardless of the persistence of partially expressed SV40 genetic information, and are discussed with regard to the membrane compositions of these cell lines.     

Increased membrane transport of 2-deoxyglucose and 3-O-methylglucose is an early event in the transformation of chick embryo fibroblasts by Rous sarcoma virus.

Transformation of chicken embryo fibroblasts with Rous sarcoma virus results in cells with an enhanced rate of hexose uptake. We have examined transport of the glucose analogs 2-deoxyglucose and 3-O-methylglucose in cells infected with a temperature sensitive variant of the virus. In cells shifted from restrictive to permissive conditions for transformation, increased transport of the non-phosphorylatable analog 3-O-methylglucose occurs at the same time as that of 2-deoxyglucose, a phosphorylatable analog. This enhanced rate of transport can be observed within three hours of the temperature shift. There is a corresponding decrease in the transport rate of both analogs following shift to the restrictive temperature. These results suggest that increased transport is likely to be the primary event in causing transformation-specific changes in sugar metabolism. We have also examined uptake into the internal pools of both the phosphorylated and non-phosphorylated forms of 2-deoxyglucose in normal cells and in cells transformed by the wild-type virus. These data indicate a corresponding increase in the rate of accumulation of the free sugar in transformed cells and point to transport as the rate limiting step in the accumulation of 2-deoxyglucose in both normal and transformed chicken embryo cells.     

Different proton-sugar stoichiometries for the uptake of glucose analogues by Chlorella vulgaris. Evidence for sugar-dependent proton uptake without concomitant sugar uptake by the proton-sugar symport system.

The uptake of hexoses by Chlorella vulgaris is accompanied by the uptake of protons. For 6-deoxyglucose a stoichiometry of one proton taken up per sugar molecule has been measured, whereas for 1-deoxyglucose approximately two protons are taken up per sugar molecule. It was found that in the presence of 1-deoxyglucose a considerable proportion of "carrier" catalyzes the transport of protons without the concomitant transport of sugar. Presumably, the binding of sugar initiates the translocation of the carrier-proton-sugar complex, but whereas 1-deoxyglucose can still dissociate from the complex at the external side of the cytoplasmic membrane, the translocation of the carrier-proton complex continues. This conclusion was reached since (a) the composition of the translocated carrier-proton-sugar complex is the same for both sugar. Its formation is a first order reaction with respect to protons. (b) When 6-deoxyglucose, present inside cells, is exchanged for external sugar, the exchange ratio is two to one when the external sugar is 1-deoxyglucose, two molecules of 6-deoxyglucose are lost for each molecule of 1-deoxyglucose entering. This result indicates that during uptake of 1-deoxyglucose statistically only each second carrier molecule appearing at the internal side of the cytoplasmic membrane is carrying sugar.     

Transport of sugars in chick-embryo fibroblasts. Evidence for a low-affinity system and a high-affinity system for glucose transport.

The rate of D-glucose uptake by cells that had been deprived of sugar for 18-24h was consistently observed to be 15-20 times higher than that in control cells maintained for the same length of time in medium containing glucose. This increased rate of glucose transport by sugar-starved cells was due to a 3-5-fold increase in the Vmax. value of a low-affinity system (Km 1 mM) combined with an increase in the Vmax of a separate high-affinity system (Km 0.05-0.2 mM). The high-affinity system, which was most characteristic of starved cells, was particularly sensitive to low concentrations of the thiol reagent N-ethylmaleimide; 50% inhibition of uptake occurred at approx. 0.01 mM-N-ethylmaleimide. In contrast with the high-affinity system, the low-affinity system of either the fed cells or the starved cells was unaffected by N-ethylmaleimide. In addition to the increases in the rate of D-glucose transport, cells deprived of sugar had increased rates of transport of 3-O-methyl-D-glucose and 2-deoxy-D-glucose. No measurable high-affinity transport system could be demonstrated for the transport of 3-O-methylgucose, and N-ethylmaleimide did not alter the initial rate. Thus the transport of 3-O-methyglucose by both fed and starved cells was exclusively by the N-ethylmaleimide-insensitive low-affinity system. The low-affinity system also appeared to be the primary means for the transport of 2-deoxyglucose by fed and starved cells. However, some of the transport of 2-deoxyglucose by starved cells was inhibited by N-ethylmaleimide, suggesting that 2-deoxyglucose may also be transported by a high-affinity system. The results of experiments that measured transport kinetics strongly suggest that glucose can be transported by a least two separate systems, and 3-O-methylglucose and 2-deoxyglucose by one. Support for these interpretations comes from the analysis of the effects of N-ethylmaleimide and cycloheximide as well as from the results of competition experiments. The uptake of glucose is quite different from that of 2-deoxyglucose and 3-O-methylglucose. The net result of sugar starvation serves to emphasize these differences. The apparent de-repression of the transport systems studied presents an interesting basis for further studies of the regulation of transport in a variety of cells.     

Induction of sugar transport in chick embryo fibroblasts by hexose starvation. Evidence for transcriptional regulation of transport.

Incubation of chick embryo fibroblasts in glucose-free medium resulted in a dramatic increase in the rate of 2-deoxy-D-glucose transport. The greatest increase in rate occurred during the first 20 hours of incubation in glucose-free medium and was blocked by actinomycin D, dordycepin, or cycloheximide. The conditions of 2-deoxy-D-glucose concentration and time of incubation with the sugar were determined where transport rather than phosphorylation was rate-limiting in sugar uptake. These studies demonstrated that the transport of 2-deoxy-D-glucose was rate-limiting for only 1 or 2 min when the concentration of sugar in the medium was near the Km for transport, i.e. 2mM. No difference was found in the level of hexokinase activity in homogenates prepared from cells incubated glucose-free medium or standard medium when either 2-deoxy-D-[14C]glucose or D-glucose was used as substrate. A kinetic analysis of the initial rates of 2-deoxy-D-glucose transport by Lineweaver-Burk plots showed that the Vmax for sugar transport increased from 18 to 95 nmol per mg of protein per min when fibroblasts were incubated in glucose-free medium for 40 hours. The Km remained constant at 2 mM. Analysis of the initial rates of 3-omicron-methyl-D-glucose transport by Lineweaver-Burk plots further substantiated that the increase in sugar transport was due to an increase in the Vmax for transport with the Km remaining constant. The activation energy for the transport reaction calculated from an Arrhenius plot was 17.4 Cal per mol for cells cultured in the standard medium and 17.2 Cal per mol for cells cultured in the glucose-free medium. These results are consistent with the interpretation that the Vmax increase observed in hexose-starved cells is due to an increase in the number of transport sites.     

Regulation of glucose metabolism in the lung: Hexokinase-catalyzed phosphorylation,a rate-limiting step

A measurement of uptake and phosphorylation of 2-deoxyglucose in rat lung slices under appropriately designed conditions showed that glucose metabolism in lung at the physiological concentration of the sugar will be limited by the rate of its phosphorylation and not by its transport into the cells.     

Different proton-sugar stoichiometries for the uptake of glucose analogues by Chlorella vulgaris: Evidence for sugar-dependent proton uptake without concomitant sugar uptake by the proton-sugar symport system

The uptake of hexoses by Chlorella vulgaris is accompanied by the uptake of protons. For 6-deoxyglucose a stoichiometry of one proton taken up per sugar molecule has been measured, whereas for 1-deoxyglucose approximately two protons are taken up per sugar molecule.It was found that in the presence of 1-deoxyglucose a considerable proportion of “carrier” catalyzes the transport of protons without the concomitant transport of sugar. Presumably the binding of sugar initiates the translocation of the carrier-proton-sugar complex, but whereas 1-deoxyglucose can still dissociate from the complex at the external side of the cytoplasmic membrane, the translocation of the carrier-proton complex continues.This conclusion was reached since (a) the composition of the translocated carrier-proton-sugar complex is the same for both sugar. Its formation is a first order reaction with respect to protons.(b) When 6-deoxyglucose, present inside cells, is exchanged for external sugar, the exchange ratio is two to one when the external sugar is 1-deoxyglucose, two molecules of 6-deoxyglucose are lost for each molecule of 1-deoxyglucose entering. This result indicates that during uptake of 1-deoxyglucose statistically only each second carrier molecule appearing at the internal side of the cytoplasmic membrane is carrying sugar.     

2-Deoxy-D-glucose uptake in cultured human muscle cells

Hexose uptake was studied with cultured human muscle cells using 2-deoxy-D-[1-3H]glucose. At a concentration of 0.25 and 4 mM, phosphorylation rather than transport was the rate-limiting step in the uptake of 2-deoxy-D-glucose. This was not due to inhibition of the hexokinase activity by either ATP depletion or 2-deoxyglucose 6-phosphate accumulation. In cellular homogenates, hexokinase showed a lower Km value for glucose as compared to 2-deoxyglucose. Intact cells preferentially phosphorylated glucose instead of 2-deoxyglucose. Therefore, transport instead of phosphorylation may be rate limiting in the uptake of glucose by cultured human muscle cells. These data suggest caution in using 2-deoxyglucose for measuring glucose transport.     

Protoplast hexose carrier activity is a determinate of genotypic difference in hexose storage in tomato fruit

Post-phloem sugar transport in developing tomato (Lycopersicon esculentum Mill. cv. Flora-Dade) fruit follows an apoplastic route during the rapid phase of sugar accumulation. The pathway is characterized by sugar retrieval by the storage parenchyma cells from the fruit apoplast. Two tomato genotypes differing in fruit hexose content were compared in terms of the transport and transfer processes controlling fruit sugar levels. The genotypic difference in fruit sugar content was independent of photoassimilate export from source leaves. Discs of pericarp tissue were cultured in a medium based on analyses of the fruit apoplastic sap. The cultured discs maintained a composition, a relative growth rate and a respiration rate similar to those of the pericarp tissue of intact fruit. Estimates of hexose fluxes into metabolic and storage pools suggested that membrane transport regulated the genotypic difference in hexose accumulation. Short-term [¹⁴C]hexose uptake experiments demonstrated a genotypic difference in V_max for glucose, fructose and 3-O-methyl-glucose, and this difference was abolished in the presence of the inhibitor p-chloromercuribenzenesulphonic acid (PCMBS). The results support the hypothesis that the activity of energized hexose carriers on the plasma membranes of storage parenchyma cells is a significant determinate of the genotypic difference in hexose accumulation.     

A model for accelerated uptake and accumulation of sugars arising from phosphorylation at the inner surface of the cell membrane

A model transport system for cellular accumulation of sugar coupled to phosphorylation is described. Sugar permeates the cell membrane via a passive facilitated transport system. On the inside surface of the membrane the bound sugar is either phosphorylated to form impermeable hexose phosphate, which is released into the intracellular solution, or released directly into the cytosol. Sugar may be regenerated from hexose phosphate in the cytosol via a phosphatase reaction. The reduction of the proportion of sites on the inner membrane surface occupied by permeable sugar, caused by the kinase reaction, increases both net and unidirectional passive inflow and reduces both net and unidirectional exit of sugar, thereby permitting large stationary state gradients of free sugar to be maintained between the cytosol and bathing solution. In cells where there is a high passive membrane permeability to free sugar, steady-state accumulation of free sugar within the cytosol, linked to metabolism is inexplicable in terms of conventional transport kinetics based on equilibrium thermodynamic assumptions. This phenomenon is analysed in terms of non-equilibrium stationary state flows of ligands via a probability network. The effects of metabolism on exchange transport are also examined. The model provides a framework to explain how sugar transport is loosely coupled to phosphorylation in mammalian epithelial cells, adipocytes, yeasts and bacteria, so that a high rate of substrate accumulation is maintained without requiring a reduction in the intracellular concentration of permeable substrate below that in the external solution.     

Transport-associated phosphorylation of 2-deoxyglucose in rat adipocytes

The relationship between ATP levels and 2-deoxyglucose uptake was investigated. When the concentration in the medium lies between 1 and 10 mM 2-deoxyglucose uptake causes a marked decrease in ATP level. This could partly be explained by an inhibiting effect of 2-deoxyglucose and 2-deoxyglucose 6-phosphate on ATP synthesis in the mitochondria. A good correlation between the various ATP levels induced by 2,4-dinitrophenol and the rate of uptake of 5 microM and 0.5 mM (but not 5 mM) 2-deoxyglucose was observed. The addition of glucose and 2-deoxyglucose to cells incubated in the presence of trace amounts of 2-deoxy-[1-14C]glucose induced marked changes in the uptake of the tracer that were associated with a rapid decline in ATP level. It appeared that the phosphorylation of 2-deoxyglucose is an important step in the uptake of the sugar. It is hypothesized that the processes of transport and phosphorylation of 2-deoxyglucose are coupled in rat adipocytes.     

Cell surface changes and Rous sarcoma virus gene expression in synchronized cells

We have investigated whether cell surface changes associated with growth control and malignant transformation are linked to the cell cycle. Chicken embryo cells synchronized by double thymidine block were examined for cell-cycle-dependent alterations in membrane function (measured by transport of 2-deoxyglucose, uridine, thymidine, and mannitol), in cell surface morphology (examined by scanning electron microscopy), and in the ability of tumor virus gene expression to induce a transformation-specific change in membrane function. We reach the following conclusions: (a) The high rate of 2-deoxyglucose transport seen in transformed cells and the low rates of 2-deoxyglucose and uridine transport characteristic of density-inhibited cells do not occur in normal growing cells as they traverse the cell cycle. (b) Although there are cell cycle-dependent changes in surface morphology, they are not reflected in corresponding changes in membrane function. (c) Tumor virus gene expression can alter cell membrane function at any stage in the cell cycle and without progression through the cell cycle.     

The pH-dependence of sugar-transport and glycolysis in cultured Ehrlich ascites-tumour cells.

1. pH-dependence of glycolysis has generally been ascribed to the effects of pH on the activities of glycolytic enzymes. The present study shows that sugar transport is pH-dependent in cultured Ehrlich ascites-tumour cells. 2. The rates of glucose consumption, of 3-O-methylglucose transport, and of 2-deoxyglucose transport and phosphorylation increased as linear functions of pH, as the pH of the cell culture medium was increased from 6.1 to 8.5. Transport of glucose, as measured in ATP-depleted cells, was pH-dependent to the same extent as transport of the non-metabolizable sugars. 3. Glucose consumption rates were about 8-fold higher at pH 8.5 than at pH 6.4. About 65-85% of glucose was converted into lactate. Sugar transport rates were 2.5-fold higher at pH 8.5 than at pH 6.3. 4. pH affected both simple diffusion and facilitated diffusion. pH effect was mainly on the Vmax. of 2-deoxyglucose uptake, and on the rapid-uptake phase of 3-O-methylglucose transport. 5. It was estimated that about 70% of the pH effect on the rates of glucose consumption may be due to the effect on sugar transport and the remainder to the effect on the activities of glycolytic enzymes.     

Phospholipase A activity determines the rate of respiration of the mitochondria in hibernating animals

The mechanisms for regulating the rate of respiration and oxidative phosphorylation in liver mitochondria from hibernating ground squirrels were studied. The microviscosity of the mitochondrial membrane in hibernating squirrels was found to be higher than that in active animals. Probably, a high microviscosity of the membrane causes a decreases in the rate of the transport of oxidation substrates into the mitochondrial matrix, which in turn may be one of the main reasons for the inhibition of mitochondrial respiration in hibernating squirrels. The activation of phospholipase A2 in a hypotonic medium results in the acceleration of the respiration and phosphorylation in the mitochondria from hibernating squirrels and is accompanied by the increase of the transport of substrates across the mitochondrial membrane. The inhibition of phospholipase A2 decreases Ca2+--induced acceleration of the transport of substrates and prevents the activation of the respiration and phosphorylation in a hypotonic medium.     

Transport-associated phosphorylation of 2-deoxy-d-glucose in Saccharomyces fragilis

2-Deoxy-d-glucose transport and metabolism was studied in Saccharomyces fragilis. Inside the cells four phosphorylated and three non-phosphorylated derivatives were found and identified. Accumulation of phosphorylated 2-deoxyglucose derivatives was balanced by a concomitant decrease of cellular ATP, orthophosphate and polyphosphates.The free sugar was concentrated against a concentration gradient, contradicting facilitated diffusion. Pulse labeling experiments revealed transport-associated phosphorylation.Theoretical considerations and analysis of the effects of iodoacetate showed that an intracellular hexokinase activity was not involved in 2-deoxyglucose phosphorylation, although this sugar is a good substrate for the enzyme in in vitro experiments.     

Sugar transport in chick embryo cardiac cells in culture. Analysis by countertransport,relationship to phosphorylation and effect of glucose starvation

Embryonic chick heart cells in culture transport 2-deoxy-D-glucose and 3-O-methyl-D-glucose very rapidly. By direct measurements of uptake, it was not possible to estimate accurately transport rates, nor, with 2-deoxyglucose, to discriminate clearly between its transport and phosphorylation. In contrast, the technique of countertransport made it possible to determine precisely initial transport velocity and to make the following observations: (1) phosphorylation, and not transport, is rate-limiting in 2-deoxyglucose uptake; (2) hexose transport is stimulated 5-fold by removal of glucose from culture medium; and (3) this stimulation is followed by an increase in phosphorylation, but the effect is much less pronounced (2-fold stimulation only). In conclusion, the adaptative regulation of glucose transport described in many fibroblast cell lines exists also in cardiac cells.     

Effect of acute and chronic vanadate administration on sugar transport in rat jejunum

Vanadate is known to have an insulin-like action which stimulates sugar transport in some systems like adipocytes and muscle cells, but in other systems it inhibits sugar transport by decreasing the activity of (Na+ +K+)-ATPase. To evaluate whether these two opposing actions may influence sugar transport across the intestine, we studied the effects of acute and chronic vanadate administration on the uptake of glucose, galactose, and 3-O-methylglucose in isolated rat intestinal cells. The sugar uptake measurements were also coupled by determinations of rubidium-86 uptake as a measure of the activity of the Na-K pump. Both acute and chronic vanadate administration reduced rubidium uptake by the cells but the reduction did not uniformly influence the uptake of the three sugars in question which were stimulated by the acute exposure of the cells to vanadate. Glucose uptake was also stimulated by chronic vanadate administration, but the uptakes of galactose and 3-O-methylglucose were respectively unaffected or inhibited by chronic vanadate. The findings suggest that the effect of vanadate on sugar transport is dependent on the net difference between two actions of vanadate: (i) stimulation of a receptor site (possibly an insulin receptor site) in the intestinal cell membrane and (ii) inhibition of the Na-K pump. During acute vanadate exposure, the stimulation of the receptor site was very likely a dominant feature which overwhelms the inhibition of the pump. Chronic exposure to vanadate led, on the other hand, to only a limited degree of stimulation of the receptor site and the inhibition of the Na-K pump became evident in the uptake measurements of galactose and 3-O-methyl-glucose. Glucose uptake, however, was stimulated by chronic vanadate ingestion due, very likely, to an increase in the metabolism of this sugar which occurred only with prolonged exposure of the rat intestine to vanadate.     

Multiple effects of mercuric chloride on hexose transport in Xenopus oocytes.

HgCl(2) had both stimulatory and inhibitory effects on [(3)H]2-deoxyglucose (DG) uptake in Xenopus laevis oocytes. The Hg dose response was complex, with 0.1-10 microM Hg increasing total DG uptake, 30-50 microM Hg inhibiting, and concentrations >100 microM increasing uptake. Analyses of the effects of Hg on DG transport kinetics and cell membrane permeability indicated that low concentrations of Hg stimulated mediated uptake, intermediate concentrations inhibited mediated uptake, but high Hg concentrations increased non-mediated uptake. 10 microM Hg increased the apparent V(max) for DG uptake, but caused little or no change in apparent K(m). Phenylarsine oxide prevented the increase in DG uptake by 10 microM Hg, suggesting that the increase was due to transporter recruitment. Microinjecting low doses of HgCl(2) into the cell increased mediated DG uptake. Higher intracellular doses of Hg increased both mediated and non-mediated DG uptake. Both insulin and Hg cause cell swelling in isotonic media and, for insulin, this swelling has been linked to the mechanism of hormone action. Osmotically swelling Xenopus oocytes stimulated DG transport 2-5-fold and this increase was due to an increased apparent V(max). Exposing cells to 10 microM Hg or 140 nM insulin both increased cellular water content by 18% and increased hexose transport 2-4-fold. These data indicate that low concentrations of Hg and insulin affect hexose transport in a similar manner and that for both an increase cellular water content could be an early event in signaling the increase in hexose transport.     

Is glucose transport enhanced in virus-transformed mammalian cells? A dissenting view

Much of the literature on the uptake of glucose by untransformed and transformed animal cells is based on experiments carried out with 2-deoxy-D-glucose (2-DOG). Results obtained with this analog can be ambiguous, since 2-DOG can be phosphorylated by hexokinases of animal cells. An intracellular trapping mechanism is thus provided. Therefore, the total flux of 2-DOG into the cell is a resultant of both transport and hexokinase action, and the measurement of total 2-DOG incorporation is a valid measurement of transport only if 2-DOG is phosphorylated as rapidly as it enters the cell. Evidence is presented here that this is not necessarily the case, significant levels of free intracellular 2-DOG approaching external concentrations were found in untransformed and transformed mouse 3T3 cells even at early times during uptake. Differences in total intracellular 2-DOG between untransformed and transformed cells were accounted for entirely by 2-deoxyglucose phosphate. Thus, it appears the apparent increase of 2-DOG uptake accompanying transformation in these cell lines is not due to an effect on the transport process, but on enhanced phosphorylation, which is a reflection of an alteration in the regulation of glycolysis. The ambiguity introduced by phosphorylation can be oviated by the use of an analog that cannot be phosphorylated, such as 3-O-methyl-D-glucose. The rate of transport and efflux of this sugar was not found to be different in untransformed versus transformed 3T3 cells. Moreover, deficiencies of this analog as a substrate for the glucose transport system are pointed out.