Evidence that activation of 2-deoxy-D-glucose transport in rat thymocyte suspensions results from enhanced coupling between transport and hexokinase activity.

1. Suspensions of rat thymocytes accumulate free 2-deoxy-D-glucose (2-dGlc) within the cytosol to a concentration approx. 25-fold above the external concentration. This active accumulation was enhanced by 40 nM-phorbol 12-myristate 13-acetate (phorbol). 2. The Km for zero-trans uptake in control cells was 2.3 +/- 0.14 mM and Vmax. was 0.41 +/- 0.08 mumol/min per 10(10) cells (n = 6). In cells treated with phorbol (40 nM) the Km for zero-trans uptake was 1.2 +/- 0.13 mM and Vmax. 0.46 +/- 0.03 mumol/min per 10(10) cells (n = 6). The Km was decreased significantly by phorbol (P less than 0.01). 3. Phorbol-dependent activation of thymocytes delayed exit of free 2-dGlc into sugar-free solution and prevented exchange exit. Activation had no effect on 3-O-methyl D-glucoside (3-OMG) exit. 4. Coupling of 2-dGlc transport to hexokinase activity was determined by observing the effects of various concentrations of unlabelled cytosolic 2-dGlc on influx of labelled 2-dGlc into the hexose phosphate pool. In control cells this coupling was 0.81 +/- 0.02 and in phorbol-activated cells it was 0.92 +/- 0.01 (P less than 0.01). 5. The high-affinity inhibitor of hexokinase, mannoheptulose, inhibited uptake of 2-dGlc in both control and phorbol-treated cells. These data are consistent with a model for activation of sugar transport in which hexokinase activity is integrated with the sugar transporter at the endofacial surface. The results suggest that phorbol increases the degree of coupling transport with hexokinase activity, thereby leading to an increase in the rate of uptake of 2-dGlc, a decrease in exit of free 2-dGlc from the cytosol and an increase in free 2-dGlc accumulation.     

Characterization of 2-deoxyglucose and 6-deoxyglucose transport in Kluyveromyces marxianus: evidence for two different transport mechanisms

Transport of 2-deoxy-d-glucose (2-dGlc) and 6-deoxy-d-glucose (6-dGlc) is studied in Kluyveromyces marxianus, grown under different conditions. It is shown that early stationary phase cells contain only one glucose transporter, with low affinity for 6-dGlc and high affinity for 2-dGlc. This transporter is recognized by glucose and fructose. In late stationary phase cells, two transport systems are operative for 6-dGlc, one with a high and one with a low affinity. The high-affinity system appears to be a glucose-galactose carrier, catalyzing uphill transport, energized by coupling sugar transport to translocation of protons. Induction (or derepression) of the high-affinity 6-dGlc transport seems to be coupled, in an as yet unknown way, to citrate consumption and a strong alkalinization of the medium during growth. It is concluded that glucose transport in K. marxianus can proceed by at least two mechanisms: a glucose-fructose carrier, probably having phosphotransferase characteristics, and a derepressible glucose/galactose-proton symporter.     

The glucose transport system of the hyperthermophilic anaerobic bacterium Thermotoga neapolitana

The glucose transport system of the extremely thermophilic anaerobic bacterium Thermotoga neapolitana was studied with the nonmetabolizable glucose analog 2-deoxy-D-glucose (2-DOG). T. neapolitana accumulated 2-DOG against a concentration gradient in an intracellular free sugar pool that was exchangeable with external source of energy, such as pyruvate, and was inhibited by arsenate and gramicidin D. There was no phosphoenolpyruvate-dependent phosphorylation of glucose, 2-DOG, or fructose by cell extracts or toluene-treated cells, indicating the absence of a phosphoenolpyruvate:sugar phosphotransferase system. These data indicate that D-glucose is taken up by T. neapolitana via an active transport system that is energized by an ion gradient generated by ATP, derived from substrate-level phosphorylation.     

Determination of the role of polyphosphate in transport-coupled phosphorylation in the yeast Saccharomyces cerevisiae

The role of polyphosphate in 2-deoxy-D-glucose transport was studied in yeast cells, pulse-labeled with [³²P]orthophosphate, by comparing the concentrations and specific activities of polyphosphate, orthophosphate and 2-dGlc-phosphate. When 2-dGlc transport was measured under aerobic conditions, it appeared that polyphosphate replenished the orthophosphate pool, indicating that polyphosphate has, at least mainly, an indirect role in sugar phosphorylation. Also in cells with a reduced respiratory capacity, due to a treatment with antimycin A, no direct role for polyphosphate in 2-dGlc transport could be detected. Under these conditions, only a very limited breakdown of polyphosphate occurred, probably because of the small decrease in the orthophosphate concentration.Abbreviations 2-dGlc 2-deoxy-D-glucose - P_i orthophosphate - P_n polyphosphate - SP sugar phosphate     

Regulation of glycolysis and sugar phosphotransferase activities in Streptococcus lactis: growth in the presence of 2-deoxy-D-glucose.

Streptococcus lactis K1 has the capacity to grow on many sugars, including sucrose and lactose, in the presence of high levels (greater than 500 mM) of 2-deoxy-D-glucose. Initially, growth of the organism was transiently halted by the addition of comparatively low concentrations (less than 0.5 mM) of the glucose analog to the culture. Inhibition was coincident with (i) rapid accumulation of 2-deoxy-D-glucose 6-phosphate (ca. 120 mM) and preferential utilization of phosphoenolpyruvate via the mannose:phosphotransferase system, (ii) depletion of phosphorylated glycolytic intermediates, and (iii) a 60% reduction in intracellular ATP concentration. During the 5- to 10-min period of bacteriostasis the intracellular concentration of 2-deoxy-D-glucose 6-phosphate rapidly declined, and the concentrations of glycolytic intermediates were restored to near-normal levels. When growth resumed, the cell doubling time (Td) and the steady-state levels of 2-deoxy-D-glucose 6-phosphate maintained by the cells were dependent upon the medium concentration of 2-deoxy-D-glucose. Resistance of S. lactis K1 to the potentially toxic analog was a consequence of negative regulation of the mannose:phosphotransferase system by two independent mechanisms. The first, short-term response occurred immediately after the initial "overshoot" accumulation of 2-deoxy-D-glucose 6-phosphate, and this mechanism reduced the activity (fine control) of the mannose:phosphotransferase system. The second, long-term mechanism resulted in repression of synthesis (coarse control) of enzyme IImannose. The two regulatory mechanisms reduced the rate of 2-deoxy-D-glucose translocation via the mannose:phosphotransferase system and minimized the activity of the phosphoenolpyruvate-dependent futile cycle of the glucose analog (J. Thompson and B. M. Chassy, J. Bacteriol. 151:1454-1465, 1982). Phosphoenolpyruvate was thus conserved for transport of the growth sugar and for generation of ATP required for biosynthetic and work functions of the growing cell.     

How hexoses and inhibitors influence the malate transport system in Zygosaccharomyces bailii

When grown in fructose or glucose the cells of Zygosaccharomyces bailii were physiologically different. Only the glucose grown cells (glucose cells) possessed an additional transport system for glucose and malate. Experiments with transport mutants had lead to the assumption that malate and glucose were transported by one carrier, but further experiments proved the existence of two separate carrier systems. Glucose was taken up by carriers with high and low affinity. Malate was only transported by an uptake system and it was not liberated by starved malate-loaded cells, probably due to the low affinity of the intracellular anion to the carrier. The uptake of malate was inhibited by fructose, glucose, mannose, and 2-DOG but not by non metabolisable analogues of glucose. The interference of malate transport by glucose, mannose or 2-DOG was prevented by 2,4-dinitrophenol, probably by inhibiting the sugar phosphorylation by hexokinase. Preincubation of glucose-cells with metabolisable hexoses promoted the subsequent malate transport in a sugar free environment. Preincubation of glucose-cells with 2-DOG, but not with 2-DOG/2,4-DNP, decreased the subsequent malate transport. The existence of two separate transport systems for glucose and malate was demonstrated with specific inhibitors: malate transport was inhibited by sodium fluoride and glucose transport by uranylnitrate. A model has been discussed that might explain the interference of hexoses with malate uptake in Z. bailii.Abbreviations 2,4-DNP 2,4-dinitrophenol - 2-DOG 2-deoxyglucose - 6-DOG 6-deoxyglucose - pCMB para-hydroxymercuribenzoate     

Regulation of sugar transport systems of Kluyveromyces marxianus: the role of carbohydrates and their catabolism

In Kluyveromyces marxianus grown on a glucose-containing synthetic medium four different sugar transporters have been identified. In cells, harvested during the exponential phase, only the constitutive glucose/fructose carrier, probed with 6-deoxy-D-glucose or sorbose, appeared to be active. In cells from the stationary phase three proton symporters can be active, recognizing 6-deoxyglucose (a glucose/galactose carrier), sorbose (a fructose carrier) and galactosides (lactose carrier), respectively. These symporters appeared to be sensitive to catabolite inactivation. This process is induced by incubating cells in the presence of glucose, fructose or mannose. Catabolite inactivation was not influenced by the inhibitor of protein synthesis, anisomycin. Derepression of the proton/sorbose and the proton/galactoside symporters proceeded readily when cells were incubated in a medium without glucose. Activation of the proton/galactose symporter needed, in addition, the presence of specific molecules (inducers) in the medium. The activation of each of these active transport systems was inhibited by anisomycin, showing the involvement of protein synthesis.     

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.     

Fructose transport in Neurospora crassa.

A specific fructose uptake system (Km = 0.4 mM) appeared in Neurospora crassa when glucose-grown mycelia were starved. Fructose uptake had kinetics different from those of intramycelial fructose phosphorylation, and uptake appeared to be carrier mediated. The only sugar which competitively inhibited fructose uptake was L-sorbose (Ki = 9 mM). Glucose, 2-deoxyglucose, mannose, and 3-O-methyl glucose were noncompetitive inhibitors of fructose uptake. Incubation of glucose-grown mycelia with glucose, 2-deoxyglucose, or mannose prevented derepression of the fructose transport system, whereas incubation with 3-O-methyl glucose caused the appearance of five times as much fructose uptake activity as did starvation conditions.     

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.     

Role of the phosphoenolpyruvate-dependent fructose phosphotransferase system in the utilization of mannose by Escherichia coli.

Mutants of Escherichia coli devoid of the membrane-spanning proteins PtsG and PtsMP, which are components of the phosphoenolpyruvate-dependent phosphotransferase system (PTS) and which normally effect the transport into the cells of glucose and mannose, do not grow upon or take up either sugar. Pseudorevertants are described that take up, and grow upon, mannose at rates strongly dependent on the mannose concentration in the medium (apparent Km > 5 mM); such mutants do not grow upon glucose but are derepressed for the components of the fructose operon. Evidence is presented that mannose is now taken up via the fructose-PTS to form mannose 6-phosphate, which is further utilized for growth via fructose 6-phosphate and fructose 1,6-bisphosphate.     

Interaction of 2-deoxy-d-glucose and adenine with phosphate anion uptake in yeast

The transport of inorganic phosphate anions into yeast cells (after preincubation with glucose; fructose or another metabolizable sugar, and in the presence of glucose) shows two kinetic components with half-saturation constants of 40 μmol/L and 2.4 mmol/L. The uptake was strikingly stimulated by 2-deoxy-d-glucose (2-dGle) at lower concentrations but inhibited above, 100 mmol/L. A similar stimulation was caused by adenine (0.01–1 mmol/L) and a very small one by uracil and inorganic sulfate. It is suggested that either a phosphorylation reaction accompanies the transport (2-dGlc) or that some compounds stimulate the H⁺-ATPase more than inorganic phosphate itself and thus increase its rate of transport.     

Effect of glucose uptake on growth rate of mouse 3T3 cells

The objective of this investigation was to determine whether the rate of glucose uptake by mouse 3T3 cells was a primary determinant of growth rate. The experimental approach was to control the rate of glucose uptake into intracellular pools by supplying this sugar at varying concentration in minimal Eagle's medium with dialyzed serum in the absence and presence of 6-deoxy-D-glucose, a metabolically inert homomorphic analog of D-glucose that competitively inhibits the uptake of D-glucose. Total hexose (D-glucose and 6-deoxy-D-glucose) concentration was maintained at the physiological concentration of 5.5 mM, in order to maintain saturation and maximum activity of the D-glucose transport system; thus the flux of D-glucose into the cell was controlled by adjusting its concentration relative to its competing nonmetabolizable analog. It was found that even when the concentration of D-glucose was reduced to 0.7 mM, one eighth of the “normal” level of 5.5 mM. and 6-deoxy-D-glucose was present in sevenfold excess (4.8 mM), conditions under which glucose uptake was reduced to 20% of that shown by cells in the presence of 5.5 mM D-glucose, and intracellular pools of glucose and phosphorylated sugars derived from glucose were reduced to approximately 14% of normal, there was not a significant decrease in growth rate. These data support the view that the rate of glucose uptake is not a primary determinant of growth rate under the usual conditions of cell culture.     

Pathways of glycogen synthesis in Novikoff ascites-hepatoma cells

Affinity of glucose, fructose and mannose for tumour hexokinase and their rates of phosphorylation at saturation concentration have been correlated with rates of glycogen synthesis by intact tumour cells at different concentrations of the three substrates. Competition experiments with one sugar labelled and the other sugar unlabelled indicate inhibition of glycogen synthesis by the sugar with a low K(m) for hexokinase. Glycogen synthesis from glucose 1-phosphate in aged cells and from nucleoside in freshly prepared cells is stimulated by fructose and inhibited by glucose. The decrease in glycogen formation from glucose 1-phosphate by oligomycin is partially overcome by increased fructose concentrations. These results are explained by an activation of alpha-glucan phosphorylase by fructose and an inhibition of this enzyme by glucose. It is suggested that differences in localization of glucose 6-phosphate, available to the intact cell in various ways, determine its transformation into glycogen by either the UDP-glucose-alpha-glucan glucosyltransferase reaction or by the alpha-glucan phosphorylase reaction.     

Glucose 6-Phosphate and Fructose 1,6-Bisphosphate Can Be Used as ATP-Regenerating Systems by Cerebellum Ca2+-Transport ATPase

Abstract : In this work, it is shown that the Ca²⁺-transport ATPase found in the microsomal fraction of the cerebellum can use both glucose 6-phosphate/hexokinase and fructose 1,6-bisphosphate/phosphofructokinase as ATP-regenerating systems. The vesicles derived from the cerebellum were able to accumulate Ca²⁺ in a medium containing ADP when either glucose 6-phosphate and hexokinase or fructose 1,6-bisphosphate and phosphofructokinase were added to the medium. There was no Ca²⁺ uptake if one of these components was omitted from the medium. The transport of Ca²⁺ was associated with the cleavage of sugar phosphate. The maximal amount of Ca²⁺ accumulated by the vesicles with the fructose 1,6-bisphosphate system was larger than that measured either with glucose 6-phosphate or with a low ATP concentration and phosphoenolpyruvate/pyruvate kinase. The Ca²⁺ uptake supported by glucose 6-phosphate was inhibited by glucose, but not by fructose 6-phosphate. In contrast, the Ca²⁺ uptake supported by fructose 1,6-bisphosphate was inhibited by fructose 6-phosphate, but not by glucose. Thapsigargin, a specific SERCA inhibitor, impaired the transport of Ca²⁺ sustained by either glucose 6-phosphate or fructose 1,6-bisphosphate. It is proposed that the use of glucose 6-phosphate and fructose 1,6-bisphosphate as an ATP-regenerating system by the cerebellum Ca²⁺-ATPase may represent a salvage route used at early stages of ischemia ; this could be used to energize the Ca²⁺ transport, avoiding the deleterious effects derived from the cellular acidosis promoted by lactic acid.     

Effect of xylose incubation on the glucose transport system in Saccharomyces cerevisiae

Incubation of Saccharomyces cerevisiae with xylose and ethanol for 16 hours leads to a decrease of hexokinase (and glucokinase) activity in the cells. It does not alter the levels of polyphosphate, orthophosphate and ATP. The transport of the glucose derivative 2-deoxy-D-glucose, a sugar that can be phosphorylated, is inhibited after this treatment, whereas transport of 6-deoxy-D-glucose, which has a blocked phosphorylation site, is not inhibited. Even though, both deoxyglucoses use the same transport system. The decrease in initial velocity of 2-deoxy-D-glucose transport is most pronounced under anaerobic conditions. Incubation of the cells with antimycin A, a treatment which has a similar effect as anaerobiosis, shows, that the inhibition of the transport of 2-deoxy-D-glucose is presumably the result of an increase in the Km of the carrier transport. Transport of glucose is probably regulated by kinase enzymes.     

Specificity of Sugar Transport in Trypanosoma gambiense*

SYNOPSIS Some carbohydrates inhibited glucose and fructose transport in Trypanosoma gambiense. Glucose transport was inhibited by glycerol, mannose, 2-deoxy-D-glucose, glucosamine and N-acetylglucosamine. Fructose transport was inhibited by glucose, glycerol, mannose, glucosamine and N-acetylglucosamine. Glucosamine transport appeared to be a mediated process and had a K_m of 1.20 mM and a V_max of 28.5 μM glucosamine/g dry wt/2 min. Glucosamine absorption was competitively inhibited by glucose, fructose and N-acetylglycosamine. N-Acetylglucosamine appeared to enter by passive diffusion. Reciprocal inhibition experiments suggested that glucosamine entered entirely via the “fructose site.” Specificity of sugar transport in T. gambiense differs from that of other organisms.     

Regulation of the glucose:H+ symporter by metabolite-activated ATP-dependent phosphorylation of HPr in Lactobacillus brevis.

Lactobacillus brevis takes up glucose and the nonmetabolizable glucose analog 2-deoxyglucose (2DG), as well as lactose and the nonmetabolizable lactose analoge thiomethyl beta-galactoside (TMG), via proton symport. Our earlier studies showed that TMG, previously accumulated in L. brevis cells via the lactose:H+ symporter, rapidly effluxes from L. brevis cells or vesicles upon addition of glucose and that glucose inhibits further accumulation of TMG. This regulation was shown to be mediated by a metabolite-activated protein kinase that phosphorylase serine 46 in the HPr protein. We have now analyzed the regulation of 2DG uptake and efflux and compared it with that of TMG. Uptake of 2DG was dependent on an energy source, effectively provided by intravesicular ATP or by extravesicular arginine which provides ATP via an ATP-generating system involving the arginine deiminase pathway. 2DG uptake into these vesicles was not inhibited, and preaccumulated 2DG did not efflux from them upon electroporation of fructose 1,6-diphosphate or gluconate 6-phosphate into the vesicles. Intravesicular but not extravesicular wild-type or H15A mutant HPr of Bacillus subtilis promoted inhibition (53 and 46%, respectively) of the permease in the presence of these metabolites. Counterflow experiments indicated that inhibition of 2DG uptake is due to the partial uncoupling of proton symport from sugar transport. Intravesicular S46A mutant HPr could not promote regulation of glucose permease activity when electroporated into the vesicles with or without the phosphorylated metabolites, but the S46D mutant protein promoted regulation, even in the absence of a metabolite. The Vmax but not the Km values for both TMG and 2DG uptake were affected. Uptake of the natural, metabolizable substrates of the lactose, glucose, mannose, and ribose permeases was inhibited by wild-type HPr in the presence of fructose 1,6-diphosphate or by S46D mutant HPr. These results establish that HPr serine phosphorylation by the ATP-dependent, metabolite-activated HPr kinase regulates glucose and lactose permease activities in L. brevis and suggest that other permeases may also be subject to this mode of regulation.     

Kinetics of Sugar Transport and Phosphorylation Influence Glucose and Fructose Cometabolism by Zymomonas mobilis

The competitive inhibition of fructokinase by glucose has been proposed as the mechanism by which Zymomonas mobilis preferentially consumes glucose from mixtures of glucose and fructose and accumulates fructose when growing on sucrose. In this study, incorporation of radioactive fructose into biomass was used as a measure of fructose catabolism. It was determined that the rate of fructose incorporation by Z. mobilis CP4 was somewhat lower in the presence of an equimolar concentration of glucose but that the inhibition of fructokinase by glucose was not nearly as severe in vivo as was predicted from in vitro studies. Interestingly, addition of glucose to a culture of Z. mobilis CP4-M2, a glucokinaseless mutant, resulted in an immediate and nearly complete inhibition of fructose incorporation. Furthermore, addition of nonmetabolizeable glucose analogs had a similar effect on fructose catabolism by the wild-type Z. mobilis CP4, and fructose uptake by Z. mobilis CP4-M2 was shown to be severely inhibited by equimolar amounts of glucose. These results suggest that competition for fructose transport plays an important role in preferential catabolism of glucose from sugar mixtures. Indeed, the apparent K(infm) values for sugar uptake by Z. mobilis CP4 were approximately 200 mM for fructose and 13 mM for glucose. Other experiments supported the conclusion that a single facilitated diffusion transport system, encoded by the glf gene, is solely responsible for the uptake of both glucose and fructose. The results are discussed with regard to the hypothesis that the kinetics of sugar transport and phosphorylation allow the preferential consumption of glucose and accumulation of fructose, making the fructose available for the enzyme glucose-fructose oxidoreductase, which forms sorbitol, an important osmoprotectant for Z. mobilis when growing in the presence of high sugar concentrations.     

Specificity of the Glucose Transport System in Leishmania tropica Promastigotes*

SYNOPSIS. The glucose transport system in Leishmania tropica promastigotes was characterized by the use of labeled 2-deoxy-D-glucose (2-DOG), a nonmetabolizable glucose analog. The uptake system has a Q₁₀ of 2 and a heat of activation of 10.2 kcal/mole. The glucose transport system is subject to competitive inhibition by 2-DOG, glucosamine, N-acetyl glucosamine, mannose, galactose, and fructose which suggests that substitutions in the hexose chain at carbons 2 and 4 do not affect carrier specificity. In contrast, changes at carbon 1 (α-methyl-D-glucoside, 1,5-anhydroglucitol) and carbon 3 (3–0-methyl glucose) lead to loss of carrier affinity since these sugars do not compete for the glucose carrier. Sugars that compete with the glucose carrier have one common feature—they all exist in the pyranose form in solution. The carrier for D-glucose does not interact with L-glucose or any of the pentose sugars tested. Uptake of 2-DOG is inhibited by glycerol. This inhibition, however, is noncompetitive; it is evident, therefore, that glucose and glycerol do not compete for the same carrier. Glycerol does not repress the glucose carrier since cells grown in presence of glycerol transport the sugar normally.