Regulation of beta-galactoside transport and accumulation in heterofermentative lactic acid bacteria.

Galactose-grown cells of the heterofermentative lactic acid bacteria Lactobacillus brevis and Lactobacillus buchneri transported methyl-beta-D-thiogalactopyranoside (TMG) by an active transport mechanism and accumulated intracellular free TMG when provided with an exogenous source of energy, such as arginine. The intracellular concentration of TMG resultant under these conditions was approximately 20-fold higher than that in the medium. In contrast, the provision of energy by metabolism of glucose, gluconate, or glucosamine promoted a rapid but transient uptake of TMG followed by efflux that established a low cellular concentration of the galactoside, i.e., only two- to fourfold higher than that in the medium. Furthermore, the addition of glucose to cells preloaded with TMG in the presence of arginine elicited a rapid efflux of the intracellular galactoside. The extent of cellular TMG displacement and the duration of the transient effect of glucose on TMG transport were related to the initial concentration of glucose in the medium. Exhaustion of glucose from the medium restored uptake and accumulation of TMG, providing arginine was available for ATP generation. The nonmetabolizable sugar 2-deoxyglucose elicited efflux of TMG from preloaded cells of L. buchneri but not from those of L. brevis. Phosphorylation of this glucose analog was catalyzed by cell extracts of L. buchneri but not by those of L. brevis. Iodoacetate, at a concentration that inhibits growth and ATP production from glucose, did not prevent efflux of cellular TMG elicited by glucose. The results suggested that a phosphorylated metabolite(s) at or above the level of glyceraldehyde-3-phosphate was required to evoke displacement of intracellular TMG from the cells. Counterflow experiments suggested that glucose converted the active uptake of TMG in L. brevis to a facilitated diffusion mechanism that allowed equilibrium of TMG between the extra- and intracellular milieux. The means by which glucose metabolites elicited this vectorial regulation is not known, but similarities to the inducer expulsion that has been described for homofermentative Streptococcus and Lactobacillus species suggested the involvement of HPr, a protein that functions as a phosphocarrier protein in the phosphotransferase system, as well as a presumptive regulator of sugar transport. Indeed, complementation assays wit extracts of Staphylococcus aureus ptsH mutant revealed the presence of HPr in L. brevis, although this lactobacillus lacked a functional phaosphoenolpyruvate-dependent phosphortransferase system for glucose, 2-deoxyglucose, or TMG.     

Effects of colicins E1 and K on transport systems

The effect of colicins E1 and K on active transport of beta-d-galactosides and of alpha-methyl-d-glucoside (alphaMG) by Escherichia coli was studied. These colicins strongly inhibited the accumulation of thio-methyl-galactoside (TMG) by bacteria and caused rapid exit of previously accumulated TMG. The inhibition effect was limited to the accumulation phase of galactoside transport; the rate of hydrolysis of o-nitrophenyl galactoside, which is dependent on transport of the substrate by the lactose-permease system, was only slightly affected. The accumulation of alphaMG was highly resistant to inhibition by these colicins under conditions which caused complete suppression of TMG accumulation. These effects of the colicins on transport resemble qualitatively those of sodium azide. The findings were interpreted by assuming that colicins E1 and K inhibit the energy-dependent steps in the accumulation of TMG but do not affect facilitated diffusion of galactosides mediated by the specific transport mechanism. The continued accumulation of alphaMG was attributed to the fact that this compound is stored by E. coli cells as a phosphorylated compound by a phosphoenolpyruvate-dependent transport system rather than by an adenosine triphosphate-linked accumulation mechanism.     

Transport of glucose, gluconate, and methyl alpha-D-glucoside by Pseudomonas aeruginosa

Glucose transport by Pseudomonas aeruginosa was studied. These studies were enhanced by the use of a mutant, strain PAO 57, which was unable to grow on glucose but which formed the inducible glucose transport system when grown in media containing glucose or other inducers such as 2-deoxy-d-glucose. Both PAO 57 and parental strain PAO transported glucose with an apparent K(m) of 7 muM. Free glucose was concentrated intracellularly by P. aeruginosa PAO 57 over 200-fold above the external level. These data constitute direct evidence that glucose is transported via active transport by P. aeruginosa. Various experimental data clearly indicated that P. aeruginosa PAO transported methyl alpha-d-glucose (alpha-MeGlc) via the glucose transport system. The apparent K(m) of alpha-MeGlc transport was 7 mM which indicated a 1,000-fold lower affinity of the glucose transport system for alpha-MeGlc than for glucose. While only unchanged alpha-MeGlc was detected intracellularly in P. aeruginosa, alpha-MeGlc was actually concentrated intracellularly less than 2-fold over the external level. Membrane vesicles of P. aeruginosa PAO retained transport activity for gluconate. This solute was concentrated intravesicularly several-fold over the external level. A component of the glucose transport system is believed to have been lost during vesicle preparation since glucose per se was not transported. Instead; glucose was converted to gluconate by membrane-associated glucose dehydrogenase and gluconate was then transported into the vesicles. Although this may constitute an alternate system for glucose transport, it is not a necessary prerequisite for glucose transport by intact cells since P. aeruginosa PAO 57, which lacks glucose dehydrogenase, was able to transport glucose at a rate equal to the parental strain.     

The lactose/H+ carrier of Escherichia coli: lac YUN mutation decreases the rate of active transport and mimics an energy-uncoupled phenotype.

The Escherichia coli K12 strain X71-54 carries the lac YUN allele, coding for a lactose/H+ carrier defective in the accumulation of a number of galactosides [Wilson, Kusch & Kashket (1970) Biochem. Biophys. Res. Commun. 40, 1409-1414]. Previous studies proposed that the lower accumulation in the mutant be due to a faulty coupling of H+ and galactoside fluxes via the carrier. Immunochemical characterization of the carriers in membranes from mutant and parent strains with an antibody directed against the C-terminal decapeptide of the wild-type carrier leads to the conclusion that the mutant carrier is similar to the wild-type in terms of apparent Mr, C-terminal sequence, and level of incorporation into the membrane. The pH-dependence of galactoside transport was compared in the mutant and the parent. At pH 8.0-9.0, mutant and parent behave similarly with respect to the accumulation of beta-D-galactosyl 1-thio-beta-D-galactoside and to the ability to grow on the carrier substrate melibiose. At pH 6.0, both the maximal velocity for active transport and the level of accumulation of beta-D-galactosyl-1-thio-beta-D-galactoside are lower in the mutant. The mutant also is unable to grow on melibiose at pH 5.5. However, at pH 6.0 and low galactoside concentrations, the symport stoichiometry is 0.90 H+ per galactoside in the mutant as compared with 1.07 in the parent. These observations suggest that symport is normal in the mutant and that the lower rate of transport in the mutant is responsible for the phenotype. At higher galactoside concentrations, accumulation is determined not only thermodynamically but also kinetically, contrary to a simple interpretation of the chemiosmotic theory. Therefore lower rates of active transport can mimic the effect of uncoupling H+ and galactoside symport. Examination of countertransport in poisoned cells at pH 6.0 reveals that the rate constants for the reorientation of the loaded and unloaded carrier are altered in the mutant. The reorientation of the unloaded carrier is slower in the mutant. However, the reorientation of the galactoside-H+-carrier complex is slower for substrates like melibiose, but faster for substrates like lactose. These findings suggest that lactose-like and melibiose-like substrates interact with the carrier in slightly different ways.     

Electrogenic symport of glucose and protons in membrane vesicles of Phanerochaete chrysosporium

The white rot fungus, Phanerochaete chrysosporium, is one of the few organisms with documented ability to degrade lignin. Protoplasts from P. chrysosporium were disrupted by osmotic shock and membrane vesicles were isolated from the cell debris. The vesicles exhibit active glucose transport that is consistent with a glucose/H+ symport mechanism. An artificial gradient of H+ (outside greater than inside) stimulates glucose uptake. Conversely, a glucose gradient (outside greater than inside) results in the accumulation of H+ by the vesicles. Glucose uptake is not stimulated by either a Na+ or a K+ gradient. Furthermore, glucose transport is electrogenic, since glucose uptake may be driven by a membrane potential (negative interior) created by K+ diffusion mediated by valinomycin.     

Abolition of crypticity of Arthrobacter pyridinolis toward glucose and alpha-glucosides by tricarboxylic acid cycle intermediates

Arthrobacter pyridinolis cannot grow on glucose as sole carbon source, although the cells possess catabolic enzymes of the Embden-Meyerhof and pentose phosphate pathways as well as a complete tricarboxylic acid cycle. Crypticity toward glucose is abolished by a period of growth in a medium containing malate, succinate, citrate, or fumarate in addition to glucose. Other carbon sources, which support as rapid growth as does malate (e.g. asparagine), do not enable the cells to use glucose. Malate, succinate, citrate, and fumarate abolish crypticity toward glucose only in the second phase of diauxic growth after the tricarboxylic acid cycle intermediate has been depleted. This sequence of events, first observed in growth curves, has been verified by experiments in which the incorporation of radioactive substrates into trichloroacetic acid-insoluble cellular material was followed. The tricarboxylic acid cycle intermediates which confer the ability to utilize glucose also enhance the utilization of the alphaglucosides sucrose and maltose. The mechanism whereby growth on certain tricarboxylic acid cycle intermediates confers the subsequent ability to grow on glucose is related to a transport system for glucose and alpha-glucosides. This transport system has been assayed by measuring the uptake of [1-(14)C]-2-deoxyglucose. Cells grown for varying periods of time in asparagine, asparagine plus glucose, or malate do not transport 2-deoxyglucose. Cells from malate-glucose cultures that are in the exponential phase of growth on glucose can transport 2-deoxyglucose. Transport of 2-deoxyglucose shows Michaelis-Menten kinetics with a K(m) of 2.9 x 10(-4) M. It is competitively inhibited by glucose, alpha-methylglucopyranoside, and maltose. The transport of 2-deoxyglucose is inhibited by cyanide, dinitrophenol, azide, and N-ethylmaleimide, but not by malonate or fluoride. No phosphoenolpyruvate: d-glucose phosphotransferase activity has been detected, and the 2-deoxyglucose transported into the cell is not phosphorylated.     

Properties of the entry and exit reactions of the beta-methyl galactoside transport system in Escherichia coli.

The Km, Vmax, and Ki of the entry reaction were determined for three substrates of the beta-methyl galactoside transport system: D-galactose, D-glycerol-beta-D-galactoside, and beta-methyl-D-galactoside. Although the data for D-galactose and D-glycerol-beta-D-galactoside followed simple Michaelis-Menten kinetics, the results for beta-methyl-D-galactoside deviated from Michaelis-Menten kinetics in that the Ki for beta-methyl-D-galactoside inhibition of both of the other two substrates was 10-fold greater than the Km for beta-methyl-D-galactoside entry. Furthermore, two partial mgl- strains retain 56% of the parental level of the beta-methyl-D-galactoside entry reaction, but only 12% of the parental level of transport of the other two substrates. The exit reaction of beta-methyl-D-galactoside was shown to be first order. It was stimulated sixfold when the cells were provided with an energy source. This stimulation required adenosine 5'-triphosphate or a related compound. The exit reaction was not altered by mutations in any of the three cistrons which inactivate the beta-methyl-D-galactoside entry reaction, was not increased by growth in the presence of inducers of the entry reaction, and was not repressed by growth on glucose. The striking differences between the entry and exit reactions suggest that they either use different carriers or that none of the three cistrons which are currently known to code for components of the beta-methyl galactoside transport system code for its membrane carrier.     

The kinetic mechanism of galactoside/H+ cotransport in Escherichia coli

To determine the kinetic mechanism of galactoside active transport by the lactose/H+ cotransporter of Escherichia coli, galactoside binding and transport are studied in the absence and presence of delta mu H+. For several reasons, the substrate beta-D-galactosyl-1-thi-beta-D-galactoside (GalSGal) is preferred over lactose. In the absence of delta mu H+, the cotransporter retains high affinity for GalSGal, and the affinity is the same on both sides of the membrane. At physiological pH, the cotransporter is protonated and the dissociation constant for H+ may be 50 pM. The cosubstrates bind in a random fashion. An isomerization of the cotransporter corresponding to reorientation of the binding sites is rate-determining. When delta mu H+ is imposed, two reorientations become faster, and one becomes slower. The affinity of the cotransporter for GalSGal on both sides of the membrane is unchanged. The inability of the cotransporter to bring the accumulation of galactoside into equilibrium with delta mu H+ at high galactoside concentrations can be explained without postulating uncoupled fluxes of galactoside or H+ across the membrane (leaks). The formation of the ternary carrier-H+-galactoside complex on the cytoplasmic side of the membrane with increasing internal levels of sugar and the rapidity of galactoside exchange inhibit net influx of galactoside and favor exchange. Net transport is slow at high galactoside levels. Thus, the cotransporter can self-regulate transport without uncoupling H+ and galactoside fluxes. Because the values of delta mu H+ during binding and transport studies were measured, these results can be subjected to a quantitative analysis.     

Low-affinity, high-capacity system of glucose transport in the ruminal bacterium Streptococcus bovis: evidence for a mechanism of facilitated diffusion

The glucose phosphotransferase system (PTS) of Streptococcus bovis could not account for the glucose consumption of exponential cultures, and the kinetics of glucose transport were biphasic. A PTS-deficient mutant lost the high-affinity, low-capacity system but retained its ability to take up glucose at high substrate concentrations. The low-affinity, high-capacity system did not require a proton motive force or ATP and could not be driven by an artificial membrane potential in the presence or absence of sodium. Since low-affinity transport was directly proportional to the external substrate concentration and exhibited counterflow kinetics, it appeared that a facilitated-diffusion mechanism was responsible for glucose transport at high substrate concentrations.     

Low-affinity, high-capacity system of glucose transport in the ruminal bacterium Streptococcus bovis: evidence for a mechanism of facilitated diffusion.

The glucose phosphotransferase system (PTS) of Streptococcus bovis could not account for the glucose consumption of exponential cultures, and the kinetics of glucose transport were biphasic. A PTS-deficient mutant lost the high-affinity, low-capacity system but retained its ability to take up glucose at high substrate concentrations. The low-affinity, high-capacity system did not require a proton motive force or ATP and could not be driven by an artificial membrane potential in the presence or absence of sodium. Since low-affinity transport was directly proportional to the external substrate concentration and exhibited counterflow kinetics, it appeared that a facilitated-diffusion mechanism was responsible for glucose transport at high substrate concentrations.     

Biochemical studies of melibiose metabolism in wild type and mel mutant strains of Salmonella typhimurium

I identified two enzyme activities, alpha-galactosidase and a galactoside permease, required for melibiose metabolism by Salmonella typhimurium. These activities are very low under normal growth conditions, but their production can be induced by melibiose and gratuitously by melibiitol. Melibiose induction is severely inhibited by glucose, but the glucose effect can be countered by 3', 5' cyclic adenosine monophosphate. I isolated two phenotypic classes of mutants not able to utilize melibiose as a carbon source. One class, Car(-), is deficient in the phosphotransferase system. The other, Mel, lacks either alpha-galactosidase, galactoside permease, or both functions.     

Thermal events associated with active membrane transport in Escherichia coli

Active transport of non-metabolizable compounds by $\text{Escherichia coli}$ resulted in thermogenesis. With substrates of the lactose permease (thiomethyl galactoside, lactose) and of the glucose transport system (α-methylglucoside) the rate of heat production was largest on initial addition, but then decreased. The kinetics of heat production varied with the transport system. For the lactose transport system, more than turnover of the permease was required since heat was not produced in azide treated cells, where facilitated diffusion is known to take place. The lactose permease thermal effects are suggested to reflect operation of the energy coupling system. The thermal effects are considered to represent a useful approach in studying transport energetics and mechanisms.     

Glucose uptake by the cellulolytic ruminal anaerobe Bacteroides succinogenes.

Glucose uptake by Bacteroides succinogenes S85 was measured under conditions that maintained anaerobiosis and osmotic stability. Uptake was inhibited by compounds which interfere with electron transport systems, maintenance of proton or metal ion gradients, or ATP synthesis. The most potent inhibitors were proton and metal ionophores. Oxygen strongly inhibited glucose uptake. Na+ and Li+, but not K+, stimulated glucose uptake. A variety of sugars, including alpha-methylglucoside, did not inhibit glucose uptake. Only cellobiose and 2-deoxy-D-glucose were inhibitory, but neither behaved as a competitive inhibitor. Metabolism of both sugars appeared to be responsible for the inhibition. Cells grown in cellobiose medium transported glucose at one-half the rate of glucose-grown cells. Spheroplasts transported glucose as well as whole cells, indicating glucose uptake is not dependent on a periplasmic glucose-binding protein. Differences in glucose uptake patterns were detected in cells harvested during the transition from the lag to the log phase of growth compared with cells obtained during the log phase. These differences were not due to different mechanisms for glucose uptake in the cell types. Based on the results of this study, B. succinogenes contains a highly specific, active transport system for glucose. Evidence of a phosphoenolpyruvate-glucose phosphotransferase system was not found.     

Intrinsic perturbing ability of alkanols in lipid bilayers

The proportionality constant between the equipotency concentrations of a series of solutes and the fraction of a solute in the membrane phase is directly related to the solute to lipid mol ratio. Experimental measurements of partition coefficient and of several alkanol-induced effects show that the solute/lipid mol ratlos for a series of alkanols are not constant at their equipotency concentrations. The deviations in the solute/lipid ratios are similar in the various systems, and these deviations seem to depend primarily upon the chain length and branching in alkanols. It is suggested that such intrinsic differences in the perturbing ability of alcohols arise from a specificity of interaction between alkanols and lipid bilayer. We have correlated partition coefficients (in n-octanol, in egg phosphatidylcholine liposomes, and in dipalmitoyl phosphatidylcholine liposomes) for thirteen alkanols to the equipotency concentrations for their ability to modify the order-disorder thermotropic transition in dipalmitoyl phosphatidylcholine, ability to stimulate the hydrolysis of phosphatidylcholine in a bilayer by bee venom phospholipase A₂, and for the activation of the galactoside transport system in Escherichia coli. Significant correlation is found between equipotency concentrations for perturbing the order-disorder transition, the activation of phospholipase A₂-catalyzed hydrolysis and the activation of galactoside transport system.     

The role of ATP in the control of H+-galactoside symport in the yeast Kluyveromyces marxianus.

Transport of methyl beta-D-thiogalactoside and p-nitrophenyl beta-D-galactoside is shown to proceed through the H+-lactose symporter of Kluyveromyces marxianus. Uptake of these compounds is strongly reduced under anaerobic conditions or aerobically in the presence of antimycin. It is shown that antimycin treatment affects p-nitrophenyl beta-D-galactoside uptake in a similar way as it affects the cellular amount of ATP, suggesting regulation of p-nitrophenyl beta-D-galactoside transport by ATP. Also, manipulation of cellular ATP by antimycin treatment followed by glucose incubation, or by aerobic incubation of cells with 2-deoxy-D-glucose, showed a similar dependence of galactoside uptake on the ATP level. Transport of the lipophilic cation tetraphenylphosphonium is affected by ATP variations in a similar way as galactoside influx. It is concluded that ATP regulates H+-galactoside symport by its influence on charge translocation. It is discussed that a membrane ATPase probably plays a central role in the control of the activity of H+-sugar symport.     

Effect of insulin to decrease glucose transport in dissociated cells from the R3230AC mammary adenocarcinoma of diabetic rats.

Dissociated cells of the R3230AC mammary tumor were found to take up glucose by diffusion and by a passive carrier system. Using labeled 3-O-methylglucose as the probe, the following properties of the passive carrier were identified: (1) specificity for glucose, (2) competition by galactose and mannose but not by mannitol and fructose, (3) inhibition by phloretin but not by phloridzin, (4) temperature sensitivity, and (5) a Km for transport of 3-4 mM. The effects of insulin in vitro on carrier-mediated glucose transport were investigated in tumor cells from diabetic rats. At 10-9 M insulin, a time-related decrease in v for transport was observed resulting in an increased calculated Km (2- to 3-fold increase after 60-90 min incubation with insulin); only slight effects on V were obtained. This unusual response in v to insulin was observed when glucose was present in the medium at 2 mM and 5 mM, but not at 20 mM glucose. The effect of insulin to decrease the v was dose-related, with the major effects seen between 10-10M and 10-8M. The apparent decrease in glucose entry in vitro may in part explain the ability of insulin to inhibit growth of this tumor in vivo.     

Lactose transport system of Streptococcus thermophilus. Functional reconstitution of the protein and characterization of the kinetic mechanism of transport.

The kinetic mechanism of the lactose transport system of Streptococcus thermophilus was studied in membrane vesicles fused with cytochrome c oxidase containing liposomes and in proteoliposomes in which cytochrome c oxidase was coreconstituted with the lactose transport protein. Selective manipulation of the components of the proton (and sodium) motive force indicated that both a membrane potential and a pH gradient could drive transport. The galactoside/proton stoichiometry was close to unity. Experiments which discriminate between the effects of internal pH and delta pH as driving force on galactoside/proton symport showed that the carrier is highly activated at alkaline internal pH values, which biases the transport system kinetically toward the pH component of the proton motive force. Galactoside efflux increased with increasing pH with a pKa of about 8, whereas galactoside exchange (and counterflow) exhibited a pH optimum around 7 with pKa values of 6 and 8, respectively. Imposition of delta pH (interior alkaline) retarded the rate of efflux at any pH value tested, whereas the rate of exchange was stimulated by an imposed delta pH at pH 5.8, not affected at pH 7.0, and inhibited at pH 8.0 and 9.0. The results have been evaluated in terms of random and ordered association/dissociation of galactoside and proton on the inner surface of the membrane. Imposition of delta psi (interior negative) decreased the rate of efflux but had no effect on the rate of exchange, indicating that the unloaded transport protein carries a net negative charge and that during exchange and counterflow the carrier recycles in the protonated form.     

Glucose effect and the galactose enzymes of Escherichia coli: correlation between glucose inhibition of induction and inducer transport

Adhya, Sankar (University of Wisconsin, Madison), and Harrison Echols. Glucose effect and the galactose enzymes of Escherichia coli: correlation between glucose inhibition of induction and inducer transport. J. Bacteriol. 92:601-608. 1966.-The inhibitory effect of glucose on the induction of the enzymes required for galactose utilization ("glucose effect") was studied in Escherichia coli. Experiments on the uptake into the cell of labeled inducers (d-galactose-C(14) and d-fucose-H(3)) pointed to inhibition at the level of inducer transport as the possible primary mechanism of the glucose effect in the case of the gal enzymes. This interpretation was supported by the finding that a mutant constitutive for the lac enzymes was resistant to glucose inhibition of galactose induction of the gal enzymes; the mutant had acquired a glucose-resistant alternative transport mechanism for galactose via the constitutively synthesized galactoside permease. Further support for the transport inhibition model was provided by the finding that glucose did not substantially inhibit induction of the gal enzymes when glucose and galactose were produced intracellularly by beta-galactosidase hydrolysis of lactose, even if excess glucose was added. The inducer uptake experiments also showed that d-galactose and d-fucose probably enter the cell via different transport systems, although uptake of both compounds was inhibited by glucose.     

Neuregulin signaling on glucose transport in muscle cells

Neuregulin-1, a growth factor that potentiates myogenesis induces glucose transport through translocation of glucose transporters, in an additive manner to insulin, in muscle cells. In this study, we examined the signaling pathway required for a recombinant active neuregulin-1 isoform (rhHeregulin-beta(1), 177-244, HRG) to stimulate glucose uptake in L6E9 myotubes. The stimulatory effect of HRG required binding to ErbB3 in L6E9 myotubes. PI3K activity is required for HRG action in both muscle cells and tissue. In L6E9 myotubes, HRG stimulated PKBalpha, PKBgamma, and PKCzeta activities. TPCK, an inhibitor of PDK1, abolished both HRG- and insulin-induced glucose transport. To assess whether PKB was necessary for the effects of HRG on glucose uptake, cells were infected with adenoviruses encoding dominant negative mutants of PKBalpha. Dominant negative PKB reduced PKB activity and insulin-stimulated glucose transport but not HRG-induced glucose transport. In contrast, transduction of L6E9 myotubes with adenoviruses encoding a dominant negative kinase-inactive PKCzeta abolished both HRG- and insulin-stimulated glucose uptake. In soleus muscle, HRG induced PKCzeta, but not PKB phosphorylation. HRG also stimulated the activity of p70S6K, p38MAPK, and p42/p44MAPK and inhibition of p42/p44MAPK partially repressed HRG action on glucose uptake. HRG did not affect AMPKalpha(1) or AMPKalpha(2) activities. In all, HRG stimulated glucose transport in muscle cells by activation of a pathway that requires PI3K, PDK1, and PKCzeta, but not PKB, and that shows cross-talk with the MAPK pathway. The PI3K, PDK1, and PKCzeta pathway can be considered as an alternative mechanism, independent of insulin, to induce glucose uptake.