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.     

Cellobiose uptake and metabolism by Ruminococcus flavefaciens

The cellulolytic ruminal bacterium Ruminococcus flavefaciens FD-1 utilizes cellobiose but not glucose as a substrate for growth. Cellobiose uptake by R. flavefaciens FD-1 was measured under anaerobic conditions (N2), using [G-3H]cellobiose. The rate of cellobiose uptake for early- or late-log-phase cellobiose-grown cells was 9 nmol/min per mg of whole-cell protein. Cellobiose uptake was inhibited by electron transport inhibitors, iron-reactive compounds, proton ionophores, sulfhydryl inhibitors, N,N-dicyclohexylcarbodiimide, and NaF, as well as lasalocid and monensin. The results support the existence of an active transport system for cellobiose. Transport of [U-14C]glucose was not detected with this system. Phosphorylation of cellobiose was not by a phosphoenolpyruvate-dependent system. Cellobiose phosphorylase activity was detected by both a coupled spectrophotometric assay and a discontinuous assay. The enzyme was produced constitutively in cellobiose-grown cells at a specific activity of 329 nmol/min per mg of cell-free extract protein.     

Cellobiose uptake and metabolism by Ruminococcus flavefaciens.

The cellulolytic ruminal bacterium Ruminococcus flavefaciens FD-1 utilizes cellobiose but not glucose as a substrate for growth. Cellobiose uptake by R. flavefaciens FD-1 was measured under anaerobic conditions (N2), using [G-3H]cellobiose. The rate of cellobiose uptake for early- or late-log-phase cellobiose-grown cells was 9 nmol/min per mg of whole-cell protein. Cellobiose uptake was inhibited by electron transport inhibitors, iron-reactive compounds, proton ionophores, sulfhydryl inhibitors, N,N-dicyclohexylcarbodiimide, and NaF, as well as lasalocid and monensin. The results support the existence of an active transport system for cellobiose. Transport of [U-14C]glucose was not detected with this system. Phosphorylation of cellobiose was not by a phosphoenolpyruvate-dependent system. Cellobiose phosphorylase activity was detected by both a coupled spectrophotometric assay and a discontinuous assay. The enzyme was produced constitutively in cellobiose-grown cells at a specific activity of 329 nmol/min per mg of cell-free extract protein.     

An Hg-sensitive channel mediates the diffusional component of glucose transport in olive cells

In several organisms solute transport is mediated by the simultaneous operation of saturable and non-saturable (diffusion-like) uptake, but often the nature of the diffusive component remains elusive. The present work investigates the nature of the diffusive glucose transport in Olea europaea cell cultures. In this system, glucose uptake is mediated by a glucose-repressible, H(+) -dependent active saturable transport system that is superimposed on a diffusional component. The latter represents the major mode of uptake when high external glucose concentrations are provided. In glucose-sufficient cells, initial velocities of D- and L-[U-(14)C]glucose uptake were equal and obeyed linear concentration dependence up to 100 mM sugar. In sugar starved cells, where glucose transport is mediated by the saturable system, countertransport of the sugar pairs 3-O-methyl-D-glucose/D-[U-(14)C]glucose and 3-O-methyl-D-glucose/3-O-methyl-D-[U-(14)C]glucose was demonstrated. This countertransport was completely absent in glucose-sufficient cells, indicating that linear glucose uptake is not mediated by a typical sugar permease. The endocytic inhibitors wortmannin-A and NH(4)Cl inhibited neither the linear component of D- and L-glucose uptake nor the absorption of the nonmetabolizable glucose analog 3-O-methyl-D-[U-(14)C]glucose, thus excluding the involvement of endocytic mediated glucose uptake. Furthermore, the formation of endocytic vesicles assessed with the marker FM1-43 proceeded at a very slow rate. Activation energies for glucose transport in glucose sufficient cells and plasma membrane vesicles were 7 and 4 kcal mol(-1), respectively, lower than the value estimated for diffusion of glucose through the lipid bilayer of phosphatidylethanolamine liposomes (12 kcal mol(-1)). Mercury chloride inhibited both the linear component of sugar uptake in sugar sufficient cells and plasma membrane vesicles, and the incorporation of the fluorescent glucose analog 2-NBDG, suggesting protein-mediated transport. Diffusive uptake of glucose was inhibited by a drop in cytosolic pH and stimulated by the protein kinase inhibitor staurosporine. The data demonstrate that the low-affinity, high-capacity, diffusional component of glucose uptake occurs through a channel-like structure whose transport capacity may be regulated by intracellular protonation and phosphorylation/dephosphorylation.     

Differential metabolism of cellobiose and glucose by Clostridium thermocellum and Clostridium thermohydrosulfuricum.

Clostridium thermohydrosulfuricum consumed glucose in preference to cellobiose as an energy source for growth. The rates of substrate uptake in glucose- and cellobiose-grown cell suspensions were 45 and 24 nmol/min per mg (dry weight), respectively, at 65 degrees C. The molar growth yields (i.e., grams of cells per mole of glucose equivalents) were similar on cellobiose and glucose (19 and 16, respectively). Both glucose- and cellobiose-grown cells contained a glucose permease activity and high levels of hexokinase (greater 0.34 mumol/min per mg of protein at 40 degrees C). Growth on cellobiose was associated with induction of a cellobiose permease activity. In contrast, Clostridium thermocellum metabolized cellobiose in preference to glucose as an energy source and displayed lower growth rates on both substrates. The substrate uptake rates in cellobiose- and glucose-grown cell suspensions were 18 and 17 nmol/min per mg (dry weight), respectively. The molar yields were 38 on cellobiose and 20 on glucose. Extracts of glucose- and cellobiose-grown cells both contained cellobiose phosphorylase and phosphoglucomutase activities, whereas only glucose-grown cells contained detectable levels of glucose permease and hexokinase activities. The general catalytic and kinetic properties of the glucose- and cellobiose-catabolizing enzymes in the two species are described, and a model is proposed to distinguish differential saccharide metabolism by these thermophilic ethanologens.     

Cellobiose metabolism and cellobiohydrolase I biosynthesis by Trichoderma reesei

The relationship between β-linked disaccharide (cellobiose, sophorose) utilization and cellulase, particularly cellobiohydrolase I (CBH I) synthesis by Trichoderma reesei, was investigated. During growth on cellobiose and sophorose as carbon sources in batch as well as resting-cell culture, only sophorose induced cellulase formation. In the latter experiments, sophorose was utilized at a much lower rate than cellobiose, and the more cellulase produced, the lower its rate of utilization. Cellobiose and sophorose were utilized by the fungus mainly via hydrolysis by the cell wall- and cell membrane-bound β-glucosidase. Addition of sophorose to T. reesei growing on cellulose did not further stimulate cellulase synthesis, and addition of cellobiose was inhibitory. Cellobiose, however, promoted cellulase formation in both batch and resting cell cultures, when its hydrolysis by β-glucosidase was inhibited by nojirimycin. No cellulase formation was observed when the uptake of glucose (produced from cellobiose by β-glucosidase) was inhibited by 3-O-methylglucoside. Cellodextrins (C₂ to C₆) promoted formation of low levels of cellobiohydrolase I in indirect proportion to their rate of hydrolysis by β-glucosidase. Studies on the uptake of [³H]cellobiose, [³H]sophorose, and [¹⁴C]glucose in the presence of inhibitors of β-glucosidase (nojirimycin) and glucose transport (3-O-methylglucoside) show that glucose transport occurs at a much higher rate than disaccharide hydrolysis. Extracellular disaccharide hydrolysis accounts for at least 95% of their metabolism. The presence of an uptake system for cellobiose was established by demonstrating the presence of intracellular labeled [³H]cellobiose in T. reesei after its extracellular supply. The data are consistent with induction of cellulase and particularly CBH I formation in T. reesei by β-linked disaccharides under conditions where their uptake is favored at the expense of extracellular hydrolysis.     

Cellodextrin efflux by the cellulolytic ruminal bacterium Fibrobacter succinogenes and its potential role in the growth of nonadherent bacteria.

When glucose or cellobiose was provided as an energy source for Fibrobacter succinogenes, there was a transient accumulation (as much as 0.4 mM hexose equivalent) of cellobiose or cellotriose, respectively, in the growth medium. Nongrowing cell suspensions converted cellobiose to cellotriose and longer-chain cellodextrins, and in this case the total cellodextrin concentration was as much as 20 mM (hexose equivalent). Because cell extracts of glucose- or cellobiose-grown cells cleaved cellobioise and cellotriose by phosphate-dependent reactions and glucose 1-phosphate was an end product, it appeared that cellodextrins were being produced by a reversible phosphorylase reaction. This conclusion was supported by the observation that the ratio of cellodextrins to cellodextrins with one greater hexose [n/(n + 1)] was approximately 4, a value similar to the equilibrium constant (Keq) of cellobiose phosphorylase (J. K. Alexander, J. Bacteriol. 81:903-910, 1961). When F. succinogenes was grown in a cellobiose-limited chemostat, cellobiose and cellotriose could both be detected, and the ratio of cellotriose to cellobiose was approximately 1 to 4. On the basis of these results, cellodextrin production is an equilibrium (mass action) function and not just an artifact of energy-rich cultural conditions. Cellodextrins could not be detected in low-dilution-rate, cellulose-limited continuous cultures, but these cultures had a large number of nonadherent cells. Because the nonadherent cells had a large reserve of polysaccharide and were observed at all stages of cell division, it appeared that they were utilizing cellodextrins as an energy source for growth.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of MI transport in retinal pigment epithelium by sugars, amiloride, and pH gradients: potential impairment of pump-leak balance in diabetic maculopathy

Impairment of transport and metabolism of retinal pigment epithelium (RPE) has been recognized to play a role in the development of diabetic macular edema. To understand the mechanism(s) of action of high glucose levels in alteration of RPE metabolism, primary cultures of RPE cells were used as an in vitro model of diabetic retinopathy/maculopathy. RPE cells were grown with 5 mM (control) or 40 mM glucose (a monosaccharide that enters the cells), or 40 mM sucrose (a disaccharide that does not enter the cells), and the extent of Na(+)-dependent active transport of an osmolyte ([3H]-myo-inositol, MI, 10 microM) into cells was determined. While 40 mM glucose down-regulated 3H-MI transport, 40 mM sucrose stimulated it, compared to 5 mM glucose feeding. Addition of 1 mM amiloride, an inhibitor of Na+/H+ exchanger, in the incubation media, significantly inhibited MI transport. Cells treated with high sucrose or high glucose were more sensitive toward amiloride inhibition, compared to controls. Inhibition of either pump or leak pathway alone was not sufficient to completely inhibit MI transport, but simultaneous inhibition of both pathways, by amiloride and ouabain (1 mM each), strongly inhibited osmolyte accumulation. The strongest inhibition of uptake occurred when 150 mM NaCl in the incubation media was replaced by 150 mM choline-Cl, and the percent inhibition of uptake, with choline-Cl, was highest with sucrose-fed cells, compared to normal or high glucose-fed cells. Imposition of a pH gradient [pHi (6.1) less than pH0 (8.0)] across the cell membrane, a condition that stimulates Na+/H+ exchange activity, also reduced MI accumulation. Cellular water content, measured by the extent of [3H]-3-O-methyl glucose uptake, in the presence of balanced salt solution (BSS), BSS containing half the ionic strength (hypotonic solution), or BSS containing 20 mM K+, for induction of cell swelling, varied when cells were fed with various sugars. Cells fed with high glucose were less sensitive toward media tonicity compared to normal. These results suggested that in cultured RPE cells, changes in Na+/H+ exchanger activity (intracellularly or extracellularly), through its inhibition by amiloride, its activation via intracellular acidification, or perhaps by chronic feeding with high sucrose or high glucose, affected the Na(+)-dependent active accumulation of MI. A metabolic factor involved in the development of diabetic macular edema is perhaps associated with glucose-induced alterations in Na+ fluxes (e.g., changes in Na+/H+ exchanger activity), which can secondarily influence osmolyte accumulation, impairment of pump-leak balance, and/or intracellular pH.(ABSTRACT TRUNCATED AT 400 WORDS)     

Transport and hydrolysis of disaccharides by Trichosporon cutaneum.

Trichosporon cutaneum is shown to utilize six disaccharides, cellobiose, maltose, lactose, sucrose, melibiose, and trehalose. T. cutaneum can thus be counted with the rather restricted group of yeasts (11 to 12% of all investigated) which can utilize lactose and melibiose. The half-saturation constants for uptake were 10 +/- 3 mM sucrose or lactose and 5 +/- 1 mM maltose, which is of the same order of magnitude as those reported for Saccharomyces cerevisiae. Our results indicate that maltose shares a common transport system with sucrose and that there may be some interaction between the uptake systems for lactose, cellobiose, and glucose. Lactose, cellobiose, and melibiose are hydrolyzed by cell wall-bound glycosidase(s), suggesting hydrolysis before or in connection with uptake. In contrast, maltose, sucrose, and trehalose seem to be taken up as such. The uptake of sucrose and lactose is dependent on a proton gradient across the cell membrane. In contrast, there were no indications of the involvement of gradients of H+, K+, or Na+ in the uptake of maltose. The uptake of lactose is to a large extent inducible, as is the corresponding glycosidase. Also the glycosidases for cellobiose, trehalose, and melibiose are inducible. In contrast, the uptake of sucrose and maltose and the corresponding glycosidases is constitutive.     

Regulation of sulfate metabolism in Neurospora crassa: Transport and accumulation of glucose 6-sulfate

Neurospora crassa can utilize glucose 6-sulfate as its sole sulfur source, although this compound cannot serve as a carbon source for this organism. Neurospora possesses a transport system capable of glucose 6-sulfate uptake; the system is energy dependent, is inhibited by extracellular sulfate, and is clearly distinct from the permeases responsible for the uptake of glucose and those for sulfate transport. The metabolism of glucose 6-sulfate apparently involves its transport as an intact molecule, followed by a slow intracellular hydrolysis. Methionine, which represses the synthesis of a number of enzymes of sulfur anabolism, also represses the synthesis of the transport system responsible for glucose 6-sulfate uptake. A regulatory gene, cys-3, which controls the synthesis of aryl sulfatase, choline sulfatase, choline-O-sulfate permease, and two distinct permease species, also regulates the permease for glucose 6-sulfate.     

Cellobiose transport by mixed ruminal bacteria from a Cow.

The transport of cellobiose in mixed ruminal bacteria harvested from a holstein cow fed an Italian ryegrass hay was determined in the presence of nojirimycin-1-sulfate, which almost inhibited cellobiase activity. The kinetic parameters of cellobiose uptake were 14 microM for the Km and 10 nmol/min/mg of protein for the Vmax. Extracellular and cell-associated cellobiases were detected in the rumen, with both showing higher Vmax values and lower affinities than those determined for cellobiose transport. The proportion of cellobiose that was directly transported before it was extracellularly degraded into glucose increased as the cellobiose concentration decreased, reaching more than 20% at the actually observed levels of cellobiose in the rumen, which were less than 0.02 mM. The inhibitor experiment showed that cellobiose was incorporated into the cells mainly by the phosphoenolpyruvate phosphotransferase system and partially by an ATP-dependent and proton-motive-force-independent active transport system. This finding was also supported by determinations of phosphoenolpyruvate phosphotransferase-dependent NADH oxidation with cellobiose and the effects of artificial potentials on cellobiose transport. Cellobiose uptake was sensitive to a decrease in pH (especially below 6.0), and it was weakly but significantly inhibited in the presence of glucose.     

Simultaneous uptake of galactose and glucose by Azotobacter vinelandii.

Azotobacter vinelandii growing on galactosides induced two distinct permeases for glucose and galactose. The apparent Vmax and Km of the galactose permease were 16 nmol galactose/min per 10(10) cells and 0.5 mM, respectively. The apparent Vmax and Km of the glucose permease were 7.8 nmol glucose/min per 10(10) cells and 0.04 mM, respectively. Excess glucose had no effect on the galactose uptake. However, excess galactose inhibited glucose transport. The galactosides-induced glucose permease also exhibited different uptake kinetics from that induced by glucose.     

Transport of glucose and cellobiose by Candida wickerhamii and Clavispora lusitaniae

The cellular location of beta-1,4-glucosidase activity from, as well as the transport of glucose and cellobiose into, cells of Clavispora lusitaniae NRRL Y-5394 and Candida wickerhamii NRRL Y-2563 was investigated. The beta-glucosidase from Cl. lusitaniae appeared to be a soluble cytoplasmic enzyme. This yeast transported both glucose and cellobiose when grown in medium containing cellobiose as the sole carbon source. Glucose, but not cellobiose, uptake was observed for cells grown on glucose. The Ks and Vmax values for cellobiose transport were different when Cl. lusitaniae was cultured either aerobically (0.11 mM, 6.28 nmol.min-1.mg-1) or anaerobically (0.25 mM, 3.88 nmol-1.min-1.mg-1). The Ks and Vmax values for glucose transport (0.23-1.10 mM and 17.2-33.9 nmol.min-1.mg-1) also differed with the various growth conditions. The beta-glucosidase from C. wickerhamii was extracytoplasmically located. This yeast transported glucose, but not cellobiose, under all growth conditions tested. The Ks for glucose uptake was 0.13-0.28 mM when C. wickerhamii was cultured on cellobiose and 0.25-0.30 mM when cultured on glucose. The Vmax values for glucose uptake were greater for cells cultured on cellobiose (35.0-37.9 nmol.min-1.mg-1) than for cells cultured on glucose (15.6-21.4 nmol.min-1.mg-1). Cellobiose did not inhibit glucose uptake in either yeast. Glucose partially inhibited cellobiose transport in C. lusitaniae, but only if the yeast was grown aerobically. In both yeasts, sugar transport was sensitive to carbonyl cyanide p-trifluoromethoxyphenylhydrazone and 1799, but insensitive to valinomycin.     

Cellobiose Transport by Mixed Ruminal Bacteria from a Cow

The transport of cellobiose in mixed ruminal bacteria harvested from a holstein cow fed an Italian ryegrass hay was determined in the presence of nojirimycin-1-sulfate, which almost inhibited cellobiase activity. The kinetic parameters of cellobiose uptake were 14 μM for the K_m and 10 nmol/min/mg of protein for the V_max. Extracellular and cell-associated cellobiases were detected in the rumen, with both showing higher V_max values and lower affinities than those determined for cellobiose transport. The proportion of cellobiose that was directly transported before it was extracellularly degraded into glucose increased as the cellobiose concentration decreased, reaching more than 20% at the actually observed levels of cellobiose in the rumen, which were less than 0.02 mM. The inhibitor experiment showed that cellobiose was incorporated into the cells mainly by the phosphoenolpyruvate phosphotransferase system and partially by an ATP-dependent and proton-motive-force-independent active transport system. This finding was also supported by determinations of phosphoenolpyruvate phosphotransferase-dependent NADH oxidation with cellobiose and the effects of artificial potentials on cellobiose transport. Cellobiose uptake was sensitive to a decrease in pH (especially below 6.0), and it was weakly but significantly inhibited in the presence of glucose.     

Coregulation of beta-galactoside uptake and hydrolysis by the hyperthermophilic bacterium Thermotoga neapolitana

Regulation of the beta-galactoside transport system in response to growth substrates in the extremely thermophilic anaerobic bacterium Thermotoga neapolitana was studied with the nonmetabolizable analog methyl-beta-D-thiogalactopyranoside (TMG) as the transport substrate. T. neapolitana cells grown on galactose or lactose accumulated TMG against a concentration gradient in an intracellular free sugar pool that was exchangeable with external galactose or lactose and showed induced levels of beta-galactosidase. Cells grown on glucose, maltose, or galactose plus glucose showed no capacity to accumulate TMG, though these cells carried out active transport of the nonmetabolizable glucose analog 2-deoxy-D-glucose. Glucose neither inhibited TMG uptake nor caused efflux of preaccumulated TMG; rather, glucose promoted TMG uptake by supplying metabolic energy. These data show that beta-D-galactosides are taken up by T. neapolitana via an active transport system that can be induced by galactose or lactose and repressed by glucose but which is not inhibited by glucose. Thus, the phenomenon of catabolite repression is present in T. neapolitana with respect to systems catalyzing both the transport and hydrolysis of beta-D-galactosides, but inducer exclusion and inducer expulsion, mechanisms that regulate permease activity, are not present. Regulation is manifest at the level of synthesis of the beta-galactoside transport system but not in the activity of the system.     

Effects of Monovalent Ions on the Transport of Noradrenaline Across the Plasma Membrane of Neuronal Cells (PC-12 Cells)

The dependence on Na+, K+, and Cl- of uptake and accumulation of [3H]noradrenaline was studied in plasma membrane vesicles isolated from PC-12 pheochromocytoma cells. Plasma membrane vesicles accumulated [3H]noradrenaline when an inward-directed gradient for Na+ and an outward-directed gradient for K+ were imposed across the vesicle membrane. Under these conditions, initial rates of uptake of [3H]noradrenaline were saturable (Km = 0.14 microM) and inhibited by a series of substrates and inhibitors of "uptake". The IC50 values were positively correlated with those for inhibition of uptake into intact PC-12 cells. Uptake and accumulation of [3H]noradrenaline in plasma membrane vesicles were absolutely dependent on external Na+ and Cl-; they were dependent on an inwardly directed gradient for Na+ but less dependent on an inwardly directed gradient for Cl-. Internal K+ strongly enhanced uptake and accumulation of [3H]noradrenaline. Rb+, but not Li+, had the capacity to replace internal K+. Two explanations are proposed for this effect of internal K+: (a) creation of a K+ diffusion potential (inside negative) provides a driving force for inward transport, and/or (b) K+ increases the turnover rate by formation of a highly mobile potassium-carrier complex. A hypothetical scheme for the transport of noradrenaline is presented.     

The role of zinc ions in reverse transport mediated by monoamine transporters

The human dopamine transporter (hDAT) contains an endogenous high affinity Zn2+ binding site with three coordinating residues on its extracellular face (His193, His375, and Glu396). Upon binding to this site, Zn2+ causes inhibition of [3H]1-methyl-4-phenylpyridinium ([3H]MPP+) uptake. We investigated the effect of Zn2+ on outward transport by superfusing hDAT-expressing HEK-293 cells preloaded with [3H]MPP+. Although Zn2+ inhibited uptake, Zn2+ facilitated [3H]MPP+ release induced by amphetamine, MPP+, or K+-induced depolarization specifically at hDAT but not at the human serotonin and the norepinephrine transporter (hNET). Mutation of the Zn2+ coordinating residue His(193) to Lys (the corresponding residue in hNET) eliminated the effect of Zn2+ on efflux. Conversely, the reciprocal mutation (K189H) conferred Zn2+ sensitivity to hNET. The intracellular [3H]MPP+ concentration was varied to generate saturation isotherms; these showed that Zn2+ increased V(max) for efflux (rather than K(M-Efflux-intracellular)). Thus, blockage of inward transport by Zn2+ is not due to a simple inhibition of the transporter turnover rate. The observations provide evidence against the model of facilitated exchange-diffusion and support the concept that inward and outward transport represent discrete operational modes of the transporter. In addition, they indicate a physiological role of Zn2+, because Zn2+ also facilitated transport reversal of DAT in rat striatal slices.     

An Hg-sensitive channel mediates the diffusional component of glucose transport in olive cells

In several organisms solute transport is mediated by the simultaneous operation of saturable and non-saturable (diffusion-like) uptake, but often the nature of the diffusive component remains elusive. The present work investigates the nature of the diffusive glucose transport in Olea europaea cell cultures. In this system, glucose uptake is mediated by a glucose-repressible, H⁺-dependent active saturable transport system that is superimposed on a diffusional component. The latter represents the major mode of uptake when high external glucose concentrations are provided. In glucose-sufficient cells, initial velocities of d- and l-[U-¹⁴C]glucose uptake were equal and obeyed linear concentration dependence up to 100 mM sugar. In sugar starved cells, where glucose transport is mediated by the saturable system, countertransport of the sugar pairs 3-O-methyl-d-glucose/d-[U-¹⁴C]glucose and 3-O-methyl-d-glucose/3-O-methyl-d-[U-¹⁴C]glucose was demonstrated. This countertransport was completely absent in glucose-sufficient cells, indicating that linear glucose uptake is not mediated by a typical sugar permease. The endocytic inhibitors wortmannin-A and NH₄Cl inhibited neither the linear component of d- and l-glucose uptake nor the absorption of the nonmetabolizable glucose analog 3-O-methyl-d-[U-¹⁴C]glucose, thus excluding the involvement of endocytic mediated glucose uptake. Furthermore, the formation of endocytic vesicles assessed with the marker FM1-43 proceeded at a very slow rate. Activation energies for glucose transport in glucose sufficient cells and plasma membrane vesicles were 7 and 4 kcal mol^− 1, respectively, lower than the value estimated for diffusion of glucose through the lipid bilayer of phosphatidylethanolamine liposomes (12 kcal mol^− 1). Mercury chloride inhibited both the linear component of sugar uptake in sugar sufficient cells and plasma membrane vesicles, and the incorporation of the fluorescent glucose analog 2-NBDG, suggesting protein-mediated transport. Diffusive uptake of glucose was inhibited by a drop in cytosolic pH and stimulated by the protein kinase inhibitor staurosporine. The data demonstrate that the low-affinity, high-capacity, diffusional component of glucose uptake occurs through a channel-like structure whose transport capacity may be regulated by intracellular protonation and phosphorylation/dephosphorylation.     

Glucose uptake by Cellulomonas fimi

Glucose uptake by whole-cell suspension of the facultative anaerobe Cellulomonas fimi, which was two-fold higher under aerobic conditions than under N₂ or H₂, was inhibited by inhibitors of electron transport and ATP synthesis and, particularly, by proton and metal ion ionophores. A variety of sugars, including 2-deoxyglucose, did not inhibit glucose uptake but cellobiose was a non-competitive inhibitor. Cells grown on cellobiose medium transported glucose at one half the rate of glucose-grown cells. Cellulomonas fimi has a highly specific active system for glucose transport.     

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.