Stop-flow analysis of cooperative interactions between GLUT1 sugar import and export sites.

The human erythrocyte sugar transporter is thought to function either as a simple carrier (sugar import and sugar export sites are presented sequentially) or as a fixed-site carrier (sugar import and sugar export sites are presented simultaneously). The present study examines each hypothesis by analysis of the rapid kinetics of reversible cytochalasin B binding to the sugar export site in the presence and absence of sugars that bind to the sugar import site. Cytochalasin B binding to the purified, human erythrocyte glucose transport protein (GLUT1) induces quenching of GLUT1 intrinsic tryptophan fluorescence. The time-course of GLUT1 fluorescence quenching reflects a second-order process characterized by simple exponential kinetics. The pseudo-first-order rate constant describing fluorescence decay (kobs) increases linearly with [cytochalasin B] while the extent of fluorescence quenching increases in a saturable manner with [cytochalasin B]. Rate constants for cytochalasin B binding to GLUT1 (k1) and dissociation from the GLUT1.cytochalasin B complex (k-1) are obtained from the relationship: kobs = k-1 + k1[cytochalasin B]. Low concentrations of maltose, D-glucose, 3-O-methylglucose, and other GLUT1 import-site reactive sugars increase k-1(app) and reduce k1(app) for cytochalasin B interaction with GLUT1. Higher sugar concentrations decrease k1(app) further. The simple carrier mechanism predicts that k1(app) alone is modulated by import- and export-site reactive sugars and is thus incompatible with these findings. These results are consistent with a fixed-site carrier mechanism in which GLUT1 simultaneously presents cooperative sugar import and export sites.     

Inhibitions of sugar transport produced by ligands binding at opposite sides of the membrane. Evidence for simultaneous occupation of the carrier by maltose and cytochalasin B

This study examines inhibitions of human erythrocyte D-glucose uptake at ice temperature produced by maltose and cytochalasin B. Maltose inhibits sugar uptake by binding at or close to the sugar influx site. Maltose is thus a competitive inhibitor of sugar uptake. Cytochalasin B inhibits sugar transport by binding at or close to the sugar efflux site and thus acts as a noncompetitive inhibitor of sugar uptake. When maltose is present in the uptake medium, Ki(app) for cytochalasin B inhibition of sugar uptake increases in a hyperbolic manner with increasing maltose. When cytochalasin B is present in the uptake medium, Ki(app) for maltose inhibition of sugar uptake increases in a hyperbolic manner with increasing cytochalasin B. High concentrations of cytochalasin B do not reverse the competitive inhibition of D-glucose uptake by maltose. These data demonstrate that maltose and cytochalasin B binding sites coexist within the glucose transporter. These results are inconsistent with the simple, alternating conformer carrier model in which maltose and cytochalasin B binding sites correspond to sugar influx and sugar efflux sites, respectively. The data are also incompatible with a modified alternating conformer carrier model in which the cytochalasin B binding site overlaps with but does not correspond to the sugar efflux site. We show that a glucose transport mechanism in which sugar influx and sugar efflux sites exist simultaneously is consistent with these observations.     

The red blood cell glucose transporter presents multiple, nucleotide-sensitive sugar exit sites.

At any instant, the human erythrocyte sugar transporter presents at least one sugar export site but multiple sugar import sites. The present study asks whether the transporter also presents more than one sugar exit site. We approached this question by analysis of binding of [3H]cytochalasin B (an export conformer ligand) to the human erythrocyte sugar transporter and by analysis of cytochalasin B modulation of human red blood cell sugar uptake. Phloretin-inhibitable cytochalasin B binding to human red blood cells, to human red blood cell integral membrane proteins, and to purified human red blood cell glucose transport protein (GluT1) displays positive cooperativity at very low cytochalasin B levels. Cooperativity between sites and K(d(app)) for cytochalasin B binding are reduced in the presence of intracellular ATP. Red cell sugar uptake at subsaturating sugar levels is inhibited by high concentrations of cytochalasin B but is stimulated by lower (<20 nM) concentrations. Increasing concentrations of the e1 ligand forskolin also first stimulate then inhibit sugar uptake. Cytochalasin D (a cytochalasin B analogue that does not interact with GluT1) is without effect on sugar transport over the same concentration range. Cytochalasin B and ATP binding are synergistic. ATP (but not AMP) enhances [3H]cytochalasin B photoincorporation into GluT1 while cytochalasin B (but not cytochalasin D) enhances [gamma-32P]azidoATP photoincorporation into GluT1. We propose that the red blood cell glucose transporter is a cooperative tetramer of GluT1 proteins in which each protein presents a translocation pathway that alternates between uptake (e2) and export (e1) states but where, at any instant, two subunits must present uptake (e2) and two subunits must present exit (e1) states.     

ATP regulation of the human red cell sugar transporter

Purified human red blood cell sugar transport protein intrinsic tryptophan fluorescence is quenched by D-glucose and 4,6-ethylidene glucose (sugars that bind to the transport), phloretin and cytochalasin B (transport inhibitors), and ATP. Cytochalasin B-induced quenching is a simple saturable phenomenon with Kd app of 0.15 microM and maximum capacity of 0.85 cytochalasin B binding sites per transporter. Sugar-induced quenching consists of two saturable components characterized by low and high Kd app binding parameters. These binding sites appear to correspond to influx and efflux transport sites, respectively, and coexist within the transporter molecule. ATP-induced quenching is also a simple saturable process with Kd app of 50 microM. Indirect estimates suggest that the ratio of ATP-binding sites per transporter is 0.87:1. ATP reduces the low Kd app and increases the high Kd app for sugar-induced fluorescence quenching. This effect is half-maximal at 45 microM ATP. ATP produces a 4-fold reduction in Km and 2.4-fold reduction in Vmax for cytochalasin B-inhibitable D-glucose efflux from inside-out red cell membrane vesicles (IOVs). This effect on transport is half-maximal at 45 microM ATP. AMP, ADP, alpha, beta-methyleneadenosine 5'-triphosphate, and beta, gamma-methyleneadenosine 5'-triphosphate at 1 mM are without effect on efflux of D-glucose from IOVs. ATP modulation of Km for D-glucose efflux from IOVs is immediate in onset and recovery. ATP inhibition of Vmax for D-glucose exit is complete within 5-15 min and is only partly reversed following 30-min incubation in ATP-free medium. These findings suggest that the human red cell sugar transport protein contains a nucleotide-binding site(s) through which ATP modifies the catalytic properties of the transporter.     

Exofacial photoaffinity labelling of the human erythrocyte sugar transporter

The 4-azidosalicylate derivative of 1,3-bis(D-mannos-4'-yloxy)-2-[2-3H]propylamine (ASA-[2-3H]BMPA) has been tested as a photoaffinity label for the sugar transporter in human erythrocytes. When photolysed in the presence of intact erythrocytes, ASA-[2-3H]BMPA covalently binds to the exofacial surface of the transporter. This labelled protein appears as a broad band in the 4.5 region in sodium dodecyl sulphate (SDS)-polyacrylamide gel electrophoresis. The peak of radiolabel incorporation gives an apparent Mr of approx. 50 000 on 5-20% acrylamide gels. The binding is 80% inhibitable by 320 mM 4,6-O-ethylidene-D-glucose, by 320 mM D-glucose and by 50 microM cytochalasin B. Photoirradiation of a saturating concentration of ASA-BMPA in the presence of erythrocytes results in a 25-30% loss of D-galactose transport activity. From transport inactivation data and estimations of the amount of ASA-[2-3H]BMPA binding to the transporter it is calculated that there are approx. 220 000 exofacial hexose-transport binding sites per erythrocyte. The labelling of the transporter has been carried out using freshly drawn blood and 4-weeks-old transfusion blood. No change in the binding profile on SDS-polyacrylamide gel electrophoresis was observed. Proteolytic digestion of the ASA-[2-3H]BMPA-labelled transporter with either trypsin or alpha-chymotrypsin results in the appearance of a labelled 19 kDa fragment on SDS-polyacrylamide gel electrophoresis.     

Cytochalasin B does not serve as a marker of glucose transport in rabbit erythrocytes

Glucose inhibitable cytochalasin B binding to erythrocyte membranes has been used as a marker of the glucose transporter. Glucose transport and cytochalasin B binding in rabbit erythrocytes differ from those activities found in human erythrocytes. We evaluated the uptake of 3-0-methylglucose and found similar Km (4.81 +/- 1.20 mM (SEM) and 6.59 +/- 0.72 mM) though significantly different Vmax (5.2 +/- 0.7 nM . min-1/10(9) cells and 234 +/- 13 nM X min -1/10(9) cells, p less than 0.001) for rabbit and human erythrocytes, respectively. Equilibrium binding of cytochalasin B to human erythrocyte membranes demonstrates a high affinity cytochalasin B binding site (Kd 38.6 +/- 22.7 nM) which is displaced by glucose. No comparable glucose inhibitable cytochalasin B site exists for rabbit erythrocyte membranes. Photoaffinity labeling of cytochalasin B confirms the presence of a glucose inhibitable cytochalasin B binding site in human, but not rabbit erythrocyte membranes. Cytochalasin B binding is a useful method in the identification of the glucose transporter in human cells, but the technique may be less useful in other species.     

Cooperative nucleotide binding to the human erythrocyte sugar transporter

The human erythrocyte glucose transport protein (GluT1) is an adenine nucleotide binding protein. When complexed with cytosolic ATP, GluT1 exhibits increased affinity for the sugar export site ligand cytochalasin B, prolonged substrate occlusion, reduced net sugar import capacity, and diminished reactivity with carboxyl terminal peptide-directed antibodies. The present study examines the kinetics of nucleotide interaction with GluT1. When incorporated into resealed human red blood cell ghosts, (2,3)-trinitrophenyl-adenosine-triphosphate (TNP-ATP) mimics the ability of cytosolic ATP to promote high-affinity 3-O-methylglucose uptake. TNP-ATP fluorescence increases upon interaction with purified human red cell GluT1. TNP-ATP binding to GluT1 is rapid (t(1/2) approximately 0.5 s at 50 microM TNP-ATP), cooperative, and pH-sensitive and is stimulated by ATP and by the exit site ligand cytochalasin B. Dithiothreitol inhibits TNP-ATP binding to GluT1. GluT1 preirradiation with saturating, unlabeled azidoATP enhances subsequent GluT1 photoincorporation of [gamma-32P]azidoATP. Reduced pH enhances azidoATP photoincorporation into isolated red cell GluT1 but inhibits ATP modulation of sugar transport in resealed red cell ghosts and in GluT1 proteoliposomes. We propose that cooperative nucleotide binding to reductant-sensitive, oligomeric GluT1 is modulated by a proton-sensitive saltbridge. The effects of ATP on GluT1-mediated sugar transport may be determined by the number of ATP molecules complexed with the transporter.     

Cytochalasin B interferes with conformational changes of the human erythrocyte glucose transporter induced by internal and external sugar binding.

To gain insight into the mechanism of facilitated sugar transport and possible mechanisms by which glucose transporter intrinsic activity might be altered, we have investigated conformational changes of the human erythrocyte glucose transporter induced by internal and external sugar binding and by the transporter inhibitor, cytochalasin B. Changes in the ability of thermolysin to digest glucose transporters present in erythrocyte ghosts were used to monitor conformational changes of the glucose transporter. The degree of protease digestion was determined by the amount of undigested glucose transporter remaining after the protease treatment, as assessed in Western blots using the glucose transporter specific monoclonal antibody 7F7.5. D-Glucose, the physiological substrate of the transporter, increased the transporter's susceptibility to cleavage by thermolysin. Nontransportable glucose analogues which bind specifically to either an internal or external glucose transporter sugar binding site also altered susceptibility of the transporter to thermolysin. Both methyl and propyl glucoside, which preferentially bind the internal sugar site, increased thermolysin susceptibility of the glucose transporter in a manner similar to that of D-glucose. In contrast, 4,6-O-ethylideneglucose, which preferentially binds the external sugar site, protected the transporter from thermolysin digestion. These results suggest that sugar binding to internal and external sugar sites induces distinct conformational changes and that the observed D-glucose effect on the susceptibility of the glucose transporter to thermolysin is due to D-glucose at equilibrium predominantly forming a complex with the internal sugar site. The protection from cleavage by thermolysin caused by external sugar binding is attenuated by the addition of an internally binding sugar.(ABSTRACT TRUNCATED AT 250 WORDS)     

D-Glucose-sensitive and -insensitive cytochalasin B binding proteins from microvillous plasma membranes of human placenta. Identification of the D-glucose transporter

Cytochalasin B was found to bind to at least two distinct sites in human placental microvillous plasma membrane vesicles, one of which is likely to be intimately associated with the glucose transporter. These sites were distinguished by the specificity of agents able to displace bound cytochalasin B. [3H]Cytochalasin B was displaceable at one site by D-glucose but not by dihydrocytochalasin B; it was displaceable from the other by dihydrocytochalasin B but not by D-glucose. Some binding which could not be displaced by D-glucose + cytochalasin B binding site. Cytochalasin B can be photoincorporated into specific binding proteins by ultraviolet irradiation. D-Glucose specifically prevented such photoaffinity labeling of a microvillous protein component(s) of Mr = 60,000 +/- 2000 as determined by urea-sodium dodecyl sulfate acrylamide gel electrophoresis. This D-glucose-sensitive cytochalasin B binding site of the placenta is likely to be either the glucose transporter or be intimately associated with it. The molecular weight of the placental glucose transporter agrees well with the most widely accepted molecular weight for the human erythrocyte glucose transporter. Dihydrocytochalasin B prevented the photoincorporation of [3H]cytochalasin B into a polypeptide(s) of Mr = 53,000 +/- 2000. This component is probably not associated with placental glucose transport. This report presents the first identification of a sodium-independent glucose transporter from a normal human tissue other than the erythrocyte. It also presents the first molecular weight identification of a human glucose-insensitive high-affinity cytochalasin B binding protein.     

Cytochalasin B as a probe of protein structure and substrate recognition by the galactose/H+ transporter of Escherichia coli.

Cytochalasin B is a potent inhibitor of mammalian passive glucose transporters. The recent demonstration of sequence similarities between these proteins and several bacterial proton-linked sugar transporters suggested that cytochalasin B might be a useful tool for investigation of the galactose/H+ symport protein (GalP) of Escherichia coli. Equilibrium binding studies using membranes from a GalP-constitutive (GalPc) strain of E. coli revealed a single set of high affinity binding sites for cytochalasin B with a Kd of 0.8-2.2 microM. Binding was inhibited by D-glucose, but not by L-glucose. UV irradiation of the membranes in the presence of [4-3H]cytochalasin B photolabeled principally a protein of apparent Mr 38,000, corresponding to the GalP protein. Labeling was inhibited by greater than 80% in the presence of 500 mM D-glucose or D-galactose, the major substrates of the GalP system. The extent of inhibition of photolabeling by different sugars and sugar analogues showed that the substrate specificity of GalP closely resembles that of the mammalian passive glucose transporters. Structural similarity to the latter was revealed by tryptic digestion of [4-3H]cytochalasin B-photolabeled GalP, which yielded a radiolabeled fragment of apparent Mr 17,000-19,000, similar to that previously reported for the human erythrocyte glucose transporter.     

Equilibrium ligand binding to the human erythrocyte sugar transporter. Evidence for two sugar-binding sites per carrier

Equilibrium [3H]cytochalasin B binding to class I sites of human red cell membranes (the sugar transporter) was examined in the presence and absence of intracellular or extracellular sugars known to interact with the transport system. D-Glucose, a transported sugar, is without effect on cytochalasin B binding when present in the extracellular medium but is an effective inhibitor of binding when present within the cell. Ethylidene glucose and maltose (reactive but nontransported sugars) inhibit cytochalasin B (CCB) binding when present either outside or inside the red cell. Inhibition by intracellular sugar (Si) is of the simple, linear competitive type. Inhibition by extracellular sugars (So) is more complex; the Kd(app) for cytochalasin B binding increases in a saturable fashion with [So]. These observations are compared with the predictions of the one-site, alternating conformer model and the two-site model for substrate binding to the sugar transporter, X. The experimental results are inconsistent with the one-site model but are explained by a two-site model in which the ternary complexes of So . X . Si or So . X . CCBi exist and where the binding sites for So and Si display negative cooperativity when occupied by nontransported substrate and little or no cooperativity when occupied by the transported species, D-glucose.     

Inhibition by nucleosides of glucose-transport activity in human erythrocytes.

The interaction of nucleosides with the glucose carrier of human erythrocytes was examined by studying the effect of nucleosides on reversible cytochalasin B-binding activity and glucose transport. Adenosine, inosine and thymidine were more potent inhibitors of cytochalasin B binding to human erythrocyte membranes than was D-glucose [IC50 (concentration causing 50% inhibition) values of 10, 24, 28 and 38 mM respectively]. Moreover, low concentrations of thymidine and adenosine inhibited D-glucose-sensitive cytochalasin B binding in an apparently competitive manner. Thymidine, a nucleoside not metabolized by human erythrocytes, inhibited glucose influx by intact cells with an IC50 value of 9 mM when preincubated with the erythrocytes. In contrast, thymidine was an order of magnitude less potent as an inhibitor of glucose influx when added simultaneously with the radioactive glucose. Consistent with this finding was the demonstration that glucose influx by inside-out vesicles prepared from human erythrocytes was more susceptible to thymidine inhibition than glucose influx by right-side-out vesicles. These data, together with previous suggestions that cytochalasin B binds to the glucose carrier at the inner face of the membrane, indicate that nucleosides are capable of inhibiting glucose-transport activity by interacting at the cytoplasmic surface of the glucose transporter. Nucleosides may also exhibit a low-affinity interaction at the extracellular face of the glucose transporter.     

A D-Glucose-Sensitive Cytochalasin B Binding Component of Cerebral Microvessels

The technique of photoaffinity labelling with [4-3H]cytochalasin B was applied to osmotically lysed cerebral microvessels isolated from sheep brain. Cytochalasin B was photo-incorporated into a membrane protein of average apparent Mr 53,000. Incorporation of cytochalasin B was inhibited by D-glucose, but not by L-glucose, which strongly suggests that the labelled protein is, or is a component of, the glucose transporter of the blood-brain barrier. Investigation of noncovalent [4-3H]cytochalasin B binding to cerebral microvessels by equilibrium dialysis indicated the presence of a single set of high-affinity binding sites with an association constant of 9.8 +/- 1.7 (SE) microM-1. This noncovalent binding was inhibited by D-glucose, with a Ki of 23 mM. These results provide preliminary identification of the glucose transporter of the ovine blood-brain barrier, and reveal both structural and functional similarities to the glucose transport protein of the human erythrocyte.     

The D-glucose transporter is tissue-specific. Skeletal muscle and adipose tissue have a unique form of glucose transporter

Using isotopic equilibration with [3H]D-glucose and measurement of D-glucose inhibitable cytochalasin B binding, I show that the erythrocytes of embryonic and newborn rats contain D-glucose transporters. On the basis of cytochalasin B binding and the time course of isotopic exchange, the number of transporters in rat embryonic erythrocytes is only 5% of that in human erythrocytes. Antibodies raised against the human erythrocyte glucose transporter were used as a probe to investigate the structural similarity between transporters. On this basis, the polypeptides of the glucose transporter of human erythrocytes and of embryonic rat erythrocytes are similar but not identical; in addition, certain antibodies showed similar reactivity toward the transporter of rat embryonic erythrocytes and that of rat brain. These antibodies, however, react with brain transporters 5 to 10 times better than with those of skeletal muscle and adipocytes suggesting that insulin responsive tissues may have a different type of glucose transporter. The cellular location of glucose transporters in skeletal muscle, determined by immunofluorescence, is on the plasma membrane or very close to the plasma membrane.     

Evidence that forskolin binds to the glucose transporter of human erythrocytes

Binding of [4-3H]cytochalasin B and [12-3H]forskolin to human erythrocyte membranes was measured by a centrifugation method. Glucose-displaceable binding of cytochalasin B was saturable, with KD = 0.11 microM, and maximum binding approximately 550 pmol/mg of protein. Forskolin inhibited the glucose-displaceable binding of cytochalasin B in an apparently competitive manner, with K1 = 3 microM. Glucose-displaceable binding of [12-3H]forskolin was also saturable, with KD = 2.6 microM and maximum binding approximately equal to 400 pmol/mg of protein. The following compounds inhibited binding of [12-3H]forskolin and [4-3H]cytochalasin B equivalently, with relative potencies parallel to their reported affinities for the glucose transport system: cytochalasins A and D, dihydrocytochalasin B, L-rhamnose, L-glucose, D-galactose, D-mannose, D-glucose, 2-deoxy-D-glucose, 3-O-methyl-D-glucose, phloretin, and phlorizin. A water-soluble derivative of forskolin, 7-hemisuccinyl-7-desacetylforskolin, displaced equivalent amounts of [4-3H]cytochalasin B or [12-3H]forskolin. Rabbit erythrocyte membranes, which are deficient in glucose transporter, did not bind either [4-3H]cytochalasin B or [12-3H]forskolin in a glucose-displaceable manner. These results indicate that forskolin, in concentrations routinely employed for stimulation of adenylate cyclase, binds to the glucose transporter. Endogenous ligands with similar specificities could be important modulators of cellular metabolism.     

Glucose transporter oligomeric structure determines transporter function. Reversible redox-dependent interconversions of tetrameric and dimeric GLUT1.

This study investigates the relationship between human erythrocyte glucose transport protein (GLUT1) oligomeric structure and glucose transporter function. Oligomeric structure was analyzed by hydrodynamic studies of cholate-solubilized GLUT1, by chemical cross-linking studies of membrane-resident GLUT1 and by using conformation-specific antibodies. Transporter function (substrate binding) was analyzed by equilibrium cytochalasin B and D-glucose binding measurements. Erythrocyte-resident glucose transporter is a GLUT1 homotetramer, binds 1 mol of cytochalasin B/2 mol of GLUT1, and presents at least two binding sites to D-glucose. Native structure and function appear to be stabilized by intramolecular disulfide bonds and are preserved during GLUT1 purification by the omission of reductant. Native structure is independent of in vitro and in vivo membrane GLUT1 density but is transformed to dimeric GLUT1 by alkaline reduction. Dimeric GLUT1 binds 1 mol of cytochalasin B/mol of GLUT1, presents a single population of binding sites to D-glucose, and is obtained upon GLUT1 purification in the presence of reductant. Native structure and function are restored by treatment of dimeric GLUT1 with glutathione-disulfide (K0.5 glutathione disulfide = 29 microM). We propose that native structure is established prior to transporter translocation to the plasma membrane and that intrasubunit disulfide bonds promote cooperative subunit interactions that stabilize transporter structure and function.     

An ATP-modulated specific association of glyceraldehyde-3-phosphate dehydrogenase with human erythrocyte glucose transporter

Glyceraldehyde-3-phosphate dehydrogenase was found to bind in vitro to purified, human erythrocyte glucose transporter reconstituted into vesicles. Mild tryptic digestion of the glucose transporter totally inactivated the binding, suggesting that the cytoplasmic domain of the transporter is involved in the binding to glyceraldehyde-3-phosphate dehydrogenase. The binding was abolished in the presence of antisera raised against the purified glucose transporter, further supporting specificity of this interaction. The binding was reversible with a dissociation constant (Kd) of 3.3 x 10(-6) M and a total capacity (Bt) of approximately 30 nmol/mg of protein indicating a stoichiometry of one enzyme-tetramer per accessible transporter. The binding was sensitive to changes in pH showing an optimum at around pH 7.0. KCl and NaCl inhibited the binding in a simple dose-dependent manner with Ki of 40 and 20 mM, respectively. The binding was also inhibited by NAD+ with an estimated Ki of 3 mM. ATP, on the other hand, enhanced the binding by up to 3-fold in a dose-dependent manner with an apparent Ka of approximately 6 mM. The binding was not affected by D-glucose or cytochalasin B. The binding did not affect either the glucose or cytochalasin B in binding affinities or the transport activity of the transporter. However, the enzyme was inactivated totally upon binding to the transporter. Based on these findings, we suggest that a significant portion of glyceraldehyde-3-phosphate dehydrogenase in human erythrocytes exists as an inactive form via an ATP-dependent, reversible association with glucose transporter, and that this association may exert regulatory intervention on nucleotide metabolism in vitro.     

Rapid GLUT-1 mediated glucose transport in erythrocytes from the grey-headed fruit bat (Pteropus poliocephalus)

D-Glucose entry into erythrocytes from adult grey-headed flying fox fruit bats (Pteropus poliocephalus) was rapid and showed saturation at high substrate concentrations. Kinetic parameters were estimated from the concentration dependence of initial rates of zero-trans D-glucose entry at 5.5 degrees C as Michaelis constant (K(m)) 1. 64+/-0.56 mM, and maximal velocity (V(max)) 1162+/-152 micromol.l. cell water(-1).min(-1). D-Glucose entry was inhibited by cytochalasin B; mass law analysis of D-glucose-displaceable cytochalasin B binding gave values of K(d) 37.1+/-5.0 nM and B(max) 361.2+/-9.1 pmol/mg membrane protein. Entry of 2-deoxy-D-glucose, and 3-O-methyl-D-glucose, into P. poliocephalus red cells was rapid, entry of D-fructose was very slow. Glucose transporter polypeptides were identified on immunoblots as a band M(r) 47000-54000 and their identity confirmed by D-glucose-sensitive photolabeling of membranes with [3H]-cytochalasin B. Peptide-N-glycanase F digestion of both human and bat erythrocyte membranes generated GLUT-1-derived bands M(r) 37000. Trypsin digestion of human and fruit bat erythrocyte membranes generated fragmentation patterns consistent with similar GLUT-1 polypeptide structures in both species. Erythrocytes from adult Australian ghost bats (Macroderma gigas), a carnivorous microchiropteran bat, also expressed high levels of GLUT-1.     

ATP-dependent sugar transport complexity in human erythrocytes

Human erythrocyte glucose sugar transport was examined in resealed red cell ghosts under equilibrium exchange conditions ([sugar](intracellular) = [sugar](extracellular), where brackets indicate concentration). Exchange 3-O-methylglucose (3MG) import and export are monophasic in the absence of cytoplasmic ATP but are biphasic when ATP is present. Biphasic exchange is observed as the rapid filling of a large compartment (66% cell volume) followed by the slow filling of the remaining cytoplasmic space. Biphasic exchange at 20 mM 3MG eliminates the possibility that the rapid exchange phase represents ATP-dependent 3MG binding to the glucose transport protein (GLUT1; cellular [GLUT1] of 相似文献   

Cytochalasin B binding proteins in human erythrocyte membranes. Modulation of glucose sensitivity by site interaction and partial solubilization of binding activities

We have previously described three different cytochalasin B binding sites in human erythrocyte membranes, a D-glucose-sensitive site (Site I), a cytochalasin E-sensitive site (Site II), and a site (Site III) insensitive to both D-glucose and cytochalasin E. Ligand bindings to each of these sites were considered to be independent (Jung, C., and Rampal, A. (1977) J. Biol. Chem. 252, 5456-5463). However, we have obtained subsequently the following evidence which indicated that an interaction occurs between Sites II and III, and this modulates sensitivity of Site III to the sugar. The displacement of cytochalasin E greatly exceeds the sum of their independent displacements. This ghosts extracted with EDTA or 2,3-dimethylmaleic anhydride at low ionic strength lack Site II activity but retain Site I and III activities, and both of these activities are displaceable by D-glucose alone. This indicated that the removal of Site II from the membrane confers glucose sensitivity to Site III. These observations are consistent with a model that Sites II and III in the membrane exist in a close association through which unliganded Site II maintains the glucose insensitivity of Site III, and once site II is liganded or removed by extraction this association is disrupted and Site III becomes glucose-sensitive. The ghosts extracted with Triton X-100 retain a cytochalasin B binding activity similar to that of site II (Kd = 1.8 X 10(-7) M, cytochalasin E-sensitive, glucose-insensitive), whereas a binding activity similar to that of Site I (Kd = 4 X 10(-7) M, cytochalasin E-insensitive, glucose-sensitive) is recovered in the Triton extract. A cytochalasin B binding activity similar to that of Site II is solubilized by EDTA at low ionic strength.