The human erythrocyte sugar transporter presents two sugar import sites

The human erythrocyte sugar transporter presents sugar import (e2) and sugar export (e1) sites simultaneously. This study asks whether the sugar transporter exposes only one or multiple import sites. We approached this question by analysis of cytochalasin B binding to the human erythrocyte sugar export site in the presence of sugars that bind to the sugar import site. Extracellular maltose does not enter human erythrocytes. High concentrations of maltose (1-100 mM) inhibit cytochalasin B binding to human red cells. Low concentrations (25-500 microM) increase the level of erythrocyte cytochalasin B binding. Maltose modulation of cytochalasin B binding is mediated by altered affinity of sugar export sites for cytochalasin B. Similar results are obtained with other cell-impermeant inhibitors of sugar uptake. Extracellular D-glucose (a transported sugar) stimulates cytochalasin B binding at low D-glucose concentrations (10-250 microM), but this effect is lost at higher concentrations. Intracellular D-glucose inhibits cytochalasin B binding. Low concentrations of extracellular maltose and other nontransported inhibitors stimulate 3-O-methylglucose uptake in erythrocytes. Higher sugar concentrations (1-100 mM) inhibit transport. These data support the hypothesis that the erythrocyte sugar transporter presents two sugar import sites and at least one sugar export site. This conclusion is consistent with the proposed oligomeric structure of the sugar transporter, a complex of four GluT1 proteins in which each subunit presents a translocation pathway.     

Photoaffinity labeling of the K562 cell membrane D-glucose transporter with cytochalasin B

D-glucose carrier protein in K562 cell membrane was studied by photoaffinity labeling with cytochalasin B. The saturable cytochalasin B binding in purified K562 cell membranes was 90 pmol/mg and 200 pmol/mg protein in the presence of D-glucose and D-sorbitol, respectively. More than half of the total cytochalasin B binding could be depressed by D-glucose. The results of SDS-PAGE analysis of K562 cell membranes after photoaffinity labeling at 0.1 microM cytochalasin B showed that the main peak of covalently bound [3H]-cytochalasin B was in the Mr range of 46-65 KDa. The label found in the peak was reduced by more than 50% in the presence of 0.5 M D-glucose, the inhibition similar being to that obtained in the binding experiment. This polypeptide has a slightly higher molecular weight than that of the human erythrocyte cell membrane.     

A model for the mode of action of cytochalasin B inhibition of D-glucose transport in the human erythrocyte.

By an optical method, cytochalasin B is shown to be a competitive inhibitor of D-glucose transport across the human erythrocyte membrane with Ki of 1.2 x 10(-7) M. A Drieding molecular model of cytochalasin B reveals an almost identical spatial distribution of four oxygen atoms to those found in the C1-conformation of beta-D-glucopyranose and implicated in hydrogen bonding to the carrier protein associated with D-glucose transport. The stereochemistry of this transport model is discussed. On the basis of the interoxygen distances found in cytochalasin B, hydrocortisone, prednisolone, corticosterone, and phenolphthalein are considered as analogues and are shown to be competitive inhibitors of D-glucose transport with Ki values of 2.2 x 10(-4) M, 3.0 x 10(-4) M, 4.0 x 10(-4) M, and 2.5 x 10(-5) M, respectively. These results are considered to be consistent with the proposed mode of action of cytochalasin B and also provide further support for the model of D-glucose stereospecifically hydrogen-bonded to a carrier protein.     

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.     

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.     

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.     

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.     

Cholate-solubilized erythrocyte glucose transporters exist as a mixture of homodimers and homotetramers

The molecular size of purified, human erythrocyte glucose transport protein (GLUT1) solubilized in cholic acid was determined by size-exclusion chromatography (SEC) and sucrose gradient ultracentrifugation. GLUT1 purified in the presence of dithiothreitol (GLUT1 + DTT) is resolved as a complex of average Stokes' radius 5.74 nm by SEC. This complex displays D-glucose-inhibitable cytochalasin B binding and, upon reconstitution into proteoliposomes, catalyzes cytochalasin B inhibitable D-glucose transport. GLUT1 purified in the absence of dithiothreitol (GLUT1-DTT) is resolved by SEC as at least two particles of average Stokes' radii 5.74 (minor component) and 7.48 nm (major component). Solubilization of GLUT1-DTT in the presence of dithiothreitol reduces the amount of 7.48-nm complex and increases the amount of 5.74-nm complex resolved by SEC. GLUT1-DTT displays D-glucose-inhibitable cytochalasin B binding and, upon reconstitution into proteoliposomes, catalyzes cytochalasin B inhibitable D-glucose transport. Sucrose gradient ultracentrifugation of GLUT1 + DTT in cholate resolves GLUT1 into two components of 4.8 and 7.6 S. The 4.8S complex is the major component of GLUT1 + DTT. The reverse profile is observed upon sucrose gradient ultracentrifugation of GLUT1-DTT. SEC of human erythrocyte membrane proteins resolves GLUT1 as a major broad peak of average Stokes' radius 7.48 nm and a minor component of 5.74 nm. Both components are characterized by D-glucose-inhibitable cytochalasin B binding. Purified GLUT1 is associated with approximately 26 tightly bound lipid molecules per monomer of transport protein. These data suggest that purified GLUT1 exists as a mixture of homodimers and homotetramers in cholate-lipid micelles and that the presence of reductant during solubilization favors dimer formation.     

Topography and functions of sulfhydryl groups of the human erythrocyte glucose transport mechanism

Summary Membrane-impermeant and -permeant maleimides were applied to characterize the location and function of the sulfhydryl (SH) groups essential for the facilitated diffusion mediated by the human erythrocyte glucose transport protein. Three such classes have been identified. Type I SH is accessible to membrane-impermeant reagents at the outer (exofacial) surface of the intact erythrocyte. Alkylation of this class inhibits glucose transport; D-glucose and cytochalasin B protect against the alkylation. Type II SH is located at the inner (endofacial) surface of the membrane and is accessible to the membrane-impermeant reagent glutathione maleimide only after lysis of the erythrocyte. D-glucose enhances, while cytochalasin B reduces, the alkylation of Type II SH by maleimides. Reaction of Types I and II SH with an impermeant maleimide increases the half-saturation concentration for binding of D-glucose to erythrocyte membranes. By contrast, inactivation of Type III SH markedly decreases the half-saturation concentration for the binding of D-glucose and other transported sugars. Type III SH is inactivated by the relatively lipid-soluble reagents N-ethylmaleimide (NEM) and dipyridyl disulfide, but not by the impermeant glutathione maleimide. Type III SH is thus located in a hydrophobic membrane domain. A kinetic model constructed to explain these observations indicates that Type III SH is required for the translocation event in a hydrophobic membrane domain which leads to the dissociation of glucose bound to transport sites at the membrane surfaces.     

D-glucose binding increases secondary structure of human erythrocyte monosaccharide transport protein

Purified hexose transport protein ("band 4.5") from human erythrocytes, reconstituted in vesicles of its endogenous lipids, displays minima in its circular dichroism (CD) spectrum at 222 and 207 nm, a pattern diagnostic for alpha-helical content of proteins. Upon addition of D-glucose, a saturable increment of +10-12% in negative ellipticity at 222 nm is observed stereospecifically and reproducibly. Addition of L-glucose had no effect on the CD spectrum of the transport protein. Addition of cytochalasin B (CB), a reversible inhibitor of hexose transport, had no effect itself on transporter CD spectra, but restored the spectrum at 222 nm to its original value when added in the presence of D-glucose. The observed D-glucose-induced increase in ordered secondary structure is proposed to result from incorporation into the membrane of a segment of the transport protein originally at a membrane-water interface.     

Reconstitution of the glucose transporter from bovine heart

Reconstitution of the glucose transporter from heart should be useful as an assay in its purification and in the study of its regulation. We have prepared plasma membranes from bovine heart which display D-glucose reversible binding of cytochalasin B (33 pmol sites/mg protein; Kd = 0.2 muM). The membrane proteins were reconstituted into liposomes by the freeze-thaw procedure. Reconstituted liposomes showed D-glucose transport activity which was stereospecific, saturable and inhibited by cytochalasin B, phloretin, and mercuric chloride. Compared to membrane proteins reconstituted directly, proteins obtained by dispersal of the membranes with low concentrations of cholate or by cholate solubilization showed 1.2- or 2.3-fold higher specific activities for reconstituted transport, respectively. SDS-polyacrylamide gel electrophoresis followed by electrophoretic protein transfer and labeling with antisera prepared against the human erythrocyte transporter identified a single band of about 45 kDa in membranes from both dog and bovine hearts, a size similar to that reported for a number of other glucose transporters in various animals and tissues.     

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.     

Retention of insulin-stimulated D-glucose transport activity by adipocyte plasma membranes following extraction of extrinsic proteins

Plasma membrane vesicles prepared from adipocytes incubated with insulin exhibited accelerated D-glucose transport activity characteristic of insulin action on intact fat cells. Both control and insulin-stimulated D-glucose transport activities were inhibited by cytochalasin B and thiol reagents. Extraction of plasma membranes with dimethylmaleic anhydride eluted 80% of the protein from plasma membrane vesicles. The two major glycoprotein bands (94,000 and 78,000 daltons) and small amounts of a 56,000-dalton band were retained in dodecyl sulfate gels of the extracted membranes. Both control and insulin-activated D-glucose transport activities were retained by plasma membrane vesicles extracted with dimethylmaleic anhydride. Cytochalasin B binding activity was also retained by extracted membrane vescles and D-glucose uptake into extracted vescles derived from untreated or insulin-treated fat cells was inhibited by cytochalasin B. These results suggest that the modification of the adipocyte hexose transport system elicited by insulin action is not altered by a major purification step which involves quantitative extraction of extrinsic membrane proteins.     

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.     

A rapid method of reconstituting human erythrocyte sugar transport proteins

A rapid reconstitution procedure for human erythrocyte hexose transfer activity is described. The procedure (reverse-phase evaporation) avoids exposure of the isolated proteins to detergent, organic solvent, sonication, or freeze-thaw steps during insertion into synthetic membranes and may be effected within 15 min. The so-formed vesicles are unilamellar structures with a large encapsulated volume, narrow size range, and low passive permeabilities. Contamination by carry-through of endogenous (red cell) lipids is less than 1%. Reconstituted hexose transfer activity was examined by using unfractionated proteins (bands 3, 4.5, and 6) and purified proteins (bands 4.5 and 3). With unfractionated proteins, hexose transport activity is low [0.34 mumol X (mg of protein)-1 X min-1], is inhibited by cytochalasin B, and increases monotonically with protein concentration. Kinetic analysis indicates that Vmax values for both influx and efflux of D-glucose are identical. Reconstitution of the cytochalasin B binding protein (band 4.5) results in hexose transport with high specific activity [5 mumol X (mg of protein)-1 X min-1] and symmetry in transfer kinetics. Band 3 proteins also appear to mediate cytochalasin B sensitive D-glucose transport activity.     

Reaction of an exofacial sulfhydryl group on the erythrocyte hexose carrier with an impermeant maleimide. Relevance to the mechanism of hexose transport

The presence of a reactive exofacial sulfhydryl on the human erythrocyte hexose carrier was used to test several predictions of the alternating conformation or one-site model of transport. The cell-impermeant glutathione-maleimide-I (GS-Mal) irreversibly inhibited hexose entry by decreasing the transport Vmax. This effect was potentiated by phloretin and maltose but decreased by cytochalasin B, indicating that under the one-site model the external sulfhydryl is on the outward-facing carrier but that it does not overlap with the exofacial substrate-binding site. Incubation of erythrocytes with maltose competitively inhibited the binding of [3H]cytochalasin B to the inward-facing carrier (Ki = 40 mM). Furthermore, both equilibrium cytochalasin B binding and its photolabeling of the band 4.5 carrier protein were decreased in ghosts prepared from GS-Mal-treated cells. Thus induction of an outward-facing carrier conformation with either maltose or GS-Mal caused the endofacial substrate-binding site to disappear. Dose-response studies of GS-Mal treatment of intact cells suggested that some functional carriers lack a reactive external sulfhydryl, which can be partially regenerated by pretreatment with excess cysteine. These data provide direct support for the one-site model of transport and further define the role of the external sulfhydryl in the transport mechanism.     

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.     

Anomalous asymmetric kinetics of human red cell hexose transfer: role of cytosolic adenosine 5'-triphosphate

Cytosolic adenosine 5'-triphosphate (ATP) modifies the properties of human red cell sugar transport. This interaction has been examined by analysis of substrate-induced sugar transporter intrinsic fluorescence quenching and by determination of Michaelis and velocity constants for D-glucose transport in red cell ghosts and inside-out vesicles lacking and containing ATP. When excited at 295 nm, human erythrocyte ghosts stripped of peripheral proteins display an emission spectrum characterized by a scattering peak and a single emission peak centered at about 333 nm. Addition of sugar transport substrate or cytochalasin B and phloretin (sugar transport inhibitors) reduces emission peak height by 10% and 5%, respectively. Cytochalasin B induced quenching is a simple saturable phenomenon with an apparent Kd (app Kd) of 60 nM and a capacity of 1.4 nmol of sites/mg of membrane protein. Quenching by D-glucose (and other transported sugars) is characterized by at least two (high and low) app Kd parameters. Inhibitor studies indicate that these sites correspond to sugar efflux and influx sites, respectively, and that both sites can exist simultaneously. ATP induces quenching of stripped ghost fluorescence with half-maximal effects at 20-30 microM ATP. ATP reduces the low app Kd and increases the high app Kd for sugar-induced fluorescence quenching. D-Glucose transport in intact red cells is asymmetric (Km and Vmax for influx less than Km and Vmax for efflux). In addition, two operational Km parameters for efflux are detected in zero- and infinite-trans efflux conditions. Protein-mediated sugar transport in ghosts and inside-out vesicles (IOVs) is symmetric with respect to Km and Vmax for entry and exit, and only one Km for exit is detected. Addition of millimolar levels of ATP to the interior of ghosts or to the exterior of IOVs restores both transport asymmetry and two operational Km parameters for native efflux. A model for red cell hexose transport is proposed in which ATP modifies the catalytic properties of the transport system. This model mimics the behavior of the sugar transport systems of intact cells, ghosts, and inside-out vesicles.     

Differential Labeling of Components in Human Erythrocyte Membranes Associated with the Transport of Glucose

The irreversible inhibition of glucose transport by 1-fluoro-2,4-dinitrobenzene (FDNB) has been used to identify membrane proteins possibly associated with glucose transport in human crythrocytes. D-Glucose was shown to enhance significantly the rate of FDNB inhibition of transport when present during the reaction, whereas cytochalasin B (CB) and D-maltose retarded this FDNB inhibition of transport. This modulation of the inhibition reaction formed the basis for a double isotopic differential labeling technique using [¹⁴C]- and [³H]FDNB followed by SDS-polyacrylamide gel electrophoresis to distinguish transport-associated polypeptides from bulk membrane dinitrophenylated proteins.

Reactions in the presence of CB or maltose revealed the presence of a differentially labeled polypeptide(s), with a molecular weight of approximately 60,000-65,000 daltons. This effect could in part be reversed in the presence of D-glucose but not L-glucose. Reactions in the presence of D-glucose resulted in two regions of differential labeling. One region was around 200,000 daltons and the other corresponded to a 90,000-dalton band.

Extraction of membrane proteins with p-chloromercuribenzene sulfonate resulted in no loss of the 60,000-dalton peak, indicating that this labeled polypeptide(s) was firmly anchored in the hydrophobic core of the membrane.

These results indicate that as many as three membrane polypeptides are differentially labeled by FDNB under conditions strongly associated with the inhibition of the glucose transport system and may be involved in the regulation of glucose transport.     

Localization of the forskolin photolabelling site within the monosaccharide transporter of human erythrocytes.

Chemical and proteolytic digestion of intact erythrocyte glucose transporter as well as purified transporter protein has been used to localize the derivatization site for the photoaffinity agent 3-[125I]iodo-4-azido-phenethylamino-7-O-succinyldeacetylforskol in [( 125I]IAPS-forskolin). Comparison of the partial amino acid sequence of the labelled 18 kDa tryptic fragment with the known amino acid sequence for the HepG2 glucose transporter confirmed that the binding site for IAPS-forskolin is between the amino acid residues Glu254 and Tyr456. Digestion of intact glucose transporter with Pronase suggests that this site is within the membrane bilayer. Digestion of labelled transporter with CNBr generated a major radiolabelled fragment of Mr approximately 5800 putatively identified as residues 365-420. Isoelectric focusing of Staphylococcus aureus V8 proteinase-treated purified labelled tryptic fragment identified two peptides which likely correspond to amino acid residues 360-380 and 381-393. The common region for these radiolabelled peptides is the tenth putative transmembrane helix of the erythrocyte glucose transporter, comprising amino acid residues 369-389. Additional support for this conclusion comes from studies in which [125I]APS-forskolin was photoincorporated into the L-arabinose/H(+)-transport protein of Escherichia coli. Labelling of this transport protein was protected by both cytochalasin B and D-glucose. The region of the erythrocyte glucose transporter thought to be derivatized with IAPS-forskolin contains a tryptophan residue (Trp388) that is conserved in the sequence of the E. coli arabinose-transport protein.