D-glucose permeability of black lipid membranes modified by human erythrocyte membrane fractions.

The D-glucose permeabilities of bimolecular lipid membranes formed from egg lecithin, cholesterol and human erythrocyte membrane fractions obtained using several fractionation procedures have been measured in order to assess their monosaccharide transport activity. The electrical properties of the bilayers containing the membrane fractions have also been measured and the bilayer thicknesses calculated. The observed D-glucose permeability coefficients are several orders of magnitude lower than that of the human erythrocyte membrane, indicating that none of the membrane fractions possessed significant glucose carrier activity. It is concluded that more refined techniques for incorporating membrane fractions into BLMs will be necessary before the monosaccharide transport system can be simulated in vitro.     

Loss of tRNA 5-methyluridine methyltransferase and pseudouridine synthetase activities in 5-fluorouracil and 1-(tetrahydro-2-furanyl)-5-fluorouracil (ftorafur)-treated Escherichia coli

The degradation of human erythrocyte membrane proteins in relation to the identification of the monosaccharide transporter has been investigated in whole membrane preparations and membrane protein extracts by polyacrylamide gel electrophoresis in sodium n-dodecyl sulphate and iodine-125 labelling. Evidence is presented for the degradation of band 3 polypeptide to lower molecular weight material some of which appears in region 4.5 of the polyacrylamide gel electrophoresis profile. It is found that the degradation process is inhibited by phenylmethylsulphonyl fluoride and is only significant in membrane extracts in the absence of detergent (Triton X-100) and on prolonged incubation at 37 degrees C, conditions which do not prevail during the isolation of membrane protein extracts for reconstitution studies. Extracts of band 3 and band 4.5 have been prepared and reconstituted in bilayer lipid membranes. The permeabilities of the reconstituted systems to D-glucose have been investigated and it is found that only bilayers incorporating band 4.5 exhibited enhanced monosaccharide transport. A linear relationship between D-glucose transport and the concentration of protein in the aqueous phase bathing the bilayers suggests a partitioning of the protein into the bilayer. Reconstitution is stereospecific and inhibited by cytochalasin B.     

D-glucosyl isothiocyanate, an affinity label for the glucose transport proteins of the human erythrocyte membrane

D-glucosyl isothiocyanate has been found to be a potent irreversible inhibitor of glucose translocation in the human erythrocyte. [¹⁴C]-D-glucosyl isothiocyanate was incorporated into two major proteins of the erythrocyte membrane, and this incorporation was inhibited by D-glucose. These proteins may be components of the glucose transport system.     

Distinction of three types of D-glucose transport systems in animal cells

Immunoblotting of plasma membrane fractions from rat kidney cortex with antibody to human erythrocyte glucose transporter showed a single major cross-reacting material of 48K in basolateral membrane fractions possessing a facilitated diffusion system for D-glucose, but not in brush border membrane fractions which have a Na-dependent active transport system. Cytochalasin B inhibited D-glucose uptake in basolateral membrane vesicles but not in brush border vesicles. Cross-reacting materials of 44-55K were detected in several animal cells exhibiting facilitated diffusion systems, including a hormone dependent system. These results indicate molecular difference between glucose transporters of facilitated diffusion systems and active transport systems.     

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.     

Photolabeling of glucose-sensitive cytochalasin B binding proteins in erythrocyte, fibroblast and adipocyte membranes

(³H)Cytochalasin B has been photoincorporated into membrane fractions of the human erythrocyte, Rous sarcoma virus-transformed chicken embryo fibroblast and rat adipocyte. Identification of D-glucose sensitive cytochalasin B binding sites was achieved by photolyzing membranes with radioligand in the presence of 0.5–0.7M D- or L-glucose. In the erythrocyte the major labeled bands on SDS-polyacrylamide gels were at 55,000 and 46,000 daltons. In the virus-transformed fibroblasts a major labeled band was at 55,000 daltons, and in adipocyte microsomal membranes, peaks at 50,000 and 45,000 daltons were observed. Binding characteristics of these polypeptides suggest that they are the putative glucose transport proteins in these three cell types.     

Does sphingomyelin inhibit the erythrocyte anion transport system?

The anion transport protein of the human erythrocyte membrane, band 3, was incorporated into unilamellar sphingomyelin vesicles. The vesicles showed a rapid sulfate efflux which could be inhibited by specific inhibitors of the erythrocyte anion transport system. All band 3 molecules contributing to the inhibitor-sensitive flux component were arranged 'right-side-out'. The turnover number of the transport protein for sulfate transport was virtually identical to that in phosphatidylcholine bilayers and around 6 times larger than in human erythrocyte membranes. Thus, in contrast to other claims, sphingomyelin does not inhibit the erythrocyte anion transport system.     

Partial puridication of a membrane protein from human erythrocytes involved in glucose transport.

In an attempt to determine which membrane proteins are essential to the stereospecific uptake of D-glucose, isolated human erythrocyte membranes were exposed to a variety of reagents capable of selectively extracting various membrane proteins. These reagents included EDTA, lithium 3,5-diiodosalicylate, sodium iodide, and 2,3-dimethylmaleic anhydride. Selective elution of spectrin and Components 2.1, 2.2, 2.3, 4.1, 4.2, 5, and 6 representing 65% of the ghost protein has no effect on the uptake of D-glucose. All of the sugar transport proteins are associated with a membrane residue consisting of the proteins of Bands 3, 4.5, and 7, the periodic acid-Schiff-sensitive glycoproteins, and ghost phospholipids. Specific cross-linking of the proteins of Band 3 of ghosts by the catalyzed oxidation of intrinsic sulfhydryl groups with the o-phenanthroline-cupric ion complex inhibits D-glucose uptake and alters the relative electrophoretic mobility of Band 3 proteins in sodium dodecyl sulfate-polyacrylamide-agarose gels. This uptake activity and the relative mobility of Band 3 proteins are recovered upon reversal of the cross-linking reaction by reduction with 2-mercaptoethanol. These results and other observations indicate that the D-glucose transport protein is an intrinsic component of the hydrophobic structure of the erythrocyte membrane and may be associated with the proteins of Band 3 which are glycoproteins spanning the membrane bilayer. It is proposed that D-glucose transport occurs through a water-filled channel formed by specific subunit aggregates of the transport proteins in the erythrocyte membrane rather than by rotation of the protein within the plane of the membrane.     

Erythrocyte D-glucose transport activity in reconstituted model membranes of different lipid composition

The stereospecific influx of D-glucose into liposomes formed on sonication of different glyco- and phospholipids with transport proteins from human erythrocyte ghosts solubilized with Triton x-100 was measured as an index of their total D-glucose transport activity. Specific D-glucose transport increased when acidic phospho- and glycolipids (especially sulfatide) were added to the phosphatidylcholine bilayers of the model membranes while cholesterol strongly inhibited the process. The modulation of D-glucose transport activity and its possible correlation with the lipid composition and the chemico-physical state of the erythrocytes is discussed.     

Immunological evidence that band 3 is the major glucose transporter of the human erythrocyte membrane

We have previously reported that human erythrocyte band 3 contains 90-95% of the reconstitutable glucose transport activity of the erythrocyte membrane (Shelton, R.L. and Langdon, R.G. (1983) Biochim. Biophys. Acta 733, 25-33). We have now found that monoclonal and polyclonal antibodies to epitopes on band 3 specifically removed band 3 and more than 90% of the reconstitutable glucose transport activity from unfractionated octylglucoside extracts of erythrocyte membranes; nonimmune serum removed neither. Western blots of whole membrane extracts revealed that the polyclonal antibody to band 4.5 used to isolate cDNA clones presumed to code for the transporter (Mueckler, M., Caruso, C., Baldwin, C.A., Pancio, M., Blench, J., Morris, H.B., Allard, W.J., Lienhard, G.E. and Lodish, H.F. (1985) Science 229, 941-945) reacts strongly with six discrete bands in the 4.5 region. A monoclonal antibody to band 3 also reacts with a Mr 55,000 component of band 4.5. We conclude that band 3 contains the major glucose transporter of human erythrocytes, and that the transport activity in band 4.5 might be attributable to a band 3 fragment. Band 3 is probably a multifunctional transport protein responsible for transport of glucose, anions, and water.     

Solubilization, reconstitution, and attempted affinity chromatography of the sugar transporter of the erythrocyte membrane

Reconstitution of the sugar transport system of human erythrocytes into artificial liposomes was achieved by freezing, thawing, and sonicating preformed phospholipid vesicles in the presence of intact ghosts, protein-depleted ghosts, or detergent-treated ghosts. D-glucose equilibrium exchange activities and affinity constants in the range of the reported erythrocyte values were reached in the best experiments. Whereas the extraction of peripheral membrane proteins did not depress the transport function crucially after reconstituting these protein-depleted ghosts, the selective solubilization of integral membrane proteins by a variety of nonionic detergents resulted in an uncontrollable, continuously increasing inactivation of the carrier. However, Emulphogene BC-720 extracts could be prepared in which the glucose transporter retained activity for days at 4 degrees C. These extracts were applied to affinity chromatography matrices of phloretin-Agarose, prepared by coupling phloretinyl-3'-benzylamine (PBA) to CH-Sepharose 4B and to Affigel 202. Although the solubilized sugar transporter appeared to be selectively adsorbed to both PBA matrices, it could not be eluted by specific counter ligands or gentle eluants in a biologically active form. However, chaotropic agents could be used to elute intrinsic proteins, including bands 3 and 4.5, from the Affigel affinity medium.     

Characterization of a photosensitive glucose derivative. A photoaffinity reagent for the erythrocyte hexose transporter

The photosensitive reagent 6-N-(4-azido-2-hydroxy-3,5-diiodobenzoyl)-D-glucosamine has been assessed as a potential photoaffinity label for the hexose transporter. Under zero-trans conditions, transport experiments performed in the dark reveal that the reagent inhibits the uptake of D-glucose in resealed human erythrocyte ghosts. Increasing the concentration of glucose in the transport medium has a protective effect, reducing the inhibition. Kinetic analysis indicates that the probe acts as a competitive inhibitor with high affinity for the erythrocyte hexose transporter (Ki between 0.07 and 0.2 microM). Exposure to a 280 nm filtered high intensity mercury-vapor lamp results in a rapid and efficient photolysis. At low concentrations of the probe, specific labeling of membrane preparations was observed. Autoradiograms of 10% SDS gels revealed the specific labeling of bands 4.51 and 6. This labeling was concentration-dependent and protected by D-glucose (not the L-isomer) and phloretin in the medium. When subjected to multiple exposures of low concentration of the photoaffinity reagent, apparent saturation was achieved.     

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.     

Rapid kinetics of the glucose transporter from human erythrocytes. Detection and measurement of a half-turnover of the purified transporter

The stopped flow method combined with fluorescence detection has been employed to study the rapid kinetics of the glucose transporter from human erythrocytes. Upon mixing the purified transporter reconstituted into unsealed membranes of erythrocyte lipids with 4,6-ethylidene D-glucose, a derivative that binds preferentially to the substrate site on the outer domain of the transporter, there was a rapid, first-order decrease in the intrinsic fluorescence of the protein. Three properties of this transient indicate that it represents a half-turnover of the transporter from a conformation with the substrate site facing inward to one with this site facing outward. The first-order rate constant decreased as the concentration of ethylidene glucose was increased; the value of the rate constant for the process is similar to that expected from steady-state kinetic studies of transport in the erythrocyte; and D-glucose at low concentration increased the rate of reaction. This study is the first determination of the kinetics of a half-turnover for a transport system of the facilitated diffusion type. The identification of this step provides direct evidence for the alternating conformation mechanism of transport.     

Properties of lecithin-dodecaprenol macrovesicular bilayer membranes

The ionic transport properties, capacitance and breakdown voltage of bilayer macrovesicles made from lecithin, dodecaprenol and their mixtures have been studied. The electrical measurements showed that polyprenol in lipid bilayers increases membrane permeability and elasticity, and decreases membrane thickness. Some physiological implications of these findings are indicated.     

Decrease in glucose transport activity of Friend erythroleukemia cell caused by dimethylsulfoxide, a differentiation-inducing reagent

A transport system for D-glucose was found in a Friend erythroleukemia cell line, T-3-C1-2-O and was characterized as a facilitated diffusion system. D-Glucose transport activity showed a half-saturation concentration of 2.2 mM and was inhibited by mercuric ions, cytochalasin B, phloretin, and stilbestrol, but was not strongly inhibited by phloridzin. Transport of 3-O-methyl-D-glucose was faster than D-glucose and the intracellular concentration of the sugar was found to reach the concentration in the assay medium. The treatment of cells with a differentiation-inducing reagent, dimethylsulfoxide(Me2SO), for 24 h caused a marked decrease in glucose transport activity due to a decrease in Vmax. In an induction-insensitive Friend cell line, T-3-K-1, D-glucose transport activity was low in untreated cells and Me2SO treatment did not cause a significant decrease in transport activity. The results obtained in this study indicate that the decrease in glucose transport activity is not due to the direct effect of Me2SO on transport activity, but is associated with the induction of differentiation. By immunoblotting cell lysates of T-3-C1-2-O cells using antibody to human erythrocyte glucose transporter, a single major band having a molecular weight of 52,000 was detected, which may be a glucose transporter in Friend cells.     

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.     

Studies on the function of pancreatic islet cell membranes.

Pancreatic islets rich in beta-cells were isolated from non-inbred ob/ob-mice and used for studying various aspects of the function of the plasma membrane. A review is given of the authors' work along the following lines: the role of transmembrane transport or membrane binding in the recognition of insulin-releasing sugars, amino acids, sulfonylureas, and sulphydryl-blocking agents; the role of cyclic 3',5'-AMP and cations in the coupling of stimulus recognition to insulin discharge; alloxan beta-cytotoxicity in vitro and its prevention by sugars; the isolation of a subcellular fraction enriched by plasma membranes. 1. It is suggested that D-glucose is recognized as an insulin secretagogue by being metabolized in the beta-cells; the teleological purpose of the transmembrane transport system being to allow fluctuations of the extracellular glucose concentration to be rapidly transmitted to the cell interior. Insulin-releasing sulfonyluraes and sulphydryl reagents are thought to act directly on the beta-cell plasma membrane, however. 2. Although cyclic 3',5'-AMP may amplify the expression of a secretory signal induced by D-glucose, studies with cholera toxin suggest that activation of the adenylate cyclase does not per se elicit secretion. The increase of islet cyclic 3',5'-AMP observed in response to several secretagogues, including D-glucose, may be secondary to membrane depolarization. 3. The possible role of an electrodiffusional mechanism in controlling the electrical potential is emphasized; a decrease of K+ permeability, rather than an increase of Na+ permeability, is suggested to be involved in the depolarizing action of D-glucose. Studies with the lanthanum-wash technique indicated that D-glucose causes a net flux of Ca2+ from the outside to the inside of the beta-cells. Although this uptake may relate to the enhancement of insulin secretion, the detailed mechanisms are unclear. 4. Inhibition of the Na+/K+ pump may be one of the earliest events in damage to the beta-cell by alloxan, on the basis of Rb+ studies. Protective effects of glucose against alloxan toxicity appear to be close related. 5. Studies of enzyme markers, the binding of wheat germ agglutinin, and electron microscopy indicate the presence of plasma membranes in a smooth-membrane fraction obtained by fractionating islet homogenates at consecutive sucrose gradients.