Enhancement of anion permeability in lecithin vesicles by hydrophobic proteins extracted from red blood cell membranes.

Triton X-100 extracts of membrane proteins from ghosts of normal and pronase treated cells enhance the anion permeability of lecithin vesicles. With proteins from cells pretreated with DIDS (4,4′-diisothiocyano-2,2′-stilbene disulfonate), a specific inhibitor of anion transport, the anion permeability is not enhanced. On the basis that the Triton X-100 extracts are considerably enriched in a protein component of 95,000 molecular weight (or a 65,000 molecular weight segment in the case of pronase treated cells), and that DIDS is bound almost exclusively to the same proteins, it is suggested that the pronase resistant, 65,000 molecular weight segment of the 95,000 molecular weight protein is directly involved in anion transport.     

Labeling of human erythrocyte membranes with eosin probes used for protein diffusion measurements. Inhibition of anion transport and photo-oxidative inactivation of acetylcholinesterase

The binding of eosin-isothiocyanate (eosin-NCS) and iodoacetamido-eosin (IA-eosin) to band 3 proteins in the membrane of human erythrocytes is characterized by studying the effect of these probes on the anion transport system. Although the unbrominated fluorescein precursors do not affect anion transport, both eosin labels are strong inhibitors of sulphate exchange in intact erythrocytes. 50% inhibition is obtained by binding 4.7 · 10⁵ or 6.0 · 10⁵ molecules/cell for eosin-NCS and IA-eosin, respectively. Both eosin probes are irreversibly bound and occupy common binding sites with 4,4′-diisothiocyano-1,2-diphenyl-ethane-2,2′-disulfonic acid (H₂DIDS), although other sites are labeled as well. The inhibition of anion transport is light independent and can therefore not be attributed to a photosensitizing action of the eosin probes. Both eosin derivatives, however, inactivate acetylcholinesterase upon illumination of air-equilibrated samples of hemoglobin-free labeled ghosts. The inactivation of the enzyme is accompanied by the formation of protein aggregates as visualized by polyacrylamide gel electrophoresis. These effects are not observed when intact erythrocytes are illuminated in the presence of eosin probes suggesting a protective effect of hemoglobin during the labeling procedure. Protection of ghosts from photo-oxidation is achieved by displacing air with argon. These results are discussed in relation to the use of these and similar probes to measure protein diffusion in membranes.     

An evaluation of techniques for labelling the surface proteins of cultured mammalian cells

We have evaluated four techniques for labelling the surface proteins of cultured mammalian cells. The techniques are: (a) the lactoperoxide system; (b) the pyridoxal phosphate-[³H]borohydride system; (c) the [³H]4,4′-diisothiocyano-2,2′-dihydrostilbene disulfonate system and (d) the galactose oxidase-[³H]borohydride system. The subcellular distribution of radiolabel produced by these techniques has been evaluated by authoradiography at the light microscope level and by cellular fractionation. We find that while all four systems label the surface membranes in the majority of the cell population, they also heavily label internal sites in a small subpopulation of nonviable cells. The contribution of the internally labelled cells to further biochemical analysis may represent a severe problem in investigations which rely solely on surface labels for the study of plasma membrane organization     

Optimal conditions for lactoperoxidase catalyzed radioiodination of external proteins on mouse erythrocytes

Optimal conditions were established for specific labelling of the surface proteins of mouse erythrocytes using lactoperoxidase-catalyzed radioiodination. The levels of H2O2 and I-, and cell concentrations required for restriction of haemoglobin labelling to less than 5% of the total 125I-protein, were different for radioiodination employing direct H2O2 addition or generation of H2O2 with glucose oxidase plus glucose. Preparation of mouse erythrocyte ghosts by hypotonic lysis caused loss of some minor labelled proteins present on intact cells and shifts to lower molecular weights of others. It is therefore important to solubilize labelled cells directly in electrophoresis buffer to avoid artifactual degradation of labelled proteins. The extent of labelling internal cell proteins was measured by a procedure suitable for the comparison of a large number of samples: solubilized radioiodinated erythrocytes were electrophoresed on 14% acrylamide gels and the radioactivity determined in the haemoglobin band which migrates separately from other proteins. The major labelled protein on the mouse erythrocytes had an apparent molecular weight of 92,000, and may be analogous to Band 3 of the human erythrocyte.     

Inhibition of anion transport associated with chymotryptic cleavages of red blood cell band 3 protein

Right-side-out vesicles derived from red blood cells treated with chymotrypsin retain specific anion transport function (defined as transport sensitive to the specific inhibitor, 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid (DIDS)), even though the transport protein, band 3, is cleaved into two segments of 60 and 35 kdaltons. In contrast, vesicles derived from alkali-stripped ghosts treated with relatively high concentrations of chymotrypsin retain almost no specific anion function. The loss of function appears to be related to additional cleavages of band 3 protein that occur in treated ghosts, the 60-kdalton segment being reduced first to a 17- and then to a 15-kdalton segment and the 35-kdalton segment being reduced to a 9-kdalton segment plus a carbohydrate containing fragment. The chymotryptic cleavages of band 3 protein of ghosts are preferentially inhibited by high ionic strength, the production of the 9-kdalton segment being somewhat slower than that of the 15-kdalton segment. Vesicles derived from ghosts treated with chymotrypsin at different ionic strengths show a graded reduction in specific anion transport activity, but it was not possible to determine, definitively, which of the additional cleavages was inhibitory. In the light of these data and other information, the functional role of the segments of band 3 is discussed.     

Pyridoxal phosphate. An anionic probe for protein amino groups exposed on the outer and inner surfaces of intact human red blood cells.

Pyridoxal phosphate is a potent probe for exploring the "sidedness" of proteins in the membrane of the intact red blood cell. It reacts with amino groups with a high degree of specificity, forming a Schiff's base that can be fixed as an irreversible bond upon reduction with NaBH4; its binding site can be identified by use of [3-H]pyridoxal phosphate or NaB3-H4; it can be used as a surface probe under conditions of minimal penetration, or it can be used as a probe for proteins on the inside of the membrane under conditions of substantial uptake. Pyridoxal phosphate uptake involves a rapid and a slow component. The former represents the binding to the outer surface of the membrane; it is not substantially affected by pH and temperature, but is reduced considerably by pretreatment of cells by 4,4-diisothiocyano-2,2-stilbenedisulfonic acid, a specific inhibitor of anion transport. The slow component represents penetration into the cell; it is blocked by high pH, low temperature, or pretreatment with the disulfonic stilbene. Pyridoxal phosphate itself is also an effective and specific inhibitor of the permeation of other anions. Under conditions of minimal uptake, the only labeled proteins are three glycoproteins and a protein of apparent molecular weight 95,000. Under conditions of substantial uptake into the cell, the other major protein bands seen by staining on acrylamide gels after electrophoresis are labeled. It is concluded that virtually all of the major membrane proteins interact with pyridoxal phosphate from one side of the membrane or the other. The differences in labeling under conditions of minimal or maximal uptake can, therefore, be attributed to the sidedness in the distribution of the membrane proteins rather than to differences in their reactivity.     

Anion transport in relation to proteolytic dissection of band 3 protein

Sulfate efflux was measured in inside-out vesicles obtained from human red cells. Inhibition was observed in vesicles derived from cells pretreated with DIDS (4,4′-diisothiocyano-2,2′-stilbene disulfonate) or after addition of dipyridamole to the vesicles, both agents being specific and potent inhibitors of anion transport in cells. Trypsinization of the cytoplasmic side of the membrane in order to release a 40 000 dalton fragment from band 3 (the purported anion transport protein) had no effect on sulfate efflux. Further degradation of band 3 to a 17 000 dalton segment, by trypsinization of inside-out vesicles derived from cells that had been pretreated with chymotrypsin, also showed little reduction in transport activity. Furthermore, such vesicles derived from DIDS pretreated cells were inhibited by over 90%. In DIDS-treated cells, the agent is highly localized in band 3. In trypsinized inside-out vesicles, it is largely found in a 55 000 fragment and in trypsinized vesicles derived from cells pretreated with chymotrypsin it is largely located in the 17 000 fragment. The data suggest that both the anion transport and inhibitor binding sites are located in a 17 000 transmembrane segment of band 3.     

Interaction of photosynthetic pigments with various organic solvents. Magnetic circular dichroism approach and application to chlorosomes

Reduction of extracellular ferricyanide by intact cells reflects the activity of an as yet unidentified trans-plasma membrane oxidoreductase. In human erythrocytes, this activity was found to be limited by the ability of the cells to recycle intracellular ascorbic acid, its primary trans-membrane electron donor. Ascorbate-dependent ferricyanide reduction by erythrocytes was partially inhibited by reaction of one or more cell-surface sulfhydryls with p-chloromercuribenzene sulfonic acid, an effect that persisted in resealed ghosts prepared from such treated cells. However, treatment of intact cells with the sulfhydryl reagent had no effect on NADH-dependent ferricyanide or ferricytochrome c reductase activities of open ghosts prepared from treated cells. When cytosol-free ghosts were resealed to contain trypsin or pronase, ascorbate-dependent reduction of extravesicular ferricyanide was doubled, whereas NADH-dependent ferricyanide and ferricytochrome c reduction were decreased by proteolytic digestion. The trans-membrane ascorbate-dependent activity was also found to be inhibited by reaction of sulfhydryls on its cytoplasmic face. These results show that the trans-membrane ferricyanide oxidoreductase is limited by the ability of erythrocytes to recycle intracellular ascorbate, that it does not involve the endofacial NADH-dependent cytochrome b(5) reductase system, and that it is a trans-membrane protein that contains sensitive sulfhydryl groups on both membrane faces.     

Pepsin cleavage of band 3 produces its membrane-crossing domains

After prolonged treatment of red-cell ghosts with pepsin followed by SDS-urea-acrylamide gel electrophoresis of the membrane peptide fraction, a heavily stained band representing peptides of about 4 kDa (with traces of higher molecular weights) was found. If the cells were first labelled with the disulfonic stilbene, DIDS (4,4'-diisothiocyano-2,2'-stilbenedisulfonic acid) or with N-ethylmaleimide, probes that react with specific sites in Band 3 the anion transport protein, both agents were largely located in the 4 kDA band. With less intensive pepsin treatment, Stained bands of about 17, 12 and 8 kDa were also visible, and DIDS labelling was associated with these higher molecular weight peptides. The 4 kDa band apparently contains at least five or six different peptides. A single peptide containing the DIDS-binding site was separated from others in the band by ion-exchange chromatography. The location of the DIDS-peptide in the primary structure of Band 3 was determined by matching the known location of DIDS and of a methionine residue cleavable by cyanogen bromide. It is concluded that two additional 4 kDA peptides are labelled with N-ethylmaleimide. Because the location of the N-ethylmaleimide-binding sites are known, these two peptides could also be mapped in the primary structure of Band 3. The findings are consistent with the suggestion that pepsin can digest those portions of Band 3 (and probably of other intrinsic peptides) that are exposed on either side of the membrane, leaving only those domains that cross the bilayer. For Band 3, the data are consistent with a structure containing five crossing strands per monomer, each crossing strand being about 4 kDa.     

Macromolecular crowding and volume perception in dog red cells

To differentiate whether the primary volume signal in dog red cells arises from a change in cell configuration or the concentration and dilution of cell contents, we prepared resealed ghosts that had the same surface area and hemoglobin concentration as intact cells but less than 1/3 their volume. Shrinkage of both intact cells and resealed ghosts triggered Na/H exchange. Activation of this transporter in the two preparations correlated closely with cytosolic protein concentration but not at all with volume. The Na/H exchanger was more sensitive to shrinkage in albumin-loaded resealed ghosts than in intact cells or ghosts containing only hemoglobin. Similar results were obtained for the swelling-induced [K-Cl] cotransporter. We believe perception of cell volume originates with changes in cytoplasmic protein concentration. We think the kinases and phosphatases that control the activation of membrane transporters in response to cell swelling or shrinkage are regulated by the mechanism of macromolecular crowding.     

Alterations in pyridoxal 5'-phosphate inhibition of human erythrocyte anion transport associated with osmotic hemolysis and resealing

When pyridoxal 5'-phosphate (PLP) is covalently bound to band 3 protein in intact red blood cells and those cells are subjected to the osmotic hemolysis and resealing process, a significant reduction in the original PLP anion transport inhibitory potency occurs. We show that partial deinhibition is not due to the development of a second anion transport pathway in resealed ghosts. Rather, partial deinhibition arises from a hemolysis-induced conformational change in CH17 (17-kDa integral chymotryptic domain of band 3). This change causes the extracellular exposure of new transport inhibitory sites. Exposure of the new sites leads to a 2-fold increase in PLP labeling of CH17 in resealed ghosts compared with CH17 in intact red cells. The hemolysis and resealing process has no effect on the labeling of CH35 (35-kDa integral chymotryptic fragment of band 3). Double-labeling studies show restoration of transport inhibitory potency to near red cell levels when the newly exposed CH17 sites are labeled with PLP in resealed ghosts. The results support the view that CH17 contains PLP transport inhibitory sites. They show that a major conformational change occurs in band 3 with hemolysis.     

HeLa cell plasma membranes : IV. Iodination of membrane proteins in synchronized cells

Intact HeLa cells and isolated HeLa cell plasma membranes were subjected to lactoperoxidase-catalysed iodination. The ¹²⁵I-labelled proteins were separated by SDS-polyacrylamide gel electrophoresis. Six protein species with apparent molecular weights from 32 000 to 200 000 were accessible to labelling from the outer cell surface, while most of the proteins present in the plasma membrane were labelled when isolated plasma membranes were iodinated. Iodination of synchronized intact cells revealed that the labelling obtained was cell cycle dependent with maximal labelling at mitosis. No changes in the distribution of radioactivity among the labelled proteins were observed when cells from different phases were iodinated.     

A fluorimetric assay for the effects of cytolytic toxins on the transport properties of resealed erythrocyte ghosts.

We prepared resealed erythrocyte ghosts loaded with SPQ and chloride. We demonstrated that these membranes were still functional, as they were capable of exchanging anions, most probably through the band-3 protein. When cytolytic toxins (Escherichia coli hemolysin and Staphylococcus aureus alpha-toxin) were offered to the resealed ghosts, the internal SPQ was released. This could be attributed to the formation of toxin-induced ion channels into the ghost membrane that were so large that SPQ could escape through them. This release was actually independent of the anion-exchanging protein, since DIDS had no inhibitory effect on it. Due to their simplicity, and because they do not lyse, erythrocyte ghosts may serve as useful models to study the action of cytolytic pore-forming toxins. To assess the validity of these model membranes we compared results obtained using RBC and resealed erythrocyte ghosts as targets for the toxin, finding complete consistency. Pre-assembled toxin channels could also be studied on the ghosts. Applying different proteolytic enzymes to the external compartment after channel formation, we found that performed E. coli hemolysin pores were at least partially destroyed by enzymatic digestion.     

Protoporphyrin-induced photodynamic effects on band 3 protein of human erythrocyte membranes

In previous studies it has been shown that protoporphyrin-induced photodynamic effects on red blood cells are caused by photooxidation of amino acid residues in membrane proteins and by the subsequent covalent cross-linking of these proteins. Band 3, the anion transport protein of the red blood cell membrane, has a relatively low sensitivity to photodynamic cross-linking. This cannot be attributed to sterical factors inherent in the specific localization of band 3 in the membrane structure. Solubilized band 3, for instance, showed a similar low sensitivity to cross-linking. By extracellular chymotrypsin cleavage of band 3 into fragments of 60 000 and 35 000 daltons it could be shown that both fragments were about equally sensitive to photodynamic cross-linking. The 17 000 dalton transmembrane segment, on the other hand, was completely insensitive. Inhibition of band 3-mediated sulfate transport proceeded much faster than band 3 interpeptide cross-linking, presumably indicating that the inhibition of transport is caused by photooxidation of essential amino acid residues or intrapeptide cross-linking. A close parallel was observed between photodynamic inhibition of anion transport and decreased binding of 4,4′-diisothiocyanodihydrostilbene-2,2′-disulfonate (H₂DIDS), suggesting that a photooxidation in the immediate vicinity of the H₂DIDS binding site may be responsible for transport inhibition.     

Direct and indirect immunolabelling of HeLa cells with quantum dots

With excellent optical properties, quantum dots (QDs) have been made as attractive molecular probes for labelling cells in biological research. In this study high‐quality CdSe QDs prepared in a paraffin–oleic acid system were used as fluorescent labels in direct and indirect detection of carcinoembryonic antigen (CEA), a cancer marker expressed on the surface of HeLa cells. The primary antibody (Ab) (rabbit anti‐CEA8) and secondary Ab (goat anti‐rabbit IgG) were covalently linked to carboxyl‐functioned CdSe QDs, and both the QDs–antibody and QDs–IgG probes were successfully used to label HeLa cells. The present study demonstrates the practicability of CdSe QDs as an attractive type of fluorescent labels for biological applications such as protein probes and cell imaging. Copyright © 2008 John Wiley & Sons, Ltd.     

Modification of human erythrocyte ghosts with transglutaminase

Guinea pig liver transglutaminase was shown to catalyze the incorporation of dansylcadaverine and putrescine into two major protein fractions of human erythrocyte ghosts. As judged by sodium dodecylsulfate gel electrophoresis under reducing conditions, one of these is a high molecular weight polymer which may contain spectrin. The other corresponds to band 3, an 88, 000 dalton polypeptide. Amine substrates of transglutaminase were synthesized with specific properties to further explore this useful enzymatic technique of covalently labelling proteins in erythrocyte ghosts and in other biological membranes.     

The interaction of human erythrocyte band 3 with cytoskeletal components

Band 3 of the human erythrocyte is involved in anion transport and binding of the cytoskeleton to the membrane bilayer. Human erythrocytes were treated to incorporate varying concentrations of DIDS (4,4′-diisothiocyanostilbene-2,2′-disulfonic acid) a non-penetrating, irreversible inhibitor of anion transport, and both functions of Band 3 were analyzed. The rate of efflux of ³⁵SO₄. was measured and the binding of cytoskeletal components to the membrane was evaluated by extracting the membranes with 0.1 n NaOH and analyzing for the peptides remaining with the membrane. It was found that 0.1 n NaOH extracts all the extrinsic proteins from membranes of untreated cells, while, in the case of the membranes from cells treated with DIDS, a portion of the cytoskeletal components, spectrin (Bands 1 and 2) and Band 2.1 (ankyrin, syndein) remain with the membrane. The amount of these cytoskeletal components remaining with the membrane depends on the concentrations of DIDS incorporated. The effect of DIDS on the extractability of the spectrin-Band 2.1 complex correlates well with DIDS inhibition of anion transport (r = 0.91). At DIDS concentrations which completely inhibit anion transport, about 10% of total spectrin-Band 2.1 complex remains unextracted. Another anion-transport inhibitor, pyridoxal phosphate, has no effect on binding of the cytoskeleton to the membrane. On the other hand, digestion of DIDS-pretreated intact erythrocytes with Pronase, chymotrypsin, or trypsin releases the tight binding of Band 3 to cytoskeleton on the inside of the membrane. Since trypsin does not hydrolyze Band 3 the data suggest that a second membrane protein which is trypsin sensitive may be involved with Band 3 in cytoskeletal binding.     

Identification of an anion channel protein from electric organ of Narke japonica

The anion permeability of membrane vesicles prepared from the electric organ of $\text{Narke japonica}$ was inhibited by the addition of 4,4′-diisothiocyano-stilbene-2,2′-disulfonic acid (DIDS). The permeability was measured by measuring changes in the scattered-light intensity caused by the osmotic volume change of vesicles; and also by the efflux measurement of ions from the vesicles using radioisotopes. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of membrane vesicles treated with dihydro analog of DIDS ([³H]H₂DIDS) showed that the H₂DIDS binding protein has a molecular weight of 180,000, and exists in membrane vesicles as a dimer formed by a disulfide bond between monomers of molecular weight 90,000.     

Involvement of cytoskeletal proteins in the barrier function of the human erythrocyte membrane. III. Permeability of spectrin-depleted inside-out membrane vesicles to hydrophilic nonelectrolytes. Formation of leaks by chemical or enzymatic modification of membrane proteins.

Spectrin-depleted inside-out vesicles (IOV's) prepared from human erythrocyte membranes were characterized in terms of size, ground permeability to hydrophilic nonelectrolytes and their sensitivity to modification by SH reagents, DIDS and trypsin. IOV's proved to have the same permeability of their lipid domain to erythritol as native erythrocytes, in contrast to resealed ghosts (Klonk, S. and Deuticke, B. (1992) Biochim. Biophys. Acta 1106, 126-136 (Part I in this series)), which have a residual leak. On the other hand, IOV's have a slightly elevated permeability for mannitol and sucrose, nonelectrolytes which are almost (mannitol) or fully (sucrose) impermeant in the native membrane. These increased fluxes, which have a high activation energy and can be stimulated by phloretin, are, however, also much smaller than the corresponding leak fluxes observed in resealed ghosts. In view of these differences, formation of IOV's can be concluded to go along with partial annealing of barrier defects persisting in the erythrocyte membrane after preparation of resealed ghosts. Oxidation of SH groups of the IOV membrane by diamide produces an enhancement of permeability for hydrophilic nonelectrolytes which is much less pronounced than that induced by a similar treatment of erythrocytes or ghosts (Klonk, S. and Deuticke, B. (1992) Biochim. Biophys. Acta 1106, 126-136 (Part I in this series)). Moreover, proteolytic treatment of the vesicle membrane, although leading to a marked digestion of integral membrane proteins, only induces a minor, saturating increase of permeability, much lower than that in trypsinized resealed ghosts (Klonk, S. and Deuticke, B. (1992) Biochim. Biophys. Acta 1106, 137-142 (Part II of this series)). Since absence of the cytoskeletal proteins, spectrin and actin, is the major difference between IOV's and resealed ghosts, these results may be taken as further evidence for a dependence of the barrier properties of the erythrocyte membrane bilayer domain on its interaction with cytoskeletal elements. In contrast, these barrier properties seem to be rather insensitive to perturbations of integral proteins.     

Identification of the Cl− transport site of human red blood cells by a kinetic analysis of the inhibitory effects of a chemical probe

H₂DIDS, the dihydro analog of DIDS (4,4′-diisothiocyanostilbene-2,2′-disulfonic acid) can interact covalently with membrane sites, resulting in an irreversible inhibition of anion exchange. At low temperatures (0°C) and for relatively short times, however, its interaction is largely reversible, so that a kinetic analysis of the nature of its inhibitory effect on Cl^? self exchange can be performed. The effects of variations in the chloride concentration on the inhibitory potency of H₂DIDS are consistent with the concept that Cl^? and H₂DIDS compete for the transport site of the anion exchange system. The value of K_i for H₂DIDS is 0.046 μM, indicating that H₂DIDS has a higher affinity for the transport system than any other inhibitor so far examined. If, as seems probable, the covalent labelling of H₂DIDS occurs at the same site as the reversible binding, H₂DIDS can be used as a covalent label for the transport site. The specific localization of H₂DIDS in the band-3 protein thus indicates that this protein participates directly in anion exchange.