Binding of sodium dodecyl sulphate to an integral membrane protein and to a water-soluble enzyme. Determination by molecular-sieve chromatography with flow scintillation detection.

We have determined the binding of sodium dodecyl sulphate (SDS) to the human red cell glucose transporter (polypeptide, Mr 54,117) and to a water-soluble enzyme, N-5'-phosphoribosylanthranilate isomerase-indole-3-glycerol-phosphate synthase (PRAI-IGPS) from Escherichia coli (Mr 49,484). [35S]SDS was equilibrated with each protein on molecular-sieve chromatography at a series of SDS concentrations. The binding ratios of SDS to protein were determined by flow scintillation detection and automated amino acid analyses. Unexpectedly the glucose transporter, which is a transmembrane protein, bound about the same amount of SDS per gram of protein as did the enzyme. At 1.6 mM SDS, slightly below the critical micelle concentration (CMC) (1.8 mM) in the eluent, the binding ratio was 1.6 g SDS/g protein for both the glucose transporter and PRAI-IGPS. At 2.0 mM SDS (above the CMC) the glucose transporter showed a binding ratio of 1.7 g SDS/g protein. The corresponding value for the enzyme was about 1.5 g/g. The SDS-glucose transporter complex seems to be more compact than the SDS-enzyme complex as judged by molecular-sieve chromatography and by SDS-polyacrylamide gel electrophoresis. Recent neutron scattering results have shown a protein-decorated triple-micelle structure for the SDS-PRAI-IGPS complex. Hypothetically, the more compact SDS-glucose transporter complex may therefore consist of a dual-micelle structure. The molecular-sieve gel beads bound considerable amounts of SDS. The SDS binding to the gel matrix and to the proteins increased with increasing SDS concentration up to at least 1.6-2.0 mM SDS. In the case of the water-soluble enzyme a shoulder was observed in the binding curve at 1 mM SDS, probably reflecting a change in the conformation of the complex.

Lipid-vesicle-surface chromatography.

Egg-yolk phospholipid vesicles (liposomes) containing stearylamine cations or phosphatidylserine anions, were formed and entrapped in agarose gel beads (Sepharose 6B) by a dialysis procedure. On a column of entrapped phospholipid-stearylamine (4:1) (cationic) vesicles, 0.36 mg of ferritin was bound per mumol lipids at 0.05 M ionic strength and pH 7. About 30% of the vesicle surface thus became covered with ferritin. Only 0.04 mg of citraconylated myoglobin was bound per mumol lipids, as myoglobin is much smaller than ferritin. Haeme groups were readily inserted into the lipid bilayers. An excess amount of bovine serum albumin (BSA) or ribonuclease A was applied to entrapped ionic vesicles and the bound proteins were eluted by increasing the ionic strength from 0.01 to 0.2 or 0.5 M. After three to five runs, 82-88% of the vesicles (the phospholipids) remained entrapped. The capacity of the cationic vesicle-column for BSA decreased more than did the amount of entrapped vesicles, which indicates a preferential loss of stearylamine. Ion-exchange experiments were done with human plasma and with BSA monomers and dimers on entrapped cationic vesicles. Plasma proteins could be separated. BSA dimers were eluted later than BSA monomers in a sodium chloride gradient and the separation was better than on DEAE-Sepharose. The contact area between the protein and the vesicle surface is important for the binding strength. Protein-vesicle surface interactions can be studied by chromatography on entrapped vesicles.

Entrapment of lipid vesicles and membrane protein-lipid vesicles in gel bead pores.

Phospholipid vesicles were entrapped in gel beads of Sepharose 6B and Sephacryl S-1000 during vesicle preparation by dialysis. Egg-yolk phospholipids solubilized with cholate or octyl glucoside were dialysed together with gel beads for 2.5 days in a flat dialysis bag. Some vesicles were formed in gel bead pores and vesicles of sufficient size became trapped. Red cell membrane protein-phospholipid vesicles could be immobilized in the same way. Non-trapped vesicles were carefully removed by chromatographic procedures and by centrifugation. The amount of entrapped vesicles increased with the initial lipid concentration and was dependent on the relative sizes of vesicles and gel pores. The largest amount of trapped vesicles, corresponding to 9.5 mumol of phospholipids per ml gel, was achieved when Sepharose 6B gel beads were dialysed with cholate-solubilized lipids at a concentration of 50 mM. In this case the vesicles had an average diameter of 60 nm and an internal volume of 15 microliters/ml gel. The amount of vesicles trapped in Sephacryl S-1000 gel beads upon dialysis under the same conditions was smaller: 2.2 mumol of phospholipids per ml gel. Probably most of the gel pores were too large to trap such vesicles. Larger vesicles, with an average diameter of 230 nm, were entrapped in the Sephacryl S-1000 matrix in an amount corresponding to 3.0 mumol phospholipids per ml gel upon dialysis of the gel beads and octyl glucoside-solubilized lipids at a concentration of 20 mM. The internal volume of these vesicles was 22 microliters/ml gel. The yield of immobilized phospholipids was up to 19%. The entrapped vesicles were somewhat unstable: 9% of the phospholipids were released during 9 days of storage at 4 degrees C. By the dialysis entrapment method vesicles can be immobilized in the gel beads without using hydrophobic ligands or covalent coupling.

Immobilization of phospholipid vesicles and protein-lipid vesicles containing red cell membrane proteins on octyl derivatives of large-pore gels.

For improved immobilization of phospholipid vesicles and protein-lipid vesicles (cf. Sandberg, M., Lundahl, P., Greijer, E. and Belew, M. (1987) Biochim. Biophys. Acta 924, 185-192) and for chromatographic experiments with vesicles containing membrane protein, we have prepared octyl sulfide derivatives of the large-pore gels Sephacryl S-1000 and Sepharose 2B with ligand concentrations up to 14 and 5 mumol/ml gel, respectively. The Sephacryl derivatives allowed higher flow rates, gave higher rates of adsorption and showed equally high or higher capacities than the Sepharose adsorbents. 'Small', 'medium' and 'large' vesicles of radii approx. 20, 50 and 100 nm showed distribution coefficients on Sephacryl S-1000 of 0.7, 0.5 and 0.05, respectively and could be immobilized on octyl sulfide-Sephacryl S-1000 in amounts corresponding to 110, 40 and 20 mumol of phospholipids per ml gel, respectively. 'Small' vesicles became absorbed onto this gel at a rate of 1.5 mumol of phospholipids per min per ml gel until 60 mumol of phospholipids had become immobilized, whereas the initial adsorption rate was about 0.4 mumol.min-1.ml-1 on octyl sulfide-Sepharose 4B (see reference above) and on octyl sulfide-Sepharose 2B. Lower ligand concentrations gave lower capacities for 'small' vesicles. When vesicles entrapping calcein were immobilized on octyl sulfide-Sephacryl S-1000 some calcein was released during the adsorption process. For 'small' and 'medium' vesicles, respectively, the leakage was 75 and 25% at a ligand concentration of 14 mumol/ml but only 3 and 2% at 5 mumol/ml. The internal volumes of immobilized 'small' and 'medium' vesicles were estimated at 0.97 and 2.9 microliters per mumol of phospholipid by determination of entrapped calcein, which could indicate vesicle radii 20 and 50 nm, respectively. The total volumes of immobilized 'medium' lipid vesicles and 'medium' protein-lipid vesicles containing integral membrane proteins from human red cells, were estimated at 2.9 and 2.0 microliters/mumol, respectively, by chromatography of D- and L-[14C]glucose and calcein on the octyl sulfide-Sephacryl S-1000 column before and after immobilization. These volumes are roughly consistent with the internal volume of the vesicles. A zone of D-glucose eluted 90 microliters later than a zone of L-glucose on a 4- or 5-ml column of octyl sulfide-Sephacryl S-1000 with immobilized 'medium' protein-lipid vesicles containing the glucose transporter from human red cells, probably since part of the internal vesicle volume was accessible to the D-glucose but not to the L-glucose. This indicates that the glucose transporter was active in the immobilized vesicles.(ABSTRACT TRUNCATED AT 400 WORDS)