Membrane isolation on polylysine-coated glass beads. Asymmetry of bound membrane

Erythrocyte membranes isolated on polylysine-coated glass beads exhibit many of the properties of the native membrane. Gel electrophoresis indicates that all major protein components of the membrane are retained during membrane isolation. The membrane integrity and accessibility of selected components was tested using non-penetrating probes. In general, membranes on beads displayed accessibility properties typical of inside-out vesicles. The accessibility of membrane acetylcholinesterase to assay reagents, as well as membrane accessibility to the actions of neuraminidase, trypsin and galactose oxidase-NaB3H4 demonstrated that the protoplasmic surface of membrane isolated on beads was exposed, while the extracellular surface was inaccessible. The differential accessibility of the membrane surfaces demonstrates the feasibility of investigating asymmetry of membranes isolated on cationic glass beads.     

Isolation of human platelet plasma membranes with polylysine beads

Human platelet plasma membranes were isolated with polylysine beads according to the technique developed by Jacobson and Branton (1977, Science [Wash. D. C.] 195:302--304). Lactoperoxidase-catalyzed surface iodination revealed that ninefold greater 125I specific activity was associated with the membranes isolated on beads than with whole platelets. Enrichment in the bead membrane preparation of the activities of membrane marker enzymes, bis(p-nitrophenyl)phosphate phosphodiesterase and Na,K-ATPase, was 8.0 and 4.4, respectively. Contamination with enzymes of other organelles, cytochrome oxidase and beta-glucuronidase, was relatively low as compared with membranes isolated by sucrose gradient centrifugation. Analysis by SDS polyacrylamide gel electrophoresis showed that a full complement of surface glycoproteins was present on the membranes isolated with polylysine beads. The polylysine bead technique is a rapid, reproducible and efficient method for the preparation of relatively pure platelet plasma membranes.     

Plasma membrane isolation on DEAE-Sephadex beads

A much-simplified method for the purification of plasma membranes of cultured cells is presented, based upon the attachment of viable cells to nitrocellulose-treated DEAE-Sephadex beads, and their subsequent shearing by hypotonic lysis, agitation on a vortex mixer and sonication. The method is suggested by an older procedure involving attachment to poly-(L-lysine)-coated glass or polyacrylamide beads; the preparation involved in the present method, however, is considerably easier, more rapid and less expensive. Recovery of L-cell plasma membrane marker enzyme activities is approx. 25%, while contamination by internal membrane markers is much less than 1%.     

One-step isolation of plasma membrane proteins using magnetic beads with immobilized concanavalin A

We have developed a simple method for isolating and purifying plasma membrane proteins from various cell types. This one-step affinity-chromatography method uses the property of the lectin concanavalin A (ConA) and the technique of magnetic bead separation to obtain highly purified plasma membrane proteins from crude membrane preparations or cell lines. ConA is immobilized onto magnetic beads by binding biotinylated ConA to streptavidin magnetic beads. When these ConA magnetic beads were used to enrich plasma membranes from a crude membrane preparation, this procedure resulted in 3.7-fold enrichment of plasma membrane marker 5′-nucleotidase activity with 70% recovery of the activity in the crude membrane fraction of rat liver. In agreement with the results of 5′-nucleotidase activity, immunoblotting with antibodies specific for a rat liver plasma membrane protein, CEACAM1, indicated that CEACAM1 was enriched about threefold relative to that of the original membranes. In similar experiments, this method produced 13-fold enrichment of 5′-nucleotidase activity with 45% recovery of the activity from a total cell lysate of PC-3 cells and 7.1-fold enrichment of 5′-nucleotidase activity with 33% recovery of the activity from a total cell lysate of HeLa cells. These results suggest that this one-step purification method can be used to isolate total plasma membrane proteins from tissue or cells for the identification of membrane biomarkers.     

Improved method for isolation of plasma membrane on cationic beads. Membranes from Dictyostelium discoideum

The plasma membrane from Dictyostelium discoideum was routinely purified 35-fold by an improved technique using beads coated with positively charged polymers. Cells were attached to the beads and bare regions between the cells were neutralized with a polyanion. The neutralization decreased contamination of the bare regions by intracellular proteins released when cells were disrupted to leave behind beads coated by plasma membrane. The neutralization increased the purification as measured by membrane-bound ¹²⁵I-labeled concanavalin A. Contamination by markers for various intracellular components was markedly decreased. Various bare-site neutralization reagents were evaluated and gave different results depending upon their charge density and molecular weight. The pH of the neutralization was critical. The optimum pH for cell attachment to beads, 5.0, had little effect as regards bare-site neutralization. A new procedure is given that optimizes the essential features for the plasma membrane isolation on beads.     

Schistosoma mansoni: surface membrane isolation by polycationic beads

The Schistosoma mansoni surface membrane complex was isolated by binding polycationic beads to the worm surface in a sucrose- or sorbitol-acetate buffer, pH 5.0, at 4 C. The ratio of incorporation [3H]cholesterol/[14C]arachidonic acid was measured as well as the specific activities of the alkaline phosphatase (EC 3.1.3.1), Type I phosphodiesterase (EC 3.1.4.1), and Ca2+-adenosine triphosphatase (EC 3.6.1.3). The results indicated that membranes isolated on beads were of comparable or greater purity than membranes isolated by sucrose gradient centrifugation. The isolation procedure was rapid (30 min) and produced membrane fractions whose cytoplasmic surfaces were probably exposed.     

Improve method for isolation of rat liver plasma membrane

An improved method for the isolation of plasma membrane from rat liver is presented.Gentle homogenization of perfused livers in buffered isotonic KCI, followed by direct flotation of a low-speed nuclear pellet through a discontinuous sucrose density gradient results in a 32% yield, and 25-fold enrichment for the plasma membrane marker, phosphodiesterase I, in a crude plasma membrane fraction. This fraction contains less than 1% of the mitochondria, and endoplasmic reticulum present in the original homogenate, but is more heavily contaminated with lysosomes and Golgi membrane.Vigorous mechanical disruption of this material, followed by a second discontinuous sucrose density gradient, gives a light plasma membrane fraction with an 80-fold purification and 20% yield of phosphodiesterase I over the original homogete (with further reduction of contaminants).     

Membrane isolation on polylysine-coated beads. Plasma membrane from HeLa cells

HeLa cell plasma membranes have been purified after binding cells to polylysine-coated polyacrylamide beads. Cell attachment to beads and membrane recovery were maximal in a sucrose-acetate buffer, pH 5.0, at 25 degrees C. Measurements of ouabain-sensitive NaK-adenosine triphosphatase, membrane-bound 125I-wheat germ agglutinin, and chemical analyses showed that membranes on beads were of comparable or greater purity than membranes isolated by conventional methods. Because the isolation procedure is rapid (approximately 2.5 h), and produces membranes whose protoplasmic surfaces are fully exposed, it should be a useful supplement to standard isolation techniques.     

Application of polylysine bound succinyl-NA to a membrane reactor

The amide bond at N-6 in succinyl-NAD was found to be more stable than in former accounts. Succinyl-NAD was coupled on polylysine to give a new polymer derivative of NAD, which retained at least 85% of the initial coenzymic activity even after dialysis for one week. The polymer derivative of NAD could be applied to a membrane reactor containing alcohol dehydrogenase and lactate dehydrogenase and lactate was continuously produced in a half-life of ten days.     

Immunoaffinity purification of plasma membrane with secondary antibody superparamagnetic beads for proteomic analysis

Plasma membrane (PM) has very important roles in cell-cell interaction and signal transduction, and it has been extensively targeted for drug design. A major prerequisite for the analysis of PM proteome is the preparation of PM with high purity. Density gradient centrifugation has been commonly employed to isolate PM, but it often occurred with contamination of internal membrane. Here we describe a method for plasma membrane purification using second antibody superparamagnetic beads that combines subcellular fractionation and immunoisolation strategies. Four methods of immunoaffinity were compared, and the variation of crude plasma membrane (CPM), superparamagnetic beads, and antibodies was studied. The optimized method and the number of CPM, beads, and antibodies suitable for proteome analysis were obtained. The PM of mouse liver was enriched 3-fold in comparison with the density gradient centrifugation method, and contamination from mitochondria was reduced 2-fold. The PM protein bands were extracted and trypsin-digested, and the resulting peptides were resolved and characterized by MALDI-TOF-TOF and ESI-Q-TOF, respectively. Mascot software was used to analyze the data against IPI-mouse protein database. Nonredundant proteins (248) were identified, of which 67% are PM or PM-related proteins. No endoplasmic reticulum (ER) or nuclear proteins were identified according to the GO annotation in the optimized method. Our protocol represents a simple, economic, and reproducible tool for the proteomic characterization of liver plasma membrane.     

A two-phase polymer method for isolation of maturing goat sperm plasma membrane

An aqueous two-phase polymer method originally developed for the isolation of plasma membrane from mature goat epididymal spermatozoa (Rana, A.P.S. and Majumder, G.C., Prep. Biochem., 17, 261, 1987) has been found to be unsuitable for the maturing spermatozoa derived from caput and corpus epididymides because of significant contamination of the isolated membrane with intact cells. A modified method has been developed by manipulating the centrifugal force (required for membrane sedimentation) for the isolation of maturing sperm plasma membrane of high yield (approximately 55%) and purity as judged by marker enzyme assays and phase contrast and electron microscopic analyses. The method consists of treatment of intact spermatozoa with 1.25 mM EDTA, dispersion of these cells to a two-phase polymer system comprising 5.5% 252-Kd dextran and 4.2% 20-Kd polyethylene glycol compound and subsequent centrifugation at 12,000 X g for 30 min when the two phases separate out and membranes sediment at the interphase. The repeatation of the two-phase fractionation step yielded greater purity of the plasma membrane.     

The isolation of plasma membrane and characterisation of the plasma membrane ATPase from the yeast Candida albicans

Plasma membrane ghosts were isolated from Candida albicans ATCC 10261 yeast cells following stabilisation of spheroplasts with concanavalin A, osmotic lysis and Percoll density gradient centrifugation. Removal of extrinsic proteins with NaCl and methyl alpha-mannoside gave increased ATPase and chitin synthase specific activities in the resultant plasma membrane fraction. Sonication of this fraction yielded unilamellar plasma membrane vesicles which exhibited ATPase and chitin synthase specific activities of 4.5-fold and 3.0-fold, respectively, over those of the plasma membrane ghosts. ATPase activity in the membrane ghosts was optimal at pH 6.4, showed high substrate specificity (for Mg X ATP) and was inhibited 80% by sodium vanadate but less than 4% by oligomycin and azide. The effects of a range of other inhibitors were also characterised. Temperature effects of ATPase activity were marked, with a maximum at 35 degrees C. Breaks in the Arrhenius plot, at 12.2 degrees C and 28.9 degrees C, coincided with endothermic heat flow peaks detected by differential scanning calorimetry. ATPase was solubilised from the plasma membranes with Zwittergent in the presence of glycerol and phenylmethylsulphonyl fluoride and partially purified by glycerol density gradient centrifugation. The solubilised enzyme hydrolysed Mg X ATP at Vmax = 20 mumol X min-1 X mg-1 in the presence of phospholipids, with optimal activity at pH 6.0--6.5.     

Immobilization of hydrogenase on glass beads

Hydrogenase from $\text{Clostridium pasteurianum}$ was immobilized on glass beads by four different methods. The sensitivity of the native and bound enzyme to oxygen was examined. Hydrogenase bound to succinyl glass proved to be the most stable to oxygen. All bound enzymes were active with ferredoxin as a substrate and evolved hydrogen in a chloroplast-ferredoxin-hydrogenase system driven by light.     

Murine leukemic lymphoblasts: homogenization and fractionation procedures for plasma membrane vesicles isolation

Plasma membrane vesicles were isolated from murine leukemic lymphoblasts L5178Y. The isolation procedure selected involved a method of mechanical disruption in a hypoosmotic-buffered solution and the separation of plasma membrane vesicles by an adaptation of the fractionation method described by D. W. McKeel and L. Jarett for fat cells (J. Cell Biol., 44, 417, 1970). In order to select the homogenization method we took into account several parameters: the extent of cell and nuclear disruption, the integrity of the nuclear membrane, the 5′-nucleotidase activity recovered at the first step of fractionation and the mitochondrial rupture. The homogenization method finally used yielded 89% of cellular rupture with only 9% of nuclear damage. The isolation procedure showed an overall yield of 70–90%. A plasma membrane fraction was isolated with an enrichment in 5′-nucleotidase and ouabain-sensitive (Na⁺K⁺)-ATPase specific activities of 15- and 13-fold, respectively, and essentially free of mitochondrial, lysosomal, and endoplasmic reticulum contamination. The electron microscopy demonstrated that the plasma membrane fraction essentially consisted of smooth vesicles of several sizes.     

The isolation and characterisation of the plasma membrane fromHalobacterium salinarium

The plasma membrane ofHalobacterium salinarium, strain 1, has been isolated and characterised. A fraction containing cell envelope vesicles was isolated from a cell homogenate by centrifuging. A crude membrane fraction was obtained from the envelope fraction by dialysing it against distilled water, incubating with nucleases and centrifuging. A nucleotide-free purified membrane fraction, identified with the plasma membrane, was obtained by gel-filtration chromatography of the crude membrane fraction on Agarose. The nucleotide-free membrane-rich fraction contained all the cell lipid, including menaquinone and carotenoid, and cytochrome. No amino sugars could be detected. The action of the detergent, sodium dodecyl sulphate, on the nucleotide-free membrane-rich fraction broke up the membrane into smaller particles. The disaggregation occurred in at least two distinct steps. The disaggregated particles could be reaggregated to a fraction which resembled the original membrane by removing the detergent by dialysis or gel-filtration. A fraction which may be analogous to mitochondrial structural protein was isolated by ammonium sulphate fractionation of a preparation of the nucleotide-free membrane-rich fraction dissolved in a mixture of sodium deoxycholate, sodium cholate and sodium dodecyl sulphate. Protein fractions were separated from the nucleotide-free membrane-rich fraction during gel-filtration chromatography on Agarose in the presence of 6m urea. The authors would like to acknowledge the technical assistance of Miss C. Goode and Mrs. J. Wicks. We are indebted to Mrs. A. Flo of the Department of Biochemistry, The Technical University of Norway, Trondheim, for technical assistance in the preparation of samples for electron microscopy.