Purification of Plasma Membrane from Acanthamoeba castellanii1

A simple method for isolation of plasma membrane from Acanthamoeba using self-generating gradients of Percoll is described. To obtain a membrane marker, intact amoebae were radioiodinated and the distribution of the radiolabel was followed through the plasma membrane isolation procedure. The purity of isolated plasma membrane was assessed by enrichment of radiolabel, by electron microscopy, and by enzymatic assays for contaminating membranes. As judged from enrichment of radiolabel, a 37-fold purification of plasma membrane was obtained. We estimate that 80% of the total protein was from plasma membrane and 10% from membrane-associated actin.     

Isolation of plasma membranes from cultured glioma cells and application to evaluation of membrane sphingomyelin turnover

A rapid and reliable method for the isolation of plasma membranes and microsomes of high purity and yield from cultured glioma cells is described. The procedure involves disruption by N2 cavitation, preliminary separation by centrifugation in Tricine buffer, and final separation on a gradient formed from 40% Percoll at pH 9.3. Enzyme and chemical markers indicated greater than 60% yield with six- to eightfold enrichment for plasma membranes and greater than 25% yield with three- to fourfold enrichment for a microsomal fraction consisting mainly of endoplasmic reticulum. The final fractions were obtained with high reproducibility in less than 1 h from the time of cell harvesting. Application of this procedure to human fibroblasts in culture is assessed. The isolation procedure was applied to investigations of synthesis and turnover of sphingomyelin and phosphatidylcholine in plasma membranes of glioma cells following incubation for 4-24 h with [methyl-3H]choline. These studies indicated that radioactivity from phosphatidylcholine synthesized in microsomes from exogenous choline may serve as a precursor of the head-group of sphingomyelin accumulating in the plasma membrane.     

Preparation of glial plasma membrane from a cell fraction enriched in astrocytes

A technique for obtaining glial plasma membrane has been developed, starting with a bulk-prepared glial cell-enriched fraction from rabbit cerebral cortex. The astrocytic-enriched fraction was hand-homogenized in isotonic sucrose media, and the crude membrane fraction sedimented at 3,000g. The isolation of a membrane-enriched fraction was accomplished with sucrose density gradient centrifugation. The plasma membrane fraction was collected at the interphase between 31.5% and 25.5% sucrose. Enzymatic and electron-microscopical analyses indicated a 4–7-fold enrichment in plasma membrane, and a 15–20% contamination with microsomal and mitochondrial material. Some multilaminar membrane structures were also seen in the fraction.     

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).     

The isolation and subfractionation of plasma membrane from the cellular slime mould Dictyostelium discoideum

A procedure for the isolation and separation of three different subfractions of plasma membrane from the cellular slime mould Dictyostelium discoideum is described. The cells were disrupted by freeze-thawing in liquid N(2) and plasma membranes were purified by equilibrium centrifugation in a sucrose gradient. The cell surface was labelled with radioactive iodide by using the lactoperoxidase iodination method. Alkaline phosphatase was identified as a plasma-membrane marker by its co-distribution with [(125)I]iodide. 5'-Nucleotidase, which has been widely described as a plasma-membrane marker enzyme in mammalian tissues, was not localized to any marked extent in D. discoideum plasma membrane. The isolated plasma membranes showed a 24-fold enrichment of alkaline phosphatase specific activity relative to the homogenate and a yield of 50% of the total plasma membranes. Determination of succinate dehydrogenase and NADPH-cytochrome c reductase activities indicated that the preparation contained 2% of the total mitochondria and 3% of the endoplasmic reticulum. When the plasma-membrane preparation was further disrupted in a tight-fitting homogenizer, three plasma-membrane subfractions of different densities were obtained by isopycnic centrifugation. The enrichment of alkaline phosphatase was greatest in the subfraction with the lowest density. This fraction was enriched 36-fold relative to the homogenate and contained 19% of the total alkaline phosphatase activity but only 0.08% of the succinate dehydrogenase activity and 0.34% of the NADPH-cytochrome c reductase activity. Electron microscopy of this fraction showed it to consist of smooth membrane vesicles with no recognizable contaminants.     

Isolation of rat hepatocyte plasma membranes. I. Presence of the three major domains

A rat liver plasma membrane preparation was isolated and characterized both biochemically and morphologically. The isolation procedure was rapid, simple and effective in producing a membrane fraction with the following biochemical characteristics: approximately 40-fold enrichment in three plasma membrane markers, 5'-nucleotidase, alkaline phosphodiesterase I (both putative bile canalicular membrane enzymes), and the asialo-glycoprotein (ASGP) receptor (a membrane glycoprotein present along the sinusoidal front of hepatocytes); a yield of each of these plasma membrane markers that averaged approximately 16%; and minimal contamination by lysosomes, nuclei, and mitochondria, but persistent contamination by elements of the endoplasmic reticulum. Morphological analysis of the preparation revealed that all three major domains of the hepatocyte plasma membrane (sinusoidal, lateral, and bile canalicular) were present in substantial amounts. The identification of sinusoidal membrane was further confirmed when ASGP binding sites were localized predominantly to this membrane in the isolated PM using electron microscope autoradiography. By morphometry, the sinusoidal front membrane accounted for 47% of the total membrane in the preparation, whereas the lateral surface and bile canalicular membrane accounted for 6.8% and 23% respectively. This is the first report of such a large fraction of sinusoidal membrane in a liver plasma membrane preparation.     

The fate of an N-formylated chemotactic peptide in stimulated human granulocytes. Subcellular fractionation studies

Experiments were performed to examine how human granulocytes process the chemotactic peptide N-formyl-Met-Leu-Phe after stimulation by the same peptide. Purified human granulocytes were stimulated with 50 nM N-formyl-Met-Leu-[3H]Phe at 37 degrees C for various times, washed, lysed by N2 cavitation, and fractionated by isopycnic sucrose density gradient sedimentation. The major subcellular fractions identified were plasma membrane, Golgi, granules, endoplasmic reticulum, and mitochondria. After 1 min of stimulation, radioactivity was found only in the plasma membrane (sedimentable) and cytosol (soluble) fraction. At 5, 10, and 25 min, radioactivity also appeared in a sedimentable, low density fraction (25-28% sucrose) enriched in galactosyl transferase activity and containing Golgi structures. The accumulation in the sedimentable fractions was maximal after 5 min but continued to increase linearly in the cytosol fraction. Incorporation of radioactivity into cells or membrane and soluble fractions was 60 to 85% specific and was inhibited if incubation with N-formyl-Met-Leu-[3H]Phe was performed at 4 degrees C. 80-90% of the radiolabel in the plasma membrane or Golgi-containing fractions remained sedimentable despite freeze thawing or sonication. Solubilization of these fractions in Triton X-100 followed by Sepharose 4B column chromatography revealed that the radiolabel eluted in the void volume. Our results are consistent with internalization which proceeds by passage of an occupied receptor in a high affinity, supramolecular complex from the plasma membrane to the Golgi followed by accumulation of peptide in the cytosol.     

PREPARATION OF PLASMA MEMBRANE FROM ISOLATED NEURONS

A bulk fraction enriched with respect to neuronal cell bodies was used as starting material for the isolation of neuronal plasma membrane The cells were gently homogenized in isotonic sucrose and a crude membrane containing fraction sedimented at 3000 g. Subsequently, the membrane fraction was purified on a discontinuous sucrose density gradient between 35% and 25 5% sucrose (w/w). Enzymatic analyses showed a 4–5-fold enrichment in plasma membrane markers, and a 10–15% contamination of mitochondrial and microsomal material. Electron micrographs of the membrane fraction confirmed the enzymatic data Fragmented membranes were found, mainly in vesicular form No ribosomes, but a few mitochondria and some multilamellar membranes were seen     

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.     

Characterization of plasma membranes from A431 cells, isolated by self-generating Percoll gradient: a rapid isolation procedure to obtain plasma membranes with functional epidermal growth factor receptors

Plasma membranes have been isolated from the human epidermoid carcinoma cell line A431 by a rapid fractionation of lysate on Percoll density gradient at pH 9.6. Endoplasmic reticulum, lysosomes and mitochondria sedimented at the bottom of gradient whereas plasma membranes focused at low density, as shown with specific markers. Plasma membranes displayed a 4.5- and 4.4-fold enrichment in [3H]concanavalin A and 5'-nucleotidase, respectively. This proteic fraction was further characterized by its lipid composition and phospholipid analysis. The cholesterol/phospholipid molar ratio was 0.45 in plasma membranes against 0.19 in lysate. Sphingomyelin increased from 7.5% of total phospholipids in lysate to 16.2% in plasma membranes, as well as phosphatidylserine which displayed a 1.5-fold enrichment in the plasma membrane fraction. This was at the expense of phosphatidylcholine (45.2% in lysate, against 35% in plasma membranes). Electron microscopy of the isolated material showed vesicles essentially free from endoplasmic reticulum and organelles. These plasma membranes retained the ability to bind 125I-labelled epidermal growth factor (125I-EGF) with a Kd = 4.7 nM and Bmax = 63 pmol/mg protein. EGF binding resulted in a stimulation of the phosphorylation protein reaction in the presence of [gamma-32P]ATP and sodium dodecyl sulfate polyacrylamide gels of phosphorylated proteins indicated that the radioactivity of the major band of molecular weight 170,000 was clearly enhanced by EGF binding. These results indicate that the EGF receptor and its intrinsic protein kinase activity were preserved during our plasma membrane isolation procedure.     

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.     

Rapid isolation of neuroblastoma plasma membranes on Percoll gradients. Characterization and lipid composition

A purified plasma membrane fraction was isolated from cultured neuroblastoma (N1E-115) cells on a discontinuous gradient of 5, 25 and 35% Percoll within 1 h of cell disruption by nitrogen cavitation. Yield of plasma membrane, banding in the 25% Percoll (d = 1.051), was high as judged by the recoveries of the marker enzymes, 5'-nucleotidase (58.0 +/- 5.4%, n = 5), alkaline phosphatase (46.0 +/- 3.0%, n = 4) and Mg2+-stimulated neutral sphingomyelinase (48.0 +/- 4.2%, n = 3); enrichment of specific activities of these enzymes relative to total cell homogenate (lysate) were 10.9 +/- 1.0-, 9.1 +/- 1.0- and 9.6 +/- 0.4-fold, respectively. Levels of marker enzymes for other organelles were less than 3% of total activity, except for microsomes (less than 9%). The plasma membrane fraction was further characterized by 2-, 5- and 6-fold higher content (nmol/mg protein) of total phospholipids, free cholesterol and sphingomyelin, respectively, compared to lysate. Ratios of free cholesterol to phospholipids and of sphingomyelin to phosphatidylcholine in the plasma membrane fraction were about 2-fold greater than that of lysate. The cholesterol ester content of plasma membrane (36 +/- 8 nmol/mg protein) was 2-3-fold higher than that of lysate. Sphingomyelin of the plasma membrane fraction had a higher concentration of long-chain fatty acids (more than 18 carbon atoms) relative to lysate or microsomes. Significant differences also were observed in the fatty acyl composition of diphosphatidylglycerol, cholesterol esters and triacylglycerol of plasma membrane. Thus, we have devised a rapid and reliable method for isolation of highly purified plasma membranes of cultured neuroblastoma cells that is suitable for comparison of metabolic relationships between the plasma membrane and other cellular organelles.     

Isolation of domains of the plasma membrane of hepatocytes

Several recent studies have demonstrated the ability of techniques based on immunoadsorption to selectively isolate specialized subregions of membranes, termed domains, which are derived from a larger more complex parent membrane like the plasma membrane. The immunoadsorbent is directed against a specific antigen that resides exclusively or predominantly in the membrane domain to be isolated. Thus, a monospecific antibody to the domain-specific antigen is required. In the present study we developed a method employing a modified immunoblotting strategy which could utilize polyspecific antibodies to isolate membrane vesicles derived from a specific membrane domain of the hepatocyte plasma membrane. We also used specific cell surface labeling of the hepatocyte plasma membrane by lactoperoxidase-catalyzed iodination at 4 degrees C and preparation of different sized vesicles by sonication to facilitate isolation of the specific domain. For this study, polyspecific antisera were raised in goats against a membrane fraction, denoted N2u, which is enriched in bile canalicular proteins. This antiserum recognizes, among other antigens, a 110,000 Mr polypeptide previously shown to be localized in the bile canaliculus (J. Cook et al. (1983) J. Cell. Biol. 97, 1823-1833). A monospecific antiserum was raised in rabbits against the rat hepatocyte asialoglycoprotein receptor, a sinusoidal domain-specific set of glycoproteins whose major form has a Mr of 43,000. These antisera were each coupled indirectly to different pieces of nitrocellulose by the immunoblotting protocol and were used to isolate membrane vesicles from a crude extract of liver plasma membrane prepared by sonication. The ratio of iodinated asialoglycoprotein receptor to the 110,000 Mr polypeptide in vesicles isolated by the affinity nitrocellulose immunoadsorbent method indicate a 10- to 15-fold enrichment of sinusoidal-derived vesicles relative to bile canalicular-derived membrane vesicles. These results show that the affinity nitrocellulose immunoadsorbent method can be used to isolate domain-specific vesicles. Further, the affinity immunoadsorbent method described here for the isolation of domains of the plasma membrane is an integrative one allowing isolation of vesicles present in relatively small concentration in crude cell extracts and it requires minimal ultracentrifugation time.     

Isolation of the plasma membrane and organelles from Chinese hamster ovary cells.

Two methods are described enabling the plasma membrane from Chinese hamster ovary (CHO) cells to be obtained rapidly, relatively pure and with a good yield. In both cases, cells were disrupted by nitrogen cavitation in an isoosmotic buffer either at pH 5.4 or at pH 7.4. In the first approach, cells were lysed at pH 7.4 and the plasma membrane and cell organelles were isolated on a self-generated gradient of Percoll, at neutral pH. Mitochondria and endoplasmic reticulum were recovered in the denser fractions, plasma membrane fragments were found in the lighter fractions, but always contaminated by lysosomes. Because lysosomes were found to sediment in acidic conditions, cells were lysed at pH 5.4 and presedimentation (1500 x g) of the cell homogenate at the same pH enabled more than 80% of the lysosomes to be removed. Then, ultracentrifugation of the supernatant over a Percoll gradient at neutral pH yielded plasma membrane fractions practically free of lysosomes with an enrichment ratio of 3 and fractions of mitochondria and endoplasmic reticulum with enrichment ratios of 17 and 6, respectively. A major problem was encountered in the final step of elimination of Percoll from the purified plasma membrane fractions. Whatever the technique used for eliminating Percoll, plasma membranes were observed to be contaminated by a Percoll constituent which prevented further purification and biochemical identification of the lipids extracted from these membrane fractions to be carried out. A second method of plasma membrane preparation was tested consisting first in the coating of the cell surface with positive colloidal silica which was stabilized by an anionic polymer. Then, and through differential centrifugations, plasma membrane fractions were easily obtained within less than 1 h, with a yield of 65% and an enrichment ratio of 7. The coating pellicle was quantitatively removed thus enabling any biochemical manipulation of the plasma membrane to be carried out. The lipids present in the plasma membrane of CHO cells were analyzed and are described, both in terms of headgroup and acyl chain composition.     

Rapid, high-yield purification of cell surface membrane using colloidal magnetite coated with polyvinylamine: sedimentation versus magnetic isolation

A new technique for the magnetic isolation of external plasma membrane from Dictyostelium discoideum is described and compared to a previously published procedure employing sedimentation of silica-coated plasma membrane. The magnetic isolation technique involves coating intact cells with a polyvinylamine-magnetite colloid and overcoating with polyacrylate to form a dense pellicle. The magnetite pellicle totally coated the cells and was not internalized. Coated cells were lysed and membrane fragments retrieved from the cell homogenate using a diverging field electromagnet. The membrane obtained in such a manner was analyzed for marker enzyme activity and cell surface label. The plasma membrane was obtained in high yield (42%) with an average purification of 8-fold. The polyvinylamine-magnetite pellicle shielded the external plasma membrane face to proteolysis by papain and pronase. It also acted as a barrier to alpha-methylmannoside in concanavalin A-carbohydrate competition studies.     

Evaluation of the silica microbead method for isolation of red beet protoplast plasma membrane sheets

The silica microbead procedure was utilized for the isolation of plasma membrane sheets from protoplasts of a higher plant, the red beet (Beta vulgaris L.). Membrane yields, as determined by recovery of an exogenous membrane marker were approx. 75%. The plasma membrane fraction contained the enzyme marker, pH 6.5, vanadate-sensitive, K+-stimulated, Mg2+-ATPase and small amounts of mitochondria, endoplasmic reticulum, and possibly tonoplast. The silica microbead procedure was also used for the isolation of intact vacuoles from microbead-coated protoplasts.     

两相分配法制备南极红酵母质膜

用葡聚糖 T-500(Dextran T-500)和聚乙二醇(PEG-3350)两相体系制备南极红酵母(Rhodotorula sp.)菌株 NJ298 的质膜.首先在 2 mmol/L KCl 浓度下,选用5种不同的聚合物浓度(5.6%、5.8%、6.0%、6.2%、6.4%,W/W),研究了 NJ298 质膜在两相体系中的分配情况,在此基础上进一步研究了 KCl 浓度(2 mmol/L、4 mmol/L、6 mmol/L、8 mmol/L、10 mmol/L)对 NJ298 质膜的纯度及得率的影响.结果表明,选用6.0%聚合物浓度,4 mmol/LKCl 的两相分配体系,分离3次可得到相对纯度在 78.2%的南极红酵母质膜组分,标志酶鉴定及磷钨酸染色电镜检测均表明获得了高纯度密实的正向型的质膜囊泡.这为进一步研究该菌株的南极极端环境适应机制奠定了基础.     

Generation of a mouse sperm membrane fraction with zona receptor activity.

To identify mouse sperm components involved in primary sperm binding to zonae pellucidae, a mouse sperm plasma membrane-enriched fraction was generated using a vortex method. The crude membrane fraction recovered after vortexing was resolved into three bands and a pellet by centrifugation on a discontinuous sucrose gradient. Ultrastructural analysis indicated that Bands 2 and 3 were composed predominantly of membranes, although Band 3 was contaminated with mitochondria; Band 1 and the gradient pellet contained insufficient material and were unsuitable for ultrastructural analysis. To determine where plasma membranes migrate in the gradient, sperm were labeled vectorially with 125I; subsequently, membrane fractions were analyzed by SDS-PAGE and autoradiography. Band 2 was enriched threefold in radiolabel when compared with Band 3. Examination of intact and vortexed sperm stained with regionally distributed anti-mouse sperm monoclonal antibodies revealed that vortexing removed anterior head plasma membrane preferentially. Bioactivity, defined as the ability to inhibit primary sperm binding to the zona pellucida in a concentration-dependent manner, was contained in the crude membrane fraction and Band 2 exclusively, with inhibition of 53% and 44%, respectively, at the maximum concentration tested. Band 3 exhibited no significant bioactivity. We conclude from these results that a plasma membrane-enriched fraction, Band 2, isolated from mouse cauda epididymal sperm, exhibits zona pellucida receptor activity.     

两相分配法制备南极红酵母质膜

用葡聚糖T-500(Dextran T-500)和聚乙二醇(PEG-3350)两相体系制备南极红酵母(Rhodotorula sp.)菌株 NJ298的质膜。首先在2 mmol/L KCl浓度下, 选用5种不同的聚合物浓度(5.6%、5.8%、6.0%、6.2%、6.4 %, W/W), 研究了NJ298质膜在两相体系中的分配情况, 在此基础上进一步研究了KCl浓度(2 mmol/L、4 mmol/L、6 mmol/L、8 mmol/L、10 mmol/L)对NJ298质膜的纯度及得率的影响。结果表明, 选用6.0%聚合物浓度, 4 mmol/L KCl的两相分配体系, 分离3次可得到相对纯度在78.2%的南极红酵母质膜组分, 标志酶鉴定及磷钨酸染色电镜检测均表明获得了高纯度密实的正向型的质膜囊泡。这为进一步研究该菌株的南极极端环境适应机制奠定了基础。     

Preparation of a human lung purified plasma membrane fraction: Confirmation by enzyme markers,electron microscopy,and histamine H1 receptor binding

Summary A simple and rapid method of isolating plasma membranes from human peripheral lung tissue is described. The method involves homogenization of tissue in 0.25m sucrose-buffered medium followed by differential and sucrose density gradient centrifugation. Enzymatic and morphological characterization of the plasma membrane fraction revealed minimal contamination by nonplasma membrane fragments. The isolated plasma membranes showed an 18-fold purification of 5-nucleotidase activity compared to the original homogenate. Electronmicroscopic studies of the plasma membrane fraction revealed the presence of small membrane vesicles having a trilaminar membrane structure. To further examine the purity of the plasma membrane preparation, the binding of the H₁ receptor antagonist,³H pyrilamine, to the plasma membrane-enriched fraction was compared to the binding to crude membrane preparations. Both the plasma membrane-enriched fraction and the crude membrane preparation had similar K_d's for the histamine antagonist, but the plasma membrane-enriched fraction had a threefold greater binding capacity, reflecting the relative enrichment of plasma membranes of the preparation. Thus, a method has been developed for the isolation of plasma membranes from human peripheral lung which should provide material for a variety of biochemical and pharmacological studies.