Cellular fractionation and isolation of the plasma membrane of Burkitt's lymphoma cells

A procedure for cellular fractionation and preparation of plasma membrane from a Burkitt's lymphoma cell line is described. This procedure involves homogenization with a Polytron in buffered isotonic sucrose, and separation of cellular fractions by differential and isopycnic centrifugation in sucrose. The isolated plasma membrane fraction contains 44% of the cellular cholesterol, 50% of the ouabain-sensitive (Na⁺ + K⁺)-ATPase activity, 43% of the γ-glutamyltranspeptidase activities and 16% of the phospholipid. This fraction contains only 3% of cellular protein and is contaminated with less than 4% of the total cellular activities of microsomal, lysosomal, mitochondrial, Golgi and soluble marker enzymes. The cholesterol : phospholipid molar ratio of the crude plasma membrane is 0.56. The membranes in this fraction are in the form of vesicles. Further purification of plasma membrane is achieved by sucrose density gradient centrifugation and results in a 25- to 30-fold enrichment of plasma membrane markers. Plasma membrane markers band in these gradients between 1.10 and 1.15 g/cm³.The distribution patterns in the cell fractions of 18 cellular constituents are quantitatively determined. Most constituents are found to distribute in a fashion consistent with the results obtained in other systems. Thymidine-5′-phosphodiesterase (phosphodiesterase I), esterase, nucleoside diphosphatase and glucose-6-phosphatase, however, are shown to be poor markers of membrane fractions in this system.Lactoperoxidase-catalyzed iodination was used to identify several plasma membrane proteins which are exposed at the surface. After separation of labeled polypeptides by sodium dodecyl sulfate gel electrophoresis, the predominant labeled protein was identified as the heavy chain of IgM. Several lesser labeled proteins were observed.     

Giant plasma membrane vesicles to study plasma membrane structure and dynamics

The plasma membrane (PM) is a highly heterogenous structure intertwined with the cortical actin cytoskeleton and extracellular matrix. This complex architecture makes it difficult to study the processes taking place at the PM. Model membrane systems that are simple mimics of the PM overcome this bottleneck and allow us to study the biophysical principles underlying the processes at the PM. Among them, cell-derived giant plasma membrane vesicles (GPMVs) are considered the most physiologically relevant system, retaining the compositional complexity of the PM to a large extent. GPMVs have become a key tool in membrane research in the last few years. In this review, I will provide a brief overview of this system, summarize recent applications and discuss the limitations.     

Mechanical forces used for cell fractionation can create hybrid membrane vesicles

The ability to understand the inner works of the cell requires methods for separation of intracellular membrane-enclosed compartments. Disruption of the plasma membrane (PM) by mechanical forces to investigate the content of the cell is common practice. Whether vesicles or membranes of different sources can fuse as a result is unclear. If such contamination occurs, conclusions based on these techniques should consider these. Utilizing an endoplasmic reticulum (ER) membrane marker and a PM marker, we were able to detect the source of membranes following the breakup of cells using flow cytometry and immuno Electron Microscopy (immuno EM). Fractionation processes produced a small fraction of new membrane entities from two distinctively different origins generated during the initial disruption steps in a temperature independent manner, stressing that defining organelles or intrinsic fusion events based on such procedures and markers are valid when exceeding the small number of vesicles fused during the fractionation process.     

ATP-dependent transport for glucuronides in canalicular plasma membrane vesicles

Using rat liver canalicular plasma membrane vesicles, it has been verified that the transport of p-nitrophenyl glucuronide (NPG) across membranes is an ATP-dependent process; the apparent Km for NPG was 20 microM. S-(2,4-dinitrophenyl)-glutathione (DNP-SG) inhibited NPG uptake dose-dependently, and NPG or testosterone glucuronide did ATP-dependent DNP-SG uptake similarly. These results suggest that transport of glucuronide is mediated by an ATP-dependent glutathione S-conjugate carrier.     

Plasma fractionation by dead-end membrane filtration: effects of membrane properties and plasma flux

Plasma fractionation by membrane filtration permits the reinfusion of the patient with his own albumin. In this study, the influence of membrane nature and plasma flux on plasma fractionation in dead-end mode is investigated with acetate hollow fiber filters. It is found that transmembrane pressure TMP rises exponentially with time, the rate of increase being proportional to plasma flux. The faster TMP rises, the faster the drop in sieving coefficient SC. It is also found that albumin SC is a function of TMP and not of plasma flux. Theoretical analysis of the dead-end filtration was performed. This theoretical model indicates that the observed variation of TMP with time is consistent with the assumptions that pore volume decreases proportionally to the filtrate plasma volume.     

Preparation and fractionation of membrane vesicles of thymocytes after osmotic cell disruption

The isolation of plasma membranes is often accompanied with a loss of sensitivity to stimulatory agents (e.g. mitogens). Changes in the structure of the cell membranes after cell breakage have also been reported. Concerning this problem, "mild" cell disruption conditions were tested by using osmotic shock. Different membrane fractions were isolated, resulting in an enrichment of plasma membranes in one fraction. All fractions were characterized by plasma membrane marker enzymes (alkaline phosphatase, gamma-glutamyltransferases), the amount of cholesterol, the molar ratio of cholesterol and phospholipid, by dodecyl sulfate-gelectrophoresis and by electronmicroscopy. Total balance sheets of the fraction were made for each of the different biochemical parameters. The enriched plasma membranes resulting by using the described method had also lost the sensitivity to the stimulatory effect caused by mitogens such as Concanavalin A.     

Sealed inside-out and right-side-out plasma membrane vesicles : optimal conditions for formation and separation

Plasma membrane preparations of high purity (about 95%) are easily obtained by partitioning in aqueous polymer two-phase systems. These preparations, however, mainly contain sealed right-side-out (apoplastic side out) vesicles. Part of these vesicles have been turned inside-out by freezing and thawing, and sealed inside-out and right-side-out vesicles subsequently separated by repeating the phase partition step. Increasing the KCI concentration in the freeze/thaw medium as well as increasing the number of freeze/thaw cycles significantly increased the yield of inside-out vesicles. At optimal conditions, 15 to 25% of total plasma membrane protein was recovered as inside-out vesicles, corresponding to 5 to 10 milligrams of protein from 500 grams of sugar beet (Beta vulgaris L.) leaves. Based on enzyme latency, trypsin inhibition of NADH-cytochrome c reductase, and H⁺ pumping capacity, a cross-contamination of about 20% between the two fractions of oppositely oriented vesicles was estimated. Thus, preparations containing about 80% inside-out and 80% right-side-out vesicles, respectively, were obtained. ATPase activity and H⁺ pumping were both completely inhibited by vanadate (K_i ≈ 10 micromolar), indicating that the fractions were completely free from nonplasma membrane ATPases. Furthermore, the polypeptide patterns of the two fractions were close to identical, which shows that the vesicles differed in sidedness only. Thus, preparations of both inside-out and right-side-out plasma membrane vesicles are now available. This permits studies on transport, signal transduction mechanisms, enzyme topology, etc., using plasma membrane vesicles of either orientation.     

Comparative lipid analysis of purified plasma membranes and shed extracellular membrane vesicles from normal murine thymocytes and leukemic GRSL cells

The lipid fluidity in purified plasma membranes (PM) of murine leukemic GRSL cells, as measured by fluorescence polarization, is much higher than in PM of normal thymocytes. This was found to be due to relatively low contents of cholesterol and sphingomyelin and a high amount of unsaturated fatty acyl chains, especially linoleic acid, in the phospholipids. PM from GRSL cells contain markedly more phosphatidylethanolamine than those from thymocytes. For both GRSL cells and thymocytes the detailed lipid composition of isolated PM was compared with that of the corresponding shed extracellular membranes (ECM), which were isolated from the ascites fluid and from thymus cell suspensions, respectively. The somewhat decreased lipid fluidity of thymocyte ECM as compared to their PM, can be ascribed to the increased cholesterol/phospholipid molar ratio (0.88 vs. 0.74). No other major differences were found between the lipid composition of these membranes. In contrast, significant differences were found between PM and ECM from GRSL cells. In this system a much lower lipid fluidity of the shed ECM was found, due to the much increased cholesterol/phospholipid molar ratio (3.5-fold) and sphingomyelin (9-fold) content, as compared to the PM. Further, the ECM contain relatively more lysophosphatidylethanolamine and less phosphatidylcholine and -inositol. ECM contain a higher amount of polyunsaturated fatty acids, especially in the phosphatidylethanolamine and lysophosphatidylethanolamine classes. On the other hand, the fatty acids of phosphatidylcholine and lysophosphatidylcholine are more saturated than in PM. In particular, ECM of GRSL cells contain less oleic and linoleic acid residues and more arachidonic acid and 22:polyunsaturated fatty acid residues than PM. The possible relevance of these differences with respect to the mechanism of shedding of vesicles from the cell surface, is discussed.     

L-glutamate transport in renal plasma membrane vesicles

Summary This review describes the uptake of L-glutamate by well-characterized preparations of renal brush border (luminal) and baso-lateral membrane vesicles derived from the plasma membrane of the polar proximal tubular cell. L-glutamate is taken up against its concentration gradient, from both sides, by co-transport systems in which the movement of the amino acid into the cell is coupled to the influx of Na⁺ and efflux of K⁺ down their respective electrochemical gradients. The presence of these ion gradient-energized systems, specific for L-glutamate, may account for the exceedingly high intracellular concentration of this metabolically important amino acid in the renal tubule.     

Calcium uptake by placental plasma membrane vesicles

The Placental plasma membrane vesicles are capable of accumulating up to 190 mM Ca²⁺. This is 24-fold higher than the external Ca²⁺ concentration.This process is dependent on ATP hydrolysis by the placental Ca²⁺-ATPase.The $\text{P}{}_{\mathrm{i}}\text{Ca}$ ratio is dependent on the external Ca²⁺ concentration, and reaches the value of 2 at 10 mM Ca²⁺.Phosphate (5 mM) can double Ca²⁺ uptake when measured in the presence of 5 mM Ca²⁺.Mg²⁺; increased Ca²⁺ uptake only at low Ca²⁺ concentrations, and had no significant effect at 5 mM Ca²⁺.     

Calcium regulation by lens plasma membrane vesicles

The role of the plasma membrane in the regulation of lens fiber cell cytosolic Ca2+ concentration has been examined using a vesicular preparation derived from calf lenses. Calcium accumulation by these vesicles was ATP dependent, and was releasable by the ionophore A23187, indicating that calcium was transported into a vesicular space. Calcium accumulation was stimulated by Ca2+ (K1/2 = 0.08 microM Ca2+) potassium (maximally at 50 mM K+), and cAMP-dependent protein kinase; it was inhibited by both vanadate (IC50 = 5 microM) and the calmodulin inhibitor R24571 (IC50 = 5 microM), indicating that this pump was plasma-membrane derived and likely calmodulin dependent. Valinomycin, in the presence of K+, stimulated calcium uptake, suggesting that the calcium pump either countertransports K+, or is regulated in an electrogenic fashion. Inhibition of calcium uptake by selenite and p-chloromercuribenzoate demonstrates the presence of an essential -SH group(s) in this enzyme. Calcium release from calcium-filled lens vesicles was enhanced by Na+, demonstrating that these vesicles also contain a Na:Ca exchange carrier. p-Chloromercuribenzoate and p-chloromercuribenzoate sulfonic acid also promoted calcium release from calcium-filled vesicles, suggesting that this release, like calcium uptake, is in part mediated by a cysteine-containing protein. We conclude that lens fiber cell cytosolic Ca2+ concentration could be regulated by a number of plasma membrane processes. The sensitivity of both calcium uptake and release to -SH reagents has implications in lens cataract formation, where oxidation of lens proteins has been proposed to account for the elevated cytosolic Ca2+ in this condition.     

Elucidating membrane structure and protein behavior using giant plasma membrane vesicles

The observation of phase separation in intact plasma membranes isolated from live cells is a breakthrough for research into eukaryotic membrane lateral heterogeneity, specifically in the context of membrane rafts. These observations are made in giant plasma membrane vesicles (GPMVs), which can be isolated by chemical vesiculants from a variety of cell types and microscopically observed using basic reagents and equipment available in any cell biology laboratory. Microscopic phase separation is detectable by fluorescent labeling, followed by cooling of the membranes below their miscibility phase transition temperature. This protocol describes the methods to prepare and isolate the vesicles, equipment to observe them under temperature-controlled conditions and three examples of fluorescence analysis: (i) fluorescence spectroscopy with an environment-sensitive dye (laurdan); (ii) two-photon microscopy of the same dye; and (iii) quantitative confocal microscopy to determine component partitioning between raft and nonraft phases. GPMV preparation and isolation, including fluorescent labeling and observation, can be accomplished within 4 h.     

Improved isolation procedures for the purple membrane of Halobacterium halobium.

Techniques for purifying teh purple membrane of Halobacterium halobium are given. This purple membrane contains a chromoprotein with a retinal prosthetic group similar to rhodopsin, the chromprotein found in the visual systems of higher invertebrates and vertebrates. The described purple membrane isolation procedures yield a highly purified preparation as determined by transmitting electron microscopy and gel electrophoresis. Critical analysis of the absorption spectra of the purple membrane was also employed to establish criteria of purity for the preparation. The visible absorption spectra of the purified purple membrane preparation in buffer was found to have a maximum at 559 nm which shifted to 567 nm on light exposure. No indication of any spectral perturbation arising from bacterioruberin-containing membrane, the major contaminant in purple membrane preparations, was found. Furthermore, the ratio of protein aromatic amino acid absorbance at 280 nm to chromophore absorbance at 567 nm was found to be 1.5 in light-exposed preparations compared to the previously reported ratio of 2.3.-3 The decrease in the value of this ratio is also indicative of an increase in the purity of the purple membrane preparation.     

The outer membrane of yeast mitochondria: isolation of outside-out sealed vesicles

The yeast mitochondrial outer membrane was isolated and 10 of its major polypeptides were identified (mol. wts. 109, 70, 57, 45, 45, 42, 33, 29, 25 and 14 kd). The membrane has no major polypeptide in common with either mitochondrial inner membrane or rough microsomes. Protease treatment and immunochemical techniques showed that virtually all of the isolated outer membrane vesicles are sealed and display the same surface orientation as in the intact mitochondrion.