Plasma membrane heterogeneity in ascites tumor cells. Isolation of a light and a heavy membrane fraction of the glycogen-free Ehrlich-Lettré substrain

In this work we report on the isolation of two plasma membrane fractions of a glycogen-free substrain of Ehrlich-Lettré ascites cells, a light fraction sedimenting in a sucrose gradient at 1.10 g/ml, and a heavy fraction sedimenting at nuclei by a combination of short-term swelling and mild Dounce homogenization. A 12 000 X g postnuclear pellet (PII) containing major portions of the plasma membrane marker enymes, 5'-nucleotidase, ouabain-sensitive (Na+ + K+)-ATPase and the alkaline phosphatase, was prepared by differential centrifugation. The two plasma membrane fractions were obtained by centrifugation on a discontinuous sucrose gradient, from which they were further purified on a linear sucrose gradient applying sedimentation velocity conditions only. Enrichment factors for the three marker enzymes were between 5- and 14-fold for the light fraction and between 3- and 7-fold for the heavy fraction with an overall yield of 1--4% and 0.5--1.7%, respectively, of cellular protein. Contamination of both fractions with nuclear material was minor. Mitochondrial contamination was about 8% for the light material and somewhat higher for the heavy material. In the light fraction, co-sedimentation of lysosomal and Golgi marker enzymes was detected. The presence of membrane structures of these organelles could not be confirmed definitely by electron microscopy. Differences in sialic acid content and phospholipid composition within the two fractions, especially in the relative proportion of lecithin to sphingomyelin, suggests differences in membrane fluidity. The light material showed mostly unit membrane vesicles in thin-section and freeze-etch electron microscopy, whereas the heavy fraction mainly consisted of sheet-like membrane fragments.     

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.     

Plasmodium lophurae: Membrane Proteins of Erythrocyte-free Plasmodia and Malaria-Infected Red Cells*

SYNOPSIS. Plasma membranes of normal duckling erythrocytes were prepared by blender homogenization and nitrogen decompression. Surface membrane vesicles of red cells infected with the avian malaria Plasmodium lophurae were produced by nitrogen decompression. Membranes of erythrocyte-free malaria parasites were removed from cytoplasmic constituents by Dounce homogenization. These membranes were collected by centrifugation in a sucrose step gradient and purified on a linear sucrose gradient. Red cell membranes had a buoyant density of 1.159 g/cm³, whereas plasmodial membranes banded at 2 densities: 1.110 g/cm³ and 1.158 g/cm³. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the isolated red cell membranes revealed 7 major protein bands with molecular weights (MW) ranging from 230,000 to 22,000, and 3 glycoprotein bands with MW of 160,000, 88,000 and 37,000. Parasite membranes also had 7 major bands with MW ranging from 100,000 to 22,000. No glycoproteins were identifiable in these membranes. The proteins of the surface membranes from infected red cells had MW similar to those from normal red cells; however, there was some evidence of a reduction in the amount of the high MW polypeptides. The red cell membrane contained 79 nmoles sialic acid/mg membrane protein, whereas plasmodial membranes had 8 nmoles sialic acid/mg membrane protein. The sialic acid content of the surface membranes of infected red cells was significantly smaller than that of normal cells. Lactoperoxidase-glucose oxidase-catalyzed iodination of intact normal and malaria-infected erythrocytes labeled 7 surface components. Although no observable differences in iodinatable proteins were seen in these preparations, there was a striking reduction in the iodinatability of erythrocytic membranes obtained from P. lophurae-infected cells. Erythrocyte-free plasmodia bound very little radioactive iodine; the small amount of radioactivity was distributed among 3 major bands with MW of 42,000, 32,000 and 28,000. It is suggested that the alterations of the surface of the P. lophurae-infected erythrocyte do not occur by a wholesale insertion of plasmodial membrane proteins into the red cell plasma membrane, but rather that there are parasite-mediated modifications of existing membrane polypeptides.     

Isolation and characterization of plasma and smooth membranes of the marine diatom Nitzschia alba

A procedure is described for isolating plasma, smooth and other cellular membranes from hypotonically lysed protoplasts of the marine diatom, Nitzschia alba. From starting material of approximately 10 g wet weight (10¹⁰ cells), about 168 mg (organic weight) of a membrane-enriched fraction, exclusive of mitochondria, is obtained by differential centrifugation. From this, six membrane fractions are separated on a discontinuous sucrose gradient by isopycnic centrifugation.The plasma membranes, from the density region 1.23-1.29 g/cc, consist of small vesicles and sheets. They are purified approximately 20-fold, based on the increase in specific activity of a (Na⁺-K⁺-Mg²⁺)-ATPase, an enzyme found predominantly in these membranes. They also contain the highest specific and total activity of a (Mg²⁺)-ATPase and, in addition, are distinguished chemically by their high sterol specific content and high molar ratio of sterol/phospholipid (0.792-0.854). The carbohydrate/ protein ratio (0.070-0.072) is appreciably lower than that of the smooth membranes.The smooth membranes separate into two distinct fractions, a light and heavy component, which occur at the top of the sucrose gradient in densities of 1.13 and 1.18 g/cc, respectively. Both fractions are composed of relatively large membrane vesicles and membrane sheets and are distinguished from other membrane fractions by an exceptionally high carbohydrate/protein ratio (0.194-0.294).The light component shows the highest specific content of lipid, phospholipid, neutral lipid, carbohydrate, sialic acid, and RNA, and the highest specific activity of NADPH cytochrome c reductase, 5′-nucleotidase and phosphodiesterase compared to the other five fractions. It shows the lowest Na⁺ plus K⁺ stimulation of the (Mg²⁺)-ATPase. This fraction is probably enriched in endoplasmic reticulum.The heavy component contains some Golgi-like vesicles, sacs and tubules. It is characterized by the highest total content of chemical constituents analyzed, with the exception of RNA, and by the highest specific activity of thiamine pyrophosphatase, uridine diphosphatase, acid and alkaline phosphatase, and glucose-6-phosphatase, suggesting that this component is enriched in Golgi membranes approximately 13-fold.A most striking feature of these diatom membranes is the presence in all fractions of (Mg²⁺)-ATPase activity which is stimulated 5- to 10-fold by the presence of equimolar Na²⁺ plus K⁺. The data clearly differentiate these membrane fractions from each other as well as from membranes prepared from animal cells.     

The isolation and characterization of plasma membrane from cultured cells V. The chemical composition of plasma membranes isolated from chicken tumors initiated with virus-transformed cells

Sarcomas were initiated in chicken muscle and wing web by Bratislava 77 and morph^r Fujinami virus. Plasma membrane was isolated from the virus-induced tumor cells by differential centrifugation and flotation equilibrium centrifugation. The levels of neutral sugar and sialic acid in these isolated plasma membranes were very similar to the levels found in cultured chick embryo fibroblasts transformed in vitro with the same oncogenic viruses and differed markedly from the levels found in uninfected and leukosis virus-infected fibroblasts.The phospholipid content of the isolated cell membranes from tumors was less than the quantity of lipid found in the plasma membrane of cultured cells and differed with the site of the tumor. Breast muscle tumors contained less plasma membrane phospholipid than did wing tumors.The similarities in the neutral sugar and the sialic acid content of these two different sources of plasma membrane indicate that oncogenic transformation in cell culture reproduces in situ neoplastic change to a large extent, for at least this one parameter of cell surface change.     

Preparation and characterization of plasma membrane vesicles from human polymorphonuclear leukocytes

It would be advantageous to prepare models of the neutrophil plasma membrane in order to examine the role of the plasma membrane in transmembrane signal transduction in the human neutrophil and to dissect ligand-receptor interactions and structural changes in the cell surface upon stimulation. A number of investigators have prepared neutrophil membrane vesicles by homogenization, sonication, or centrifugation--techniques that can result in the loss of substantial amounts of surface membrane material, disruption of lysosomes causing proteolysis of membrane proteins, and contamination of the plasma membrane fraction by internal membranes. These limitations have been overcome in the present studies by employing a modification of the method previously developed in this laboratory. Human neutrophils were suspended in a buffer simulating cytoplasmic ionic and osmotic conditions and disrupted by nitrogen cavitation. The resultant cavitate was freed of undisrupted cells and nuclei and then centrifuged through discontinuous isotonic/isoosmotic Percoll gradients, which resolved four fractions: alpha (intact azurophilic granules), beta (intact specific granules), gamma (membrane vesicles), and delta (cytosol). The gamma fraction was highly enriched in alkaline phosphatase, a marker of the plasma membrane. In addition, this fraction contained less than 5% of the amounts of lysosomes (indicated by lysozyme activity) and nuclei (indicated by DNA content) found in intact cells or in unfractionated cavitate. Furthermore, the gamma fraction contained less than 10% of the levels of endoplasmic reticulum, Golgi, mitochondrial, and lysosomal membranes in cells or cavitates, as determined by assays for glucose 6-phosphatase, galactosyl transferase, monoamine oxidase, and Mo1 (CD11b/CD18; Mac-1), respectively. Finally, 75% of the membrane vesicles were sealed, as indicated by assay of ouabain-sensitive (Na+,K+) ATPase activity, and 55% were oriented right-side-out, as determined by exposure of concanavalin A (ConA) receptors and sialic acid residues on the surfaces of the vesicles. These heterogeneous preparations could be enriched for right-side-out vesicles by their selective adherence to ConA-coated plates and subsequent detachment by rinsing the surfaces of the plates with alpha-methylmannoside. This enrichment protocol did not affect the integrity of the vesicles and resulted in populations in which greater than 85% of the vesicles were oriented right-side-out. This procedure thus permits the preparation of sealed, right-side-out membrane vesicles that may be used as valid experimental models of the neutrophil plasma membrane in a variety of functional studies.     

Properties of plasma membrane H<Superscript>+</Superscript>-ATPase in salt-treated <Emphasis Type="Italic">Populus euphratica</Emphasis> callus

The plasma membrane (PM) vesicles from Populus euphratica (P. euphratica) callus were isolated to investigate the properties of the PM H⁺-ATPase. An enrichment of sealed and oriented right-side-out PM vesicles was demonstrated by measurement of the purity and orientation of membrane vesicles in the upper phase fraction. Analysis of pH optimum, temperature effects and kinetic properties showed that the properties of the PM H⁺-ATPase from woody plant P. euphratica callus were consistent with those from herbaceous species. Application of various thiol reagents to the reaction revealed that reduced thiol groups were essential to maintain the PM H⁺-ATPase activity. In addition, there was increased H⁺-ATPase activity in the PM vesicles when callus was exposed to NaCl. Western blotting analysis demonstrated an enhancement of H⁺-ATPase content in NaCl-treated P. euphratica callus compared with the control.     

NADH-Ferricyanide Reductase of Leaf Plasma Membranes : Partial Purification and Immunological Relation to Potato Tuber Microsomal NADH-Ferricyanide Reductase and Spinach Leaf NADH-Nitrate Reductase

Plasma membranes obtained by two-phase partitioning of microsomal fractions from spinach (Spinacea oleracea L. cv Medania) and sugar beet leaves (Beta vulgaris L.) contained relatively high NADH-ferricyanide reductase and NADH-nitrate reductase (NR; EC 1.6.6.1) activities. Both of these activities were latent. To investigate whether these activities were due to the same enzyme, plasma membrane polypeptides were separated with SDS-PAGE and analyzed with immunoblotting methods. Antibodies raised against microsomal NADH-ferricyanide reductase (tentatively identified as NADH-cytochrome b₅ reductase, EC 1.6.2.2), purified from potato (Solanum tuberosum L. cv Bintje) tuber microsomes, displayed one single band at 43 kilodaltons when reacted with spinach plasma membranes, whereas lgG produced against NR from spinach leaves gave a major band at 110 kilodaltons together with a few fainter bands of lower molecular mass. Immunoblotting analysis using inside-out and right-side-out plasma membrane vesicles strongly indicated that NR was not an integral protein but probably trapped inside the plasma membrane vesicles during homogenization. Proteins from spinach plasma membranes were solubilized with the zwitterionic detergent 3-[(3-cholamidopropyl) dimethylammonio] 1-propane-sulfonate and separated on a Mono Q anion exchange column at pH 5.6 with fast protein liquid chromatography. One major peak of NADH-ferricyanide reductase activity was found after separation. The peak fraction was enriched about 70-fold in this activity compared to the plasma membrane. When the peak fractions were analyzed with SDS-PAGE the NADH-ferricyanide reductase activity strongly correlated with a 43 kilodalton polypeptide which reacted with the antibodies against potato microsomal NADH-ferricyanide reductase. Thus, our data indicate that most, if not all, of the truly membrane-bound NADH-ferricyanide reductase activity of leaf plasma membranes is due to an enzyme very similar to potato tuber microsomal NADH-ferricyanide reductase (NADH-cytochrome b₅ reductase).     

On the presence of inside-out plasma membrane vesicles and vanadate-inhibited K+,Mg2+-ATPase in microsomal fractions from wheat and maize roots

We have estimated the amount of inside-out plasma membrane (PM) vesicles in microsomal fractions from wheat (Triticum aestivum L. cv. Drabant) and maize (Zea mays L.) roots; non-latent activities of the PM markers vanadate-inhibited K⁺, Mg²⁺-ATPase (ΔVO₄-ATPase) and glucan synthase II (GS II, EC 2.4.1.34) were used as markers for inside-out PM vesicles, latent activities as markers for right-side-out PM vesicles, and specific staining with silicotungstic acid (STA) as a general marker for the PM. Separation of presumptive inside-out PM vesicles from right-side-out ones was achieved by counter-current-distribution (CCD) in an aqueous polymer two-phase system. Most of the GS II activity was latent and was found in material partitioning into the upper phase; a distribution which correlated well with that of STA-stained vesicles. Thus, most of the PM vesicles had a right-side-out orientation. ΔVO₄-ATPase, on the other hand, had a dual distribution (particularly pronounced in wheat) and was recovered both in material partitioning into the lower phase and into the upper phase. This indicates that ΔVO₄-ATPase activity was present also in membranes other than the PM. Additional evidence for this interpretation came from sucrose gradient centrifugation of wheat root material. This produced two peaks of ΔVO₄-ATPase activity with the membranes partitioning into the lower phase, none of which coincided with the peak obtained with right-side-out PM vesicles. Taken together, these results indicate that only very few inside-out PM vesicles are present in the microsomal fraction, and that ΔVO₄-ATPase as a marker for the PM, in contrast to GS II, may give quite misleading results with some plant materials. This stresses the need to use well-defined preparations of scaled, inside-out PM vesicles in solute uptake studies. The distribution of Ca²⁺-inhibited ATPase, on the other hand, agreed well with those of GS II and STA-stained vesicles both after CCD and sucrose gradient centrifugation, which suggests that Ca²⁺ inhibition may be a more specific property of the PM H⁺-ATPase than vanadate inhibition.     

Isolation of plasma membrane fractions from green wheat leaves by free-flow electrophoresis or two-phase partition alone or in combination

Plasma membrane vesicles were isolated from shoots of light-grown wheat seedlings by preparative free-flow electrophoresis, aqueous polymer two-phase partition or both. Plasma membrane vesicles were identified from staining of thin sections prepared for electron microscopy with phosphotungstic acid at low pH. The orientation of the plasma membrane vesicles was determined from latency and trypsin sensitivity of K⁺ Mg²⁺ATPase and of glucan synthase II, and concanavalin A-peroxidase binding and membrane asymmetry visualized by electron microscopy. The K⁺Mg²⁺ATPase and of glucan synthase II activities of plasma membrane fractions isolated by two-phase partition were latent and trypsin resistant. The vesicles bound concanavalin A-peroxidase strongly and exhibited a cytoplasmic side-in morphology. These fractions of cytoplasmic side-in vesicles were less than 10% contaminated by cytoplasmic side-out vesicles. By free-flow electrophoresis, two populations of vesicles which stained with phosphotungstic acid at low pH, designated D and E, were obtained. The vesicle population with the lower electrophoretic mobility, fraction E, contained plasma membrane vesicles with properties similar to those of the plasma membrane vesicles obtained after two-phase partition. The phosphotungstic-reactive vesicles with greater electrophoretic mobility, fraction D, were concanavalin A unreactive with the cytoplasmic membrane leaflet outwards. Less than 50% of the K⁺Mg²⁺-ATPase activity of this fraction was latent and trypsin sensitive. The vesicles of fraction D appeared to be preferentially cytoplasmic side-out. The electrophoretic mobilities of cytoplasmic side-out (non-latent glucan synthase II activity) and cytoplasmic side-in (latent glncan synthase II activity) plasma membrane vesicles isolated from a frozen and thawed wheat plasma membrane fraction, corresponded with the mobilities of fraction D and E, respectively, again showing that the plasma membrane vesicles with the lesser electrophoretic mobility were cytoplasmic side-in. The cytoplasmic side-in and cytoplasmic side-out vesicles therefore showed opposite eletrophoretic mobilities compared with a previous free-flow electrophoretic separation of soybean plasma membranes. The majorities of the plasma membrane vesicles of both fractions D and E entered the upper phase upon two-phase partition with the phase composition used for purification of wheat plasma membranes. Thus, neither electrophoretic mobility nor phase partitioning characteristics can be used as the only criteria for assignment of vesicle orientation.     

Transmembrane Electron Transport in Plasma Membrane Vesicles Loaded with an NADH-Generating System or Ascorbate

Sugar beet (Beta vulgaris L.) leaf plasma membrane vesicles were loaded with an NADH-generating system (or with ascorbate) and were tested spectrophotometrically for their ability to reduce external, membrane-impermeable electron acceptors. Either alcohol dehydrogenase plus NAD⁺ or 100 millimolar ascorbate was included in the homogenization medium, and right-side-out (apoplastic side-out) plasma membrane vesicles were subsequently prepared using two-phase partitioning. Addition of ethanol to plasma membrane vesicles loaded with the NADH-generating system led to a production of NADH inside the vesicles which could be recorded at 340 nanometers. This system was able to reduce 2,6-dichlorophenolindophenol-3′-sulfonate (DCIP-sulfonate), a strongly hydrophilic electron acceptor. The reduction of DCIP-sulfonate was stimulated severalfold by the K⁺ ionophore valinomycin, included to abolish membrane potential (outside negative) generated by electrogenic transmembrane electron flow. Fe³⁺-chelates, such as ferricyanide and ferric citrate, as well as cytochrome c, were not reduced by vesicles loaded with the NADH-generating system. In contrast, right-side-out plasma membrane vesicles loaded with ascorbate supported the reduction of both ferric citrate and DCIP-sulfonate, suggesting that ascorbate also may serve as electron donor for transplasma membrane electron transport. Differences in substrate specificity and inhibitor sensitivity indicate that the electrons from ascorbate and NADH were channelled to external acceptors via different electron transport chains. Transplasma membrane electron transport constituted only about 10% of total plasma membrane electron transport activity, but should still be sufficient to be of physiological significance in, e.g. reduction of Fe³⁺ to Fe²⁺ for uptake.     

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.     

Studies on plasma membranes XVII. On the chemical composition of plasma membranes prepared from rat and mouse liver and hepatomas

Summary Plasma membranes were isolated under hypotonic conditions from rat and mouse livers and five hepatomas, i.e. one rather anaplastic rat hepatoma (and its subline) and three well-differentiated mouse hepatomas. All these membranes contained some 25% protein soluble in 0.15m NaCl. Evidence is presented that this protein is mainly, if not exclusively of nonmembranous origin. Protein/phospholipid P (P=phosphorus) ratios did not differ significantly for the various plasma membrane species except the rat-hepatoma subline, which showed a markedly lower ratio and was thus identified. Hepatoma membranes contained more P of a nonphospholipid nature than did liver membranes and to this increase contributed in all instances an increased RNA content and in some cases also an increased DNA content. The presence of DNA in these plasma membranes is artefactual, but that of RNA is more complicated. Artefactually, Ca²⁺-associated RNA of low mol wt and soluble in 0.15m NaCl, and residual RNA (genuine?, in liver membranes less than 1% in respect of protein) have been demonstrated. The increase in hepatoma-membrane RNA is attributed to the ribosomal RNA of the few microsomal vesicles which are structurally connected with these plasma membranes. The sialic acid content and the percentage of neuraminidase-resistant sialic acid of hepatoma as compared with liver membranes was either similar or changed, depending on the hepatoma strain. Gelfiltration of trypsin-released peptides of liver plasma membranes showed hexosamine and hexose to be confined to the sialic acidcontaining fractions. In spite of quantitative differences among fractions, the relative contents of the three carbohydrates in the combined fractions were (about) similar to those in intact liver membranes. Similar experiments with the rat-hepatoma membranes showed a changed carbohydrate expression.     

Body Plasma Membrane Vesicles from Paramecium Contain a Vanadate-Sensitive Ca--ATPase

Paramecia are an excellent model system for studying the mechanisms involved in sensory transductions and intracellular Ca²⁺ regulation. These cells have two functionally distinct plasma membrane domains, body and cilia. The body plasma membrane is responsible for transduction of sensory stimuli into receptor potentials and the ciliary membrane is required for Ca²⁺ action potentials. Although ciliary membrane vesicles (cmv) have been purified and well characterized, body plasma membranes have not. We have generated body plasma membrane vesicles (bmv) by homogenization of deciliated cells and purified them from the microsome fraction by a two-phase aqueous polymer separation. The major criteria for purity of the bmv fraction are: (i) It is enriched 15-fold for a known plasma membrane marker (immobilization antigen) while the marker activities for other membranes were all decreased. The protein banding pattern of bmv is generally similar to cmv on SDS-PAGE. (ii) It contains a vanadate-sensitive Ca²⁺-ATPase activity that has been suggested to be a plasma membrane Ca²⁺ pump. The specific activity of this bmv Ca²⁺-ATPase is increased 4-fold over that of the homogenate. (iii) The phospholipid, fatty acid, and sterol composition of the bmv fraction are indicative of plasma membranes because they are qualitatively similar to cmv. The bmv also contains a membrane-bound NADPH-dependent cytochrome c reductase activity, suggesting that it may play a role in body plasma membrane function. This purified bmv preparation is useful for studying the role of the body plasma membrane in Ca²⁺ regulation, sensory transduction, protein and lipid trafficking, and plasma membrane fusion events.     

Orientation of NAHD-linked ferric chelate (turbo) reductase in plasma membranes from roots ofPlantago lanceolata

Summary Plasma membrane vesicles isolated from roots ofPlantago lanceolata L. revealed approximately 70% right-side-out orientation based on structure-linked latency with H⁺-ATPase as a marker. Incubation with 0.05% Brij 58 caused the formation of sealed insideout vesicles, evidenced by assaying ATP-dependent proton pumping activity with the optical pH probe acridine orange. NADH-linked FeEDTA reductase activity was stimulated by including either Triton X-100 or Brij 58 in the assay medium. The activity of inverted (Brijtreated) vesicles was not further increased by the addition of Triton, suggesting that maximum activity was obtained in inside-out vesicles. Iron deficiency resulted in a ca. 2-fold increase in the specific activity of both ATPase and Fe(III) chelate reductase but did not cause significant alterations with respect to the effect of detergents. It is concluded that in vitro both donor and acceptor sites of NADH-FeEDTA reductase are located on the cytosolic face of the membrane and trans-oriented flow of electrons is not detectable in plasma membrane vesicles. Unlike Fe chelate reduction in vivo, the plasma membrane-bound reductase activity was insensitive towards application of the translation inhibitor cycloheximide prior to isolation of the membranes, implying the involvement of a regulatory enzyme in the electron transport in vivo.Abbreviations BPDS bathophenanthroline disulfonate - BTP 1,3-bis[tris(hydroxymethyl)methylamino]-propane - PM plasma membrane     

N-1-napthylphthalamic-acid-binding activity of a plasma membrane-rich fraction from maize coleoptiles

Summary Plasma membrane-rich fractions were prepared from maize coleoptiles by low-shear homogenization and differential and sucrose-gradient centrifugation. Plasma membrane fragments were identified using a specific cytochemical stain based on phosphotungstic acid prepared in chromic acid. In a comparison of 10 different cell fractions of varying plasma membrane content, the N-1-napthylphthalamic-acid (NPA)-binding activity of the fractions was directly proportional to the content of plasma membrane. The NPA binding appears to be strong K _M between 10^-8 and 10^-7 M) but non-covalent. NPA is known to inhibit auxin transport efficiently and quickly. Thus, the results are consistent with the localization of auxin transport sites at the plasma membrane of plant cells.Purdue University Agricultural Experiment Station Journal Paper No. 4355. This work was supported in part by a grant from the National Science Foundation GB-23183.Supported by National Science Foundation Postdoctoral Fellowship.     

Mode of action of LciA, the lactococcin A immunity protein

Monoclonal antibodies were raised against a fusion between the Escherichia coli maltose-binding protein and LciA, the immunity protein that protects Lactococcus lactis against the effects of the bacteriocin lactococcin A. One of the antibodies directed against the LciA moiety of the fusion protein was used to locate the immunity protein in the L. lactis producer cell. LciA was present in the cytosolic. the membrane-associated, and the membrane fractions in roughly equal amounts, irrespective of the production by the cells of lactococcin A. The monoclonal antibody specifically reacted with right-side-out vesicles obtained from a strain producing the immunity protein. It did not react with inside-out vesicles of the same strain, or with right-side-out vesicles obtained from a strain producing both LciA and lactococcin A. Also, externally added lactococcin A blocked the interaction between the antibody and right-side-out vesicles obtained from a strain producing only LciA. The epitope in LciA was localized between amino acid residues 60 and 80. As the epitope could be removed from right-side-out vesicles by proteinase K, it is located at the outside of the cell. The immunity protein contains a putative a-amphiphilic helix from residue 29 to 47. A model is proposed in which this helix is thought to traverse the membrane in such a way that the C-terminal part of the protein, containing the epitope, is on the outside of the cell. Vesicle-fusion studies together with leucine-uptake experiments suggest that the immunity protein interacts with the putative receptor for lactococcin A, thus preventing pore formation by the bacteriocin.     

Sidedness of plant plasma membrane vesicles altered by conditions of preparation

Right-side-out vesicles of plasma membrane from soybean (Glycine max Merr.) were isolated by aqueous two-phase partition. Inside-out vesicles were formed when these preparations were diluted or frozen and thawed. Sidedness (orientation) was determined by preparative free-flow electrophoresis, concanavalin A binding, and ATPase latency. Under usual conditions of aqueous two-phase partition, the bulk of the vesicles were strongly reactive with concanavalin A-peroxidase and showed a high level of structure-linked latency as expected of a right-side-out (cytoplasmic-side-in) orientation. The vesicles migrated as a single electrophoretic peak. When frozen and thawed, vesicle diameters were reduced and a second population of vesicles of increased electrophoretic mobility was obtained. This second population of vesicles was weakly reactive with concanavalin A-peroxidase and showed low latency as expected of an inside-out (cytoplasmic-side-out) orientation. If the plasma membrane vesicles were diluted with water, a mixture of right-side-out and inside-out vesicles again was obtained. However, some of the cytoplasmic-side-out vesicles that were concanavalin A-unreactive and had low ATPase latency migrated more slowly as a second, less electronegative peak, upon free-flow electrophoresis. The results suggest that right-side-out and inside-out plasma membrane vesicles differ in electrophoretic mobility but that both the orientation and the absolute electrophoretic mobility of the differently oriented vesicles may be influenced by the preparative conditions.     

Isolation of basolateral and brush-border membranes from the rabbit kidney cortex: Vesicle integrity and membrane sidedness of the basolateral fraction

A rapid and reproducible method has been developed for the simultaneous isolation of basolateral and brush-border membranes from the rabbit renal cortex. The basolateral membrane preparation was enriched 25-fold in (Na⁺ + K⁺)-ATPase and the brush-border membrane fraction was enriched 12-fold in alkaline phosphatase, whereas the amount of cross-contamination was low. Contamination of these preparations by mitochondria and lysosomes was minimal as indicated by the low specific activities of enzyme markers, i.e., succinate dehydrogenase and acid phosphatase. The basolateral fraction consisted of 35–50% sealed vesicles, as demonstrated by detergent (sodium dodecyl sulfate) activation of (Na⁺ + K⁺)-ATPase activity and [³H]ouabain binding. The sidedness of the basolateral membranes was estimated from the latency of ouabain-sensitive (Na⁺ + K⁺)-ATPase activity assayed in the presence of gramicidin, which renders the vesicles permeable to Na⁺ and K⁺. These studies suggest that nearly 90% of the vesicles are in a right-side-out orientation.     

Biological and physicochemical characterization of recombinant human erythropoietins fractionated by Mono Q column chromatography and their modification with sialytransferase

Ten erythropoietin (EPO) fractions differing in sialic acid content, ranging from 9.5 to 13.8 mol mol^–1 of EPO, were obtained from baby hamster kidney cell-derived recombinant human EPO by Mono Q column chromatography. The mean pI values of the EPO fractions determined by IEF-gel electrophoresis systematically shifted from 4.11 to 3.31, coinciding with the sialic acid content, without a change in the constitution of asialo N-linked oligosaccharides of each fraction. Although a linear relationship between thein vivo bioactivity and the sialic acid content of the fractionated, samples was observed until 12.1 mol mol^–1 of EPO, there was no further increase in their activity over 12.4 mol mol^–1 of EPO. On the other hand, an inverse relationship between thein vitro bioactivity and sialic acid content of EPO was observed. Also, we showed that thein vivo bioactivity of some fractions with low sialic acid contents was increased after treatment with 2,6-sialyltransferase, but thein vivo bioactivity of the other fractions with high sialic acid contents was either decreased or not affected.Abbreviations EPO erythropoietin - rHuEPO recombinant human erythropoietin - hCG human chorionic gonadotropin - BHK baby hamster kidney - CHO Chinese hamster ovary - NeuAc N-acetyl neuraminic acid - Gal galactose - HRCs hemolyser-resistant cells - WST-1 2-(4-iodophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium Na - IEF isoelectric focusing - pI isoelectric point