Localization and distribution of Microccus lysodeikticus membrane ATPase determined by ferritin labeling

Antiserum to Ca²⁺-activated ATP phosphohydrolase (EC 3.6.1.3) isolated and purified from membranes of Micrococcus lysodeikicus was prepared in rabbits and guinea pigs. The γ-globulin fractions of these antisera reacted with and inhibited ATPase activity in isolated membranes but failed to absorb to intact protoplasts or purified mesosome fractions. ATPase activity was not detectable in the purified mesosomal preparations and trypsin treatment and sonication failed to release any activity. Ferritin conjugated to the γ-globulin fractions of the antiserum reacted with the ATPase particles on the membrane as visualized in negatively stained preparations examined in the electron microscope. Labeled membranes showed a distribution of ferritin very similar to the patterns observed for ATPase particles on untreated membranes. No significant labeling occurred when the ferritin conjugate was reacted with intact protoplasts or mesosome fractions. Thin sections of ferritin-labeled membranes established the asymmetric disposition of the ATPase, with the conjugate visible on only one side of the membrane. The results indicate that the ATPase protein occurs on the inner face of the membrane. All labeling experiments were verified immunologically. When ferritin-labeled membranes were subjected to the selective release procedure used in releasing the ATPase-like particles from the membranes, a complex of ferritin-conjugate associated with the ATPase particles was released. The selective release of ferritin-antibody-enzyme complexes from the membrane opens up a new way of studying the molecular architecture of cell membranes.     

Orientation and integrity of plasma membrane vesicles obtained from carrot protoplasts

Two fractions enriched in plasma membrane derived from suspension-cultured carrot (Daucus carota L.) cells were examined to determine if they differed from each other either in physical nature or in orientation. Parameters studied included the protein composition of purified membranes derived from trypsinized and nontrypsinized protoplasts as well as from trypsinized purified plasma membranes, the effect of inhibitors and membrane perturbants on ATPase activity, the binding of [acetyl-¹⁴C]concanavalin A to purified membrane fractions, and the competitive removal of [acetyl-¹⁴C]concanavalin A from purified membranes derived from [acetyl-¹⁴C]concanavalin A-labeled protoplasts. One fraction (at density of 1.102 grams per cubic centimeter on Renografin gradients) appears to be a mixed population of `tightly' sealed vesicles with the majority being rightside-out vesicles of plasma membrane, and the other fraction (density 1.128 grams per cubic centimeter) apparently is a population of predominantly `leaky' vesicles and/or nonvesicular fragments of plasma membrane, a large portion of which appear to be `leaky' inside-out vesicles. In addition, it is shown that plasma membrane-enriched fractions can be distinguished from cellular endomembranes on the basis of protein and glycoprotein composition.     

Orientation of vesicles isolated from baso-lataral membranes of renal cortex

Baso-lateral membranes were isolated from the canine and porcine kidney cortex by several different methods currently in use. Sidedness of the isolated membrane vesicles was determined by procedures using 1. ouabain-sensitive (Na+K+)ATPase assays in the presence and in the absence of sodium dodecylsulfate or digitoxigenin plus monensin, 2. (Na+, K+, Mg2+)ATPase assays with valinomycin, 3. sialidase accessibility, and 4. binding of hydrophilic and lipophilic cardiac glycosides. The (Na+K+)ATPase activity in the membrane preparation was increased 10-fold of that found in the crude homogenate. Isolated membrane vesicles, prepared by different techniques, were all found to be overwhelmingly of right-side-out orientation;namely, right-side-out = 51-68%, inside-out = 4-13%, and unsealed vesicles = 26-42%. Results of sidedness determinations by different methods showed a good agreement. Thus, predominantly right-side-out oriented vesicles are formed during conventional isolation procedures for membranes of the kidney cortex.     

Plasma membranes from Candida tropicalis grown on glucose or hexadecane. I. Isolation, identification and purification.

Plasma membranes from Candida tropicalis grown on glucose or hexadecane were isolated using a method based on the difference in surface charge of mitochondria and plasma membranes. After mechanical disruption of the cells, a fraction consisting of mitochondrial and plasma membrane vesicles was obtained by differential centrifugation. Subsequently the mitochondria were separated from the plasma membrane vesicles by aggregation of the mitochondria at a pH corresponding to their isoelectric point. Additional purification of the isolated plasma membrane vesicles was achieved by osmolysis. Surface charge densities of mitochondria and plasma membranes were determined and showed substrate-dependent differences. The isolated plasma membranes were morphologically characterized by electron microscopy and, as a marker enzyme, the activity of Mg2+-dependent ATPase was determine. By checking for three mitochondrial marker enzymes the plasma membrane fractions were estimated to be 94% pure with regard to mitochondrial contamination.     

Isolation by preparative free-flow electrophoresis and aqueous two-phase partition from rat adipocytes of an insulin-responsive small vesicle fraction with glucose transport activity

Preparative free-flow electrophoresis and aqueous two-phase polymer partition were used to obtain a plasma membrane-enriched fraction of adipocytes isolated from epididymal fat pads of the rat together with a fraction enriched in small vesicles with plasma membrane characteristics (thick membranes, clear dark-light-dark pattern). The electrophoretic mobility of the small vesicles was much less than that of the plasma membrane consistent with an inside-out orientation whereby charged molecules normally directed to the cell surface were on the inside. When plasma membranes and the small vesicle fraction were isolated from fat cells treated or not treated with 100 μU/ml insulin and the resident proteins of the two fractions analyzed by SDS-PAGE, the two fractions exhibited characteristics responses involving specific protein bands. Insulin treatment for 2 min resulted in the loss of a 90 kDa band from the plasma membrane. At the same time, a ca. 55-kDa peptide band that was enhanced in the plasma membrane was lost from the small vesicle fraction. The latter corresponded on Western blots to the GLUT-4 glucose transporter. Thus, we suggest that the small vesicle fraction with characteristics of inside-out plasma membrane vesicles may represent the internal vesicular pool of plasma membrane subject to modulation by treatment of adipocytes with insulin.     

Studies on the heterogeneity of sarcoplasmic reticulum vesicles.

Isolated sarcoplasmic reticulum vesicles from rabbit white muscle were separated into a light (15--20% of total microsomes) and a heavy (80--85%) fraction by density gradient centifugation. The ultrastructure, chemical composition, enzymic activities and localization of membrane components in the vesicles of both fractions were investigated. From the following results it was concluded that both fractions are derived from the membranes of the sarcoplasmic reticulum system of the muscle: (i) The protein pattern of both fractions is essentially the same, except for different ratios of acidic, Ca2+-binding proteins. (ii) The 105000 dalton protein of the light fraction cross-reacts immunologically with the Ca2+-dependent ATPase of the heavy fraction. (iii) Ca2+-dependent ATPase, although of different specific activity, is found in both fractions. After rendering the vesicles leaky, specific activities in both fractions reach the same value. The light fraction was found to consist of "inside-out" vesicles by the following criteria: (i) No Ca2+ accumulation can be measured and the Ca2+-dependent ATPase activity is low and variable. (ii) The rate of trypsin digestion is lower and, compared to the heavy microsomes, a different ratio of degradation products is obtained. (iii) The sarcoplasmic reticulum membrane has a highly asymmetrical lipid distribution. This distribution of aminophospholipids is opposite to that in vesicles of heavy fraction. The light sarcoplasmic reticulum fraction has a higher phospholipid to protein ratio than the heavy one. This is consistent with the possibility that the two fractions derive from different parts of the sarcoplasmic reticulum system.     

P-glycoprotein substrate transport assessed by comparing cellular and vesicular ATPase activity

We compared the P-glycoprotein ATPase activity in inside-out plasma membrane vesicles and living NIH-MDR1-G185 cells with the aim to detect substrate transport. To this purpose we used six substrates which differ significantly in their passive influx through the plasma membrane. In cells, the cytosolic membrane leaflet harboring the substrate binding site of P-glycoprotein has to be approached by passive diffusion through the lipid membrane, whereas in inside-out plasma membrane vesicles, it is accessible directly from the aqueous phase. Compounds exhibiting fast passive influx compared to active efflux by P-glycoprotein induced similar ATPase activity profiles in cells and inside-out plasma membrane vesicles, because their concentrations in the cytosolic leaflets were similar. Compounds exhibiting similar influx as efflux induced in contrast different ATPase activity profiles in cells and inside-out vesicles. Their concentration was significantly lower in the cytosolic leaflet of cells than in the cytosolic leaflet of inside-out membrane vesicles, indicating that P-glycoprotein could cope with passive influx. P-glycoprotein thus transported all compounds at a rate proportional to ATP hydrolysis (i.e. all compounds were substrates). However, it prevented substrate entry into the cytosol only if passive influx of substrates across the lipid bilayer was in a similar range as active efflux.     

Plasma membranes from candida tropicalis grown on glucose or hexadecane. I. Isolation,identification and purification

Plasma membranes from Candida tropicalis grown on glucose or hexadecane were isolated using a method based on the difference in surface charge of mitochondria and plasma membranes.After mechanical disruption of the cells, a fraction consisting of mitochondrial and plasma membrane vesicles was obtained by differential centrifugation.Subsequently the mitochondria were separated from the plasma membrane vesicles by aggregation of the mitochondria at a pH corresponding to their isoelectric point. Additional purification of the isolated plasma membrane vesicles was achieved by osmolysis. Surface charge densities of mitochondria and plasma membranes were determined and showed substrate-dependent differences.The isolated plasma membranes were morphologically characterized by electron microscopy and, as a marker enzyme, the activity of Mg²⁺-dependant ATPase was determined.By checking for three mitochondrial marker enzymes the plasma membrane fractions were estimated to be 94% pure with regard to mitochondrial contamination.     

Isolation and characterization of plasma membranes from rabbit skeletal muscle

An improved procedure was developed for the isolation of skeletal muscle plasma membranes. This method includes a DNAse treatment of the homogenate prior to the isolation of membranes by differential and sucrose gradient centrifugation techniques. We obtained two light fractions which were highly enriched in many biochemical and chemical plasma membrane markers. These fractions were shown to be mostly inside-out vesicles containing a Ca2+-ATPase activity. These results suggested that this enzyme could participate in the extrusion of calcium ions from the muscle cells.     

Subfractionation of cardiac sarcolemma with wheat-germ agglutinin.

The properties of highly purified bovine cardiac sarcolemma subfractionated with the lectin, wheat-germ agglutinin (WGA) were studied. Two different membrane subfractions were isolated, one which was agglutinated in the presence of 1.0 mg of WGA/mg of protein (WGA+ vesicles) and a second fraction which failed to agglutinate (WGA- vesicles). These two membrane fractions had quantitatively different rates of Na+/K+-dependent, ouabain-sensitive ATPase and Na+/Ca2+ exchange activities, yet a similar protein composition, which suggests that they were both derived from the plasma membrane. WGA- vesicles had a decreased number of [3H]quinuclidinyl benzilate-binding sites and no detectable [3H]nitrendipine-binding sites. Electron-microscopic and freeze-fracture analysis showed that the WGA+ fraction was composed of typical spherical sarcolemmal vesicles, whereas the WGA- fraction primarily contained elongated tubular structures suggestive of the T-tubule vesicles which were previously isolated from skeletal muscle. Assays of marker enzymes revealed that these fractions were neither sarcoplasmic reticulum nor plasma membrane from endothelial cells. Moreover, WGA agglutination did not result in the separation of right-side-out and inside-out vesicles. On the basis of these findings we propose that the WGA+ fraction corresponds to highly purified sarcolemma, whereas the WGA- fraction may be derived from T-tubule membranes.     

Synthesis of plasmalemmal glycoproteins in intestinal epithelial cells. Separation of Golgi membranes from villus and crypt cell surface membranes; glycosyltransferase activity of surface membrane

The relationship between Golgi and cell surface membranes of intestinal cells was studied. These membranes were isolated from intestinal crypt cells and villus cells. The villus cell membranes consisted of microvillus membrane, a Golgi-rich fraction, and two membrane fractions interpreted as representing lateral-basal membranes. The villus cell microvillus membrane was purified by previously published techniques while the other membranes were obtained from isolated cells by differential centrifugation and density gradient velocity sedimentation. The two membrane fractions obtained from villus cells and considered to be lateral-basal membranes were enriched for Na+,K+-ATPase activity, but one also showed enrichment in glycosyltransferase activity. The Golgi membrane fraction was enriched for glycosyltransferase activity and had low to absent Na+,K+-ATPase activity. Adenylate cyclase activity was present in all membrane fractions except the microvillus membrane but co-purified with Golgi rather than lateral-basal membranes. Electron microscopy showed that the Golgi fraction consisted of variably sized vesicles and cisternalike structures. The two lateral-basal membrane fractions showed only vesicles of smaller, more uniform size. After 125I labeling of isolated intact cells, radioactivity was found associated with the lateral-basal and microvillus membrane fractions and not with the Golgi fraction. Antibody prepared against lateral-basal membrane fractions reacted with the surface membrane of isolated villus cells. The membrane fractions from isolated crypt cells demonstrated that all had high glycosyltransferase activity. The data show that glycosyltransferase activity, in addition to its Golgi location, may be a significant property of the lateral-basal portion of the intestinal villus cell plasma membrane. Data obtained with crypt cells support earlier data and show that the crypt cell surface membrane possesses glycosyltransferase activity.     

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.     

Isolation and characterization of Neurospora crassa plasma membranes.

The isolation and characterization of plasma membranes from a cell wall-less mutant of Neurospora crassa are described. The plasma membranes are stabilized against fragmentation and vesiculation by treatment of intact cells with concanavalin A just prior to lysis. After lysis, the concanavalin A-stabilized plasma membrane ghosts are isolated by low speed centrifugation techniques and the purified ghosts subsequently converted to vesicles by removal of the bulk of the concanavalin A. The yield of ghosts is about 50% whereas the yield of vesicles is about 20%. The isolated plasma membrane vesicles have a characteristically high sterol to phospholipid ratio, Mg2+-dependent ATPase activity and (Na+ plus K+)-stimulated Mg2+ATPase activity. Only traces of succinate dehydrogenase and 5'-nucleotidase are present in the plasma membrane preparations.     

Characterisation of the H+-ATPase in plasma membranes isolated from the green alga Chlamydomonas reinhardtii

Plasma membranes from the green alga Chlamydomonas reinhardtii were purified by differential centrifugation and two-phase partitioning in an aqueous polymer system. The isolated plasma membranes were virtually free from contaminating chloroplasts, mitochondria, endoplasmic reticulum and Golgi membranes as shown by marker enzyme and pigment analysis. The isolated plasma membranes exhibited vanadate sensitive ATPase activity, indicating the presence of a P-type ATPase. This was verified by using antibodies against P-type ATPase from Arabidopsis , which crossreacted with a protein of 109 kDa. The ATPase activity was inhibited to more than 90% by vanadate (K_i= 0.9 μ M ) but not affected by inhibitors specific for F- or V-type ATPases. demonstrating the purity of the plasma membranes. Mg-ATP was the substrate, and the rate of ATP-hydrolysis followed simple Michaelis-Menten kinetics giving a K_m= 0.46 m M . Free Mg²⁺ stimulated the activity, K_1/2= 0.68 m M . Maximal activity was obtained at pH 8. The ATPase activity was latent but stimulated 10 to 20-fold in the presence of detergents. This indicates that the isolated plasma membrane vesicles were tightly sealed and mostly right-side-out, making the ATPase inaccessible to the hydrophilic substrate ATP. In the presence of the Brij 58, the isolated plasma membranes performed ATP dependent H⁺-pumping as shown by the optical pH probe acridine orange. H⁺-pumping was dependent on the presence of valinomycin and K⁺ ions and completely abolished by vanadate. Addition of Brij 58 has been shown to produce 100% sealed inside-out vesicles of plant plasma membranes (Johansson et al. 1995, Plant J. 7: 165–173) and this was also the case for plasma membranes from the green alga Chlamydomonas reinhardtii.     

Sub-cellular fractionation of Trypanosoma brucei. Isolation and characterization of plasma membranes

A procedure is described for the isolation of sub-cellular fractions from bloodstream forms of Trypanosoma brucei. The method leaves intact most of the nuclei, mitochondria and microbodies. All the fractions have been chemically characterized and tested for 10 enzymatic markers. About 5% of total cell protein was isolated as a microsomal fraction containing mostly plasma membranes and endoplasmic reticulum vesicles. Plasma membranes were purified by high-speed centrifugation on magnesium-containing Dextran, and on linear sucrose-density gradients. The yield of membranes was approximately 0.3% of the total cell protein. The purified material had a sucrose density of 1.14 g/cm3 and consisted of smooth vesicles. Specific activity of the membrane markers Na+, K+, ouabain-sensitive ATPase and adenylate cyclase were 26- and 20-fold higher, respectively, than in total cells. Neither DNA nor RNA was detected. The sum of the cholesterol and phospholipid content was 0.99 mg/mg protein. The cholesterol/phospholipid molar ratio was 1:2.     

Localization of phosphatases in Trypanosoma rhodesiense

Phosphatase activity in Trypanosoma rhodesiense has been examined histochemically by light and electron microscopy and by enzymatic assay in homogenate fractions. Using a method with lead as capture ion, acid phosphatase was found in lysosome-like vesicles and in the flagellar pocket. No alkaline adenosine triphosphatase (ATPase) was detectable by this method. Direct assay of p-nitrophenylphosphatase activity in homogenate fractions showed that acid phosphatase activity was strongly membrane-bound, but that activity at pH 9 was minimal in both soluble and particulate fractions. "Endogenous" ATPase activity was localized specifically and reproducibly in the mitochondrial membranes and under the plasma membrane of he flagellum. This nonenzymic reaction product could not be eradicated by glycerol extraction or glucose depletion. Unlike the membrane staining, which was manifest only after lead treatment, heat-resistant electron-dense material was found in the matrix of lysosomal vesicles in trypanosomes fixed in glutaraldehyde only and not subjected to further treatment with heavy metal reagents. X-ray emission analysis showed the presence of calcium and phosphorus, indicating that the matrix might have a phosphate storage function.     

Transbilayer mapping of membrane proteins using membranes isolated on polylysine-coated polyacrylamide beads

Erythrocyte and HeLa cell plasma membranes were isolated on polylysinecoated polyacrylamide beads and the transbilayer disposition of their proteins was investigated.When membranes of intact erythrocytes were isolated on beads and then labelled by lactoperoxidase-catalysed iodination, their labelling pattern was similar to that of inside-out vesicles in solution.When the membranes of intact HeLa cells were isolated on beads and then labelled by galactose oxidase-[³H]borohydride treatment, no glycoprotein or glycolipid sugars were accessible. On the other hand, when the HeLa cell membranes were isolated on beads and then labelled by the lactoperoxidase-catalysed iodination, all of the major membrane proteins were iodinated. These experiments confirmed for HeLa cell membranes what had previously been shown for erythrocyte membranes: when the membranes of intact cells are isolated on beads, the accessibility of their surfaces to enzymatic probes is the same as would be expected of inside-out vesicles in suspension. Double-label experiments, in which the HeLa cell membranes were labelled first on the intact HeLa cells and again after isolation on beads, identified several     

Effect of centrifugation on separation by aqueous two-phase partition of an early and late endosome model using inside-out plasma membrane vesicles from plants

Inside-out vesicles of plasma membranes prepared from a plant source were used as models to investigate effects of centrifugal forces on separations of early and late endosome populations by aqueous two-phase partition. Endosome subpopulations were resolved readily by preparative free-flow electrophoresis where acidification of the interiors of late endosomes occurred upon addition of ATP to activate a proton translocating ATPase. The resultant increased diffusion potential provided for a surface difference between late and early endosomes to permit electrophoretic separation. With the plant membranes, unincubated inside-out plasma membrane vesicles modeled early endosomes, whereas inside-out vesicles incubated with 1 mM ATP modeled late endosomes. A latent, 2,4-dichlorophenoxyacetic acid (2,4-D)-(auxin)-stimulated NADH:protein disulfide reductase measured spectrophotometrically was used as an enzymatic marker for both populations of inside-out vesicles. Phase partition behavior of each population was quantitated using total protein as the parameter.     

Isolation of Membrane Fractions with Sodium Channels Sensitive to Veratridine and tetrodotoxin from the Electric Organ of the Eel Electrophorus electricus

The veratridine/tetrodotoxin-sensitive sodium influx was measured in membrane fractions isolated from the electric organ of Electrophorus electricus. The fractions were characterized, and the main biochemical markers and their acetylcholine receptor content were determined. The innervated and noninnervated faces of the electroplax were separated. The different biochemical criteria used indicate that the pre- and postsynaptic membranes of the innervated face were isolated. Sodium influx increased by veratridine and blocked by tetrodotoxin was found in fractions from the presynaptic membrane. Because some of the vesicles in this fraction are in the inside-out conformation, tetrodotoxin had to be applied to both faces of the vesicles so that sodium influx was blocked completely. The fractions from the innervated face of the electroplax contained sodium channels with sensitivities to tetrodotoxin and veratridine similar to those of fractions from other nerve membrane preparations.