Random, presumably hydrolytic, and lysosomal glycogenolysis in the livers of rats treated with phlorizin and of newborn rats.

A method was developed for the analytical and preparative isolation of basolateral plasma membranes from rat small intestine. They were separated on a self-orientating Percoll (modified colloidal silica) gradient starting with a heavy microsomal-membrane fraction and involving centrifugation at 48,000 g for 1 h. (Na+ + K+)-stimulated ATPase activity, used as a marker enzyme for the basolateral plasma membrane, is enriched 20-fold compared with that found in the homogenate of isolated intestinal epithelial cells.     

An investigation into the feasibility of using azide-insensitive ATPase and ConA as yeast plasma membrane markers

Cytochemical localization of Concanavalin A binding sites in protoplasts of Candida tropicalis, investigated with glycosylated-ferritin and electron microscopy, showed that the lectin was specifically bound to the external protoplast surface. Thus, the plasma membranes have been labelled with ¹²⁵I-Concanavalin A and followed through the isolation procedure. Relative distribution of ¹²⁵I-radioactivity and azide-insensitive ATPase activity in the obtained fractions, suggested that this enzyme was an equivocal plasma membrane marker. Despite the presence of internal Concanavalin A binding sites, Concanavalin A could be used unambiguously as an exogenous plasma membrane marker of intact protoplasts.Abbreviations ConA Concanavalin A - MM -Methyl-D-Mannoside     

Purification of plasma membrane from Acanthamoeba castellanii

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.     

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 the dorsal, ventral and intracellular domains of HeLa cell plasma membranes following adhesion to a gelatin substrate

The plasma membrane is a complex organelle responsible for many cellular functions. In addition to mediating the exchange of components with the extracellular fluid, the plasma membrane is involved in cell adhesion to matrix proteins in vivo and in vitro. In vitro, adherent cells have three distinct plasma membrane domains to carry out these functions: one attached to the substrate (ventral); another exposed to the media (dorsal); and an intracellular domain involved in endocytosis and secretion. A technique has been developed for the rapid isolation of these specific domains from HeLa cells immediately following adhesion to a gelatin substrate. The isolation procedure utilizes the tight binding of cationic colloidal silica to the dorsal plasma membrane domain of attached cells. Following silica binding and cell lysis, the silica-coated dorsal plasma membrane domain is readily separated from intracellular plasma membrane components by virtue of the high density of the silica pellicle, and the intact ventral plasma membrane domain remains attached to the gelatin substrate. Fluorescence and electron microscopy and biochemical studies using 125I-lactoperoxidase labeling, 125I-labeled wheat germ agglutinin binding, and [3H]-fucose incorporation into plasma membrane glycoproteins confirmed the separation of these three topologically distinct plasma membrane domains. The fractions isolated by the technique contained essentially all of the plasma membrane components present in intact cells. This unique membrane-isolation procedure is now being used to analyze membrane flow during plasma membrane domain formation accompanying cell adhesion to an extracellular matrix.     

Trafficking of the plant potassium inward rectifier KAT1 in guard cell protoplasts of Vicia faba

Trafficking of K+ inward (Kin+) rectifying channels was analyzed in guard cells of Vicia faba transfected with the Kin+ rectifier from Arabidopsis thaliana KAT1 fused to the green fluorescent protein (GFP). Confocal images and whole-cell patch-clamp measurements confirmed the incorporation of active KAT1 channels into the plasma membrane of transfected guard cell protoplasts. The Kin+ rectifier current density of the plasma membrane was much larger in transfected protoplasts than in wild-type (wt) protoplasts. This shows a coupling between K+ channel synthesis and incorporation of the channel into the plasma membrane. Pressure-driven increase and decrease in surface area led to the incorporation and removal of vesicular membrane carrying active Kin+ rectifier in wt and transfected protoplasts. These vesicular membranes revealed a higher channel density than the plasma membrane, suggesting that Kin+ rectifier remains in clusters during trafficking to and from the plasma membrane. The observed results can be explained by a model illustrating that vesicles of a pre-plasma membrane pool carry K+ channels preferentially in clusters during constitutive and pressure-driven exo- and endocytosis.     

Biochemical characterization of plasma membrane H+-ATPase activation in guard cell protoplasts of Arabidopsis thaliana in response to blue light

Recent genetic analysis showed that phototropins (phot1 and phot2) function as blue light receptors in stomatal opening of Arabidopsis thaliana, but no biochemical evidence was provided for this. We prepared a large quantity of guard cell protoplasts from Arabidopsis. The immunological method indicated that phot1 was present in guard cell protoplasts from the wild-type plant and the phot2 mutant, that phot2 was present in those from the wild-type plant and the phot1 mutant, and that neither phot1 nor phot2 was present in those from the phot1 phot2 double mutant. However, the same amounts of plasma membrane H+-ATPase were found in all of these plants. H+ pumping was induced by blue light in isolated guard cell protoplasts from the wild type, from the single mutants of phototropins (phot1-5 and phot2-1), and from the zeaxanthin-less mutant (npq1-2), but not from the phot1 phot2 double mutant. Moreover, increased ATP hydrolysis and the binding of 14-3-3 protein to the H+-ATPase were found in response to blue light in guard cell protoplasts from the wild type, but not from the phot1 phot2 double mutant. These results indicate that phot1 and phot2 mediate blue light-dependent activation of the plasma membrane H+-ATPase and illustrate that Arabidopsis guard cell protoplasts can be useful for biochemical analysis of stomatal functions. We determined isogenes of the plasma membrane H+-ATPase and found the expression of all isogenes of functional plasma membrane H+-ATPases (AHA1-11) in guard cell protoplasts.     

A Rapid and Reproducible Hcmogenization Procedure for the Isolation of Plasma Membranes from Rat Liver

A simplified modification of the Neville procedure for the isolation of plasma membranes from rat liver is described in which cells are broken by low-shear homogenizetion with a Polytron homogenizer. Plasma membranes are recovered from the homogenates by differential and discontinuous sucrose gradient centrifugetions. The procedure provides plasma membrane fractions enriched 25-fold for AMPase, a marker enzyme for the plasma membrane of rat liver, with a combined contamination from endoplasmic reticulum, Golgi apparatus and mitochondria of less than 10% The procedure is uncomplicated, reproducible, and yields enzymatically active plasma membrane fractions of high purity.     

Rapid procedure for preparation of macrophage plasma membrane

This report describes a simple and efficient procedure for the isolation of plasma membrane from guinea pig peritoneal macrophages. The use of polycationic beads (Affi-gel 731 beads) facilitates rapid and high-clear separation of plasma membrane within 30 min. The final plasma membrane coated beads fraction has high specific activities of marker enzymes with little contamination with mitochondrial, lysosomal or cytoplasmal markers.     

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.     

New Procedure for the Isolation of Membrane Vesicles of Bacillus subtilis and an Electron Microscopy Study of Their Ultrastructure

A rapid procedure for the isolation of membrane vesicles of Bacillus subtilis is described that minimizes the action of proteolytic enzymes, excreted by this organism, on the membrane proteins. The membrane vesicles obtained have, in addition to a low endogenous respiration rate, a low endogenous activity for transport of amino acids and carboxylic acids. In the presence of the electron donor, ascorbate-phenazine methosulfate, the transport activities for these compounds were comparable to the activities of intact cells. In addition, these activities were retained for a prolonged period of time. Electron microscopy examination of thin sections of the vesicles showed that the preparation consisted almost exclusively of membrane vesicles which were not contaminated with other cell components. The membrane vesicles, which are six to seven times smaller in diameter than protoplasts, often enclosed smaller vesicles. Freeze-etching of intact cells, protoplasts, and membrane vesicles showed that the orientation of the membrane of the vesicles was identical to the orientation of the plasma membrane in intact cells and protoplasts. This also held for the majority of the membranes of the enclosed vesicles, only 15% having the opposite orientation.     

The use of colloid gold labelling in the detection of plasma membrane from symbiotic and non-symbiotic Glycine max root cells

Glycine max L. Merr. cv. Maple Arrow protoplasts were prepared from both tissue-cultured root cells and symbiotically-infected (fix⁺) nodule cells. Whilst both cell types showed glucan synthetase II (GS II; EC 2.4.1.29) activity, neither cell type, whole or gently disrupted, showed glucan synthetase I activity. After sucrose density gradient centrifugation one of the several GS II activity peaks co-sedimented with the single radioactive particulate peak from [¹²⁵I]-labelled protoplasts at 1.14 g ml⁻¹. This peak is presumed to be the plasma membrane peak because labelling of protoplasts with colloidal gold prior to disruption moved the ¹²⁵I peak and the corresponding glucan synthetase II activity into denser regions of the gradient, leaving endoplasmic reticulum-contaminating IDPase (EC 3.1.3.31) and other glucan synthetase II peaks unmoved. Results are discussed in relation to various strategies of plasma membrane isolation.     

Early stages in Bacillus subtilis transformation: association between homologous DNA and surface structures.

The addition of ethylenediaminetetraacetate to competent cultures of Bacillus subtilis irreversibly inhibited the transformability as well as the cellular binding of DNA. Our results show that the inhibition of DNA binding by ethylenediaminetetraacetate in whole cells, protoplasts, and membrane vesicles is mainly due to a permanent alteration of the DNA receptors. Transformation absolutely requires free magnesium ions, whereas DNA binding is a magnesium-independent step. In contrast to ethylenediaminetetraacetate, the absence of Mg2+ does not irreversibly affect the capacity of the competent cells to be transformed DNA-binding receptors located at the cell surface remain associated with the plasma membrane after protoplasting and after isolation of membrane vesicles. A Mg2+-dependent endonucleolytic activity associated with the membrane appears to be responsible for the lower levels of binding by protoplasts in the presence of this ion.     

Plasma membrane isolated with a defined orientation used to investigate protein topography

An investigation into the protein topography of tomato plasma membrane proteins was undertaken. Plasma membrane was isolated by phase partitioning to expose the extracellular leaflet, and by coating the protoplasts with silica microbeads to expose the cytosolic surface. Marker enzyme analysis indicated that both methods yielded relatively pure plasma membrane. Orientation of these plasma membrane fractions was established by investigating the latency of H⁺-ATPase activity. Triton X-100 stimulated H⁺-ATPase activity by 6-fold in the phase-partitioned plasma membrane fraction but did not stimulate this enzyme in the silica microbead-isolated plasma membrane. The impermeant photoactivable probes, 3-azido-(2,7)-naphthalene disulfonate and 5-azido-1-naphthalene monosulfonate, were used to probe the hydrophilic and hydrophobic regions of the plasma membrane, respectively. Using 5-azido-1-naphthalene monosulfonate, six proteins were labeled from the cytosolic leaflet of the plasma membrane and five proteins were labeled from the extracellular leaflet. Only two proteins were labeled by 3-azido-(2,7)-naphthalene disulfonate, and these were from the cytosolic-facing leaflet. The results indicate that these photoactive probes can be used in conjunction with aqueous two-phase partitioning and silica microbeads for transmembrane mapping of plasma membrane proteins.     

Isolation of a synaptic membrane fraction enriched in cholinergic receptors by controlled phospholipase A2 hydrolysis of synaptic membranes.

A procedure is described for the isolation of synaptic membrane fragments that retain such functionally important proteins as acetylcholine receptors, acetylcholinesterase, 3',5'-cyclic nucleotide phosphodiesterase, and (Na+ + K+)-ATPase. The method is based on the observation, made in brain slices, that junctional membranes are more resistant to phospholipase A2 attack than mitochondrial or plasma membranes. Hydrolysis by phospholipase A2 was controlled by addition of fatty acid-free bovine serum albumin. The membrane fraction obtained represents approximately a 15-fold enrichment of the postsynaptic marker proteins muscarinic and nicotinic acetylcholine receptor and 3',5'-cyclic nucleotide phosphodiesterase over an ordinary synaptic plasma membrane preparation, and is devoid of mitochondrial and microsomal contaminations. The membranes appear on the electron micrographs as rigid fragments (average length 2500-4000A), which do not form vesicles.     

Presence of a Na+-activated ATPase in the Plasma Membrane of the Marine Raphidophycean Heterosigma akashiwo

Highly purified plasma membranes were isolated from Heterosigmaakashiwo cells, a marine raphidophycean unicellular biflagellate,by the silica microbead method, and the ATPase activity of themembranes was characterized. The ionic requirements and spectrumof effective inhibitors enable us to identify a novel Na⁺-activatedATPase in the plasma membrane of this organism. Furthermore,we detected two phosphorylated intermediate forms of ATPases,with molecular weights of 150 kDa and 95 kDa as judged by acidSDS-polyacrylamide gel electrophoresis of extracts of isolatedplasma membrane. The 150 kDa intermediate was phosphorylated in the presenceof both Mg²⁺ and Na⁺, while the 95 kDa intermediate was phosphorylatedin the presence of Mg²⁺ alone. Both were dephosphorylated inthe presence of monovalent cations. These results indicate thatthe former intermediate was a Na⁺-activated ATPase, similarto Na⁺,K⁺-ATPases from animals, and the latter was similar toH⁺,K⁺-ATPases from higher plants. The physiological significanceof the two kinds of ATPase in the plasma membrane of marinealgae. (Received March 15, 1989; Accepted June 23, 1989)     

Plasma membranes of human neutrophils: a one-step isolation procedure by cell disruption in paraffin oil

Plasma membranes of high purity and good yield have been prepared from human polymorphonuclear neutrophils by a one-step procedure involving disruption of cells suspended in paraffin oil and forced by pressure through an annular slit. This results in a band floating above the oil which is composed of large sheets of plasma membranes. Enrichment values for the plasma membrane marker alkaline phosphatase and 125I-labeled protein after surface labeling performed at the whole cell level were 23-fold and 22-fold, respectively. Contamination of the plasma membrane by other organelles was negligible and approximately 2 mg of membrane protein was obtained from 10(9) neutrophils. The procedure is very fast and the use of paraffin oil avoids lengthy high-speed centrifugation. The technique also allows isolation of granules devoid of plasma membrane and can probably be applied to other cell types.     

The Isolation of Plasma Membrane from Vicia faba Leaves and Pollen Tubes of Luffs cylindrica by the Two-Polymer Phase System

A method for the isolation of plasma membrane enriched fraction from plant sources is described. An aqueous two-phase system is suitable for the isolation of plasma membrane. Purified plasma membrane fractions have been prepared from Vicia faba leaves and pollen tubes of Luffa cylindrica. The determination of marker enzymes shows that the plasma membrane has a high affinity for the polyethylene glycol-rich upper phase, whereas those membranes from mitochondria, chloroplasts and other organelles prefer the dextran-rich lower phase and the interface. The plasma membrane was identified with the aid of silicotungstic acid-chromic acid staining. In the upper phase there are mainly stained elliptical vesicles, whereas in the lower phase there are many differnet kind of unstained vesicles. This result is coincident with the marker enzyme examination. The two-phase method for the isolation of plasma membrane may be widely applied not only to nongreen tissues but also to green tissues of plants.     

Isolation of surface lectins of GH3 cells from whole cells and isolated plasma membranes

Lectins localized in the plasma membranes seem to be of special importance for the intercellular interaction mechanisms. We describe the isolation of mannose-binding proteins by Triton X-100 extraction and affinity chromatography on agarose-bound mannose. The isolation procedure was performed with whole GH₃ cells as well as with isolated plasma membranes. For the isolation of plasma membranes of GH₃ cells a mechanical pump was used for the disruption. After differential centrifugation an enriched plasma membrane fraction was achieved by discontinuous sucrose gradient centrifugation. The whole fractionation procedure was controlled by total balance sheets for the marker enzymes of the different cell organelles. The plasma membrane fraction was further characterized by gel electrophoresis and electron microscopy. The SDS gel electrophoresis patterns of the proteins, resulting from the Triton X-100 extraction and the affinity chromatography, are nearly identical for whole cells as well as for the enriched plasma membrane fraction. Therefore we presume these mannose-specific proteins to be plasma membrane bound, showing the molecular properties of integral proteins and having a molecular weight of $\text{M}{}_{\mathrm{<mtext>r</mtext>}}$ 67 000, 57 000, 47 000.