Plasma membranes from rat intestinal epithelial cells at different stages of maturation. I. Preparation and characterization of plasma membrane subfractions originating from crypt cells and from villous cells.

To determine the mechanism of the maturation of the brush border membrane in intestinal epithelial cells, purification of the plasma membrane from undifferentiated rat crypt cells and of the basal-lateral membrane from villous cells has been performed. The method is based on density perturbation of the mitochondria to selectively disrupt their association with the membrane. With both cell populations, two membrane subfractions displaying the same respective density on sucrose gradient have been obtained with an overall yield of 15--20% and a 10-fold enrichment of the plasma membrane markers 5'-nucleotidase and (Na+ + K+)-dependent, ouabain-sensitive ATPase chosen to follow their purification. The four fractions were constituted by sheets and apparently closed vesicles of various sizes. Each fraction was characterized by a distinct protein composition and different levels of enzyme activities. The cells, used for the preparation of the membranes, were isolated as a villus to crypt gradient. This separation and that of the membranes, led to the conclusion that the (Na+ + K+)-dependent ATPase is localized principally in the plasma membrane of all cells whatever their state of maturation, while 5'-nucleotidase is predominantly located in the basal-lateral membrane of the villous cells and may serve as a specific marker for the purification of this membrane. Finally it has been shown that aminopeptidase, dissacharidases and alkaline phosphatase do not appear simultaneously in the maturation process of the cells, alkaline phosphatase being absent from the crypt cells and aminopeptidase being the first to be synthesized. This enzyme seems to appear in the crypt cells membrane before being integrated into the mature brush border membrane.     

Isolation of plasma membranes from the bovine retinal pigment epithelium

Retinal pigment epithelium plasma membranes have been isolated by differential and density gradient centrifugation of glass-bead-bound, collagenase-treated cells. Electron microscopic evidence indicates that the glass-bead-bound cells were devoid of red blood cells, rod outer segments and other ocular cell contaminants. The plasma membranes were recovered in 4–6 μg/eye yields and purified 10-fold by 5′-nucleotidase and alkaline phosphodiesterase 1, and 6.5-fold by (Na⁺ + K⁺)-ATPase. Plasma membrane purity as measured by covalent labeling of the epithelial cell plasma membrane proteins with p-(diazonium) benzene[³²S]sulfonic acid was 8–19-fold. In purified plasma membranes contamination by mitochondria was undetectable and lysosomal contamination reduced 100-fold, while endoplasmic reticulum was 2-fold enriched. SDS-polyacrylamide gel electrophoresis of the plasma membrane proteins revealed 23–26 major bands by Coomassie blue staining and 12–16 major bands by radioactive labeling. The plasma membranes exhibited a 3-fold lower concentration of docosahexaenoic acid, a 3-fold higher cholesterol/phosphate ratio, and were 10-fold enriched in cholesterol per μg protein when compared to the whole cell fraction. Retinal epithelial plasma membranes contain an average of 1 mol cholesterol per mol of lipid phosphorus, a high palmitic acid concentration (39 mol%) and a low concentration of docosahexaenoic acid (2 mol%). The lipid profile of the retinal pigment epithelial plasma membranes indicates that they are typical of plasma membranes from many other cell types and that they appear to be less fluid than total rod outer segment membranes.     

Fast and efficient purification of yeast plasma membranes using cationic silica microbeads

A fast and efficient procedure for the purification of plasma membranes of Saccharomyces cerevisiae is described. Protoplasts served as starting material. They were coated with cationic silica microbeads. After lysis, the plasma membranes were washed free from debris and cell organelles. This procedure resulted in a high yield (about 85%) of plasma membranes, as judged by measuring vanadate-sensitive ATPase as a plasma membrane marker. The enzyme was enriched 12-fold relative to the homogenate after lysis. Its specific activity was 1.5--2.0 micromol/min per mg protein, the pH optimum was 6.5, and 10 microM vanadate was sufficient to obtain maximum inhibition. Based on the assay of internal markers and electron microscopic studies, we found our preparation essentially free of contamination from other cell organelles.     

Plasma membranes from rat intestinal epithelial cells at different stages of maturation. I. Preparation and characterization of plasma membrane subfractions originating from crypt cells and from villous cells

To determine the mechanism of the maturation of the brush border membrane in intestinal epithelial cells, purification of the plasma membrane from undifferentiated rat crypt cells and of the basal-lateral membrane from villous cells has been performed. The method is based on density perturbation of the mitochondria to selectively disrupt their association with the membrane. With both cell populations, two membrane subfractions displaying the same respective density on sucrose gradient have been obtained with an overall yield of 15–20% and a 10-fold enrichment of the plasma membrane markers 5′-nucleotidase and $\text{(}\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-dependent}$, ouabain-sensitive ATPase chosen to follow their purification. The four fractions constituted by sheets and apparently closed vesicles of various sizes. Each fraction was characterized by a distinct protein composition and different levels of enzyme activities. The cells, used for the preparation of the membranes, were isolated as a villus to crypt gradient. This separation and that of the membranes led to the conclusion that the $\text{(}\text{Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-dependent}$ ATPase is localized principally in the plasma membrane of all cells whatever their state of maturation, while 5′-nucleotidase is predominantly located in the basal-lateral membrane of the villous cells and may serve as a specific marker for the purification of this membrane. Finally it has been shown that aminopeptidase, disaccharidases and alkaline phosphatase do not appear simultaneously in the maturation process of the cells, alkaline phosphatase being absent from the crypt cells and aminopeptidase being the first to be synthesized. This enzyme seems to appear in the crypt cells membrane before being integrated into the mature brush border membrane.     

Rapid simultaneous isolation of microsomes and plasma membranes from neuroblastoma C 1300 N 18 cells

The method is suggested to isolate simultaneously microsomes and plasma membranes of neuroblastoma S 1300 N 18 cells by means of differential centrifugation in the step density gradient of Percoll/Ficoll with a high degree of purification determined from the activity of marker enzymes (acetyl cholinesterase Na+,K+-ATPase, alkali phosphatase, glucose-6-phosphatase, succinate-dehydrogenase, acid phosphatase) as well as from the content of DNA and RNA and with a sufficiently high protein yield. The purified fractions of microsomes and plasma membranes are established to contain no phosphatidyl glycerol and cardiolipin--safety markers of mitochondrial membrane purification. A degree of separation of microsomes, plasma membranes and proteins dissolved in cytosol may be estimated by the activity of the cholesterol-synthesizing system of enzymes with the use of sterol-transferring protein.     

Glycoproteins and antigens of membranes prepared from rat thymocytes after lysis by shearing or with the detergent Tween-40

In purification of cell surface antigens an efficient method for preparing membrane from large numbers of cells is needed. Such a method is described for preparing membranes from rat thymocytes after lysis in the non-ionic detergent Tween-40. Cell surface antigens were recovered at a yield of 30–50%, and a purification of 30–40-fold. By contrast enzyme markers for the other cell organelles were present in the membrane fraction in very low yield.The membrane obtained with the detergent method was compared with that resulting from the best of previously described methods involving cell lysis by shearing. The detergent method compared favourably for simplicity as well as for yield and purification, and both membrane preparations contained similar protein and glycoprotein constituents.The main glycoprotein bands of membranes from thymocytes and thoracic duct lymphocytes were identified after polyacrylamide gel electrophoresis in dodecyl sulphate. In thymocyte membrane, three main bands at apparent molecular weights of 150 000, 84 000 and 25 000 were seen, and of these the 84 000 glycoprotein did not bind to the lentil lectin. In thoracic duct lymphocyte membrane the 25 000 glycoprotein was absent and a band at 95 000 was intensified in comparison with thymocytes.     

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.     

Plasma membranes from rat Sertoli cells: purification and properties

A method is reported for preparing surface (plasma) membranes from rat Sertoli cells. The procedure is based upon homogenization in hypotonic buffer, extraction in a two-phase system, and sedimentation through two sucrose density gradients. The purified membranes consist of large sheets of membrane. The identity and purity of the membranes was demonstrated by electron microscopy, enzyme markers, and functional activities associated with the membranes (binding of follicle-stimulating hormone [FSH] and production of cyclic adenosine 5'-monophosphate [cAMP]. Electron microscopy showed membranes with small fragments of cytoplasm attached to the inside of the membrane sheets. Marker enzymes for plasma membrane (5'-nucleotidase and alkaline phosphatase) showed more than 16- and 6-fold enrichment, respectively, and other enzymes showed that contamination by nuclei, mitochondria, endoplasmic reticulum, or cytosol was negligible. Binding of FSH was found to be specific, with KD 1.2 nM and the equivalent of 7500 sites per cell. This binding was enriched 20-fold compared to whole homogenate. Production of cAMP by membranes was increased by addition of FSH and by forskolin to the purified membranes in vitro.     

Isolation of plasma membranes from rat lungs. Effect of age on the subcellular distribution of adenylate cyclase activity

A simple and rapid method of isolating plasma membranes from rat lungs is described. The method involves homogenization of tissue in isotonic sucrose-buffered medium followed by differential and sucrose density gradient centrifugation. Plasma membranes obtained by this procedure were essentially free from other subcellular contamination. Plasma membranes isolated from 2-day-old rat lungs showed 6 to 7-fold purification of adenylate cyclase and 5′-nucleotidase activities compared to the original homogenate In contrast, plasma membranes from 35-day-old rat lungs showed no purification of adenylate cyclase activity although 5′-nucleotidase activity showed similar enrichment. These results suggest that adenylate cyclase activity is not a reliable marker for plasma membranes from adult rat lungs.     

Isolation of plasma membranes from rat lungs: effect of age on the subcellular distribution of adenylate cyclase activity

A simple and rapid method of isolating plasma membranes from rat lungs is described. The method involves homogenization of tissue in isotonic sucrose-buffered medium followed by differential and sucrose density gradient centrifugation. Plasma membranes obtained by this procedure were essentially free from other subcellular contamination. Plasma membranes isolated from 2-day-old rat lungs showed 6 to 7-fold purification of adenylate cyclase and 5'-nucleotidase activities compared to the original homogenate. In contrast, plasma membranes from 35-day-old rat lungs showed no purification of adenylate cyclase activity although 5'-nucleotidase activity showed similar enrichment. These results suggest that adenylate cyclase activity is not a reliable marker for plasma membranes from adult rat lungs.     

A characterization of gamma-glutamyltranspeptidase in normal, perinatal, premalignant and malignant rat liver

gamma-Glutamyltranspeptidase displays the following order of activity in tissues of the Fischer 344 rat: kidney much greater than small intestine much greater than cerebral cortex = testis greater than lung much greater than liver = heart. The activity of the hepatic enzyme in rats is: 4-fold higher in females than males; 4-fold higher in male Wistar, Sprague-Dawley and Zucker rats than male Fischer 344 rats; increased 10-fold in very old vs young male Fischer 344. The hepatic enzyme displays significant species variation: the mouse and rat liver enzymes are similar and low in activity, while duck, dog, pig and beef enzymes are 7, 13, 86 and 92-fold higher, respectively, in activity than the male Fischer rat liver enzyme. A liver plasma membrane isolation procedure has been devised which selects for the sinusoidal face of the liver parenchymal cell as assessed by marker enzyme analysis: for these plasma membranes the purification of gamma-glutamyltranspeptidase is 21.5 and the recovery is 42% indicating that this is the cellular and subcellular locus of the enzyme in rat liver. The characteristics of the liver plasma membrane from female rats are: pH optimum of 8.0; classical Michaelis-Menten kinetics; Km of 1.43 mM and Vmax of 33.3 nmol X mg-1 X min-1. In Fischer 344 rats, gamma-glutamyltranspeptidase activities are elevated over adult levels in perinatal liver: in fetal liver homogenates and plasma membranes the activities are increased 179 and 109-fold, respectively. The activity peaks just after birth and declines rapidly over the first 15 postnatal days. The activity of the liver enzyme in the male Fischer 344 rat exhibits a progressive increase throughout diethylnitrosamine-induced hepatocarcinogenesis: it is increased 7.8-fold in homogenates and 5.4-fold in plasma membranes at the early premalignant stage; 74-fold in homogenates and 31-fold in plasma membranes at the later hyperplastic nodular premalignant stage; and 174-fold in homogenates and 61-fold in plasma membranes at the hepatoma stage. The gradual drop in purification during hepatocarcinogenesis is associated with the appearance of the enzyme in the blood.     

A novel technique for gentle lysis of eucaryotic cells Isolation of plasma membranes from Dictyostelium discoideum

A new type of lysis technique for eucaryotic cells was used for the isolation of highly purified plasma membranes from Dictyostelium discoideum. Suspensions of amoebae (10 μm diameter) were lysed by forced passage through Nuclepore filters with pores of 5 μm diameter. Virtually complete lysis was effected with minimal fragmentation of lysosomes and mitochondria. By subsequent differential and isopycnic centrifugation, 25–35-fold purified plasma membranes were isolated in 35–50% yield for cells from vegetative through tip formation stages of development. Lysis, yield and purity were enhanced by use of slightly alkaline conditions. Contamination with other organelles and with soluble proteins was found to be minimal. At each developmental stage, the plasma membranes generated three closely-spaced, equally pure bands in a sucrose density gradient. Two-dimensional electrophoretic analysis of the individual bands showed that they were very similar to each other, indicating that the density differences are not due to gross differences in protein composition.     

Isolation of adenylate cyclase-enriched membranes from mammalian cells using concanavalin A.

Plasma membrane vesicles containing adenylate cyclase and beta-adrenergic receptors were prepared from 1321N1 human astrocytoma cells by a procedure involving the use of concanavalin A to stabilize the plasma membrane to fragmentation and vesiculation upon cell lysis. Treatment of cells with concanavalin A causes these plasma membrane markers to sediment to a higher density of sucrose and in a narrower band than observed with untreated cells. Upon treatment of the heavy membrane fragments with alpha-methylmannoside to remove bound concanavalin A, the enzyme markers again sediment a lower densities of sucrose. This reversible change in sedimentation behavior has been used to obtain preparations of plasma membranes enriched 14- to 21-fold (recovery 25%) in adenylate cyclase activity and about 12-fold (recovery 16%) in beta-adrenergic receptor density, as compared to lysates. The adenylate cyclase of purified membranes responded normally to isoproterenol and prostaglandin E1. Experiments with S49 and YAC mouse lymphoma cells and human skin fibroblasts indicate that this procedure may be adaptable to the isolation of plasma membranes from a variety of cultured cell lines.     

Use of a novel rapid preparation of fat-cell plasma membranes employing Percoll to investigate the effects of insulin and adrenaline on membrane protein phosphorylation within intact fat-cells.

1. A rapid method was developed for the preparation of plasma membranes from either isolated rat fat-cells or intact epididymal fat-pads with the use of density-gradient centrifugation in the presence of Percoll. On the basis of 5'-nucleotidase activity, the yield of plasma membranes was about 50% and purification over 10-fold. Activities of marker enzymes indicated that contamination by mitochondria and microsomal fraction was small. 2. Incorporation of 32Pi into proteins associated with plasma membranes within isolated fat-cells was investigated. Four major bands of labelled phosphoproteins were separated by sodium dodecyl sulphate/polyacrylamide-slab-gel electrophoresis; the apparent subunit mol.wts. were 67 000, 61 000, 26 000 and 20 000. None of these phosphoprotein bands corresponded to periodate/Schiff-staining glycoproteins. The extent of phosphorylation of the 61 000 mol.wt phosphoprotein band was increased by about 30 and 60% after exposure of fat-cells for 15 min to insulin or adrenaline respectively.     

The plasma membrane ATPase of Dictyostelium discoideum

During centrifugation of Dictyostelium membranes on sucrose and metrizamide gradients, an ATPase activity resistant to azide and molybdate but sensitive to diethylstilbestrol was found to copurify with the plasma membrane markers alkaline phosphatase and ¹²⁵I in cells surface-labelled by lactoperoxidase catalyzed iodination. This ATPase was enriched 50-fold in purified plasma membranes and could be separated from the mitochondrial ATPase on metrizamide gradients. The plasma membrane ATPase is very specific for ATP as substrate and Mg²⁺ as essential cofactor. Its pH optimum is 6.5 and it is inhibited by dicyclohexylcarbodiimide, diethylstilbestrol, vanadate, mercurials and Cu²⁺, but not by ouabain, molybdate, azide or oligomycin. It was not specifically affected by either monovalent cations or anions. These results suggest that the plasma membranes of Dictyostelium contain an ATPase similar to the proton-pumping ATPases recently identified in fungal and plant plasma membranes (Serrano, R. (1984) Curr. Top. Cell. Regul. 23, 87–126).     

Isolation and characterization of the plasma membrane of L-1210 cells. Iodination as a marker for the plasma membrane.

Mouse leukemia L-1210 cells were iodinated with 125I; this permitted the development of a method for the isolation of the plasma membranes. These show a 10- to 16-fold increase in the specific activity of 125I over that of the cell homogenate and a 20-fold increase in the specific activities of 5'-nucleotidase and alkaline phosphatase; 20-fold increase in the specific activities of 5'-nucleotidase and alkaline phosphatase; no mitochondrial or microsomal marker enzyme activities were detected. Sodium dodecyl sulfate gel electrophoresis of the plasma membranes shows approx. 40 peptides with molecular weights ranging from 10 000 to over 200 000; a polypeptide (Mr 50 000) predominates. Of 13 iodinated surface membrane proteins, the major radioactive peptide has a molecular weight of 85 000. The importance of the selection of the appropriate gel system for the analysis of membrane proteins is emphasized.     

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.     

Membrane receptors as general markers for plasma membrane isolation procedures. The use of 125-I-labeled wheat germ agglutinin, insulin, and cholera toxin.

Specific cell surface membrane receptors, labeled by forming a complex with low concentrations (about 10--9 M to 10--10 M) of a highly radioactive (125-I, carrier-free) ligand, can serve as simple, reliable, sensitive, and quantitative markers for plasma membranes in fractionation procedures. 125-I-Labeled insulin, cholera toxin and the plant lictins, wheat germ agglutinin (WGA), and concanavalin A are the receptor ligands used for labeling plasma membranes. Plasma membranes are labeled before homogenization by incubating intact cells briefly at 24 degrees or 4 degrees, or by very brief in situ perfusion of the organ, with the 125-I-Labeled marker. After removing the free 125-I-labeled ligand from the medium by washing (at 4 degrees), the membrane-marker complex remains intact over prolonged (days) periods of time at 4 degrees. Labeling occurs nearly exclusively on the cell surface, the specificity of this plasma membrane reaction is maintained through homogenization and fractionation, and little dissociation of the complex, detectable exchange of label, or aggregation occur even upon prolonged incubation of the homogenates. When desired, the complex can be dissociated deliberately by manipulating experimental conditions such as temperature or by adding specific simple sugars. The most generally suitable marker appears to be WGA. At least in certain tissues (e. g. fat cells) labeling of the plasma membrane with 125-I-WGA and 125-I-isnulin can be performed equally well and selectively in homogenates as in the intact cell. 125-I-Cholera toxin cannot be used in homogenates because of significant binding to nuclei. The use of 125-I-labeled WGA as a specific plasma membrane marker is illustrated in following the course of fractionations, and in quantitating the yield and purity, of plasma membranes from fat cells, lymphocytes, and liver. The results are compared with simultaneous measurements of the plasma membrane enzyme "markers," ATPase, 5-nucleotidase, and basal as well as hormone-stimulated adenylate cyclase activities. The fractionation of liver plasma membranes by aqueous dextran-polyethylene glycol two-phase polymer systems and by conventional differential centrifugation procedures arealso quantitated with the marker, 125I-WGA. Substantial quantities of plasma membrane material are no recovered in the interphase of the two-phase polymer system. Conventional liver fractionation procedures which retain, for further purification, only the readily sedimented pellet (2000 times g, 15 min) discard a very large (at least 70%) questenal hy     

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.     

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.