Cell surface and metabolic labelling of the proteins of normal and transformed chicken cells.

We have studied the surface proteins of normal and transformed chick cells using four-labelling techniques with different specificities, (a) lactoperoxidase catalysed iodination (b) galactose oxidase/B3H4 (c) pyridoxal phosphate/B3H4 and (d) periodate/B3H4. All methods labelled a large external transformation-sensitive (LETS) protein, in agreement with previous studies. In addition, using galactose oxidase and periodate labelling techniques, we present evidence which suggests that the transformed cell surface glycoproteins are more sialylated. The LETS protein was also labelled with (14C) glucosamine and after trypsinization a small band of identical molecular weight to LETS remained, possibly representing an internal pool of the protein. In contrast LETS protein labelled with (3H) fucose was completely removed by trypsin, suggesting that the internal pool of the protein is incompletely glycosylated. Evidence is also presented to show that although the level of the protein is drastically reduced at the transformed cell surface, it is still synthesised and shed into the medium.     

Plasmodium berghei: modification of sialic acid on red cells from infected mouse blood

The surface membrane glycoproteins of normal mouse erythrocytes can be labeled by oxidation with either periodate or galactose oxidase in the presence of neuraminidase, followed by reduction with NaB³H₄. Without neuraminidase there is little galactose oxidase-catalyzed labeling of protein. Analysis of labeled proteins by SDS-polyacrylamide gel electrophoresis showed that both methods labeled the same set of glycoproteins. Plasmodium berghei infection dramatically reduced the sialoglycoprotein labeling of red blood cells from infected blood using the periodate/NaB³H₄ method. Provided neuraminidase was present, labeling by the galactose oxidase method gave identical results to normal erythrocytes. We conclude that the glycoprotein sialic acid of uninfected as well as infected red cells is modified during infection such that it is refractory to periodate oxidation. Acylation of the exocyclic hydroxyls of sialic acid is suggested to account for this. Lectin binding and cell agglutination experiments using Limulin, soybean and wheatgerm lectins, and concanavalin A confirmed and extended these observations. The possible implications of these results with regard to anemia induced by malaria are briefly discussed.     

Exposure of major glycolipids in human Pk and p erythrocytes

The exposure of glycolipids in P^k and p red cells was studied by the galactose oxidase/ NaB²H₄ and galactose oxidase/NaB³H₄ surface labeling techniques. The major glycolipid in P^k cells, ceramide trihexoside was efficiently labeled when high amounts of galactose oxidase were used. In contrast, the major glycolipid in p cells, ceramide dihexoside was not oxidized by galactose oxidase. However, minor components with longer oligosaccharide chains were readily labeled in p cells by the galactose oxidase/NaB³H₄ method.Abbreviations CDH ceramide dihexoside, LacCer - CTH ceramide trihexoside, GbOse₃Cer     

Altered Cell surface glycoproteins in phytohemagglutinin-resistant mutants of Chinese hamster ovary cells

Purified membranes from surface-labelled phytohemagglutinin-resistant (Pha^R) and wild-type chinese hamster ovary cells have been analysed by sodium dodecyl sulphate gel electrophoresis. Gel patterns were compared for cells labelled via galactose oxidase and B³H₄ or lactoperoxidase and radioactive iodide. The results suggest that Pha^R cells are altered in the carbohydrate portion of a number of their membrane glycoproteins.     

Identification of differences between the surface proteins and glycoproteins of normal mouse (Balb/c) and human erythrocytes

Summary The topography of the external surface of the Balb/c mouse erythrocyte has been investigated and compared to the human erythrocyte by using a series of protein radiolabeling probes. After sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the pattern of Coomassie Blue stained proteins was very similar for mouse and human erythrocyte ghosts, as was the distribution of radioactivity in protein bands after lactoperoxidase catalyzed radioiodination. The mouse erythrocyte glycoproteins identified by periodic-acid-Schiff and Stains-All reagents, sialic acid analysis of gel slices, binding of¹²⁵I-wheat germ agglutinin and¹²⁵I-concanavalin A to the gels, and glycoprotein radiolabeling techniques, differed markedly from the sets of proteins labeled by radioiodination, and also differed from the human erythrocyte glycoproteins. Instead of the PAS I to PAS IV series of sialoglycoproteins characteristic of human erythrocytes, the mouse erythrocyte possesses a broad band of sialoglycoproteins with several peaks ranging in mol wt from 65,000 to 32,000. The same group of sialoglycoproteins were labeled by the periodate/B³H₄ ^– technique specific for terminal sialic acid, and the galactose oxidase/B³H₄ ^– method (plus neuraminidase) specific for galactosyl/N-acetylgalactosaminyl residues penultimate to sialic acid. These results emphasize the necessity to employ a variety of protein radiolabeling probes based on different labeling specificities, to study the membrane topography of cells which are poorly understood compared to the human erythrocyte membrane.     

Identification of exposed surface glycoproteins in undifferentiated and differentiated mouse N-18 neuroblastoma cells

A simple method is described that permitted rapid isolation of plasma membranes from mouse N-18 neuroblastoma cells. The purified plasma membranes gave a 10-fold increase in the specific activity of incorporated [³H]fucose over that of the cell homogenate. The specific activities of two other membrane markers, 5′-nucleotidase and alkaline phosphatase, increased 11-fold and 15-fold, respectively. Metabolic labeling with [³H]fucose identified a major fucosyl glycoprotein with apparent molecular weight of 92 000. Three surface labeling methods together with SDS-polyacrylamide gel electrophoresis and fluorography were used to characterize and compare the surface glycoproteins of undifferentiated and differentiated N-18 cells. The galactose oxidase/NaB³H₄ method labeled two major galactoproteins (M_r = 52 000, 42 000) in both undifferentiated and differentiated cells. The neuraminidase/galactose oxidase/NaB³H₄ method revealed many sialylgalactoproteins. Among them, the 220-kdalton, 150-kdalton and 130-kdalton bands were at least 100% more prominently labeled in the differentiated calls whereas the 76-kdalton and 72-kdalton bands were less prominently labeled in the differentiated cells when compared to their undifferentiated counterparts. The prominently iodinated protein bands in the undifferentiated cells had apparent molecular weights of 130 000, 92 000, 76 000 and 72 000 as compared to 150-, 130-, 92- and 76-kdalton bands in the differentiated cells. The labeling data obtained will enable us to further study the changes of these identified surface glycoproteins, both quantitatively and topologically, during the differentiation of neuroblastoma cells.     

Isolation and partial characterization of “galactoprotein a” (LETS) and “galactoprotein b” from hamster embryo fibroblasts

The cell surface glycoproteins of hamster NIL cells, labeled with galactose oxidase and NaB³H4, were selectively solubilized by sequential extraction with Tris buffer containing 1) sucrose-ATP-EDTA, 2) zwitterionic detergent (Empigen BB), and 3) 8 M urea. The previously reported “galactoprotein b” $\text{(Gap b)}$ and “galactoprotein a” ($\text{Gap a}$ or LETS) were isolated by affinity chromatography on insoluble Ricinus communis lectin colums (RCA column) from extracts 2) and 3), respectively. The affinity-purified $\text{Gap a}$ contained an actin-like protein, whereas the other affinity-purified galactoproteins did not contain the actin-like protein. The isolated $\text{Gap b}$ was heterogeneous, and an additional glycoprotein, specific for NILpy cells was copurified on RCA-column with $\text{Gap b}$.     

Enzymatic and chemical oxidation of gangliosides in cultured cells: effects of choleragen.

Cell surface glycolipids of normal human fibroblasts and NCTC2071 cells (transformed mouse fibroblasts) were labeled by incubating the intact cells with either galactose oxidase or sodium periodate, followed by reduction of the oxidized sugar residues with NaB3H4. In intact human fibroblasts, incorporation of 3H was increased with increasing time of exposure to galactose oxidase prior to treatment with NaB3H4. Following limited exposure to galactose oxidase, more label was incorporated into the larger glycolipids. Although labeling of the monosialoganglioside GM1 was maximal by 16 h, not all of the GM1 in the intact cells appeared to be accessible to galactose oxidase, since 10 to 12 times more GM1 was labeled when cells were disrupted before incubation with the enzyme. The human fibroblasts contained approximately 8 X 10(6) molecules of GM1 per cell. Maximal binding of choleragen (5 X 10(5) molecules of [125I]choleragen per cell) completely prevented cholevented oxidation of GM1 in intact fibroblasts by galactose oxidase but only partially protected the sialic acid moiety of GM1 from oxidation by periodate. Choleragen had little effect on the enzymatic or chemical oxidation of other glycolipids. NCTC 2071 cells do not contain endogenous GM1 but incorporate exogenous GM1 from the culture medium. When bound to NCTC 2071 cells, exogenous GM1 was protected by choleragen from oxidation by galactose oxidase or whether endogenous or taken up from the incubation medium, are, after interaction with choleragen, less accessible to oxidation by periodate or galactose oxidase.     

An evaluation of techniques for labelling the surface proteins of cultured mammalian cells

We have evaluated four techniques for labelling the surface proteins of cultured mammalian cells. The techniques are: (a) the lactoperoxide system; (b) the pyridoxal phosphate-[³H]borohydride system; (c) the [³H]4,4′-diisothiocyano-2,2′-dihydrostilbene disulfonate system and (d) the galactose oxidase-[³H]borohydride system. The subcellular distribution of radiolabel produced by these techniques has been evaluated by authoradiography at the light microscope level and by cellular fractionation. We find that while all four systems label the surface membranes in the majority of the cell population, they also heavily label internal sites in a small subpopulation of nonviable cells. The contribution of the internally labelled cells to further biochemical analysis may represent a severe problem in investigations which rely solely on surface labels for the study of plasma membrane organization     

Alterations of red cell membranes from phenylhydrazine-treated rabbits

Reticulocytosis was induced in rabbits by two methods: phlebotomy and injection of phenylhydrazine. Normal erythrocytes, reticulocytes from bed rabbits, reticulocytes from phenylhydrazine-treated rabbits, and erythrocytes treated in vitro with phenylhydrazine were compared with respect to their plasma membrane labeling by galactose oxidase and NaB³H₄, and lactoperoxidase-catalyzed incorporation of ¹²⁵I. Normal erythrocyte membranes and membranes from reticulocytes of bled rabbits showed almost identical labeling patterns, the presence of 2–3 glycoproteins with moderate to low mobilities on dodecyl sulfate acrylamide gel electrophoresis. Labeling in the absence of enzyme was negligible. In contrast, the reticulocytes from phenylhydrazine-treated rabbits exhibited a large incorporation of tritium without prior treatment with galactose oxidase. Even after prereduction with unlabeled NaBH₄ to remove this nonspecific labeling, the labeled glycoprotein components found in normal erythrocytes were not detectable. Normal erythrocytes treated in vitro with phenylhydrazine, washed, and labeled with galactose oxidase had labeling patterns, including high nonspecific incorporation of ³H, similar to those observed with in vivo phenylhydrazine treatment.Solubilization of membranes with lithium diiososalicylate followed by partitioning with phenol showed that the same glycoproteins were presented in normal or phenylhydrazine membranes, although only the former extract was labeled by galactose oxidase. Individual carbohydrates from the membranes were analyzed by gas-liquid chromatography and, in the case of hexosamines, on the amino acid analyzer. The results of these analyses indicated a slight decline in galactose content with phenylhydrazine treatment. Reticulocyte membranes from bled rabbits also showed a decrease in galactose content, although it was less pronounced.Most of the label incorporated by nonspecific borohydride labeling of membranes from phenylhydrazine-treated animals was found associated with protein. The modified amino acids from labeled proteins are similar to those formed in reactions of oxidized lipids and proteins in model systems.     

Surface glycoproteins of resting and activated human T lymphocytes

Summary This review summarizes some recent studies on the surface glycoproteins of human thymocytes and T lymphocytes. Purified cells were surface labeled by the galactose oxidase-NaB³H₄ or periodate-NaB³H₄ techniques. The radioactive membrane glycoproteins were separated by polyacrylamide slab gel electrophoresis and visualized by fluorography. Thymocytes and T lymphocytes show characteristic surface glycoprotein profiles which are easily distinguishable from those of the other main groups of human leukocytes. We observed specific changes in the surface glycoprotein patterns which correlate with the degree of maturation and functional activation of T cells. Surface molecules carrying T cell specific antigens were identified by immune-precipitation from lysates of surface labeled thymocytes and T lymphocytes using rabbit anti-human T cell antibodies. Finally we describe a leukocyte membrane glycoprotein which is a precursor of serum ₁ acid glycoprotein (orosomucoid).     

Adsorption behavior and enzymatically or chemically induced cross‐linking of a mussel adhesive protein

The adsorption behavior of the mussel adhesive protein Mytilus edulis foot protein‐1 (Mefp‐1) has been investigated on a negatively charged polar SiO₂ surface and an electrically inert non‐polar CH₃‐terminated thiolated gold surface. How the structure of adsorbed Mefp‐1 is changed upon chemically and enzymatically induced cross‐linking using sodium periodate (NaIO₄) and catechol oxidase, both of which transform DOPA residues in Mefp‐1 into highly reactive o‐quinones, was also investigated. The results are compared with those resulting from addition of Cu²⁺ to adsorbed Mefp‐1, which forms complexes with and catalyses oxidation of DOPA residues, previously suggested to participate in the cohesive and adhesive properties of the byssus thread of M. edulis. By combining surface plasmon resonance (SPR) and quartz crystal microbalance/dissipation (QCM‐D) measurements, the effects of these agents were investigated with respect to changes in the amount of coupled water, the viscoelastic properties (rigidity) and the hydrodynamic thickness of the protein adlayers. The layer of Mefp‐1 formed on the bare CH₃‐terminated surface was elongated, flexible and coupled hydrodynamically a substantial amount of water, whereas Mefp‐1 formed a rigidly attached adlayer on the SiO₂ surface. Upon enzymatically and chemically induced cross‐linking of Mefp‐1 formed on the CH₃ surface, the rigidity of the adlayer(s) increased significantly. A similar increase in the rigidity was observed also upon addition of Cu²⁺, suggesting that the high level of metal ions present in the byssus thread might be essential for the cohesive and adhesive properties of this protein. For the mass‐uptake kinetics of enzymatically induced cross‐linking, three different phases were observed and are interpreted as competition between binding of protein and release of coupled water. For the reaction with NaIO₄ and Cu²⁺, only release of water affected the coupled mass. The importance of this type of information for an improved understanding of the strong adhesion and cohesive properties in marine environments is discussed.     

Ontogeny of ppp(A2′p)nA-binding protein in mouse brain

Mouse brain tissue extracts at various stages of development show a drastic change in the specific activity of pp(A2′p)₂A-[³²P]pCp binding protein. Identification of the ppp(A2′p)₃A-[³²P]pCp binding protein was established by (i) binding to the specific ligand ppp(A2′p)₃A-[³²P]pCp, (ii) displacement of binding by nanomolar concentration of pppA(pA)₃, and (iii) affinity labeling techniques in which periodate oxidized ppp(A2′p)₃A-[³²P]pC was specifically cross-linked to a protein with a molecular weight of 86 000. These data suggest that the ppp(A2′p)₃A-[³²P]pCp protein is closely associated with the process of cellular proliferation and differentiation.     

N-acetyl-D-galactosaminyl-β-(1→4)-D-galactose: A terminal non-reducing structure in human blood group Sda-active Tamm-Horsfall urinary glycoprotein

Human Sd^a-active Tamm-Horsfall urinary glycoprotein labelled with galactose oxidase and tritiated sodium borohydride was found to contain both galactose and N-acetylgalactosamine as [³H]-labelled terminal non-reducing sugars. Fragmentation of the macromolecule achieved by hydrazinolysis and acid hydrolysis was followed by fractionation of the degradation products by gel filtration, ion exchange and paper chromatography. A major product was a disaccharide which contained unlabelled galactose and [³H]-labelled N-acetylgalactosamine. Sugar analysis, sodium borohydride reduction, methylation analysis and enzymic degradation enabled the structure N-acetyl-D-galactosaminyl-β-(1→4)-D-galactose to be assigned to the disaccharide.     

Wilson and Wilson's comprehensive analytical chemistry: Vol. XII,Thermal Analysis,Part A,Simultaneous thermoanalytical examinations by means of the Derivatograph. By J. Paulik and F. Paulik,Elsevier, Amsterdam/New York, 1981. 278 pp., $83.00

The reductive methylation procedure of G.E. Means and R. E. Feeney (1968)Biochemistry7, 2192–2201) was adapted for ³H-labeling of membrane proteins using pigeon erythrocyte membrane. Usably high ³H incorporation into protein was obtained, e.g., 28 μCi/mg protein with 83 nmol (input) H₂CO/mg protein, B³H₄^? at 10 Ci/mmol, and a B³H₄^?/H₂CO ratio of 0.34. With this low H₂CO/protein ratio, methylation did not perturb ATP-dependent ⁴⁵Ca²⁺ uptake, Na⁺-dependent [¹⁴C]glycine uptake, membrane vesicle sealing, or isoelectric focusing patterns of methylated membrane proteins. The labeled membrane proteins were shown to be good tracers for the unlabeled proteins by using two-dimensional isoelectric focusing x sodium dodecyl sulfate gel electrophoresis.     

Preparation of 3H-labeled serum glycoproteins from antarctic fish

Radioactive glycoproteins were prepared from the purified serum glycoproteins of antarctic fish by introducing tritium atoms (³H) into their carbohydrate moiety. The carbohydrate moiety is composed of disaccharides, β-D-galactosyl-(1→4) α-N-acetylgalactosamine, which accounts for 60% of the molecule. The hydroxyl groups (OH) at the carbon-6 positions of both sugar residues were oxidized with galactose oxidase to aldehyde groups and subsequently reduced to hydroxyl groups (O³H) with sodium borohydride-³H (NaB³H₄). Under suitable conditions, the end products (tritiated glycoproteins) are highly radioactive and retain their original unique freezing point depressing activity.     

Galactose, aspartate crossway and rhythm inhibition in Aspergillus niger

When the glucose/K⁺ balance in the medium is favourable to rhythm expression in Aspergillus niger Van Tieghem, galactose has an inhibitory effect on amplitude but not on period length of the rhythm. Galactose is active when its level reaches 1/10 of that of glucose. On liquid media a small quantity of glucose is necessary to start growth on galactose. Under these conditions U¹⁴C-galactose is rather slowly metabolized. After 6 h of feeding on the labelled galactose medium, this sugar is converted into glucose, which is used both for the synthesis of compounds derived from C₃ and C₄ units and for synthesis of polysaccharides and perhaps small peptides. The labelling of the macromolecules always remains low. The insoluble carbohydrates of the mycelium are little affected by the type of sugar supplied to the fungus. The metabolism on galactose differs from the metabolism on glucose mainly in a decrease of the free asparagine pool and a simultaneous equivalent increase of the free aspartate pool; such an effect could not be correlated with an increase of the aspartate aminotransferase activity. Supply of aspartate but not of gluta-mate into the agar medium inhibits the rhythm amplitude. So, the damping effect of galactose on the rhythm might be at least partly due to its effect on the regulation of the aspartate cross-way.     

Lactosaminoglycans synthesized by mouse male germ cells are fucosylated by an epididymal fucosyltransferase

We have studied the synthesis of protein-bound carbohydrates in differentiating male germ cells in the mouse. Spermatocytes and spermatids synthesize asparagine-linked and high-molecular-weight glycopeptides as the major classes of protein bound carbohydrates. Asparagine-linked glycopeptides were found to be mainly composed of the complex bi-antennary type as shown by affinity chromatography on concanavalin-A Sepharose; high-molecular-weight glycopeptides were represented by nonfucosylated lactosaminoglycans since they were metabolically labeled with [¹⁴C]glucosamine but not with [³H]fucose, did not bind to DEAE-cellulose, and were susceptible to endo-β-galactosidase. Labeling with galactose oxidase/Na B³H₄ technique demonstrated that lactosaminoglycans were present on the surface of differentiating germ cells and of testicular and epididymal spermatozoa. Since lactosaminoglycans from germ cells and testicular spermatozoa were not retained on a column of fucose-binding lectin, it was concluded that these molecules do not contain fucose. On the other hand, epididymal spermatozoa lactosaminoglycans bound to the lectin and therefore contained fucose. A soluble fucosyltransferase, capable of transferring fucose to germ cell lactosaminoglycans, was found to be present in the epididymis but not in the testis. These data show that developing germ cells synthesize nonfucosylated lactosaminoglycans which are probably preserved throughout spermiogenesis. We suggest that these molecules are fucosylated in vivo by a fucosyltransferase secreted by the epididymal epithelium.     

The proton pump of heme-copper oxidases.

Proton pumping heme-copper oxidases represent the terminal, energy-transfer enzymes of respiratory chains in prokaryotes and eukaryotes. The Cu_B-heme a₃ (or heme o) binuclear center, associated with the largest subunit I of cytochrome c and quinol oxidases, is directly involved in the coupling between dioxygen reduction and proton pumping. The role of the other subunits is less clear. The following aspects will be covered in this paper:i) the efficiency of coupling in the mitochondrial aa₃ cytochrome c oxidase. In particular, the effect of respiratory rate and protonmotive force on the H⁺/e^? stoichiometry and the role of subunit IV; ii) mutational analysis of the aa₃ quinol oxidase of Bacillus subtilis addressed to the role of subunit III, subunit IV and specific residues in subunit I; iii) possible models of the protonmotive catalytic cycle at the binuclear center. The observations available suggest that H⁺/e^?coupling is based on the combination of protonmotive redox catalysis at the binuclear center and co-operative proton transfer in the protein.     

Concerted involvement of cooperative proton–electron linkage and water production in the proton pump of cytochrome c oxidase

In cytochrome c oxidase, oxido-reductions of heme a/Cu_A and heme a₃/Cu_B are cooperatively linked to proton transfer at acid/base groups in the enzyme. H⁺/e⁻ cooperative linkage at Fe_a3/Cu_B is envisaged to be involved in proton pump mechanisms confined to the binuclear center. Models have also been proposed which involve a role in proton pumping of cooperative H⁺/e⁻ linkage at heme a (and Cu_A). Observations will be presented on: (i) proton consumption in the reduction of molecular oxygen to H₂O in soluble bovine heart cytochrome c oxidase; (ii) proton release/uptake associated with anaerobic oxidation/reduction of heme a/Cu_A and heme a₃/Cu_B in the soluble oxidase; (iii) H⁺ release in the external phase (i.e. H⁺ pumping) associated with the oxidative (R → O transition), reductive (O → R transition) and a full catalytic cycle (R → O → R transition) of membrane-reconstituted cytochrome c oxidase. A model is presented in which cooperative H⁺/e⁻ linkage at heme a/Cu_A and heme a₃/Cu_B with acid/base clusters, C₁ and C₂ respectively, and protonmotive steps of the reduction of O₂ to water are involved in proton pumping.