Nuclear glycoproteins of hamster liver and Kirkman-Robbins hepatoma recognized by concanavalin A.

1. Glycoproteins recognized by Concanavalin A (ConA) have been identified in nuclei and nuclear fractions differing in sensitivity to micrococcal nuclease digestion from hamster liver and Kirkman-Robbins hepatoma. 2. The major ConA binding proteins from hamster liver and Kirkman-Robbins hepatoma nuclei have molecular weights about 27,000 and 57,000, and 38,000 and 49,000, respectively. 3. A distinct distribution of glycoproteins between fractions differing in sensitivity to nuclease digestion has not been observed.     

Developmental changes of proteins and concanavalin A reactive glycoproteins in growth cones from rat forebrain.

Growth cones were isolated from the forebrains of 1, 5 and 9 days-old rats. The ultrastructural characterization of the obtained subcellular fractions reveals that two of them (GC1 and GC2) contain predominantly growth cones. It was found that the protein content of the membranes contained in these fractions increases 7.5 times, while in whole forebrain the increase is only 3 times, showing that during the studied developmental period there is a predominant protein enrichment of the specialized brain structures (e.g. growth cones). Electrophoretic studies show that there are characteristic changes of the Coomassie Brilliant Blue R250 staining and concanavalin A reactive protein profiles. Comparison of the protein patterns of growth cones to those of synaptosomes from mature forebrain reveal a number of bands, which appear to be characteristic for one of these structures. The possible roles of the developmentally controlled proteins in the processes of synaptogenesis is discussed.     

Changes in plasma membrane glycoproteins of rat spermatozoa during maturation in the epididymis

Glycoproteins on the plasma membrane of testicular and cauda epididymidal spermatozoa have been labeled with galactose oxidase/NaB [3H]4 and sodium metaperiodate/NaB[3H]4, followed by analysis on SDS polyacrylamide gels. The major glycoprotein labeling on testicular spermatozoa has a molecular weight 110,000 whereas on cauda epididymidal spermatozoa greater than 90% of the radio-label is incorporated into proteins of molecular weight 32,000. These 32,000-mol wt X proteins are homologous with proteins of similar molecular weight purified from the epididymal secretion and which have been shown previously to be synthesized in the caput epididymidis under hormonal control. Immunofluorescence revealed that the 32,000-mol wt proteins are present on the flagellum of mature but not immature spermatozoa and that they have a patchy distribution suggesting that they are mobile within the plane of the membrane. The membrane-bound 32,000-mol wt proteins possess hydrophobic domains as revealed by charge-shift electrophoresis and they also label with a lipophilic photoaffinity probe suggesting that they are in contact with the lipid bilayer. The evidence indicates that there is a considerable reorganization of the molecular structure of the plasma membrane of spermatozoa during maturation in the epididymis and that some of the changes are brought about by a direct interaction with epididymal secretory proteins.     

Changes in cell surface glycoproteins on non-differentiating L6 rat myoblasts selected for resistance to concanavalin A

Four independently selected conA-resistant, non-differentiating rat L6 myoblast cell lines and their parental wild-type populations were examined for cell surface alterations. [³H]conA-binding studies indicated that the variant myoblasts bound significantly less lectin than wild-type cells at 4 and at 37 °C. Scatchard analysis revealed two general types of binding sites (high and low affinity sites) on wild-type cells; the variants appeared to be deficient in the high affinity sites. These changes in conA binding probably play an important role in determining the conA-resistant phenotype. Lectin-binding results could be significantly modified by altering the composition of the serum in the growth medium used to culture myoblasts prior to performing binding experiments, suggesting the existence of productive and non-productive lectin-binding sites on the cell surface. SDS slab gel electrophoresis of [³H]mannose-labelled surface membranes prepared from variant and wild-type cells showed that several glycoproteins of the conA-resistant myoblasts were defective in mannosylation. The conA-binding abilities of a pronase digest of one of these altered regions from variant separations, with a molecular weight of 44 500 D, was found to contain glycopeptides with reduced affinity for the lectin, supporting the idea that variant membranes are deficient in a set of high affinity lectin-binding sites. Studies on [GDP-¹⁴C]-mannose incorporation into lipid by membranes from variant and wild-type myoblasts indicated that the biosynthetic lesion likely involved a mannosyl transferase enzyme directly, rather than a lack of free dolichol-PO₄. These studies link conA resistance, cell surface glycoprotein alterations, and defective mannosyl transferase activity with the inability to carry out normal cellular differentiation to form multinucleated myotubes.     

Glycans of synaptosomal plasma membrane glycoproteins from adult rat forebrain: Characterization after fractionation by concanavalin A-Sepharose affinity chromatography

Glycopeptides obtained by exhaustive proteolytic digestion of synaptosomal plasma membranes from adult rat forebraini were separated by affinity chromatography on concanavalin A-Sepharoe. Concanavalin A-binding glycopeptides are essentially made up of mannose and N-acetylglucosamine in a molar ration of 3.45:1, whereas glycopeptides not bound to concanavalin A have a complex monosaccharide composition. By gel filtration on Bio-Gel P-30, concanavalin A-binding glycopeptides appear as low-molecular-weight glycopeptides (migrating like ovalbumin glycopeptides), whereas glycopeptides not bound to concanavalin A behave as high-molecular-weight glycopeptides (migrating like fetuin glycopeptides). Comparison of concanavalin A-binding glycopeptides from rat brain synaptosomal plasma membranes with concanavalin A-binding glycoproteins isolated from the same membrane fraction shows clear differences in monosccharide composition. We demonstrate here that this discrepancy is due to the presence on most concanavalin A-binding glycoprotein subunits of at least two different types of glycan: in addition to the concanavalin A-binding glycans, these glycoprotein subunits carry other glycans which do not interact with concanavalin A. Biological implications of the presence of two (or more) types of glycan on the same polypeptide are discussed.     

Leaching of concanavalin A during affinity chromatographic isolation of cell surface glycoproteins from human fetal neurons and glial cells.

Preparation of surface glycoproteins from human fetal brain cells by affinity chromatography on Con A-Sepharose 4B was a problematic endeavor due to leaching of Con A from the matrix. Dissociation of Con A from the matrix took place irrespective of the presence of lipid and/or detergent and the buffer composition during chromatography and was apparently related to the nature of the protein under study. Pretreatment of Con A-Sepharose with 6 M guanidine or 8 M urea reduced Con A leaching. The Con A eluate also contained noncovalently associated glycolipid. Elution at 25 degrees C rendered fractions containing a higher degree of Con A and glycolipid contamination compared to the negligible contamination by these two components when elution was carried out at 4 degrees C. This phenomenon was attributed to the formation of heterogeneous mixed micelles of glycoprotein.     

Changes in platelet membrane glycoproteins during blood bank storage.

The literature on membrane glycoprotein changes occurring during platelet storage is reviewed. Technical problems which may have biased reports are clarified, and the consensus of current studies is established. The membrane alterations that occur during blood bank storage are reminiscent of the surface changes which result from platelet secretion: an increased surface concentration of GP IIb-IIIa and GMP-140, and the appearance of platelet membrane microparticles in the supernatant plasma. The clinical importance of these changes is unknown. Future directions for research on the structure and function of stored platelets are discussed.     

Partial characterization of rat hepatoma cell-surface glycopeptides possessing concanavalin A receptor activity.

Papain digestion of Novikoff or AS-30D rat hepatoma cells released glycopeptides from the cell surface. That portion of the glycopeptides accessible to Sephadex G-50 was digested with pronase and the component glycopeptides partially resolved by ion-exchange chromatography. Each tumor type yielded two well resolved sialoglycopeptide fractions which possessed concanavalin A receptor activity. The amino acid and saccharide composition of these low molecular weight (3,100 ± 300 daltons) sialoglycopeptides was determined.     

Approach to the mechanism of Zajdela's hepatoma cell growth inhibition induced by concanavalin A and phytohaemagglutinin

Cell growth of tumour ascites cells was inhibited by concanavalin A, phytohaemagglutinin and Ricinus lectin at 2-100 micrograms/ml. As expected, the Ricinus lectin inhibited the protein synthesis estimated by leucine incorporation and decreased thymidine incorporation, whereas concanavalin A and phytohaemagglutinin stimulate the uptake and the incorporation of both leucine and thymidine, and thus, synthesis of protein and DNA. These results suggest that different mechanisms are involved in the hepatoma cell growth inhibition by the lectins. This difference was not related to the kinetic characteristics of the lectin interactions with the cells which represent a first and necessary step. It was showed that concanavalin A and phytohaemagglutinin as well as chloroquine inhibited the 14C-labelled asialofetuin degradation. We can conclude that Ricinus lectin present a toxic effect whereas both concanavalin A and phytohaemagglutinin show an anti-protease activity.     

Rapid intramolecular turnover of N-linked glycans in plasma membrane glycoproteins. Extension of intramolecular turnover to the core sugars in plasma membrane glycoproteins of hepatoma

Plasma membrane glycoproteins of rat hepatocytes undergo a rapid terminal deglycosylation in that the terminal sugars of the oligosaccharide side chains are rapidly removed from the otherwise intact glycoproteins [Tauber, R., Park, C.S. & Reutter, W. (1983) Proc. Natl Acad. Sci. USA 80, 4026-4029]. The present paper demonstrates that this rapid intramolecular turnover of plasma membrane glycoproteins is not restricted to peripheral sugars but, in contrast to liver, in hepatoma the core sugars of the oligosaccharide chains are also involved. Intramolecular turnover was measured in Morris hepatoma 7777 in five plasma membrane glycoproteins with Mr of 85,000 (hgp85), 105,000 (hgp105), 115,000 (hgp115), 125,000 (hgp125), 175,000 (hgp175) (hgp = hepatoma glycoprotein) that were isolated and purified to homogeneity by concanavalin-A--Sepharose affinity chromatography and semipreparative SDS gel electrophoresis. Analysis of the carbohydrates of hgp85, hgp105, hgp115 and hgp125 revealed the presence of N-linked oligosaccharides containing L-fucose, D-galactose, D-mannose and N-acetyl-D-glucosamine, but only of trace amounts of N-acetyl-D-galactosamine; hgp175 additionally contained significant amounts of N-acetyl-D-galactosamine, indicating the presence of both N- and O-linked oligosaccharides. As shown by digestion with endoglucosaminidase H, the N-linked oligosaccharides of hgp105, hgp115, hgp125 and hgp175 were of the complex type, whereas hgp85 also contained oligosaccharides of the high-mannose type. Half-lives of the turnover of the oligosacharide chains and of the protein backbone of the five glycoproteins were measured in the plasma membrane in pulse-chase experiments in vivo, using L-[3H]fucose as a marker of terminal sugars, D-[3H]mannose as marker of a core sugar and L-[3H]leucine for labelling the protein backbone. Protein backbones of the five glycoproteins were degraded with individual half-lives ranging over 41-90 h with a mean of 66 h. Compared to the degradation of the polypeptide backbone, both the terminal sugar L-fucose and the core sugar D-mannose turned over with much shorter half-lives averaging about 20 h in the five glycoproteins. The data show that, conversely to liver, within plasma membrane glycoproteins of hepatoma not only peripheral sugars but also core sugars of the oligosaccharides are split off during the life-span of the protein backbone. It may therefore be assumed that this reprocessing of plasma membrane glycoproteins is sensitive to malignant transformation.     

Preparation and properties of concanavalin A-binding glycopeptides derived from rat brain glycoproteins.

Mannose-rich glycopeptides derived from brain glycoproteins were recovered by affinity chromatography on Concanavalin A-Sepharose. These glycopeptides, which adsorb to the lectin and are eluted with alpha-methylmannoside, constitute about 25--30% of the total glycopeptide material recovered from rat brain glycoproteins. They contain predominately mannose and N-acetylglucosamine (mannose/N-acetylglucosamine = 3), as well as small amounts of galactose and fucose. Approx. 65% of the Concanavalin A-binding glycopeptide carbohydrate was recovered after treatment with leucine aminopeptidase, gel filtration on Biogel P-4, and ion-exchange chromatography on coupled Dowex 50-hydrogen and Dowex 1-chloride columns. The purified glycopeptide fraction contained six mannose and two N-acetylglucosamine residues per aspartic acid and possessed an apparent molecular weight of about 2000 as assessed by gel filtration and amino acid analysis. Galactose and fucose were absent. Treatment of the purified glycopeptides with alpha-mannosidase drastically reduced their affinity for Concanavalin A, suggesting the presence of one or more terminal mannose residues.     

Identification of liver plasma membrane glycoproteins which bind to 125I-labelled concanavalin A following electrophoresis in sodium dodecyl sulfate.

Following electrophoresis of ovalbumin in sodium dodecyl sulfate (SDS) this glycoprotein bound 125I-labelled concanavalin A (Con A). The reaction was specific and proportional to the amount of glycoprotein present on the gel. This technique was used to study the Con-A-binding glycoproteins of liver cell surfaces. Mouse liver plasma membranes were purified and subfractionated to yield two fractions corresponding to the bile canalicular surface and the surface between adjacent hepatocytes (Evans, W.H. (1970) Biochem. J. 116, 833-842). Both fractions bound 125I-labelled Con A, the former binding two to three times more lectin than the latter. Following SDS gel electrophoresis individual membrane glycoproteins reacted with 125I-labelled Con A. Both membrane subfractions yielded qualitatively similar Con A binding profiles, seven binding proteins being present in each. The results are consistent with a generally uniform distribution of glycoproteins over the hepatocyte surface. The reaction of lectins with glycoproteins following SDS gel electrophoresis should find general application in the study of membrane composition.     

Structural perturbations in the plasma membrane during concanavalin A endocytosis

Endocytosis of Concanavalin A, triggered by its interaction with the surface of cells from a murine plasmocytoma line, is characterised by various steps which can be visualised by cytochemistry and freeze-fracturing. Plasma membrane internalisation is initiated by clustering of Concanavalin A receptors and by formation of intramembraneous particle necklaces, which were observed on fracture faces. Subsequent perturbation of the lipid bilayer precedes the fusion and formation of closed vesicles.