Isolation and Characterization of Golgi Membranes from Suspension-cultured Cells of Rice (Oryza sativa L.)

The isolation of Golgi membranes from suspension-cultured cellsof rice (Oryza sativa L.) was attempted by linear glycerol densitygradient centrifugation. When "burst" membranes in the pelletobtaind after differential centrifugation at 100,000 ? g weresuspended in 20% (w/w) glycerol in 50 mM malate-NaOH (pH 6.0)and loaded onto a linear density gradient of glycerol, whichextended from 30 to 80% (w/w) in 1 mM EDTA in 50 mM glycylglycine-NaOH(pH 7.5), IDPase, a marker enzyme for Golgi membranes, was separatedfrom other membrane markers on the glycerol gradient. In addition,UDPase and GDPase activities overlapped with the peak fractionof IDPase activity. Furthermore, membrane glycoproteins in eachfraction were characterized by lectin-peroxidase staining. ConcanavalinA and lentil lectin, which have the ability to bind to the high-mannosetype of oligosaccharide, bound to glycoproteins distributedin ER membrane fractions, while wheat germ lectin, castor beanlectin, peanut lectin, and Ulex europaeus lectin-I which recognizethe complex type and/or the mucin type of oligosaccharides interactedwith glycoproteins in the Golgi membrane fractions but not withthose in the ER membrane. These results strongly suggest thatthe oligosaccharide structures of glycoproteins in the ER membraneare of the high-mannose type, whereas glycoproteins in the Golgimembrane have modified N-linked and/or O-linked oligosaccharidechains. (Received November 9, 1988; Accepted October 17, 1989)     

Molecular and phenotypic analysis of the S. cerevisiae MNN10 gene identifies a family of related glycosyltransferases

The Saccharomyces cerevisiae mnn10 mutant is defective in thesynthesis of N-linked oligosaccharides (Ballou et al., 1989).This mutation has no effect on O-linked sugars, but resultsin the accumulation of glycoproteins that contain severely truncatedN-linked outer-chain oligosaccharides. We have cloned the MNN10gene by complementation of the hygromycin B sensitivity conferredby the mutant phenotype. Sequence analysis predicts that Mnn10pis a 46.7 kDa type II membrane protein with structural featurescharacteristic of a glycosyltransferase. Subcellular fractionationdata indicate that most of the Mnn10 protein cofractionateswith Golgi markers and away from markers for the endoplasmicreticulum (ER), suggesting Mnn10p is localized to the Golgicomplex. A comparison of the Mnn10 protein sequence to proteinsin the two different databases identified five proteins thatare homologous to Mnn10p, including a well characterized Schizosaccharomycespombe     

Localization of Mannose, TV-Acetylglucosamine and Galactose in the Golgi Apparatus, Plasma Membranes and Cell Walls of Scenedesmus acuminatus

The localization of lectin binding sites in the Golgi apparatus,plasma membranes and cell walls of Scenedesmus acuminatus wasinvestigated by cytochemical electron microscopy. The lectinsused were concanavalin A (Con A), peanut agglutinin (PNA) andwheat germ agglutinin (WGA), all labeled with gold. Con A-goldparticles were deposited not on the Golgi apparatus, but onthe outer cell-wall layer. PNA-gold and WGA-gold particles weredeposited on distal Golgi cisternae and vesicles derived fromthe Golgi apparatus. Entire cell-wall layers were evenly labeledby PNA-gold. The plasma membrane and cytoplasmic regions closeto the plasma membrane were labeled with WGA-gold. The processingof oligosaccharide in the Golgi apparatus, plasma membranesand cell walls of Scenedesmus acuminatus is discussed in referenceto that reported for animal cells. (Received March 5, 1987; Accepted July 18, 1987)     

Helix pomatia agglutinin binds specifically to the Golgi apparatus in cultured human fibroblasts and reveals two Golgi apparatus-specific glycoproteins

Summary Fluorochrome-coupled Helix pomatia agglutinin (HPA), but not other lectin-conjugates with the same nominal specificity, bound specifically to the Golgi apparatus in cultured human fibroblasts, revealing a cytoplasmic juxtanuclear reticular structure. Unlike other Golgi-binding lectins the HPA-conjugates did not bind to the cell surface membrane or pericellular matrix. Experiments with ³⁵S-methionine-labeled cells showed that HPA recognized two glycoproteins of M_r 170000 and 400000 among the secreted products of fibroblasts and two major cellular glycoproteins of M_r 40000 and M_r 180000 in Triton X-100 extracts of the cells. The two cellular HPA-binding polypeptides were also found in cells depleted of secretory products and in cells pulselabeled shortly with ³⁵S-methionine and then chased with methionine containing medium up to 12 h. These findings suggest that the two cellular glycoproteins recognized by HPA are retained in the Golgi apparatus and are therefore not precursors of secretory proteins. The results suggest that there are two endogenous, Golgi apparatus-specific glycoproteins in cultured human fibroblasts with terminal non-reducing O-glycosidic N-acetyl galactosaminyl residues.     

Migration of glycoprotein from the Golgi apparatus to the surface of various cell types as shown by radioautography after labelled fucose injection into rats

A single intravenous injection of L-[³H]fucose, a specific glycoprotein precursor, was given to young 35–45 g rats which were sacrificed at times varying between 2 min and 30 h later. Radioautography of over 50 cell types, including renewing and nonrenewing cells, was carried out for light and electron microscope study. At early time intervals (2–10 min after injection), light microscope radioautography showed a reaction over nearly all cells investigated in the form of a discrete clump of silver grains over the Golgi region. This reaction varied in intensity and duration from cell type to cell type. Electron microscope radioautographs of duodenal villus columnar cells and kidney proximal and distal tubule cells at early time intervals revealed that the silver grains were restricted to Golgi saccules. These observations are interpreted to mean that glycoproteins undergoing synthesis incorporate fucose in the saccules of the Golgi apparatus. Since fucose occurs as a terminal residue in the carbohydrate side chains of glycoproteins, the Golgi saccules would be the site of completion of synthesis of these side chains. At later time intervals, light and electron microscope radioautography demonstrated a decrease in the reaction intensity of the Golgi region, while reactions appeared over other parts of the cells: lysosomes, secretory material, and plasma membrane. The intensity of the reactions observed over the plasma membrane varied considerably in various cell types; furthermore the reactions were restricted to the apical surface in some types, but extended to the whole surface in others. Since the plasma membrane is covered by a "cell coat" composed of the carbohydrate-rich portions of membrane glycoproteins, it is concluded that newly formed glycoproteins, after acquiring fucose in the Golgi apparatus, migrate to the cell surface to contribute to the cell coat. This contribution implies turnover of cell coat glycoproteins, at least in nonrenewing cell types, such as those of kidney tubules. In the young cells of renewing populations, e.g. those of gastro-intestinal epithelia, the new glycoproteins seem to contribute to the growth as well as the turnover of the cell coat. The differences in reactivity among different cell types and cell surfaces imply considerable differences in the turnover rates of the cell coats.     

Functional compartments of the yeast Golgi apparatus are defined by the sec7 mutation.

The role of the SEC7 gene product in yeast intercompartmental protein transport was examined. A spectrum of N-linked oligosaccharide structures, ranging from core to nearly complete outer chain carbohydrate, was observed on glycoproteins accumulated in secretion-defective sec7 mutant cells. Terminal alpha 1-3-linked outer chain mannose residues failed to be added to N-linked glycoproteins in sec7 cells at the restrictive temperature. These results suggest that outer chain glycosyl modifications do not occur within a single compartment. Additional evidence consistent with subdivision of the yeast Golgi apparatus came from a cell-free glycoprotein transport reaction in which wild-type membranes sustained outer chain carbohydrate growth up to, but not including, addition of alpha 1-3 mannose residues. Golgi apparatus compartments may specialize in addition of distinct outer chain determinants. The SEC7 gene product was suggested to regulate protein transport between and from functional compartments of the yeast Golgi apparatus.     

Golgi Glycosylation

Glycosylation is a very common modification of protein and lipid, and most glycosylation reactions occur in the Golgi. Although the transfer of initial sugar(s) to glycoproteins or glycolipids occurs in the ER or on the ER membrane, the subsequent addition of the many different sugars that make up a mature glycan is accomplished in the Golgi. Golgi membranes are studded with glycosyltransferases, glycosidases, and nucleotide sugar transporters arrayed in a generally ordered manner from the cis-Golgi to the trans-Golgi network (TGN), such that each activity is able to act on specific substrate(s) generated earlier in the pathway. The spectrum of glycosyltransferases and other activities that effect glycosylation may vary with cell type, and thus the final complement of glycans on glycoconjugates is variable. In addition, glycan synthesis is affected by Golgi pH, the integrity of Golgi peripheral membrane proteins, growth factor signaling, Golgi membrane dynamics, and cellular stress. Knowledge of Golgi glycosylation has fostered the development of assays to identify mechanisms of intracellular vesicular trafficking and facilitated glycosylation engineering of recombinant glycoproteins.The Golgi is home to a multitude of glycosyltransferases (GTs), glycosidases, and nucleotide sugar transporters that function together to complete the synthesis of glycans from founding sugars covalently attached to protein or lipid in the endoplasmic reticulum (ER) (Fig. 1, sugars shaded in green). Thus, glycoproteins, glycosphingolipids (GSLs), proteoglycans, and glycophosphatidylinositol (GPI) anchors acquire their final sugar complement during passage through the Golgi. Most glycoproteins and proteoglycans are either secreted from the cell, or span the plasma membrane with their glycans becoming the molecular frontier of the cell (Fig. 1). GSLs and GPI-anchored proteins also reside in the plasma membrane, the latter being confined to the outer leaflet of the lipid bilayer. The forest of glycans at the cell surface is often called the glycocalyx and can be visualized by electron microscopy after staining for sugars.Open in a separate windowFigure 1.Glycans that mature in the Golgi. The diagram depicts simple N- and O-glycans attached to glycoproteins, proteoglycans, glycosphingolipids, and a GPI anchor in the plasma membrane. Rather rare O-glycans are found attached to EGF-like repeats (EGF; pink) or thrombospondin repeats (TSR; gray) with a particular consensus sequence. The WxxW motif in a TSR is C-mannosylated. Core regions boxed in teal are sugars added in the ER. The remaining sugars in each class of glycan are added during passage through the cis-, medial-, and trans-Golgi network (TGN) compartments of the Golgi. Abbreviations are: Man, mannose; Gal, galactose; Glc, glucose; GlcNAc, N-acetylglucosamine; GlcNH₂, Glucosamine; GlcA, glucuronic acid; IdoA, iduronic acid; GalNAc, N-acetylgalactosamine; Xyl, xylose; Fuc, Fucose; Sia, sialic acid; 3S, 3-O-sulfated; 6S, 6-O-sulfated, PO₄⁻, phosphate. (Modified from Figure 1.6 in Essentials of glycobiology, with permission from Varki and Sharon 2009.)Glycosylation is the most common posttranslational modification of proteins. Mature glycans at any one glycosylation site may be as simple as a single sugar, or as complex as a polymer of more than 200 sugars, potentially modified with phosphate, sulfate, acetate, or phosphorylcholine. Most importantly, glycans are often branched. For example, a complex N-glycan (Fig. 1) may have up to six branches or antennae, and each antenna may contain many repeating disaccharide units. This article will describe the nature of resident Golgi GTs and other activities involved in Golgi glycosylation from entry into the cis-Golgi through passage to the trans-Golgi network (TGN). The focus is on mammalian Golgi glycosylation but comparisons with yeast, Caenorhabditis elegans, and Drosophila are made where appropriate.     

Properties of a protein-linked glucuronoxylan formed in the plant Golgi apparatus

Radiolabelled glucuronoxylan was formed by incubation of a Golgimembrane fraction from pea seedlings with UDP-(¹⁴C)GlcA andUDP-Xyl. Chelator-soluble glucuronoxylan was analysed by gelfiltration on Sepharose CL-6B and CL-2B, and was resolved intoa very high molecular weight peak (at least 7000 kDa) and apartially-excluded peak (50-75 kDa). Treatment of the latterpeak with proteinase K caused a change in elution behaviourcorresponding to the removal of a protein of 36-45 kDa. Theassociation between poly-saccharide and protein was not disruptedby high temperature or by high salt concentration, and was probablycovalent. When radioactive glucuronoxylan was formed using endoplasmicreticulum rather than Golgi membranes, protease treatment causeda decrease in molecular weight of approximately 20 kDa. Thechelator-insoluble glucuronoxylan produced by pea membraneswas also partly susceptible to protease treatment, since almosthalf of it was solubilized by incubation with proteinase K. Key words: Glucuronoxylan, Golgi apparatus, endoplasmic reticulum, Pisum     

Multi-protein complexes in the cis Golgi of Saccharomyces cerevisiae with alpha-1,6-mannosyltransferase activity.

Anp1p, Van1p and Mnn9p constitute a family of membrane proteins required for proper Golgi function in Saccharomyces cerevisiae. We demonstrate that these proteins colocalize within the cis Golgi, and that they are physically associated in two distinct complexes, both of which contain Mnn9p. Furthermore, we identify two new proteins in the Anp1p-Mnn9p-containing complex which have homology to known glycosyltransferases. Both protein complexes have alpha-1, 6-mannosyltransferase activity, forming a series of poly-mannose structures. These reaction products also contain some alpha-1, 2-linked mannose residues. Our data suggest that these two multi-protein complexes are responsible for the synthesis and initial branching of the long alpha-1,6-linked backbone of the hypermannose structure attached to many yeast glycoproteins.     

Distribution of xylosylation and fucosylation in the plant Golgi apparatus

Antibodies have been immunopurified which are specific for carbohydrate epitopes containing the β1→2 xylose or α1→3 fucose residues found on complex N-linked glycans in plants. The antibody specificity was determined by taking advantage of an Arabidopsis thaliana N-glycosylation mutant which lacks N-acetyl-glucosaminyltransferase I and is unable to synthesize complex glycans. These antibodies were used to immunolocalize xylose- and fucose-containing glycoproteins in suspension-cultured sycamore cells (Acer pseudoplatanus). By mapping the enzymatic reaction products within the Golgi apparatus, the fucosyl- and xylosyltransferase subcellular localization was made possible using immunocytochemistry on thin sections of high-pressure frozen and freeze-substituted sycamore cells. This procedure allows a much better preservation of organelles, and particularly of the Golgi stack morphology, than that obtained with conventionally fixed samples. Glycoproteins containing β→2 xylose and α1→3 fucose residues were immunodetected in the cell wall, the vacuole, and the Golgi cisternae. The extent of immunolabeling over the different cisternae of 50 Golgi stacks was quantified after treatment with anti-xylose or anti-fucose antibodies. Labeling for xylose-containing glycoproteins was predominent in the medial cisternae, while fucose-containing glycoproteins were mainly detected in the trans compartment. Therefore, in plants, complex N-linked glycan xylosylation probably occurs mostly at the medial Golgi level and α1→3 fucose is mainly incorporated in the trans cisternae. Finally, fucose- and xylose-containing glycoproteins were also immunolocalized, albeit to a lesser extent, in earlier Golgi compartments. This indicates that the glycosylation events are a continuous process with some maxima in given compartments, rather than a succession of discrete and compartment-dependent steps.     

Functional compartmentation of the Golgi apparatus of plant cells : immunocytochemical analysis of high-pressure frozen- and freeze-substituted sycamore maple suspension culture cells

The Golgi apparatus of plant cells is engaged in both the processing of glycoproteins and the synthesis of complex polysaccharides. To investigate the compartmentalization of these functions within individual Golgi stacks, we have analyzed the ultrastructure and the immunolabeling patterns of high-pressure frozen and freeze-substituted suspension-cultured sycamore maple (Acer pseudoplatanus L.) cells. As a result of the improved structural preservation, three morphological types of Golgi cisternae, designated cis, medial, and trans, as well as the trans Golgi network, could be identified. The number of cis cisternae per Golgi stack was found to be fairly constant at approximately 1, whereas the number of medial and trans cisternae per stack was variable and accounted for the varying number of cisternae (3-10) among the many Golgi stacks examined. By using a battery of seven antibodies whose specific sugar epitopes on secreted polysaccharides and glycoproteins are known, we have been able to determine in which types of cisternae specific sugars are added to N-linked glycans, and to xyloglucan and polygalacturonic acid/rhamnogalacturonan-I, two complex polysaccharides. The findings are as follows. The β-1,4-linked d-glucosyl backbone of xyloglucan is synthesized in trans cisternae, and the terminal fucosyl residues on the trisaccharide side chains of xyloglucan are partly added in the trans cisternae, and partly in the trans Golgi network. In contrast, the polygalacturonic/rhamnogalacturonan-I backbone is assembled in cis and medial cisternae, methylesterification of the carboxyl groups of the galacturonic acid residues in the polygalacturonic acid domains occurs mostly in medial cisternae, and arabinose-containing side chains of the polygalacturonic acid domains are added to the nascent polygalacturonic acid/rhamnogalacturonan-I molecules in the trans cisternae. Double labeling experiments demonstrate that xyloglucan and polygalacturonic acid/rhamnogalacturonan-I can be synthesized concomitantly within the same Golgi stack. Finally, we show that the xylosyl residue-linked β-1,2 to the β-linked mannose of the core of N-linked glycans is added in medial cisternae. Taken together, our results indicate that in sycamore maple suspension-cultured cells, different types of Golgi cisternae contain different sets of glycosyl transferases, that the functional organization of the biosynthetic pathways of complex polysaccharides is consistent with these molecules being processed in a cis to trans direction like the N-linked glycans, and that the complex polysaccharide xyloglucan is assembled exclusively in trans Golgi cisternae and the trans Golgi network.     

Helix pomatia agglutinin binds specifically to the Golgi apparatus in cultured human fibroblasts and reveals two Golgi apparatus-specific glycoproteins

Fluorochrome-coupled Helix pomatia agglutinin (HPA), but not other lectin-conjugates with the same nominal specificity, bound specifically to the Golgi apparatus in cultured human fibroblasts, revealing a cytoplasmic juxtanuclear reticular structure. Unlike other Golgi-binding lectins the HPA-conjugates did not bind to the cell surface membrane or pericellular matrix. Experiments with 35S-methionine-labeled cells showed that HPA recognized two glycoproteins of Mr 170,000 and 400,000 among the secreted products of fibroblasts and two major cellular glycoproteins of Mr 40,000 and Mr 180,000 in Triton X-100 extracts of the cells. The two cellular HPA-binding polypeptides were also found in cells depleted of secretory products and in cells pulse-labeled shortly with 35S-methionine and then chased with methionine containing medium up to 12 h. These findings suggest that the two cellular glycoproteins recognized by HPA are retained in the Golgi apparatus and are therefore not precursors of secretory proteins. The results suggest that there are two endogenous, Golgi apparatus-specific glycoproteins in cultured human fibroblasts with terminal non-reducing O-glycosidic N-acetyl galactosaminyl residues.     

Intracellular transport of lymphoid surface glycoproteins: Role of the Golgi complex

The biosynthesis of the heavy chains of two membrane glycoproteins, identified as immunoglobulin M and histocompatibility antigens, has been studied in [³⁵S]methionine pulse-chase experiments by one and two-dimensional gel electrophoresis. Terminal sugar addition results in marked shifts in gel mobility that are mainly due to sialic acid addition, since they are sensitive to neuraminidase. These shifts are prevented when the ionophore monensin is present during the chase incubation. We conclude that both membrane IgM² and H2 heavy chains normally pass through the Golgi subsite defined by monensin and acquire terminal sialic acid distal to this site. Analysis of surface-iodinated control and monensin-treated cells indicates that, in the presence of monensin, newly synthesized, incompletely glycosylated IgM and H2 are not transported to the cell surface. Thus these membrane proteins appear to follow the same intracellular pathway as secretory proteins.     

Subcellular characterization of glycoproteins in the principal cells of human gallbladder

Gallbladder mucus is mainly composed of glycoproteins, which seem to play a critical role in cholesterol nucleation during gallstone formation. The biosynthetic pathway and sequential processing as well as the characterization of the oligosaccharide sidechains of human gallbladder secretory glycoproteins have not been completely defined. The aim of the present study is the subcellular characterization of the glycoproteins in the principal cells of human gallbladder. Principal cells of normal human gallbladder were studied by means of a variety of cytochemical techniques, including lectin histochemistry, enzyme and chemical treatments, immunocytochemistry and lectin-gold technology. Fucose, galactose, N-acetylglucosamine, N-acetylgalactosamine and N-acetylneuraminic acid residues were detected in mucous granules, Golgi apparatus and apical membrane of principal cells. Mannose residues were only observed in dense bodies. Oligosaccharide side-chains of the glycoproteins contained in the biliary mucus are synthesized in the Golgi apparatus of the principal cells of the gallbladder epithelium and are also contained in the mucous granules of these cells. Terminal N-acetylneuraminic acid(2-3)galactose(1-3)N-acetylgalactosamine, N-acetylneuraminic acid(2-3)galactose(1-4)N-acetylglucosamine and galactose(1-4)N-acetylglucosamine sequences are contained in the oligosaccharide chains of gallbladder mucus glycoproteins. The dense bodies detected in the cytoplasm of the principal cells contained N-linked glycoproteins. Mucin-type O-linked glycoproteins were the main components of the mucous granules although some N-linked chains were also detected.     

Peanut (Arachis hypogaea) lectin recognizes α-linked galactose, but not N-acetyl lactosamine in N-linked oligosaccharide terminals

Peanut (Arachis hypogaea) agglutinin (PNA) is extensively used as tumour marker as it strongly recognises the cancer specific T antigen (Galβ1→3GalNAc-), but not its sialylated version. However, an additional specificity towards Galβ1→4GlcNAc (LacNAc), which is not tumour specific, had been attributed to PNA. For correct interpretation of lectin histochemical results we examined PNA sugar specificity using naturally occurring or semi-synthetic glycoproteins, matrix-immobilised galactosides and lectin-binding tissue glycoproteins, rather than mono- or disaccharides as ligands. Dot-blots, transfer blots or polystyrene plate coatings of the soluble glycoconjugates were probed with horse-radish peroxidase (HRP) conjugates of PNA and other lectins of known specificity. Modifications of PNA-binding glycoproteins, including selective removal of O-linked oligosaccharides and treatment with glycosidases revealed that Galβ1→4GlcNAc (LacNAc) was ineffective while terminal α-linked galactose (TAG) as well as exposed T antigen (Galβ1→3 GalNAc-) was excellent as sugar moiety in glycoproteins for their recognition by PNA. When immobilised, melibiose was superior to lactose in PNA binding. Results were confirmed using TAG-specific human serum anti-α-galactoside antibody.     

Human MR1 expression on the cell surface is acid sensitive, proteasome independent and increases after culturing at 26°C

Protein O-linked mannose β1,2-N-acetylglucosaminyltransferase 1 (POMGnT1) catalyzes the transfer of GlcNAc to O-mannose of glycoproteins. Mutations in the POMGnT1 gene cause muscle–eye–brain disease (MEB). POMGnT1 is a typical type II membrane protein, which is localized in the Golgi apparatus. However, details of the catalytic and reaction mechanism of POMGnT1 are not understood. To develop a better understanding of POMGnT1, we examined the substrate specificity of POMGnT1 using a series of synthetic O-mannosyl peptides based on the human α-dystroglycan (α-DG) sequence as substrates. O-Mannosyl peptides consisting of three to 20 amino acids are recognized as substrates. Enzyme kinetics improved with increasing peptide length up to a length of 8 amino acids but the kinetics of peptides longer than 8 amino acids were similar to those of octapeptides. Our results also show that the amino acid sequence affects POMGnT1 activity. These data suggest that both length and amino acid sequence of mannosyl peptides are determinants of POMGnT1 substrate specificity.     

Glycoconjugates in normal human kidney

Summary The avidin-biotin-peroxidase complex technique was used with 13 lectins to study the glycoconjugates of normal human renal tissue. The evaluated lectins included Triticum vulgaris (WGA), Concanavalin ensiformis (ConA), Phaseolus vulgaris leukoagglutinin and erythroagglutinin (PHA-L and PHA-E), Lens culinaris (LCA), Pisum sativum (PSA), Dolichos biflorus (DBA), Glycine max (SBA), Bandeiraea simplicifolia I (BSL-I), Ulex europaeus I (UEA-I) and Ricinus communis I (RCA-I). Characteristic and reproducible staining patterns were observed. WGA and ConA stained all tubules; PHA-L, PHA-E, LCA, PSA stained predominantly proximal tubules; DBA, SBA, PNA, SJA and BSL-I stained predominantly distal portions of nephrons. In glomeruli, WGA and PHA-L stained predominantly visceral epithelial cells; ConA stained predominantly basement membranes and UEA-I stained exclusively endothelial cells. UEA-I also stained endothelial cells of other blood vessels and medullary collecting ducts. Sialidase treatment before staining caused marked changes of the binding patterns of several lectins including a focal loss of glomerular and tubular staining by WGA; an acquired staining of endothelium by PNA and SBA; and of glomeruli by PNA, SBA, PHA-E, LCA, PSA and RCA-I. The known saccharide specificities and binding patterns of the lectins employed in this study allowed some conclusions about the nature and the distribution of the sugar residues in the oligosaccharide chains of renal glycoconjugates. The technique used in this report may be applicable to other studies such as evaluation of normal renal maturation, classification of renal cysts and pathogenesis of nephrotic syndrome. The observations herein reported may serve as a reference for these studies.     

N- and O-linked oligosaccharides completely lack galactose residues in the gms1och1 mutant of Schizosaccharomyces pombe

Unlike their counterparts in budding yeast Saccharomyces cerevisiae, the glycoproteins of Schizosaccharomyces pombe contain, in addition to α-d-mannose (Man), a large number of α-d-galactose (Gal) residues. In both yeasts, large outer chains are attached to the oligosaccharide cores of glycoproteins during export via Golgi. Formation of the yeast-specific large outer chain is initiated by α-1,6-mannosylatransferase encoded by the och1 ⁺ gene, the disruption of which blocked outer chain elongation. We previously reported that N-linked oligosaccharide structures of S. pombe och1Δ mutant consisted of Gal_2–6Man₉GlcNAc₂ with α-linked Gal residues attached to the core oligosaccharide moiety. The disruption of gms1 ⁺, a gene encoding the UDP-galactose transporter required for the synthesis of galactomannan, abolished cell surface galactosylation in S. pombe. In this study, we constructed a gms1Δoch1Δ double mutant and determined the N- and O-linked oligosaccharide structures present on the cell surface. Oligosaccharides were liberated from glycoproteins by hydrazinolysis and labeled with the fluorophore, 2-aminopyridine. The pyridylaminated N-linked oligosaccharides were analyzed by high-performance liquid chromatography in combination with α1,2-mannosidase digestion and partial acetolysis. These analyses revealed that the N-linked oligosaccharides of gms1Δoch1Δ cells consisted of α1,2-linked Man-extended core oligosaccharides (Man_8–12GlcNAc₂) from which the fission yeast-specific α-linked Gal residues were completely absent.     

Ultrastructural distribution of lectin-binding sites on gastric superficial mucus-secreting epithelial cells

Normal human gastric epithelial cells were examined by electron microscopy using each of five biotinylated lectins [Ulex europaeus agglutinin I (UEA-I), peanut agglutinin (PNA), wheat germ agglutinin (WGA), soybean agglutinin (SBA) andDolichos biflorus agglutinin (DBA)] as a probe. We employed 35 gastric surgical specimens removed from complicated peptic disease. The lectin-binding sites were revealed with streptavidin-colloidal gold complex. All specimens were embedded in Spurr and LR White resins. In superficial foveolar epithelial cells, the lectins used were generally positive in all cell types (mainly UEA-1 and PNA) on the Golgi region and mucus cytoplasmic vacuoles, with many variations among cells in the same case. On the other hand, extracellular mucus was negative for WGA. Labelling with PNA revealed a biphasic pattern (peripheral positivity) on mucous droplets in surface and foveolar cells. Thecis side of the Golgi apparatus was labelled with SBA and PNA and rough endoplasmic reticulum with SBA (only five cases). Lectin-binding variability could be related to heterogeneous composition of gastric mucus. Our results with SBA suggest initiation ofO-glycosylation at the Golgi apparatus; however a role of the rough endoplasmic reticulum cannot be excluded (N-glycosylation). We propose the following sequence of sugar addition to the carbohydrate side-chains of gastric glycoproteins: (1) GaNAc (Golgi apparatuscis-side), (2) GlcNAc (Golgi apparatus intermediate face), (3) GalNac or Gal, -l-fucose (Golgi apparatustrans-side).Supported by a grant from Junta de Andalucía (Consolidación de Grupos de Investigación. Ref. 541A.6.60.609.018311)