Sulfated N-linked oligosaccharides in mammalian cells. III. Characterization of a pancreatic carcinoma cell surface glycoprotein with N- and O-sulfate esters on asparagine-linked glycans

In the preceding two papers, we described two new classes of sulfated N-linked oligosaccharides isolated from total cellular 35SO4-labeled macromolecules of different mammalian cell lines. The first class carries various combinations of sialic acids and 6-O-sulfate esters on typical complex-type chains, while the second carries heparin and heparan-like sequences. In this study, we have characterized a sulfophosphoglycoprotein of 140 kDa from FG-Met-2 pancreatic cancer cells whose oligosaccharides share some properties of both these classes. The molecule was localized to the cell surface by electron microscopy using a monoclonal antibody (S3-53) and by cell surface 125I-labeling. Metabolic labeling of the cells with radioactive glucosamine, methionine, inorganic sulfate, or phosphate all demonstrated a single 140-kDa molecule. Pulse-chase analysis and tunicamycin treatment indicated the glycosylation of a putative primary translation product of 110 kDa via an intermediate (120 kDa) to the mature form (140 kDa). Digestion with peptide:N-glycosidase F (PNGaseF) indicated a minimum of four N-linked glycosylation sites. PNGaseF released more than 90% of the [6-3H]GlcNH2 label and 40-70% of 35SO4 label from the immunoprecipitated 140-kDa molecule. The isolated oligosaccharides were characterized as described in the preceding two papers. The majority of [6-3H]GlcNH2-labeled molecules were susceptible to neuraminidase. More than 50% of the 35SO4 label was associated with only 5-10% of the 3H-labeled chains. Some of the sulfated chains were partly sialylated molecules with four to five negative charges. Treatment with nitrous acid released about 25% of the 35SO4 label as free sulfate, together with 6% of the [6-3H]GlcNH2 label, indicating the presence of N-sulfated glucosamine residues. Some of these oligosaccharides were degraded by heparinase and heparitinase. Therefore, while they are not as highly charged as typical heparin or heparan chains, they must share structural features that permit recognition by the enzymes. Thus, this 140-kDa glycoprotein contains at least four asparagine-linked chains substituted with a heterogeneous mixture of sulfated sequences. The heterogeneity of these molecules is as extensive as that described for whole-cell sulfated N-linked oligosaccharides in the preceding two papers.     

Sulfated N-linked oligosaccharides in mammalian cells. I. Complex-type chains with sialic acids and O-sulfate esters

The structures of sulfated N-linked oligosaccharides have been reported for a few specific proteins. We recently demonstrated that such oligosaccharides occur in many different types of tissue culture cell lines (Freeze, H. H., and Varki, A. (1986) Biochem. Biophys. Res. Commun. 140, 967-973). Here we report improved methods to metabolically label cell lines with 35SO4 and to release sulfated N-linked oligosaccharides with peptide:N-glycosidase F as well as the partial structure of some of these novel oligosaccharides. The released 35SO4-labeled chains from Chinese hamster ovary (CHO) cells and bovine pulmonary artery endothelial cells (CPAE) were characterized by gel filtration, anion exchange and lectin affinity chromatography, and various enzymatic and chemical treatments. Each cell line contains a class of sulfated oligosaccharide chains bearing from two to six negative charges in varying combinations of O-sulfate esters and sialic acids. These molecules represent a significant proportion of both the total 35SO4 label and the total anionic N-linked oligosaccharides. They are also relatively enriched in a CHO mutant that is deficient in glycosaminoglycan chain synthesis. Lectin affinity chromatography of such molecules from CPAE cells indicates that the majority are sialylated multiantennary complex-type chains. The sulfate esters are exclusively of the primary type. Sequential exoglycosidase digestions, including beta-hexosaminidase A treatment at low pH, demonstrate that at least one-third of these sulfate esters are found in the following structure, (formula; see text) where R is the remainder of the underlying oligosaccharide, and SA is sialic acid. In addition to these molecules, a more highly charged group of sulfated N-linked oligosaccharides sharing structural features with glycosaminoglycans was found in CPAE cells, but not in CHO cells. These are described in the following paper (Sundblad, G., Holojda, S., Roux, L., Varki, A., and Freeze, H. H. (1988) J. Biol. Chem. 263, 8890-8896).     

Structural analysis of N-linked oligosaccharides from glycoproteins secreted by Dictyostelium discoideum. Identification of mannose 6-sulfate

The N-linked oligosaccharides found on the lysosomal enzymes from Dictyostelium discoideum are highly sulfated and contain methylphosphomannosyl residues (Gabel, C. A., Costello, C. E., Reinhold, V. N., Kurtz, L., and Kornfeld, S. (1984) J. Biol. Chem. 259, 13762-13769). Here we report studies done on the structure of N-linked oligosaccharides found on proteins secreted during growth, a major portion of which are lysosomal enzymes. Cells were metabolically labeled with [2-3H]Man and 35SO4 and a portion of the oligosaccharides were released by a sequential digestion with endoglycosidase H followed by endoglycosidase/peptide N-glycosidase F preparations. The oligosaccharides were separated by anion exchange high performance liquid chromatography into fractions containing from one up to six negative charges. Some of the oligosaccharides contained only sulfate esters or phosphodiesters, but most contained both. Less than 2% of the oligosaccharides contained a phosphomonoester or an acid-sensitive phosphodiester typical of the mammalian lysosomal enzymes. A combination of acid and base hydrolysis suggested that most of the sulfate esters were linked to primary hydroxyl groups. The presence of Man-6-SO4 was demonstrated by the appearance of 3,6-anhydromannose in acid hydrolysates of base-treated, reduced oligosaccharides. These residues were not detected in acid hydrolysates without prior base treatment or in oligosaccharides first treated by solvolysis to remove sulfate esters. Based on high performance liquid chromatography quantitation of percentage of 3H label found in 3,6-anhydromannose, it is likely that Man-6-SO4 accounts for the majority of the sulfated sugars in the oligosaccharides released from the secreted glycoproteins.     

Biosynthesis of methylphosphomannosyl residues in the oligosaccharides of Dictyostelium discoideum glycoproteins. Evidence that the methyl group is derived from methionine

The phosphorylated oligosaccharides of Dictyostelium discoideum contain methylphosphomannosyl residues which are stable to mild-acid and base hydrolysis (Gabel, C. A., Costello, C. E., Reinhold, V. N., Kurtz, L., and Kornfeld, S. (1984) J. Biol. Chem. 259, 13762-13769). Here we present evidence that these methyl groups are derived from [methyl-3H]methionine, in vivo and [methyl-3H]S-adenosylmethionine in vitro. About 18% of the macromolecules secreted from vegetative cells labeled with [methyl-3H]methionine are released by digestion with preparations of endoglycosidase/peptide N-glycosidase F. The majority of the released molecules are sulfated, anionic high mannose-type oligosaccharides. Strong acid hydrolysis of the [3H]methyl-labeled molecules yields [3H]methanol with kinetics of release similar to those found for the generation of Man-6-P from chemically synthesized methylphosphomannose methylglycoside. Treatment of the [3H]methyl-labeled molecules with a phosphodiesterase from Aspergillus niger which is known to cleave this phosphodiester also releases [3H]methanol from a portion of the oligosaccharides. In vitro incorporation of [methyl-3H]S-adenosylmethionine into endogenous acceptors found in membrane preparations shows that the [3H]methyl group of the methylphosphomannose residues can be derived from this molecule.     

Sulfated oligosaccharides block antibodies to many Dictyostelium discoideum acid hydrolases

The lysosomal hydrolases of the cellular slime mold, Dictyostelium discoideum, possess a common posttranslational modification which is extremely antigenic in rabbits and mice. Rabbit antisera and mouse monoclonal antibodies that recognize this determinant cross-react with a group of at least 40-50 highly negatively charged proteins which include most or all of the lysosomal enzymes. (Knecht, D. A., Dimond, R. L., Wheeler, S., and Loomis, W. F. (1984) J. Biol. Chem. 259, 10633-10640). The present study demonstrates that the determinant is found on certain N-linked oligosaccharides derived from one of these proteins. An esterified sulfate is absolutely required for antigenicity.     

Biochemical and genetic analysis of an antigenic determinant found on N-linked oligosaccharides in Dictyostelium.

Dictyostelium discoideum synthesizes many highly immunogenic carbohydrates of unknown structure and function. We have used monoclonal antibodies prepared against one of these called CA1 to investigate its structure and the consequences of its loss. CA1 is preferentially expressed on lysosomal enzymes as a specific arrangement of mannose-6-SO4 residues on N-linked oligosaccharides. Mutant strains HL241 and HL243 do not express CA1, and synthesize a truncated lipid-linked oligosaccharide (LLO) precursor that lacks the critical mannose residues needed for expression. The lesion appears to result from the loss of mannosyl transferase activity involved in LLO biosynthesis. The truncated LLO is poorly transferred to an artificial peptide acceptor in a cell-free N-glycosylation assay, and this appears to result from improper topological localization of the LLO or to a lower affinity of the LLO for the oligosaccharyl transferase. Although both mutants share these lesions, they are biochemically and genetically distinct. Only HL243 is lower in N-glycosylation in intact cells, and this is not a result of an altered structure of the LLO. There are other differences between the strains. HL241 can form fruiting bodies at a slower rate than normal while HL243 cannot aggregate. Genetic analysis of defects shows that the CA1 lesion in HL241 is recessive, while the lesion in both CA1 and in development are dominant and co-segregate in HL243 and are, therefore, likely to be in the same gene. Lysosomal enzyme targeting is normal but enzyme processing proceeds at a 2-3 fold slower rate in HL241 and HL243 compared to wild-type. Strain HL244 does not express CA1 since it completely lacks protein sulfation, but lysosomal enzyme targeting and processing proceeds at a normal rate, showing that sulfate is not essential for these processes. Alterations in oligosaccharide structure can have individualized effects on the biosynthesis of lysosomal enzymes. The results presented here illustrate how this approach can be used to study both the structure and function of carbohydrate epitopes.     

Carbohydrate composition of purified serum glycoproteins in Mucolipidosis II and Mucolipidosis III

Summary Mucolipidosis II (I-cell disease) and Mucolipidosis III (ML III) are inherited disorders in which the molecular defect may involve an abnormality in a common post-translational modification step (possibly glycosylation) shared by lysosomal hydrolases. We tested whether such an alteration might be a generalized defect in glycoprotein biosynthesis and, thus, be reflected in an abnormal carbohydrate composition of non-lysosomal glycoproteins. The apoprotein of low density lipoprotein (apo-LDL) and immunoglobulin G (IgG) were purified to apparent homogeneity. Gas liquid chromatographic (glc) analysis of the carbohydrate content of these glycoproteins from ML II, ML III and normal sera revealed no differences in the relative ratios and total amounts of mannose, galactose, N-acetylglucosamine and sialic acid. These results suggest that if the postulated post-translational defect in these disorders involves changes in carbohydrate composition, it is not a general defect in glycosylation and may be specific for lysosomal hydrolases.     

Leaf and tepal anatomy, plastid ultrastructure and chlorophyll content in Galanthus nivalis L. and Leucojum aestivum L.

The leaf structure of Galanthus nivalis L. (snowdrop) and Leucojum aestivum L. (snowflake) is characterized by a homogeneous mesophyll tissue. The dominant characters of the leaves are cavities with mucose substance. There is a striking difference between these plants tepal anatomy. A central cavity occurs only in snowdrop tepals. Plastids from white parts of the tepals have a poorly developed membrane system. Leaves and green parts of tepals of both species possess amoeboid chloroplasts and contain chlorophyll a and b. The chlorophyll content in tepals is lower than in leaves, but the chlorophyll a:b ratio is always 2:1. Both, snowdrop and snowflake are from the family Amaryllidaceae, but their ecology is different. This paper presents common features related to systematic relatedness and differences induced by ecological factors.     

Deficiency of the Cog8 Subunit in Normal and CDG‐Derived Cells Impairs the Assembly of the COG and Golgi SNARE Complexes

Multiple mutations in different subunits of the tethering complex Conserved Oligomeric Golgi (COG) have been identified as a cause for Congenital Disorders of Glycosylation (CDG) in humans. Yet, the mechanisms by which COG mutations induce the pleiotropic CDG defects have not been fully defined. By detailed analysis of Cog8 deficiency in either HeLa cells or CDG‐derived fibroblasts, we show that Cog8 is required for the assembly of both the COG complex and the Golgi Stx5‐GS28‐Ykt6‐GS15 and Stx6‐Stx16‐Vti1a‐VAMP4 SNARE complexes. The assembly of these SNARE complexes is also impaired in cells derived from a Cog7‐deficient CDG patient. Likewise, the integrity of the COG complex is also impaired in Cog1‐, Cog4‐ and Cog6‐depleted cells. Significantly, deficiency of Cog1, Cog4, Cog6 or Cog8 distinctly influences the production of COG subcomplexes and their Golgi targeting. These results shed light on the structural organization of the COG complex and its subcellular localization, and suggest that its integrity is required for both tethering of transport vesicles to the Golgi apparatus and the assembly of Golgi SNARE complexes. We propose that these two key functions are generally and mechanistically impaired in COG‐associated CDG patients, thereby exerting severe pleiotropic defects.