Molecular cloning and heterologous expression of beta1,2-xylosyltransferase and core alpha1,3-fucosyltransferase from maize

Maize is considered a promising alternative production system for pharmaceutically relevant proteins. However, like in all other plant species asparagine-linked oligosaccharides of maize glycoproteins are modified with beta1,2-xylose and core alpha1,3-fucose sugar residues, which are considered to be immunogenic in mammals. This altered N-glycosylation when compared to mammalian cells may reduce the potential of maize as a production system for heterologous glycoproteins. Here we report the cloning and characterization of the cDNA sequences coding for the maize enzymes beta1,2-xylosyltransferase (XylT) and core alpha1,3-fucosyltransferase (FucT). The cloned XylT and FucT cDNAs were shown to encode enzymatically active proteins, which were independently able to convert a mammalian acceptor glycoprotein into an antigen binding anti-plant N-glycan antibodies. The complete sequence of the XylT gene was determined. Evidence for the presence of at least three XylT and FucT gene loci in the maize genome was obtained. The identification of the two enzymes and their genes will allow the targeted downregulation or even elimination of beta1,2-xylose and core alpha1,3-fucose addition to recombinant glycoproteins produced in maize.     

Biosynthesis of human-type N-glycans in heterologous systems

Insects, yeasts and plants generate widely different N-glycans, the structures of which differ significantly from those produced by mammals. The processing of the initial Glc2Man9GlcNAc2 oligosaccharide to Man8GlcNAc2 in the endoplasmic reticulum shows significant similarities among these species and with mammals, whereas very different processing events occur in the Golgi compartments. For example, yeasts can add 50 or even more Man residues to Man(8-9)GlcNAc2, whereas insect cells typically remove most or all Man residues to generate paucimannosidic Man(3-1)GlcNAc2N-glycans. Plant cells also remove Man residues to yield Man(4-5)GlcNAc2, with occasional complex GlcNAc or Gal modifications, but often add potentially allergenic beta(1,2)-linked Xyl and, together with insect cells, core alpha(1,3)-linked Fuc residues. However, genomic efforts, such as expression of exogenous glycosyltransferases, have revealed more complex processing capabilities in these hosts that are not usually observed in native cell lines. In addition, metabolic engineering efforts undertaken to modify insect, yeast and plant N-glycan processing pathways have yielded sialylated complex-type N-glycans in insect cells, and galactosylated N-glycans in yeasts and plants, indicating that cell lines can be engineered to produce mammalian-like glycoproteins of potential therapeutic value.     

Generation of glyco-engineered BY2 cell lines with decreased expression of plant-specific glycoepitopes

Plants are known to be efficient hosts for the production of mammalian therapeutic proteins. However, plants produce complex N-glycans bearing β1,2-xylose and core α1,3-fucose residues, which are absent in mammals. The immunogenicity and allergenicity of plant-specific N-glycans is a key concern in mammalian therapy. In this study, we amplified the sequences of 2 plant-specific glycosyltransferases from Nicotiana tabacum L. cv Bright Yellow 2 (BY2), which is a well-established cell line widely used for the expression of therapeutic proteins. The expression of the endogenous xylosyltranferase (XylT) and fucosyltransferase (FucT) was downregulated by using RNA interference (RNAi) strategy. The xylosylated and core fucosylated N-glycans were significantly, but not completely, reduced in the glyco-engineered lines. However, these RNAi-treated cell lines were stable and viable and did not exhibit any obvious phenotype. Therefore, this study may provide an effective and promising strategy to produce recombinant glycoproteins in BY2 cells with humanized N-glycoforms to avoid potential immunogenicity.     

The accumulation of Man(6)GlcNAc(2)-PP-dolichol in the Saccharomyces cerevisiae Deltaalg9 mutant reveals a regulatory role for the Alg3p alpha1,3-Man middle-arm addition in downstream oligosaccharide-lipid and glycoprotein glycan processing

N-Glycans in nearly all eukaryotes are derived by transfer of a precursor Glc(3)Man(9)GlcNAc(2) from dolichol (Dol) to consensus Asn residues in nascent proteins in the endoplasmic reticulum. The Saccharomyces cerevisiae alg (asparagine-linked glycosylation) mutants fail to synthesize oligosaccharide-lipid properly, and the alg9 mutant, accumulates Man(6)GlcNAc(2)-PP-Dol. High-field (1)H NMR and methylation analyses of Man(6)GlcNAc(2) released with peptide-N-glycosidase F from invertase secreted by Deltaalg9 yeast showed its structure to be Manalpha1,2Manalpha1,2Manalpha1, 3(Manalpha1,3Manalpha1,6)-Manbeta1,4GlcNAcbeta1, 4GlcNAcalpha/beta, confirming the addition of the alpha1,3-linked Man to Man(5)GlcNAc(2)-PP-Dol prior to the addition of the final upper-arm alpha1,6-linked Man. This Man(6)GlcNAc(2) is the endoglycosidase H-sensitive product of the Alg3p step. The Deltaalg9 Hex(7-10)GlcNAc(2) elongation intermediates were released from invertase and similarly analyzed. When compared with alg3 sec18 and wild-type core mannans, Deltaalg9 N-glycans reveal a regulatory role for the Alg3p-dependent alpha1,3-linked Man in subsequent oligosaccharide-lipid and glycoprotein glycan maturation. The presence of this Man appears to provide structural information potentiating the downstream action of the endoplasmic reticulum glucosyltransferases Alg6p, Alg8p and Alg10p, glucosidases Gls1p and Gls2p, and the Golgi Och1p outerchain alpha1,6-Man branch-initiating mannosyltransferase.     

Novel Schizosaccharomyces pombe N-linked GalMan9GlcNAc isomers: role of the Golgi GMA12 galactosyltransferase in core glycan galactosylation

Schizosaccharomyces pombe synthesizes very large N-linked galactomannans, which are elongated from the Man9GlcNAc2 core that remains after the trimming of three Glc residues from the Glc3Man9GlcNAc2 originally transferred from dolichyl pyrophosphate to nascent proteins in the endoplasmic reticulum. Prior to elongation of the galactomannan outer chain, the Man9GlcNAc2 core is modified into a family of Hex10-15GlcNAc2 structures by the addition of both Gal and Man residues (Ziegler et al. (1994) J. Biol. Chem., 269, 12527-12535). To understand the pathway of Man9GlcNAc2 modification, the Hex10GlcNAc-sized pool was isolated by Bio-Gel P-4 gel filtration from the endo H-released N-glycans of S.pombe glycoproteins. This pool yielded four major fractions, a, b, c, and g, on preparative high pH, anion exchange chromatography, that represented 10, 29, 46, and 13% of the total Hex10GlcNAc present, respectively. Structures of the glycan isomers present in each fraction were determined by one- and two-dimensional 1H NMR spectroscopy techniques. Fraction a is principally (approximately 93%) a Man10GlcNAc with a new alpha1,2-linked Man cap on the upper-arm of Man9GlcNAc. Fraction b contained two isomers of GalMan9GlcNAc in which an alpha1,2-linked terminal Gal had been added either to the upper (b1, 30%) or middle-arm (b2, 70%) of Man9GlcNAc. The gma12 - alpha1,2-galactosyltransferase-negative S. pombe strain (Chappell et al. (1994) Mol. Biol. Cell., 5, 519-528) did not make fraction b implying that the gma12p galactosyltransferase is responsible for synthesis of both isomers b1 and b2. Isomer c is Man10GlcNAc in which a new branching alpha1, 6-linked Man had been added to the lower-arm alpha1,3-linked core residue as found earlier in Saccharomyces cerevisiae and Pichia pastoris. Fraction g had less than molar stoichiometry of both Gal and Glc. The major isomer (g1, 85%) is the Man9GlcNAc core with an alpha1,3-linked branching Gal on the penultimate 2-O-substituted Man of the lower arm. This residue is also found on a novel O-linked oligosaccharide recently described in S.pombe; Manalpha1,2(Galalpha1, 3)Manalpha1,2Mannitol (Gemmill and Trimble (1999) Glycobiology, 9, 507-515). The second isomer (g2, 15%) is the partially processed Glc2Man9GlcNAc intermediate. Defining these Hex10GlcNAc structures provides a starting point for understanding the enzymology of N-linked galactomannan core heterogeneity seen on S.pombe glycoproteins.     

Comparative analysis of the site-specific N-glycosylation of human lactoferrin produced in maize and tobacco plants.

We have compared the site-by-site N-glycosylation status of human lactoferrin (Lf) produced in maize, a monocotyledon, and in tobacco, used as a model dicotyledon. Maize and tobacco plants were stably transformed and recombinant Lf was purified from both seeds and leaves. N-glycopeptides were generated by trypsin digestion of recombinant Lf and purified by reverse-phase HPLC. The N-glycosylation pattern of each site was determined by mass spectrometry. Our results indicated that the N-glycosylation patterns of recombinant Lf produced in maize and tobacco share common structural features. In particular, both N-glycosylation sites of each recombinant Lf are mainly substituted by typical plant paucimannose-type N-glycans, with beta1,2-xylose and alpha1,3-linked fucose at the proximal N-acetylglucosamine. However, tobacco Lf shows a significant amount of processed N-glycans with one or two beta1,2GlcNAc linked to the trimannose core, which are weakly expressed in maize Lf. Finally, no Lewisa epitope was observed on tobacco Lf.     

Alpha1,3fucosyltransferases in cystic fibrosis airway epithelial cells

Cystic fibrosis (CF) has a glycophenotype of aberrant sialylation and/or fucosylation. The CF glycophenotype is expressed on membrane glycoconjugates of CF airway epithelial cells as increased fucosyl residues in alpha1,3/4 linkage to N-acetyl glucosamine, decreased fucosyl residues in alpha1,2 linkage to galactose and decreased sialic acid. To define the cause of this phenotype, the enzyme activity of alpha1,3fucosyltransferase (FucT) was examined in extracts of CF airway epithelial cells with a variety of low molecular weight substrates. Using Galbeta1,4GlcNAc as substrate, the activity was divided into 66% alpha1,3FucT and 34% alpha1,2FucT. mRNA expression examined with probes to FucTIII, IV, and VII showed that the highest expression of two CF cell lines was for FucTIV. Only one CF cell line expressed mRNA for FucTIII. The non CF airway epithelial cells had significant enzyme activity for alpha1,3FucT and strong mRNA expression for FucTIV. Thus as reported previously for alpha1,2FucT, the biochemical capacity for alpha1,3FucT was present in both the CF and non CF cells and can not be the cause of the CF glycophenotype. These results support the hypothesis that wild type CFTR acts in the Golgi and when mutated as in CF, faulty compartmentalization of terminal glycosyltransferases results, yielding the CF glycophenotype.     

Specificity of IgG and IgE antibodies against plant and insect glycoprotein glycans determined with artificial glycoforms of human transferrin

Cross-reactive carbohydrate determinants of plants are essentially a mixture of N-glycans containing beta1,2-xylose and core alpha1,3-fucose, the latter also found in insect glycoproteins. To determine the relative contributions of these two sugar residues to antibody binding, we prepared an array of glycomodified forms of human apo-transferrin. Using core-alpha1, 3-fucosyltransferase (EC 2.4.1.214) and beta1,2-xylosyltransferase (EC 2.4.2.38) recombinantly expressed in Pichia pastoris and suitable glycosidases, glycoforms containing either only fucose (MMF), only xylose (MMX), both (MMXF), or neither (MM) linked to the common pentasaccharide core were generated. Additional glycoforms were obtained by enzymatic removal of the alpha1,3-linked mannosyl residue. These transferrin glycoforms served to define the binding specificity of antibodies in western blot, ELISA, and inhibition ELISA. Rabbit anti-horseradish peroxidase serum bound to both the fucosylated (MMF) and the xylosylated (MMX) glycoforms. Inhibition studies indicated two independent highly specific populations reacting with either of the two epitopes. In contrast, the monoclonal antibody YZ1/2.23 appears to recognize a larger structure including both the fucosyl and the xylosyl residue. The mannose-deficient glycoform was a poorer inhibitor for both antibodies. Terminal GlcNAc residues prevented antibody binding. Rabbit anti-bee venom serum reacted with fucosylated forms (MMF and MMXF) only. Experiments with sera from allergic patients suggest that glycomodified human transferrin, especially the MMXF glycoform, is a suitable reagent for the detection of antibodies against cross-reactive carbohydrate determinants. Within the panel studied, several sera contained high levels of fucose-reactive IgE but only a few sera showed any binding to MMX-transferrin.     

Generation of glyco-engineered Nicotiana benthamiana for the production of monoclonal antibodies with a homogeneous human-like N-glycan structure

A common argument against using plants as a production system for therapeutic proteins is their inability to perform authentic human N -glycosylation (i.e. the presence of β1,2-xylosylation and core α1,3-fucosylation). In this study, RNA interference (RNAi) technology was used to obtain a targeted down-regulation of the endogenous β1,2- xylosyltransferase (XylT) and α1,3- fucosyltransferase (FucT) genes in Nicotiana benthamiana , a tobacco-related plant species widely used for recombinant protein expression. Three glyco-engineered lines with significantly reduced xylosylated and/or core α1,3-fucosylated glycan structures were generated. The human anti HIV monoclonal antibody 2G12 was transiently expressed in these glycosylation mutants as well as in wild-type plants. Four glycoforms of 2G12 differing in the presence/absence of xylose and core α1,3-fucose residues in their N -glycans were produced. Notably, 2G12 produced in XylT/FucT-RNAi plants was found to contain an almost homogeneous N -glycan species without detectable xylose and α1,3-fucose residues. Plant-derived glycoforms were indistinguishable from Chinese hamster ovary (CHO)-derived 2G12 with respect to electrophoretic properties, and exhibited functional properties (i.e. antigen binding and HIV neutralization activity) at least equivalent to those of the CHO counterpart. The generated RNAi lines were stable, viable and did not show any obvious phenotype, thus providing a robust tool for the production of therapeutically relevant glycoproteins in plants with a humanized N -glycan structure.     

A plant-derived human monoclonal antibody induces an anti-carbohydrate immune response in rabbits

A common argument against using plants as a production system for therapeutic proteins is their inability to perform authentic N-glycosylation. A major concern is the presence of beta 1,2-xylose and core alpha 1,3-fucose residues on complex N-glycans as these nonmammalian N-glycan residues may provoke unwanted side effects in humans. In this study we have investigated the potential antigenicity of plant-type N-glycans attached to a human monoclonal antibody (2G12). Using glyco-engineered plant lines as expression hosts, four 2G12 glycoforms differing in the presence/absence of beta 1,2-xylose and core alpha 1,3-fucose were generated. Systemic immunization of rabbits with a xylose and fucose carrying 2G12 glycoform resulted in a humoral immune response to both N-glycan epitopes. Furthermore, IgE immunoblotting with sera derived from allergic patients revealed binding to plant-produced 2G12 carrying core alpha 1,3 fucosylated N-glycan structures. Our results provide evidence for the adverse potential of nonmammalian N-glycan modifications present on monoclonal antibodies produced in plants. This emphasizes the need for the use of glyco-engineered plants lacking any potentially antigenic N-glycan structures for the production of plant-derived recombinant proteins intended for parenteral human application.     

A new fungal lectin recognizing alpha(1-6)-linked fucose in the N-glycan

In this report, we describe a new lectin from the fungus Rhizopus stolonifer that agglutinates rabbit red blood cells. Agglutinating activity was detected in the extract of mycelium-forming spores cultured on agar plates but not in the mycelium-forming no spores from liquid medium. This lectin, which we designated R. stolonifer lectin (RSL), was isolated by affinity chromatography with porcine stomach mucin-Sepharose. SDS-polyacrylamide gel electrophoresis and mass spectral analysis showed that RSL is approximately 4.5 kDa, whereas gel filtration indicated a mass of 28 kDa. This indicates that the lectin is a hexamer of noncovalently associated RSL monomers. RSL activity was very stable, since it was insensitive to heat treatment at 70 degrees C for 10 min. Analysis of RSL binding specificity by both microtiter plate and precipitation assays showed that N-glycans with l-fucose linked to the reducing terminal GlcNAc residues are the most potent inhibitors of RSL binding, whereas N-glycans without alpha(1-6)-linked fucose residues are approximately 100-fold weaker inhibitors of binding. Oligosaccharides with alpha(1-2, -3, and -4) linkages showed no inhibition of binding in these assays. In a mirror resonance biosensor assay, high affinity binding was observed between RSL and the glycopeptide of bovine gamma-globulin, which has N-glycans with alpha(1-6)-linked fucose residues. However, RSL showed only a weak interaction with the glycopeptide of quail ovomucoid, which lacks fucose residues. Finally, capillary affinity electrophoresis studies indicated that RSL binds strongly to N-glycans with alpha(1-6)-linked fucose residues. Together, these results show that RSL recognizes the core structure of N-glycans with alpha(1-6)-linked l-fucose residues. This specificity could make RSL a valuable tool for glycobiological studies.     

Concanavalin A binding and endoglycosidase D resistance of beta1,2-xylosylated and alpha 1,3-fucosylated plant and insect oligosaccharides

The binding to concanavalin A (Con A) by pyridylaminated oligosaccharides derived from bromelain (Man alpha 1,6(Xyl beta 1, 2) Man beta 1, 4GlcNAc beta 1, 4(Fuc alpha 1, 3)GlcNAc), horseradish peroxidase (Man alpha 1,6(Man alpha 1, 3) (Xyl beta 1, 2)Man beta 1, 4GlcNAc beta 1,4(Fuc alpha 1, 3) GlcNAc), bee venom phospholipase A2 (Man alpha 1,6Man beta 1,4GlcNAc beta 1,4GlcNAc and Man alpha 1,6(Man alpha 1, 3)Man beta 1,4GlcNAc beta 1, 4 (Fuc alpha 1, 3)GlcNAc) and zucchini ascorbate oxidase (Man alpha 1,6(Man alpha 1, 3) (Xyl beta 1, 2)Man beta 1, 4 GlcNAc beta 1, 4GlcNAc) was compared to the binding by Man3GlcNAc2, Man5GlcNAc2 and the asialo-triantennary complex oligosaccharide from bovine fetuin. While the fetuin oligosaccharide did not bind, bromelain, zucchini, Man2GlcNAc2 and horseradish peroxidase were retarded (in that order). The alpha 1, 3-fucosylated phospholipase, Man3GlcNAc2 and Man5GlcNAc2 structures were eluted with 15 M alpha -methylmannoside. It is concluded that core alpha 1,3-fucosylation has little or no effect on ConA binding while xylosylation decreases affinity for ConA. In a parallel study comparing the endoglycosidase D (Endo D) sensitivities of Man3GlcNAc2, IgG-derived GlcNAc beta 1, 2Man alpha 1,6(GlcNAc beta 1,2Man alpha 1,3)Man beta 1,4GlcNAc beta 1,4(Fuc alpha 1,6)GlcNAc, the phospholipase Man alpha 1,6(Man alpha 1, 3)Man beta 1, 4GlcNAc beta 1,4(Fuc alpha 1,3)GlcNAc, and horseradish and zucchini pyridylaminated N-linked oligosaccharides, it was found that only the Man3GlcNAc2 structure was cleaved. The IgG structure was sensitive only when beta -hexosaminidase was also present. Thus, in contrast to core alpha 1,6-fucosylated structures, such as those present in mammals, the presence of core alpha 1,3-fucose, as found in structures from plants and insects, and/or beta 1,2-xylose, as found in plants, causes resistance to Endo D.     

Characterization of N-linked oligosaccharides assembled on secretory recombinant glucose oxidase and cell wall mannoproteins from the methylotrophic yeast Hansenula polymorpha

Presently almost no information is available on the oligosaccharide structure of the glycoproteins secreted from the methylotrophic yeast Hansenula polymorpha, a promising host for the production of recombinant proteins. In this study, we analyze the size distribution and structure of N-linked oligosaccharides attached to the recombinant glycoprotein glucose oxidase (GOD) and the cell wall mannoproteins obtained from H. polymorpha. Oligosaccharide profiling showed that the major oligosaccharide species derived from the H. polymorpha-secreted recombinant GOD (rGOD) had core-type structures (Man(8-12)GlcNAc(2)). Analyses using anti-alpha 1,3-mannose antibody and exoglycosidases specific for alpha 1,2- or alpha 1,6-mannose linkages revealed that the mannose outer chains of N-glycans on the rGOD have very short alpha 1,6 extensions and are mainly elongated in alpha 1,2-linkages without a terminal alpha 1,3-linked mannose addition. The N-glycans released from the H. polymorpha mannoproteins were shown to contain mostly mannose in their outer chains, which displayed almost identical size distribution and structure to those of H. polymorpha-derived rGOD. These results strongly indicate that the outer chain processing of N-glycans by H. polymorpha significantly differs from that by Saccharomyces cerevisiae, thus generating much shorter mannose outer chains devoid of terminal alpha 1,3-linked mannoses.     

A new yeast mutation in the glucosylation steps of the asparagine-linked glycosylation pathway. Formation of a novel asparagine-linked oligosaccharide containing two glucose residues

We have isolated and characterized a new yeast mutation in the glucosylation steps of lipid-linked oligosaccharide biosynthesis, alg8-1. Cells carrying the alg8-1 mutation accumulate Glc1Man9GlcNAc2-lipid both in vivo and in vitro. We present evidence showing that the alg8-1 mutation blocks addition of the second alpha 1,3-linked glucose. alg8-1 cells transfer Glc1Man9GlcNAc2 to protein instead of the wild type oligosaccharide, Glc3Man9GlcNAc2. Pulse-chase studies indicate that the Glc1Man9GlcNAc2 transferred is processed more slowly than the wild type oligosaccharide. The yeast mutation gls1-1 lacks glucosidase I activity (Esmon, B., Esmon, P.C., and Schekman, R. (1984) J. Biol. Chem. 259, 10322-10327), the enzyme responsible for removing the alpha 1,2-linked glucose residues from protein-linked oligosaccharides. We demonstrate that gls1-1 cells contain glucosidase II activity (which removes alpha 1,3-linked glucose residues) and have constructed the alg8-1 gls1-1 haploid double mutant. The Glc1Man9GlcNAc2 oligosaccharide was trimmed normally in these cells, demonstrating that the alg8-1 oligosaccharide contained an alpha 1,3-linked glucose residue. A novel Glc2 compound was probably produced by the action of the biosynthetic enzyme that normally adds the alpha 1,2-linked glucose to lipid-linked Glc2Man9GlcNAc2. This enzyme may be able to slowly add alpha 1,2-linked glucose residue to protein-bound Glc1Man9GlcNAc2. The relevance of these findings to similar observations in other systems where glucose residues are added to asparagine-linked oligosaccharides and the possible significance of the reduced rate of oligosaccharide trimming in the alg mutants are discussed.     

Poly-N-acetyllactosamine extension in N-glycans and core 2- and core 4-branched O-glycans is differentially controlled by i-extension enzyme and different members of the beta 1,4-galactosyltransferase gene family

Poly-N-acetyllactosamines are attached to N-glycans, O-glycans, and glycolipids and serve as underlying glycans that provide functional oligosaccharides such as sialyl Lewis(X). Poly-N-acetyllactosaminyl repeats are synthesized by the alternate addition of beta1,3-linked GlcNAc and beta1,4-linked Gal by i-extension enzyme (iGnT) and a member of the beta1,4-galactosyltransferase (beta4Gal-T) gene family. In the present study, we first found that poly-N-acetyllactosamines in N-glycans are most efficiently synthesized by beta4Gal-TI and iGnT. We also found that iGnT acts less efficiently on acceptors containing increasing numbers of N-acetyllactosamine repeats, in contrast to beta4Gal-TI, which exhibits no significant change. In O-glycan biosynthesis, N-acetyllactosamine extension of core 4 branches was found to be synthesized most efficiently by iGnT and beta4Gal-TI, in contrast to core 2 branch synthesis, which requires iGnT and beta4Gal-TIV. Poly-N-acetyllactosamine extension of core 4 branches is, however, less efficient than that of N-glycans or core 2 branches. Such inefficiency is apparently due to competition between a donor substrate and acceptor in both galactosylation and N-acetylglucosaminylation, since a core 4-branched acceptor contains both Gal and GlcNAc terminals. These results, taken together, indicate that poly-N-acetyllactosamine synthesis in N-glycans and core 2- and core 4-branched O-glycans is achieved by iGnT and distinct members of the beta4Gal-T gene family. The results also exemplify intricate interactions between acceptors and specific glycosyltransferases, which play important roles in how poly-N-acetyllactosamines are synthesized in different acceptor molecules.     

Oligosaccharide preferences of beta1,4-galactosyltransferase-I: crystal structures of Met340His mutant of human beta1,4-galactosyltransferase-I with a pentasaccharide and trisaccharides of the N-glycan moiety

beta-1,4-Galactosyltransferase-I (beta4Gal-T1) transfers galactose from UDP-galactose to N-acetylglucosamine (GlcNAc) residues of the branched N-linked oligosaccharide chains of glycoproteins. In an N-linked biantennary oligosaccharide chain, one antenna is attached to the 3-hydroxyl-(1,3-arm), and the other to the 6-hydroxyl-(1,6-arm) group of mannose, which is beta-1,4-linked to an N-linked chitobiose, attached to the aspargine residue of a protein. For a better understanding of the branch specificity of beta4Gal-T1 towards the GlcNAc residues of N-glycans, we have carried out kinetic and crystallographic studies with the wild-type human beta4Gal-T1 (h-beta4Gal-T1) and the mutant Met340His-beta4Gal-T1 (h-M340H-beta4Gal-T1) in complex with a GlcNAc-containing pentasaccharide and several GlcNAc-containing trisaccharides present in N-glycans. The oligosaccharides used were: pentasaccharide GlcNAcbeta1,2-Manalpha1,6 (GlcNAcbeta1,2-Manalpha1,3)Man; the 1,6-arm trisaccharide, GlcNAcbeta1,2-Manalpha1,6-Manbeta-OR (1,2-1,6-arm); the 1,3-arm trisaccharides, GlcNAcbeta1,2-Manalpha1,3-Manbeta-OR (1,2-1,3-arm) and GlcNAcbeta1,4-Manalpha1,3-Manbeta-OR (1,4-1,3-arm); and the trisaccharide GlcNAcbeta1,4-GlcNAcbeta1,4-GlcNAc (chitotriose). With the wild-type h-beta4Gal-T1, the K(m) of 1,2-1,6-arm is approximately tenfold lower than for 1,2-1,3-arm and 1,4-1,3-arm, and 22-fold lower than for chitotriose. Crystal structures of h-M340H-beta4Gal-T1 in complex with the pentasaccharide and various trisaccharides at 1.9-2.0A resolution showed that beta4Gal-T1 is in a closed conformation with the oligosaccharide bound to the enzyme, and the 1,2-1,6-arm trisaccharide makes the maximum number of interactions with the enzyme, which is in concurrence with the lowest K(m) for the trisaccharide. Present studies suggest that beta4Gal-T1 interacts preferentially with the 1,2-1,6-arm trisaccharide rather than with the 1,2-1,3-arm or 1,4-1,3-arm of a bi- or tri-antennary oligosaccharide chain of N-glycan.     

Importance of glycosidases in mammalian glycoprotein biosynthesis

Processing glycosidases play an important role in N-glycan biosynthesis in mammalian cells by trimming Glc(3)Man(9)GlcNAc(2) and thus providing the substrates for the formation of complex and hybrid structures by Golgi glycosyltransferases. Processing glycosidases also play a role in the folding of newly formed glycoproteins and in endoplasmic reticulum quality control. The properties and molecular nature of mammalian processing glycosidases are described in this review. Membrane-bound alpha-glucosidase I and soluble alpha-glucosidase II of the endoplasmic reticulum remove the alpha1,2-glucose and alpha1,3-glucose residues, respectively, beginning immediately following transfer of Glc(3)Man(9)GlcNAc(2) to nascent polypeptides. The alpha-glucosidases participate in glycoprotein folding mediated by calnexin and calreticulin by forming the monoglucosylated high mannose oligosaccharides required for the interaction with the chaperones. In some mammalian cells, Golgi endo alpha-mannosidase provides an alternative pathway for removal of glucose residues. Removal of alpha1,2-linked mannose residues begins in the endoplasmic reticulum where trimming of mannose residues in the endoplasmic reticulum has been implicated in the targeting of malfolded glycoproteins for degradation. Removal of mannose residues continues in the Golgi with the action of alpha1, 2-mannosidases IA and IB that can form Man(5)GlcNAc(2) and of alpha-mannosidase II that removes the alpha1,3- and alpha1,6-linked mannose from GlcNAcMan(5)GlcNAc(2) to form GlcNAcMan(3)GlcNAc(2). These membrane-bound Golgi enzymes have been cloned and shown to have very distinct patterns of tissue-specific expression. There are also broad specificity alpha-mannosidases that can trim Man(4-9)GlcNAc(2) to Man(3)GlcNAc(2), and provide an alternative pathway toward complex oligosaccharide formation. Cloning of the remaining alpha-mannosidases will be required to evaluate their specific functions in glycoprotein maturation.     

Lectin affinity high-performance liquid chromatography. Interactions of N-glycanase-released oligosaccharides with Ricinus communis agglutinin I and Ricinus communis agglutinin II

The structural determinants required for interaction of oligosaccharides with Ricinus communis agglutinin I (RCAI) and Ricinus communis agglutinin II (RCAII) have been studied by lectin affinity high-performance liquid chromatography (HPLC). Homogeneous oligosaccharides of known structure, purified following release from Asn with N-glycanase and reduction with NaBH4, were tested for their ability to interact with columns of silica-bound RCAI and RCAII. The characteristic elution position obtained for each oligosaccharide was reproducible and correlated with specific structural features. RCAI binds oligosaccharides bearing terminal beta 1,4-linked Gal but not those containing terminal beta 1,4-linked GalNAc. In contrast, RCAII binds structures with either terminal beta 1,4-linked Gal or beta 1,4-linked GalNAc. Both lectins display a greater affinity for structures with terminal beta 1,4-rather than beta 1,3-linked Gal, although RCAII interacts more strongly than RCAI with oligosaccharides containing terminal beta 1,3-linked Gal. Whereas terminal alpha 2,6-linked sialic acid partially inhibits oligosaccharide-RCAI interaction, terminal alpha 2,3-linked sialic acid abolishes interaction with the lectin. In contrast, alpha 2,3- and alpha 2,6-linked sialic acid equally inhibit but do not abolish oligosaccharide interaction with RCAII. RCAI and RCAII discriminate between N-acetyllactosamine-type branches arising from different core Man residues of dibranched complex-type oligosaccharides; RCAI has a preference for the branch attached to the alpha 1,3-linked core Man and RCAII has a preference for the branch attached to the alpha 1,6-linked core Man. RCAII but not RCAI interacts with certain di- and tribranched oligosaccharides devoid of either Gal or GalNAc but bearing terminal GlcNAc, indicating an important role for GlcNAc in RCAII interaction. These findings suggest that N-acetyllactosamine is the primary feature required for oligosaccharide recognition by both RCAI and RCAII but that lectin interaction is strongly modulated by other structural features. Thus, the oligosaccharide specificities of RCAI and RCAII are distinct, depending on many different structural features including terminal sugar moieties, peripheral branching pattern, and sugar linkages.     

Limited Addition of the 6-Arm β1,2-linked N-Acetylglucosamine (GlcNAc) Residue Facilitates the Formation of the Largest N-Glycan in Plants

The most abundant N-glycan in plants is the paucimannosidic N-glycan with core β1,2-xylose and α1,3-fucose residues (Man₃XylFuc(GlcNAc)₂). Here, we report a mechanism in Arabidopsis thaliana that efficiently produces the largest N-glycan in plants. Genetic and biochemical evidence indicates that the addition of the 6-arm β1,2-GlcNAc residue by N-acetylglucosaminyltransferase II (GnTII) is less effective than additions of the core β1,2-xylose and α1,3-fucose residues by XylT, FucTA, and FucTB in Arabidopsis. Furthermore, analysis of gnt2 mutant and 35S:GnTII transgenic plants shows that the addition of the 6-arm non-reducing GlcNAc residue to the common N-glycan acceptor GlcNAcMan₃(GlcNAc)₂ inhibits additions of the core β1,2-xylose and α1,3-fucose residues. Our findings indicate that plants limit the rate of the addition of the 6-arm GlcNAc residue to the common N-glycan acceptor as a mechanism to facilitate formation of the prevalent N-glycans with Man₃XylFuc(GlcNAc)₂ and (GlcNAc)₂Man₃XylFuc(GlcNAc)₂ structures.     

Purification and properties of the glycoprotein processing N-acetylglucosaminyltransferase II from plants

The presence of an N-acetylglucosaminyltransferase (GlcNAc-transferase) capable of adding a GlcNAc residue to GlcNAcMan3GlcNAc was demonstrated in mung bean seedlings. This enzyme was purified about 3400-fold by using (diethylaminoethyl)cellulose and phosphocellulose chromatographies and chromatography on Concanavalin A-Sepharose. The transferase was assayed by following the change in the migration of the [3H]mannose-labeled GlcNAc beta 1,2Man alpha 1,3(Man alpha 1,6)Man beta 1,4GlcNAc on Bio-Gel P-4, or by incorporation of [3H]GlcNAc from UDP-[3H]GlcNAc into a neutral product, (GlcNAc)2Man3GlcNAc. Thus, the purified enzyme catalyzed the addition of a GlcNAc to that mannose linked in alpha 1,6 linkage to the beta-linked mannose. GlcNAc beta 1,2Man alpha 1,3(Man alpha 1,6)Man beta 1,4GlcNAc was an excellent acceptor while Man alpha 1,6(Man alpha 1,3)Man beta 1,4GlcNAc, Man alpha 1,6(Man alpha 1,3)Man alpha 1,6(Man alpha 1,3)Man beta 1,4GlcNAc, and Man alpha 1,6(Man apha 1,3)Man alpha 1,6[GlcNAcMan alpha 1,3]Man beta 1,4GlcNAc were not acceptors. Methylation analysis and enzymatic digestions showed that both terminal GlcNAc residues on (GlcNAc)2Man3GlcNAc were attached to the mannoses in beta 1,2 linkages. The GlcNAc transferase had an almost absolute requirement for divalent cation, with Mn2+ being best at 2-3 mM. Mn2+ could not be replaced by Mg2+ or Ca2+, but Cd2+ showed some activity. The enzyme was also markedly stimulated by the presence of detergent and showed optimum activity at 0.15% Triton X-100. The Km for UDP-GlcNAc was found to be 18 microM and that for GlcNAcMan3GlcNAc about 16 microM.