Carbohydrate structure of erythropoietin expressed in Chinese hamster ovary cells by a human erythropoietin cDNA

The proper glycosylation of erythropoietin is essential for its function in vivo. Human erythropoietins were isolated from Chinese hamster ovary cells transfected with a human erythropoietin cDNA and from human urine. Carbohydrate chains attached to these proteins were isolated and fractionated by anion-exchange high performance liquid chromatography (HPLC) and HPLC employing a Lichrosorb-NH2 column. The structures of fractionated saccharides were analyzed by fast atom bombardment-mass spectrometry and methylation analysis before and after treatment with specific exoglycosidases. Both erythropoietins were found to contain one O-linked oligosaccharide/mol of the proteins, and its major component was elucidated to be NeuNAc alpha 2----3Gal beta 1----3(NeuNAc alpha 2----6)GalNAcOH (where NeuNAc represents N-acetylneuraminic acid) in both proteins. The N-linked saccharides of recombinant erythropoietin were found to consist of biantennary (1.4% of the total saccharides), triantennary (10%), triantennary with one N-acetyllactosaminyl repeat (3.5%), tetraantennary (31.8%), and tetraantennary with one (32.1%), two (16.5%), or three (4.7%) N-acetyllactosaminyl repeats. All of these saccharides are sialylated by 2----3-linkages. Tetraantennary with or without polylactosaminyl units are mainly present as disialosyl or trisialosyl forms, and these structures exhibit the following unique features. alpha 2----3-Linked sialic acid and N-acetyllactosaminyl repeats are selectively present in the side chains attached to C-6 and C-2 of 2,6-substituted alpha-mannose and C-4 of 2,4-substituted alpha-mannose. We have also shown that the carbohydrate moiety of urinary erythropoietin is indistinguishable from recombinant erythropoietin except for a slight difference in sialylation, providing the evidence that recombinant erythropoietin is valuable for biological as well as clinical use.     

Application of liquid chromatography/mass spectrometry and liquid chromatography with tandem mass spectrometry to the analysis of the site-specific carbohydrate heterogeneity in erythropoietin

High-performance liquid chromatography with electrospray ionization mass spectrometry (LC/MS) and liquid chromatography with tandem mass spectrometry (LC/MS/MS) were applied to the analysis of the site-specific carbohydrate heterogeneity in erythropoietin (EPO) used as a model of the sialylated glycoprotein. N-linked oligosaccharides were released from recombinant human EPO expressed in Chinese hamster ovary cells enzymatically and reduced with NaBH(4). Many different sialylated oligosaccharides of EPO were separated and characterized by LC/MS equipped with a graphitized carbon column (GCC). Glycosylation sites and the preliminary glycosylation pattern at each glycosylation site were determined by LC/MS of endoproteinase Glu-C-digested EPO. The detailed site-specific carbohydrate heterogeneity caused by the differences in the molecular weight, branch, linkage, and sequence was elucidated by GCC-LC/MS of the N-linked oligosaccharides released from the isolated glycopeptides. Structural details of the isomers were analyzed by LC/MS/MS, and it was indicated that di- and trisialylated tetraantennary oligosaccharides are attached to Asn24, 38, and 83, whereas their isomers, di- and trisialylated triantennary oligosaccharides containing N-acetyllactosamines, are combined with Asn24. Our method is useful for the determination of glycosylation sites, the site-specific carbohydrate heterogeneity of glycoproteins, and the carbohydrate structure.     

Major carbohydrate structures at five glycosylation sites on murine IgM determined by high resolution 1H-NMR spectroscopy

Mouse myeloma immunoglobulin IgM heavy chains were cleaved with cyanogen bromide into nine peptide fragments, four of which contain asparagine-linked glycosylation. Three glycopeptides contain a single site, including Asn 171, 402, and 563 in the intact heavy chain. Another glycopeptide contains two sites at Asn 332 and 364. The carbohydrate containing fragments were treated with Pronase and fractionated by elution through Bio-Gel P-6. The major glycopeptides from each site were analyzed by 500 MHz 1H-NMR and the carbohydrate compositions determined by gas-liquid chromatography. The oligosaccharide located at Asn 171 is a biantennary complex and is highly sialylated. The amount of sialic acid varies, and some oligosaccharides contain alpha 1,3-galactose linked to the terminal beta 1,4-galactose. The oligosaccharides at Asn 332, Asn 364, an Asn 402 are all triantennary and are nearly completely sialylated on two branches and partially sialylated on the triantennary branch linked beta 1,4 to the core mannose. The latter is sialylated about 40% of the time for all three glycosylation sites. The major oligosaccharide located at Asn 563 is of the high mannose type. The 1H-NMR determination of structures at Asn 563 suggests that the high mannose oligosaccharide contains only three mannose residues.     

Site-specific glycosylation analysis of human apolipoprotein B100 using LC/ESI MS/MS

Human apolipoprotein B100 (apoB100) has 19 potential N-glycosylation sites, and 16 asparagine residues were reported to be occupied by high-mannose type, hybrid type, and monoantennary and biantennary complex type oligosaccharides. In the present study, a site-specific glycosylation analysis of apoB100 was carried out using reversed-phase high-performance liquid chromatography coupled with electrospray ionization tandem mass spectrometry (LC/ESI MS/MS). ApoB100 was reduced, carboxymethylated, and then digested by trypsin or chymotrypsin. The complex mixture of peptides and glycopeptides was subjected to LC/ESI MS/MS, where product ion spectra of the molecular ions were acquired data-dependently. The glycopeptide ions were extracted and confirmed by the presence of carbohydrate-specific fragment ions, such as m/z 204 (HexNAc) and 366 (HexHexNAc), in the product ion spectra. The peptide moiety of glycopeptide was determined by the presence of the b- and y-series ions derived from its amino acid sequence in the product ion spectrum, and the oligosaccharide moiety was deduced from the calculated molecular mass of the oligosaccharide. The heterogeneity of carbohydrate structures at 17 glycosylation sites was determined using this methodology. Our data showed that Asn2212, not previously identified as a site of glycosylation, could be glycosylated. It was also revealed that Asn158, 1341, 1350, 3309, and 3331 were occupied by high-mannose type oligosaccharides, and Asn 956, 1496, 2212, 2752, 2955, 3074, 3197, 3438, 3868, 4210, and 4404 were predominantly occupied by mono- or disialylated oligosaccharides. Asn3384, the nearest N-glycosylation site to the LDL-receptor binding site (amino acids 3359-3369), was occupied by a variety of oligosaccharides, including high-mannose, hybrid, and complex types. These results are useful for understanding the structure of LDL particles and oligosaccharide function in LDL-receptor ligand binding.     

Glycosylation sites and site-specific glycosylation in human Tamm- Horsfall glycoprotein

The N-glycosylation sites of human Tamm-Horsfall glycoprotein from one healthy male donor have been characterized, based on an approach using endoproteinase Glu-C (V-8 protease, Staphylococcus aureus ) digestion and a combination of chromatographic techniques, automated Edman sequencing, and fast atom bombardment mass spectrometry. Seven out of the eight potential N-glycosylation sites, namely, Asn52, Asn56, Asn208, Asn251, Asn298, Asn372, and Asn489, turned out to be glycosylated, and the potential glycosylation site at Asn14, being close to the N-terminus, is not used. The carbohydrate microheterogeneity on three of the glycosylation sites was studied in more detail by high-pH anion-exchange chromatographic profiling and 500 MHz1H-NMR spectroscopy. Glycosylation site Asn489 contains mainly di- and tri-charged oligosaccharides which comprise, among others, the GalNAc4 S (beta1-4)GlcNAc terminal sequence. Only glycosylation site Asn251 bears oligomannose-type carbohydrate chains ranging from Man5GlcNAc2to Man8GlcNAc2, in addition to a small amount of complex- type structures. Profiling of the carbohydrate moieties of Asn208 indicates a large heterogeneity, similar to that established for native human Tamm-Horsfall glycoprotein, namely, multiply charged complex-type carbohydrate structures, terminated by sulfate groups, sialic acid residues, and/or the Sda-determinant.      

Site-specific detection and structural characterization of the glycosylation of human plasma proteins lecithin:cholesterol acyltransferase and apolipoprotein D using HPLC/electrospray mass spectrometry and sequential glycosidase digestion.

Site-specific structural characterization of the glycosylation of human lecithin:cholesterol acyltransferase (LCAT) was carried out using microbore reversed-phase high performance liquid chromatography coupled with electrospray ionization mass spectrometry (HPLC/ESIMS). A recently described mass spectrometric technique involving monitoring of carbohydrate-specific fragment ions during HPLC/ESIMS was employed to locate eight different groups of glycopeptides in a digest of a human LCAT protein preparation. In addition to the four expected N-linked glycopeptides of LCAT, a di-O-linked glycopeptide was detected, as well as three additional glycopeptides. Structural information on the oligosaccharides from all eight glycopeptides was obtained by sequential glycosidase digestion of the glycopeptides followed by HPLC/ESIMS. All four potential N-linked glycosylation sites (Asn20, Asn84, Asn272, and Asn384) of LCAT were determined to contain sialylated triantennary and/or biantennary complex structures. Two unanticipated O-linked glycosylation sites were identified at Thr407 and Ser409 of the LCAT O-linked glycopeptide, each of which contain sialylated galactose beta 1-->3N-acetylgalactosamine structures. The three additional glycopeptides were determined to be from a copurifying protein, apolipoprotein D, which contains potential N-linked glycosylation sites at Asn45 and Asn78. These glycopeptides were determined to bear sialylated triantennary oligosaccharides or fucosylated sialylated biantennary oligosaccharides. Previous studies of LCAT indicated that removal of the glycosylation site at Asn272 converts this protein to a phospholipase (Francone OL, Evangelista L, Fielding CJ, 1993, Biochim Biophys Acta 1166:301-304). Our results indicate that the carbohydrate structures themselves are not the source of this functional discrimination; rather, it must be mediated by the structural environment around Asn272.     

Analysis of the site-specific N-glycosylation of beta1,6 N-acetylglucosaminyltransferase V

N-acetylglucosaminyltransferase V (GnT-V) catalyzes the addition of a beta1,6-linked GlcNAc to the alpha1,6 mannose of the trimannosyl core to form tri- and tetraantennary N-glycans and contains six putative N-linked sites. We used mass spectrometry techniques combined with exoglycosidase digestions of recombinant human GnT-V expressed in CHO cells, to identify its N-glycan structures and their sites of expression. Release of N-glycans by PNGase F treatment, followed by analysis of the permethylated glycans using MALDI-TOF MS, indicated a range of complex glycans from bi- to tetraantennary species. Mapping of the glycosylation sites was performed by enriching for trypsin-digested glycopeptides, followed by analysis of each fraction with Q-TOF MS. Predicted tryptic glycopeptides were identified by comparisons of theoretical masses of peptides with various glycan masses to the masses of the glycopeptides determined experimentally. Of the three putative glycosylation sites in the catalytic region, peptides containing sites Asn 334, 433, and 447 were identified as being N-glycosylated. Asn 334 is glycosylated with only a biantennary structure with one or two terminating sialic acids. Sites Asn 433 and 447 both contain structures that range from biantennary with two sialic acids to tetraantennary terminating with four sialic acids. The predominant glycan species found on both of these sites is a triantennary with three sialic acids. The appearance of only biantennary glycans at site Asn 433, coupled with the appearance of more highly branched structures at Asn 334 and 447, demonstrates that biantennary acceptors present at different sites on the same protein during biosynthesis can differ in their accessibility for branching by GnT-V.     

Carbohydrate heterogeneity of vesicular stomatitis virus G glycoprotein allows localization of the defect in a glycosylation mutant of CHO cells

The carbohydrate portion of the G glycoprotein of vesicular stomatitis virus (VSV) grown in CHO cells (CHO/VSV) has been fractionated on BioGelP6, concanavalin A-Sepharose, and pea lectin-agarose. The results suggest that, in addition to sialic acid and fucose heterogeneity, the asparagine-linked complex carbohydrate moieties of CHO/VSV also display branching heterogeneity. Although the majority of the glycopeptides bind to concanavalin A-Sepharose in a manner typical of certain biantennary carbohydrate structures, a significant proportion do not bind to the lectin. The latter behavior is typical of tri- or tetraantennary (branched) carbohydrate structures. The CHO/VSV glycopeptides which do not bind to concanavalin A-Sepharose separate into bound and unbound fractions on pea lectin-agarose suggesting that they include at least two different types of (branched) carbohydrate structures. Glycopeptides from the G glycoprotein of VSV grown in two, independently derived CHO glycosylation mutants which belong to complementation group 4 (Lec4 mutants) were examined in the same manner. In contrast to glycopeptides from CHO/VSV, glycopeptides from Lec4/VSV which passed through concanavalin A-Sepharose did not contain a component which subsequently bound to pea lectin-agarose. A glycopeptide fraction with these lectin-binding properties was also missing from cell surface glycopeptides derived from Lec4 cells. The combined results are consistent with the hypothesis that Lec4 CHO glycosylation mutants lack a glycosyltransferase activity responsible for the addition of a (branch) N-acetylglucosamine residue linked β1,6 to mannose.     

Antibody variable region glycosylation: position effects on antigen binding and carbohydrate structure.

The presence of N-linked carbohydrate at Asn58 in the VH of the antigen binding site of an antibody specific for alpha(1----6)dextran (TKC3.2.2) increases its affinity for dextran 10- to 50-fold. Site-directed mutagenesis has now been used to create novel carbohydrate addition sequences in the CDR2 of a non-glycosylated anti-dextran at Asn54 (TST2) and Asn60 (TSU7). These antibodies are glycosylated and the carbohydrates are accessible for lectin binding. The amino acid change in TSU7 (Lys62----Thr62) decreases the affinity for antigen; however, glycosylation of TSU7 increased its affinity for antigen 3-fold, less than the greater than 10-fold increase in affinity seen for glycosylated TKC3.2.2. The difference in impact of glycosylation could result either from the position of the carbohydrate or from its structure; unlike the other antibodies, TSU7 attaches a high mannose, rather than complex, carbohydrate in CDR2. In contrast, glycosylation of TST2 at amino acid 54 inhibits dextran binding. Thus slight changes in the position of the N-linked carbohydrate in the CDR2 of this antibody result in substantially different effects on antigen binding. Unlike what was observed for the anti-dextrans, a carbohydrate addition site placed in a similar position in an anti-dansyl is not utilized.     

A general approach for characterizing glycosylation sites of glycoproteins.

Recent advances in glycobiology have greatly stimulated carbohydrate research; however, improving techniques for identification and isolation of specific glycosylation sites in protein structure analysis remains a challenge. We report here a practical approach utilizing a membrane staining technique on Problott, a PVDF-type membrane, to screen glycoproteins and glycopeptides derived from enzymatic digests of glycoproteins. To improve the detection sensitivity, an amplified staining technique using biotinylated lectins, avidin, and biotinylated peroxidase was employed. In addition, we describe a micro-batch affinity binding procedure to isolate glycopeptides from complex glycoprotein enzymatic digests. These protocols allow us to start with a subnanomole quantity of glycoprotein and locate the glycosylation sites; isolate glycopeptides in a homogeneous form; and perform amino acid composition, amino acid sequence, and mass analyses on the isolated glycopeptides. The characterization of glycosylation site of a model glycoprotein, carboxypeptidase P, of which the structure is still largely unknown, has been investigated.     

The asparagine-linked oligosaccharides at individual glycosylation sites in human thyrotrophin.

The asparagine-linked carbohydrate structures at each of the three glycosylation sites of human thyrotrophin were investigated by 400 MHz 1H-NMR spectroscopy. Highly purified, biologically active human thyrotrophin (hTSH) was dissociated into its subunits hTSH alpha (glycosylated at Asn 52 and Asn 78) and hTSH beta (glycosylated at Asn 23). The alpha-subunit was further treated with trypsin which gave two glycopeptides that were subsequently separated by reverse-phase HPLC and identified by amino acid sequence analysis. The oligosaccharides were liberated from hTSH alpha glycopeptides and from intact hTSH beta by hydrazinolysis, and were fractionated as alditols by anion-exchange and ion-suppression amine-adsorption HPLC preparatory to structural analysis. The N-glycans present on hTSH were mainly diantennary complex-type structures with a common Man alpha 1-3 branch that terminated with 4-O-sulphated GalNAc. The Man alpha 1-6 branch displayed structural heterogeneity in the terminal sequence, with chiefly alpha 2-3-sialylated Gal and/or 4-O-sulphated GalNAc. The relative amounts of the two major complete diantennary oligosaccharides and their core fucosylation differed according to glycosylation site; the sulphated/sialylated diantennary oligosaccharide was most abundant at the two sites on the alpha-subunit, whereas the disulphated, core-fucosylated oligosaccharide was more plentiful on the beta-subunit. Some interesting structural features, not previously reported for the N-glycans of hTSH, included 3-O-sulphated galactose (SO4-3Gal) and peripheral fucose (Fuc alpha 1-3GlcNAc) in the Man alpha 1-6 branch of some diantennary structures; the former suggests the presence of a hitherto uncharacterized galactose-3-O-sulphotransferase in thyrotroph cells of the human anterior pituitary gland.     

Usefulness of glycopeptide mapping by liquid chromatography/mass spectrometry in comparability assessment of glycoprotein products.

We previously reported on glycopeptide mapping of erythropoietin (EPO) by liquid chromatography/mass spectrometry (LC/MS). Using this method, glycopeptides in proteolytic digestion can be eluted before peptides, and are further separated on the basis of the carbohydrate structure. The detailed glycosylation at each glycosylation site can be elucidated based on mass chromatography and mass spectroscopy. In this study, we evaluated glycopeptide mapping with regard to its use in comparability assessment of glycoprotein products possessing multiple glycosylation sites. Models of closely related glycoprotein products used in this study are EPOs produced from three different sources. We previously reported that there are differences in the carbohydrate heterogeneity of these EPOs with regard to sialylation, acetylation, and sulphation patterns, using sugar mapping by LC/MS. In this paper, we demonstrated that glycopeptide mapping can distinguish site-specific glycosylation among these three EPOs and reveal the differences in acetylation, sialylation, and sulphation at each glycosylation site in one analysis. Our method can thus be useful in comparability assessment of therapeutic glycoproteins in terms of glycosylation.     

Characterization of the glycosylation sites in cyclooxygenase-2 using mass spectrometry

Cyclooxygenase is involved in the biosynthesis and function of prostaglandins. It is a glycoprotein located in the endoplasmic reticulum and in the nuclear envelope, and it has been found to have two isoforms termed COX-1 and COX-2. This paper reports on the glycosylation site analysis of recombinant COX-2 using matrix-assisted laser desorption/ionization (MALDI) time-of-flight (TOF) mass spectrometry (MS) and nanoelectrospray (nanoESI) quadrupole-TOF (Q-TOF) MS. The nanoESI MS analysis of COX-2 revealed the presence of three glycoforms at average molecular masses of 71.4, 72.7, and 73.9 kDa. Each glycoform contained a number of peaks differing by 162 Da indicating heterogeneity and suggesting the presence of high-mannose sugars. The masses of the glycoforms indicate that oligosaccharides occupy two to four sites and a single N-acetylglucosamine (GlcNAc) residue occupied up to two sites. The MALDI MS analysis of a tryptic digest of the protein showed a number of potential glycopeptides. The peptides differed by 162 Da which further suggested high-mannose sugars. Nanoelectrospray MS/MS experiments confirmed glycosylation at the Asn 53 and Asn 130 sites and confirmed the presence of the peptides Asn 396-Arg 414 + GlcNAc and Thr 576-Arg 587 + GlcNAc containing Asn 580. It was not possible to conclusively determine whether the Asn 396 site was glycosylated via an MS/MS experiment, so the tryptic digest was deglycosylated to confirm the presence of the glycopeptides. Finally, a non-glycosylated tryptic peptide was observed containing the Asn 592.     

Site-specific N-glycosylation analysis of human plasma ceruloplasmin using liquid chromatography with electrospray ionization tandem mass spectrometry

Ceruloplasmin has ferroxidase activity and plays an essential role in iron metabolism. In this study, a site-specific glycosylation analysis of human ceruloplasmin (CP) was carried out using reversed-phase high-performance liquid chromatography with electrospray ionization tandem mass spectrometry (LC-ESI-MS/MS). A tryptic digest of carboxymethylated CP was subjected to LC-ESI-MS/MS. Product ion spectra acquired data-dependently were used for both distinction of the glycopeptides from the peptides using the carbohydrate B-ions, such as m/z 204 (HexNAc) and m/z 366 (HexHexNAc), and identification of the peptide moiety of the glycopeptide based on the presence of the b- and y-series ions derived from the peptide. Oligosaccharide composition was deduced from the molecular weight calculated from the observed mass of the glycopeptide and theoretical mass of the peptide. Of the seven potential N-glycosylation sites, four (Asn119, Asn339, Asn378, and Asn743) were occupied by a sialylated biantennary or triantennary oligosaccharide with fucose residues (0, 1, or 2). A small amount of sialylated tetraantennary oligosaccharide was detected. Exoglycosidase digestion suggested that fucose residues were linked to reducing end GlcNAc in biantennary oligosaccharides and to reducing end and/or alpha1-3 to outer arms GlcNAc in triantennary oligosaccharides and that roughly one of the antennas in triantennary oligosaccharides was alpha2-3 sialylated and occasionally alpha1-3 fucosylated at GlcNAc.     

Characterization of N-glycans from mouse brain neural cell adhesion molecule.

The N-glycosylation pattern of the neural cell adhesion molecule (NCAM), isolated from brains of newborn mice, has been analyzed. Following digestion with trypsin, generated glycopeptides were fractionated by serial immunoaffinity chromatography using immobilized monoclonal antibodies specifically recognizing polysialic acid (PSA) units or the HNK1-carbohydrate epitope. Subsequent analyses of the resulting (glyco)peptides by Edman degradation and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS) revealed polysialylated glycans to be exclusively linked to glycosylation sites 5 (Asn(431)) and 6 (Asn(460)), whereas glycans carrying the HNK1-epitope could be assigned to sites 2 (Asn(297)), 5, 6, and, to a lesser extent, site 3 (Asn(329)). PSA-, HNK1-, and non-PSA/HNK1-glycan fractions were characterized by carbohydrate constituent and methylation analyses as well as MALDI-TOF-MS in conjunction with chromatographic fractionation techniques. The results revealed that the core structures of PSA-glycans represented predominantly fucosylated, partially sulfated 2,6-branched isomers of triantennary as well as tetraantennary complex-type glycans, whereas carbohydrate chains bearing the HNK1-epitope were dominated by diantennary species carrying in part bisecting GlcNAc residues. Non-PSA/HNK1-glycans exhibited a highly heterogeneous pattern of partially truncated, mostly diantennary structures being characterized by the presence of additional fucose, bisecting GlcNAc and/or sulfate residues. In conclusion, our results revealed that the glycosylation pattern of murine NCAM displays high structural and regional selectivity, which might play an important role in controlling the biological activities of this molecule.     

Site-specific glycosylation in animal cells. Substitution of glutamine for asparagine 293 in chicken ovalbumin does not allow glycosylation of asparagine 312

It has been shown previously that chicken ovalbumin synthesized and secreted in a heterologous cell system is glycosylated at the correct site and that the oligosaccharides at that site, similar to the protein made in hen oviduct, are predominantly of the hybrid type (Sheares, B. T., and Robbins, P. W. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 1993-1997). This site-specific glycosylation of Asn293, but not Asn312, suggested a prominent role for the nascent protein chain rather than the specific cell type in directing the proper attachment of oligosaccharide chains. In the present study, the effect of glycosylation at Asn293 on the glycosylation of Asn312 has been investigated. Using a 20-base oligodeoxynucleotide primer containing a 2-base mismatch, the codon for Asn293 in the chicken ovalbumin gene (AAC) was changed to that for Gln (CAA), thereby preventing glycosylation at amino acid 293. Constructions containing this mutation were transfected into mouse L (tk-) cells which were subsequently labeled with [35S]methionine. Ovalbumin secreted by these cells was recovered by immunoaffinity chromatography and analyzed for the presence of an oligosaccharide attached at Asn312. Treatment of the material with peptide:N-glycosidase F demonstrated that ovalbumin molecules containing Gln substituted for Asn293 were not glycosylated. This further supports our earlier hypothesis that the nascent protein chain is responsible for directing site-specific glycosylation of ovalbumin, and that the presence of an oligosaccharide chain at the first site has no influence on glycosylation at the second site.     

Carbohydrate mapping by mass spectrometry: a novel method for identifying attachment sites of Asn-linked sugars in glycoproteins

A new method is described for locating the specific sites of attachment of Asn-linked carbohydrates in glycoproteins. The molecular weights of peptides released from the glycoprotein with proteases of known specificity are determined by fast atom bombardment mass spectrometry and fitted to the known or DNA-derived sequence. Oligosaccharides attached to Asn are released either before or after proteolysis with a glycosidase, usually peptide: N-glycosidase F, an enzyme that cleaves the beta-aspartylglycosylamine linkage of all known types of Asn-linked sugars and converts the attachment-site Asn to Asp. New peaks appearing in the mass spectra after treatment with glycosidase correspond to formerly glycosylated sites. Conversely, signals which disappear after glycosidase treatment correspond to glycopeptides. The differences in mass between these sets of signals define the composition of the carbohydrate at the given site in terms of deoxyhexose, hexose, N-acetylhexosamine, and sialic acid content. The extent of glycosylation at a given site can be estimated from the ratio of the peak heights corresponding to the Asn- vs Asp-containing peptides which differ by 1 Da in mass. This rapid and sensitive (low nmol) technique is illustrated here for ribonuclease B and for tissue plasminogen activator, a multiply glycosylated glycoprotein.     

The N-glycosylation sites of soybean seed coat peroxidase

Tryptic digestion of apo-soybean peroxidase (apo-SBP), withand without acetamidation, chromatographic separation of thetryptic fragments and MALDI-TOF analysis of the major components,both before and after digestion with glycopeptidase A, demonstratedthe presence of six carbohydrate groups on five peptides. Fiveof the glycopeptides can be mapped with confidence to the peptidescontaining Asn16, Asn90, Asn104, Asn169, and Asn174. The sixthN-glycosylation site is not known and does not appear to beAsn145. It may be present on the N-terminus of SBP, which hasnot been sequenced. soybean seed coat peroxidase glycopeptides glycosylation sites MALDI-TOF MS     

Chemo-enzymatic synthesis and structure-activity study of artificially N-glycosylated eel calcitonin derivatives with a complex type oligosaccharide

Starting from N-glycosylated eel calcitonin derivatives that contain an N-acetyl-D-glucosamine residue specifically at the 3rd, 14th, 20th or 26th amino acid residue, corresponding glycopeptides with a complex-type oligosaccharide attached to the respective amino acid residue were synthesized by means of a transglycosylation reaction catalyzed by an endo-beta-N-acetylglucosaminidase from Mucor hiemalis . The use of a recombinant enzyme and an excess of a glycosyl donor led to a yield in excess of 60%. Calcitonin derivatives containing truncated oligosaccharides were also prepared via digestion of the complex-type N-glycan with exoglycosidases. Using these N-glycosylated calcitonin derivatives, the effect of carbohydrate structure and glycosylation site on the three-dimensional structure and the biological activity of the peptide were studied. The conformation of the peptide backbone did not change irrespective of the carbohydrate structure or the glycosylation site. However, hypocalcemic activity, calcitonin-receptor binding activity and the biodistribution of the derivatives were affected by the glycosylation and were dependent on both the carbohydrate structure and the glycosylation site. Although the larger oligosaccharides tended to hinder receptor binding, the biodistribution altered by N-glycosylation appeared to enhance the hypocalcemic activity in some cases, and the magnitude of the effect was dependent on the site of glycosylation.     

Characterization of protein glycosylation using chip-based infusion nanoelectrospray linear ion trap tandem mass spectrometry.

Mass spectrometry (MS) has the potential to revolutionize structural glycobiology and help in the understanding of how post-translation events such as glycosylation affect protein activities. Several approaches to determine the structure of glycopeptides have been used successfully including fast atom bombardment, matrix-assisted laser desorption ionization, and electrospray ionization with a wide variety of mass analyzers. However, the identification of glycopeptides in a complex mixture still remains a challenge. The source of this challenge is primarily due to the poor ionization efficiency and rapid degradation of glycopeptides. In this report we describe the use of a chip-based infusion nanoelectrospray ionization technique in combination with a recently developed linear ion trap for identification and characterization of glycosylation in complex mixtures. Two standard synthetic glycans were analyzed using multiple-stage fragmentation analysis in both positive and negative ionization modes. In addition, the high mannose type N-glycosylation in ribonuclease B (RNase B) was used to map the glycosylation site and obtain the glycan structures. We were able to map the glycosylation site and obtain the glycan structures in RNase B in a single analysis. The results reported here demonstrate that the fully automated chip-based nanoelectrospray linear ion trap platform is a valuable system for oligosaccharide analyses due to the unique MS/MS and MS(n) capability of the linear ion trap and the extended analysis time provided by the ionization technique.