O-Glycosylation of glycine-serine linkers in recombinant Fc-fusion proteins

A xylose-based glycosaminoglycan (GAG) core was recently identified at a Ser residue in the linker sequence of a recombinant Fc fusion protein. The linker sequence, G-S-G-G-G-G, and an upstream acidic residue were serving as a substrate for O-xylosyltransferase, resulting in a major glycan composed of Xyl-Gal-Gal-GlcA and other minor intermediates. In this paper, a portion of an unrelated protein was fused to the C-terminus of an IgG Fc domain using the common (G4S)₄ linker repeat. This linker resulted in a heterogenous population of xylose-based glycans all containing at least a core Xyl. Commonly observed glycan structures include GAG-related di-, tri-, tetra-, and penta-saccharides (e.g., Xyl-Gal, Xyl-Gal-Gal, Xyl-Gal-Gal-GlcA, and Xyl-Gal-Gal-GlcA-HexNAc), as well as Xyl-Gal-Neu5Ac. Following alkaline phosphatase or sialidase treatment combined with CID fragmentation, low-level glycans with a mass addition of 79.9 Da were confirmed to be a result of phosphorylated xylose. A minute quantity of phosphorylated GAG pentasaccharides may also be sulfated (also 79.9 Da), possibly at the HexNAc moiety due to non-reactivity to alkaline phosphatase. The xylose moiety may be randomly incorporated in one of the three G-S-G sequence motifs; and the linker peptide shows evidence for multiple additions of xylose at very low levels.     

Recombinant human lecithin‐cholesterol acyltransferase Fc fusion: Analysis of N‐ and O‐linked glycans and identification and elimination of a xylose‐based O‐linked tetrasaccharide core in the linker region

Recombinant human lecithin‐cholesterol acyltransferase Fc fusion (huLCAT‐Fc) is a chimeric protein produced by fusing human Fc to the C‐terminus of the human enzyme via a linker sequence. The huLCAT‐Fc homodimer contains five N‐linked glycosylation sites per monomer. The heterogeneity and site‐specific distribution of the various glycans were examined using enzymatic digestion and LC‐MS/MS, followed by automatic processing. Almost all of the N‐linked glycans in human LCAT are fucosylated and sialylated. The predominant LCAT N‐linked glycoforms are biantennary glycans, followed by triantennary sugars, whereas the level of tetraantennary glycans is much lower. Glycans at the Fc N‐linked site exclusively contain typical asialobiantennary structures. HuLCAT‐Fc was also confirmed to have mucin‐type glycans attached at T₄₀₇ and S₄₀₉. When LCAT‐Fc fusions were constructed using a G‐S‐G‐G‐G‐G linker, an unexpected +632 Da xylose‐based glycosaminoglycan (GAG) tetrasaccharide core of Xyl‐Gal‐Gal‐GlcA was attached to S₄₁₈. Several minor intermediate species including Xyl, Xyl‐Gal, Xyl‐Gal‐Gal, and a phosphorylated GAG core were also present. The mucin‐type O‐linked glycans can be effectively released by sialidase and O‐glycanase; however, the GAG could only be removed and localized using chemical alkaline β‐elimination and targeted LC‐MS/MS. E₄₁₆ (the C‐terminus of LCAT) combined with the linker sequence is likely serving as a substrate for peptide O‐xylosyltransferase. HuLCAT‐Fc shares some homology with the proposed consensus site near the linker sequence, in particular, the residues underlined PPP E₄₁₆GS₄₁₈G G G GDK. GAG incorporation can be eliminated through engineering by shifting the linker Ser residue downstream in the linker sequence.     

High-resolution mass spectrometry confirms the presence of a hydroxyproline (Hyp) post-translational modification in the GGGGP linker of an Fc-fusion protein

Flexible and protease resistant (G4S)_n linkers are used extensively in protein engineering to connect various protein domains. Recently, several groups have observed xylose-based O-glycosylation at linker Ser residues that yield unwanted heterogeneity and may affect product quality. Because of this, an engineering effort was implemented to explore different linker sequence constructs. Here, we demonstrate the presence of an unexpected hydroxylation of a prolyl residue in the linker, made possible through the use of high-resolution mass spectrometry (HR-MS) and MS_n. The discovery started with the detection of a poorly resolved ～+17 Da mass addition at the reduced protein chain level of an Fc-fusion construct by liquid chromatography-MS. Upon further investigation at the peptide level using HR-MS, the mass increase was determined to be +15.99 Da and was localized to the linker peptide SLSLSPGGGGGPAR [210–223]. This peptide corresponds to the C-terminus of Fc [210–216], the G4P linker [217–221], and first 2 amino acids of a growth factor [222–223]. The linker peptide was first subjected to MS² with collision-induced dissociation (CID) activation. The fragmentation profile localized the modification to the GGGPA [218–222] portion of the peptide. Accurate mass measurement indicated that the modification is an addition of an oxygen and cannot be CH₄, thus eliminating several possibilities such as Pro→Leu. However, other possibilities cannot be ruled out. Higher-energy collision-induced dissociation (HCD)-MS² and MS³ using CID/CID were both unable to differentiate between Ala222→ Ser222 or Pro221→ Hyp221. Finally, MS³ using high-resolution CID/HCD confirmed the mass increase to be a Pro221→Hyp221 post-translational modification.     

Inhibition of heparan sulfate and chondroitin sulfate proteoglycan biosynthesis

Proteoglycans (PGs) are composed of a protein moiety and a complex glycosaminoglycan (GAG) polysaccharide moiety. GAG chains are responsible for various biological activities. GAG chains are covalently attached to serine residues of the core protein. The first step in PG biosynthesis is xylosylation of certain serine residues of the core protein. A specific linker tetrasaccharide is then assembled and serves as an acceptor for elongation of GAG chains. If the production of endogenous GAG chains is selectively inhibited, one could determine the role of these endogenous molecules in physiological and developmental functions in a spatiotemporal manner. Biosynthesis of PGs is often blocked with the aid of nonspecific agents such as chlorate, a bleaching agent, and brefeldin A, a fungal metabolite, to elucidate the biological roles of GAG chains. Unfortunately, these agents are highly lethal to model organisms. Xylosides are known to prime GAG chains. Therefore, we hypothesized that modified xylose analogs may able to inhibit the biosynthesis of PGs. To test this, we synthesized a library of novel 4-deoxy-4-fluoroxylosides with various aglycones using click chemistry and examined each for its ability to inhibit heparan sulfate and chondroitin sulfate using Chinese hamster ovary cells as a model cellular system.     

Detection of a phosphorylated glycine-serine linker in an IgG-based fusion protein

Molecular mass determination by electrospray ionization mass spectrometry of a recombinant IgG-based fusion protein (mAb1-F) produced in human embryonic kidney (HEK) cells demonstrated the presence of a dominant +79 Da product variant. Using LC-MS tryptic peptide mapping analysis and collision-induced dissociation (CID) and electron-transfer/higher-energy collision dissociation fragmentations, the modification was localized to the C-terminal serine residue of a glycine-serine linker [(G₄S)₂] of a fused heavy chain containing in total 2 (G₄S)₂-linkers. The modification was identified as a phosphorylation (+79.97 Da) by the presence of a 98 Da neutral loss reaction with CID, by spiking a synthetic phosphoserine peptide, and by dephosphorylation with alkaline phosphatase. A thermolysin digest combined with higher-energy collision dissociation (HCD) positioned the phosphoserine to one specific glycine-serine linker of the fused heavy chain, and the relative level of phosphorylated linker was determined to be 11.3% and 0.4% by LC-MS when the fusion protein was transiently expressed in HEK or in stably transformed Chinese hamster ovary cells, respectively. This observation demonstrates that fusions with glycine-serine linker sequences should be carefully evaluated during drug development to prevent the introduction of a phosphorylation site in therapeutic fusion proteins.     

A beta-N-acetylglucosaminyl phosphate diester residue is attached to the glycosylphosphatidylinositol anchor of human placental alkaline phosphatase: a target of the channel-forming toxin aerolysin

Glycosylphosphatidylinositol (GPI)-anchored proteins are ubiquitous in eukaryotes. The minimum conserved GPI core structure of all GPI-anchored glycans has been determined as EtN-PO4-6Manalpha1-2Manalpha1-6Manalpha1-4GlcN-myo-inositol-PO3H. Human placental alkaline phosphatase (AP) has been reported to be a GPI-anchored membrane protein. AP carries one N-glycan, (NeuAcalpha2-->3)2Gal2GlcNAc2Man3GlcNAc(+/-Fuc)GlcNAc, and a GPI anchor, which contains an ethanolamine phosphate diester group, as a side chain. However, we found that both sialidase-treated soluble AP (sAP) and its GPI-anchored glycan bound to a Psathyrella velutina lectin (PVL)-Sepharose column, which binds beta-GlcNAc residues. PVL binding of asialo-sAP and its GPI-anchored glycan was diminished by digestion with diplococcal beta-N-acetylhexosaminidase or by mild acid treatment. After sequential digestion of asialo-sAP with beta-N-acetylhexosaminidase and acid phosphatase, the elution patterns on chromatofocusing gels were changed in accordance with the negative charges of phosphate residues. Trypsin-digested sAP was analyzed by liquid chromatography/electrospray ionization mass spectrometry, and the structures of two glycopeptides with GPI-anchored glycans were confirmed as peptide-EtN-PO4-6Manalpha1-->2(GlcNAcbeta1-PO4-->6)Manalpha1-6(+/-EtN-PO4-->)Manalpha1-->4GlcN, which may be produced by endo-alpha-glucosaminidase. In addition to AP, GPI-anchored carcinoembryonic antigen, cholinesterase, and Tamm-Horsfall glycoprotein also bound to a PVL-Sepharose column, suggesting that the beta-N-acetylglucosaminyl phosphate diester residue is widely distributed in human GPI-anchored glycans. Furthermore, we found that the beta-N-acetylglucosaminyl phosphate diester residue is important for GPI anchor recognition of aerolysin, a channel-forming toxin derived from Aeromonas hydrophila.     

Neutral N-glycans of the gastropod Arion lusitanicus.

The neutral N-glycan structures of Arion lusitanicus (gastropod) skin, viscera and egg glycoproteins were examined after proteolytic digestion, release of the glycans from the peptides, fluorescent labelling with 2-aminopyridine and fractionation by charge, size and hydrophobicity to obtain pure glycan structures. The positions and linkages of the sugars in the glycan were analysed by two dimensional HPLC (size and hydrophobicity) and MALDI-TOF mass spectrometry before and after digestion with specific exoglycosidases. The most striking feature in the adult tissues was the high amount of oligomannosidic and small paucimannosidic glycans terminated with 3-O-methylated mannoses. The truncated structures often contained modifications of the inner core by beta1,2-linked xylose to the beta-mannose residue and/or an alpha-fucosylation (mainly alpha1,6-) of the innermost GlcNAc residue. Skin and viscera showed predominantly the same glycans, however, in different amounts. Traces of large structures carrying 3-O-methylated galactoses were also detected. The egg glycans contained mainly (approximately 75%) oligomannosidic structures and some paucimannosidic structures modified by xylose or alpha1,6-fucose, but in this case no methylation of any monosaccharide was detected. Thus, gastropods seem to be capable of producing many types of structures ranging from those typical in human to structures similar to those found in nematodes, and therefore will be a valuable model to understand the regulation of glycosylation. Furthermore, this opens the way for using this organism as a host for the production of recombinant proteins. The detailed knowledge on glycosylation also may help to identify targets for pest control.     

N-linked glycans with similar location in the fusion protein head modulate paramyxovirus fusion

N-linked glycans not only orchestrate the folding and intracellular transport of viral glycoproteins but also modulate their function. We have characterized the three glycans attached to fusion (F) proteins of the morbilliviruses canine distemper virus and measles virus. The individual Morbillivirus glycans have similar functional properties: the glycan at position 68 is essential for protein transport, and those at positions 36 and 75 modulate fusion (numbering according to the Newcastle disease virus [NDV] F protein sequence). Based on the crystal structure of the NDV F protein, we then predicted the locations of the Morbillivirus glycans: the glycan at position 36 is located in the F protein head, and those at positions 68 and 75 are located near the neck-stalk interface. NDV position 36 is not occupied by a glycan; the only glycan in that F protein head also has a fusion control function and grows from residue 366, located only 6 A from residue 36. We then exchanged the glycan at position 36 with the glycan at position 366 and showed functional complementation. Thus, structural information about the F proteins of Paramyxoviridae coupled with functional analysis disclosed a location in the protein head into which fusion-modulating glycans independently evolved.     

Structure of the heparan sulfate-protein linkage region. Demonstration of the sequence galactosyl-galactosyl-xylose-2-phosphate

We have treated bovine lung heparan sulfate with alkaline [3H]borohydride to end label the chains with [3H]xylitol. After subsequent periodate oxidation-alkaline elimination products were separated by gel permeation and ion exchange chromatography. The linkage region fragment expected to have 2 galactoses and 1 [3H]xylitol residue appeared in the tetra-/trisaccharide region after gel filtration and was bound to the anion exchange resin. A similar negatively charged fragment, expected to have 2 galactoses, 1 xylose and 1 serine, was isolated after periodate oxidation-alkaline elimination of unlabeled heparan sulfate. The negative charge was due to the presence of alkaline phosphatase-labile phosphate ester. The molar ratio of galactose:phosphate:xylose was 2.17:1.19:1.00. The phosphate ester was associated with the xylose/[3H] xylitol moiety as indicated by the formation of phosphoxylose/-xylitol by beta-galactosidase digestion of the phosphorylated trisaccharide. Furthermore, orcinol reactivity disappeared after periodate oxidation of the dephosphorylated trisaccharide. The phosphate ester must be located to C-2 of xylose/xylitol as the 1-3H radioactivity could be released by periodate oxidation when it was preceded by alkaline phosphatase treatment. It is estimated that almost every chain of heparan sulfate carries 2-phosphoxylose. It would be of interest to know if glycosaminoglycan chains that are artificially initiated onto exogeneous beta-D-xylosides also acquire the 2-phosphoxylose moiety.     

Processing of complex N-glycans in IgG Fc-region is affected by core fucosylation

We investigated N-glycan processing of immunoglobulin G1 using the monoclonal antibody cetuximab (CxMab), which has a glycosite in the Fab domain in addition to the conserved Fc glycosylation, as a reporter. Three GlcNAc (Gn) terminating bi-antennary glycoforms of CxMab differing in core fucosylation (α1,3- and α1,6-linkage) were generated in a plant-based expression platform. These GnGn, GnGnF³, and GnGnF⁶ CxMab variants were subjected in vivo to further processing toward sialylation and GlcNAc diversification (bisected and branching structures). Mass spectrometry-based glycan analyses revealed efficient processing of Fab glycans toward envisaged structures. By contrast, Fc glycan processing largely depend on the presence of core fucose. A particularly strong support of glycan processing in the presence of plant-specific core α1,3-fucose was observed. Consistently, molecular modeling suggests changes in the interactions of the Fc carbohydrate chain depending on the presence of core fucose, possibly changing the accessibility. Here, we provide data that reveal molecular mechanisms of glycan processing of IgG antibodies, which may have implications for the generation of glycan-engineered therapeutic antibodies with improved efficacies.     

Recognition by TNF-alpha of the GPI-anchor glycan induces apoptosis of U937 cells

Tumor necrosis factor-alpha (TNF-alpha) binds to TNF-alpha receptors (TNFR) to produce a hexameric (TNF-alpha)(3)-(TNFR)(3) structure that stimulates apoptosis. We found by using ELISA that TNF-alpha binds to the glycosylphosphatidylinositol (GPI) anchor glycans of carcinoembryonic antigen, human placental alkaline phosphatase (hAP), and Tamm-Horsfall glycoprotein. These binding abilities were inhibited by 10(-6)M mannose-6-phosphate. Treatment of hAP with mild acid and phosphatase, which releases the N-acetylglucosamine (GlcNAc) beta1 -->phosphate-->6 residue from the GPI-anchor glycan of hAP, abrogated the binding of TNF-alpha to hAP. Thus, TNF-alpha binds to the GlcNAcbeta1-->phosphate-->6Man residue in GPI-anchor glycans. To investigate whether the carbohydrate-binding ability of TNF-alpha is related to its physiological functions, human lymphoma U937 cells were used. TNF-alpha stimulates U937 cell apoptosis in a dose-dependent manner and the presence of mannose-6-phosphate inhibited this. TNF-alpha-dependent tyrosine phosphorylation of several proteins in U937 cells was also diminished by mannose-6-phosphate. Phosphatidylinositol-specific phospholipase C-pretreatment also inhibited this tyrosine phosphorylation. These data suggest that TNF-alpha stimulates U937 cell apoptosis by forming a high-affinity nanomeric (TNF-alpha)(3)-(TNFR)(3)-(GPI-anchored glycan)(3) complex. The GPI-anchored glycoprotein involved remains to be identified.     

N-linked glycans of the human insulin receptor and their distribution over the crystal structure

The human insulin receptor (IR) homodimer is heavily glycosylated and contains a total of 19 predicted N-linked glycosylation sites in each monomer. The recent crystal structure of the IR ectodomain shows electron density consistent with N-linked glycosylation at the majority of sites present in the construct. Here, we describe a refined structure of the IR ectodomain that incorporates all of the N-linked glycans and reveals the extent to which the attached glycans mask the surface of the IR dimer from interaction with antibodies or other potential therapeutic binding proteins. The usefulness of Fab complexation in the crystallization of heavily glycosylated proteins is also discussed. The compositions of the glycans on IR expressed in CHO-K1 cells and the glycosylation deficient Lec8 cell line were determined by protease digestion, glycopeptide purification, amino acid sequence analysis, and mass spectrometry. Collectively the data reveal: multiple species of complex glycan at residues 25, 255, 295, 418, 606, 624, 742, 755, and 893 (IR-B numbering); multiple species of high-mannose glycan at residues 111 and 514; a single species of complex glycan at residue 671; and a single species of high-mannose glycan at residue 215. Residue 16 exhibited a mixture of complex, hybrid, and high-mannose glycan species. Of the remaining five predicted N-linked sites, those at residues 397 and 906 were confirmed by amino acid sequencing to be glycosylated, while that at residue 78 and the atypical (NKC) site at residue 282 were not glycosylated. The peptide containing the final site at residue 337 was not recovered but is seen to be glycosylated in the electron density maps of the IR ectodomain. The model of the fully glycosylated IR reveals that the sites carrying high-mannose glycans lie at positions of relatively low steric accessibility.     

Nucleotide sequence of the gene for alkaline phosphatase of Thermus caldophilus GK24 and characteristics of the deduced primary structure of the enzyme

The gene encoding Thermus caldophilus GK24 (Tca) alkaline phosphatase was cloned into Escherichia coli. The primary structure of Tca alkaline phosphatase was deduced from its nucleotide sequence. The Tca alkaline phosphatase precursor, including the signal peptide sequence, was comprised of 501 amino acid residues. Its molecular mass was determined to be 54? omitted?760 Da. On the alignment of the amino acid sequence, Tca alkaline phosphatase showed sequence homology with the microbial alkaline phosphatases, 20% identity with E. coli alkaline phosphatase and 22% Bacillus subtilis (Bsu) alkaline phosphatases. High sequence identity was observed in the regions containing the Ser-102 residue of the active site, the zinc and magnesium binding sites of E. coli alkaline phosphatase. Comparison of Tca alkaline phosphatase and E. coli alkaline phosphatase structures suggests that the reduced activity of the Tca alkaline phosphatase, in the presence of zinc, is directly involved in some of the different metal binding sites. Heat-stable Tca alkaline phosphatase activity was detected in E. coli YK537, harboring pJRAP.     

Glycopeptide profiling of beta-2-glycoprotein I by mass spectrometry reveals attenuated sialylation in patients with antiphospholipid syndrome

β2-glycoprotein I (β2GPI) is a five-domain protein associated with the antiphospholipid syndrome (APS), however, its normal biological function is yet to be defined. β2GPI is N-glycosylated at several asparagine residues and the glycan moiety conjugated to residue 143 has been proposed to interact with the Gly40–Arg43 motif of β2GPI. The Gly40–Arg43 motif has also been proposed to serve as the epitope for the anti-β2GPI autoantibody associated with APS. We hypothesized that the structure or composition of the glycan at Asn-143 might be associated with the APS symptom by shielding or exposing the Gly40–Arg43 motif towards the anti-β2GPI autoantibody. To test this hypothesis we used mass spectrometry (MS) for comparative glycopeptide profiling of human β2GPI obtained from blood serum from four healthy test subjects and six APS patients. It revealed significant differences in the extent of sialylation and branching of glycans at Asn-143. Biantennary glycans were more abundant than triantennary glycans at Asn-143 in both healthy subjects and patients. In APS patient samples we observed a decrease in sialylated triantennary glycans and an increase in sialylated biantennary glycan structures, as compared to controls. These data indicate that some APS patients have β2GPI molecules with a reduced number of negatively charged sialic acid units in the glycan structure at Asn-143. This alteration of the electrostatic properties of the glycan moiety may attenuate the intramolecular interactions with the positively charged Gly40–Arg43 motif of β2GPI and, in turn, leads to conformational instability and exposure of the disease-related linear epitope Gly40–Arg43 to the circulating autoantibody. Thus, our study suggests a link between site-specific glycan profiles of β2GPI and the pathology of antiphospholipid syndrome.     

Glycan Microarray Analysis of P-type Lectins Reveals Distinct Phosphomannose Glycan Recognition

The specificity of the cation-independent and -dependent mannose 6-phosphate receptors (CI-MPR and CD-MPR) for high mannose-type N-glycans of defined structure containing zero, one, or two Man-P-GlcNAc phosphodiester or Man-6-P phosphomonoester residues was determined by analysis on a phosphorylated glycan microarray. Amine-activated glycans were covalently printed on N-hydroxysuccinimide-activated glass slides and interrogated with different concentrations of recombinant CD-MPR or soluble CI-MPR. Neither receptor bound to non-phosphorylated glycans. The CD-MPR bound weakly or undetectably to the phosphodiester derivatives, but strongly to the phosphomonoester-containing glycans with the exception of a single Man7GlcNAc2-R isomer that contained a single Man-6-P residue. By contrast, the CI-MPR bound with high affinity to glycans containing either phospho-mono- or -diesters although, like the CD-MPR, it differentially recognized isomers of phosphorylated Man7GlcNAc2-R. This differential recognition of phosphorylated glycans by the CI- and CD-MPRs has implications for understanding the biosynthesis and targeting of lysosomal hydrolases.     

Trastuzumab and pertuzumab plant biosimilars: Modification of Asn297-linked glycan of the mAbs produced in a plant with fucosyltransferase and xylosyltransferase gene knockouts

Plant biosimilars of anticancer therapeutic antibodies are of interest not only because of the prospects of their practical use, but also as an instrument and object for study of plant protein glycosylation. In this work, we first designed a pertuzumab plant biosimilar (PPB) and investigated the composition of its Asn297-linked glycan in comparison with trastuzumab plant biosimilar (TPB). Both biosimilars were produced in wild-type (WT) Nicotiana benthamiana plant (PPBWT and TPB-WT) and transgenic ΔXTFT N. benthamiana plant with XT and FT genes knockout (PPB-ΔXTFT and TPBΔXTFT). Western blot analysis with anti-α1,3-fucose and anti-xylose antibodies, as well as a test with peptide-N-glycosidase F, confirmed the absence of α1,3-fucose and xylose in the Asn297-linked glycan of PPB-ΔXTFT and TPB-ΔXTFT. Peptide analysis followed by the identification of glycomodified peptides using MALDI-TOF/TOF showed that PPB-WT and TPB-WT Asn297-linked glycans are mainly of complex type GnGnXF. The core of PPB-WT and TPB-WT Asn297linked GnGn-type glycan contains α1,3-fucose and β1,2-xylose, which, along with the absence of terminal galactose and sialic acid, distinguishes these plant biosimilars from human IgG. Analysis of TPB-ΔXTFT total carbohydrate content indicates the possibility of changing the composition of the carbohydrate profile not only of the Fc, but also of the Fab portion of an antibody produced in transgenic ΔXTFT N. benthamiana plants. Nevertheless, study of the antigen-binding capacity of the biosimilars showed that absence of xylose and fucose residues in the Asn297-linked glycans does not affect the ability of the glycomodified antibodies to interact with HER2/neu positive cancer cells.     

Synthesis and biology of oligoethylene glycol linked naphthoxylosides

Proteoglycans (PGs) are important macromolecules in mammalian cells, consisting of a core protein substituted with carbohydrate chains, known as glycosaminoglycans (GAGs). Simple xylosides carrying hydrophobic aglycons can enter cells and act as primers for GAG chain synthesis, independent of the core protein. Previously it has been shown that aromatic aglycons can be separated from the sugar residue by short linkers without affecting the GAG priming ability. To further investigate the effects of the xylose–aglycon distance on the GAG priming ability, we have synthesized xyloside derivatives with 2-naphthyl and 2-(6-hydroxynaphthyl) moieties connected to xylose, directly, via a methylene bridge, or with oligoethylene glycol linkers of three different lengths. The GAG priming ability and the antiproliferative activity of the xylosides, as well as the composition of the xyloside-primed GAG chains were investigated in a matched pair of human breast fibroblasts and human breast carcinoma cells. An increase of the xylose–aglycon distance from 0.24 to 0.37 nm resulted in an increased GAG priming ability in both cell lines. Further increase of the xylose–aglycon distance did not result in any pronounced effects. We speculate that by increasing the xylose–aglycon distance, and thereby the surface area of the xyloside, to a certain level would make it more accessible for enzymes involved in the GAG synthesis. The compositions of the primed GAG chains varied with different xylosides, independent of the xylose–aglycon distance, probably due to various affinities for enzymes and/or different cellular uptake. Furthermore, no correlations between the antiproliferative activities, the xylose–aglycon distances, and the amounts or compositions of the GAG chains were detected suggesting involvement of other factors such as fine structure of the GAG chains, effects on endogenous PG synthesis, or other unknown factors for the antiproliferative activity.     

Glycopeptide profiling of beta-2-glycoprotein I by mass spectrometry reveals attenuated sialylation in patients with antiphospholipid syndrome

β2-glycoprotein I (β2GPI) is a five-domain protein associated with the antiphospholipid syndrome (APS), however, its normal biological function is yet to be defined. β2GPI is N-glycosylated at several asparagine residues and the glycan moiety conjugated to residue 143 has been proposed to interact with the Gly40–Arg43 motif of β2GPI. The Gly40–Arg43 motif has also been proposed to serve as the epitope for the anti-β2GPI autoantibody associated with APS. We hypothesized that the structure or composition of the glycan at Asn-143 might be associated with the APS symptom by shielding or exposing the Gly40–Arg43 motif towards the anti-β2GPI autoantibody. To test this hypothesis we used mass spectrometry (MS) for comparative glycopeptide profiling of human β2GPI obtained from blood serum from four healthy test subjects and six APS patients. It revealed significant differences in the extent of sialylation and branching of glycans at Asn-143. Biantennary glycans were more abundant than triantennary glycans at Asn-143 in both healthy subjects and patients. In APS patient samples we observed a decrease in sialylated triantennary glycans and an increase in sialylated biantennary glycan structures, as compared to controls. These data indicate that some APS patients have β2GPI molecules with a reduced number of negatively charged sialic acid units in the glycan structure at Asn-143. This alteration of the electrostatic properties of the glycan moiety may attenuate the intramolecular interactions with the positively charged Gly40–Arg43 motif of β2GPI and, in turn, leads to conformational instability and exposure of the disease-related linear epitope Gly40–Arg43 to the circulating autoantibody. Thus, our study suggests a link between site-specific glycan profiles of β2GPI and the pathology of antiphospholipid syndrome.     

Impact of variable domain glycosylation on antibody clearance: an LC/MS characterization

Variable (Fv) domain N-glycosylation sites are found in approximately 20% of human immunoglobulin Gs (IgGs) in addition to the conserved N-glycosylation sites in the C(H)2 domains. The carbohydrate structures of the Fv glycans and their impact on in vivo half-life are not well characterized. Oligosaccharide structures in a humanized anti-Abeta IgG1 monoclonal antibody (Mab) with an N-glycosylation site in the complementary determining region (CDR2) of the heavy chain variable region were elucidated by LC/MS analysis following sequential exoglycosidase treatments of the endoproteinase Lys-C digest. Results showed that the major N-linked oligosaccharide structures in the Fv region have three characteristics (core-fucosylated biantennary oligosaccharides with one or two N-glycolylneuraminic acid [NeuGc] residues, zero or one alpha-linked Gal residue, and zero or one beta-linked GalNAc residue), whereas N-linked oligosaccharides in the Fc region contained typical Fc glycans (core-fucosylated, biantennary oligosaccharides with zero to two Gal residues). To elucidate the contribution of Fv glycans to the half-life of the antibody, a method that allows capture of the Mab and determination of its glycan structures at various time points after administration to mice was developed. Anti-Abeta antibody in mouse serum was immunocaptured by immobilized goat anti-human immunoglobulin Fc(gamma) antibody resin, and the captured material was treated with papain to generate Fab and Fc for LC/MS analysis. Different glycans in the Fc region showed the same clearance rate as demonstrated previously. In contrast to many other non-antibody glycosylated therapeutics, there is no strong correlation between oligosaccharide structures in the Fv region and their clearance rates in vivo. Our data indicated that biantennary oligosaccharides lacking galactosylation had slightly faster clearance rates than other structures in the Fv domain.     

Antigen binding allosterically promotes Fc receptor recognition

A key question in immunology is whether antigen recognition and Fc receptor (FcR) binding are allosterically linked. This question is also relevant for therapeutic antibody design. Antibody Fab and Fc domains are connected by flexible unstructured hinge region. Fc chains have conserved glycosylation sites at Asn297, with each conjugated to a core heptasaccharide and forming biantennary Fc glycan. The glycans modulate the Fc conformations and functions. It is well known that the antibody Fab and Fc domains and glycan affect antibody activity, but whether these elements act independently or synergistically is still uncertain. We simulated four antibody complexes: free antibody, antigen-bound antibody, FcR-bound antibody, and an antigen-antibody-FcR complex. We found that, in the antibody’s “T/Y” conformation, the glycans, and the Fc domain all respond to antigen binding, with the antibody population shifting to two dominant clusters, both with the Fc-receptor binding site open. The simulations reveal that the Fc-glycan-receptor complexes also segregate into two conformational clusters, one corresponding to the antigen-free antibody-FcR baseline binding, and the other with an antigen-enhanced antibody-FcR interaction. Our study confirmed allosteric communications in antibody-antigen recognition and following FcR activation. Even though we observed allosteric communications through the IgG domains, the most important mechanism that we observed is the communication via population shift, stimulated by antigen binding and propagating to influence FcR recognition.