A molecular basis for glycosylation-induced conformational switching

Background: Asparagine-linked glycosylation has the capacity to greatly influence the structure and function of glycoproteins. In most cases, however, it is unclear specifically how the carbohydrate moiety interacts with the protein to influence its conformation.Results: A series of glycopeptides based on the critical A285 glycosylation site of the hemagglutinin glycoprotein from influenza virus was used as a model system to study the effects of asparagine-linked glycosylation. Derivatization of this peptide with a family of short carbohydrates reveals that subtle changes in the structure of the carbohydrate have a dramatic impact on peptide conformation. Modification of the hemagglutinin glycopeptide with a truncated version of the native carbohydrate induces a β-turn structure similar to the structure found in the native protein. Replacement of the C2 and C2′ N-acetyl groups of the carbohydrates with hydroxyl moieties results in a less well-ordered peptide conformation.Conclusions: It is likely that the N-acetyl groups of the carbohydrates have a critical role in promoting the more compact β-turn conformation through steric interactions with the peptide. This study has demonstrated that relatively small changes in carbohydrate composition can have dramatic ramifications on glycopeptide conformation.     

Principles of mucin architecture: structural studies on synthetic glycopeptides bearing clustered mono-, di-, tri-, and hexasaccharide glycodomains

The structural characteristics of a mucin glycopeptide motif derived from the N-terminal fragment STTAV of the cell surface glycoprotein CD43 have been investigated by NMR. In this study, a series of molecules prepared by total synthesis were examined, consisting of the peptide itself, three glycopeptides having clustered sites of alpha-O-glycosylation on the serine and threonine side chains with the Tn, TF, and STF carbohydrate antigens, respectively, and one with the beta-O-linked TF antigen. Additionally, a glycopeptide having the sequence SSSAVAV, triglycosylated with the Le(y) epitope, was investigated. NMR data for the tri-STF-STTAV glycopeptide were used to solve the structure of this construct through restrained molecular dynamics calculations. The calculations revealed a defined conformation for the glycopeptide core rooted in the interaction of the peptide and the first N-acetylgalactosamine residue. The similarity of the NMR data for each of the alpha-O-linked glycopeptides demonstrates that this structure persists for each construct and that the mode of attachment of the first sugar and the peptide is paramount in establishing the organization of the core. The core provides a common framework on which a variety of glycans may be displayed. Remarkably, while there is a profound organizational effect on the peptide backbone with the alpha-linked glycans, attachment via a beta-linkage has little apparent consequence.     

Recent progress in the solid-phase synthesis of glycopeptide

The recent understanding of the biological role of glycoproteins has brought about a demand for the highly homogeneous glycopeptides as the functional model for glycoproteins. Thus, much efforts have been made to establish easy and efficient method for glycopeptide synthesis. In this paper, we briefly review the recent advances in the synthesis of O- and N-linked glycopeptide based on the solid-phase method. In O-glycopeptide section, the preparation of glycosylated amino acid units with mucin type and other O-linked carbohydrate chains and their use for solid-phase synthesis are summarized. Other approaches, such as the glycosylation of resin bound peptide are also overviewed. In N-glycopeptide section, the synthesis using glycosylated amino acid units as well as other methods are described.     

Characterization of O-glycosylation sites in MUC2 glycopeptides by nanoelectrospray QTOF mass spectrometry

Sequencing of eight O-glycosylated peptides by nanoESI-QTOF-MS/MS was carried out to provide a sensitive general characterization method for determination of glycosylation site(s) and of the type of the attached carbohydrate moiety in a single experiment. The glycopeptide structures were chosen to demonstrate the feasibility of this sensitive and accurate approach, where isobaric peptide structures either (i) with the same number of attachment sites in different position in the peptide backbone, and (ii) with the same number of sugar moieties distributed on different attachment sites in the peptide backbone, can be clearly distinguished. Beside the B-type carbohydrate sequence ions of high abundance, it is possible to register diagnostic b- and y-type glycosylated peptide ions of lower abundance due to high dynamic range of the QTOF analyser. The applicability of this approach for detailed analysis of highly clustered O-glycan structures as found in biological mucin samples is discussed.     

Toward fully synthetic glycoproteins by ultimately convergent routes: a solution to a long-standing problem

A method is disclosed for the convergent synthesis of multiply glycosylated peptides. The approach centers on a convergent technique for generating masked, complex glycopeptide-containing C-terminal acyl donors. Activation of the latent donor in situ and use directly in segment coupling with a second peptide bearing a complex carbohydrate produces a completely unprotected, bifunctional glycopeptide. The system demonstrates a minimum level of hydrolysis and epimerization at the C-terminal amino acid residue of the acyl donor during fully convergent segment coupling and is therefore a powerful tool for the synthesis of glycoproteins.     

Characterization of a gel-separated unknown glycoprotein by liquid chromatography/multistage tandem mass spectrometry: analysis of rat brain Thy-1 separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis

We developed an efficient and convenient strategy for protein identification and glycosylation analysis of a small amount of unknown glycoprotein in a biological sample. The procedure involves isolation of proteins by electrophoresis and mass spectrometric peptide/glycopeptide mapping by LC/ion trap mass spectrometer. For the complete glycosylation analysis, proteins were extracted in intact form from the gel, and proteinase-digested glycoproteins were then subjected to LC/multistage tandem MS (MSn) incorporating a full mass scan, in-source collision-induced dissociation (CID), and data-dependent MSn. The glycopeptides were localized in the peptide/glycopeptide map by using oxonium ions such as HexNAc+ and NeuAc+, generated by in-source CID, and neutral loss by CID-MS/MS. We conducted the search analysis for the glycopeptide identification using search parameters containing a possible glycosylation at the Asn residue with N-acetylglucosamine (203 Da). We were able to identify the glycopeptides resulting from predictable digestion with proteinase. The glycopeptides caused by irregular cleavages were not identified by the database search analysis, but their elution positions were localized using oxonium ions produced by in-source CID, and neutral loss by the data-dependent MSn. Then, all glycopeptides could be identified based on the product ion spectra which were sorted from data-dependent CID-MSn spectra acquired around localized positions. Using this strategy, we successfully elucidated site-specific glycosylation of Thy-1, glycosylphosphatidylinositol (GPI)-anchored proteins glycosylated at Asn23, 74, and 98, and at Cys111. High-mannose-type, complex-type, and hybrid-type oligosaccharides were all found to be attached to Asn23, 74 and 98, and four GPI structures could be characterized. Our method is simple, rapid and useful for the characterization of unknown glycoproteins in a complex mixture of proteins.     

Rapid characterization of N-linked glycosylation site using non-specific protease digestion of gel-separated glycoproteins and matrix-assisted laser desorption/ionization tandem time-of-flight mass spectrometry

Rapid identification of glycosylation sites of glycoproteins is urgently needed in glycoproteomics study. In the present work, a rapid and simple method based on non-specific digestion of gel-separated glycoproteins and matrix-assisted laser desorption/ionization tandem time-of-flight mass spectrometry was described, which can efficiently identify the N-linked glycosylation sites. One-step in-gel digestion of Ribonuclease B (RNase B) by proteinase K was employed to generate glycopeptides with short and discrepant peptide composition. When compared with glycopeptides prepared by two-step in gel-digestion using trypsin-proteinase K or trypsin-pronase, the direct proteinase K treatment showed obvious superiority in both glycopeptide recovery and preparation simplicity. Most importantly, it helps to generate greater variety of glycopeptide series with rich information for glycosylation site identification. In addition, binary matrices 5-chloro-2-mercaptobenzothiazole (CMBT) /2,5-dihydroxybenzoic acid (DHB) were found to form homogeneous microcrystal on the target with the purified glycopeptides, leading to improved detection sensitivity. Thus, the present work provides an optimized solution to speed up the characterization of N-linked glycosylation sites in glycoproteins.     

Glycosylation of extracellular superoxide dismutase studied by high-performance liquid chromatography and mass spectrometry

Extracellular superoxide dismutase, EC-SOD, the main superoxide dismutase in biological fluids, is known from its lectin binding to be a glycoprotein. We have characterized the glycosylation of recombinant EC-SOD. A tryptic digest of the protein contained only one glycosylated peptide. This peptide was specifically bound to lectins and stained by periodic acid-Schiff stain. Although appearing very large on size-exclusion chromatography, it was shown to be glycosylated at only one site, asparagine-89, by specific cleavage with glycanases followed by mass spectrometry of the resulting peptide. Based on the binding properties of the peptide to concanavalin A and lentil lectin and the elution profile of N-glycanase-treated glycopeptide on ion-exchange chromatography, the carbohydrate appears to be the complex biantennary type with a core fucose.     

Syntheses,Conformations and X-Ray Structure Analyses of the Saccharide Chains from the Core Regions of Glycoproteins

The covalently bound carbohydrate moiety in glycoproteins can stabilize the protein molecule intramolecularly, or it may have an intermolecular function as receptor in biological recognition. The discovery of these biological phenomena has led to a renaissance of the chemistry and biochemistry of carbohydrates. Both N-glycoproteins as well as O-glycoproteins contain special, invariant oligosaccharide chains in the protein-binding region, which occur again in all glycoproteins, and are described as the “core regions.” This review describes the various methods of oligosaccharide synthesis that may be used to arrive at the basic core structures by chemical means. Methods of oligosaccharide synthesis have improved so much that it is possible to synthesize complex lactosamine-type structures, and “bisected”-type structures up to nona- and undecasaccharides respectively. Oligosaccharide chains are considerably less flexible than peptide chains. Using modern methods of NMR spectroscopy, their preferred solution conformation can readily be determined. In the case of one branched octasaccharide, a comparison of the conformations in solution and in the crystal is possible. Oligosaccharides may be linked to the amide group of an asparagine, or to the hydroxyl groups of serine or threonine. By using suitable protecting groups, the glycosyl amino acids obtained can be extended with further amino acids at the N- or C-terminus, thus arriving at the desired glycopeptide sequences. In the linkage region, glycopeptides prefer certain conformations. Future research into glycoprotein functions may involve the synthesis and biochemical study of modified glycoprotein segments.     

Ultrasmall gold nanoparticles for highly specific isolation/enrichment of N-linked glycosylated peptides

In recent years, gold nanoparticles have been increasingly utilized as a promising material for biomedical analysis. We report here for the first time the synthesis of ultrasmall gold nanoparticles with core diameter of 1.2 nm functionalized with hydrazide groups and their use in isolation/enrichment of N-glycosylated peptides. Hydrazide-functionalized gold nanoparticles showed excellent stability in biological samples and exhibited a large capacity for peptide capturing. The captured peptides from tested standard glycoproteins were found to be highly specific as determined by Agilent HPLC chip and quadrupole time-of-flight (Q-TOF) mass spectrometer. The hydrazide-functionalized gold nanoparticles were successfully utilized in the isolation of a real proteome complex, which showed that more than 90% of captured product was glycopeptide. These results demonstrate that the ultrasmall gold nanoparticles can be used for a high-throughput analysis platform of glycoproteins.     

重组含糖识别结构域的人源半乳糖凝集素-3在糖蛋白/糖肽富集中的应用

植物凝集素是广泛使用的糖蛋白富集和识别材料,动物凝集素则较少被尝试用于糖蛋白富集。基于人源半乳糖凝集素-3的糖识别结构域（CRD）,设计了两种重组凝集素：Gal3C （一个CRD）和Tetra-Gal3C （四重串联CRD）。通过将两种凝集素固定于链霉亲和素琼脂糖小球上,构造了富集糖蛋白的重组凝集素亲和柱。使用凝胶电泳、免疫印迹以及生物质谱技术对重组凝集素的生物特征及其糖蛋白富集能力进行了表征与评价,发现两种类型的重组凝集素对糖蛋白/糖肽都有良好的富集效果,并具有较高的特异性和灵敏度。相对于Gal3C而言,Tetra-Gal3C由于具有四重串联的CRD结构域,表现出更高的糖蛋白/糖肽富集能力。该凝集素亲和柱成功用于人肝癌细胞系HepG2的糖蛋白富集,表明重组凝集素具有从复杂生物样本中选择性识别和富集糖蛋白/糖肽的能力。     

Glycopeptide and Oligosaccharide Libraries

Despite the burgeoning interest in the various biological functions and consequent therapeutic potential of the vast number of oligosaccharides found in nature on glycoproteins and cell surfaces, the development of combinatorial carbohydrate chemistry has not progressed as rapidly as expected. The reason for this imbalance is rooted in the difficulty of oligosaccharide assembly and analysis that renders synthesis a rather cumbersome endeavor. Parallel approaches that generate series of analogous compounds rather than real libraries have therefore typically been used. Since generally low affinity is obtained for interactions between carbohydrate receptors and modified oligosaccharides designed as mimetics of natural carbohydrate ligands, glycopeptides have been explored as alternative mimics. Glycopeptides have been proven in many cases to be superior ligands with higher affinity for a receptor than the natural carbohydrate ligand. High-affinity glycopeptide ligands have been found for several types of receptors including the E-, P-, and L-selectins, toxins, glycohydrolases, bacterial adhesins, and the mannose-6-phosphate receptor. Furthermore, the assembly of glycopeptides is considerably more facile than that of oligosaccharides and the process can be adapted to combinatorial synthesis with either glycosylated amino acid building blocks or by direct glycosylation of peptide templates. The application of the split and combine approach using ladder synthesis has allowed the generation of very large numbers of compounds which could be analyzed and screened for binding of receptors on solid phase. This powerful technique can be used generally for the identification and analysis of the complex interaction between the carbohydrates and their receptors.     

Synthesis of tumor-associated glycopeptide antigens for the development of tumor-selective vaccines

In contrast to normal cells, the glycoprotein profile on epithelial tumor cells is distinctly altered. Due to an incomplete formation of the glycan side-chains resulting from a premature sialylation, additional peptide epitopes become accessible to the immune system in mucin-type glycoproteins on tumor cells. These tumor-associated structure alterations constitute the basis for a selective immunological attack on cancer cells. For the construction of immunostimulating antigens, glycopeptide partial structures from the mucins MUC1 and MUC4 carrying the tumor-associated sialyl-T(N), alpha2,6-sialyl-T and alpha2,3-sialyl-T antigens have been synthesized. Employing different linkers such as the allylic HYCRON or the fluoride-sensitive PTMSEL anchor, the antigenic glycopeptide structures were constructed on the solid phase utilizing pre-assembled glycosyl amino acid building blocks prepared in solution by convergent chemical or chemoenzymatic strategies. The proliferation of cytotoxic T cells has been induced applying a construct composed of a sialyl-T(N) MUC1-glycopeptide conjugated with a tetanus toxin T cell peptide epitope.     

聚烯丙基氯点击反应接合葡萄糖纳米磁球的制备与糖肽富集

糖蛋白及与蛋白质结合的糖链在生物体内的丰度一般极低,为实现其准确定性及定量,去除高丰度非糖蛋白、非糖肽的干扰,通常需要进行富集前处理操作。该文设计并制备了一种基于点击化学反应和烯丙基氯多功能化位点聚合物的葡萄糖改性核-壳-壳型磁性纳米颗粒,并建立了相应的用于糖肽亲水富集的固相微萃取方法。以人免疫球蛋白G酶解液为样品,共测得32个糖肽信号。该方法检出限可达10 fmol,每克磁性分离介质的富集容量达100 mg。     

Characterization of N-glycans of recombinant human thyrotropin using mass spectrometry

Thyroid-stimulating hormone is a vital component of the regulatory mechanism that maintains the structure and function of the thyroid gland and governs thyroid hormone release. In this paper we report the first detailed structural characterization of the N-linked oligosaccharides of recombinant human thyroid-stimulating hormone (rhTSH). Using a strategy combining mass spectrometric analysis and sequential exoglycosidase digestion, we have defined the structures of the N-glycans released from recombinant human thyrotropin by peptide N-glycosidase F. All glycans are complex-type glycans and are mainly of the bi- and triantennary type with variable degrees of fucosylation and sialylation. The major non-reducing epitope in the complex-type glycans is: NeuAcalpha2-3Galbeta1-4GlcNAc (sialylated LacNAc). The carbohydrate microheterogeneity at the three glycosylation sites was studied using reversed-phase high-performance liquid chromatography (RP-HPLC), concanavalin A affinity chromatography and mass spectrometric techniques, including both matrix-assisted laser desorption/ionization (MALDI) and electrospray. rhTSH was reduced, carboxymethylated and then digested with trypsin. The mixture of peptides and glycopeptides was subjected to RP-HPLC and the structures of the glycopeptides were determined by MALDI in conjunction with on-target exoglycosidase digestions. After PNGase F digestion, the peptide moiety of the glycopeptide was determined by the presence of the b- and y-series ions derived from its amino acid sequence in the quadrupole time-of-flight tandem mass (QTOF-MS/MS) spectrum. Glycosylation sites Asn-alpha52 and Asn-alpha78 contain mainly bi- and triantennary complex-type glycans. Only glycosylation site Asn-alpha52 bears fucosylated N-glycans. Minor tetraantennary complex structures were also observed on both glycosylation sites. Profiling of the carbohydrate moieties of Asn-beta23 indicates a large heterogeneity. Bi-, tri-, and tetraantennary N-glycans were present at this site. These data demonstrate site-specificity of glycosylation in the alpha subunit but not in the beta subunit of rhTSH with Asn-alpha52 bearing essentially di- and triantennary glycans with or without core fucosylation and bi- and triantennary glycans with no core fucosylation being attached to Asn-alpha78.     

Characterization of glycopeptides by combining collision‐induced dissociation and electron‐transfer dissociation mass spectrometry data

Structural characterization of a glycopeptide is not easily attained through collision‐induced dissociation (CID), due to the extensive fragmentation of glycan moieties and minimal fragmentation of peptide backbones. In this study, we have exploited the potential of electron‐transfer dissociation (ETD) as a complementary approach for peptide fragmentation. Model glycoproteins, including ribonuclease B, fetuin, horseradish peroxidase, and haptoglobin, were used here. In ETD, radical anions transfer an electron to the peptide backbone and induce cleavage of the N–Cα bond. The glycan moiety is retained on the peptide backbone, being largely unaffected by the ETD process. Accordingly, ETD allows not only the identification of the amino acid sequence of a glycopeptide, but also the unambiguous assignment of its glycosylation site. When data acquired from both fragmentation techniques are combined, it is possible to characterize comprehensively the entire glycopeptide. This is being achieved with a mass spectrometer capable of alternating between CID and ETD on‐the‐fly during an LC/MS/MS analysis. This is demonstrated here with several tryptic glycopeptides. Copyright © 2008 John Wiley & Sons, Ltd.     

Biological surfactants stabilizing natural microbubbles in aqueous media

Recent experimental work, using carbohydrate (agarose) gels derived from marine algae, has provided much evidence that largely hydrophobic surfactants surround and stabilize the long-lived gas microbubbles present in such aqueous gels. Later work involving three different types of protein-specific chemical tests further revealed that these biological surfactants, which were also found to be present (in much higher concentrations) in forest soils, are proteinaceous compounds whose surface activity depend upon aromatic amino acid residues. These proteinaceous surfactants have now been successfully isolated from both agarose and aqueous soil extracts and found to-have extremely similar total amino acid compositions. Electrophoresis showed that the microbubble surfactants from both natural sources migrated as a single (but somewhat diffuse) band with or without sulfhydryl-reducing reagent present, and the same apparent molecular weight (< 6,000 daltons), were stained by both peptide- and carbohydrate- specific reagents and, in effect, were essentially indistinguishable. Further electrophoresis experiments, involving enzymatic degradation of the isolated microbubble glycopeptide surfactant, verified the present of covalently bound carbohydrate in the microbubble surfactant. Thereafter, the glycopeptide surfactant was dansylated and chromatographed on Sephadex G-25 and LH-20 columns and, thereby, separated into five major fractions; it was calculated that the $\text{average}$ molecular weight of the microbubble glycopeptide surfactant (as a whole) was very close to 4,000 daltons. Moreover, the same dansyl NH₂-terminal amino acid, specifically alanine, was identified for all five major fractions. It is concluded that microbubble glycopeptide surfactant actually represents a small distribution of structurally similar surface-active glycopeptides, rather than a single molecular species. In addition, a selected review of the biochemical and natural-product organochemical literature further suggests that the microbubble surfactant is essentially a partial degradation product of larger, precursor glycoproteins, which are probably of biological exudate origin and are widely distributed in the environment.     

Glycopeptide analysis by matrix-assisted laser desorption/ionization tandem time-of-flight mass spectrometry reveals novel features of horseradish peroxidase glycosylation

We explored matrix-assisted laser desorption/ionization (MALDI) tandem time-of-flight (TOF/TOF) mass spectrometry for the analysis of N-glycosylated peptides, using horseradish peroxidase (HRP) as a test case. Two different types of cleavage were observed in the TOF/TOF fragmentation spectra: Firstly, cleavages of peptide bonds yielded fragments with the attached N-glycans staying intact, thus revealing information on peptide sequence and glycan attachment site. Secondly, fragmentation of the glycan moiety was characterized by cleavage of glycosidic bonds as well as a (0,2)X-ring fragmentation of the innermost N-acetylglucosamine of the chitobiose core. Loss of the complete N-glycan moiety occurred by cleavage of both the N-glycosidic bond and the side-chain amide group of the N-glycosylated asparagine, yielding a characteristic peak doublet with a mass difference of 17 Da, which revealed the individual masses of the N-glycan and the peptide moiety. Analysis of a HRP tryptic digest at the sub-picomole level allowed the characterization of various N-glycosylated peptides including those with internal disulfide linkages, a glycopeptide linked via a disulfide bond to another peptide, and a 5 kDa glycopeptide carrying two N-glycans. The potential of our approach was illustrated by the detection of the following novel features of HRP glycosylation: (i) The conjugation of a xylosylated trimannosyl N-glycan without core-fucosylation to site Asn316, showing for the first time unambiguously the occupation of this site; and (ii) A disaccharide N-acetylhexosamine1deoxyhexose1 attached to N-glycosylation sites Asn285 and Asn298, which might represent a Fuc(alpha1-3)GlcNAc- moiety arising from the processing of N-glycans by a horse-radish endoglycosidase during biosynthesis of HRP.     

Chemoselective elaboration of O-linked glycopeptide mimetics by alkylation of 3-thioGalNAc.

A critical branch point in mucin-type oligosaccharides is the beta 1-->3 glycosidic linkage to the core alpha-N-acetylgalactosamine (GalNAc) residue. We report here a strategy for the synthesis of O-linked glycopeptide analogues that replaces this linkage with a thioether amenable to construction by chemoselective ligation. The key building block was a 2-azido-3-thiogalactose-Thr analogue that was incorporated into a peptide by fluorenylmethoxycarbonyl (Fmoc)-based solid-phase peptide synthesis. Higher order oligosaccharides were readily generated by alkylation of the corresponding 3-thioGalNAc with N-bromoacetamido sugars. The rapid assembly of "core 1"and "core 3" O-linked glycopeptide mimetics was accomplished in this fashion.     

Sugar-assisted glycopeptide ligation

The chemical synthesis of glycopeptides and glycoproteins from readily available materials presents an attractive route to homogeneous products for structural and functional studies. Chemical synthesis of glycopeptides and glycoproteins based on native chemical ligation represents one of the useful methods for the synthesis of natural glycopeptide structures. Here we describe a method that allows for the synthesis of glycopeptides from cysteine-free peptides. This method utilizes a peptide thioester and a glycopeptide in which the sugar moiety is modified with a thiol handle at the C-2 position. Upon completion of the ligation reaction, the thiol handle can be reduced with H2/metal to the acetamide moiety, furnishing the unmodified glycopeptides. Together, this sequence of reactions displays an attractive potential in glycopeptides and glycoproteins synthesis.