岡本 亮

A bioinspired semisynthesis of human‐interleukin‐6 bearing N‐glycan at Asn143 (143glycosyl‐IL‐6) was performed by intentional glycosylation effects and protein folding chemistry for regioselective peptide‐backbone activation. 143Glycosyl‐IL‐6 is a genetically coded cytokine, but isolation was difficult owing to a tiny amount. IL6‐polypeptide (1‐141‐position) with an intentionally inserted cysteine at 142‐position was expressed in E. coli. The expressed polypeptide was treated with a chemical folding process to make a specific helices bundle conformation through native two‐disulfide bonds (43–49 and 72–82). Utilizing the successfully formed free‐142‐cysteine, sequential conversions using cyanation of 142‐cysteine, hydrazinolysis, and thioesterification created a long polypeptide (1–141)‐thioester. However, the resultant polypeptide‐thioester caused considerable aggregation owing to a highly hydrophobic peptide sequence. After the reduction of two‐disulfide bonds of polypeptide (1–141)‐thioester, an unprecedented hydrophilic N‐glycan tag was inserted at the resultant cysteine thiols. The N‐glycan tags greatly stabilized polypeptide‐thioester. The subsequent native chemical ligation and desulfurization successfully gave a whole 143glycosyl‐IL‐6 polypeptide (183‐amino acids). Removal of four N‐glycan tags and immediate one‐pot in vitro folding protocol efficiently produced the folded 143glycosyl‐IL‐6. The folded 143glycosyl‐IL‐6 exhibited potent cell proliferation activity. The combined studies with molecular dynamics simulation, semisynthesis, and bioassays predict the bioactive conformation of latent 143glycosyl‐IL‐6.

Protein ubiquitination is involved in nearly all biological processes in Eukaryotes. To gain precise insights into the function of ubiquitination in these processes, researchers frequently employ ubiquitinated protein probes with well-defined structures. While chemical protein synthesis has afforded a variety of ubiquitinated protein probes, there remains a demand for efficient synthesis methods for complex probes, such as ubiquitinated glycoproteins and ubiquitinated cysteine-containing proteins. In this study, we introduce a new method to obtain ubiquitinated proteins through isopeptide bond formation mediated by δ-selenolysine residues. We synthesized δ-selenolysine derivatives in both L- and D-forms starting from DL-δ-hydroxy-DL-lysine, accomplished by substituting the δ-mesylate with KSeCN and by enzymatic optical resolution with L- and D-aminoacylase. We synthesized ubiquitin (46–76)-α-hydrazide with a δ-seleno-L-lysine residue at position 48, as well as ubiquitin (46–76)-α-thioester, using solid-phase peptide synthesis. Subsequently, the δ-selenolysine-mediated ligation of these peptides, followed by one-pot deselenization, provided the desired isopeptide-linked ubiquitin peptide. The new δ-selenolysine-mediated isopeptide bond formation offers an alternative method to obtain complex ubiquitin- and ubiquitin-like probes with multiple post-translational modifications. These probes hold promise for advancing our understanding of ubiquitin biology.

To uncover how cells distinguish between misfolded and correctly-folded glycoproteins, homogeneous misfolded glycoproteins are needed as a probe for analysis of their structure and chemical characteristic nature. In this study, we have synthesized misfolded glycosyl interleukin-8 (IL-8) by combining E. coli expression and chemical synthesis to improve the synthetic efficiency. In order to prepare N-terminal peptide-thioester segment (1-33), we prepared an E. coli expressed peptide and then activated the C-terminal Cys by using an intramolecular N-to-S acyl shift reaction, followed by trans-thioesterification of the Cys-thioester with an external bis(2-sulfanylethyl)amine (SEA). The glycopeptide segment (34-49) was prepared by solid phase peptide synthesis and the C-terminal peptide (50-72) was prepared in E. coli. These peptide and glycopeptide segments were successfully coupled by sequential native chemical ligation. To obtain homogeneous misfolded glycoproteins by shuffling the disulfide bond pattern, folding conditions were optimized to maximize the yield of individual homogeneous misfolded glycoproteins.

Serine protease inhibitor Kazal type 13 (SPINK13) is a secreted protein that has been recently studied as a therapeutic drug and an interesting biomarker for cancer cells. Although SPINK13 has a consensus sequence (Pro-Asn-Val-Thr) for N-glycosylation, the existence of N-glycosylation and its functions are still unclear. In addition to this, the preparation of glycosylated SPINK 13 has not been examined by both the cell expression method and chemical synthesis. Herein we report the chemical synthesis of the scarce N-glycosylated form of SPINK13 by a rapid synthetic method combined with the chemical glycan insertion strategy and a fast-flow SPPS method. Glycosylated asparagine thioacid was designed to chemoselectively be inserted between two peptide segments where is the sterically bulky Pro-Asn(N-glycan)-Val junction by two coupling reactions which consist of diacyl disulfide coupling (DDC) and thioacid capture ligation (TCL). This insertion strategy successfully afforded the full-length polypeptide of SPINK13 within two steps from glycosylated asparagine thioacid. Because the two peptides used for this synthesis were prepared by a fast-flow SPPS, the total synthetic time of glycoprotein was considerably shortened. This synthetic concept enables us to repetitively synthesize a target glycoprotein easily. Folding experiments afforded well-folded structure confirmed by CD and disulfide bond map. Invasion assays of glycosylated SPINK13 and non-glycosylated SPINK13 with pancreatic cancer cells showed that non-glycosylated SPINK-13 was more potent than that of glycosylated SPINK13.

Antifreeze glycoprotein (AFGP), which inhibits the freezing of water, is highly O-glycosylated with a disaccharide, d-Galβ1-3-d-GalNAcα (GalGalNAc). To elucidate the function of the sugar residues for antifreeze activity at the molecular level, we conducted a total chemical synthesis of partially sugar deleted AFGP derivatives, and unnatural forms of AFGPs incorporating glucose (Glc)-type sugars instead of galactose (Gal)-type sugars. These elaborated AFGP derivatives demonstrated that the stereochemistry of each sugar residue on AFGPs precisely correlates with the antifreeze activity. A hydrogen-deuterium exchange experiment using synthetic AFGPs revealed a different dynamic behavior of water around sugar residues depending on the sugar structures. These results indicate that sugar residues on AFGP form a unique dynamic water phase that disturbs the absorbance of water molecules onto the ice surface, thereby inhibiting freezing.

Peptide-aminothiazoline enabled the sequential peptide ligation in one-pot manner and demonstrated convergent synthesis of a circular protein and homogeneous glycoproteins.

N-acetylglucosaminyltransferase-V (GnT-V or MGAT5) catalyzes the formation of an N-glycan β1,6-GlcNAc branch on selective target proteins in the Golgi apparatus and is involved in cancer malignancy and autoimmune disease etiology. Several three-dimensional structures of GnT-V were recently solved, and the recognition mechanism of the oligosaccharide substrate was clarified. However, it is still unclear how GnT-V selectively acts on glycoprotein substrates. In this study, we focused on an uncharacterized domain at the N-terminal side of the luminal region (N domain) of GnT-V, which was previously identified in a crystal structure, and aimed to reveal its role in GnT-V action. Using lectin blotting and fluorescence assisted cell sorting analysis, we found that a GnT-VΔN mutant lacking the N domain showed impaired biosynthetic activity in cells, indicating that the N domain is required for efficient glycosylation. To clarify this mechanism, we measured the in vitro activity of purified GnT-VΔN toward various kinds of substrates (oligosaccharide, glycohexapeptide, and glycoprotein) using HPLC and a UDP-Glo assay. Surprisingly, GnT-VΔN showed substantially reduced activity toward the glycoprotein substrates, whereas it almost fully maintained its activity toward the oligosaccharides and the glycopeptide substrates. Finally, docking models of GnT-V with substrate glycoproteins suggested that the N domain could interact with the substrate polypeptide directly. Our findings suggest that the N domain of GnT-V plays a critical role in the recognition of glycoprotein substrates, providing new insights into the mechanism of substrate-selective biosynthesis of N-glycans.

This paper reports the optimized methods that can accelerate the semisynthesis of homogeneous glycoproteins based on recombinant expression and chemical conversion.

Degradation of misfolded glycoproteins by the ubiquitin-proteasome system (UPS) is a very important process for protein homeostasis. To demonstrate the accessibility toward a ubiquitinated glycoprotein probe for the study of glycoprotein degradation by UPS, we synthesized ubiquitinated glycoprotein CC motif chemokine 1 (CCL1) bearing a high-mannose-type N-glycan, starting from six peptide segments. A native isopeptide linkage was constructed using δ-thiolysine (thioLys)-mediated chemical ligation. CCL1 glycopeptide with a high-mannose-type N-glycan as well as a δ-thioLys residue was synthesized chemically. The chemical ligation between δ-thioLys-containing glycopeptide and ubiquitin-α-thioester successfully yielded a ubiquitinated glycopeptide with a native isopeptide bond after desulfurization, even in the presence of a large N-glycan. In vitro folding experiments under reduced and redox conditions gave the desired two types of ubiquitinated glycosylated CCL1s, consisting of unfolded CCL1 and folded ubiquitin, and the folded form of both CCL1 as well as ubiquitin. We achieved the chemical synthesis of a complex protein molecule that contains not only the two major post-translational modifications, ubiquitination and glycosylation, but also controlled folding states of ubiquitin and CCL1. These chemical probes could have useful applications in the study of complex ubiquitin biology and glycobiology.

The benzylidene acetal group is one of the most important protecting groups not only in carbohydrate chemistry but also in general organic chemistry. In the case of 4,6-O-benzylidene glycosides, we previously found that the stereochemistry at 4-position altered the reaction rate constant for hydrolysis of benzylidene acetal group. However, a detail of the acceleration or deceleration factor was still unclear. In this work, the hydrolysis reaction of benzylidene acetal group was analyzed using the Arrhenius and Eyring plot to obtain individual parameters for glucosides (Glc), mannosides (Man), and galactosides (Gal). The Arrhenius and Eyring plot indicated that the pre-exponential factor (A) and ΔS⧧ were critical for the smallest reaction rate constant of Gal among nonacetylated substrates. On the other hand, both Ea/ΔH⧧ and A/ΔS⧧ were influential for the smallest reaction rate constant of Gal among diacetylated substrates. All parameters obtained suggested that the rate constant for hydrolysis reaction was regulated by protonation and hydration steps along with solvation. The obtained parameters support wide use of benzylidene acetal group as orthogonal protection of cis- and trans-fused bicyclic systems through the fast hydrolysis of the trans-fused benzylidene acetal group.

Glycosylation is an accepted strategy to improve the therapeutic value of peptide and protein drugs. Insulin and its analogues are life-saving drugs for all type I and 30% of type II diabetic patients. However, they can readily form fibrils which is a significant problem especially for their use in insulin pumps. Because of the solubilizing and hydration effects of sugars, it was thought that glycosylation of insulin could inhibit fibril formation and lead to a more stable formulation. Since enzymatic glycosylation results in heterogeneous products, we developed a novel chemical strategy to produce a homogeneous glycoinsulin (disialo-glycoinsulin) in excellent yield (∼60%). It showed a near-native binding affinity for insulin receptors A and B in vitro and high glucose-lowering effects in vivo, irrespective of the route of administration (s.c. vs i.p.). The glycoinsulin retained insulin-like helical structure and exhibited improved stability in human serum. Importantly, our disialo-glycoinsulin analogue does not form fibrils at both high concentration and temperature. Therefore, it is an excellent candidate for clinical use in insulin pumps.

© 2019 The Chemical Society of Japan | 1391 Enzymes and ribosomes accurately form peptide bonds without protecting groups in vivo. Inspired by biological chemistries, we have been exploring a chemoselective reaction for peptide bond formation. In this manuscript, we describe amino thioacid coupling (ATC) that enables peptide bond formation between a peptide-aryl thioester and an amino thioacid. The results suggest that ATC proceeds through the formation of a thioanhydride intermediate afforded by a chemoselective thioacid-thioester exchange reaction.

Poly-N-acetyllactosamine (poly-LacNAc) structures on glycoproteins play important roles in essential biological events such as cell-cell adhesion. Here, we report a new strategy for the semisynthesis of LacNAc-extended complex-type biantennary oligosaccharides. We found an efficient isopropylidenation reaction that selectively protects the terminal Gal-3,4-OH of a biantennary complex-type nonasaccharide isolated from a natural source. This finding enabled the conversion of the nonasaccharide into the two types of oligosaccharides containing di-LacNAc units at one or two antennae via ten-step chemical sequences.

UDP-glucose:glycoprotein glucosyltransferase (UGGT) distinguishes glycoproteins in non-native conformations from those in native conformations and glucosylates from only non-native glycoproteins. To analyze how UGGT recognizes non-native glycoproteins, we chemically synthesized site-specifically N-15-labeled interleukin 8 (IL-8) C-terminal (34-72) glycopeptides bearing a Man(9)GlcNAc(2) (M9) oligosaccharide. Chemical shift perturbation mapping NMR experiments suggested that Phe65 of the glycopeptide specifically interacts with UGGT. To analyze this interaction, we constructed a glycopeptide library by varying Phe65 with 10 other natural amino acids, via parallel native chemical ligation between a glycopeptide-alpha-thioester and a peptide library consisting of 11 peptides. UGGT assay against the glycopeptide library revealed that, although less hydrophobic glycopeptides could be used as substrates for UGGT, hydrophobic glycopeptides are preferred.

Antifreeze glycoprotein (AFGP) is an O-glycoprotein that displays antifreeze activity through depression of the freezing point of water. GalNAc is a core sugar structure of AFGP, and contributes to induce antifreeze activity of this glycoprotein. However, the general functional role that this sugar plays at the molecular level is still unknown. To elucidate this, it is essential to determine the relationship between structure and activity of O-GalNAcylated AFGP using homogeneous glycoproteins. Thus, the total synthesis of homogeneous O-GalNAcylated AFGP was conducted by using a unique peptide derivative: peptidyl- N-pivaloylguanidine. It was found that peptidyl-N-pivaloylguanidine is an "unreactive" peptide in peptide coupling reactions but is interconvertible with a "reactive" peptide-a-thioester by means of a simple treatment under buffer condition at pH=7 to 8. The unique switchable reactivity of peptidyl-N-pivaloylguanidine enabled an efficient sequential peptide coupling strategy. By using this strategy, various lengths of homogeneous O-GalNAcylated AFGP were synthesized, including one that was 120 amino acids in length, with 40 O-GalNAcylation sites. The structural analysis by circular dichroism spectroscopy and evaluation of the antifreeze activity of the synthetic AFGP(GalNAc) s revealed that the simple O-glycosylation with GalNAc is essential for both structural and functional basis of AFGP to exhibit antifreeze activity.

Elucidating the effects of oligosaccharides on glycoprotein properties, such as local conformational changes, stability, and dynamics, has still been challenging. In this paper, a novel partial N-15-labeling method for the amide backbone of a synthetic glycoprotein is proposed. Using solid-phase peptide synthesis (SPPS) and native chemical ligation (NCL), thirteen N-15-labeled amino acids were inserted at specific positions of the protein backbone, while intentionally varying the enrichment of N-15 atoms. This idea discriminated even the same type of amino acid based on the intensities of H-1-N-15 HSQC signals, combined with classic homonuclear TOCSY and NOESY methods, thus allowing for understanding the dynamics of the local conformation of a synthetic homogeneous glycoprotein. Results suggested that the attachment of an oligosaccharide of either a bi-antennary complex-type or a high-mannose-type did not disturb protein conformation. However, T-1 values suggested that the oligosaccharide influenced dynamics at the local conformation. Temperature-varied circular dichroism (CD) spectra and T-1 values clearly indicated that oligosaccharides appeared to inhibit protein fluctuation or, in other words, stabilize protein structure. This insight into oligosaccharide behavior suggests some further effects on binding affinity between a glycoprotein and its receptor.

Chemical or chemoenzymatic synthesis is an emerging approach to produce homogeneous glycoproteins with structurally defined forms. Modern synthetic techniques are capable of the preparation of complex glycoproteins. This minireview especially focuses on the several latest syntheses of N-glycoproteins that generally have relatively large glycan moieties. The structurally defined glycoproteins can be a novel material for understanding molecular basis of glycoprotein functions or the next generation of biopharmaceuticals.

In the modern protocols of chemical protein syntheses, peptide-alpha-thioesters have been used as key components for the assembly of full-length polypeptides through chemoselective peptide coupling reactions. A variety of thioester precursors have been developed for the synthesis of the peptide-alpha-thioesters by Fmoc solid phase peptide synthesis (Fmoc-SPPS). Recently our group found a peptidyl-N-acetylguanidine as a new peptide-alpha-thioester precursor. This peptide derivative can be converted into a corresponding peptide-alpha-thioester only by treatment with an excess amount of a thiol in aqueous buffers at around neutral pH. This unique property allowed us to envision the practical use of the peptidyl-N-acetylguanidines for the chemical syntheses of proteins; however, an efficient synthetic method has been lacking. Herein, we report an efficient solid-phase synthesis of peptidyl-N-acetylguanidines. This new synthetic method employing selective activation and cleavage of a peptide bond successfully provided peptidyl-N-acetylguanidines from the on-resin protected peptides prepared by standard Fmoc-SPPS. We also evaluated the reactivity of a peptidyl-N-acetylguanidine in native chemical ligation through the synthesis of glucose-dependent insulinotropic polypeptide analogue. Copyright (C) 2016 European Peptide Society and John Wiley & Sons, Ltd.

Glycoproteins in non-native conformations are often toxic to cells and may cause diseases, thus the quality control (QC) system eliminates these unwanted species. Lectin chaperone calreticulin and glucosidaseII, both of which recognize the Glc(1)Man(9) oligosaccharide on glycoproteins, are important components of the glycoprotein QC system. Reported herein is the preparation of Glc(1)Man(9)-glycoproteins in both native and non-native conformations by using the following sequence: misfolding of chemically synthesized Man(9)-glycoprotein, enzymatic glucosylation, and another misfolding step. By using synthetic glycoprotein probes, calreticulin was found to bind preferentially to a hydrophobic non-native glycoprotein whereas glucosidaseII activity was not affected by glycoprotein conformation. The results demonstrate the ability of chemical synthesis to deliver homogeneous glycoproteins in several non-native conformations for probing the glycoprotein QC system.

Attachment of oligosaccharides to proteins is a major post-translational modification. Chemical syntheses of oligosaccharides have contributed to clarifying the functions of these oligosaccharides. However, syntheses of oligosaccharide-linked proteins are still challenging because of their inherent complicated structures, including diverse di- to tetra-antennary forms. We report a highly efficient strategy to access the representative two types of triantennary oligosaccharides through only 9 or 10-step chemical conversions from a biantennary oligosaccharide, which can be isolated in exceptionally homogeneous form from egg yolk. Four benzylidene acetals were successfully introduced to the terminal two galactosides and two core mannosides of the biantennary asialononasaccharide bearing 24 hydroxy groups, followed by protection of the remaining hydroxy groups with acetyl groups. Selective removal of one of the benzylidene acetals gave two types of suitably protected glycosyl acceptors. Glycosylation toward the individual acceptors with protected Gal-beta-1,4-GlcN thioglycoside and subsequent deprotection steps successfully yielded two types of complex-type triantennary oligosaccharides.

The role of sialyloligosaccharides on the surface of secreted glycoproteins is still unclear because of the difficulty in the preparation of sialylglycoproteins in a homogeneous form.We selected erythropoietin (EPO) as a targetmolecule and designed an efficient synthetic strategy for the chemical synthesis of a homogeneous form of five EPO glycoforms varying in glycosylation position and the number of human-type biantennary sialyloligosaccharides. A segment coupling strategy performed by native chemical ligation using six peptide segments including glycopeptides yielded homogeneous EPO glycopeptides, and folding experiments of these glycopeptides afforded the correctly folded EPO glycoforms. In an in vivo erythropoiesis assay in mice, all of the EPO glycoforms displayed biological activity, in particular the EPO bearing three sialyloligosaccharides, which exhibited the highest activity. Furthermore, we observed that the hydrophilicity and biological activity of the EPO glycoforms varied depending on the glycosylation pattern. This knowledge will pave the way for the development of homogeneous biologics by chemical synthesis.

Glycoprotein quality control processes are very important for an efficient production of glycoproteins and for avoiding the accumulation of unwanted toxic species in cells. These complex processes consist of multiple enzymes and chaperones such as UGGT, calnexin/calreticulin, and glucosidase II. We designed and synthesized monomeric and dimeric misfolded glycoprotein probes. Synthetic homogeneous monomeric glycoproteins proved to be useful substrates for kinetic analyses of the folding sensor enzyme UGGT. For a concise synthesis of a bismaleimide-linked dimer, we examined double native chemical ligation (dNCL) of a dimeric peptide-alpha-thioester. The dNCL to two equivalents of glycopeptides gave a homodimer. The dNCL to a 1 : 1 mixture of a glycopeptide and a non-glycosylated peptide gave all the three possible ligation products consisting of two homodimers and a heterodimer. Both the homodimer bearing two Man(9)GlcNAc(2) (M9) oligosaccharides and the heterodimer bearing one M9 oligosaccharide were found to be good substrates of UGGT.

Amino acids bearing a thiol group at the beta-position are useful for native chemical ligation. Phenylalanine and tyrosine derivatives bearing a thiol group at the beta-position were synthesized. Racemic phenylalanine and tyrosine were selected as starting materials and were introduced a bromo atom at the beta-position by photoreaction. Subsequent substitution reaction of the bromo atom with p-methoxybenzylmercaptan yielded the corresponding amino acids bearing a thiol group at the beta-position. Enzymatic optical resolution using L-aminoacylase and subsequent chemical conversion gave the corresponding optically pure L- and D-phenylalanine and tyrosine derivatives bearing a thiol group at the beta-position. (C) 2015 Elsevier Ltd. All rights reserved.

Racemic protein crystallography is an emerging methodology to obtain high- resolution protein structures. Preparation of both a mirror image of protein and a mirror image of glycan is essential to apply the new methodology to glycoprotein. This article describes an efficient synthesis of L- galactose that is amirror image of D- galactose. The developed method takes only 6 steps from D- galactose without any chromatographic purification.

As a basis for the development of an artificial carbohydrate-binding lectin, we chemically synthesized a domain of siglec-7, a well-characterized sialic-acid-binding lectin. The full polypeptide (127 amino acids) was constructed by sequential native chemical ligation (NCL) of five peptide segments. Because of poor cysteine availability for NCL, cysteine residues were introduced at suitable ligation sites; these cysteine residues were alkylated in order to mimic native glutamine or asparagine residues, or converted to an alanine residue by desulfurization after NCL. After folding the full-length polypeptide, the sialic-acid-binding activity of the synthetic siglec-7 was clearly demonstrated by STD NMR and ELISA experiments. We succeeded in the synthesis of siglec-7 by installing three extra cysteine residues with side-chain modifications and found that these modifications did not affect the binding activity.

Chemical or chemoenzymatic synthesis is an emerging approach to produce homogeneous glycoproteins, which are hard to obtain by conventional biotechnology methods. Recent advances in the synthetic methodologies for the decoration of protein molecules with oligosaccharides provide several remarkable syntheses of homogeneous glycoproteins. This short review highlights several of the latest syntheses of glycoproteins including therapeutically important glycoproteins, a highly glycosylated protein, and unnatural glycoproteins in order to illustrate the power of the modern glycoprotein synthesis. Structurally defined glycoproteins are a novel material for understanding the molecular basis of glycoprotein functions and for the development of the next generation of biopharmaceuticals.

Herein, we describe a new semisynthetic strategy of a post-translationally modified protein in which the middle region is glycosylated. We designed a single-plasmid coding for a fusion polypeptide, which can provide both an N-terminal -thioester and a C-terminal cysteine peptide of a target glycoprotein by using chemical-cleavage and activation methods. The use of these resultant peptide derivatives resulted in the successful synthesis of N-glycosylated-interleukin13.

Our goal was to obtain the X-ray crystal structure of the glycosylated chemokine Ser-CCL1. Glycoproteins can be hard to crystallize because of the heterogeneity of the oligosaccharide (glycan) moiety. We used glycosylated Ser-CCL1 that had been prepared by total chemical synthesis as a homogeneous compound containing an N-linked asialo biantennary nonasaccharide glycan moiety of defined covalent structure. Facile crystal formation occurred from a quasi-racemic mixture consisting of glycosylated L-protein and non-glycosylated-D-protein, while no crystals were obtained from the glycosylated L-protein alone. The structure was solved at a resolution of 2.6-2.1 angstrom. However, the glycan moiety was disordered: only the N-linked GlcNAc sugar was well-defined in the electron density map. A racemic mixture of the protein enantiomers L-Ser-CCL1 and D-Ser-CCL1 was also crystallized, and the structure of the true racemate was solved at a resolution of 2.7-2.15 angstrom. Superimposition of the structures of the protein moieties of L-Ser-CCL1 and glycosylated-L-Ser-CCL1 revealed there was no significant alteration of the protein structure by N-glycosylation.

CCL1 is a naturally glycosylated chemokine protein that is secreted by activated T-cells and acts as a chemoattractant for monocytes.1 Originally, CCL1 was identified as a 73 amino acid protein having one N-glycosylation site,1 and a variant 74 residue non-glycosylated form, Ser-CCL1, has also been described.2 There are no systematic studies of the effect of glycosylation on the biological activities of either CCL1 or Ser-CCL1. Here we report the total chemical syntheses of both N-glycosylated and non-glycosylated forms of (Ser-)CCL1, by convergent native chemical ligation. We used an N-glycan isolated from hen egg yolk together with the Nbz linker for Fmoc chemistry solid phase synthesis of the glycopeptide-thioester building block.3 Chemotaxis assays of these glycoproteins and the corresponding non-glycosylated proteins were carried out. The results were correlated with the chemical structures of the (glyco)protein molecules. To the best of our knowledge, these are the first investigations of the effect of glycosylation on the chemotactic activity of the chemokine (Ser-)CCL1 using homogeneous N-glycosylated protein molecules of defined covalent structure.

The N-glycosylation of proteins is generated at the consensus sequence NXS/T (where X is any amino acid except proline) by the biosynthetic process, and occurs in the endoplasmic reticulum and Golgi apparatus. In order to investigate the influence of human complex-type oligosaccharides on counterpart protein conformation, crambin and ovomucoide, which consist of 46 and 56 amino acid residues, respectively, were selected for synthesis of model glycoproteins. These small glycoproteins were intentionally designed to be glycosylated at the a-helix (crambin: 8 position), beta-sheet (crambin: 2 position) and loop position between the antiparallel beta-sheets (ovomucoide: 28 position), and were synthesized by using a peptide-segment coupling strategy. After preparation of these glycosylated polypeptide chains, protein folding experiments were performed under redox conditions by using cysteinecystine. Although the small glycoproteins bearing intentional glycosylation at the a-helix and beta-sheet exhibited a suitable folding process, glycosylation at the loop position between the antiparallel beta-strands caused multiple products. The conformational differences in the isolated homogeneous glycoproteins compared with non-glycosylated counterparts were evaluated by circular dichroism (CD) and NMR spectroscopy. These analyses suggested that this intentional N-glycosylation did not result in large conformational changes in the purified protein structures, including the case of glycosylation at the loop position between the antiparallel beta-strands. In addition to these experiments, the conformational properties of three glycoproteins were evaluated by CD spectroscopy under different temperatures. The oligosaccharides on the protein surface fluctuated considerably; this was dependent on the increase in the solution temperature and was thought to disrupt the protein tertiary structure. Based on the measurement of the CD spectra, however, the glycoproteins bearing three disulfide bonds did not exhibit any change in their protein tertiary structure. These results suggest that the oligosaccharide conformational fluctuations were not disruptive to protein tertiary structure, and the tertiary structure of glycoproteins might be stabilized by the disulfide bond network.

Protein glycosylation is a major post-translational modification. To elucidate the effect of this modification on protein function, homogeneous glycoproteins are required. Because glycoproteins isolated from biological sources contain glycoforms, a mixture of a single protein chain with several different oligosaccharides appended, homogeneous glycoproteins obtained through chemical synthesis offer a better solution. In this review, several methods used by our group for the chemical synthesis of homogeneous glycoproteins are addressed. First, preparation of sufficient amounts of oligosaccharides with the desired structures was achieved using a combination of chemical protection and enzymatic digestion. Then glycopeptide-athioesters were prepared by incorporation of oligosaccharides onto the side chains of cysteine residues in peptide-athioesters. Finally, biologically active homogeneous glycoproteins were prepared through native chemical ligation of glycopeptide-athioesters and subsequent oxidative folding.

Sialyloligosaccharides are synthesised by various glycosyltransferases and sugar nucleotides. All of these nucleotides are diphosphate compounds except for cytidine-5'-monophosphosialic acid (CMP-Neu5Ac). To obtain an insight into why cytidine-5'-diphosphosialic acid (CDP-Neu5Ac) has not been used for the sialyltransferase reaction and why it is not found in biological organisms, the compound was synthesised. This synthesis provided the interesting finding that the carboxylic acid moiety of the sialic acid attacks the attached phosphate group. This interaction yields an activated anhydride between carboxylic acid and the phosphate group and leads to hydrolysis of the pyrophosphate linkage. The mechanism was demonstrated by stable isotope-labelling experiments. This finding suggested that CMP-Neu5Ac might also form the corresponding anhydride structure between carboxylic acid and phosphate, and this seems to be the reason why CMP-Neu5Ac is acid labile in relation to other sugar nucleotides. To confirm the role of the carboxylic acid, CMP-Neu5Ac derivatives in which the carboxylic acid moiety in the sialic acid was substituted with amide or ester groups were synthesised. These analogues clearly exhibited resistance to acid hydrolysis. This result indicated that the carboxylic acid of Neu5Ac is associated with its stability in solution. This finding also enabled the development of a novel chemical synthetic method for CMP-Neu5Ac and CMP-sialic acid derivatives.

Glycoprotein is one of the important biopolymer in a biological system. In order to understand the complex correlation between the exact oligosaccharide structure of the glycoprotein and its function, preparation of homogeneous glycoprotein is to be essential. For such a purpose, chemical synthesis is one of the most promising methods to obtain homogeneous glycoproteins. Glycopolypeptide, which is a backbone of glycoprotein and an essential intermediate for glycoprotein synthesis, can be obtained through coupling of peptide and glycopeptide segments because straightforward synthesis of such a long glycopolypeptide is still a challenging task. Native chemical ligation (NCL) is one of the powerful methods for the coupling reaction of peptides, however, despite extensive investigation, NCL has site limitation for the coupling. In this context, we discovered NCL at serine site, where is a highly conserved amino acid residue in glycoproteins. This reaction strategy is owed to conversion reaction of cysteine residue to serine residue after conventional NCL. This conversion reaction is consisted of three steps; S-methylation of cysteine, CNBr reaction to afford O-ester linked peptide, and O to N acyl shift to get native peptide linkage with serine residue. During extensive investigation of the strategy, we found new reaction media for CNBr reaction, which is the key reaction in the strategy. This enabled us to synthesize not only N-linked glycopeptides but also O-linked sialyl glycopeptides. Thus we could demonstrate the usefulness of this new glycopeptide ligation strategy. In this short review, we will introduce our newly developed cysteine to serine conversion reaction which will expand the application of NCL in peptide as well as glycopeptide synthesis.