A novel GlcNAc-Asn unit carrying trifluoroacetic acid (TFA)-sensitive O-protecting groups was prepared. The unit was used for the solid-phase peptide synthesis (SPPS) of the N-acetylglucosaminylated emmprin (35–69) thioester via one-step deprotection by TFA combined with the N-alkylcysteine thioesterification method. This segment was used for the synthesis of the first Ig domain (22–104) of emmprin carrying GlcNAc by one-pot ligation with other segments using the thioester method. Finally, the sugar chain was elongated by transglycosylation using glycosynthase to give the Ig domain carrying the disialo- and asialo-complex-type sugar chain.

One of the condensation methods for the preparation of long-chain peptides, the so-called thioester method requires protecting groups for amino and thiol groups for regioselective ligation. In this study, we demonstrated that the phenacyl (Pac) group acts as an efficient protecting group of cysteine side chains. We synthesized a cysteine derivative carrying the Pac group at the side chain sulfur atom, and Pac-containing peptides and peptide thioesters were synthesized using it by the ordinary 9-fluorenylmethoxycarbonyl (Fmoc)-based solid-phase peptide synthesis strategy. Pac-containing peptide segments could be condensed by the thioester method. After the condensation reaction, Pac groups could be removed by Zn/AcOH treatment. In addition, the azido group, which was used for the protection of lysine side chains, was simultaneously converted into an amino group, demonstrating that this protecting group scheme simplified the deprotecting reaction after the peptide condensation reaction to a single step.

The complex-type N-linked octasaccharide oxazoline having LacNAc as the nonreducing end sugar was efficiently synthesized using the benzyl-protected LacNAc, mannose, and β-mannosyl GlcNAc units as key building blocks. To achieve a highly β-selective glycosylation with the LacNAc unit, the N-trichloroacetyl group was used for the protection of the amino group in the LacNAc unit. After complete assembly of these units and deprotection, the obtained free sugar was successfully derivatized into the corresponding sugar oxazoline. On the other hand, the N-acetylglucosaminylated saposin C, a hydrophobic lipid-binding protein, was chemically synthesized by the native chemical ligation reaction. On the basis of the previous results related to the synthesis of the nonglycosylated saposin C, the O-acyl isopeptide structure was introduced to the N-terminal peptide thioester carrying GlcNAc to improve its solubility toward aqueous organic solvents. The ligation reaction efficiently proceeded with the simultaneous O- to N-acyl shift at the O-acyl isopeptide moiety. After the removal of the cysteine-protecting group and folding, saposin C carrying GlcNAc was successfully obtained. The synthetic sugar oxazoline was then transferred to this glycoprotein using the mutant of endo-β-N-acetylglucosaminidase from Mucor hiemalis (Endo-M) (glycosynthase), and the saposin C carrying the complex-type nonasaccharide was successfully obtained.

In the so-called thioester method for the condensation of peptide segments, protecting groups for amino and thiol groups are required for chemoselective ligation. In this study, we developed a novel thiol protecting group, N-methyl-phenacyloxycarbamidomethyl (Pocam). We used it for protection of cysteine side chains, and synthesized Pocam-containing peptides and peptide thioesters. These were condensed by the thioester method. After the condensation reaction, Pocam groups were cleaved by Zn/AcOH treatment. At the same time, the azido group, which was used for the protection of lysine side chains, was also converted to an amino group, demonstrating that this protecting group strategy simplified the deprotecting reaction after the peptide condensation reaction to only one step.

The synthesis of Fmoc-aminoacyl-N-ethyl-S-triphenylmethylcysteine, an N- to S-acyl migratory device for the preparation of peptide thioesters by Fmoc-SPPS (solid-phase peptide synthesis) is described. Condensation of Fmoc-aminoacyl pentafluorophenyl ester and N-ethyl-S-triphenylmethylcysteine was efficiently performed in the presence of HOOBt (3-hydroxy-3,4-dihydro-4-oxo-1,2,3-benzotriazine) in DMF. A small amount of diastereomer yielded during the reaction was easily separated by HPLC purification and the highly pure devices were obtained for most of the proteinogenic amino acids.

In order to achieve an efficient synthesis of highly hydrophobic proteins by the native chemical ligation (NCL) reaction, we examined to incorporate the O-acyl isopeptide method, which is known to improve the solubility of the segment, to the NCL reaction: a peptide thioester having O-acyl isopeptide structures is prepared by the Boc mode solid-phase method using an azido group as a protecting group for the isopeptide site, and then ligated with C-terminal segment with an in situ reduction of the azido group followed by an O- to N-acyl shift. This method was successfully applied to the synthesis of the sphingolipid activator protein, saposin C.Saposin C was prepared by the NCL using the peptide thioester having azido-protected O-acyl isopeptide structure.

The biantennary complex-type N-glycans bearing LacNAc and LacdiNAc as the nonreducing end motif were synthesized in a protected form suitable to use in the Fmoc solid-phase peptide synthesis studies. Two approaches for the nonasaccharide synthesis were examined by taking advantage of the highly β-selective glycosylation with GlcNTCA (N-phenyl)trifluoroacetimidate. An earlier approach, which involved the reaction of the trisaccharide donor (Gal-GlcNTCA-Man) and trisaccharide acceptor (Man-GlcNPhth2-N3), produced a mixture of nonasaccharide isomers. On the other hand, mannosylation of the trisaccharide acceptor (Man-GlcNPhth2-N3) stereoselectively afforded the known pentasaccharide (Man3-GlcNPhth2-N3), which was reacted with the disaccharyl glycosyl donor (Gal-GlcNTCA or GalNTCA-GlcNTCA) to produce the desired nonasaccharide as a single stereoisomer. Selective dephthaloylation followed by N-acetylation furnished the GlcNAc2 functionality. The resulting nonasaccharyl azides were condensed with Fmoc-Asp(OPfp)-OBut or Fmoc-Asp(OPfp)-OPac in the presence of Ph(CH3)2P and HOOBt. Finally, the Zn reduction and cleavage of the tert-butyl ester or Zn reduction alone produced the targeted nonasaccharyl Asn building blocks.

The thioester method is a peptide condensation reaction, which requires the protection of Lys side chains for chemoselective ligation. We recently found that the azido group could be used as an amino protecting group in the peptide condensation by the thioester method. In this study, we synthesized the glycosylated mouse pro-opiomelanocortin (1–74) by the thioester method. The N-terminal peptide thioester segment, whose Lys side chain was protected by an azido group, was prepared using a 9-fluorenylmethoxycarbonyl (Fmoc) strategy and an N-alkylcysteine (NAC)-assisted thioesterification reaction. The C-terminal azido-glycopeptide segment carrying N- and O-linked glycans was also prepared by the Fmoc chemistry and condensed with the N-terminal segment by the silver ion-free thioester method. These results showed that our azido-based strategy was fully compatible with the NAC-assisted method and glycoprotein synthesis.

Androgenic gland hormone (AGH) of the woodlouse, Armadillidium vulgare, is a heterodimeric glycopeptide. In this study, we synthesized AGH with a homogeneous N-linked glycan using the expressed protein ligation method. Unexpectedly, disulfide bridge arrangement of a semisynthetic peptide differed from that of a recombinant peptide prepared in a baculovirus expression system, and the semisynthetic peptide showed no biological activity in vivo. To confirm that the loss of biological activity resulted from disulfide bond isomerization, AGH with a GlcNAc moiety was chemically synthesized by the selective disulfide formation. This synthetic AGH showed biological activity in vivo. These results indicate that the native conformation of AGH is not the most thermodynamically stable form, and correct disulfide linkages are important for conferring AGH activity.

Aryl thioesters of peptide segments were prepared by the conventional 9-fluorenylmethoxycarbonyl (Fmoc) strategy using a novel N-alkyl cysteine (NAC)-assisted thioesterification reaction. The peptide carrying NAC at its C-terminus was prepared by the Fmoc strategy and converted to the aryl thioester by 4-mercaptophenylacetic acid (MPAA) treatment without significant side reactions. The peptide thioester was used for the efficient preparation of 95-amino acid (AA) chemokine CCL27 by an Ag+-free thioester method.

One of the condensation methods for the preparation of long-chain peptides, the so-called thioester method requires protecting groups for amino and thiol groups for regioselective ligation. In this study, we demonstrated that the phenacyl (Pac) group acts as an efficient protecting group of cysteine side chains. We synthesized a cysteine derivative carrying the Pac group at the side chain sulfur atom, and Pac-containing peptides and peptide thioesters were synthesized using it by the ordinary 9-fluorenylmethoxycarbonyl (Fmoc)-based solid-phase peptide synthesis strategy. Pac-containing peptide segments could be condensed by the thioester method. After the condensation reaction, Pac groups could be removed by Zn/AcOH treatment. In addition, the azido group, which was used for the protection of lysine side chains, was simultaneously converted into an amino group, demonstrating that this protecting group scheme simplified the deprotecting reaction after the peptide condensation reaction to a single step.

The thioester method is a peptide condensation reaction, which requires the protection of Lys side chains for chemoselective ligation. We recently found that the azido group could be used as an amino protecting group in the peptide condensation by the thioester method. In this study, we synthesized the glycosylated mouse pro-opiomelanocortin (1–74) by the thioester method. The N-terminal peptide thioester segment, whose Lys side chain was protected by an azido group, was prepared using a 9-fluorenylmethoxycarbonyl (Fmoc) strategy and an N-alkylcysteine (NAC)-assisted thioesterification reaction. The C-terminal azido-glycopeptide segment carrying N- and O-linked glycans was also prepared by the Fmoc chemistry and condensed with the N-terminal segment by the silver ion-free thioester method. These results showed that our azido-based strategy was fully compatible with the NAC-assisted method and glycoprotein synthesis.

The synthesis of Fmoc-aminoacyl-N-ethyl-S-triphenylmethylcysteine, an N- to S-acyl migratory device for the preparation of peptide thioesters by Fmoc-SPPS (solid-phase peptide synthesis) is described. Condensation of Fmoc-aminoacyl pentafluorophenyl ester and N-ethyl-S-triphenylmethylcysteine was efficiently performed in the presence of HOOBt (3-hydroxy-3,4-dihydro-4-oxo-1,2,3-benzotriazine) in DMF. A small amount of diastereomer yielded during the reaction was easily separated by HPLC purification and the highly pure devices were obtained for most of the proteinogenic amino acids.

A novel GlcNAc-Asn unit carrying trifluoroacetic acid (TFA)-sensitive O-protecting groups was prepared. The unit was used for the solid-phase peptide synthesis (SPPS) of the N-acetylglucosaminylated emmprin (35–69) thioester via one-step deprotection by TFA combined with the N-alkylcysteine thioesterification method. This segment was used for the synthesis of the first Ig domain (22–104) of emmprin carrying GlcNAc by one-pot ligation with other segments using the thioester method. Finally, the sugar chain was elongated by transglycosylation using glycosynthase to give the Ig domain carrying the disialo- and asialo-complex-type sugar chain.

Aryl thioesters of peptide segments were prepared by the conventional 9-fluorenylmethoxycarbonyl (Fmoc) strategy using a novel N-alkyl cysteine (NAC)-assisted thioesterification reaction. The peptide carrying NAC at its C-terminus was prepared by the Fmoc strategy and converted to the aryl thioester by 4-mercaptophenylacetic acid (MPAA) treatment without significant side reactions. The peptide thioester was used for the efficient preparation of 95-amino acid (AA) chemokine CCL27 by an Ag+-free thioester method.

In the so-called thioester method for the condensation of peptide segments, protecting groups for amino and thiol groups are required for chemoselective ligation. In this study, we developed a novel thiol protecting group, N-methyl-phenacyloxycarbamidomethyl (Pocam). We used it for protection of cysteine side chains, and synthesized Pocam-containing peptides and peptide thioesters. These were condensed by the thioester method. After the condensation reaction, Pocam groups were cleaved by Zn/AcOH treatment. At the same time, the azido group, which was used for the protection of lysine side chains, was also converted to an amino group, demonstrating that this protecting group strategy simplified the deprotecting reaction after the peptide condensation reaction to only one step.