Establishment of One-Pot Disulfide-Driven Cyclic Peptide Synthesis with a 3-Nitro-2-pyridinesulfenate.

We have developed a new one-pot disulfide-driven cyclic peptide synthesis. The entire process is carried out in the solid phase, thus eliminating complicated work up procedures to remove by-products and unreacted reagents and enabling production of high-purity cyclic disulfide peptides by simple cleavage of a peptidyl resin. The one-pot synthesis of oxytocin was accomplished in this way with an isolated yield of 28% over 13 steps. These include peptide chain elongation from an initial resin, sulfenylation of the protected side chain of a cysteine (Cys) residue, disulfide ligation between thiols in an additional peptide fragment and a 3-nitro-2-pyridinesulfenyl-protected cysteine (Cys(Npys))-containing peptide resin, subsequent intramolecular amide bond formation of the disulfide-connected fragments by an Ag+-promoted thioester method, followed by deprotection and HPLC purification.

Use of solid-supported 4-fluorophenyl 3-nitro-2-pyridinesulfenate in the construction of disulfide-linked hybrid molecules.

To construct disulfide-linked hybrid molecules systematically and efficiently, we established a more practical solid-phase disulfide ligation (SPDSL) system with enhanced utility. The group Npys-OPh(pF) shows reactivity similar to that of Npys-Cl, but it is more stable. An efficient synthesis of the cyclic peptide oxytocin and a peptide-sugar conjugate was accomplished as models. These results indicate that the Npys-OPh(pF) resin functions as a common synthetic platform in SPDSL.