Effect of Brønsted Acids on the Activation of Mixed Anhydride/Mixed Carbonic Anhydride and C-Terminal-Free N-Methylated Peptide Synthesis in a Micro-Flow Reactor.

Amidations employing mixed (carbonic) anhydrides have long been favoured in peptide synthesis because of their cost-effectiveness and less waste generation. Despite their long history, no study has compared the effects of additives on the activation of mixed anhydrides and carbonic anhydrides. In this study, we investigated the amidation of mixed (carbonic) anhydride in the presence of a base and/or Brønsted acids. The use of NMI·HCl significantly improved the conversion of the mixed carbonic anhydride, while expediting nucleophilic attacks on the desired carbonyl group. In contrast, in the case of mixed carbonic anhydrides, neither the conversion nor the desired nucleophilic attack improved significantly. We developed a C-terminus-free N-methylated peptide synthesis method using mixed carbonic anhydrides in a micro-flow reactor. Fourteen N-alkylated peptides were synthesized in moderate to high yields (55-99%) without severe racemization (<1%). Additionally, a significant enhancement in the amidation between mixed carbonic anhydrides and bis-TMS-protected N-methyl amino acids with the inclusion of NMI·HCl was observed for the first time. In addition, we observed unexpected C-terminal epimerization of the C-terminus-free N-methyl peptides.

Peptide Cyclization by the Use of Acylammonium Species.

Although cyclic peptides have become increasingly important as drugs, the most conventional peptide cyclization method using moderately active coupling agents suffers from a lot of waste and high cost as well as long reaction times and burdensome purification. Herein, we report an unconventional approach to peptide cyclization that uses acylammonium species generated from inexpensive and less wasteful Me2 NBn and ClCO2 i-Pr. Using this approach, we observed the desired rapid activation of the C-terminus of cyclization precursors by an acylammonium ion for rapid and epimerization/dimerization-free cyclization of synthetically challenging peptides, including a difficult cyclization involving N-methyl amide bond formation. The ease of purification, productivities, and reaction mass efficiencies of our approach were significantly superior to those in previous reports. We synthesized a previously reported versicotide D analogue, and our data indicated that its assigned stereostructure should be revised.