Synthesis of Peptidyl Aldehydes from Thiazolidines

Total Syntheses of Streptamidine and Klebsazolicin Using Biomimetic On-Resin Ring-Closing Amidine Formation

Diketopiperazine (DKP) derived cyclic amidine structures widely exist in peptide natural products according to the genome mining result. The largely unknown bioactivity and mode of action are partially caused by the poor availability of the compounds via microbiological and chemical approaches. To tackle this challenge, in this work, we have developed the on-resin ring-closing amidine formation strategy to synthesize peptides containing N-terminal DKP derived cyclic amidine structure, in which the 6-exo-trig cyclization mediated by HgCl2 activation of thioamides was the key step. Leveraging from this new strategy, we finished the total syntheses of streptamidine and klebsazolicin. Meanwhile, eleven klebsazolicin analogues were synthesized for its structure-activity relationship study.

Copper-Mediated Deprotection of Thiazolidine and Selenazolidine Derivatives Applied to Native Chemical Ligation

Cupric sulfate efficiently opens thiazolidine and selenazolidine rings, producing a protected N-terminal cysteine or selenocysteine derivative without the use of inert gas or solvent. This is a clear advantage over methods that use water-soluble palladium salts, which fail to react with the selenazolidine ring. This copper-mediated reaction proceeds with monovalent or divalent copper ions, and disulfide bond formation followed by ring-opening promotes the process. This copper-mediated reaction, which is compatible with the standard native chemical ligation conditions, was applied to the synthesis of the 77-mer CXCL14 protein.

The epimerization of peptide aldehydes—a systematic study

Peptide aldehydes are interesting targets as enzyme inhibitors, and can be used for pseudopeptide chemistry or ligation. However, they are known to be subjected to epimerization during synthesis or purification. By (1)H NMR, a model dipeptide aldehyde can be used to check the possible epimerization occurring during synthesis. Various purification methods were investigated, but none was free from epimerization.

Functionalization of peptides and proteins by aldehyde or keto groups

The functionalization of peptides and proteins by aldehyde or keto groups has become the subject of intensive research since the discovery of the inhibition properties of peptide aldehydes and the advent of protein engineering. The first part of this review focuses upon the tremendous efforts devoted to the solid-phase synthesis of peptide aldehydes as protease inhibitors. The second part describes the utility of the aldehyde or keto functionalities for the site-specific modification of peptides or proteins.