Login / Signup

Thiocarbazate building blocks enable the construction of azapeptides for rapid development of therapeutic candidates.

Ahmad AltitiMingzhu HeSonya VanPattenKai Fan ChengUmair AhmedPui Yan ChiuIbrahim T MughrabiBayan Al JabariRonald M BurchKirk R ManogueKevin J TraceyBetty DiamondChristine N MetzHuan YangLaQueta K HudsonStavros ZanosMyoungsun SonBarbara SherryThomas R ColemanYousef Al-Abed
Published in: Nature communications (2022)
Peptides, polymers of amino acids, comprise a vital and expanding therapeutic approach. Their rapid degradation by proteases, however, represents a major limitation to their therapeutic utility and chemical modifications to native peptides have been employed to mitigate this weakness. Herein, we describe functionalized thiocarbazate scaffolds as precursors of aza-amino acids, that, upon activation, can be integrated in a peptide sequence to generate azapeptides using conventional peptide synthetic methods. This methodology facilitates peptide editing-replacing targeted amino acid(s) with aza-amino acid(s) within a peptide-to form azapeptides with preferred therapeutic characteristics (extending half-life/bioavailability, while at the same time typically preserving structural features and biological activities). We demonstrate the convenience of this azapeptide synthesis platform in two well-studied peptides with short half-lives: FSSE/P5779, a tetrapeptide inhibitor of HMGB1/MD-2/TLR4 complex formation, and bradykinin, a nine-residue vasoactive peptide. This bench-stable thiocarbazate platform offers a robust and universal approach to optimize peptide-based therapeutics.
Keyphrases
  • amino acid
  • immune response
  • molecular dynamics
  • mass spectrometry
  • tissue engineering
  • nuclear factor
  • loop mediated isothermal amplification