Unprotected peptide macrocyclization and stapling via a fluorine-thiol displacement reaction
Genre
Journal articleDate
2022-01-17Author
Islam, Md ShafiqulJunod, Samuel L.
Zhang, Si
Buuh, Zakey Yusuf
Guan, Yifu
Zhao, Mi
Kaneria, Kishan H.
Kafley, Parmila
Cohen, Carson
Maloney, Robert
Lyu, Zhigang
Voelz, Vincent A.
Yang, Weidong
Wang, Rongsheng
Department
BiologyChemistry
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http://hdl.handle.net/20.500.12613/7249
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https://doi.org/10.1038/s41467-022-27995-5Abstract
We report the discovery of a facile peptide macrocyclization and stapling strategy based on a fluorine thiol displacement reaction (FTDR), which renders a class of peptide analogues with enhanced stability, affinity, cellular uptake, and inhibition of cancer cells. This approach enabled selective modification of the orthogonal fluoroacetamide side chains in unprotected peptides in the presence of intrinsic cysteines. The identified benzenedimethanethiol linker greatly promoted the alpha helicity of a variety of peptide substrates, as corroborated by molecular dynamics simulations. The cellular uptake of benzenedimethanethiol stapled peptides appeared to be universally enhanced compared to the classic ring-closing metathesis (RCM) stapled peptides. Pilot mechanism studies suggested that the uptake of FTDR-stapled peptides may involve multiple endocytosis pathways in a distinct pattern in comparison to peptides stapled by RCM. Consistent with the improved cell permeability, the FTDR-stapled lead Axin and p53 peptide analogues demonstrated enhanced inhibition of cancer cells over the RCM-stapled analogues and the unstapled peptides.Citation
Islam, M.S., Junod, S.L., Zhang, S. et al. Unprotected peptide macrocyclization and stapling via a fluorine-thiol displacement reaction. Nat Commun 13, 350 (2022). https://doi.org/10.1038/s41467-022-27995-5Citation to related work
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http://dx.doi.org/10.34944/dspace/7228