Modular Synthesis of Clickable Peptides Via Late-stage Maleimidation on C(7)-H Tryptophan

Overview

Journal Nat Commun

Specialty Biology

Date 2023 Jul 5

PMID 37407547

Authors

Peng Wang

Jiang Liu

Xiaomei Zhu

Kenry

Zhengqing Yan

Jiahui Yan

Jitong Jiang

Manlin Fu

Jingyan Ge

Qing Zhu

Yuguo Zheng

Affiliations

Soon will be listed here.

Abstract

Cyclic peptides have attracted tremendous attention in the pharmaceutical industry owing to their excellent cell penetrability, stability, thermostability, and drug-like properties. However, the currently available facile methodologies for creating such peptides are rather limited. Herein, we report an efficient and direct peptide cyclization via rhodium(III)-catalyzed C(7)-H maleimidation. Notably, this catalytical system has excellent regioselectivity and high tolerance of functional groups which enable late-stage cyclization of peptides. This architecture of cyclic peptides exhibits higher bioactivity than its parent linear peptides. Moreover, the Trp-substituted maleimide displays excellent reactivity toward Michael addition, indicating its potential as a click functional group for applications in chemical biology and medicinal chemistry. As a proof of principle, RGD-GFLG-DOX, which is a peptide-drug-conjugate, is constructed and it displays a strong binding affinity and high antiproliferative activity toward integrin-αvβ overexpressed cancer cell lines. The proposed strategy for rapid preparation of stapled peptides would be a robust tool for creating peptide-drug conjugates.

Citing Articles

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Late-stage peptide modification and macrocyclization enabled by tertiary amine catalyzed tryptophan allylation.

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