Efficient Ligand Discovery Using Sulfur(VI) Fluoride Reactive Fragments

Overview

Journal ACS Chem Biol

Publisher American Chemical Society

Specialties Biochemistry
Biology

Date 2023 Apr 21

PMID 37084287

Authors

Arron Aatkar

Aini Vuorinen

Oliver E Longfield

Katharine Gilbert

Rachel Peltier-Heap

Craig D Wagner

Francesca Zappacosta

Katrin Rittinger

Chun-Wa Chung

David House

Nicholas C O Tomkinson

Jacob T Bush

Affiliations

Soon will be listed here.

Abstract

Sulfur(VI) fluorides (SFs) have emerged as valuable electrophiles for the design of "beyond-cysteine" covalent inhibitors and offer potential for expansion of the liganded proteome. Since SFs target a broad range of nucleophilic amino acids, they deliver an approach for the covalent modification of proteins without requirement for a proximal cysteine residue. Further to this, libraries of reactive fragments present an innovative approach for the discovery of ligands and tools for proteins of interest by leveraging a breadth of mass spectrometry analytical approaches. Herein, we report a screening approach that exploits the unique properties of SFs for this purpose. Libraries of SF-containing reactive fragments were synthesized, and a direct-to-biology workflow was taken to efficiently identify hit compounds for CAII and BCL6. The most promising hits were further characterized to establish the site(s) of covalent modification, modification kinetics, and target engagement in cells. Crystallography was used to gain a detailed molecular understanding of how these reactive fragments bind to their target. It is anticipated that this screening protocol can be used for the accelerated discovery of "beyond-cysteine" covalent inhibitors.

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