Abstract
Protein tyrosine phosphatases (PTPs) are an important class of enzymes that modulate essential cellular processes through protein dephosphorylation and are dysregulated in various disease states. There is demand for new compounds that target the active sites of these enzymes, for use as chemical tools to dissect their biological roles or as leads for the development of new therapeutics. In this study, we explore an array of electrophiles and fragment scaffolds to investigate the required chemical parameters for covalent inhibition of tyrosine phosphatases. Our analysis juxtaposes the intrinsic electrophilicity of these compounds with their potency against several classical PTPs, revealing chemotypes that inhibit tyrosine phosphatases while minimizing excessive, potentially non-specific reactivity. We also assess sequence divergence at key residues in PTPs to explain their differential susceptibility to covalent inhibition. We anticipate that our study will inspire new strategies to develop covalent probes and inhibitors for tyrosine phosphatases.
Supplementary materials
Title
Supporting Information
Description
Supplementary figures S1-S13, sequences of protein constructs, synthesis and characterization of compounds, and Table S1, containing structures of all compounds.
Actions
Title
Table S2
Description
Residual activity of PTPs after treatment with diverse phenyl-substituted warheads.
Actions
Title
Table S3
Description
Residual activity of PTPs after treatment with chloroacetamide-substituted scaffolds.
Actions
Title
Table S4
Description
IC50 values for inhibition of PTPs by chloroacetamides.
Actions
Title
Table S5
Description
Second-order rate constants for reactions between chloroacetamides and TNB2+.
Actions