Chemical and Computational Methods for the Characterization of Covalent Reactive Groups for the Prospective Design of Irreversible Inhibitors

Mark E. Flanagan; J. A. Abramite; Dennis P. Anderson; Ann Aulabaugh; Upendra P. Dahal; A. Gilbert; Chao Li; Justin I. Montgomery; Stacey R. Oppenheimer; Tim F. Ryder; Brandon P. Schuff; Daniel P. Uccello; Gregory S. Walker; Yan Wu; Matthew F. Brown; Jinshan M. Chen; Matthew M. Hayward; Mark C. Noe; R. Scott Obach; Laurence Philippe; Veerabahu Shanmugasundaram; Michael J. Shapiro; Jeremy T. Starr; Justin G. Stroh; Ye Che

doi:10.1021/jm501412a

Chemical and Computational Methods for the Characterization of Covalent Reactive Groups for the Prospective Design of Irreversible Inhibitors

Mark E. Flanagan(Pfizer (United States)), J. A. Abramite(Pfizer (United States)), Dennis P. Anderson(Pfizer (United States)), Ann Aulabaugh(Pfizer (United States)), Upendra P. Dahal(Pfizer (United States)), A. Gilbert(Pfizer (United States)), Chao Li(Pfizer (United States)), Justin I. Montgomery(Pfizer (United States)), Stacey R. Oppenheimer(Pfizer (United States)), Tim F. Ryder(Pfizer (United States)), Brandon P. Schuff(Pfizer (United States)), Daniel P. Uccello(Pfizer (United States)), Gregory S. Walker(Pfizer (United States)), Yan Wu(Pfizer (United States)), Matthew F. Brown(Pfizer (United States)), Jinshan M. Chen(Pfizer (United States)), Matthew M. Hayward(Pfizer (United States)), Mark C. Noe(Pfizer (United States)), R. Scott Obach(Pfizer (United States)), Laurence Philippe(Pfizer (United States)), Veerabahu Shanmugasundaram(Pfizer (United States)), Michael J. Shapiro(Pfizer (United States)), Jeremy T. Starr(Pfizer (United States)), Justin G. Stroh(Pfizer (United States)), Ye Che(Pfizer (United States))

Journal of Medicinal Chemistry

November 6, 2014

10.1021/jm501412a

Cited by 324

Abstract

Interest in drugs that covalently modify their target is driven by the desire for enhanced efficacy that can result from the silencing of enzymatic activity until protein resynthesis can occur, along with the potential for increased selectivity by targeting uniquely positioned nucleophilic residues in the protein. However, covalent approaches carry additional risk for toxicities or hypersensitivity reactions that can result from covalent modification of unintended targets. Here we describe methods for measuring the reactivity of covalent reactive groups (CRGs) with a biologically relevant nucleophile, glutathione (GSH), along with kinetic data for a broad array of electrophiles. We also describe a computational method for predicting electrophilic reactivity, which taken together can be applied to the prospective design of thiol-reactive covalent inhibitors.

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