Label-Free Bottom-Up Proteomic Workflow for Simultaneously Assessing the Target Specificity of Covalent Drug Candidates and Their Off-Target Reactivity to Selected Proteins

Although designed covalent inhibitors as drug candidates offer several unique advantages over conventional reversible inhibitors, including high potency and the potential for less frequent dosing, there is a general tendency to avoid the covalent mode of action in drug discovery programs due to concerns regarding immune-mediated toxicity that can arise from indiscriminate reactivity with off-target proteins. Therefore, the ability to assess off-target reactivity relative to target specificity is desirable for optimizing covalent drug candidates in the early discovery stage. One concern with current surrogate nucleophile trapping approaches is that they employ a simplistic model nucleophile such as glutathione, which may not reliably reflect the covalent interactions with cellular or extracellular proteins. One way to get a more relevant reactivity assessment is to directly measure the ability of an inhibitor to covalently modify nucelophilic amino acids on biologically relevant proteins, both on- and off-target. In this article, we describe a label-free bottom-up proteomic workflow for simultaneous evaluation of target binding and off-target reactivity of covalent drug candidates to selected proteins at the peptide level. Ibrutinib, a covalent drug targeting the active site of BTK protein, was used as a model compound to demonstrate the feasibility of the workflow. The compound was incubated with a mixture of target protein, Brutons tyrosine kinase (BTK), and two abundant proteins in blood, hemoglobin (Hb) and human serum albumin (HSA), and then the ibrutinib modification sites were determined utilizing a bottom-up proteomic approach. A non-BTK specific model compound (1) known to modify cysteine residues was also included. By comparing the extent of off-target modifications to the targeted BTK C481 binding in a wide compound concentration range, we were able to determine the concentration where maximum target binding was achieved with minimal off-target reactivity. The generic label-free bottom-up proteomics workflow described in this article should be useful in the rank order assessment of off-target reactivity vs on-target reactivity of covalent drug candidates in the early drug discovery stage.