Abstract
Site-specific modification approaches have been extensively employed in the development of protein-based technologies. In this field, stability and activity integrity are the envisioned features of chemically modified proteins. These methods are especially used in the design of antibody-drug conjugates (ADCs). Nevertheless, a biochemical feature of the target protein in these reactions is often overlooked, residue specificity. Usually, in the course of developing chemical probes to modify a protein of interest (POI), specific amino acids are selected due to their reactivity. It is not critical which residue is modified as long as its modification does not compromise the POI's activity. However, no attention is paid as to why certain residues are preferentially modified over others. Physicochemical and structural constraints are often involved in the reactivity of the residue and account for the preferential modification. We propose that site-specific protein modification approaches can be applied beyond the development of ADCs or protein-drug conjugates, and used as a tool to reveal functionally relevant residues. By preferentially modifying certain side chains in the POI, chemical probes can uncover new binding motifs to investigate. Here we describe methods for protein modification, and how some pitfalls in the field can be turned into tools to reveal and exploit druggable pockets. Thus, allowing the design of innovative inhibitors against disease-relevant POIs. We discuss methodologies for site-specific modification of lysine, tryptophan, cysteine, histidine and tyrosine and comment on instances where the modified residues were used as targets for functionalization or drug design.
Highlights
The chemical modification of proteins has emerged as a valuable approach to interrogate and to intervene in biological systems (Stephanopoulos and Francis, 2011). It is inspired in the natural ability of cells to induce specific post-translational modifications (PTMs) which influence the fate of protein targets and their role in cellular processes, including trafficking, signaling, migration and differentiation (Walsh et al, 2005)
We focus on selected cases of loss-of-function induced by site-specific chemical probes upon modification of certain residues, and propose that these probes can reveal hitherto unknown functions of their targeted residues and unveil promising “druggable pockets.”
It is our understanding that site-specific modification approaches might offer an alternative avenue in the forefront of covalent inhibitor design
Summary
The chemical modification of proteins has emerged as a valuable approach to interrogate and to intervene in biological systems (Stephanopoulos and Francis, 2011). The loss-of-function promoted by some chemical probes as a result of an unintended specific modification can indicate the role of the modified amino acid in the POI’s activity or structure while revealing possible “druggable pockets.” This information can be exploited in drug design approaches directed to POIs involved in disease, including cancer. Authors tried to understand the reasons for the preferential targeting of a specific cysteine or lysine residue by a chemical probe over other reactive and accessible residues and the consequent loss-of-function induced by the modification Such analysis revealed interesting new motifs, which prompted interest in drug design platforms. Since there is a resurgence in the development of covalent inhibitors, applying this method to aid drug discovery programs seems highly appropriate
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