Structure-Based Design of Reactive Nucleosides for Site-Specific Modification of the A2A Adenosine Receptor.

Adenosine receptors (ARs) are members of the G protein-coupled receptor (GPCR) superfamily and have shown much promise as therapeutic targets. We have used an agonist-bound A2AAR X-ray crystallographic structure to design a chemically reactive agonist for site-specific chemical modification of the receptor. To further explore and chemically engineer its binding cavity, a 2-nitrophenyl active ester was attached through an elongated chain at adenine C2 position. This general structure was designed for irreversible transfer of a terminal acyl group to a nucleophilic amino group on the A2AAR. Preincubation with several O-acyl derivatives prevented radioligand binding that was not regenerated upon extensive washing. In silico receptor docking suggested two lysine residues (second extracellular loop) as potential target sites for an O-acetyl derivative (MRS5854, 3a), and site-directed mutagenesis indicated that K153 but not K150 is essential. Similarly, a butyl azide for click reaction was incorporated in the active ester moiety (3b). These promising results indicate a stable, covalent modification of the receptor by several reactive adenosine derivatives, which could be chemical tools for future imaging, structural probing, and drug discovery. Thus, structure-based ligand design has guided the site-specific modification of a GPCR.