Structure−Activity Relationships of Uridine 5‘-Diphosphate Analogues at the Human P2Y6Receptor

Abstract

The structure−activity relationships and molecular modeling of the uracil nucleotide activated P2Y₆ receptor have been studied. Uridine 5‘-diphosphate (UDP) analogues bearing substitutions of the ribose moiety, the uracil ring, and the diphosphate group were synthesized and assayed for activity at the human P2Y₆ receptor. The uracil ring was modified at the 4 position, with the synthesis of 4-substituted-thiouridine 5‘-diphosphate analogues, as well as at positions 2, 3, and 5. The effect of modifications at the level of the phosphate chain was studied by preparing a cyclic 3‘,5‘-diphosphate analogue, a 3‘-diphosphate analogue, and several dinucleotide diphosphates. 5-Iodo-UDP 32 (EC₅₀ = 0.15 μM) was equipotent to UDP, while substitutions of the 2‘-hydroxyl (amino, azido) greatly reduce potency. The 2- and 4-thio analogues, 20 and 21, respectively, were also relatively potent in comparison to UDP. However, most other modifications greatly reduced potency. Molecular modeling indicates that the β-phosphate of 5‘-UDP and analogues is essential for the establishment of electrostatic interactions with two of the three conserved cationic residues of the receptor. Among 4-thioether derivatives, a 4-ethylthio analogue 23 displayed an EC₅₀ of 0.28 μM, indicative of favorable interactions predicted for a small 4-alkylthio moiety with the aromatic ring of Y33 in TM1. The activity of analogue 19 in which the ribose was substituted with a 2-oxabicyclohexane ring in a rigid (S)-conformation (P = 126°, 1‘-exo) was consistent with molecular modeling. These results provide a better understanding of molecular recognition at the P2Y₆ receptor and will be helpful in designing selective and potent P2Y₆ receptor ligands.