Abstract
Efficient siRNA loading into Argonaute2 (AGO2) requires a 5'-phosphate (5'-P) on the guide strand, yet this group is vulnerable to metabolic degradation in vivo. Although numerous chemical mimics of 5'-P have been reported, structural principles governing AGO2 interactions with organyl substituents on the 5'-P remain unclear. Moreover, structural determinants of 5'-P mimic recognition by known degradative enzymes (principally phosphatases and 5'-exonucleases) are also poorly understood. The 5'-P binding site of the AGO2 MID domain contains a stack of aromatic residues (Y527/F811/Y815), presenting a structural basis for augmenting canonical anchoring interactions. Herein, we systematically synthesized and characterized a diverse panel of organyl 5'-phosphates (5'-POR; R = 35 variable substituents) as guide strand 5'-P mimics designed to engage this unique hydrophobic pocket. Among the compounds evaluated, 5'-POR guide strands bearing methyl (Me) or phenylpropargyl (PhPrp) substituents are well-tolerated by AGO2 in cells. Previously uncharacterized 5'-P mimics, including 5'-phosphorothioate (5'-PS), phenylpropargyl 5'-phosphorothioate (5'-PS-PhPrp), and 5'-mesylphosphoramidate (5'-MsPA), maintain comparable AGO2 compatibility. All examined 5'-P mimics are markedly resistant to phosphatase, while 5'-POR variants and 5'-PS-PhPrp are also resistant to 5'-exonuclease degradation due to masking a negative charge of 5'-P. A crystal structure of a 5'-PO-PhPrp guide strand loaded into AGO2 reveals an unexpected network of π-π interactions between the rigid phenylpropargyl group and the targeted hydrophobic pocket of the MID domain. Collectively, these findings expand the functional chemical space of 5'-P mimics and define new modes for metabolically stabilizing the guide strand 5'-end while augmenting AGO2 MID anchoring.