Enzymatic activation of double-targeted 5'-O-L-valyl-decitabine prodrug by biphenyl hydrolase-like protein and its molecular design basis.

A primary focus of this research was to explore the activation process and mechanism of decitabine (5-aza-2'-deoxycytidine, DAC) prodrug. Recently, it has been reported that biphenyl hydrolase-like protein (BPHL) can play an important role in the activation of some amino acid nucleoside prodrugs with a general preference for hydrophobic amino acids and 5'-esters. Therefore, we put forward a bold hypothesis that this novel enzyme may be primarily responsible for the activation process of DAC prodrug as well. 5'-O-L-valyl-decitabine (L-val-DAC) was synthesized before and can be transported across biological membranes by the oligopeptide transporter (PEPT1), granting it much greater utility in vivo. In this report, L-val-DAC was found to be a good substrate of BPHL protein (K m 0.59 mM; k cat/K m 553.69 mM-1 s-1). After intestinal absorption, L-val-DAC was rapidly and almost completely hydrolyzed to DAC and L-valine. The catalysis was mainly mediated by the BPHL hydrolase and resulted in the intestinal first-pass effect of L-val-DAC after oral administration in Sprague-Dawley rats with cannulated jugular and portal veins. The structural insights using computational molecular docking showed that BPHL had a unique binding mode for L-val-DAC. As a fundamental basis, the simulation was employed to explain the catalytic mechanism in molecular level. In conclusion, BPHL was at least one of the primary candidate enzymes for L-val-DAC prodrug activation. This promising double-targeted prodrug approach have more advantages than the traditional targeted designs due to its higher transport and more predictable activation, thereby leading to a favorable property for oral delivery.