ABSTRACT
Plasmodium falciparum hypoxanthine-guanine-xanthine phosphoribosyltransferase (PfHGXPRT) exhibits a kinetic mechanism that differs from that of the human homolog. Human HGPRT follows a steady-state ordered mechanism, wherein PRPP binding precedes the binding of hypoxanthine/guanine and release of product IMP/GMP is the rate limiting step. In the current study, initial velocity kinetics with PfHGXPRT indicates a steady-state ordered mechanism, wherein xanthine binding is conditional to the binding of PRPP. The value of the rate constant for IMP dissociation is greater by 183-fold than the kcat for hypoxanthine phosphoribosylation and this results in the absence of burst in progress curves from pre-steady-state kinetics. Further, IMP binding is 1000 times faster (4s(-1) at 0.5µM IMP) when compared to the kcat (3.9±0.2×10(-3)s(-1)) for the reverse IMP pyrophosphorolysis reaction. These results lend support to the fact that in both forward and reverse reactions, the process of chemical conversion (formation of IMP/hypoxanthine) is slow and the events of ligand association and dissociation are faster.