Protoporphyrin ferrochelatase catalyzes the insertion of Fe2+ into protoporphyrin IX to form heme. To determine whether a conserved, active site π-helix contributes to the translocation of the metal ion substrate to the ferrochelatase-bound porphyrin substrate, the invariant π-helix glutamates were replaced with amino acids with non-negatively charged side chains, and the kinetic mechanisms of the generated variants were examined. Analysis of yeast wild-type ferrochelatase-, E314Q- and E318Q-catalyzed reactions, under multi- and single-turnover conditions, demonstrated that the mutations of the π-helix glutamates hindered both protoporphyrin metalation and release of the metalated porphyrin, by slowing each step by approximately 30-50%. Protoporphyrin metalation occurred with an apparent pKa of 7.3 ± 0.1, which was assigned to binding of Fe2+ by deprotonated Glu-314 and Glu-314-assisted Fe2+ insertion into the porphyrin ring. We propose that unwinding of the π-helix concomitant with the adoption of a protein open conformation positions the deprotonated Glu-314 to bind Fe2+ from the surface of the enzyme. Transition to the closed conformation, with π-helix winding, brings Glu-314-bound Fe2+ to the active site for incorporation into protoporphyrin.
Keywords: Enzyme mechanism; Erythropoiesis; Heme; Metalloenzyme; Porphyrin; Protoporphyrin ferrochelatase.
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