Abstract
The phosphobase methylation pathway catalyzed by the phosphoethanolamine methyltransferase in Plasmodium falciparum (PfPMT), the malaria parasite, offers an attractive target for anti-parasitic drug development. PfPMT methylates phosphoethanolamine (pEA) to phosphocholine for use in membrane biogenesis. Quantum mechanics and molecular mechanics (QM/MM) calculations tested the proposed reaction mechanism for methylation of pEA involving the previously identified Tyr-19-His-132 dyad, which indicated an energetically unfavorable mechanism. Instead, the QM/MM calculations suggested an alternative mechanism involving Asp-128. The reaction coordinate involves the stepwise transfer of a proton to Asp-128 via a bridging water molecule followed by a typical Sn2-type methyl transfer from S-adenosylmethionine to pEA. Functional analysis of the D128A, D128E, D128Q, and D128N PfPMT mutants shows a loss of activity with pEA but not with the final substrate of the methylation pathway. X-ray crystal structures of the PfPMT-D128A mutant in complex with S-adenosylhomocysteine and either pEA or phosphocholine reveal how mutation of Asp-128 disrupts a hydrogen bond network in the active site. The combined QM/MM, biochemical, and structural studies identify a key role for Asp-128 in the initial step of the phosphobase methylation pathway in Plasmodium and provide molecular insight on the evolution of multiple activities in the active site of the PMT.
Highlights
In Plasmodium, phosphoethanolamine methyltransferase (PfPMT) is essential for normal growth and development
The kcat/Km values for pDME with the D128A and D128N mutants were reduced by 18- and 36-fold, respectively. These results demonstrate that Asp-128 plays a critical role in the methylation of pEA and has a greatly diminished but still significant role in the methylation of pDME
AdoMet-dependent methylations of macromolecules and metabolites are ubiquitous in biological systems, the enzymes that perform these transformations employ a variety of chemical strategies [1]
Summary
In Plasmodium, phosphoethanolamine methyltransferase (PfPMT) is essential for normal growth and development. The combined QM/MM, biochemical, and structural studies identify a key role for Asp-128 in the initial step of the phosphobase methylation pathway in Plasmodium and provide molecular insight on the evolution of multiple activities in the active site of the PMT. X-ray crystal structures of PfPMT in complex with various substrates and inhibitors and extensive biochemical characterization provide insight on the organization of the AdoMet and phosphobase-binding sites in the enzyme (Fig. 1, bottom) [18, 19]. 9.12 8.06 9.44 8.42 8.34 8.68 Ϯ 0.52 all, these studies suggest the importance of Asp-128 in the initial step of the phosphobase methylation pathway catalyzed by PfPMT and provide insight on the evolution of multiple activities in the active site of the PMT from the malaria parasite
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