Abstract
The virulent form of malaria is caused by Plasmodium falciparum that infects red blood cells. In order to survive inside the host, the parasite remodels the infected erythrocytes by exporting more than 300 effector proteins outside the parasitophorous vacuole membrane into the cytosol. The main feature of all the export proteins is the presence of a pentapeptide sequence motif; RxLxE/Q/D. This sequence motif is hydrolysed between L – x and the proteins with the acetylated new N-terminus xE/Q/D are exported. The enzyme responsible for this hydrolysis is plasmepsin V which is one of the ten aspartic proteases in P. falciparum. In order to understand the structural rationale for the specificity of this protease towards cleavage of the above motif, we generated three-dimensional models of seven plasmepsins (I, V to X) for which experimental structures are not available and compared these along with the crystal structures of three P. falciparum plasmepsins (II to IV). The structure comparisons revealed the importance of Tyr13, Glu77 and Ala117 specific to plasmepsin V that facilitates the accommodation of arginine at P3 in the RxLxE/Q/D motif. Our analysis correlates the structure- function relationship of plasmepsin V.
Keywords: Plasmodium falciparum, aspartic protease, plasmepsin V, RxLxE/Q/D sequence motif, PEXEL motif, substrate specificity, structure-function correlationPlasmodium falciparum, aspartic protease, plasmepsin V, RxLxE/Q/D sequence motif, PEXEL motif, substrate specificity, structure-function correlation
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