Artemisinin-resistantPlasmodium falciparumKelch13 mutant proteins display reduced heme-binding affinity and decreased artemisinin activation

Abstract

AbstractThe rapid emergence of artemisinin resistance (ART-R) poses a challenge to global malaria control efforts. ART potency is triggered by ferrous iron- and/or heme-mediated cleavage of the endoperoxide bond to generate reactive heme-ART alkoxy radicals and covalent heme-ART adducts that alkylate parasite targets or inhibit the detoxification of heme into β-hematin crystals; both of which lead to parasite death. Mutations in theP. falciparumKelch-containing protein Kelch13 (PfKekch13) confer clinical ART-R, in which the resistant parasites exhibit impaired hemoglobin uptake, reduced heme yield, and thus decreased ART activation. However, a more direct involvement of PfKelch13 in heme-mediated ART activation has not been reported. Here, we show that recombinant, purified PfKelch13 wild-type (WT) protein displays measurable binding affinity for both iron and heme, the main effectors for ART activation. Comparative biochemical analyses further indicate weaker heme-binding affinities in the two Southeast Asian ART-R PfKelch13 mutants C580Y and R539T compared to the ART-sensitive WT and A578S mutant proteins, which ultimately translates into reduced yield of heme-ART derivatives. In conclusion, this study provides the first evidence for regulated ART activationviathe heme-binding propensity of PfKelch13, which may contribute towards modulating the level of ART-R in malaria parasites with PfKelch13 mutations.