Protein abundance and folding rather than the redox state of Kelch13 determine the artemisinin susceptibility of Plasmodium falciparum

Abstract

AbstractDecreased susceptibilities of Plasmodium falciparum towards the endoperoxide antimalarial artemisinin are linked to mutations of residue C580 of Kelch13, which is the homologue of the redox sensor Keap1 in vertebrates. Here, we addressed whether mutations alter the artemisinin susceptibility by modifying the redox properties of Kelch13 or by compromising its native fold or abundance. Using selection-linked integration and the glmS ribozyme, efficient down-regulation of Kelch13 resulted in ring-stage survival rates around 40%. While the loss of a potential disulfide bond between residues C580 and C532 had no effect on the artemisinin suceptibility, the thiol group of C473 could not be replaced. We also established a protocol for the production of recombinant Kelch13. In contrast to cysteine-to-serine replacements, common field mutations resulted in misfolded and insoluble protein. In summary, not the redox properties but impaired folding of Kelch13, resulting in a decreased Kelch13 abundance, is the central parameter for mutant selection.