Background: Malaria parasites import essential nutrients from plasma into their host erythrocytes through the plasmodial surface anion channel (PSAC), a conserved ion and nutrient channel on the infected cell surface. A parasite-encoded ternary complex consisting of CLAG3, RhopH2, and RhopH3 determines PSAC activity, but the precise contributions of each member to formation of the nutrient uptake pore remains uncertain. Methods: Here, we devised a two-step CRIPSR transfection strategy to examine an amphipathic CLAG3 helix, termed α-helix 44 (α-H44), as a candidate pore-lining domain. Results: A CLAG3 truncation protein without α-H44 phenocopies a CLAG3 knockout line, suggesting a critical role of α-H44 in formation of the nutrient channel; CLAG3 restoration using a recodonized α-H44 restores PSAC activity fully. A saturation mutagenesis library that splits the helix into four sequential segments was devised and implemented. Two engineered mutants exhibit distinct PSAC phenotypes; their cultures failed to expand in a modified medium that approximates in vivo nutrient availability. Conclusions: These studies support a α-H44 role in channel permeation and block by a strain-specific inhibitor. Our strategy will enable saturation mutagenesis to determine how PSAC achieves its unique ion and nutrient selectivity and should help guide drug discovery against this antimalarial target.
González‐Chávez et al. (Wed,) studied this question.