Differential importance of MSP4 and MSP5 for infection of red blood cells between human infecting malaria parasites

Plasmodium species malaria parasites require invasion and replication within red blood cells to cause disease. Merozoite surface proteins (MSPs) are proposed to play a role in attachment of merozoites to RBCs and have long been considered as potential vaccine targets, but their functions during invasion are largely unknown. We applied targeted gene editing to investigate MSP4 and 5 function in P. falciparum , which causes most malaria mortality, and P. knowlesi , an in vitro culturable zoonotic species closely related to the widespread P. vivax . CRISPR-Cas9 gene-editing revealed that P. knowlesi MSP4 was not required for parasite growth in vitro . While P. knowlesi MSP5 could be functionally replaced by P. vivax MSP5, it was refractory to gene deletion. We confirmed the opposite for two different P. falciparum laboratory isolates where MSP4 is essential but MSP5 is dispensable. Attempts to select for reliance on the non-essential MSP (e.g. P. knowlesi MSP4 or P. falciparum MSP5) through long-term growth of inducible knock-out parasites, or via chimeric complementation of the essential MSP4 or 5 with the essential MSP from the other species, were unsuccessful. Live cell filming revealed a severe cell-entry defect with conditional knock-down of MSP5 protein expression in P. knowlesi . This study demonstrates differential importance of MSP4 and MSP5 during merozoite RBC invasion across human infecting malaria species, emphasises that vaccine candidates must be considered individually for the two most prominent human malarias and promotes MSP5 as a potential vaccine candidate for P. knowlesi and P. vivax .