Host SNARE Proteins Mediate Lysosome-PVM Fusion to Support <em>Plasmodium</em> Liver infection

Malaria, caused by Plasmodium parasites, remains a global health crisis, necessitating novel therapeutic strategies targeting host-parasite interactions. During liver stage in-fection, parasites exploit host vesicular trafficking machinery, particularly SNARE pro-teins that mediate membrane fusion. Using a CRISPR/Cas9 knockout system in HeLa cells combined with advanced microscopy of Plasmodium berghei-infected HeLa cells, we identified specific endolysosomal SNAREs VAMP7, VAMP8, Vti1B, and Stx7 to be re-cruited to the parasitophorous vacuole membrane (PVM) with distinct temporal profiles. This demonstrates the parasite’s precise manipulation of host endolysosomal trafficking pathways. VAMP7 and Vti1B localized to the PVM within 30 minutes post-infection suggesting potential roles during invasion, while VAMP8 and Stx7 appeared later toward 24 hpi, coinciding with increased nutrient acquisition. Single gene deletions showed minimal impact, but combinatorial knockouts revealed critical redundancy. VAMP7-VAMP8 as well as VAMP7–Vti1B double KO significantly reduced parasite in-fection and growth, with Vti1B playing a dominant role. Triple KO phenotypes mirrored VAMP7-Vti1B disruption, underscoring Vti1B’s dominant role. SNARE depletion also impaired lysosome-PVM association and LAMP1 positive vesicle recruitment. Our findings indicate Plasmodium hijacks a coordinated host SNARE network to fuse lysosomes with the PVM for nutrient uptake. Targeting Vti1B-containing complexes disrupts this pathway without host cell toxicity, offering a promising host-directed antimalarial ap-proach.