RALP1 is essential for schizont maturation and erythrocyte invasion in Plasmodium falciparum.

BACKGROUND: Plasmodium falciparum merozoite invasion of erythrocytes is an essential step in the asexual blood-stage cycle and a major target for antimalarial intervention. Rhoptry neck proteins play key roles in the formation and function of the tight junction, yet many remain poorly characterized. RALP1, a conserved rhoptry neck-associated leucine zipper-like protein, has been proposed to participate in erythrocyte binding and invasion. Conventional gene disruption attempts have been unsuccessful, suggesting that RALP1 may be essential for parasite survival. Nevertheless, its precise role and broader molecular impact during intraerythrocytic development remain to be fully elucidated. METHODS: We generated a 3 × HA-tagged conditional knockdown line (ralp1-ha-glmS) using CRISPR-Cas9-mediated homologous recombination. RALP1 abundance and subcellular localization were evaluated by Western blotting and immunofluorescence assays. Effects on parasite growth, schizont maturation, merozoite invasion, and merozoite numbers were assessed using tightly synchronized cultures and established invasion and cytological assays. Transcriptomic changes following GlcN-induced RALP1 knockdown were analyzed by RNA-seq at early ring and schizont stages. Sequence-based structural and epitope features were examined using IUPred2A, ANCHOR2, AlphaFold3, NetMHCpan, and NetMHCIIpan. RESULTS: Precise integration of the ha-glmS cassette enabled GlcN-inducible reduction of RALP1 protein levels, most prominently in schizonts. RALP1 knockdown reduced parasite proliferation, impaired schizont maturation, decreased merozoite numbers, and lowered erythrocyte invasion efficiency. RNA-seq showed limited effects in early rings but widespread downregulation of invasion- and host-parasite interaction-related genes in schizonts after correction for glucosamine-responsive transcripts, with GO enrichment highlighting processes related to host cell interaction, biological adhesion, and membrane-associated components. Sequence-based analyses indicated that RALP1 contains extensive intrinsically disordered regions with multiple predicted interaction motifs, while predicted B- and T-cell epitope hotspots concentrated within the C-terminal RBC-binding domain. AlphaFold3 modeling yielded low global confidence (pTM = 0.23), consistent with a primarily disordered architecture. CONCLUSIONS: RALP1 is required for normal schizont maturation and efficient erythrocyte invasion in P. falciparum. Its partial knockdown perturbs transcription of key invasion ligands and apical components, indicating a broader role in preparing merozoites for host-cell entry. The extensive disorder, epitope-rich C-terminal region, and essential function of RALP1 highlight its potential as a candidate for therapeutic or vaccine targeting.