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The human malaria parasite Plasmodium falciparum invades red blood cells (RBCs) and exports parasite proteins to transform the host cell for its survival. These exported proteins facilitate cytoadherence of the infected RBC (iRBC) to endothelial cells of small blood vessels, protecting iRBCs from splenic clearance. The parasite protein PfEMP1 and the host protein CD36 play a major role in P. falciparum iRBC cytoadherence. The murine parasite Plasmodium berghei is a widely used experimental model that combines high genetic tractability with access to in vivo studies. The P. berghei iRBC also sequesters by CD36-binding via an unknown parasite ligand and few parasite proteins, including EMAP1 and EMAP2, have been localised to the iRBC membrane. We have identified a new protein named EMAP3 and demonstrated its export to the iRBC membrane where it likely interacts with EMAP1, with only EMAP3 exposed on the outer surface of the iRBC. Parasites lacking EMAP3 display no significant reduction in growth or sequestration, indicating that EMAP3 is not a major CD36-binding protein. The outer-surface location of EMAP3 offers a new scaffold for displaying P. falciparum proteins on the surface of the P. berghei iRBC, providing a platform to screen in vivo for putative inhibitors of P. falciparum cytoadherence.

Genetic modification is essential for understanding parasite biology, yet it remains challenging in Plasmodium. This is partially due to the parasite’s low genetic tractability and reliance on homologous recombination, since the parasites lack the canonical non-homologous end-joining pathway. Existing approaches, such as the PlasmoGEM project, enable genome-wide knockouts but remain limited in coverage and flexibility. Here, we present the Plasmodium berghei high-throughput (PbHiT) system, a scalable CRISPR-Cas9 protocol for efficient genome editing in rodent malaria parasites. The PbHiT method uses a single cloning step to generate vectors in which a guide RNA (gRNA) is physically linked to short (100 bp) homology arms, enabling precise integration at the target locus upon transfection. The gRNA also serves as a unique barcode, allowing pooled vector transfections and identification of mutants by downstream gRNA sequencing. The PbHiT system reliably recapitulates known mutant growth phenotypes and supports both knockout and tagging strategies. This protocol provides a reproducible and scalable tool for genome editing in P. berghei, enabling both targeted functional studies and high-throughput genetic screens. Additionally, we provide an online resource covering the entire P. berghei protein-coding genome and describe a step-by-step pooled ligation approach for large-scale vector production.

Many Plasmodium genes remain uncharacterized due to low genetic tractability. Previous large-scale knockout screens have only been able to target about half of the genome in the more genetically tractable rodent malaria parasite Plasmodium berghei. To overcome this limitation, we have developed a scalable CRISPR system called P. berghei high-throughput (PbHiT), which uses a single cloning step to generate targeting vectors with 100-bp homology arms physically linked to a guide RNA (gRNA) that effectively integrate into the target locus. We show that PbHiT coupled with gRNA sequencing robustly recapitulates known knockout mutant phenotypes in pooled transfections. Furthermore, we provide an online resource of knockout and tagging designs to target the entire P. berghei genome and scale-up vector production using a pooled ligation approach. This work presents for the first time a tool for high-throughput CRISPR screens in Plasmodium for studying the parasite’s biology at scale.

The ∼30 Mb genomes of the Plasmodium parasites that cause malaria each encode ∼5000 genes, but the functions of the majority remain unknown. This is due to a paucity of functional annotation from sequence homology, which is compounded by low genetic tractability compared with many model organisms. In recent years technical breakthroughs have made forward and reverse genome-scale screens in Plasmodium possible. Furthermore, the adaptation of Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) and CRISPR-Associated protein 9 (CRISPR/Cas9) technology has dramatically improved gene editing efficiency at the single gene level. Here, we review the arrival of genetic screens in malaria parasites to analyse parasite gene function at a genome-scale and their impact on understanding parasite biology. CRISPR/Cas9 screens, which have revolutionised human and model organism research, have not yet been implemented in malaria parasites due to the need for more complex CRISPR/Cas9 gene targeting vector libraries. We therefore introduce the reader to CRISPR-based screens in the related apicomplexan Toxoplasma gondii and discuss how these approaches could be adapted to develop CRISPR/Cas9 based genome-scale genetic screens in malaria parasites. Moreover, since more than half of Plasmodium genes are required for normal asexual blood-stage reproduction, and cannot be targeted using knockout methods, we discuss how CRISPR/Cas9 could be used to scale up conditional gene knockdown approaches to systematically assign function to essential genes.

Malaria, caused by Plasmodium parasites, claims over 600,000 deaths annually. Parasite invasion of red blood cells (RBCs) involves protein secretion from specialised organelles— micronemes, rhoptries, and dense granules—to facilitate host cell entry and establish a protective parasitophorous vacuole (PV). Despite the critical role of rhoptry proteins in infection, many remain poorly characterised due to the absence of recognisable trafficking motifs and dispensability in vitro. Here, we leverage spatial proteomics from Plasmodium falciparum to identify two novel Plasmodium berghei ortholog proteins associated with the PV (MAP1, PBANKA_1425900 and RhoSH, PBANKA_1001500) both containing hydrolase domains. Ultra-expansion microscopy reveals their localisation to the rhoptries in late schizogony, while co-immunoprecipitation shows their interaction. In vivo studies demonstrate that these proteins help the parasite evade spleen-mediated clearance and contribute to disease progression. One protein, MAP1, mediates sequestration to adipose tissue, and conditional knockdown of its P. falciparum ortholog results in reduced CD36-mediated cytoadhesion, suggesting a mechanism for immune evasion and sustained infection. Our findings identify MAP1 and RhoSH as key mediators of Plasmodium virulence. Takingadvantage of an in vivo approach, this work provides valuable insights toward global malaria eradication efforts as it lays the groundwork for novel therapeutic strategies, positioning mainly MAP1 but also RhoSH as promising targets, including their use as antigens in recombinant vaccines, attenuated live vaccine candidates, or enzyme-inhibiting drugs.

The human malaria parasite Plasmodium falciparum invades red blood cells (RBC) and exports parasite proteins to transform the host cell for its survival. These exported proteins facilitate uptake of nutrients and cytoadherence of the infected RBC (iRBC) to endothelial cells of small blood vessels, thus protecting the iRBC from splenic clearance. The parasite protein PfEMP1 and the host protein CD36 play a major role in P. falciparum iRBC cytoadherence. The murine parasite Plasmodium berghei is a widely used experimental model that combines high genetic tractability with access to in vivo studies. P. berghei iRBC also sequesters in small blood vessels, mediated by binding to CD36. However, the parasite proteins binding to CD36 are unknown and only very few parasite proteins, including EMAP1 and EMAP2, have been identified that are present at the iRBC membrane. We have identified a new protein named EMAP3 and demonstrated its export to the iRBC membrane where it interacts with EMAP1, with only EMAP3 exposed on the outer surface of the iRBC. Parasites lacking EMAP3 display no significant reduction in growth or sequestration, indicating that EMAP3 is not the major CD36-binding protein. The outer-surface location of EMAP3 offers a new scaffold for displaying P. falciparum proteins on the surface of the P. berghei iRBC, providing a platform to screen in vivo putative inhibitors of P. falciparum cytoadherence.