Host cell CRISPR genomics and modelling reveal shared metabolic vulnerabilities in the intracellular development of Plasmodium falciparum and related hemoparasites.
Marina MaurizioMaria MasidKerry WoodsReto CaldelariJohn G DoenchArunasalam NaguleswaranDenis JolyMartín González FernándezJonas ZempMélanie BorteeleVassily HatzimanikatisVolker T HeusslerSven RottenbergPhilipp OliasPublished in: Nature communications (2024)
Parasitic diseases, particularly malaria (caused by Plasmodium falciparum) and theileriosis (caused by Theileria spp.), profoundly impact global health and the socioeconomic well-being of lower-income countries. Despite recent advances, identifying host metabolic proteins essential for these auxotrophic pathogens remains challenging. Here, we generate a novel metabolic model of human hepatocytes infected with P. falciparum and integrate it with a genome-wide CRISPR knockout screen targeting Theileria-infected cells to pinpoint shared vulnerabilities. We identify key host metabolic enzymes critical for the intracellular survival of both of these lethal hemoparasites. Remarkably, among the metabolic proteins identified by our synergistic approach, we find that host purine and heme biosynthetic enzymes are essential for the intracellular survival of P. falciparum and Theileria, while other host enzymes are only essential under certain metabolic conditions, highlighting P. falciparum's adaptability and ability to scavenge nutrients selectively. Unexpectedly, host porphyrins emerge as being essential for both parasites. The shared vulnerabilities open new avenues for developing more effective therapies against these debilitating diseases, with the potential for broader applicability in combating apicomplexan infections.
Keyphrases
- plasmodium falciparum
- genome wide
- single cell
- global health
- dna methylation
- crispr cas
- genome editing
- endothelial cells
- stem cells
- risk assessment
- reactive oxygen species
- minimally invasive
- physical activity
- induced apoptosis
- heavy metals
- cell proliferation
- cancer therapy
- high throughput
- cell death
- signaling pathway
- drug delivery
- mesenchymal stem cells
- copy number
- free survival
- cell therapy