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ItemCharacterisation of the Plasmodium aspartyl proteases DNA-damage inducible protein 1 (DDI1) and Plasmepsin VII (PMVII)( 2019)Plasmodium falciparum resistance to artemisinin-(ART) based combination therapies (ACTs) and other antimalarials poses a major threat to malaria control and elimination. Current efforts are aimed towards identifying potent antimalarials which inhibit multiple stages of the parasite lifecycle or discovering novel drug targets which may help overcome ART-resistance. This work aimed to characterise two aspartyl proteases of P. falciparum which may hold promise as antimalarial targets. One strategy recently proposed to overcome ART-resistance is the synergistic use of a parasite-selective proteasome inhibitor to sensitise ART-resistant parasites to artemisinin. Therefore, development of an inhibitor targeting a parasite-specific protein involved in the P. falciparum ubiquitin-proteasome system (UPS) could yield a combination therapy to tackle ART-resistance. DNA-damage inducible protein 1 (DDI1) is a previously uncharacterised essential aspartyl protease in P. falciparum. Recent studies have shown that the catalytic domain of human DDI2 upregulates the UPS in mammalian cells. In other organisms, DDI1 plays a role in shuttling proteins to the proteasome for degradation via its ubiquitin-like domain. We hypothesise PfDDI1 is an active aspartyl protease and plays a role in the parasite’s UPS. To investigate the role of DDI1 in the UPS and parasite survival, we identified a DDI1 orthologue in P. falciparum and characterised this using several strategies. We utilised CRISPR-Cas9 to knock out, tag and inducibly knock down DDI1 across the asexual lifecycle of P. falciparum, and study the effect of this on parasites. Expression of recombinant DDI1 proteins provided insight into the protease activity and substrate repertoire of PfDDI1. Together these studies provide insight into the domain architecture, essentiality and function of PfDDI1 and clues into its potential as an antimalarial target. Development of an antimalarial to block parasite transmission between humans and mosquitos is also a viable strategy to reduce malaria burden. In this study, we also explore a potential transmission-blocking target, Plasmepsin VII (PMVII) and create tools to enable further study of this aspartyl protease in sexually reproductive gametocytes. These tools are vital to determine the function and substrate repertoire of PMVII and elucidate its potential as an antimalarial target.