Plasmodium DDI1 is a potential therapeutic target and important chromatin-associated protein.

DNA damage inducible 1 protein (DDI1) is involved in a variety of cellular processes including proteasomal degradation of specific proteins. All DDI1 proteins contain a ubiquitin-like (UBL) domain and a retroviral protease (RVP) domain. Some DDI1 proteins also contain a ubiquitin-associated (UBA) domain. The three domains confer distinct activities to DDI1 proteins. The presence of a RVP domain makes DDI1 a potential target of HIV protease inhibitors, which also block the development of malaria parasites. Hence, we investigated the DDI1 of malaria parasites to identify its roles during parasite development and potential as a therapeutic target. DDI1 proteins of Plasmodium and other apicomplexan parasites share the UBL-RVP domain architecture, and some also contain the UBA domain. Plasmodium DDI1 is expressed across all the major life cycle stages and is important for parasite survival, as conditional depletion of DDI1 protein in the mouse malaria parasite Plasmodium berghei and the human malaria parasite Plasmodium falciparum compromised parasite development. Infection of mice with DDI1 knock-down P. berghei was self-limiting and protected the recovered mice from subsequent infection with homologous as well as heterologous parasites, indicating the potential of DDI1 knock-down parasites as a whole organism vaccine. Plasmodium falciparum DDI1 (PfDDI1) is associated with chromatin and DNA-protein crosslinks. PfDDI1-depleted parasites accumulated DNA-protein crosslinks and showed enhanced susceptibility to DNA-damaging chemicals, indicating a role of PfDDI1 in removal of DNA-protein crosslinks. Knock-down of PfDDI1 increased susceptibility to the retroviral protease inhibitor lopinavir and antimalarial artemisinin, which suggests that simultaneous inhibition of DDI1 could potentiate antimalarial activity of these drugs. As DDI1 knock-down parasites confer protective immunity and it could be a target of HIV protease inhibitors, Plasmodium DDI1 is a potential therapeutic target for malaria control.

Dissecting Plasmodium yoelii Pathobiology: Proteomic Approaches for Decoding Novel Translational and Post-Translational Modifications.

Malaria is a vector-borne disease. It is caused by Plasmodium parasites. Plasmodium yoelii is a rodent model parasite, primarily used for studying parasite development in liver cells and vectors. To better understand parasite biology, we carried out a high-throughput-based proteomic analysis of P. yoelii. From the same mass spectrometry (MS)/MS data set, we also captured several post-translational modified peptides by following a bioinformatics analysis without any prior enrichment. Further, we carried out a proteogenomic analysis, which resulted in improvements to some of the existing gene models along with the identification of several novel genes. Analysis of proteome and post-translational modifications (PTMs) together resulted in the identification of 3124 proteins. The identified PTMs were found to be enriched in mitochondrial metabolic pathways. Subsequent bioinformatics analysis provided an insight into proteins associated with metabolic regulatory mechanisms. Among these, the tricarboxylic acid (TCA) cycle and the isoprenoid synthesis pathway are found to be essential for parasite survival and drug resistance. The proteogenomic analysis discovered 43 novel protein-coding genes. The availability of an in-depth proteomic landscape of a malaria pathogen model will likely facilitate further molecular-level investigations on pre-erythrocytic stages of malaria.

Independent amino acid residues in the S2 pocket of falcipain-3 determine its specificity for P2 residues in substrates.

Falcipain-3 (FP3) is an essential and drug target cysteine protease of the most lethal human malaria parasite Plasmodium falciparum. FP3 and its majority of homologs in malaria parasites prefer Leu at the P2 position in substrates and inhibitors, whereas its major host homolog cathepsin L prefers Phe. However, FP3 is much less active on peptide substrates and has negligible activity against a P2 Arg-containing substrate (Z-RR-AMC) compared to its paralog falcipain-2A (FP2A). To identify the specificity determinants, the S2/3 pocket residues of FP3 were substituted with the corresponding residues in FP2 or cathepsin L, and the wild type and mutant proteases were assessed for hydrolysis of peptide and protein substrates. Our results indicate that the S2 pocket residues I94 and P181 of FP3 are chiefly responsible for its P2 Leu preference and negligible activity for Z-RR-AMC, respectively. E243 in FP3 and the corresponding residue D234 in FP2 have a key role in Z-RR-AMC hydrolysing activity, possibly through stabilization of side chain interactions, as their substitution with Ala abolished the activity. Several FP3 mutants, which retained P2 Leu preference and showed similar or more activity than wild type FP3 on peptide substrates, degraded haemoglobin less efficiently than wild type FP3, suggesting that multiple residues contribute to haemoglobinase activity. Furthermore, P181 and E243 appear to contribute to the optimum activity of FP3 in the food vacuole milieu (≈pH 5.5). The identification of residues determining specificity of FP3 could aid in developing specific inhibitors of FP3 and its homologs in malaria parasites.