The human malaria parasite, Plasmodium falciparum possesses unique gliding machinery referred to as the glideosome that powers its entry into the insect and vertebrate hosts. Several parasite proteins including Photosensitized INA-labelled protein 1 (PhIL1) have been shown to associate with glideosome machinery. Here we describe a novel PhIL1 associated protein complex that co-exists with the glideosome motor complex in the inner membrane complex of the merozoite. Using an experimental genetics approach, we characterized the role(s) of three proteins associated with PhIL1: a glideosome associated protein- PfGAPM2, an IMC structural protein- PfALV5, and an uncharacterized protein—referred here as PfPhIP (PhIL1 Interacting Protein). Parasites lacking PfPhIP or PfGAPM2 were unable to invade host RBCs. Additionally, the downregulation of PfPhIP resulted in significant defects in merozoite segmentation. Furthermore, the PfPhIP and PfGAPM2 depleted parasites showed abrogation of reorientation/gliding. However, initial attachment with host RBCs was not affected in these parasites. Together, the data presented here show that proteins of the PhIL1-associated complex play an important role in the orientation of P. falciparum merozoites following initial attachment, which is crucial for the formation of a tight junction and hence invasion of host erythrocytes.
Reduced sensitivity of the human malaria parasite, Plasmodium falciparum, to Artemisinin and its derivatives (ARTs) threatens the global efforts towards eliminating malaria. ARTs have been shown to cause ubiquitous cellular and genetic insults, which results in the activation of the unfolded protein response (UPR) pathways. The UPR restores protein homeostasis, which otherwise would be toxic to cellular survival. Here, we interrogated the role of DNA-damage inducible protein 1 (PfDdi1), a unique proteasome-interacting retropepsin in mediating the actions of the ARTs. We demonstrate that PfDdi1 is an active A2 family protease that hydrolyzes ubiquitinated proteasome substrates. Treatment of P. falciparum parasites with ARTs leads to the accumulation of ubiquitinated proteins in the parasites and blocks the destruction of ubiquitinated proteins by inhibiting the PfDdi1 protease activity. Besides, whereas the PfDdi1 is predominantly localized in the cytoplasm, exposure of the parasites to ARTs leads to DNA fragmentation and increased recruitment of the PfDdi1 into the nucleus. Furthermore, we show that Ddi1 knock-out Saccharomycescerevisiae cells are more susceptible to ARTs and the PfDdI1 protein robustly restores the corresponding functions in the knock-out cells. Together, these results show that ARTs act in multiple ways; by inducing DNA and protein damage and might be impairing the damage recovery by inhibiting the activity of PfDdi1, an essential ubiquitin-proteasome retropepsin.
The human malaria parasite, Plasmodium falciparum possess a unique mechanism of gliding motility guided by glideosome that powers its entry into insect and vertebrate hosts to facilitate its invasion and internalization within the targeted host cell. Photosensitized INA-labelled protein 1 (PhIL1) forms a novel protein complex that is associated with glideosome motor complex in the inner membrane complex of invasive merozoite. To establish the role of PfPhIL1 associated novel complex at asexual blood stages, we characterized three proteins associated with PhIL1: a glideosome associated protein- PfGAPM2, an IMC structural protein- PfALV5 and a previously uncharacterised protein - referred here as PfPhIP (PhIL1 interacting protein). GFP targeting and co-immunoprecipitation analysis confirmed that these proteins are part of a PhIL1 associated novel complex, which co-exists with the glideosomal complex. To know the functional significance of PhIL1 associated complex, transgenic parasites were generated for glmS mediated conditional knock-down of each of the three proteins. Parasites lacking PfPhIP or PfGAPM2 were unable to invade the RBCs. PfPhIP deficient parasites also showed defects in merozoite segmentation. PfPhIP and PfGAPM2 depleted parasites revealed abrogation of reorientation/gliding, although initial attachment with human RBCs was not affected in these knock-down parasites. Together, the data presented here shows that proteins of the PhIL1 associated complex play an important role in orientation of P. falciparum merozoites post initial attachment, which is crucial for formation of tight junction and hence invasion of host erythrocytes.
The human malaria parasite, Plasmodium falciparum possess a unique gliding machinery referred as glideosome that powers its entry into the insect and vertebrate hosts. A number of parasite proteins including Photosensitized INA-labelled protein 1 (PhIL1) have been shown to associate with glideosome machinery. Here we describe a novel PhIL1 associated protein complex that co-exists with glideosome motor complex in the inner membrane complex of the merozoite. Furthermore, using experimental genetics approach we characterized the role(s) of three proteins associated with PhIL1: a glideosome associated protein- PfGAPM2, an IMC structural protein- PfALV5 and a previously uncharacterised protein - referred here as PfPhIP (PhIL1 Interacting Protein). Parasites lacking PfPhIP or PfGAPM2 were unable to invade the host RBCs. Additionally, the down regulation of PfPhIP resulted in significant defects in merozoite segmentation. Furthermore, the PfPhIP and PfGAPM2 depleted parasites revealed abrogation of reorientation/gliding, however initial attachment with host RBCs was not affected in these parasites. Together, the data presented here shows that proteins of the PhIL1 associated complex plays an important role in orientation of P. falciparum merozoites following initial attachment, which is crucial for formation of tight junction and hence invasion of host erythrocytes. The identification and characterization of PhIL1 associated complex opens new avenues for future anti-malarial drug development.
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