Clinical malaria is associated with proliferation of blood-stage parasites. During the blood stage, Plasmodium parasites invade host red blood cells, multiply, egress and reinvade uninfected red blood cells to continue the life cycle. Here we demonstrate that calcium-dependent permeabilization of host red blood cells is critical for egress of Plasmodium falciparum merozoites. Although perforin-like proteins have been predicted to mediate membrane perforation during egress, the expression, activity and mechanism of action of these proteins have not been demonstrated. Here, we show that two perforin-like proteins, perforin-like protein 1 and perforin-like protein 2, are expressed in the blood stage. Perforin-like protein 1 localizes to the red blood cell membrane and parasitophorous vacuolar membrane in mature schizonts following its Ca 2 þ -dependent discharge from micronemes. Furthermore, perforin-like protein 1 shows Ca 2 þ -dependent permeabilization and membranolytic activities suggesting that it may be one of the effector proteins that mediate Ca 2 þ -dependent membrane perforation during egress.
SummaryEgress of Plasmodium falciparum merozoites from host erythrocytes is a critical step in multiplication of blood-stage parasites. A cascade of proteolytic events plays a major role in degradation of membranes leading to egress of merozoites. However, the signals that regulate the temporal activation and/or secretion of proteases upon maturation of merozoites in intra-erythrocytic schizonts remain unclear. Here, we have tested the role of intracellular Ca 2+ in regulation of egress of P. falciparum merozoites from schizonts. A sharp rise in intracellular Ca 2+ just before egress, observed by timelapse video microscopy, suggested a role for intracellular Ca 2+ in this process. Chelation of intracellular Ca 2+ with chelators such as BAPTA-AM or inhibition of Ca 2+ release from intracellular stores with a phospholipase C (PLC) inhibitor blocks merozoite egress. Interestingly, chelation of intracellular Ca 2+ in schizonts was also found to block the discharge of a key protease PfSUB1 (subtilisin-like protease 1) from exonemes of P. falciparum merozoites to parasitophorous vacuole (PV). This leads to inhibition of processing of PfSERA5 (serine repeat antigen 5) and a block in parasitophorous vacuolar membrane (PVM) rupture and merozoite egress. A complete understanding of the steps regulating egress of P. falciparum merozoites may provide novel targets for development of drugs that block egress and limit parasite growth.
The human malaria parasite proliferates in red blood cells following repeated cycles of invasion, multiplication, and egress. serine repeat antigen 5 (PfSERA5), a putative serine protease, plays an important role in merozoite egress. However, regulation of its activity leading to merozoite egress is poorly understood. In this study, we show that PfSERA5 undergoes phosphorylation prior to merozoite egress. Immunoprecipitation of parasite lysates using anti-PfSERA5 serum followed by MS analysis identified calcium-dependent protein kinase 1 (PfCDPK1) as an interacting kinase. Association of PfSERA5 with PfCDPK1 was corroborated by co-sedimentation, co-immunoprecipitation, and co-immunolocalization analyses. Interestingly, PfCDPK1 phosphorylated PfSERA5 in the presence of Ca and enhanced its proteolytic activity. A PfCDPK1 inhibitor, purfalcamine, blocked the phosphorylation and activation of PfSERA5 both as well as in schizonts, which, in turn, blocked merozoite egress. Together, these results suggest that phosphorylation of PfSERA5 by PfCDPK1 following a rise in cytosolic Ca levels activates its proteolytic activity to trigger merozoite egress.
HSP100 protein is an important component of the heat-shock response in diverse organisms. Using specific primers based on cDNA sequence, rice hsp101 gene was PCR-amplified and sequenced. Southern analysis revealed that there appears to be a single gene per haploid genome coding for HSP101 protein in rice. Northern analysis showed that expression of hsp101 transcript is strictly heat-inducible and induction is transient in nature. In the temperature regime tested, 45 degrees C treatment to intact rice seedlings for 2 h showed maximal levels of hsp101 mRNA. Rice full-length hsp101 cDNA complemented yeast mutant disrupted for its own hsp104 gene by insertional mutagenesis, with efficacy that was comparable with Arabidopsis hsp101 cDNA. Electron micrographic evidence suggested that rice hsp101 cDNA in yeast is active in re-solubilizing the stress-induced protein granules in the post-stress recovery period. Rice hsp101 cDNA expression in hsp104 deficient yeast also caused recovery in tolerance against arsenite. Western analyses showed that this protein is expressed more rapidly during the stress period and retained for longer duration in the post-stress recovery period in japonica rice as compared to indica rice types. This is the first report wherein plant HSP100 protein expression is correlated to disappearance of protein granules in the yeast cells and distinct rice type-dependent protein expression patterns are reported.
It appears that cellular functions such as signalling, sugar and ion transport and transcript stability play an important role in conferring higher flooding tolerance in the FR13A rice type.
Natural products offer an abundant source of diverse novel scaffolds that inspires development of next generation anti-malarials. With this vision, a library of scaffolds inspired by natural biologically active alkaloids was synthesized from chiral bicyclic lactams with steps/scaffold ratio of 1.7:1. On evaluation of library of scaffolds for their growth inhibitory effect against malaria parasite we found one scaffold with IC50 in low micro molar range. It inhibited parasite growth via disruption of Na+ homeostasis. P-type ATPase, PfATP4 is responsible for maintaining parasite Na+ homeostasis and is a good target for anti-malarials. Molecular docking with our scaffold showed that it fits well in the binding pocket of PfATP4. Moreover, inhibition of Na+-dependent ATPase activity by our potent scaffold suggests that it targets parasite by inhibiting PfATP4, leading to ionic imbalance. However how ionic imbalance attributes to parasite’s death is unclear. We show that ionic imbalance caused by scaffold 7 induces autophagy that leads to onset of apoptosis in the parasite evident by the loss of mitochondrial membrane potential (ΔΨm) and DNA degradation. Our study provides a novel strategy for drug discovery and an insight into the molecular mechanism of ionic imbalance mediated death in malaria parasite.
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