Structure of the Plasmodium-interspersed repeat proteins of the malaria parasite.

The deadly symptoms of malaria occur as Plasmodium parasites replicate within blood cells. Members of several variant surface protein families are expressed on infected blood cell surfaces. Of these, the largest and most ubiquitous are the Plasmodium-interspersed repeat (PIR) proteins, with more than 1,000 variants in some genomes. Their functions are mysterious, but differential pir gene expression associates with acute or chronic infection in a mouse malaria model. The membership of the PIR superfamily, and whether the family includes Plasmodium falciparum variant surface proteins, such as RIFINs and STEVORs, is controversial. Here we reveal the structure of the extracellular domain of a PIR from Plasmodium chabaudi We use structure-guided sequence analysis and molecular modeling to show that this fold is found across PIR proteins from mouse- and human-infective malaria parasites. Moreover, we show that RIFINs and STEVORs are not PIRs. This study provides a structure-guided definition of the PIRs and a molecular framework to understand their evolution.

Mesangial proliferative glomerulonephritis in murine malaria parasite, Plasmodium chabaudi AS, infected NC mice.

BACKGROUND: Malaria is an important tropical disease and has remained a serious health problem in many countries. One of the critical complications of malarial infection is renal injury, such as acute renal failure and chronic glomerulopathy. Few animal models of nephropathy related to malarial infection have been reported. Therefore, we developed and investigated a novel malarial nephropathy model in mice infected by murine malaria parasites. METHODS: NC mice and C57BL/6J mice were infected with Ttwo different murine malaria parasites, Plasmodium (P.) chabaudi AS and P. yoelii 17X. After the infection, renal pathology and blood and urinary biochemistry were analyzed. RESULTS: NC mice infected by the murine malaria parasite P. chabaudi AS, but not P. yoelii 17X, developed mesangial proliferative glomerulonephritis with endothelial damage, and decreased serum albumin concentration and increased proteinuria. These pathological changes were accompanied by deposition of immunoglobulin G and complement component 3, mainly in the mesangium until day 4 and in the mesangium and glomerular capillaries from day 8. On day 21, renal pathology developed to focal segmental sclerosis according to light microscopy. In C57BL/6J mice, renal injuries were not observed from either parasite infection. CONCLUSION: The clinical and pathological features of P. chabaudi AS infection in NC mice might be similar to quartan malarial nephropathy resulting from human malaria parasite P. malariae infection. The NC mouse model might therefore be useful in analyzing the underlying mechanisms and developing therapeutic approaches to malaria-related nephropathy.

Electron tomography characterization of hemoglobin uptake in Plasmodium chabaudi reveals a stage-dependent mechanism for food vacuole morphogenesis.

In the course of their intraerythrocytic development, malaria parasites incorporate and degrade massive amounts of the host cell cytoplasm. This mechanism is essential for parasite development and represents a physiological step used as target for many antimalarial drugs; nevertheless, the fine mechanisms underlying these processes in Plasmodium species are still under discussion. Here, we studied the events of hemoglobin uptake and hemozoin nucleation in the different stages of the intraerythrocytic cycle of the murine malaria parasite Plasmodium chabaudi using transmission electron tomography of cryofixed and freeze-substituted cells. The results showed that hemoglobin uptake in P. chabaudi starts at the early ring stage and is present in all developmental stages, including the schizont stage. Hemozoin nucleation occurs near the membrane of small food vacuoles. At the trophozoite stage, food vacuoles are found closely localized to cytostomal tubes and mitochondria, whereas in the schizont stage, we observed a large food vacuole located in the central portion of the parasite. Taken together, these results provide new insights into the mechanisms of hemoglobin uptake and degradation in rodent malaria parasites.

Rapid transport of the acidic phosphoproteins of Plasmodium berghei and P. chabaudi from the intraerythrocytic parasite to the host membrane using a miniaturized fractionation procedure.

A miniaturized procedure for the separation of the host erythrocyte membrane from malarial parasites based on saponin lysis and density-gradient centrifugation with Percoll is described. The procedure requires only 20-35 microliters packed infected erythrocytes, is simple to perform, needs no sophisticated equipment, and can be completed in less than 2 h. Analysis of the isolated erythrocyte membranes and parasites using marker enzymes and electron microscopy revealed that both the purity and the yield of these fractions were relatively high. Erythrocyte membrane proteins, including spectrin, ankyrin, and band 4.1, were not found on the parasitophorous vacuolar membrane, which remained associated with some but not all of the isolated parasites. Application of this method to pulse-chase experiments indicated that the acidic phosphoproteins of Plasmodium berghei and P. chabaudi were rapidly transported from the parasite to the erythrocyte membrane immediately after their synthesis. The rapid export of these acidic phosphoproteins from the parasite distinguishes them from other proteins exported by the malarial parasite.

Characterization of Ca2+ transport activity associated with a non-mitochondrial calcium pool in the rodent malaria parasite P. chabaudi.

Non-mitochondrial calcium deposits were investigated in the intraerythrocytic malaria parasite Plasmodium chabaudi at the trophozoite stage by means of arsenazo III in the presence of ATP and the mitochondrial poisons, antimycin and oligomycin. Addition of vanadate and 2,5-di-(t-butyl)-1,4-hydroquinone (BHQ), both known to interact with SERCA pump, induced calcium release by permeabilized parasites when the medium free calcium concentration was kept at 3.5 microM. The tumor promoter thapsigargin also caused elevation of the free calcium concentration in permeabilized parasites. Our results support the view that P. chabaudi sequesters calcium in an exchangeable form and maintains its calcium homeostasis by way of an endoplasmic reticulum Ca2+ pump.

Isolation of merozoite rhoptries, identification of novel rhoptry-associated proteins from Plasmodium yoelii, P. chabaudi, P. berghei, and conserved interspecies reactivity of organelles and proteins with P. falciparum rhoptry-specific antibodies.

Rhoptries were isolated from merozoites of P. yoelii (17 XL), P. chabaudi adami and P. berghei (K-173), using sucrose gradient density centrifugation. Mouse antisera was prepared against the organelles and characterized. Antibodies specific for a known P. yoelii rhoptry protein were used to identify gradient fractions containing rhoptries and electron microscopy was used to confirm rhoptry enrichment and organelle morphology. Western blotting analysis of the gradients with organelle-specific antisera from each species, revealed several major cross-reactive interspecies protein bands of approximately 235, 210, 180, 160/170, 140, and 96-110 kDa, predominantly in densities of 1.12 and 1.15 g/ml. The parasite origin of the proteins was verified by immunoprecipitation, and reactive epitopes localized to the rhoptries by IEM. By Western blotting antisera specific for P. falciparum rhoptries reacted with protein bands of approximately 96-110 kDa in schizont extracts, and gradient fractions of density 1.12 and 1.15 g/ml from all three rodent malaria species, as well as with the rhoptries in P. yoelii, P. chabaudi, and P. berghei merozoites by IEM. We conclude that the three rodent malaria species and P. falciparum share conserved interspecies epitopes.

Ultrastructural changes associated with reversal of chloroquine resistance by verapamil in Plasmodium chabaudi.

Reversal of chloroquine (CQ) resistance by verapamil, a Ca2+ antagonist, has been shown in CQ-resistant human and rodent malaria parasites. Here, we report ultrastructural changes associated with this phenomenon in CQ-resistant Plasmodium chabaudi (AS strain) after infected mice were administered CQ and verapamil. At parasitaemias of 5-7%, CQ at 6 mg/kg caused little morphological effect on CQ-resistant parasites. In contrast, co-administration of CQ and verapamil at 50 mg/kg induced swelling of food vacuoles with clumped pigment at 2.5 h. Morphological changes other than food vacuole enlargement occurred at 21 and 45 h: disappearance of endoplasmic reticulum, formation of myelin structures, focal cytoplasmic vacuolization and coarse clumping of electron-dense material in nuclei. These structural changes appeared to be very similar to those observed in CQ-sensitive P. chabaudi in mice injected with CQ alone or CQ plus verapamil. On the other hand, verapamil at 50 mg/kg alone did not induce any effect on both CQ-sensitive and CQ-resistant P. chabaudi. These results suggest that swelling of the food vacuoles is an initial event associated with reversal of CQ-resistance by verapamil.