Vancomycin improves Plasmodium yoelii malaria parasite in vitro liver stage cultures by controlling Elizabethkingia anophelis, a bacterium in the microbiome of lab-reared Anopheles mosquitoes.

Studies of Plasmodium sporozoites and liver stages require dissection of Anopheles mosquitoes to obtain sporozoites for experiments. Sporozoites from the rodent parasite P. yoelii are routinely used to infect hepatocytes for liver stage culture, but sometimes these cultures become contaminated. Using standard microbiological techniques, a single colony type of Gram-negative rod-shaped bacteria was isolated from contaminated cultures. Mass spectrometry and sequencing of the bacterial 16S ribosomal RNA gene identified the contaminant as Elizabethkingia spp. Based on sequence comparison and published studies of the Anopheles microbiome, the best match was E. anophelis. Culture contamination was not ameliorated by density gradient purification of sporozoites. However, the addition of vancomycin to the culture media consistently reduced contamination and improved culture outcomes as measured by liver stage parasite size. Thus, mosquito salivary gland-derived E. anophelis is identified a potential contaminant of Plasmodium liver stage cultures that can be mitigated by the addition of antibiotics.

Observation of morphological changes of female osmiophilic bodies prior to Plasmodium gametocyte egress from erythrocytes.

Plasmodium parasites cause malaria in mammalian hosts and are transmitted by Anopheles mosquitoes. Gametocytes, which differentiate from asexual-stage parasites, are activated by environmental changes when ingested into the mosquito midgut, and are rapidly released from erythrocytes prior to fertilization. Secretory proteins localized to osmiophilic bodies (OBs), organelles unique to gametocytes, have been reported to be involved in female gametocyte egress. In this study, we investigate the dynamics of OBs in activated gametocytes of Plasmodium falciparum and Plasmodium yoelii using the female OB-specific marker protein, G377. After activation, female gametocyte OBs migrate to the parasite surface and fuse to form large vesicles beneath the parasite plasma membrane. At the marginal region of female gametocytes, fused vesicles secrete contents by exocytosis into the parasitophorous vacuole space, prior to parasite egress via the break-down of the erythrocyte membrane. This is the first detailed description of how proteins are transported through osmiophilic bodies.

Polychromatic polarization microscope: bringing colors to a colorless world.

Interference of two combined white light beams produces Newton colors if one of the beams is retarded relative to the other by from 400 nm to 2000 nm. In this case the corresponding interfering spectral components are added as two scalars at the beam combination. If the retardance is below 400 nm the two-beam interference produces grey shades only. The interference colors are widely used for analyzing birefringent samples in mineralogy. However, many of biological structures have retardance <100 nm. Therefore, cells and tissues under a regular polarization microscope are seen as grey image, which contrast disappears at certain orientations. Here we are proposing for the first time using vector interference of polarized light in which the full spectrum colors are created at retardance of several nanometers, with the hue determined by orientation of the birefringent structure. The previously colorless birefringent images of organelles, cells, and tissues become vividly colored. This approach can open up new possibilities for the study of biological specimens with weak birefringent structures, diagnosing various diseases, imaging low birefringent crystals, and creating new methods for controlling colors of the light beam.

Malaria Sporozoites Traverse Host Cells within Transient Vacuoles.

Plasmodium sporozoites are deposited in the host skin by Anopheles mosquitoes. The parasites migrate from the dermis to the liver, where they invade hepatocytes through a moving junction (MJ) to form a replicative parasitophorous vacuole (PV). Malaria sporozoites need to traverse cells during progression through host tissues, a process requiring parasite perforin-like protein 1 (PLP1). We find that sporozoites traverse cells inside transient vacuoles that precede PV formation. Sporozoites initially invade cells inside transient vacuoles by an active MJ-independent process that does not require vacuole membrane remodeling or release of parasite secretory organelles typically involved in invasion. Sporozoites use pH sensing and PLP1 to exit these vacuoles and avoid degradation by host lysosomes. Next, parasites enter the MJ-dependent PV, which has a different membrane composition, precluding lysosome fusion. The malaria parasite has thus evolved different strategies to evade host cell defense and establish an intracellular niche for replication.

Plasmodium yoelii: novel rhoptry proteins identified within the body of merozoite rhoptries in rodent Plasmodium malaria.

The biogenesis, organization and function of the rhoptries are not well understood. Antisera were prepared to synthetic peptides prepared as multiple antigenic peptides (MAPs) obtained from a Plasmodium yoelii merozoite rhoptry proteome analysis. The antisera were used in immunofluorescence and immunoelectron microscopy of schizont-infected erythrocytes. Twenty-seven novel rhoptry proteins representing proteases, metabolic enzymes, secreted proteins and hypothetical proteins, were identified in the body of the rhoptries by immunoelectron microscopy. The merozoite rhoptries contain a heterogeneous mixture of proteins that may initiate host cell invasion and establish intracellular parasite development.

Plasmodium yoelii: contribution of oocysts melanization to natural refractoriness in Anopheles dirus.

It is well known that Anopheles dirus is naturally refractory to rodent malaria parasite, Plasmodium yoelii, but the mechanism is still largely unknown. Here, we found that some P. yoelii taken into An. dirus could develop into oocysts, but oocysts were partially melanized at 7 days and completely melanized at 15 days post-infectious blood meal. Transmission electronic microscopy could find the melanized P. yoelii oocysts in An. dirus as early as 5 days post-infection, with a few haemocytes attaching to the melanized oocysts, indicating a typical humoral melanization reaction. Although the change of protein pattern at 24h post-infection suggested that other unknown mechanisms and/or factors might be involved in killing ookinetes, our data implied that oocysts melanization was one of the mechanisms of An. dirus to block P. yoelii development. In addition, activity of phenoloxidase, such as monophenol oxidase and o-diphenoloxidase, in haemolymph of An. dirus fed on infectious blood meal was much higher than that of mosquitoes fed on 5% glucose or normal mouse blood (p<0.05), implying the possible role of PO in oocysts melanization by An. dirus.

[Immunity of peritoneal monocytes against Plasmodium yoelii infected erythrocytes].

OBJECTIVE: To test the immunity of peritoneal monocytes against Plasmodium yoelii infected red blood cells (target cells). METHODS: Saponinized Plasmodium yoelii infected red blood cells (SPRBC, Ghost erythrocyte) were used to immunize mice i.p twice. Three weeks later, the infected red blood cells were injected i.p.; 90 min later, the total peritoneal cells were isolated and washed for scanning electromicroscopy to observe the effects of the peritoneal monocyte to the target cell. RESULTS: The peritoneal cells of the immunized mice were activated after 90 min of the challenge of target cells. The size of the cell was not even and the pili on the cell surface turned to be long and densed. Cell interconnections were found among the cells. In some peritoneal monocytes, their cell plasma were scattered (omlette-like) or with the shape as "cellular bomb". The scattered or the sheeted pili and spredding cell plasma could adhere to the target cells which were perforated densely and damaged. CONCLUSION: The protective adaptive immunity exists in the peritoneal monocytes of immunized mice.

[Morphological characteristics of Plasmodium yoelii schizonts in ghost erythrocytes].

OBJECTIVE: To observe the morphological characteristics of Plasmodium yoelii schizogony in their ghost erythrocytes. METHODS: Saponify, hypotonic shock, and electron microscopy were used to observe the different fashions of erythrocytic parasites and their characteristic organellae in ghost erythrocytes. RESULTS: The malarial parasites and their fine structures were dramatically well preserved in the ghost erythrocytes, such as the ring-like early trophozoites, the brassiere-like early schizonts, the emerging buds on the surface of late schizonts, and the grape-cluster like late schizonts. The cytostome, food vacuole, and crystallized malarial pigments were found in the early trophozoites. The proliferations of nucleoplasma and nuclear membrane as well as and the clot-like nuclear division were followed by the budding during the schizogony. CONCLUSION: The saponify technique that makes the erythrocytic malaria parasites and their fine organellae to be dramatically revealed in their ghost erythrocytes, may be a useful method in the Plasmodium biological research and anti-malaria immunological researches.

A member of a conserved Plasmodium protein family with membrane-attack complex/perforin (MACPF)-like domains localizes to the micronemes of sporozoites.

Pore-forming proteins are employed by many pathogens to achieve successful host colonization. Intracellular pathogens use pore-forming proteins to invade host cells, survive within and productively interact with host cells, and finally egress from host cells to infect new ones. The malaria-causing parasites of the genus Plasmodium evolved a number of life cycle stages that enter and replicate in distinct cell types within the mosquito vector and vertebrate host. Despite the fact that interaction with host-cell membranes is a central theme in the Plasmodium life cycle, little is known about parasite proteins that mediate such interactions. We identified a family of five related genes in the genome of the rodent malaria parasite Plasmodium yoelii encoding secreted proteins all bearing a single membrane-attack complex/perforin (MACPF)-like domain. Each protein is highly conserved among Plasmodium species. Gene expression analysis in P. yoelii and the human malaria parasite Plasmodium falciparum indicated that the family is not expressed in the parasites blood stages. However, one of the genes was significantly expressed in P. yoelii sporozoites, the stage transmitted by mosquito bite. The protein localized to the micronemes of sporozoites, organelles of the secretory invasion apparatus intimately involved in host-cell infection. MACPF-like proteins may play important roles in parasite interactions with the mosquito vector and transmission to the vertebrate host.

Myosin A tail domain interacting protein (MTIP) localizes to the inner membrane complex of Plasmodium sporozoites.

Apicomplexan host cell invasion and gliding motility depend on the parasite's actomyosin system located beneath the plasma membrane of invasive stages. Myosin A (MyoA), a class XIV unconventional myosin, is the motor protein. A model has been proposed to explain how the actomyosin motor operates but little is known about the components, topology and connectivity of the motor complex. Using the MyoA neck and tail domain as bait in a yeast two-hybrid screen we identified MTIP, a novel 24 kDa protein that interacts with MyoA. Deletion analysis shows that the 15 amino-acid C-terminal tail domain of MyoA, rather than the neck domain, specifically interacts with MTIP. In Plasmodium sporozoites MTIP localizes to the inner membrane complex (IMC), where it is found clustered with MyoA. The data support a model for apicomplexan motility and invasion in which the MyoA motor protein is associated via its tail domain with MTIP, immobilizing it at the outer IMC membrane. The head domain of the immobilized MyoA moves actin filaments that, directly or via a bridging protein, connect to the cytoplasmic domain of a transmembrane protein of the TRAP family. The actin/TRAP complex is then redistributed by the stationary MyoA from the anterior to the posterior end of the zoite, leading to its forward movement on a substrate or to penetration of a host cell.

Malaria sporozoites actively enter and pass through rat Kupffer cells prior to hepatocyte invasion.

Malaria sporozoites have to cross the layer of sinusoidal liver cells to reach their initial site of multiplication in the mammalian host, the hepatocytes. To determine the sinusoidal cell type sporozoites use for extravasation, endothelia or Kupffer cells, we quantified sporozoite adhesion to and invasion of sinusoidal cells isolated from rat liver. In vitro invasion assays reveal that Plasmodium berghei and P. yoelii sporozoites attach to and enter Kupffer cells, but not sinusoidal endothelia. Unlike hepatocytes and other nonphagocytic cells, which are invaded in vitro only within the first hour of parasite exposure, the number of intracellular sporozoites in Kupffer cells increases for up to 12 hours. By confocal and electron microscopy, sporozoites are enclosed in a vacuole that does not colocalize with lysosomal markers. Inhibition of phagocytosis with gadolinium chloride has no effect on Kupffer cell invasion, but abolishes phagocytosis of inactivated sporozoites. Furthermore, sporozoites traverse in vitro from Kupffer cells to hepatocytes where they eventually develop into exoerythrocytic schizonts. Thus, malaria sporozoites selectively recognize and actively invade Kupffer cells, avoid phagosomal acidification, and safely passage through these phagocytes.

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.

Effects of nitroquine on ultrastructures and cytochrome oxidase of exoerythrocytic Plasmodium yoelii in rat liver.

AIM: To study the effects of nitroquine acetate (NA) on the ultrastructures and cytochrome-c oxidase (CCO) of exoerythrocytic forms (EEF) of Plasmodium yoelii. METHODS: Rats were inoculated with sporozoites directly into the liver. After 48 h rats were killed. Rat liver thin sections were incubated in histochemical reaction medium, then examined by transmission electron microscopy. NA (2 mg.kg-1) was fed to rats 3.5 h and 14 h before killing the rats. RESULTS: At 3.5 h, in the parasites there appeared swelling and proliferation of mitochondria, dilation of endoplasmic reticulum, and reduction of the electron density of parasites' nuclei. The structures of the parasites disintegrated to form many autophagocytes 14 h after exposure to NA. The reaction products of CCO still existed until 14 h after using NA. CONCLUSION: CCO was not the starting point of NA action. NA interferes with the structure and function of the cytoplasm and nucleus of malaria parasites and exerts its antimalarial effects in many aspects.

The course of Plasmodium berghei, P. chabaudi and P. yoelii infections in beta-thalassaemic mice.

In order to study the effects of acclimatization of Plasmodium in beta-thalassaemic mice, we used a mouse model of beta-thalassaemia (DBA/2J/beta-thal/beta-thal), similar to that observed in humans. We acclimatized 3 rodent malarias (P. berghei, P. chabaudi and P. yoelii) in DBA/2J and DBA/2J/beta-thal mice lines, by 4 intraperitoneal serial transfers. All 3 rodent malarias developed in red blood cells of beta-thalassaemic mice without losing their virulence. There was no delay in infection and peaks of parasitaemia were similar in beta-thalassaemic and normal mice. The mortality occurred earlier in beta-thalassaemic mice than in control mice for P. berghei and P. chabaudi. The difference was more pronounced for P. yoelii NS where normal mice did not die. These results could be explained by a failure of erythropoiesis in beta-thalassaemic mice, which are unable to compensate for the destruction of red blood cells by the parasites, and the mice died of anaemia. Ultrastructural examination of the rodent malaria parasites in beta-thalassaemic RBC showed a normal development even in the presence of Heinz bodies. In conclusion, no effective protection against malaria was provided by the beta-thalassaemia in this mouse model.

Plasmodium yoelii: 17-kDa hepatic and erythrocytic stage protein is the target of an inhibitory monoclonal antibody.

Infected hepatocytes are important targets for malaria vaccines. To identify Plasmodium yoelii proteins expressed in infected hepatocytes, we immunized BALB/c ByJ mice with P. yoelii liver stage schizonts and produced a panel of monoclonal antibodies (Mabs). An IgG1 Mab, navy yoelii liver stage 3 (NYLS3), had the strongest reactivity against liver stage parasites and was selected for further characterization. The Mab does not recognize P. yoelii sporozoites, but recognizes liver stage parasites within 6 hr of invasion of mouse hepatocytes and throughout the hepatic and asexual erythrocytic stages of the parasite life cycle as determined by the immunofluorescent antibody test. This Mab is species-specific, and it reacts with liver stages of P. yoelii but does not react with liver stages of other Plasmodium species. The protein recognized by this Mab is present on the parasitophorous vacuole membrane of infected hepatocytes and erythrocytes as demonstrated by immunoelectron microscopy and has a relative molecular weight of 17 kDa as demonstrated by immunoblot of an extract of infected erythrocytes. It is therefore designated P. yoelii hepatic and erythrocytic stage protein, 17 kDa or PyHEP17. When added to primary cultures of mouse hepatocytes 24 hr after inoculation with P. yoelii sporozoites, when all sporozoites have invaded hepatocytes, NYLS3 eliminates up to 98% of liver-stage parasites. Intravenous injection of NYLS3 into mice delays the onset and reduces the density of blood-stage parasitemia after sporozoite or blood-stage challenge. The P. falciparum and P. vivax homologs of PyHEP17 may therefore be important targets for vaccines designed to attack the hepatic and erythrocytic stages of the parasite life cycle.

Plasmodium yoelii: brefeldin A-sensitive processing of proteins targeted to the rhoptries.

We have shown that a family of high-molecular-mass proteins can be detected in lysates of parasitized erythrocytes using antibodies specific for a Plasmodium yoelii rhoptry protein. When these polypeptides are biosynthetically labeled in the presence of brefeldin A or at 15 degrees C, their electrophoretic mobility on polyacrylamide gels is decreased. Removal of the drug restores the size of the polypeptides to that in the absence of the drug. These results indicate that the proteins undergo a processing event, most probably a proteolytic cleavage, which is inhibited by brefeldin A and low temperature. The data suggest that the proteins are moved by secretory transport from the endoplasmic reticulum through a functional Golgi to the rhoptry organelles.

Plasmodium sporozoites possess both positively and negatively charged sites accessible on their surface.

Studies were conducted on the distribution of anionic and cationic sites on the surface of intact Plasmodium berghei and P. yoelii sporozoites. Anionic and cationic ferritins were used as probes for electron microscope studies and fluorescein conjugates of the same charged ferritins were used for correlative studies by fluorescence light microscopy. We found that the surfaces of mature sporozoites from mosquito salivary glands possess both negatively and positively charged sites that are accessible to charged ferritin molecules. Sporozoites obtained from oocysts expressed negatively charged sites but were inconsistent in their expression of positively charged sites. The charged nature of the ferritin probes was confirmed by their binding to cellulose particles or cellular components with known negative or positive charges. The electrostatic nature of the binding of ferritin to sporozoites was established by showing that binding could be blocked by competition with high concentrations of NaCl. The most likely source of these surface charges is circumsporozoite (CS) protein, the major protein covering the surface of sporozoites. Circumsporozoite proteins contain a cluster of positively charged amino acids, which may play a role as components of a surface ligand capable of binding to a liver receptor.

[Early ultrastructural evolution of murine malaria merozoites after entering red cells].

A TEM study of murine malaria parasites, Plasmodium berghei and P. yoelii was performed by consecutive sampling in vivo to look into the early sequential changes in the ultrastructure of the merozoites after entering red cells. The results showed that once finishing invasion, the merozoite resided in the peripheral cytoplasm of the red cell, creating a bulge at the invasion site, with an additional unit membrane around it (parasitophorous vacuole); apical structures disappeared; the spherical body was degenerative or atrophic and separated from the mitochondrion and nucleus. The mitochondrion became more extended and the nucleus elongated and curved. There were more Er vesicles in the cytoplasm, taking a dilated polyangular shape. The inner double membrane was separated from the outer membrane and got into incomplete, winding, finally disappeared. Sometimes multimembranous bodies could be seen in the peripheral spaces. Once the dedifferentiation process was over, the merozoite was transformed into an early trophozoite, with a single plasma membrane and decreased density. Individual large Er vesicle with acute angles was found in the cytoplasm, and small food pills appeared beneath the plasma membrane; then the shape of the parasite changed from a ball-like one to a pie-like one, gradually the flat cell body rolled up, with its edges met and fused, resulting in the formation of a large food vacuole, with digestive vacuoles and pigment granules around it. Thus, it grew into a middle-aged trophozoite.

[Localization of the antigen in erythrocytic stages of Plasmodium yoelii by immuno-electron microscopy].

In this study, the antigen recognized by the protective McAb M26-32 in erythrocytic stages of P. yoelii was localized by immuno-electron microscopy with LR Whithe resin embedding and colloidal gold probe cytochemical techniques. The results indicated that the antigen which reacts specifically to McAb M26-32 was mainly localized within the cytoplasm of early and late trophozoites, schizonts and merozoites, being the common antigen of asexual blood stages of the plasmodium. The amount of the antigen was on the increase during the development of trophozoite, while a portion of the antigen might be transported outward by exocytosis of the parasites and then be localized in the cytoplasm of the infected erythrocytes adjacent to the parasites.