Plasmodium berghei: Osmotic fragility of malaria parasites and mouse host erythrocytes

The osmotic properties of intraerythrocytic and ultrasonically liberated malaria parasites (Plasmodium berghei) were analyzed and compared with those of mouse host erythrocytes utilizing a multiple tube fragility test. Cells were incubated in phosphate buffered saline solutions of varying osmolalities ranging from 20–4000 mOsm. Changes in cell ultrastructure and parasite infectivity were used as indicators of osmotic damage. Intraerythrocytic and host cell-free plasmodia showed similar patterns of cell alteration and changes in infectivity following osmotic stress. The various developmental forms within each of the preparations responded somewhat differently to hypo-osmotic stress, however. The majority of merozoites seemed to be more sensitive than many trophozoites, schizonts, and segmenters. Small trophozoites were, on the average, more resistant than other developmental forms. Incubation of parasite populations in hypotonic salt solutions with osmolalities slightly greater than the infectivity threshold of 100 mOsm lysed the majority of the merozoites, whereas many small trophozoites were still intact. While normal erythrocytes were more resistant to hypo-osmotic stress than were either intracellular or free parasites, the majority of parasitized erythrocytes was less resistant than normal erythrocytes. The predominant alteration induced by hyperosmotic stress appears in the parasite's nuclear region with myelination of the nuclear membranes and chromatin clumping. The infectivity threshold in the hypertonic range was found to be approximately 2500 mOsm. Results indicate that these obligate intracellular parasites have a wide range of osmotic sensitivities and that they are capable of existing for short periods in various osmotic environments ranging from 100–2500 mOsm without complete loss of infectivity. This suggests that these parasites have osmotic regulatory capabilities at least comparable to those of host cells.     

Plasmodium lophurae: Antibody-induced movement and capping of surface membranes of erythrocyte-free malarial parasites

Surface antigens of the avian malarial parasite, Plasmodium lophurae, and its host cell, the duckling erythrocyte, were visualized at the ultrastructural level using rabbit antisera and ferritin-labeled goat anti-rabbit IgG. Rabbit antisera to P. lophurae caused an aggregation of parasite and parasitophorous vacuole surface membrane antigens, a phenomenon known as capping. Capping required living plasmodia and did not occur if parasites had been fixed with glutaraldehyde prior to exposure to antisera. Antisera against duckling erythrocytes did not cross-react with erythrocyte-free malarial parasites, and did not form caps on the surface of the red blood cell. Antiplasmodial sera did not react with normal or malaria-infected red cells. These results suggest that surface membrane proteins of the intracellular plasmodium are capable of lateral movement.     

Morphological changes in erythrocytes induced by malarial parasites

Host cell alterations induced by Plasmodium falciparum, P. brasilianum, P. vivax and P. malariae were described by electron microscopy and post-embedding immunoelectron microscopy. P. falciparum infection induces knobs, electron-dense material and clefts in the erythrocyte. Clefts are involved in exporting P. falciparum antigen from the parasite to the erythrocyte membrane. P. falciparum antigen is present in knobs which adhere to endothelial cells causing the blockage of cerebral capillaries and ensuing pathological changes in cerebral tissues. P. brasilianum infection induces knobs, short and long clefts and electron-dense material. These structures appear to contain different P. brasilianum antigens. This indicates that each structure functions independently in trafficking P. brasilianum protein to the erythrocyte surface. P. vivax infection induces caveola-vesicle complexes and clefts in the erythrocyte. These structures are also involved in trafficking P. vivax protein from the parasite to the erythrocyte membrane. P. malariae induces caveolae, electron-dense material, vesicles, clefts and knobs in the erythrocyte. Although vesicles and caveolae are seen in the erythrocyte cytoplasm, they do not form caveola-vesicle complexes as seen in P. vivax-infected erythrocytes. They also appear to be involved in trafficking of malaria antigens. These studies, therefore, indicate that host cell changes occur in order to facilitate the transport of malarial antigens to the host cell membrane. The significance of these phenomena is still not clear.     

Ultrastructural studies on the secretory process in the epithelioid cells of the juxtaglomerular apparatus

The epithelioid cells of the juxtaglomerular apparatus have been studied with respect to the release mechanism of the secretory granules. Invaginations of the plasma membrane into the interior of the epithelioid cells are interpreted as stages before or after an exocytotic process. Granules are sometimes observed in close contact with the plasma membrane, and material with electron density similar to that of the granules can also be observed in the invaginations. These morphological features suggest that the granular material of the epithelioid cells is extruded into the texture of the basal lamina. Furthermore, a dense network of microtubules and microfilaments is described and the functional role of this system in exocytosis is discussed.     

Alterations in the permeability of mouse erythrocytes infected with the malaria parasite, Plasmodium berghei

Alterations in the permeability of erythrocytes from mice infected with the malaria parasite Plasmodium berghei were demonstrated with l-¹⁴C-glucose. This sugar rapidly entered erythrocytes from infected mice but not those from normal mice. The results obtained were not due to contamination either by white cells, which were removed beforehand, or by immature cells, as judged by comparable investigations on blood from phenylhydrazine treated mice. Uptake was proportional to the concentration in the suspending medium, and was affected neither by relatively high concentrations of d-glucose nor by N-ethyl maleimide, and this suggests that the rapid uptake was due to an increased rate of diffusion through the membrane of the erythrocytes.     

Separation of erythrocytes infected with murine malaria parasites in metrizamide gradients

Density gradients with metrizamide, a tri-iodinated benzamido derivative of glucose, have been used to separate erythrocytes infected with 3 species of murine plasmodia. Good separations were obtained of uninfected erythrocytes from erythrocytes containing parasites in different developmental stages. With metrizamide solutions, the densities required for isopyenic separation can be obtained without hypertonicity or high viscosity, and the viability and those aspects of the metabolism of parasites and erythrocytes that we measured are not detectably modified by exposure to these solutions. This type of separation has many possible applications to biochemical and immunological investigations.     

Postnatal differentiation of the Golgi apparatus and the dendrites of Purkinje cells of the rat cerebellum

Summary The morphology of postnatal differentiation of the Golgi apparatus, the nucleus, the perikaryon, and the dendrites was studied in Purkinje cells of the rat cerebellum for 30 days after birth using histochemical, histological, and electron microscopic methods.The Golgi apparatus during differentiation undergoes morphological and positional changes. From the 1st to 7th postnatal day, the Golgi apparatus is found in a supranuclear position, and is connected with the axes of differentiating primary dendrites by beam-like processes. From days 8 to 11 this connection disappears, and most of the Golgi apparatus assumes a lateronuclear and infranuclear position. After the 11th or 12th day, the Golgi apparatus is found in perinuclear and peripheral cytoplasmic positions. The formation of granular endoplasmic reticulum occurs in the vicinity of the perinuclear Golgi apparatus. The differentiation of cell and nuclear forms requires approximately 20 days. The morphological changes of differentiation are discussed in relation to the participation of the Golgi apparatus in the differentiation of dendrites and in the formation of the granular endoplasmic reticulum.     

Homopolymer tract organization in the human malarial parasite Plasmodium falciparum and related Apicomplexan parasites

Background

Homopolymeric tracts, particularly poly dA.dT, are enriched within the intergenic sequences of eukaryotic genomes where they appear to act as intrinsic regulators of nucleosome positioning. A previous study of the incomplete genome of the human malarial parasite Plasmodium falciparum reports a higher than expected enrichment of poly dA.dT tracts, far above that anticipated even in this highly AT rich genome. Here we report an analysis of the relative frequency, length and spatial arrangement of homopolymer tracts for the complete P. falciparum genome, extending this analysis to twelve additional genomes of Apicomplexan parasites important to human and animal health. In addition, using nucleosome-positioning data available for P. falciparum, we explore the correlation of poly dA.dT tracts with nucleosome-positioning data over key expression landmarks within intergenic regions.

Results

We describe three apparent lineage-specific patterns of homopolymeric tract organization within the intergenic regions of these Apicomplexan parasites. Moreover, a striking pattern of enrichment of overly long poly dA.dT tracts in the intergenic regions of Plasmodium spp. uniquely extends into protein coding sequences. There is a conserved spatial arrangement of poly dA.dT immediately flanking open reading frames and over predicted core promoter sites. These key landmarks are all relatively depleted in nucleosomes in P. falciparum, as would be expected for poly dA.dT acting as nucleosome exclusion sequences.

Conclusions

Previous comparative studies of homopolymer tract organization emphasize evolutionary diversity; this is the first report of such an analysis within a single phylum. Our data provide insights into the evolution of homopolymeric tracts and the selective pressures at play in their maintenance and expansion.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-848) contains supplementary material, which is available to authorized users.     

Studies on the juxtaglomerular apparatus

The vascular pole of the juxtaglomerular apparatus in Tupaia belangeri was studied with special reference to the intercellular contacts of the periendothelial cells and the endothelium of the vas afferens. The periendothelial cells of the vascular pole of the glomerulum are connected by numerous gap junctions; and the granulated epithelial cells are suggested to form a functional unit. Probably there is a continuity of this system throughout the entire vascular pole including (1) all granulated cells, (2) all lacis cells, (3) the mesangium cells and (4) the adjacent smooth muscle cells of the vas afferens and vas efferens. Analysis of the endothelial junctions shows a zonular arrangement of tight junctions indicating a rather tight blood-tissue barrier next to the glomerular vascular pole; The ultrastructure of the different cell types of the vas afferens is also described, emphasizing the granulated epithelial cells and their innervation.     

Plasmodium iophurae: cationized ferritin staining, an electron microscope cytochemical method for differentiating malarial parasite and host cell membranes

The surface membranes of erythrocyte-free Plasmodium lophurae and its host cell, the duckling erythrocyte, stain differentially when exposed to cationized ferritin (CF). At low CF concentrations (0.18 mg/ml) only the outer surface of the red cell stains, whereas at the standard concentration (0.7 mg/ml) both the red cell and the parasitophorous vacuolar membranes (PVM) were stained on their outer faces. By using a high CF concentration (3.7 mg/ml), the parasite's plasma membrane (PM) could be distinguished from that of the PVM: The former did not bind CF, whereas the latter was stained on its outer surface. At this level of CF the red cell membrane stained on both faces if these surfaces were exposed to stain. Although the PVM is formed by red cell endocytosis of the parasite, it can be distinguished from the membrane of the erythrocyte as well as that of the PM.     

Plasmodium spp.: dispersion of malarial oocyst populations in anopheline and culicine mosquitoes

The numbers of malarial oocysts developing in individual, like mosquitoes fed concurrently on a single vertebrate malarial host were found to be distributed according to the negative binomial distribution in 169 experiments utilizing 6 species of Plasmodium, 6 species of mosquitoes and 3 species of vertebrate hosts. Dispersion constants ranged upward to 8.0, and mean clump sizes ranged upward to 298.4. The dispersion constant was demonstrated to be contingent on the species, strain and identity of the mosquito, the parasite and the vertebrate host; on the genetic state of the mosquito; and on the state of the infection in the vertebrate host. It was concluded that the concentration of oocyst production in particular mosquitoes was produced by varying levels and combinations of numerous factors associated with the parasite, the mosquito and the vertebrate host and that the pattern of oocyst distribution favors parasite survival and the maintenance of malaria in the field.     

Surface multivesicular structures associated with maturing erythrocytes in rats

Summary Surface multivesicular structures associated with the plasmalemma of erythrocytes were observed in the peripheral blood of rats which have a significant number of circulating reticulocytes. These surface structures appear as ovoid evaginations (0.2 to 0.7 in diameter) of the plasma membrane and contain numerous small vesicles ranging from 0.05 to 0.1 in diameter. The structures were present during the final stages of maturation of erythrocytes, after nuclei and mitochondria had been extruded and only a few polysomes and small vesicles remained. They appear quite distinct from the autophagic vacuoles which have been described in association with degeneration and extrusion of mitochondria from erythrocytes. The exact origin of the small internal vesicles of these surface multivesicular structures is unknown; however, similar vesicles have been observed in the cytoplasm of the maturing erythrocyte especially in the vicinity of the Golgi body. These structures suggest a process by which Golgi elements and other small cytoplasmic vesicles are extruded during the late stages of maturation of rat erythrocytes.Supported by U.S. Public Health Service Research Grant AM 12950.The author is indebted to Dr. Edward G. Rennels and Dr. William B. Winborn for their guidance.     

Plasmodium falciparum: comparative analysis of antigens from continuous in vitro cultured and in vivo derived malarial parasites

A comparison of metabolically labeled proteins from continuous in vitro and in vivo derived Plasmodium falciparum revealed both similarities and differences. Metabolic labeling of synchronized cultures showed that the uptake of label increased as the parasites matured from the ring to the schizont stage in both cultures. Also, in both continuous in vitro and in vivo derived cultures, prominent high-molecular-weight proteins were synthesized during the late developmental stages. However, the continuous in vitro cultured parasites incorporated twice as much of the label at each stage as did the in vivo derived parasites. Immunoprecipitation with serum samples from vaccinated Aotus trivirgatus griseimembra monkeys revealed major differences involving protein antigens that migrated in the molecular weight regions of b (Mr = 152,000), c (Mr = 143,000), j (Mr = 82,700), and n (Mr = 57,400). These antigens were more readily detected in the continuous in vitro cultured schizonts than in the in vivo derived schizonts.     

Pexel/VTS: a protein-export motif in erythrocytes infected with malaria parasites

The trafficking of proteins from the malaria parasite into the erythrocyte host has an important role in both the adaptation by the parasite of its immediate environment and the pathophysiology of disease. The molecular basis of these trafficking processes, particularly export from the parasitophorous vacuole (PV), is poorly understood and a matter of some controversy. In this article, we highlight two recent, independent reports that have provided new insights into protein translocation across the PV membrane, characterizing a novel signalling motif as a key signature in cataloguing the parasite secretome.     

Plasmodium simium: Ultrastructure of erythrocytic phase

An electron microscopic study of Plasmodium simium infections in the squirrel monkey has supplied information on the ultrastructure of erythrocytic trophozoites, schizonts, merozoites, and gametocytes, in addition to an unusual form of host cell pathology. In general, the structural features, as well as certain specialized functions, e.g., hemoglobin ingestion and utilization, nuclear and cytoplasmic division, were found to be similar to those described for other malarial parasites. Some striking features were noted, however. A highly asynchronous mode of merozoite production was observed within single segmenting parasites in spite of the overall developmental synchrony displayed by the population as a whole. Secondly, during parasite segmentation, newly formed merozoites are connected to one another, as well as to the parasitophorous membrane, by periodic surface strands. It is speculated that these interparasite bridges serve as structural support to the segmenting parasite. When merozoites are matured fully, these interconnections break, leaving a uniform array of short surface bristles. In addition, a number of different pathological changes in host cell structure have been noted. Localized surface discontinuities appear in region of infected cells where apical regions of developing or fully mature merozoites are abutted against the plasma membrane. These profiles suggest that these specialized apical regions of the merozoite function in release as well as in host cell penetration. More generalized surface pathology occurs within parasitized erythrocytes in the form of surface blebs, surface clefts, and associated cytoplasmic microvesicles. The severity of this pathology increases as the intraerythrocytic parasite matures. Topographically these altered cells have a “berry-like” surface texture which makes them quite distinctive when viewed by scanning electron microscopy.     

Morphogenesis and dynamics of the yeast Golgi apparatus

A kinetic and morphometric study was conducted with the electron microscope to clarify the biogenesis and structural diversity of the Golgi apparatus in the yeast Saccharomyces cerevisiae . Secretion was synchronized by inhibiting protein synthesis and/or by subjecting thermosensitive secretory mutants to double temperature shifts. Five membrane-bounded structures disappeared or reappeared in an orderly manner at approximately the rate of secretory protein flow. 1) The first detectable post-ER intermediates were very short-lived clusters of small vesicles that appeared next to the endoplasmic reticulum (ER). 2) Their constituent small vesicles were rapidly bridged by membrane tubules in a SEC18 -dependent manner, giving short-lived tubular clusters of small vesicles, analogous to mammalian vesicular-tubular clusters. 3) Fine and 4) large nodular networks (coated with the Golgi protein Sec7), and 5) secretory granules. Upon relieving a secretory block, each structure successively reappeared, seemingly by transformation of the previous one. When no secretory cargo was to be transported, these structures were not renewed. They disappeared more than five times faster than some Golgi enzymes such as Och1p, implying that the latter are recycled and perhaps partially retained. Retention could arise from intra-compartmental flow of cargo/carrier, hinted at by the varying calibers within a single nodular network.     

Parasite-induced processes for adenosine permeation in mouse erythrocytes infected with the malarial parasite Plasmodium yoelii.

In fura-2-loaded A10 vascular smooth-muscle cells, 1 nM-vasopressin and 200 nM-endothelin evoked a rapid transient rise in intracellular free Ca2+ concentration [( Ca2+]i), which was then followed by a maintained elevation of [Ca2+]i. The maintained elevation of [Ca2+]i was only partially inhibited by 5 microM-nifedipine, but completely abolished in the presence of 1 mM-EGTA. When extracellular Ca2+ was replaced with 1 mM-Mn2+ (Mn2+ quenches fura-2 fluorescence), both endothelin and vasopressin evoked an Mn2+ quench of the fluorescence from the intracellularly trapped fura-2, even in the presence of 5 microM-nifedipine. These data suggest that both vasopressin and endothelin promote a bivalent-cation influx and provide further evidence for receptor-mediated Ca2+ entry in vascular smooth muscle.