The mechanisms of ferritin uptake and digestion differ in bloodstream and culture forms of Trypanosoma brucei. Ferritin enters bloodstream forms from the flagellar pocket by pinocytosis in large spiny-coated vesicles. These vesicles become continuous with straight tubular extensions of a complex, mostly tubular, collecting membrane membrane system where ferritin is concentrated. From the collecting membrane system the tracer enters large digestive vacuoles. Small spiny-coated vesicles, which never contain ferritin, are found in the Golgi region, fusing with the collecting membrane system, and around the flagellar pocket. Acid phosphatase activity is present in some small spiny-coated vesicles which may represent primary lysosomes. This enzymic activity is also found in the flagellar pocket, pinocytotic vesicles, the collecting membrane system, the Golgi (mature face), and digestive vacuoles of bloodstream forms. About 50 percent of the acid phosphatase activity of blood forms is latent. The remaining nonlatent activity is firmly cell-associated and probably represents activity in the flagellar pocket. The structures involved in ferritin uptake and digestion are larger and more active in the short stumpy than in the long slender bloodstream forms. The short stumpy forms also have more autophagic vacuoles. No pinocytotic large, spiny-coated vesicles or Golgi-derived, small spiny-coated vesicles are seen in culture forms. Ferritin leaves the flagellar pocket of these forms and enters small smooth cisternae located just beneath bulges in the pocket membrane. The tracer then passes through a cisternal collecting membrane network, where it is concentrated, and then into multivesicular bodies. In the culture forms, acid phosphatase activity is localized in the cisternal system, multivesicular bodies, the Golgi (mature face), and small vesicles in the Golgi and cisternal regions. The flagellar pocket has no acid phosphatase activity, and almost all the acitvity is latent in these forms. The culture forms do not release acid phosphatase into culture medium during 4 days growth. Uptake of ferritin by all forms is almost completely inhibited by low temperature. These differences among the long slender and short stumpy bloodstream forms and culture forms are undoubtedly adaptive and reflect different needs of the parasite in different life cycle stages.
The erythrocytic cycle of the human malaria parasite, Plasmodium, falciparum, was examined by electron microscopy. Three strains of parasites maintained in continuous culture in human erythrocytes were compared with in vivo infections in Aotus monkeys. The ultrastructure of P. falciparum is not altered by continuous cultivation in vitro. Mitochondria contain DNA-like filaments and some cristae at all stages of the erythrocytic life cycle. The Golgi apparatus is prominent at the schizont stage and may be involved in the formation of rhoptries. In culture, knob-like protrusions first appear on the surface of trophozoite-infected erythrocytes. The time of appearance of knobs on cells in vitro correlates with the life cycle stage of parasites which are sequestered from the peripheral circulation in vivo. Knob material of older parasites coalesces and forms extensions from the erythrocyte surface. Some of this material is sloughed from the host cell surface. The parasitophorous vacuole membrane breaks down in erythrocytes containing mature merozoites both in vitro and in vivo. Merozoite structure is similar to that of P. knowlesi. The immature gametocytes in culture have no knobs.
Spermiogenesis in Cancer crabs was studied by light and electron microscopy. The sperm are aflagellate, and when mature consist primarily of a spherical acrosome surrounded by the nucleus with its short radiating arms. The acrosome forms by a coalescence of periodic acid-Schiff-positive (PAS-positive) vesicles. During spermiogenesis one edge of the acrosomal vesicle invaginates to form a PAS-negative central core. The inner region of the acrosome bounding the core contains basic proteins which are not complexed to nucleic acid. The formation of an elaborate lattice-like complex of fused membranes, principally from membranes of the endoplasmic reticulum, is described. These membranes are later taken into the nucleus and subsequently degenerate. In late spermatids, when most of the cytoplasm is sloughed, the nuclear envelope and the cell membrane apparently fuse to become the limiting boundary over most of the sperm cell. In the mature sperm the chromatin of the nucleus and arms, which is Feulgen-positive, contains no detectable protein. The chromatin filaments appear clumped, branched, and anastomosed; morphologically, they resemble the DNA of bacterial nuclei. Mitochondria are absent or degenerate in mature sperm of Cancer crabs, but the centrioles persist in the nucleoplasm at the base of the acrosome.
Pneumocystis carinii organisms were isolated from viral antibody-negative rats that had been infected by intratracheal intubation of organism preparations tested negative for common bacteria and fungi. Infection scores of lungs from infected animals at the time of parasite isolation was > 5 (100-1,000 organisms/oil immersion field). Electron microscopy of heavily infected lungs revealed that the pathogens adhered to Type I pneumocytes and to each other, resulting in obstructions up to several cell layers thick, which extended into the alveolar lumen. Protocols for purifying the organisms were developed to optimize separation from each other and from host cells, and to optimize preparation purity, recovery efficiency, and organism viability. The study tested mucolytic agents, sieving, various centrifugation speeds, lysis of host cells by osmotic shock and filtration through membranes of different pore diameter. Final preparations contained no intact host cells as determined by light microscopy. Only minor amounts (< 5%) of host debris were detected by electron microscopy. Most organisms and their pellicles were ultrastructurally intact but no longer adhered to one another. The final preparation was characterized biochemically by quantitation of the specific lung surfactant marker surfactant protein A, which indicated > 99.5% purity. The total non-P. carinii protein in the final preparation (< 6%, depending on the level of infection) was estimated by the protein content of pelletable material resulting from processing uninfected lungs in an identical manner. Elimination of free cholesterol and phospholipids from host lung tissue was monitored during the purification process. Exogenous stigmasterol, added as an extracellular marker, decreased during the purification process and was undetectable in the final organism preparation. Yields of 10(8)-10(9) organisms/rat were routinely obtained. Viability, assessed by the calcein acetoxymethyl ester-propidium iodide assay, was 80-95%.
Chaperonin 60 (Cpn60) is a well-established marker protein for eukaryotic mitochondria and plastids. In order to determine whether the small double-membrane-bounded organelle posterior to the nucleus in the apicomplexan Cryptosporidium parvum is a mitochondrion, the Cpn60 gene of C. parvum sporozoites ( CpCpn60) was analyzed and antibodies were generated for localization of the peptide. Sequence and phylogenetic analyses indicated that CpCpn60 is a mitochondrial isotype and that antibodies against it localize to the rough endoplasmic reticulum-enveloped remnant organelle of C. parvum sporozoites. These data show this organelle is of mitochondrial origin.
Sporozoites of the apicomplexan Cryptosporidium parvum possess a small, membranous organelle sandwiched between the nucleus and crystalloid body. Based upon immunolabelling data, this organelle was identified as a relict mitochondrion. Transmission electron microscopy and tomographic reconstruction reveal the complex arrangement of membranes in the vicinity of this organelle, as well as its internal organization. The mitochondrion is enveloped by multiple segments of rough endoplasmic reticulum that extend from the outer nuclear envelope. In tomographic reconstructions of the mitochondrion, there is either a single, highly-folded inner membrane or multiple internal subcompartments (which might merge outside the reconstructed volume). The infoldings of the inner membrane lack the tubular "crista junctions" found in typical metazoan, fungal, and protist mitochondria. The absence of this highly conserved structural feature is congruent with the loss, through reductive evolution, of the normal oxidative phosphorylation machinery in C. parvum. It is proposed that the retention of a relict mitochondrion in C. parvum is a strategy for compartmentalizing away from the cytosol toxic ferrous iron and sulfide, which are needed for iron sulfur cluster biosynthesis, an essential function of mitochondria in all eukaryotes.
The pathogenicity, immunogenicity, and morphological stability of a knobless clone of strain FCR-3 of the human malaria parasite Plasmodium falkiparum was investigated in Aotus monkeys. An early knob-bearing (K+), wild-type isolate of strain FCR-3 and the D3 knobless (K-) clone were adapted to Aotus monkey erythrocytes in continuous culture, establishing the parasites in Aotus cells without exposure to in vivo cellular or humoral immune responses. All monkeys, intact or splenectomized, which were infected with wild-type FCR-3 adapted to Aotus cells in vitro, developed virulent infections and had to be drug treated. The intact nonsplenectomized animals which received knobless D3 cloned parasites did not develop virulent infections even after multiple infections. The splenectomized monkeys which received the K-D3 clone had virulent infections. Late-stage wild-type K+ parasites sequestered in both intact and splenectomized monkeys, whereas late-stage D3 K-parasites did not sequester in the splenectomized animals. These results suggest that two elements affected the pathogenicity of the malaria parasites in these experiments. Knobs on K+-infected erythrocytes enabled these parasites to sequester, presumably by attachment to capillary endothelium. When present, the spleen eliminated circulating Klate-stage erythrocytes, presumably by selection on the basis of their nondeformability. Although clone D3 Kparasites are nonvirulent in intact monkeys, they induced some immunological protection against challenge with wild-type K+ parasites. The surface morphology of K-infected erythrocytes remains unaltered throughout these experiments, suggesting that loss of knobs is a stable condition. 760 on August 2, 2020 by guest http://iai.asm.org/ Downloaded from
Recent advances in techniques for the in vitro cultivation of Plasmodium falciparumhave now made it possible to obtain all stages of the asexual erythrocytic life cycle of the parasite (1). The protective properties of antisera from individuals immune to malaria and the antigenicity of parasite components can now be examined in vitro.During the erythrocytic cycle of Plasmodium falciparum two important foreign surfaces are exposed to the host immune system: the infected erythrocyte membrane and the plasma membrane of the parasite at the merozoite stage. This paper reports the results of our experiments on the immunocytochemical localization of antibodies from immune sera on these two surfaces.Infection with Plasmodium falciparum results in alterations of the host erythrocyte membrane, which develop as the parasite within matures. Most prominent of these are the knobs, electron-dense inverted cuplike protrusions from the erythrocyte surface. These knobs or excrescences arise in both in vivo and in vitro infections (2-6). They are believed to provide receptors by which erythrocytes, containing late-stage parasites, sequester in the capillaries (7,8). Although the knobs induced by P. falciparum may be antigenically distinct from the rest of the infected erythrocyte surface (8), their reactivity with the sera from animals which are immune to malaria has not been examined. P. knowlesi does not induce knobs but does induce antigenic variant-specific alterations in its host erythrocyte membrane. These alterations have been demonstrated by the agglutination of schizont-infected erythrocytes when treated with sera from monkeys immune to this malaria parasite (9).Several important questions have not yet been answered about the antigenicity of the P. falciparum-infected erythrocyte surface. Are the parasite-induced alterations which stimulate antibody in the immune host located on the knobs (7,8) or are other regions of the membrane also involved, such as with P. knowlesi (9)? Do different strains of P. falciparum from different geographic areas induce immunologically crossreactive alterations of the erythrocyte membrane, or are the alterations strain and/or variant specific? Are the knobs induced by a single strain of parasite antigenically similar in both human and monkey erythrocytes, or is their antigenicity influenced by the host cell?
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