THE TRANSFORMATION OF THE PLASMODIUM GALLINACEUM OOCYST IN AEDES AEGYPTI MOSQUITOES

Sporoblast and sporozoite formation from oocysts of the avian malarial parasite, Plasmodium gallinaceum, after the seventh day of infection in Aedes aegypti mosquitoes offers an interesting example of differentiation involving the appearance and modification of several cellular components. Sporoblast formation is preceded by (a) invaginations of the oocyst capsule into the oocyst cytoplasm, (b) subcapsular vacuolization and cleft formation, (c) the appearance of small tufts of capsule material on the previously noted invaginations, and (d) linear dense areas located just below the oocyst plasma membrane which predetermine the site of emerging sporozoites from the sporoblast. The subcapsular clefts subdivide the once-solid oocyst into sporoblast peninsulae. Within the sporoblast, nuclei migrate from the random distribution seen in the solid oocyst and come to lie at the periphery of the sporoblast just below the linear dense areas noted in the earlier stage. A typical nuclear fiber apparatus occurs in most of the nuclei seen in random sections at this stage although such a fiber apparatus may occasionally be seen in the solid oocyst stage. The nucleus, its associated fiber apparatus, and the overlying dense area appear to induce the onset of sporozoite budding from the sporoblast as well as the formation of the sporozoite pellicular complex and the paired organelle precursor. Several mitochondria are present in each sporozoite, in contrast to the single mitochondrion seen in the merozoites of the erythrocytic and exoerythrocytic stages of avian malaria infection. The paired organelles and associated dense inclusion bodies are formed by condensation of an irregular meshwork of membrane-bound, coarse, dense material. The nature of small, particulate cytoplasmic inclusions is described.     

间日疟原虫卵囊内成孢子细胞与子孢子形成的超微结构观察

应用透射电镜观察间日疟原虫在大劣按蚊体内发育的卵囊内成孢子细胞及子孢子形成过程形态变化。疟原虫采自带有配子体的间日疟自愿者。蚊虫在感染后8天作解剖。本研究观察结果与前人所描述的柏氏疟原虫和鸣疟原虫的成孢子细胞与子孢子形成过程相似,即成孢子细胞形成开始于卵囊被膜下的周围出现液泡,而随着膜下液泡增大,逐渐向胞质延伸并联接成裂缝,使胞质再分裂而形成。子孢子周围的膜下微管分布不对称,其数目和排列型式,多数为:7+4、7+5、8+4和8+5,少数为10+1,与前人报告不同(10+1)。     

Scanning electron microscopic observations of the oocyst, sporoblast and sporozoite of Plasmodium yoelii yoelii

Scanning electron microscopy was used to study the surface characteristics of the oocyst, sporoblast and sporozoite of Plasmodium yoelii yoelii. Observations were made of the sporogonic stages of 6-12 day infections of the malaria parasite in Anopheles stephensi. Oocyst and sporoblast development were not synchronous. The surface of the undifferentiated (early stage) oocyst appeared smooth, whereas that of differentiated (late stage) oocysts were rough or wrinkled. The wall of the differentiated oocysts showed numerous micropores at higher magnification (x15,000-20,000) the biological significance of which is not known. Small, bud-like satellite bodies were seen attached to some oocysts. Various forms of different stages of the sporoblast were described. Sporozoite budding took place on the surface of the sporoblast body. The sporozoite was elongate, curved and with a blunt anterior end.     

Sporogony of Isospora rivolta Oocysts from the Dog*

SYNOPSIS. Sporogony of oocysts of Isospora rivolta from the dog was studied by observation of individual oocysts in hanging drop preparations. Oocysts were passed with the feces in the unsporulated sporont stage. Division of the sporont gave rise to 2 spherical sporoblasts. Each sporoblast elongated and developed into a transient double pyramid stage. This stage changed into the sporocyst, which then differentiated into the sporulated oocyst. Sporulation time was determined for 4 temperatures. At 20 C, 100% of the sporulating oocysts (Sz 100) had formed sporozoites by 48 hr. At 25 C, Sz 100 was 24 hr, at 30 C it was 16 hr, and at 38 C 8 hr. The percentages of sporulation at 20, 25, 30, and 38 C were 94, 97, 96, and 93, respectively. Oocysts incubated at 50 C for 4 hr did not develop or survive, since they failed to sporulate when reincubated at 30 C.     

Plasmodium vivax:A Monoclonal Antibody Recognizes a Circumsporozoite Protein Precursor on the Sporozoite Surface

Gonzalez-Ceron, L., Rodriguez, M. H., Wirtz, R. A., Sina, B. J., Palomeque, O. L., Nettel, J. A., and Tsutsumi, V. 1998.Plasmodium vivax:A monoclonal antibody recognizes a circumsporozoite protein precursor on the sporozoite surface.Experimental Parasitology90, 203–211. The major surface circumsporozoite (CS) proteins are known to play a role in malaria sporozoite development and invasion of invertebrate and vertebrate host cells.Plasmodium vivaxCS protein processing during mosquito midgut oocyst and salivary gland sporozoite development was studied using monoclonal antibodies which recognize different CS protein epitopes. Monoclonal antibodies which react with the CS amino acid repeat sequences by ELISA recognized a 50-kDa precursor protein in immature oocyst and additional 47- and 42-kDa proteins in older oocysts. A 42-kDa CS protein was detected after initial sporozoite invasion of mosquito salivary glands and an additional 50-kDa precursor CS protein observed later in infected salivary glands. These data confirm previous results with otherPlasmodiumspecies, in which more CS protein precursors were detected in oocysts than in salivary gland sporozoites. A monoclonal antibody (PvPCS) was characterized which reacts with an epitope found only in the 50-kDa precursor CS protein. PvPCS reacted with allP. vivaxsporozoite strains tested by indirect immunofluorescent assay, homogeneously staining the sporozoite periphery with much lower intensity than that produced by anti-CS repeat antibodies. Immunoelectron microscopy using PvPCS showed that the CS protein precursor was associated with peripheral cytoplasmic vacuoles and membranes of sporoblast and budding sporozoites in development oocysts. In salivary gland sporozoites, the CS protein precursor was primarily associated with micronemes and sporozoite membranes. Our results suggest that the 50-kDa CS protein precursor is synthesized intracellularly and secreted on the membrane surface, where it is proteolytically processed to form the 42-kDa mature CS protein. These data indicate that differences in CS protein processing in oocyst and salivary gland sporozoites development may occur.     

La Sporogenèse chez la Coccidie Aggregata eberthi. Etude en Microscopic Electronique

SYNOPSIS. The structure of the oocyst and formation of sporozoites of Aggregata eberthi were studied with the electron microscope. After penetration of the microgamete, a cyst wall containing fine projections is formed beneath the "anhist" layer which is pushed away. The cytoplasm is retracted beneath the cyst wall and is irregular in outline. Lipid inclusions are abundant, while paraglycogen is less so. Vacuoles present in the early stages of development may be instrumental in elaboration of the cyst wall. Granulations appear in the early oocyst cytoplasm and form large compact masses in the sporoblasts, assuming a crystalline appearance (crystalloid) in the sporozoites. The sporoblasts are separated by the coalescence of vesicles. Each sporoblast is surrounded by an epispore and a striated endospore which is perforated by the "dehiscence device." Three sporozoites of classical structure are formed in each sporoblast.     

Fine structure of the developing spore of Nosema apis zander

Summary The mature spore possesses a thick spore coat and a particle-bearing spore membrane. The highly laminated polaroplast membranes are located at the anterior pole of the spore. Close to its base, the polar filament is surrounded by the polaroplast membrane. The polar filament runs spirally towards the posterior pole of the spore. A large portion of the polar filament is arranged in two layers. A similar arrangement was also observed in immature spores and in the sporoblast stage, although it was not so orderly arranged in the latter. The developing polaroplast membrane was observed in the immature spore, but not in the sporoblast. The sporoblast wall is much thinner than the spore coat, but has the same texture. Endoplasmic reticulum is the most prominent cytoplasmic organelle in the developing stages of Nosema apis. Porous nuclear envelopes are also observed in developing stages. The role of the endoplasmic reticulum in the formation of the polar filament, polaroplast and spore coat, and the function of the spore membrane, are discussed.     

Peroxidase catalysed cross-linking of an intrinsically unstructured protein via dityrosine bonds in the oocyst wall of the apicomplexan parasite, Eimeria maxima

Apicomplexan parasites such as Eimeria maxima possess a resilient oocyst wall that protects them upon excretion in host faeces and in the outside world, allowing them to survive between hosts. The wall is formed from the contents of specialised organelles – wall-forming bodies – found in macrogametes of the parasites. The presence of dityrosine in the oocyst wall suggests that peroxidase-catalysed dityrosine cross-linking of tyrosine-rich proteins from wall-forming bodies forms a matrix that is a crucial component of oocyst walls. Bioinformatic analyses showed that one of these tyrosine-rich proteins, EmGAM56, is an intrinsically unstructured protein, dominated by random coil (52–70%), with some α-helix (28–43%) but a relatively low percentage of β-sheet (1–11%); this was confirmed by nuclear magnetic resonance and circular dichroism. Furthermore, the structural integrity of EmGAM56 under extreme temperatures and pH indicated its disordered nature. The intrinsic lack of structure in EmGAM56 could facilitate its incorporation into the oocyst wall in two ways: first, intrinsically unstructured proteins are highly susceptible to proteolysis, explaining the several differently-sized oocyst wall proteins derived from EmGAM56; and, second, its flexibility could facilitate cross-linking between these tyrosine-rich derivatives. An in vitro cross-linking assay was developed using a recombinant 42 kDa truncation of EmGAM56. Peroxides, in combination with plant or fungal peroxidases, catalysed the rapid formation of dityrosine cross-linked polymers of the truncated EmGAM56, as determined by western blotting and HPLC, confirming this protein’s propensity to form dityrosine bonds.     

Eimeria lipura and E. landersi n. spp. (Protozoa,Eimeriidae) from the Long-tailed Porcupine Trichys lipura Günther, 1876 in Malaysia1

SYNOPSIS. Oocysts of 2 new species of Eimeria are described from the long-tailed porcupine Trichys lipura. The ovoid, 2-layered oocysts of E. lipura average 33.1 by 24.4 μ. A micropyle and polar granules are present; an oocyst residuum is absent. Ovoid sporocysts average 10.9 by 9.3 μ. A sporcyst residuum is present; Stieda body is absent. The subspherical, 3-layered oocyst of E. landersi averages 25.2 by 24.2 μ. An oocyst residuum is absent; a polar granule is present. Ovoid sporocysts average 11.7 by 7.9 μ. A sporcysts residuum is present; a Stieda body is absent.     

Molecular characterisation of a novel family of cysteine-rich proteins of Toxoplasma gondii and ultrastructural evidence of oocyst wall localisation

Among apicomplexan parasites, the coccidia and Cryptosporidium spp. are important pathogens of livestock and humans, and the environmentally resistant stage (oocyst) is essential for their transmission. Little is known of the chemical and molecular composition of the oocyst wall. Currently, the only parasite molecules shown to be involved in oocyst wall formation are the tyrosine-rich proteins gam56, gam82 and gam230 of Eimeria spp. and the cysteine-rich proteins COWP1 and COWP8 of Cryptosporidium parvum. In the present study, we searched the ToxoDB database for the presence of putative Toxoplasma gondii oocyst wall proteins (OWPs) and identified seven candidates, herein named TgOWP1 through TgOWP7, showing homology to the Cryptosporidium COWPs. We analysed a cDNA library from partially sporulated oocysts of T. gondii and cloned the full-length cDNAs encoding TgOWP1, TgOWP2 and TgOWP3, which consist of 499, 462 and 640 amino acids, respectively. The three proteins share 24% sequence identity with each other and a markedly similar overall structure, based on the presence of an N-terminal leader peptide followed by tandem duplications of a six-cysteine amino acid motif closely related to the Type I repeat of COWPs. Using antisera to recombinant TgOWP1, TgOWP2 and TgOWP3, we showed by Western blot that these molecules are expressed in T. gondii oocysts but are not detectable in tachyzoites. The solubilisation of TgOWP1–3 strictly depended on the presence of reducing agents, consistent with a likely involvement of these proteins in multimeric complexes mediated by disulphide bridges. Immunofluorescence analysis allowed the localisation of TgOWP1, TgOWP2 and TgOWP3 to the oocyst wall. Additionally, using immunoelectron microscopy and the 1G12 monoclonal antibody, TgOWP3 was specifically detected in the outer layer of the oocyst wall, thus representing the first validated molecular marker of this structure in T. gondii.     

Ultrastructure of Cryptosporidium parvum Oocysts and Excysting Sporozoites as Revealed by High Resolution Scanning Electron Microscopy1

Cryptosporidium parvum oocysts isolated from calf feces were examined by scanning electron microscopy during excystation. Intact C. parvum oocysts were spheroid to ellipsoid, ?3.5 × 4.0 μm, with length: width ratio = 1.17. The oocyst wall had a single suture at one pole, which spanned 1/3 to 1/2 the circumference of the oocyst. During excystation the suture dissolved, resulting in a slit-like opening, which the sporozoites used to exit the oocyst. Sporozoites were 3.8 times 0.6 μm and had a rough outer surface.     

Observations on Haemogregarina balli sp. n. from the Common Snapping Turtle,Chelydra serpentina*

SYNOPSIS. Haemogregarina balli sp. n. is described from the blood and organs of the common snapping turtle Chelydra serpentina serpentina and from the gastric and intestinal ceca of the presumed invertebrate hosts, the leeches Placobdella parasitica and Placobdella ornata. In the peripheral blood of the turtle, male and female gametocytes and immature erythrocytic schizonts are found within erythrocytes. The maturation of erythrocytic schizonts containing 6–8 merozoites is recorded from liver imprints. Schizonts with 13–25 merozoites are found in various cells of the liver, lung and spleen. In the gastric ceca of the leeches the host erythrocytes are digested, releasing the gametocytes and immature erythrocytic schizonts. Immature erythrocytic schizonts degenerate. Association of the gametocytes occurs in the intestinal ceca. The microgametocyte apparently gives rise to 4 nonmotile microgametes, one of which fertilizes the macrogamete while the other remain as condensed, residual nuclei on the periphery of the developing oocyst. The oocyst increases in size with maturity. A mature oocyst produces 8 sporozoites from a single germinal center. Sporozoites liberated from the oocyst are found in the tissues of the leech. Transovarial transmission of the parasite does not occur in the turtle. Attempts at experimental transmission failed. Previously unfed (control) leeches were negative for the parasite. Haemogregarina balli is compared with other haemogregarines described from C. serpentina. Features of species of Haemogregarina and Hepatozoon as well as the taxonomy of these genera are discussed.     

Light and Electron Microscope Observations on Nosema nelsoni Sprague, 1950 (Microsporida,Nosematidae) with Particular Reference to its Golgi Complex*

SYNOPSIS. A species of Nosema in the muscles of the North American white shrimp, generally known as Penaeus setiferus but also known as P. fluviatilis, appears identical with type specimens of N. nelsoni Sprague, 1950, in P. aztecus. Its Golgi apparatus, as seen in the sporoblast, is a complex system of cisternae, small vesicles and expanded sacs which plays a major role in spore morphogenesis. It transforms directly into the polaroplast complex, certain membranous investments of the polar filament, the polar sac and perhaps part of the posterior vacuolar system. Probably the polar sac contains the polar cap. The PAS-positive material in both the cap and the filament may be a component of the Golgi complex. This new concept of the Golgi complex supplements our earlier view of spore morphogenesis according to which the polar filament is of nuclear origin. It also reconciles the idea with Vávra's identification of Golgi vesicles associated with the developing polar filament.     

Ultrastructural study of microsporidian development

Summary Vegetative growth of Nosema sp. occurs within the gut submucosal cells of Callinectes sapidus. Vegetative cell morphology is dominated by profiles of endoplasmic reticulum, numerous free ribosomes and aggregates of vesicles enclosed by a membranous sac. The dikaryotic vegetative cell is the earliest stage found in the target area for sporogenesis, the sarcoplasm of the striated muscle cell. The next obvious stage is the sporoblast mother cell; it undergoes karyokinesis without breakdown of the nuclear envelope. Intranuclear mitotic microtubules extend from the chromosomes to the intact nuclear envelope. After repeated nuclear divisions, the sporoblast mother cell undergoes delayed cytokinesis and a series of sporoblast progeny develops.The polar filament is the first visually apparent system to develop during sporogenesis. It appears to be of dual origin: (1) the central core component is condensed in Golgi-like saccules, and (2) the envelopes around the core originate from the endoplasmic reticulum.The polaroplast, which forms after early polar filament development, appears to originate as an elaboration of the endoplasmic reticulum.Supported in part by a training grant from the National Institutes of Health (GM-669-05) and research grants from the National Science Foundation (GB-3036, GB-5235, and GB-7938) to Prof. F. Sogandares-Bernal. The skillful guidance of Prof. F. Sogandares-Bernal is acknowledged. Special thanks are extended to Prof. D. E. Copeland for the use of a Siemens Elmiskop IA electron microscope. I also wish to thank Mr. Julian King, professional fisherman of Irish Bayou, Louisiana, for providing hundreds of blue crabs used in the course of this study.     

Environmental Inactivation of <Emphasis Type="Italic">Cryptosporidium parvum</Emphasis> Oocysts in Waste Stabilization Ponds

The survival of Cryptosporidium parvum oocysts in a waste stabilization pond system in northwestern Spain and the effects of sunlight and the depth and type of pond on oocyst viability were evaluated using an assay based on the exclusion or inclusion of two fluorogenic vital dyes, 4′,6-diamidino-2-phenylindole (DAPI) and propidium iodide (PI). All tested factors had significant effects (P < 0.01) over time on C. parvum oocyst viability. Sunlight exposure was the most influential factor for oocyst inactivation. A 40% reduction was observed after 4 days exposure to sunlight conditions compared with dark conditions. The type of pond also caused a significant reduction in C. parvum oocyst viability (P < 0.01). Inactivation rates reflected that the facultative pond was the most aggressive environment for oocysts placed both at the surface (presence of sunlight) and at the bottom (absence of sunlight) of the pond, followed by the maturation pond and the anaerobic pond. The mean inactivation rates of oocysts in the ponds ranged from 0.0159 to 0.3025 day⁻¹.     

Eimeria clethrionomyis sp. n., Eimeria gallatii sp. n., Eimeria pileata sp. n. and Eimeria marconii sp. n. from the Red-Backed Vole Clethrionomys gapperi Vigors,from Pennsylvania§

SYNOPSIS Four new eimerian species are described from red-backed voles. Clethrionomys gapperi in Pennsylvania. Sporulated oocysts of Eimeria clethrionomyis sp. n. are ellipsoidal, 18.8 (16.5–21.5) × 14.9 (14.0–16.5) with elongate, ovoid sporocysts, 10.6 (9.5–12.0) × 6.1 (5.5–7.0). The oocyst wall is smooth, with 2 layers, and thins, with terminal cap at one or both ends. Polar granules, dark Stieda body and sporocyst residuum are present. The occyst residuum is absent. Sporulated oocysts of Eimeria gallatii sp. n. are ellipsoidal, 27.7 (21–32) × 19.3 (17–24) with ovoid sporocysts, 13.5 (12–15) × 8.8 (8–10). The oocyst wall is smooth, 2-layered, with a micropyle and thin wall at the end opposite the micropyle. Polar granules. Stieda body and sporocyst residuum are present. The oocyst residuum is atypical, of cobwebby material. Sporulated oocysts of Eimeria pileata sp. n. are subspherical to spherical, 25.2 (20.5–29.5) × 22.5(19.5–25.5) with ellipsoidal sporocysts, 13.4(10.5–15.0) × 8.4 (7.5–9.5). The oocyst wall is rough, pitted, striated, 2-layered, with no micropyle. Polar granules, oocyst and sporocyst residuum. Stieda body and stiedal cap are present. Sporulated oocysts of Eimeria marconii sp. n. are ellipsoidal, 13.0 (10.5–15.0) × 10.6 (9.5–12.0) with elongate, ovoid sporocysts, 7.7 (7.0–8.5) × 4.2 (3.0–4.5). The oocyst wall is smooth, single-layered, with no micropyle. Polar granules, dark Stieda body and sporocyst residuum are present. There is no oocyst residuum.     

Ultrastructural Studies of the Zygote and Oocyst Wall Formation of Eimeria truncata of the Lesser Snow Goose1

ABSTRACT. Zygote development and oocyst wall formation of Eimeria truncata occurred in epithelial cells in renal tubules and ducts of experimentally infected lesser snow geese (Anser c. caerulescens). Post-fertilization stages were present throughout the kidneys beginning nine days post-inoculation. Initially, a single plasmalemma enclosed the zygote, and type 1 wall-forming bodies (WF1) became labyrinthine and moved toward the surface. There, WF1 degranulated and formed the outer layer of the oocyst wall between the plasmalemma and a newly formed second subpellicular membrane. Several WF2 fused and formed the inner layer, of the oocyst wall between the third and fourth subpellicular membranes. Six subpellicular membranes were observed during wall formation. Other features of oocyst development were similar to those of other eimerian species.     

Plasmodium malariae: distribution of circumsporozoite protein in midgut oocysts and salivary gland sporozoites

The distribution of the circumsporozoite protein within developing Plasmodium malariae oocysts and salivary gland sporozoites was examined by immunoelectron microscopy using protein A-gold and a monoclonal antibody specific for the CS protein of P. malariae. Gold particles were found along the capsule of immature oocysts but rarely within the cytoplasm. Gold label was detected on the inner surface of peripheral vacuoles during oocyst maturation and the plasma membrane of the sporoblast. Salivary gland sporozoites and budding sporozoites in mature oocysts were labeled uniformly on the outer surface of their plasma membranes. The surface of sporozoites that ruptured into midgut epithelial cells were entirely covered with gold particles. No label was seen on the surface of sporozoites which ruptured into the midgut lumen. In addition, a rabbit polyclonal antibody against repeat a region of P. brasilianum CS protein reacted with P. malariae sporozoites.     

Eimeria tenggilingi sp. n. from the Scaly Anteater Manis javanica Desmarest in Malaysia*

SYNOPSIS. Eimeria tenggilingi is described from the pangolin or scaly anteater, Manis javanica, in Malaysia. The spheroid to subspheroid oocysts average 18.9 × 17.8 μm. The oocyst wall is composed of 3 layers, each ～ 0.6 μm thick. The 2 outer layers are striated and yellowish green. The inner layer is dark brown. One or 2 polar granules are present, but an oocyst residuum is absent. Ellipsoid sporocysts average 12.4 × 6.2 μm. A sporocyst residuum is present. This is the first Eimeria species reported from a host in the order Pholidota.