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.     

Fine Structure of Zygotes and Oocysts of Eimeria nieschulzi*

SYNOPSIS. Mature macrogamonts were present in the small intestine of rats 5.5 to 7.5 days postinoculation with Eimeria nieschulzi oocysts; oocysts were present at 6 to 7.5 days. Types I and II wall-forming bodies in macrogamonts began to undergo ultrastructural changes within zygotes to form the outer and inner layers of the oocyst wall. Before and during oocyst wall formation a total of 5 membranes (M1–5) were formed at or near the surface of the zygote. The outer and inner oocyst wall layers formed between M2 and M3, and M4 and M5, respectively. The mature oocyst was loosely surrounded by M1 and M2, had an electron-dense outer layer, 100–275 nm thick, and an electron-lucent inner layer, 160–180 nm thick. It also contained an electron-lucent line consisting of M3 and M4 interposed between the outer and inner layers of the oocyst wall. The micropyle, measuring 935 × 47 nm, was located in the outer layer of the oocyst wall and consisted of 10–14 alternating layers of electron-dense and lucent material. The sporont of mature oocysts was covered by M5, immediately beneath which were M6 and M7. The sporont contained a nucleus and nucleolus, lipid and amylopectin bodies, mitochondria, ribosomes, as well as smooth and rough endoplasmic reticulum. Canaliculi, Golgi complexes, and types I and II wall-forming bodies were absent.     

The development of the macrogamete and oocyst wall in Eimeria maxima: immuno-light and electron microscopy

We have identified, and followed the development of three macrogamete organelles involved in the formation of the oocyst wall of Eimeria maxima. The first were small lucent vacuoles that cross-reacted with antibodies to the apple domains of the Toxoplasma gondii microneme protein 4. They appeared early in development and were secreted during macrogamete maturation to form an outer veil and were termed veil forming bodies. The second were the wall forming bodies type 1, large, electron dense vacuoles that stained positively only with antibodies raised to an enriched preparation of the native forms of 56 (gam56), 82 (gam82) and 230 kDa (gam230) gametocyte antigens (termed anti-APGA). The third were the wall forming bodies type 2, which appeared before the wall forming bodies type 1 but remain enclosed within the rough endoplasmic reticulum and stained positively with antibodies raised to recombinant versions of gam56 (anti-gam56), gam82 (anti-gam82) and gam230 (anti-gam230) plus anti-APGA. At the initiation of oocyst wall formation, the anti-T. gondii microneme protein 4 positive outer veil detached from the surface. The outer layer of the oocyst wall was formed by the release of the contents of wall forming bodies type 1 at the surface to form an electron dense, anti-APGA positive layer. The wall forming bodies type 2 appeared, subsequently, to give rise to the electron lucent inner layer. Thus, oocyst wall formation in E. maxima represents a sequential release of the contents of the veil forming bodies, wall forming bodies types 1 and 2 and this may be controlled at the level of the rough endoplasmic reticulum/Golgi body.     

Ultrastructural studies on the sporulation of oocysts of Toxoplasma gondii. II. Formation of the sporocyst and structure of the sporocyst wall

The ultrastructural changes observed during sporocyst formation and the structure of the sporocyst wall was examined in oocysts which had been allowed to sporulate for between 12 and 48 hours at 27 degrees C. As the spherical sporoblast developed into the sporocyst the cytoplasmic mass became ellipsoidal in shape although no change was noted in the organelle compliment, which cosisted of two nuclei plus a number of polysaccharide granules, lipid globules, mitochondria, Golgi bodies, and some rough endoplasmic reticulum. The sporocyst wall consisted of a thin outer layer (15-20 nm) which was formed from two limiting membranes of the sporoblast and an inner layer (40-50 nm) which was comprised of four curved plates. This inner layer was formed under the outer layer and, although no specific cytoplasmic organelle disappeared with its formation, some unit membranes were observed close to the plasmalemma during its formation. Each curved plate has a marginal swelling and an interposing strip of material is present between the margins of adjacent plates. The plates are joined to the interposing strip by a thin band of osmiophilic material. In oblique and tangential sections through the plates two types of cross banding were observed which differed in periodicity.     

Ultrastructural Changes Associated with Spore Formation in Sporangia and Sporangiola of Thamnidium elegans Link

Fully formed pre-cleavage sporangia and sporangiola of Thamnidiumelegans Link were bounded by a primary wall plus a thick, internalsecondary wall layer. In sporangia in late pre-cleavage, Golgi-likecisternae were associated with groups of cytoplasmic vesiclesof characteristic size and appearance which were not found insporangia containing large cleavage vesicles. In both sporangia and sporangiola, protoplast cleavage was effectedby enlargement of endogenous cleavage vesicles each containinga lining layer of variable appearance, mutual fusion of cleavagevesicle membranes and fusion of cleavage vesicle membranes withthe plasmalemma. Golgi-like cisternae and small vesicular profileswere present in sporangium protoplasts at all stages of cleavagevesicle enlargement. In sporangia, the columella zone was delimitedby cleavage vesicles and separated from the sporogenous zoneby a fibrillar wall. A similar wall, which sometimes protrudedto form a small columella, was formed in sporangiola. Recently delimited spore protoplasts were bounded by plasmalemmamembrane derived from cleavage vesicle bounding membrane andsporangium or sporangiolum plasmalemma and surrounded by aninvesting layer derived from cleavage vesicle lining material.The investing layer at first appeared single, but later twoelectron opaque profiles were discernible. The spore wall wasformed between the investing layer and the plasmalemma. Wallsof sporangia and sporangiola which contained fully formed sporesconsisted of the primary layers only.     

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)。     

Light and electron microscopy on the sporulation of the oocysts of Eimeria brunetti. II. Development into the sporocyst and formation of the sporozoite

The later stages of sporulation in oocysts of Eimeria brunetti were examined in samples which had been allowed to sporulate at 27 degrees C for 24, 36 and 48 hours. It was observed that the sporoblasts became ellipsoidal and the nucleus underwent the final division. A nucleus with associated Golgi bodies was not observed at either end of the organism. The cytoplasm was limited by two unit membranes and contained rough endoplasmic reticulum, dense bodies, electron translucent vacuoles and mitochondria. The first evidence of sporozoite formation was the appearance of a dense plaque at either end of the organism. This appeared in the vicinity of the nuclei, and adjacent to the limiting membrane of the soroblast. At this stage the sporocyst wall was still unformed. Then the two sporozoites were formed from opposite ends of the organism by growth of the dense plaques and invaginations of the plasmalemma which thus formed the pellicles of the developing sporozoites. A conoid and subpellicular microtubules were observed at this stage as development continued, a number of vacuoles were found between the nucleus and the conoid. These vacuoles constituted the precursors of the rhoptries and micronemes. At the same stage a large dense body had appeared within the forming sporozoite. As the sporozoite developed, this body, anterior refractile body, is followed by the nucleus and another dense body which formed the posterior refractile body. During this period, the thin sporocyst wall was formed and Stieda and sub-Stieda bodies were now present at one end of the sporocyst. Each mature sporocyst contained two sporozoites.     

Scanning and transmission electron microscopy of the oocyst wall of Isospora lacazei

The oocyst wall of Isospora lacazei from sparrows was studied with scanning (SEM) and transmission (TEM) electron microscopy. In TEM, the oocyst wall consisted of four distinct layers (L1-4). The innermost layer, L1, was moderately electron-lucent and 240--285 nm thick; L2 was electron-dense and 210--240 nm thick; L3 was moderately electron-lucent and 15--150 nm thick; L4, the outer most layer, was discontinuous and consisted of electron-dense discoid bodies which measured 180--220 nm x 320--840 nm. The discoid bodies of L4 as seen by TEM appeared spheroid in shape when observed by SEM. One or two membranes were situated on or between various layers of the oocyst wall. One such membrane occurred on the inner margin of L1, two closely applied membranes were interposed between L1 and L2, one membrane occurred between L2 and L3, and one membrane on the outer margin of L3.     

The microneme protein MIC4, or an MIC4-like protein, is expressed within the macrogamete and associated with oocyst wall formation in Toxoplasma gondii

The expression and localisation of MIC4, or an immuno-cross reacting MIC4-like protein, was examined in the enteric forms of Toxoplasma gondii using immunocytochemistry. In addition to being located within the micronemes of the merozoites, MIC4 or the MIC4-like protein was present within the macrogamete and was associated with the developing oocyst wall. The macrogamete is characterised by two types of structurally distinct wall forming bodies (WFB1 and 2). However, by immuno-electron microscopy, it was possible to identify two populations of dense granules (WFB1) which appear to form sequentially during macrogamete development. The first granules to form (WFB1a) stained positively with anti-MIC4 and were followed by MIC4 negative granules (WFB1b). During oocyst wall formation, the WFB1a and b sequentially released their contents onto the surface with WFB1a material forming an anti-MIC4 positive outer veil, while the WFB1b forms the electron dense outer layer of the oocyst wall. The inner layer was formed by WFB2. Thus, for the first time, it was possible to identify two populations of dense granules (WFB1a and b) involved in the formation of different parts of the oocyst wall. It was not possible to analyse the contents of macrogametes by western blot to unequivocally identify the antigen recognised by the polyclonal antisera as MIC4.     

Studies on the Ontogeny of the Pollinium of Goodyera Procera

Using light, transmission and scanning electron microscopy, the development of the pollinium of Goodyera procera (Ker-Gawler) Hooker. was investigated. At the early stage, sporogenous cells inside the microsporangium were seen grouping together into small aggregates each containing few cells. After the aggregates have formed the sporogenous cells inside the aggregates (which could now be called massulae) divide to form numerous pollen mother cells. Later, the pollen mother cells undergo meiosis to form tetrads. The pattern of formation of the exine of tetrads varies according to the location of the tetrads inside the micro- sporangium. Those tetrads that are situated near the outer region of the massulae can form: exine with well developed tectum, bacula and foot layer; and the sequence of events leading to the formation of this type of well developed exine is as follows the original wall and the cyto- plasmic channels associated with the wall become surrounded by a thick layer of callose thus isolating the wall from the plasmalemma. Near the plasmalemma a layer of primexine containing callose and cellulose begins to form. Later, the primexine develops into exine and between the exine and plasmalemma a layer of intine is laid down. Similar type of exine with well developed tectum, bacula and foot layer, is also present in tetrads facing the tapetum. But in this case the original wall of the tedtrad is not retained but undergoes dissolution and in its place a new exine formed. The pattern of formation of exine in the region between tetrads is even more different. Here the original wall also undergoes dissolution but instead of forming a proper exine it only forms a thin foot layer with bulges at places. The pattern of formation of the exine in the cells inside the tetrad is even more different. Here the original wall of the cells only undergoes partial dissolution. The loose fibrils of the partially dissolved wall then become mixed with the callose layer surrounding the cell. Inside this wall-fibril/callose mixture thin sheets of exine appear, but these thin sheets of exine do not develop further into tectum or bacula. In Goodyera a quite substantial amount of callose is retained in the regions between massulae and tetrads, and we believe that it is this callose which is holding the massulae and tetrads together to form pollinium.     

Development of Babesiosoma stableri (Dactylosomatidae; Adeleida; Apicomplexa) in its Leech Vector (Batracobdella picta) and the Relationship of the Dactylosomatids to the Piroplasms of Higher Vertebrates

The sporogonic and merogonic development of Babesiosoma stableri Schmittner & McGhee, 1961 within its definitive host and vector, a leech Batracobdella picta (Verrill, 1872), was studied by light and electron microscopy. Gamonts released from frog erythrocytes in the blood meal of the leech associated in syzygy and fused; the gamonts were isogamous and only 1 microgamete was formed. The ultrastructural appearance of the resulting zygote was similar to that of the gamonts, but it was larger. The zygote had an apical complex (including a polar ring, conoid and 2 pre-conoidal rings and micronemes, but no recognizable rhoptries), triple-membraned pellicle, about 40 subpellicular microtubules and prominent stores of amylopectin. Zygotes penetrated the cells of the intestine and underwent sporogony directly within the cytosplasm of the ieech epithelial cell without the formation of a parasitophorous vacuole. Eight sporozoites budded simultaneously around the periphery of an irregularly shaped oocyst. No oocyst wall was formed. Each sporozoite had a complete apical complex (including rhoptries), abundant amylopectin inclusions and a triple-membraned pellicle with about 32 subpellicular microtubules. The sporozoites initiated merogonic replication primarily within the salivary cells of the leech although other tissues, such as muscle, were infected. Each meront produced 4 merozoites by simultaneous budding, forming a cruciform meront typical of the intraerythrocytic development of this parasite. The meront was located directly within the cytoplasm of the host cell. Merozoites, with abundant amylopectin, had a complete apical complex and triple-membraned pellicle with about 40 subpellicular microtubules. The merozoites either initiated a further cycle of replication, or they moved into the ductules of the leech salivary cells which extend to the tip of the proboscis. Observations on gametogenesis. syngamy and sporogony of B. stableri in its leech host indicate that the family Dactylosomatidae should be placed in the suborder Adeleina (Eucoccidiida: Apicomplexa). Babesiosoma stableri was transmitted to uninfected frogs (Rana spp.) by the bite of infected leeches. Prepatent periods ranged from 26 to 38 days at 25° C. Despite a directed search in laboratory reared tadpoles which had each been injected intraperitoneally with 150,000 merozoites, no pre-erythrocytic developmental stages were observed. Similarities in their biology suggest close phylogenetic affinities of the dactylosomatids, and other adeleid blood parasites, with the piroplasms of higher vertebrates.     

Immunogold localization of circumsporozoite protein of the malaria parasite Plasmodium falciparum during sporogony in Anopheles stephensi midguts

The occurrence of the circumsporozoite (CS) proteins of Plasmodium falciparum sporozoites was monitored during sporogonic development in Anopheles stephensi mosquitoes. Using a monoclonal anti-CS protein antibody (3Sp2) and immunogold labeling on ultrathin cryosections it was found that CS protein is synthesized in immature oocysts from day 6 onwards when there are not yet signs of sporozoite formation. The CS protein is rapidly incorporated in the oocyst plasmalemma, which subsequently invaginates into the parasite. In the oocyst only the external sporozoite membrane contains CS protein. The inner pellicle membranes, rhoptries and micronemes do not react with monoclonal antibody (MoAb) 3Sp2.     

Fine Structure of the Oocyst Walls of Isospora serini and Isospora canaria and Excystation of Isospora serini From the Canary, Serinus canarius L.

SYNOPSIS. Oocysts of Isospora serini and Isospora canaria , from the canary Serinus canarius , were broken, added to a cell suspension, fixed in Karnovsky's fluid, and studied in the electron microscope. The oocyst wall of each species had an electronlucent inner layer, a more osmiophilic middle layer and an outer layer of electron-lucent ( I. serini ) or electron-dense material interspersed with some electron-lucent material ( I. canaria ). A few, relatively large lipid-like bodies were present in the outer or middle layer of the oocyst wall of I. canaria. As many as 9 membranes were present in the oocyst wall of I. canaria and 3 in that of I. serini. When exposed to a trypsin-sodium taurocholate fluid, sporozoites of I. serini excysted from 5-month-old sporocysts in vitro , but not from sporocysts stored for more than 6 months. No excystation occurred in 15-month-old I. canaria sporocysts. Similarities and differences in excystation between I. serini and other Isospora, Eimeria , and Sarcocystis species are discussed.     

Ultrastructure of asci,ascospores, and spore release inLophodermella sulcigena (Rostr.) v. Hohn.

Summary The croziers were formed from large multinucleate cells at the base of the hysterothecium. The diploid ascus had basal and apical vacuoles and there was prominant endoplasmic reticulum near the extending tip of the ascus. The spore delimiting membranes were continuous with the plasmalemma and possibly arose from it. The spore walls were formed between the two membranes. The ascus had a simple apical ring around a thinner region of the wall which became the pore through which the spores were released. Just before spore release the outer layer of the ascospore wall became vesiculated and eventually mucilagenous. The long clavate ascospores were released one at a time, stretching the neck of the ascus as they emerged.     

Fine structure of the oocyst walls of Isospora serini and Isospora canaria and excystation of Isospora serini from the canary, Serinus canarius L.

Oocysts of Isospora serini and Isospora canaria, from the canary Serinus canarius, were broken, added to a cell suspension, fixed in Karnovsky's fluid, and studied in the electron microscope. The oocyst wall of each species had an electron-lucent inner layer, a more osmiophilic middle layer and an outer layer of electron-lucent (I. serini) or electron-dense material interspersed with some electron-lucent material (I. canaria). A few, relatively large lipid-like bodies were present in the outer or middle layer of the oocyst wall of I. canaria. As many as 9 membranes were present in the oocyst wall of I. canaria and 3 in that of I. serini. When exposed to a trypsin-sodium taurocholate fluid, sporozoites of I. serini excysted from 5-month-old sporocysts in vitro, but not from sporocysts stored for more than 6 months. No excystation occurred in 15-month-old I. canaria sporocysts. Similarities and differences in excystation between I. serini and other Isospora, Eimeria, and Sarcocystis species are discussed.     

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.     

Ultrastructural studies of microgametogenesis and macrogametogenesis of Eimeria truncata of the lesser snow goose

Microgamonts and macrogamonts of Eimeria truncata were observed in renal epithelial cells of collecting tubules and ducts and occasionally in macrophages of experimentally infected lesser snow geese (Anser c. caerulescens) beginning 8.5 days post inoculation. Intraparasitophorous vesicles in parasitophorous vacuoles of both types of gamonts appeared to originate in host cell cytoplasm and enter gamonts through micropores by budding of plasmalemma or by pinocytosis. Within the parasite's cytoplasm, the vesicles were broken down in Golgi-associated vacuoles. The surfaces of microgamonts were highly invaginated to facilitate extrusion of numerous microgametes. Formation and maturation of microgametes were similar to those of other eimerian species. Each microgamete had two flagella, a mitochondrion, and a peculiarly shaped electron-dense nucleus that was oval anteriorly in cross section and somewhat dumbbell-shaped posteriorly. A longitudinally arranged inner membrane complex lay between a portion of the mitochondrion and the plasmalemma. About five subpellicular microtubules extended the length of the microgamete body. Macrogametogony differed little from that described in other eimerian species. Type 1 wall-forming bodies (WFB) formed in Golgi complexes early in macrogametogony, and type 2 WFB formed in cisternae of endoplasmic reticulum in intermediate stages of macrogamont development.     

SIEVE-ELEMENT ULTRASTRUCTURE IN PLATYCERIUM BIFURCATUM AND SOME OTHER POLYPODIACEOUS FERNS: THE NACREOUS WALL THICKENING AND MATURATION OF THE PROTOPLAST

Sieve elements of various ages were examined in petioles and midribs of Platycerium bifurcatum (Cav.) C. Chr. and Phlebodium aureum (L.) J. Sm., only older ones in similar parts of leaves of Polypodium schraderi Mett. and Microgramma lycopodioides (L.) Copel. Nacreous walls apparently are formed by most, if not all, protophloem and metaphloem sieve elements in all four species. In Platycerium and Phlebodium nacreous wall formation is closely correlated with the appearance of numerous membranes or vesicles in the region of the wall. These extracytoplasmic membranes apparently are derived from protrusions of the plasmalemma. After the nacreous layer is fully thickened, many endoplasmic reticulum (ER) membranes apparently end up outside the plasmalemma of Platycerium, where they degenerate and gradually intergrade in appearance with the fibrillar material comprising the nacreous thickening. In Phlebodium, Polypodium, and Microgramma the ER forms multivesicular bodies. As the cells approach maturity, the membranes delimiting the multivesicular bodies fuse with the plasmalemma and their vesicular contents, which are not discharged into the region of the wall, disappear. Gradually, the nacreous layer decreases in thickness and disappears. At maturity the enucleate sieve-element protoplasts of all four species are essentially similar. They are lined by a plasmalemma and a parietal, anastomosing network of ER and contain both plastids and mitochondria. The plastids in Polypodium and Microgramma are chloroplasts, but those in Platycerium and Phlebodium lack grana and intergrana lamellae.     

Ultrastructural Studies of Microgametogenesis and Macrogametogenesis of Eimeria truncata of the Lesser Snow Goose1

ABSTRACT. Microgamonts and macrogamonts of Eimeria truncata were observed in renal epithelial cells of collecting tubules and ducts and occasionally in macrophages of experimentally infected lesser snow geese (Anser c. caerulescens) beginning 8.5 days post inoculation. Intraparasitophorous vesicles in parasitophorous vacuoles of both types of gamonts appeared to originate in host cell cytoplasm and enter gamonts through micropores by budding of plasmalemma or by pinocytosis. Within the parasite's cytoplasm, the vesicles were broken down in Golgi-associated vacuoles. The surfaces of microgamonts were highly invaginated to facilitate extrusion of numerous microgametes. Formation and maturation of microgametes were similar to those of other eimerian species. Each microgamete had two flagella, a mitochondrion, and a peculiarly shaped electron-dense nucleus that was oval anteriorly in cross section and somewhat dumbbell-shaped posteriorly. A longitudinally arranged inner membrane complex lay between a portion of the mitochondrion and the plasmalemma. About five subpellicular microtubules extended the length of the microgamete body. Macrogametogony differed little from that described in other eimerian species. Type 1 wall-forming bodies (WFB) formed in Golgi complexes early in macrogametogony, and type 2 WFB formed in cisternae of endoplasmic reticulum in intermediate stages of macrogamont development.     

Discharge papilla development in the phycomycete Allomyces

The process of discharge papilla (DP) formation in Allomyces macrogynus was studied by light and electron microscopy. The plug of the DP was first deposited between the plasmalemma and the wall of the zoosporangium (ZS). The wall above the plug subsequently was eroded away. Deposition of a new inner wall layer in the sporangium held the plug in place and thickening of the layer formed a collar around the plug. Further deposition of material after this stage resulted in the characteristic pulley-shape. The plug material appeared homogeneous in electron micrographs but there was evidence of an outer layer. Digestion of the plug at the time of spore release was from within.Abbreviations DP discharge papilla - ZS zoosporangium