Ultrastructural Features of the Apical Complex,Pellicle, and Membranes Investing the Gamonts of Haemogregarina magna (Apicomplexa: Adeleina)1

ABSTRACT. Mature gamonts of Haemogregarina magna lie within a type of parasitophorous vacuole (Pv) apparently unique to the haemogregarines. The cytoplasm of infected erythrocytes was separated from the parasite by two Pv membranes. An additional membrane, coated on both sides with electron-dense material, closely invested the gamonts. The apical complex of the gamonts includes a conoid, two preconoidal rings, and an elaborate polar ring complex. The latter consisted of the polar ring and approximately 78 posteriorly directed, radially arranged, “tine-like” structures which fuse as they merge anteriorly into the polar ring. Freeze fracture replicas demonstrated that the pellicle of gamonts of H. magna was structurally similar to that of other apicomplexans. The closely apposed inner membranes of the pellicle formed plates which were arranged into strips along the long axis of the gamont. Calculations indicated that 13 such strips are found around the circumference of the gamonts with about six subpellicular microtubules associated with the inner surface of each strip. Gamonts of H. magna share many structural similarities with the kinetes, ookinetes, and sporokinetes of other apicomplexans. We propose that the conoid and polar ring complex are fundamental features of all apicomplexan “kinetes.”     

Ultrastrukturen Und Cytochemie Der Pellikula Und Des Apikalkomplexes Der Kineten Von Babesia Bigemina Und Babesia Ovis In Hämolymphe Und Ovar Von Zecken*,†

SYNOPSIS The term kinete is used in this paper for the cigar-shaped, motile development stages (“vermicule”) of Babesia occurring intra- and extracellularly in hemolymph and ovary (including oocytes) of vectors, hard ticks (Ixodoidea). The structure of, and cyto-chemical activities of hydrolases (acid phosphatase, nonspecific esterase) in the pellicle and the apical complex were studied at the fine-structural level in kinetes of Babesia bigemina Smith & Kilborne, in hemolymph of female Boophilus microplus Canestrini. The cytochemistry of acid hydrolases was studied also in kinetes of Babesia ovis (Babes) Starcovici, in hemolymph and ovary of Rhipi-cephultis bursa Canestrini & Fanzago. The pellicle of the B. bigemina kinetes is composed of 3 membranes (pellicular complex): an outer membrane, ?8 nm thick (the plasmalemma) and 2 inner ones, each ?6 nm thick, lying closely together. The outer membrane appears to be covered by a structureless coat, 3 nm thick. The space between the inner double membrane and the plasmalemma is 7.5 nm. The whole pellicular complex is 30 nm in diameter. The 2 inner pellicular membranes appear to be derived from the endoplasmic reticulum (ER) for the following reasons: (a) a layer of hydrolase-active material is enclosed by these membranes; (b) in the spheroid parasite stages which transform from kinetes inside hemocytes, the inner double membrane is apparently replaced by an ER cisterna; (c) the thickness of each of the inner pellicular membranes is approximately the same as that of the ER membrane. There are circular openings in the pellicular double membrane with average diameters of 100 nm; despite some similarity to micropores, they have a specific structure. The term Intrapellikularfenster (IPF) (intrapellicular windows) or pseudomicropores is proposed for these pellicular differentiations. The margin of an FPF is formed by the 2 inner membranes folding into each other; cytoplasmic, electron-dense material is accumulated alongside this edge. Unlike that of micropores, the plasmalemma of the IPF is not invaginated. The IPF appears as a single, dark ring in tangential sections. At times, rhoptry-like bodies are associated with the openings. The function of the IPF is not known. An intrapellicular opening similar to the IPF, although wider, is present at the apex of the parasite. Its margin coincides with the inner edge of the apical ring. Typical subpellicular microtubuli were not observed in the Babesia kinetes. The apical complex of the B. bigemina kinetes consists of an Apikalschirm (apical umbrella), a crown of microtubuli beneath it, and rhoptries: micronemes are also present in large numbers. The Apikalschirm is located beneath the pellicle of the apical pole of the parasite. It is a wheel-like structure composed of spokes radiating from a wide, hub-like central ring (apical ring). It should be stressed that the apical ring is not identical with the polar ring described as an integral part of the pellicular complex in other Apicomplexa. Beneath each “rib” of the Apikalschirm there is one microtubule (subcostal microtubule). In kinetes of B. ovis the “ribs” are less well developed. In addition, the Apikalschirm is more pointed in kinetes of this species in tick oocytes and ova. The rhoptries of the kinetes are spindle-shaped and largely located directly beneath the Apikalschirm. They are arranged radially, each row being associated with a “rib”. A conoid was not observed. Occasionally, low hydrolytic activity could be detected in micronemes. The rhoptries and the Apikalschirm were always negative for phosphatase and esterase activity. With regard to the number and arrangement of its membranes and to its hydrolase activity, the pellicle of the kinetes of Babesia closely resembles the pellicular complex of the Coccidia. It differs from the latter by the presence of the IFF and by the lack of micropores and of true subpellicular microtubules. In the complexity of their pellicle and in some details of the organization of their apical complex (lack of a conoid; umbrella-like structure), the kinetes of Babesia resemble the ookinetes of the Haemosporidia.     

Ultrastructure of the ookinetes of Haemoproteus meleagridis (Haemosporina: Haemoproteidae)

Ookinetes of Haemoproteus meleagridis were structurally similar to kinetes of other apicomplexan parasites and possessed a polar ring complex (PRC) composed of an electron-lucent polar ring with 25 supporting tines. Fifty subpellicular microtubules were anchored in a circle to the inner surface of the polar ring. A bilayered electron-dense canopy was continuous with the inner layer of the pellicle and formed a caplike cover over the PRC. Embedded rings of actin-sized microfilaments completely encircled each layer of the canopy. Numerous micronemes, 2 smaller preconoidal rings, and a conoid composed of approximately 6 spirally wound, electron-dense tubules were also present. Other organelles were similar to those reported in previous studies of haemosporidian ookinetes. Mature ookinetes of H. meleagridis developed in the midguts of engorged specimens of Culicoides edeni (Diptera: Ceratopogonidae) within 24 hr after a blood meal. Most parasites were found beneath, or embedded within, a peritrophic membrane composed of fine granules and fibrils. The observation of actin-sized microfilaments within the canopy is a previously unrecognized modification of the pellicle that probably supports the anterior end of ookinetes during penetration of the peritrophic membrane.     

Fine Structure of Hepatozoon mocassini (Apicomplexa,Eucoccidiorida) Gamonts and Modifications of the Infected Erythrocyte Plasmalemma1

Transmission electron microscopy and scanning electron microscopy were used to investigate the fine structure of Hepatozoon mocassini gamonts and modifications of the infected erythrocyte plasmalemma. Intraerythrocytic gamonts were contained within a parasitophorous vacuole. An electron-lucid space observed between the gamont pellicle and the membrane of the vacuole corresponded to the unstained space described in light microscopy studies. Gamonts possessed a conoid, polar ring, subpellicular microtubules, four pairs of rhoptries, micronemes, ovoid granules, mitochondria with tubular cristae, and a pellicle composed of three individual unit membranes. The conoid had an anterior diameter of 320 nm, a posterior diameter of 360 nm, and a length of 150 nm. In contrast to a report on Hepatozoon aegypti, no micropore or “canopy-like structure” was observed. The plasmalemma of infected erythrocytes exhibited two types of modifications: gross membrane deformations and knobs with an electron-dense central mass. These knobs are structurally distinct from previously described membrane excrescences.     

Ultrastructural study of developmental stages of Mattesia dispora (Neogregarinorida: Lipotrophidae), a parasite of the flour moth Ephestia kuehniella (Lepidoptera)

The ultrastructure of merozoites, gamonts and oocysts of the neogregarine Mattesia dispora and their development in larvae of the flour moth Ephestia kuehniella were studied by electron microscopy. The apical complex of free macronuclear merozoites was very distinct in micrographs of sections, the polar rings being especially prominent. Two gamonts associated in head-to-head syzygy and the apical complexes served as the contact point during pairing. At this stage the rhoptries became reduced and the conoid widened. The gamonts had a foam-like appearance in the light microscope. Paired gamonts formed an envelope and developed into a gametocyst, within which the gamonts were separated by a distinct border. Four gametes and two residual cells developed inside the gametocyst. The gametes were covered with a single membrane. The gametes fused in pairs to form two spherical zygotes, each covered by two membranes and with one large nucleus. The external layer appeared more undulated than the inner one. A single membrane covered each residual cell. Walls were formed around both zygotes to produce two oocysts. Each mature oocyst was lemon-shaped with polar plugs and eight peripheral sporozoites, which had a pellicle similar to that of the merozoites, lay beneath the thick oocyst wall.     

Observations on the ultrastructure of Haemogregarina simondi in the marine flatfish Solea solea (L.).

Developing stages of Haemogregarina simondi from the marine fish Solea solea (L.) were examined by electron microscopy. Merozoites lay in a parasitophorous vacuole and were bound by a pellicle of three unit membranes beneath which lay a ring of 45--61 microtubules. The cytoplasm contained 4--6 rhoptries, more than 169 micronemes, several mitochondria, and amylopectin granules. A conoid and one polar ring were observed at the anterior end. Intraleucocytic and intraerythrocytic schizonts with up to eight merozoites were described also. Intraerythrocytic and free gametocytes were characterized by distinct refractile bodies and a pellicle consisting of only two unit membranes. The number of micronemes was in excess of 194. The results were discussed in comparison with other members of the Haemogregarinidae.     

Cytoskeleton of Toxoplasma gondii

The cytoskeleton of Toxoplasma gondii was studied by electron microscopy using whole mounts of detergent-extracted parasites and thin sections of routine preparations, tannic acid-stained organisms, and detergent-extracted parasites. In whole mounts, the spiral arrangement of the 22 pellicular microtubules closely corresponded to the pattern of surface ridges seen previously by scanning electron microscopy and reflected the torsion of the parasite body during locomotion. The microtubules had free posterior ends and were anchored anteriorly in the polar ring, presumed to be a microtubule organizing center (MTOC). The insertions of the microtubules were supported by blunt projections of the polar ring, forming a cogwheel pattern in transverse view. The internal microtubules had 13 protofilaments and were twice the length of the conoid. They extended through the conoid and ended at the anterior preconoidal ring, presumably a second MTOC. The subunits of the conoid were arranged in a counterclockwise spiral when traced from base to tip, as were the pellicular microtubules. We postulate that as the conoid moves, the polar ring complex moves along the spiral pathway of the conoid subunits. Retraction of the conoid would then rotate the polar ring, producing the torsion of the body we observed by SEM.     

A Comparative Electron Microscopic Study of the Morphology of Toxoplasma gondii by Freeze-Etch Replication and Thin Sectioning Technic

SYNOPSIS. Freeze-etch preparations of Toxoplasma gondii reveal details of structure and organelles in 3-dimensional relationships. The subpellicular microtubules and their relationship to the polar ring, the tripartite pellicle, the pellicle constituents, and the spatial relationship of the rhoptries to the conoid and conoid canal are clearly demarcated.     

Cytoskeleton of Toxoplasma gondii1

The cytoskeleton of Toxoplasma gondii was studied by electron microscopy using 1) whole mounts of detergent-extracted parasites and 2) thin sections of routine preparations, tannic acid-stained organisms, and detergent-extracted parasites. In whole mounts, the spiral arrangement of the 22 pellicular microtubules closely corresponded to the pattern of surface ridges seen previously by scanning electron microscopy and reflected the torsion of the parasite body during locomotion. The microtubules had free posterior ends and were anchored anteriorly in the polar ring, presumed to be a microtubule organizing center (MTOC). The insertions of the microtubules were supported by blunt projections of the polar ring, forming a cogwheel pattern in transverse view. The internal microtubules had 13 protofilaments and were twice the length of the conoid. They extended through the conoid and ended at the anterior preconoidal ring, presumably a second MTOC. The subunits of the conoid were arranged in a counterclockwise spiral when traced from base to tip, as were the pellicular microtubules. We postulate that as the conoid moves, the polar ring complex moves along the spiral pathway of the conoid subunits. Retraction of the conoid would then rotate the polar ring, producing the torsion of the body we observed by SEM.     

Light and Electron Microscopic Observations on the Intraerythrocytic Development of Babesiosoma stableri (Apicomplexa,Dactylosomatidae) in Frogs from Algonquin Park,Ontario1

ABSTRACT. The intraerythrocytic development and ultrastructure of Babesiosoma stableri Schmittner & McGhee, 1961 are described from Rana catesbeiana and Rana septentrionalis from Algonquin Park, Ontario. Morphometric and chronological observations on B. stableri in an experimentally infected Rana pipiens support the hypothesis that two successive types of merogonic cycles occur within the erythrocytes of infected frogs; the first cycle gives rise to the second and the second cycle produces merozoites destined to become gamonts. Merozoites, meronts, and gamonts are described by light and electron microscopy. Merozoites are typically coccidian and have a trilaminate pellicle with micropores, approximately 40 sub-pellicular microtubules, an apical and posterior polar ring, a conoid with two accessory rings and a pair of intra-conoidal microtubules, three rhoptries and numerous micronemes, and a nucleus with a nucleolus and a paranuclear Golgi body. The gamonts are larger than merogonic stages and are isogamous. They have approximately 55 sub-pellicular microtubules and large stores of amylopectin. These observations indicate that the genus Babesiosoma should be transferred from the Family Haemohormidiidae (Piroplasmida, Piroplasmia) to the Family Dactylosomatidae (Eucoccidiida, Coccidia).     

Fine Structure of Sporozoites of Eimeria nieschulzi*

SYNOPSIS. An electron microscope study of sporozoites of Eimeria nieschulzi Dieben, 1924 revealed that they have a pellicle which is thickened at the anterior end to form 2 polar rings. Radiating posteriorly from the rings, directly beneath the pellicle, are approximately 25 microtubules which may aid in support and locomotion of the sporozoite. Within the polar ring is a dense conoid. Numerous toxonemes extend posteriorly from the area of the conoid. Two paranuclear bodies are present and some toxonemes are closely associated with the anterior body. Numerous ribosomes, bodies containing granular material, and osmiophilic vesicle bounded bodies are also present. Each sporozoite has a single nucleus with a diffuse karyosome and distinct nuclear double membrane.     

Ultrastructural and Cytologic Studies of the Sporozoites of Four Eimeria Species*

SYNOPSIS. Studies were made with the light microscope of live sporozoites of E. ninakohlyakimovae and E. ellipsoidalis as well as sporozoites fixed with Schaudinn's, Stieve's and Zenker's fluids, methanol and ethanol saturated with picric acid. Sporozoites were stained with Giemsa, bromphenol blue, modified PAS-AO, Feulgen, Harris’hematoxylin and eosin Y, and iron hematoxylin. Sporozoites of the above species as well as those of E. auburnensis and E. bovis were also fixed with glutaraldehyde and osmium tetroxide or negatively stained for study with the electron microscope. Living sporozoites had gliding, pivoting, flexing, and probing movements. Each sporozoite of each species was covered by a pellicle consisting of an outer limiting unit membrane that was continuous around the sporozoite and an inner membrane that terminated at the polar ring. Twenty-four subpellicular microtubules were longitudinally arranged just beneath the inner membrane. At the anterior end of the sporozoites was a protruded or retracted conoid composed of spirally-arranged fibrillar structures, 2 rings anterior to the conoid, and the polar ring, a thickening at the anterior termination of the microtubules and inner membrane. Other organelles observed with the electron microscope were a nucleus with or without a net-like nucleolus, club-shaped organelles, refractile bodies, micronemes, endoplasmic reticulum, Golgi apparatus, mitochondria with tubular cristae, micropores, lipoid-like bodies, oval polysaccharide bodies and ribosomes. The fine structure of these sporozoites is compared to that of related Sporozoa.     

Fine Structure of Haemoproteus columbae Kruse During Differentiation of the Ookinete*

Ookinete differentiation begins in vitro～1 hr after blood infected with mature gametocytes of Haemoproteus columbae is withdrawn from a pigeon. In the undifferentiated zygote, dense material accumulates at the point under the plasma membrane. The conoid and conoidal rings condense from this material. The nucleus is drawn out to a point with the intranuclear spindle (INS) at the peak. Atypical centrioles lie under the forming conoid in the cytoplasm next to the INS. Fibrous material under the inner membrane forms the polar ring from which subpellicular microtubules originate. One hr later the centrioles have disappeared and the nucleus has returned to the center of the organism. The conoidal complex forms the tip of a growing cytoplasmic projection, the anterior end of the ookinete. During this time an elaborate pellicle is differentiating antero-posteriorly; crystalloid formation begins with an extensive proliferation of rough endoplasmic reticulum (ER) continuous with the outer membrane of the nuclear envelope. Crystalloid particles are formed between the lamellae of the ER and collected in a sphere that is later partially surrounded by a small amount of ER. Ookinetes, differentiated 2 hr longer than the ookinetes in vitro, were obtained from the gut of the pigeon fly, Pseudolynchia maura. The differentiated pellicle of these ookinetes consists of a plasma membrane, an inner membrane layer composed of 2 appressed membranes, and in the anterior end, an electron-opaque lamina immediately under the inner membrane. Anterior to the polar ring, this lamina forms a canopy which, posteriorly, is drawn out into projecting ribs which diminish and disappear in the first third of the organism. Fifty to 60 subpellicular microtubules insert on the polar ring. Ookinetes differentiated in vitro were no more than 4 hr old. They lacked micronemes and retained a pellicular cytostome and “internal cytostomes.” The differentiation of micronemes probably occurs at a later time because they are visible after 6 hr in ookinetes in the fly gut. So many degenerating organisms appeared in vitro after 5 hr that this material was discarded.     

Ultrastructure of Sarcocystis tenella. I. Endozo?te (after negative staining]

The employment of negative staining technics for the endozoites (cyst stages) of Sarcocystis tenella allowed the elucidation of certain aspects of their fine structure. The conoid consists of similar to 20 oblique fibers and is surmounted by a ring with regular ornamentation. In the conoid's interior there are 2 excentric parallel microtubules which extend posteriorly for a considerable distance into the adjacent cytoplasm. The fibers of the conoid, intraconoid microtubules, appear to have the same diameter and structure as the 22 subpellicular microtubules. They are "cemented" anteriorly into a periconoidal ring which surrounds the conoid. The "reticulated" pellicle has certain differentiations: the micropore, surrounded by a "fibrillar" element, similar to 10 subcircular structures arranged into an anterior crown, and 11 rows of granules converging toward the posterior end. The sarconemes look like rice grains which, contrary to previous statements, are independent of one another. It is established that there are only 2 rhoptries.     

Fine Structure of Schizonts and Merozoites of Eimeria nieschulzi*

SYNOPSIS. Schizonts of E. nieschulzi lie in a vacuole within the host cell. After nuclear division the cell membrane invaginates forming merozoites. Differentiation of the pellicle and other organelles occurs while merozoites are still attached to the schizont cytoplasm. Merozoites have a pellicle thickened at the anterior end to form a polar ring. Radiating posteriorly from the ring, directly beneath the pellicle, are about 25 microtubules. Within the polar ring is a dense conoid. Extending posteriorly from within the conoid is a paired organelle. The paired organelle varies in size and shape in each generation of merozoites. Numerous toxonemes occupy the anterior half of the merozoites. Two paranuclear bodies are present in 1st generation merozoites. One or 2 granular bodies were seen in the anterior end of 2nd generation merozoites. In 3rd generation merozoites 6 or more granular bodies were seen anterior to the nucleus. Each merozoite has a single nucleus containing diffuse chromatin material. Elongate mitochondria and glycogen granules are present. The vacuole surrounding mature merozoites contains residual cytoplasm of the schizont and some granular material. Microvilli project into the vacuole from the host cell membrane.     

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.     

The Fine Structure of the Sporozoite of Lankesteria culicis

SYNOPSIS. The sporozoite of Lankesteria culicis was studied by light and electron microscopy, after excystation in the intestine of Aedes aegypti 1st stage larvae. The sporozoite was 9.5–10.0 μ long with a blunt anterior end and a tapered posterior region. The organism was enclosed by a typical pellicle consisting of an outer and an inner membrane with underlying subpellicular microtubules. The anterior end had a conoid with 2 associated rings, a polar ring which served as a termination of the subpellicular microtubules and a flask-shaped structure situated internal and posterior to the conoid. A micropyle consisting of a collar formed from the inner membrane and lacking an invagination of the outer membrane was present near the anterior end of the parasite. The nucleus was centrally located and had a peripheral concentration of chromatin and a central nucleolus. One or more mitochondria were observed in the vicinity of the nucleus.     

Protococcidian Eleutheroschizon duboscqi,an Unusual Apicomplexan Interconnecting Gregarines and Cryptosporidia

This study focused on the attachment strategy, cell structure and the host-parasite interactions of the protococcidian Eleutheroschizon duboscqi, parasitising the polychaete Scoloplos armiger. The attached trophozoites and gamonts of E. duboscqi were detected at different development stages. The parasite develops epicellularly, covered by a host cell-derived, two-membrane parasitophorous sac forming a caudal tipped appendage. Staining with Evans blue suggests that this tail is protein-rich, supported by the presence of a fibrous substance in this area. Despite the ultrastructural evidence for long filaments in the tail, it stained only weakly for F-actin, while spectrin seemed to accumulate in this area. The attachment apparatus consists of lobes arranged in one (trophozoites) or two (gamonts) circles, crowned by a ring of filamentous fascicles. During trophozoite maturation, the internal space between the parasitophorous sac and parasite turns translucent, the parasite trilaminar pellicle seems to reorganise and is covered by a dense fibrous glycocalyx. The parasite surface is organised in broad folds with grooves in between. Micropores are situated at the bottom of the grooves. A layer of filaments organised in bands, underlying the folds and ending above the attachment fascicles, was detected just beneath the pellicle. Confocal microscopy, along with the application of cytoskeletal drugs (jasplakinolide, cytochalasin D, oryzalin) confirmed the presence of actin and tubulin polymerised forms in both the parasitophorous sac and the parasite, while myosin labelling was restricted to the sac. Despite positive tubulin labelling, no microtubules were detected in mature stages. The attachment strategy of E. duboscqi shares features with that of cryptosporidia and gregarines, i.e. the parasite itself conspicuously resembles an epicellularly located gregarine, while the parasitophorous sac develops in a similar manner to that in cryptosporidia. This study provides a re-evaluation of epicellular development in other apicomplexans and directly compares their niche with that of E. duboscqi.     

Toxoplasma gondii: ultrastructure and antigenicity of purified tachyzoite pellicle.

When purified Toxoplasma gondii tachyzoites were treated with hemolysin, DNase, and RNase, the organisms yielded a three-component system containing the outer membrane (pellicle), microtubules, and conoid in relatively normal morphological configuration. Further treatment of this preparation with protease digested all but the pellicle which was more collapsed in appearance. These two preparations were used in rabbit anti-toxoplasma and goat anti-rabbit ferritin labeling experiments. The three-component system showed ferritin label on the conoid and equal ferritin label on the outer and inner surfaces of the pellicle. The microtubules were unlabeled. The pellicle after protease treatment was labeled equally on its outer and inner surfaces, which indicated that the rabbit anti-toxoplasma serum contained antibodies against antigens on the outer and inner surfaces of the pellicle.     

The Fine Structure of Haemoproteus columbae Sporozoites*

SYNOPSIS. The fine structure of Haemoproteus columbae sporozoites has been studied and compared to sporozoite structure as revealed by the light microscope. The sporozoites are ultrastructurally similar to those of other Haemosporidia in that they possess a 3-layered pellicle, subpellicular microtubules, polar ring, micropore, free ribosome-like particles, micronemes, a structure resembling a Golgi complex, an irregular mitochondrion, and a large nucleus. In the anterior region of the sporozoite there are 21–22 regularly arranged longitudinal subpellicular microtubules located peripherally around the cell. In the apical region the microtubules appear thickened on 1 side. The sporozoite of H. columbae has a microneme system in which 1–3 micronemes are associated with the outer pellicular membrane at the anterior end. Micronemes are found throughout the cytoplasm, but occur in greater concentration in the anterior region of the sporozoite. A clear pellicular cavity, located between the polar ring and the termination of the inner pellicular layer, is present at the anterior end of the sporozoite. Vesicular invaginations of the inner pellicular layer have been observed in the anterior region; their function is unknown. Spherical osmophilic bodies are found throughout the cytoplasm.