Septate Gregarines From Reticulitermes Flavipes and Reticulitermes Virginicus (Isoptera: Rhinotermitidae)

ABSTRACT. The gregarine parasites of Reticulitermes virginicus and Reticulitermes flavipes begin their development as trophozoites attached to the midgut epithelium by a small button-shaped epimerite. the epimerite is lost when the parasite becomes free-living in the gut lumen as a solitary gamont. Syzygy is late and was not observed. When full-grown, gamonts enter the hemocoel and fuse in pairs to form large gametocysts that are attached to the midgut of the termite by a duct. Thousands of sporocysts are formed within the original gametocyst. the mature sporocysts are released into the lumen of the midgut through the connecting duct. They are then passed out with the feces. These gregarines are believed to be identical to Gregarina termitis Leidy which was described from a single gamont and later erroneously placed in the genus Hirmocystis by Henry.     

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.     

PSEUDOBRYOPSIS MYURA AND ITS REPRODUCTION

Pseudobryopsis myura, type of the genus, is monoecious; male and female gametocysts occur on the same plant; there is definite anisogamy and only macrogametes possess a stigma. The mode of extrusion of the gametes differs both from the Bryopsis-type and from the Codium-type. As in Codium the discharge of the gametocyst is due to internal pressure. Gametes become motile only after their extrusion from the gametocyst.     

Cytology of Leidyana canadensis (apicomplexa: eugregarinida) in Lambdina fiscellaria fiscellaria larvae (lepidoptera: geometridae)

The eugregarine Leidyana canadensis infects the larval gut of the eastern hemlock looper, Lambdina fiscellaria fiscellaria. Guts of infected larvae were chemically fixed, embedded in epoxy resin, and sectioned for light and electron microscopy to describe the cytology of L. canadensis and its pathology in the larval host. Oocysts of L. canadensis are ingested by larval hemlock looper. Trophozoites emerge from the oocysts, pass through the peritrophic membrane into the ectoperitrophic space, and attach to the epithelium of the midgut by means of an apical epimerite. The epimerite does not actually penetrate the affected epithelial cell; instead, it causes an invagination of the plasma membrane of the cell. The center of the epimerite contains membrane cisternae, and mitochondria line its periphery. Microtubules and mitochondria in the host cell cytoplasm surround the epimerite. At the light microscopic level, there appeared to be septa between the epimerite and the protomerite and between the protomerite and the deutomerite; however, in the electron microscope, no septa were evident. Only differences in the concentrations and nature of the inclusions in the cytoplasms of these three regions were apparent. The deutomerite contains a single nucleus in the central-posterior area. After an undetermined period, the epimerite detaches from the host gut epithelium and is withdrawn into the protomerite, and the trophozoites float freely in the ectoperitrophic space before differentiating into gamonts. Division of the single, large nucleus into numerous small nuclei appears to occur prior to syzygy. Gamonts pair and a cyst wall is laid down around them, forming a gametocyst. Oocysts are extruded from mature gametocysts, in chains, through sporoducts.     

Host-parasite relationships of Ascogregarina chagasi (Eugregarinorida, Aseptatorina, Lecudinidae) in Lutzomyia longipalpis (Diptera: Psychodidae)

The life cycle of Ascogregarina chagasi in larvae and in adult female Lutzomyia longipalpis was studied by light and electron microscopy. Sporozoites and young gamonts were attached to the epithelial lining of the larval midgut via an osmiophilic contact zone. The mucron of young gamonts was bordered by an invaginated pellicular fold, and an electron-opaque vesicular structure was observed adjacent to it. Sporozoites possessed an apical complex and were bound by a double membrane with underlying subpellicular microtubules. The gamont pellicle was uniformly corrugated and consisted of two cortical membranes and a plasma membrane. Mature gamonts and gametocysts were found in the posterior ectoperitrophic space of third and fourth instar larval midguts and in the haemocoel of adult flies. Gametocysts in adult females adhered to the genital accessory glands, where they were encased in electron-dense capsules secreted by the fly through haemocyte-mediated humoral immune reactions. Oocytes were spindle-shaped and bound by a double-layered wall with a discernible polar plug at each end. Sporulation was endogenous, occurring within gametocysts in the midguts of larvae or the accessory glands of adult females. FITC-phalloidine staining of all stages of A. chagasi except mature gametocysts produced bright fluorescence, indicating the presence of a diffuse, actin-like protein in the cytoplasm.     

Gametogenesis and Sporogony of Hepatozoon Mocassini (Apicomplexa: Adeleina: Hepatozoidae) In an Experimental Mosquito Host, Aedes Aegypti

ABSTRACT. The sexual life cycle of the hemogregarine Hepatozoon mocassini was studied in Aedes aegypti , an experimental mosquito host, using transmission electron microscopy. Gamonts were observed leaving the host snake erythrocyte as early as 30 min after mosquitoes ingested infected blood, and some gamonts had penetrated the gut epithelial cells by this time. Six hours post-feeding, gamonts were identified within cells of the abdominal fat body. Twenty-four hours post-feeding, gamonts were often entrapped within the peritrophic membrane, but were no longer observed within the gut wall. Parasites pairing up in syzygy and undergoing sexual differentiatioe were observed within fat cells at this time, and by 48 hours post-feeding, well-developed macro- and microgametocytes as well as microgametes were discernible. Developing zygotes observed 3 days post-feeding were enclosed within a panoitophorous vacuole. By day 6, multinucleate oocysts with crystalloid bodies in the cytoplasm were seen. Sporazoites developing within sporocysts appeared by day 12. Seventeen days post-feeding, mature oocysts with sporocysts containing approximately 16 sporozoites were observed upon dissection of mosquitoes. Large crystalloid bodies no longer bound by rough endopbsmic reticulum were located anterior and posterior to the sporozoite nucleus. Free sporozoites were not observed.     

Ultrastructural observations on fertilization and sporulation in Goussia iroquoina (Molnar and Fernando, 1974) in experimentally infected fathead minnows (Pimephales promelas, Cyprinidae)

The ultrastructural features of fertilization and sporogony of Eimeria iroquoina are described from the intestinal epithelium of experimentally infected fathead minnows (Pimephales promelas). Intact microgametes were observed in the cytoplasm of macrogametes. Within immature macrogametes the microgamete was segregated from the cytoplasm of the former by the plasma membrane of each cell plus additional membranes. Within mature macrogametes, only the plasma membranes separated the gametes. Fertilization by fusion of the limiting membrane of both gametes occurred after the entire microgamete lay within the cytoplasm of the macrogamete. The cytoplasm of the zygote cleaved into sporoblasts within cisternae of endoplasmic reticulum. The sporocystic wall was composed of an outer electron-lucent layer and an inner, thicker layer with periodic striations at right angles to the surface of the sporocyst. The sporocysts were bivalved and joined by a continuous suture. The sporozoites were morphologically similar to sporozoites and merozoites of other Coccidia. Due to the structure of the sporocyst, Eimeria iroquoina Molnar and Fernando, 1974 is amended to Goussia iroquoina (Molnar and Fernando, 1974).     

Dynamic organization of microtubules and microtubule-organizing centers during the sexual phase of a parasitic protozoan, Lecudina tuzetae (Gregarine, Apicomplexa)

Lecudina tuzetae is a parasitic protozoan (Gregarine, Apicomplexa) living in the intestine of a marine polychaete annelid, Nereis diversicolor. Using electron and fluorescence microscopy, we have characterized the dynamic changes in microtubule organization during the sexual phase of the life cycle. The gametocyst excreted from the host worm into seawater consists of two (one male and one female) gamonts in which cortical microtubule arrays are discernible. Each gamont undergoes multiple nuclear divisions without cytokinesis, resulting in the formation of large multinucleate haploid cells. After cellularization, approximately 1000 individual gametes are produced from each gamont within 24 h. Female gametes are spherical and contain interphase cytoplasmic microtubule arrays emanating from a gamma-tubulin-containing site. In male gametes, both interphase microtubules and a flagellum with "6 + 0" axonemal microtubules extend from the same microtubule-organizing site. At the beginning of spore formation, each zygote secretes a wall to form a sporocyst. Following meiotic and mitotic divisions, each sporocyst gives rise to eight haploid cells that ultimately differentiate into sporozoites. The ovoid shaped sporocyst is asymmetric and forms at least two distinctive microtubule arrays: spindle microtubules and microtubule bundles originating from the protruding apical end corresponding to the dehiscence pole of the sporocyst. Because antibodies raised against mammalian centrosome components, such as gamma-tubulin, pericentrin, Cep135, and mitosis-specific phosphoproteins, react strongly with the microtubule-nucleating sites of Lecudina, this protozoan is likely to share common centrosomal antigens with higher eukaryotes.     

Intracoelomic parasitic Sporozoa in the burrowing spatangoid echinoidEchinocardium cordatum: coelomocyte reaction and formation of brown bodies

Echinocardium cordatum frequently harbours in its coelomic cavity the protozoan parasiteLithocystis schneideri. Motile stages of this gregarine (trophozoites and gamonts) may be surrounded by echinoid coelomocytes which show a peculiar transformation of their shape (i.e. each cell develops a single spine-like extension giving a pincushion aspect to the parasite). Encysted stages of the gregarine (gametocysts and sporocysts) are found mostly within brown bodies. Brown bodies are particular mesothelium-covered formations occurring usually in the coelomic cavity ofE. cordatum. It is suggested that brown bodies naturally originate from detached fragments of mesenteries.     

The response of Gregarina niphandrodes (Apicomplexa: Eugregarinida: Septatina) to host starvation in Tenebrio molitor (Coleoptera: Tenebrionidae) adults.

Numerous studies of host starvation have emphasized pathological effects of parasites on their insect host, but little attention has been focused on the effects of host starvation on the parasites. This study addressed the possibility that parasite life-cycle events could be manipulated by withholding food from the host. The system used was Gregarina niphandrodes (Apicomplexa: Eugregarinida) in Tenebrio molitor (Coleoptera: Tenebrionidae) adults. Gregarine gametocyst formation and shedding ceased after 1 day in starved beetles but continued in fed controls. There were no statistically significant differences between total lengths of associated (3 of 5 trials) or unassociated (5 of 5 trials) gregarines found between experimental and control groups, but average numbers of the 2 life cycle events were generally higher in fed hosts than in starved ones. If infected, fed control beetles continued to form gametocysts throughout the 7-day trial periods, and gametocysts could be observed in the gut. Starved experimental beetles had no gametocysts in their guts. Refeeding of starved beetles after 4 days resulted in resumption of gametocyst formation and shedding. The studies demonstrated that the gregarine life cycle could be stopped and then started at the gametocyst formation stage like an off/on switch, simply by withholding food from, then refeeding, the host.     

Characterization of a coelomic gregarine parasite from Thitarodes pui (Lepidoptera: Hepialidae) in the Tibetan Plateau

Thitarodes pui, one of the host species of entomopathogenic fungus Ophiocordyceps sinensis, has great economic importance in the Tibetan Plateau. We report here, for the first time, a gregarine parasite found in the coelom of 7th instar and adults of T. pui. Gregarine gamonts (ovoid, ～15×8μm) underwent syzygy to produce reproductive gametocysts in T. pui larval hemolymph. All infected T. pui carried 2-17 mature gametocysts filled with numerous oocysts (lemon-shaped, 17.17±0.73×6.49±0.4μm). Transmission electron microscopy showed that these oocysts contained vacuoles of various sizes and amylopectin granules in the cytoplasm; scanning electron microscopy revealed a number of small bumps all over the surface of these oocysts. Small subunit ribosomal DNA sequence analysis showed a close relationship between the gregarine and the species of Ascogregarina (Eugregarinorida: Lecudinidae). Internal transcribed spacers and 5.8S ribosomal DNA from this gregarine exhibited 76% highest sequence identity with that from Ascogregarina culicis Ross.     

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.     

Cytological Studies of the Double Fertilization in Rice

Detailed studies on the process of double fertilization in rice were conducted in the present work. The results are summarized as follows: 1. In the embryosac 30 minutes after anthesis, the pollen tube has already reached the micropyle in every specimen. In some cases, it has even entered further into the embryosac and discharged its contents, including the two male gametes. 2. 1½ hours after anthesis, the male gamete enters into the egg cell. As soon as it comes in contact with the egg nucleus, it increases in size. 2 hours after anthesis, the male nucleus is found inside the female one. A male nucleolus is now clearly discernible. 3. The male nucleolus is gradually growing until it reaches the size of the female one, and then the fusion of the two takes place. The fusion is generally completed and the zygote is formed 7 hours after anthesis. 4. The first mitotic division of the zygote occurs 9 hours after anthesis. 5. The fusion of the male gamete and the polar nucleus proceeds in a similar way as that of the male and female gametes, but it takes a much shorter time usually being completed within 3 hours after anthesis. 6. The male gamete enters into one of the polar nuclei and reveals its nucleolus which increases rapidly in size and then unites with that of the polar nucleus. As soon as the union is completed, the nuclear membrane between the closely contacted parts of the two polar nuclei disappears and the primary endosperm nucleus is formed. 7. The first mitotic division of the primary endosperm nucleus begins right after its formation. 8. With the fusion of the male and female gametes and the development of the zygote, the mitochondria in the cytoplasm surrounding the nucleus increase in size and number. However, in the central cytoplasm about the polar nuclei they show no notice- able change during the fertilization process. 9. Based on the facts that in the embryosac a secondary pollen tube is often seen in every stage of the fertilization process and that additional nucleoli are also observed sometimes in the egg nucleus, the authors believe that polyspermy most probably exists in rice plants, and that this may be one of the causes of polyploid plants often found in rice field as reported by several authors.     

The Unique Adaptation of the Life Cycle of the Coelomic Gregarine Diplauxis hatti to its Host Perinereis cultrifera (Annelida,Polychaeta): an Experimental and Ultrastructural Study

ABSTRACT. The coelomic gregarine Diplauxis hatti exhibits a unique adaptation of its life cycle to its polychaete host Perinereis cultrifera. Experimental and ultrastructural observations on natural populations from the English Channel showed that release of parasite spores is concomitant with the polychaete spawning. As the development of P. cultrifera is direct, the notochete larva ingest parts of the jelly coat covered with numerous sporocysts of D. hatti during hatching. Transepithelial migration of the sporozoites takes place in the gut of three‐ or four‐segment notochete larvae and syzygies of about 20 μm are observed in the coelom. Growth of these young syzygies is slow: after 18–24 mo they reach only 60–70 μm. They exhibit active pendular movements. In the English Channel, female and male gametogenesis of P. cultrifera begins at 19 mo and 2 yr, respectively; the somatic transformations (epitoky) in the last 4 mo of their 3‐year life. During epitoky, the syzygies undergo an impressive growth and reach 700–800 μm within a few weeks. A shift from pendular to active peristaltic motility is observed when the syzygies reach 200–250 μm. When gamogony occurs, syncytial nuclear divisions are initiated and cellularization produces hundred to thousands of male and female gametes of similar size. The male gametes exhibit a flagellum with 3+0 axoneme. The mixing of the gametes (“danse des gametes”) and fertilization are observed during 4–5 h. Zygotes differentiate sporoblasts with eight sporozoites. The sporozoites exhibit the canonical structure of Apicomplexa, a polarized cell with micronemes and rhoptries.     

The Biology of Gregarina fernandoi n. sp. in the Cockroach Pysnoscelus surinamensis with Observations on its Development and Cytochemical Nature

SYNOPSIS. Gregarina fernandoi n. sp. is a eugregarine. Its structure, development and life history in the gut of the cockroach Pycnoscelus surinamensis are described. It is named as a new species on the basis of its size, nuclear structure, structure and form of the gametocyst and oocyst. Observations were made on the different stages of the parasite and related to the pH of the gut. In the ceca, pH 4.5–5, the parasite was in its early stages of development, in the midgut, pH 6.5–7, it was in syzygy and in the rectum, pH 7.5–8, gametocysts were found.     

Uniform Terminology for the Protozoan Subphylum Apicomplexa*

SYNOPSIS. Uniform names for the stages, processes and structures of apicomplexan protozoa are proposed and defined, and names that should be superseded are listed. The same names are used for the same stages of all members of the group. Gregarines are designated as either septate or aseptate rather than as polycystid or monocystid. The gregarine stage often called a sporadin is recognized for what it is, a gamont. The cyst formed around 2 gregarine gamonts in which zygotes are formed is a gametocyst; it contains oocysts which in turn contain sporozoites. The term “spore” is inappropriate for these oocysts. The apical complex includes the polar ring, conoid, rhoptries, micronemes and subpellicular tubules. The gregarine “pseudocyst” is actually a gametocyst residuum. The term micropore is preferred to cytostome for the apicomplexan structure, since it is visible only with the electron microscope.     

Evidence for intercellular cohesion in the septate junction of the protozoon Gregarina

Injection of Lucifer Yellow dye was used to establish whether septate junctions formed a permeability barrier between primite and satellite gamonts in the syzygy of the protozoon Gregarina. The fluorescent dye did not pass from one cell to the other, thus suggesting that the septate junction served only for mechanical adhesion. Later on in development, when the gametocyst had formed, the septate junction vanished and interruptions were observed between opposing cell membranes. At this stage the fluorescent dye was able to pass freely into the conjugated cells.     

Lankesteria barretti n. sp. (Eugregarinida,Diplocystidae), a Parasite of the Mosquito Aedes triseriatus (Say) and a Review of the Genus Lankesteria Mingazzini*

SYNOPSIS. Lankesteria barretti n. sp. (Eugregarinida, Diplocystidae) is named from the mosquito Aedes triseriatus in Texas. The young cephalins occur within the midgut epithelial cells. When they reach a length of about 150–200 μ they rupture the host cell and are released into the space between the epithelium and the peritrophic membrane, becoming gamonts. These grow to about 140–310 by 40 μ at the anterior end and 12 μ at the posterior end. When the host pupates they enter the lumen of the Malpighian tubules; pairs join in syzygy by their anterior ends and later more laterally. Each pair forms a spherical gametocyst about 60–100 μ (exceptionally 250 μ) in diameter. A large number of oocysts develop in each gametocyst. The mature oocysts are spindle-shaped, 11 by 5.4–5.7 μ, and contain 8 elongate sporozoites and a refractile residuum. The gametocyst wall breaks down, releasing oocysts in the Malpighian tubules of the host when it is adult. The oocysts pass out in the feces and presumably infect new larvae by ingestion. The cephalins and gamonts of L. barretti differ from those of L. culicis (of Aedes aegypti) in having a relatively anterior instead of a central nucleus and in lacking a noticeable mucron; its longitudinal folds are not as well-developed as in L. culicis, and its paraglycogen granules are larger. The fine structure of L. culicis and L. barretti is described in detail. Their gamonts have a polar ring but no definite conoid. The taxonomy of the genus is reviewed, but its species have been so poorly described that it is impossible to be sure whether they are all really Lankesteria. About 19 species have been described (5 from turbellaria, 8 from tunicates, perhaps 1 from Amphioxus, 1 from the chaetognath Sagitta sp., 1 from Phlebotomus and 3 from mosquitoes).     

The Life Cycle of Ganymedes oaklandi n. sp., an Acephaline Gregarine of Gammarus fasciatus (Say)*

SYNOPSIS. Ganymedes oaklandi n. sp. (Ganymedidae) from the intestine of Gammarus fasciatus (Say) is described, and its life cycle is given. In the trophic stage the gregarine is acephaline, with an elongated cylindrical body slightly tapered anteriorly, and is up to 298 × 64 μ. The gametocysts are up to 121 × 99 μ, and are covered with a secreted thick sticky gelatinous coat. The spores are released from the gametocyst by rupturing of the cyst wall. The spore body is spherical, approximately 6 μ in diameter, and has 4 episporal rays about 20 μ long.     

Cytochemical Nature and Fine Structure of the Gregarine Zeylanocystis burti Dissanaike, with Special Reference to Microfilaments, Microtubules and Movement

SYNOPSIS. The mature trophozoite of the acephaline gregarine Zeylanocystis burti Dissanaike, parasitic in the seminal vesicles of the Sri Lankan earthworm Pheretima peguana Rosa, was studied by cytochemical methods and by electron microscopy. Some observations were also made on gametocysts and oocysts. The trophozoite has a peculiar saucer shape, unlike other monocystid gregarines, and has marginal papillae with cytoplasmic hairs. Its fine structure conforms broadly to that of other gregarines, but differs with respect to its fibrillar organization and in some details of cytoplasmic organelle structure. The pellicle is composed of 2 parallel unit membranes elevated into a number of stumpy epicytary folds, more or less evenly distributed on both surfaces of the gregarine. Some of these are associated with adjacent accessory cells and may have a nutritive role. Bundles of fine microfilaments (5–6 nm) were detected both in the ectoplasm and deep in the endoplasm; these are possibly the main contractile elements (“myonemes”) involved in movement. Microtubules are larger (22–24 nm) and are found predominantly in papillae and cytoplasmic hairs, but extend also in small bundles beneath the pellicle—they appear to be more skeletal in nature. The significance of these findings is discussed in the light of recent work on the roles of microfilaments and microtubules in nonmuscle cells. Mitochondria are located superficially and have a complex organization. The endoplasmic reticulum is poorly developed, but ribosomes are abundant. Golgi lamellae-like membranes and vesicles akin to lysosomes were observed. Typical paraglycogen granules were found together with blobs of lipid and glycogen. The nucleus had a wrinkled envelope, a homogeneous matrix, and a spherical nucleolus. A variety of staining reactions and cytochemical tests were carried out. The distribution of lipids, polysaccharides, nucleic acids, calcium, and melanin were studied. Succinate dehydrogenase was detected in mitochondria, thiamine pyrophosphatase in Golgi bodies, and acid phosphatase in lysosomes. Golgi structures were found to be chemically very complex. Gametocysts and oocysts were associated with extraneous cells which probably contribute to the formation of their walls. The gametocyst wall is thin and consists of 2 membranes of the unit type. The oocyst wall is thicker and composed of 2 chemically different layers. Telolysosomes were seen in the disorganized residual cytoplasm within gametocysts.