Morphologic, immunohistochemical, and molecular characterization of a novel Lankesterella protozoan in two White's tree frogs (Litoria caerulea).

Two White's tree frogs (Litoria caerulea) housed at a zoological park died after a short period of lethargy, weight loss, and edema. Detailed postmortem examinations were performed on both frogs, including bacterial cultures and complete histologic examinations. Intracytoplasmatic as well as free protozoan parasites were identified in multiple organs from both frogs. The parasites were identified within erythrocytes, leukocytes, endothelial cells, and hepatocytes. Immunohistochemistry demonstrated a cross-reaction with Toxoplasma gondii antisera. Parasite ultrastructural analysis was performed by transmission electron microscopy. The parasites demonstrated an apical complex containing a conoid, rhoptries, and micronemes, demonstrating it was a member of the phylum Apicomplexa. In addition, the parasites had bipolar paranuclear bodies, organelles that are typical of coccidian sporozoites. The organisms were tentatively identified as members of the genus Lankesterella on the basis of histologic and ultrastructural morphology. A portion of the 18s ribosomal RNA (rRNA) gene was amplified via a polymerase chain reaction, sequenced, and used in a Basic Local Alignment Search Tool search of the GenBank database. The 18s rRNA gene sequence was found to be most similar to gene sequences isolated from Lankesterella organisms (88%). In aggregate, these data support the classification of these protozoa as a novel species of Lankesterella. A causal relationship between frog morbidity and protozoal parasitism was not determined. This is the first report of Lankesterella sp. in White's tree frogs.

Neospora caninum and Hammondia heydorni are separate species/organisms.

Neospora caninum and Hammondia heydorni are two coccidian parasites with morphologically similar oocysts in canine feces. It was recently proposed that they are one species. In this paper, we review the biology and morphology of these parasites and present evidence that N. caninum and H. heydorni are separate species.

A guideline for the preparation of species descriptions in the Eimeriidae.

Members of the suborder Eimeriina (phylum Apicomplexa: class Sporozoea: order Eucoccidiorida) have complex 1 or 2 host life cycles that involve endogenous development in the tissues of vertebrates or invertebrates and exogenous development in an oocyst, usually outside the host(s). Because tissue stages are logistically difficult or even impossible to obtain in natural (wild) host-parasite systems, the vast majority (> 98%) of species in this parasite complex are known only from the structure of their sporulated oocyst. Unfortunately, the quality of these species descriptions is uneven because no guidelines are available for workers in the field to follow. Here we propose a specific set of guidelines for the preparation of species descriptions of coccidia based predominently on the structure of the sporulated oocyst, because the oocyst is the most readily available stage in the life cycle. In addition, we emphasize that ancillary data be incorporated whenever possible with the species description; these data may include, but are not limited to, ecological parameters, prevalence, seasonal data, and the deposition of both host symbiotypes and parasite hepantotypes (= phototypes) into accredited musecums so that accurate identification of both host and parasite material can be assured in perpetuity. And finally, if oocysts are collected in pure suspension, that is, if only one coccidian species (morphotype) is present in the sample, then some oocysts should be saved in 70% ethanol and archived in an accredited museum in the event that future workers might wish to amplify and, later, sequence the parasite's DNA.

Life cycle of Calyptospora funduli (Apicomplexa: Calyptosporidae).

The taxonomic status of the extraintestinal piscine coccidium Calyptospora funduli is based in part on its requirement of an intermediate host (the daggerblade grass shrimp Palaemonetes pugio). In the present study, grass shrimp fed livers of Gulf killifish (Fundulus grandis) infected with sporulated oocysts of C. funduli exhibited numerous sporozoites suspended in the intestinal contents when fresh squash preparations were examined by light microscopy. Using this method, sporozoites were not seen in intestinal epithelial cells of the grass shrimp or in any other cell types. Ultrastructural examination, however, revealed sporozoites in the cytoplasm of the gut basal cells. Cross-sections of 1-13 sporozoites were seen within a single cell, and those sporozoites each appeared to be situated in individual membrane-bound vesicles, rather than in a single parasitophorous vacuole. These ultrastructural observations indicate that in the grass shrimp intermediate host, sporozoites that develop into an infective stage probably undergo that development in gut mucosal basal cells. Prior studies revealed that these sporozoites modified their structure over 4-5 days and that before that time, they were not infective to the fish host. Following ingestion of an infected shrimp by a killifish, the infective sporozoites apparently reach the liver of their killifish definitive hosts through the bloodstream. Sporozoites were seen in blood smears from the longnose killifish, Fundulus similis, 4 hr after fish were fed experimentally infected grass shrimp. Additionally, coccidian trophozoites and early meronts were seen in hepatocytes from several longnose killifish at 48, 72, and 96 hr postinfection. This study, in conjunction with previous findings, clearly confirms that a true intermediate host is required in the life cycle of C. funduli, that a developmental period of about 5 days in grass shrimp is necessary for sporozoites to become infective to killifishes, and that sporozoites do occur intracellularly in gut basal cells of the grass shrimp.

Hammondia hammondi organelle proteins are recognized by monoclonal antibodies directed against organelles of Toxoplasma gondii.

Hammondia hammondi and Toxoplasma gondii, 2 closely related coccidia of cats, are known to share many antigenic molecules as shown by serologic cross reactivity. Monoclonal antibodies (MAbs) directed against the internal organelles of Toxoplasma gondii were tested by immunofluorescence assay and immunoelectron microscopy on the tachyzoites of H. hammondi. The MAbs anti-apex, anti-dense granules, anti-micronemes, and anti-rhoptries recognized, although weakly, the corresponding antigens on H. hammondi. This finding demonstrates that organelles of the 2 parasites are not only morphologically, but also antigenically, similar.

Margolisiella kabatai gen. et sp. n. (Apicomplexa: Eimeriidae), a parasite of native littleneck clams, Protothaca staminea, from British Columbia, Canada, with a taxonomic revision of the coccidian parasites of bivalves (Mollusca: Bivalvia).

Two of 98 native littleneck clams, Protothaca staminea Conrad, from Cooper's Cove, Sooke Basin were infected with an eimeriorin coccidian parasite. Merogonic gamontogonic and sporogonic development were observed in renal tubular epithelial cells. Sporulation of the oocysts occurred within the host. Mature oocysts were spherical mean 41 microns (range 30-44), and contained about 32 subspherical sporocysts (9 x 10 microns), each of which contained 4 sporozoites. Spherical 19 microns (18-20), cyst-like structures and smaller multinucleate bodies, some of which resembled sporocysts, were also seen. A review of the coccidian parasites of bivalves led to the erection of the new genus, Margolisiella (family Eimeriidae Minchin, 1903) to accommodate M. kabatai sp. n., the parasite in Protothaca staminea described herein. Four previously described monoxenous species (Pseudoklossia patellae Debaisieux, P. chitonis Debaisieux, P. tellinovum Buchanan and P. haliotis Friedman, Gardner, Hedrick, Stephenson, Cawthorn et Upton) were also transferred to the new genus. The 2 remaining possibly heteroxenous species (P. pelseneeri Léger and P. glomerata Léger et Duboscq) were retained in the genus Pseudoklossia Léger et Duboscq (family Aggregatidae Labbé, 1899).

Ultrastructure of Frenkelia sp. from a Norwegian lemming in Finland.

An apparently healthy Norwegian lemming (Lemmus lemmus) caught in northern Finland was observed to have a whitish body 0.5 to 1.0 mm in diameter in the external layer of the cerebral cortex. By light microscopy a highly lobulated cyst of Frenkelia sp. was observed. By transmission electron microscopy lemmus) collected in the cyst wall was seen consisting of a parasitophorous vacuolar membrane, an underlying electron-dense layer and a granular layer. The membrane was only slightly convoluted. The protrusions of the cyst wall appeared round but were often not distinctive. A very thin septum divided the interior of the cyst into compartments packed with bradyzoites and maturing zoites. The bradyzoites were elongate measuring 5-8 x 1.5-2 microm. This is the first electron microscopical study of Frenkelia sp. from L. lemmus.

The morphology and pathology of Besnoitia sp. in reindeer (Rangifer tarandus tarandus).

Four of five reindeer (Rangifer tarandus tarandus) obtained from a Besnoitia sp.- infected herd at the Assiniboine Park Zoo in Winnipeg, Manitoba, Canada, in October 1989, had evidence of mild dermatitis over the articular surfaces of carpal and tarsal joints. Cysts of Besnoitia sp., either surrounded by inflammatory reactions or without evident host response, were present within the dermis, submucosa of the nasal turbinates, periosteum, tendons, testes and hooves. The light microscopic and histochemical features of Besnoitia sp. from reindeer were indistinguishable from those of other Besnoitia spp. described in cattle, rodents and horses. The Besnoitia sp. cysts and organisms from reindeer were unique in that bradyzoite membrane micropores and cytoplasmic enigmatic bodies were not observed. Two cats were fed cysts of Besnoitia sp. but no oocysts were detected in feces for 90 days post-infection.

Schellackia calotesi n. sp. from agamid lizards of the genus Calotes in Thailand.

Schellackia calotesi n. sp. is described from the Thai agamids Calotes mystaceus and C. versicolor. Schellackia-type sporozoites were recovered from blood and liver of one C. versicolor from Kon Kaen North-East Thailand and two C. mystaceus from Chiang Mai, North Thailand. Specimens of both species were fed on sporozoite infected blood, of these only one C. mystaceus developed endogenous infection in the anterior intestine. Description, from histological material includes early and dividing meronts, micro and macrogamonts and non sporulated oocysts.

Comparative ultrastructural studies on Besnoitia besnoiti and Besnoitia caprae.

Comparative transmission electron microscopy on Besnoitia besnoiti and on a strain of Besnoitia derived from goats in Kenya revealed that the two organisms differ in their pellicle, micropore, microtubules, nucleus, wall-forming body 1 (W1), amount of lipids and amylopectin. Thus the caprine besnoitia is probably a different organism and the term Besnoitia caprae should continue to be used.

An epizootic of besnoitiosis in goats in Fars province of Iran.

Over 100,000 goats were grazing freely in isolated herds of 100 to 600 goats in a mountainous area of more than 2000 km2 to the north-east of Darab City in Fars Province in southern Iran. Twenty to fifty percent of the goats in this area were infected with besnoitiosis. Sheep, cattle and donkeys grazing in the same area showed no clinical manifestations of the infection. The diagnosis of the infection in the clinically suspected animals was confirmed by histological studies on skin biopsies from the ear tips and carpal and tarsal regions, and the distribution of this protozoon in the tissues and organs of this intermediate host was studied by post-mortem and histological examinations. Skin biopsies from the carpal and tarsal areas of 12% of clinically normal goats from the infected area were also lightly infected with besnoitia cysts.

Neospora caninum: is it really different from Hammondia heydorni or is it a strain of Toxoplasma gondii? An opinion.

The published data concerning Toxoplasma gondii, Hammondia hammondi, H. heydorni and Neospora caninum on one side and between T. gondii on the other were neglected by most authors. As conclusion we are convinced that there are only two valid species: Isospora (Toxoplasma) gondii and Hammondia heydorni. The first includes as a strain H. hammondi and the latter N. caninum. In any case there is absolutely no reason (with respect to general Zoological nomenclature) to create new genera!

Differentiating between Besnoitia besnoiti from cattle and Sarcocystis hoarensis from rodents.

To provide a biological basis for studies designed to establish the mode of transmission of the veterinary pathogen Besnoitia besnoiti, we compared salient features of this pathogen in cattle with those of Sarcocystis hoarensis in rodents. The cysts and cystozoites of these organisms can readily be distinguished morphologically. In contrast to S. hoarensis, which is well adapted to rodents, B. besnoiti fails to mature in jirds or mice and generally is lethal in jirds. Serological reagents discriminately detect these pathogens. B. besnoiti, therefore, can unambiguously be differentiated from S. hoarensis either by morphological or serological methods or on the basis of experimental comparisons of virulence in laboratory rodents.