Nomenclature of Sarcocystis in the ox and sheep and of fecal Coccidia of the dog and cat.

The nomenclature of Sarcocystis and related protozoan genera is reviewed, and modern diagnoses of the genera Isospora, Toxoplasma, Besnoitia, Sarcocystis, and Frenkelia in the coccidian family Eimeriidae are given. S cruzi (Hasselmann 1926) comb. n., S. hirsuta Moulé 1888, and S. hominis (Railliet and Lucet 1891) comb. n. are recognized in the muscles of the ox Bos taurus; S. ovicanis Heydorn, Gestrich, Melhorn, and Rommel 1975, and S. tenella Railliet 1886 are recognized in the muscles of the sheep Ovis aries; S. bigemina (Stiles 1891) comb. n., S. cruzi, S. ovicanis, S. bertrami Doflein 1901, S. miescheriana (Kühn 1865) Lankester 1882, I. ohioensis Dubey 1975, I. canis Nemeséri 1959, Isospora sp. n. Dubey, and Isospora sp. n. Trayser and Todd are recognized in dog (Canis familiaris) feces; and S. hirsuta, S. tenella, S. muris (Blanchard 1885) Labbé 1899, B. besnoiti (Marotel 1912) Henry 1913, Besnoitia sp. n. Frenkel, T. gondii (Nicolle and Manceaus 1908) Nicolle and Manceaux 1909, T. hammondi (Frenkel 1974) Levine and Nye 1976, I. rivolta (Grassi 1879) Wenyon 1923, and I. felis Wenyon 1923 are recognized in cat (Felis catus) feces. Hoareosporidium Pande, Bhatia, and Chauhan 1972 is considered a synonym of Sarcocystis.     

Molecular Phylogenetic Relatedness of Frenkelia spp. (Protozoa,Apicomplexa) to Sarcocystis falcatula Stiles 1893: Is the Genus Sarcocystis Paraphyletic?

ABSTRACT The coccidians Frenkelia microti and F. glareoli (Apicomplexa: Sarcocystidae) form tissue cysts in the brain of small rodents (intermediate hosts) while oocysts are formed in the intestine of final hosts, buzzards of the genus Buteo. The inclusion of the small subunit ribosomal RNA gene sequences (SSU rRNA) of both Frenkelia species into the SSU rRNA trees of other, tissue cyst-forming coccidia strongly supports paraphyly of the genus Sarcocystis. Frenkelia spp. exhibit close relatedness to Sarcocystis falcatula Stiles 1893, a bird-opossum parasite, recognized under its junior synonym S. neurona Dubey et al. 1991, as the causative agent of equine protozoan myeloencephalitis on the American continent. As the definition of the genus Frenkelia is based on a plesiomorphic character (affinity to the neural tissue) of supposedly low phylogenetic value, the synonymization of the genus Frenkelia with Sarcocystis is proposed. This renders the genus Sarcocystis monophyletic.     

Note on the Taxonomy of Frenkelia microti (Findlay & Middleton, 1934) (Apicomplexa: Sarcocystidae)

Based on biological, morphological and molecular data, species of Frenkelia Biocca, 1968 should be reclassified within the genus Sarcocystis Poche, 1913. This taxonomic change leads to the secondary homonymy of S. microti (Findlay & Middleton, 1934) n. comb. and S. microti Dubey, 1983. The recently suggested conspecificity and consequent synonymy of S. microti (Findlay & Middleton, 1934) and S. buteonis (Henry, 1932) is not really justifiable and thus S. microti (Findlay & Middleton, 1934) should be considered a valid species. S. jaypeedubeyi nom. nov. is, therefore, proposed as a nomen novum for S. microti Dubey, 1983 to alleviate the problem of this secondary homonymy.     

Multiple origin of the dihomoxenous life cycle in sarcosporidia

Although their ssrRNA gene sequences are closely related, the lizard sarcosporidia (Apicomplexa, Sarcocystidae) Sarcocystis lacertae and Sarcocystis gallotiae posses heteroxenous and dihomoxenous life cycles, respectively. When aligned with available sarcosporidian ssrRNA genes, both species constitute a monophyletic clade that is only distantly related with sarcosporidia that have a viperid snake as their definitive host (Sarcocystis sp., Sarcocystis atheridis). To test the phyletic status of the dihomoxenous life style, Sarcocystis rodentifelis and Sarcocystis muris, two dihomoxenous parasites of mammals were included into this study. All studied species group together with former Frenkelia spp., Sarcocystis neurona and related marsupial and bird sarcosporidia in a monophyletic clade. However, the available dataset supports independent appearance of the dihomoxenous life cycle at least twice during the evolution of the Sarcocystidae.     

Comparative review of the developmental biology of the genera Sarcocystis, Frenkelia, Isospora, Cystoisospora, Hammondia, Toxoplasma and Besnoitia (author's transl)]

A review is given of the advances in our knowledge of the developmental biology of the so-called cyst-forming coccidia in the years from 1974 to 1978. Until 1970 only 6 Isospora species were known to occur in cats, dogs and men. After the discovery of the coccidian nature of the genera Toxoplasma, Sarcocystis, Besnoitia and Frenkelia, and after the discovery of the new genus Hammondia the number of known species rose to over 30. In addition it could be shown that also birds of prey, owls and reptiles serve as final hosts for several Sarcocystis and Frenkelia species. The coccidia with isosporoid oocysts can be classified into two major groups: Species with gamogony and sporogony in the final host (Sarcocystis, Frenkelia) and species with schizogony and gamogony in the final host and sporogony on the ground (Isospora, Cystoisospora, Hammondia, Toxoplasma, Besnoitia). The subdivision of the first group into the genera Sarcocystis and Frenkelia based on the localization of their cysts in the musculature and in the brain, respectively, cannot be upheld in the future. Their classification into organisms with small cystozoites of about 7 microm with birds or reptiles as final hosts (Sarcocystis and Frenkelia species of rodents) and those with large cystozoites of about 15 microm and mammals as final hosts (Sarcocystis spp. of domestic animals and rodents) would be more significative. The second group can be subdivided into monoxenous species (Isospora), species with an optional intermediate host in which no or only slight multiplication occurs (Cystoisospora) and in genera with a multiplication in two phases in the intermediate host (Hammondia, Toxoplasma, Besnoitia). The nomenclature of single species is very controversial. As an example the controversial apprehension of the taxonomy of the Sarcocystis species of cattle is discussed. An application has been submitted to the International Commission for the Zoological Nomenclature to delcare a number of names as nomina dubia and to introduce unambiguous names for those organisms for which type specimens are available.     

Characterization of Sarcocystis species in domestic animals using a PCR-RFLP analysis of variation in the 18S rRNA gene: a cost-effective and simple technique for routine species identification

Thirteen restriction endonucleases were used to investigate nuclotide sequence variation in the 18S rRNA DNA of 88 individuals from ten Sarcocystis taxa collected as cysts from their intermediate hosts, swine, cattle and water buffalo. A DNA sequence of approximately 900 bp was used. A total of 26 electromorphs were detected. The electromorphs were sorted into seven different haplotypes that coincided with the six named species and an unidentified species from cattle. These findings support those of our morphological examinations, which suggested that the taxa resembling Sarcocystis hirsuta, S. hominis, both found in water buffalo, and S. sinensis found in cattle, are not new species but are in fact S. hirsuta and S. hominis as found in cattle, and S. sinensis as found in water buffalo; this finding supports the idea that these species can utilize both cattle and water buffalo as intermediate hosts and are not restricted to one or the other host group as previously thought. PCR-RFLP resolved by agarose gel electrophoresis is shown to be an easy and rapid method of discriminating between these species.     

黄牛、水牛体内人肉孢子虫18S rRNA基因研究及虫种鉴定

本文对自然感染的水牛源的人肉孢子虫以及黄牛源人孢子虫ＤＮＡ的１８Ｓ ｒＲＮＡ基因的ＰＣＲ扩增产物进行了测序。对年获的８６３ｂｐ的１８Ｓ ｒＲＮＡ基因分析比较表明,二者有较高的同源性,因此认为二者可能同是一种肉孢子虫－－人肉孢子虫（Ｓａｒｃｏｃｙｓｔｉｓ ｈｏｍｉｎｉｓ Ｒａｉｌｌｉｅｔ ａｎｄ Ｌｕｃｅｔ,１８９１）。由此推断,不仅黄牛可作为人肉孢子虫的中间宿主,水牛也可作为人肉孢子虫的中间宿主。     

Effects of frozen storage on the structure of sarcocysts in pig muscle and implications in taxonomic studies

The morphology of the cyst wall of Sarcocystis has unique characteristics that can be used in species identification. To find a suitable way to preserve Sarcocystis cyst samples for species identification, by light microscopy and electron microscopy, we recorded the morphological changes in the cysts of Sarcocystis suihominis and Sarcocystis miescheriana from pig muscle, induced by storage at -20 degrees C. Comparisons were made between fresh cysts and those subjected to frozen storage for periods of 3 days, 20 days and 30 days. Results: cyst wall of the two Sarcocystis species appeared unaffected by storage. There was no obvious change in the length, nor in the width of the protrusions after storage (P>0.05), but the structure of the bradyzoite in the sarcocyst was in many cases disintegrated at -20 degrees C in 20 days for S. miescheriana and 30 days for S. suihominis. To our knowledge this is the first report that Sarcocystis cyst in muscle can be stored at -20 degrees C before and remain suitable for ultrastructural morphological study. Consequently, this paper proposes freezing as a convenient storage method for samples used in taxonomic studies of Sarcocystis.     

Separation of antigens from Sarcocystis species using chromatofocusing

Crude antigen preparations from bradyzoites of Sarcocystis species exhibit a high degree of cross-reactivity with antisera against heterologous Sarcocystis species, preventing the development of a species-specific immunological test for sarcocystiosis. In this study, we fractionated bradyzoite-derived protein extracts from Sarcocystis tenella, Sarcocystis arieticanis, Sarcocystis gigantea, and Sarcocystis muris by chromatofocusing and obtained distinct protein elution profiles for each species. We then examined the isolated protein fractions for antigenicity with homologous and heterologous reference sera in an enzyme-linked immunosorbent assay. Whereas some antigenic fractions of bradyzoite proteins had equally high reactivity with the homologous and heterologous sera, the reactivity of other fractions was 3-38 times higher with homologous serum than with heterologous sera. Mice immunized with less cross-reactive protein fractions of S. gigantea and S. muris bradyzoites produced a specific immune serum. Thus, it is possible to isolate species-specific antigens from crude mixtures of bradyzoite-derived Sarcocystis antigens for development of species-specific immunological tests for sarcocystiosis.     

Phylogenetic relationships of the genus Frenkelia: a review of its history and new knowledge gained from comparison of large subunit ribosomal ribonucleic acid gene sequences.

The different genera currently classified into the family Sarcocystidae include parasites which are of significant medical, veterinary and economic importance. The genus Sarcocystis is the largest within the family Sarcocystidae and consists of species which infect a broad range of animals including mammals, birds and reptiles. Frenkelia, another genus within this family, consists of parasites that use rodents as intermediate hosts and birds of prey as definitive hosts. Both genera follow an almost identical pattern of life cycle, and their life cycle stages are morphologically very similar. However, the relationship between the two genera remains unresolved because previous analyses of phenotypic characters and of small subunit ribosomal ribonucleic acid gene sequences have questioned the validity of the genus Frenkelia or the monophyly of the genus Sarcocystis if Frenkelia was recognised as a valid genus. We therefore subjected the large subunit ribosomal ribonucleic acid gene sequences of representative taxa in these genera to phylogenetic analyses to ascertain a definitive relationship between the two genera. The full length large subunit ribosomal ribonucleic acid gene sequences obtained were aligned using Clustal W and Dedicated Comparative Sequence Editor secondary structure alignments. The Dedicated Comparative Sequence Editor alignment was then split into two data sets, one including helical regions, and one including non-helical regions, in order to determine the more informative sites. Subsequently, all four alignment data sets were subjected to different tree-building algorithms. All of the analyses produced trees supporting the paraphyly of the genus Sarcocystis if Frenkelia was recognised as a valid genus and, thus, call for a revision of the current definition of these genera. However, an alternative, more parsimonious and more appropriate solution to the Sarcocystis/Frenkelia controversy is to synonymise the genus Frenkelia with the genus Sarcocystis.     

Effects of sequence alignment and structural domains of ribosomal DNA on phylogeny reconstruction for the protozoan family sarcocystidae

Finding correct species relationships using phylogeny reconstruction based on molecular data is dependent on several empirical and technical factors. These include the choice of DNA sequence from which phylogeny is to be inferred, the establishment of character homology within a sequence alignment, and the phylogeny algorithm used. Nevertheless, sequencing and phylogeny tools provide a way of testing certain hypotheses regarding the relationship among the organisms for which phenotypic characters demonstrate conflicting evolutionary information. The protozoan family Sarcocystidae is one such group for which molecular data have been applied phylogenetically to resolve questionable relationships. However, analyses carried out to date, particularly based on small-subunit ribosomal DNA, have not resolved all of the relationships within this family. Analysis of more than one gene is necessary in order to obtain a robust species signal, and some DNA sequences may not be appropriate in terms of their phylogenetic information content. With this in mind, we tested the informativeness of our chosen molecule, the large-subunit ribosomal DNA (lsu rDNA), by using subdivisions of the sequence in phylogenetic analysis through PAUP, fastDNAml, and neighbor joining. The segments of sequence applied correspond to areas of higher nucleotide variation in a secondary-structure alignment involving 21 taxa. We found that subdivision of the entire lsu rDNA is inappropriate for phylogenetic analysis of the Sarcocystidae. There are limited informative nucleotide sites in the lsu rDNA for certain clades, such as the one encompassing the subfamily Toxoplasmatinae. Consequently, the removal of any segment of the alignment compromises the final tree topology. We also tested the effect of using two different alignment procedures (CLUSTAL W and the structure alignment using DCSE) and three different tree-building methods on the final tree topology. This work shows that congruence between different methods in the formation of clades may be a feature of robust topology; however, a sequence alignment based on primary structure may not be comparing homologous nucleotides even though the expected topology is obtained. Our results support previous findings showing the paraphyly of the current genera Sarcocystis and Hammondia and again bring to question the relationships of Sarcocystis muris, Isospora felis, and Neospora caninum. In addition, results based on phylogenetic analysis of the structure alignment suggest that Sarcocystis zamani and Sarcocystis singaporensis, which have reptilian definitive hosts, are monophyletic with Sarcocystis species using mammalian definitive hosts if the genus Frenkelia is synonymized with Sarcocystis.     

Identification of Sarcocystis hominis-like (Protozoa: Sarcocystidae) cyst in water buffalo (Bubalus bubalis) based on 18S rRNA gene sequences

DNA templates were extracted from isolates of Sarcocystis hominis-like cysts collected from cattle and water buffalo, as well as from Sarcocystis fusiformis cysts and Sarcocystis suihominis cysts. The 18S rRNA genes were amplified using DNA from a single cyst as the templates. Approximately 1,367-1,440 bp sequences were obtained. The sequence difference in isolates of Sarcocystis hominis-like cysts from water buffaloes, and isolates of S. hominis cysts from cattle were very low, only about 0.1%, much lower than the lowest value (1.7%) among different species. Combined with their morphological structure, these sequence data indicate that the 4 isolates from cattle and water buffalo might be the same species, i.e., S. hominis, suggesting that both cattle and water buffalo may serve as the intermediate hosts for this parasite. Apparently, this is the first report using a single cyst to do such work and is a useful way to distinguish the Sarcocystis cyst in an intermediate host that may be simultaneously infected by several different Sarcocystis species.     

Protozoan parasites of British small rodents

Thirty-five species of protozoan parasites belonging to thirteen genera have now been recorded for British small rodents. These include species of Entamoeba, Giardia, Spironucleus, Trichomonas, Chilomastix, Eimeria and Cryptosporidium in the gut; Trypanosoma, Hepatozoon and Babesia in the blood; and Toxoplasma, Frenkelia and Sarcocystis in the tissues. Recent advances have progressed along two lines, the elucidation of the life-cycles of the species of Frenkelia and Sarcocystis , which are now known to involve a carnivore as the final host, and laboratory studies on those parasites that can be maintained in laboratory animals. It is now possible to draw up a definitive list of hosts and parasites and this should serve as a basis for studies on the epidemiology of these parasites and their possible effects on their hosts.     

Effect of tryptic or peptic digestion or mechanical isolation on the extraction of proteins, antigens, and ribonucleic acids from Sarcocystis muris bradyzoites

Various methods have been used for the isolation of bradyzoites of Sarcocystis species. Using Sarcocystis muris as a model, the effect of 3 methods, trypsin digestion, pepsin digestion, and mechanical isolation, on the subsequent extraction of S. muris proteins, antigens, and RNA was examined. Although some quantitative differences were found among the proteins, antigens, and RNA extracted after the 3 isolation methods, qualitative differences were not evident. The overall isoelectric focusing protein profile showed approximately 30 bands in the pH range of 3-9 and was dominated by 5 bands with pI values of approximately 5.3, 6.3, 6.8, 7.0, and 7.4. In experimentally infected mice, antibodies were recorded from 35 days postinoculation (PI) until the end of examination (130 days PI). The S. muris RNA appeared to consist of at least 10 subunits in the range of 200-4,200 nucleotides. A Toxoplasma gondii DNA fragment specific for small subunit ribosomal RNA (rRNA) hybridized mainly to the S. muris 1,900-nucleotide subunit and a range of smaller subunits, and a probe specific for large subunit rRNA hybridized mainly to the 4,200-nucleotide subunit and a range of smaller subunits. All 3 methods of bradyzoite isolation gave good yields of intact messenger RNAs that showed similar in vitro translation curves.     

The structure of the surface apparatus in sarcocysts of Sarcosporidia in the persistence process

The structure of the sarcocyst surface apparatus (SSA) was investigated for two sarcosporidian species: Sarcocystis muris (non-pathogenic) and S. fusiformis (pathogenic). The surface membrane, being the main SSA subsystem, makes numerous vesicle-like protrusions with different ultrastructural patterns. This made it possible to distinguish between four and three types of these protrusions in S. fusiformis and S. muris, respectively. Vesicles of similar structure, pinched off from the fully formed protrusions, were classified, correspondingly, in the same four and three different types. A presumable functional role of both protrusions and membrane-coated vesicles in pathogenicity of different sarcosporidian species is proposed. The vesicles pinched off from corresponding protrusions may be involved in transporting certain substance complexes from the sarcocyst to the harbouring host cell. In addition, another way of substance transporting was observed, when the cystic substances, not surrounded with any membrane coating, are thrown from open protrusions directly into the immediate cytoplasm of the host cell.     

Sarcocystis miescheriana infection in domestic pigs (Sus scrofa) in the Philippines

Sarcocystis miescheriana sarcocysts were identified in skeletal muscles of 9 (27%) of 33 swine slaughtered for human consumption. Sarcocysts were 144-180 microm x 20-38 microm in size. Ultrastructurally, the cyst wall resembled the type 10 sarcocyst wall. The villar protrusions (VP) were 3-4.5 microm long and 0.6-1.2 microm wide and had prominent longitudinally arranged microtubules extending from the VP tips to the granular layer (=ground substance). The parasitophorous vacuolar membrane with its underlying electron-dense layer (EDL) measured 25 nm in thickness. The base of the VP exhibited minute (0.42-0.87 microm) bulblike inpocketings. Each VP had 80-90 microtubules situated underneath the EDL. The granular layer was 0.5-1.2 microm thick, and contained hairlike microtubules continuous with those of the VP core. This is the first report of S. miescheriana in Philippine domestic pigs Sus scrofa.     

Cockroaches as vectors of Sarcocystis muris and of other coccidia in the laboratory.

To assess the roles of the German cockroach (Blatella germanica) and the American cockroach (Periplaneta americana) in the transmission of Sarcocystis muris and of 3 other coccidia of cats-Toxoplasma gondii, Isospora felis, and Isospora rivolta, cockroaches exposed to feces containing these coccidia were periodically fed to mice, as was a portion of the fecal matter. Sarcocystis muris sporocysts, which in feces remained infectious for at least 20 days, were also transmitted to mice by P. americana for at least 20 days and by B. germanica for 5 days after exposure to infectious feces. Toxoplasma gondii oocysts were transmitted by P. americana intermittently up to 10 days, but by B. germanica only immediately after exposure to feces. Oocysts of 2 species of Isospora, when associated with fecal matter, remained infectious for 20 days. Those of I. rivolta were transmitted by both cockroach species for 10 days, but I. felis was transmitted only by by B. germanica, and for only 2 days.