A Microsporidian Infection in Phoronids (Phylum Phoronida): Microsporidium phoronidi n. sp. from a Phoronis embryolabi

Microsporidia‐like spores (2.0–3.0 × 1.3–1.5 μm) were discovered upon examination of histological sections taken from Phoronis embryolabi Temereva, Chichvarkhin 2017 found inhabiting burrows of shrimps Nihonotrypeae japonica (Decapoda, Callianassidae) from the Sea of Japan, Russia. Ultrastructural examination of spores revealed one nucleus and a uniform polar filament of 7–11 coils. Representatives of the phylum Phoronida have never been recorded as hosts of microsporidia. Parasites developed in vasoperitoneal tissue and caused formation of multinucleate syncytia. Basing on unique host and fine morphology, we assign the novel finding to Microsporidium phoronidi n. sp. and place provisionally in the collective genus Microsporidium.     

Myosporidium merluccius n. g., n. sp. infecting muscle of commercial hake (Merluccius sp.) from fisheries near Namibia

A new species of Microsporidia classified to a new genus was observed in the trunk muscle of commercial hake (Merluccius capensis/paradoxus complex) from Namibian fisheries. Macroscopic examination revealed thin and dark filaments inserted among muscle fibers. Inside the filaments were many sporophorous vesicles with about 30-50 spores per vesicle. The shape of the spore was pyriform and the extruded polar filament was of moderate length (up to 4.29 microm, n=12). This new species of Microsporidia is described using macrophotography, microphotography, staining, and transmission electron microscopy (TEM), as well as molecular methods. Its 16S rRNA was found to be similar to that of Microsporidium prosopium Kent et al., 1999, while both sequences were quite different from 16S rRNA sequences known for other Microsporidia. Nevertheless, this new species is separated morphologically from M. prosopium by the presence of 11-12 anisofilar coils and the formation of the xenoma at the site of infection. Type species.     

A new microsporidian parasite, Potaspora morhaphis n. gen., n. sp. (Microsporidia) infecting the Teleostean fish, Potamorhaphis guianensis from the River Amazon. Morphological, ultrastructural and molecular characterization

A fish-infecting Microsporidia Potaspora morhaphis n. gen., n. sp. found adherent to the wall of the coelomic cavity of the freshwater fish, Potamorhaphis guianensis, from lower Amazon River is described, based on light microscope and ultrastructural characteristics. This microsporidian forms whitish xenomas distinguished by the numerous filiform and anastomosed microvilli. The xenoma was completely filled by several developmental stages. In all of these stages, the nuclei are monokaryotic and develop in direct contact with host cell cytoplasm. The merogonial plasmodium divides by binary fission and the disporoblastic pyriform spores of sporont origin measure 2.8+/-0.3 x 1.5+/-0.2 microm. In mature spores the polar filament was arranged into 9-10 coils in 2 layers. The polaroplast had 2 distinct regions around the manubrium and an electron-dense globule was observed. The small subunit, intergenic space and partial large subunit rRNA gene were sequenced and maximum parsimony analysis placed the microsporidian described here in the clade that includes the genera Kabatana, Microgemma, Spraguea and Tetramicra. The ultrastructural morphology of the xenoma, and the developmental stages including the spores of this microsporidian parasite, as well as the phylogenetic analysis, suggest the erection of a new genus and species.     

Development of an immunomagnetic separation-polymerase chain reaction (IMS-PCR) assay specific for Enterocytozoon bieneusi in water samples

AIMS: Microsporidia have become widely recognized as important human pathogens. Among Microsporidia, Enterocytozoon bieneusi is responsible for severe gastrointestinal disease. To date, no current therapy has been proven effective. Their mode of transmission and environmental occurrence are poorly documented because of the lack of detection methods that are both species-specific and sensitive. In this study, we developed a sensitive and specific molecular method to detect E. bieneusi spores in water samples. METHODS AND RESULTS: The molecular assay combined immunomagnetic separation (IMS) and polymerase chain reaction (PCR) amplification to detect E. bieneusi spores. A comparison was made of IMS magnetic beads coated with two different monoclonal antibodies, one specific for the Encephalitozoon genus that cross-reacts with E. bieneusi and the other specific only for the E. bieneusi species itself. CONCLUSIONS: Immunotech beads coated with the antibody specific for E. bieneusi were found to be the most effective combination. SIGNIFICANCE AND IMPACT OF THE STUDY: The highly specific IMS-PCR assay developed in this study provides a rapid and sensitive means of screening water samples for the presence of E. bieneusi spores.     

Pleistophora carpocapsae Sp. N. (Microsporidia, Nosematidae) - a parasite of the codling moth]

A new species of Microsporidia, Pleistiophora carpocapsae sp. n., a parasite of caterpillars and pupae of the codling moth, is described from Moldavia. It is noteworthy that one sporant forms pansporoblasts containing from 4 to 64 sporoblasts and then the same number of spores.     

Identification and characterization of two subpopulations of Encephalitozoon intestinalis

Microsporidia are obligate intracellular protozoa that have been shown to be pathogenic to most living creatures. The development of in vitro cell culture propagation methods has provided researchers with large numbers of spores and facilitated the study of these organisms. Here, we describe heterogeneity within cell culture-propagated Encephalitozoon intestinalis suspensions. Flow cytometer histograms depicting the log side scatter and forward-angle light scatter of spores from nine suspensions produced over 12 months consistently showed two populations differing in size. The suspensions were composed primarily of the smaller-spore subpopulation (76.4% +/- 5.1%). The presence of two subpopulations was confirmed by microscopic examination and image analysis (P < 0.001). Small subpopulation spores were noninfectious in rabbit kidney (RK13) cell culture infectivity assays, while the large spores were infectious when inocula included > or = 25 spores. The small spores stained brilliantly with fluorescein isothiocyanate-conjugated monoclonal antibody against Encephalitozoon genus spore wall antigen, while the large spores stained poorly. There was no difference in staining intensities using commercial (MicroSporFA) and experimental polyclonal antibodies. Vital-dye (DAPI [4',6'-diamidino-2-phenylindole], propidium iodide, or SYTOX Green) staining showed the spores of the small subpopulation to be permeable to all vital dyes tested, while spores of the large subpopulation were not permeable in the absence of ethanol pretreatment. PCR using primers directed to the 16S rRNA or beta-tubulin genes and subsequent sequence analysis confirmed both subpopulations as E. intestinalis. Our data suggest that existing cell culture propagation methods produce two types of spores differing in infectivity, and the presence of these noninfective spores in purified spore suspensions should be considered when designing disinfection and drug treatment studies.     

A first record of microsporidia in the ixodid tick Ixodes ricinus L. (Ixodidae) in the territory of the Commonwealth of Independent States, Republic Moldova

Spores of microsporidia have been recovered in 5 specimens of 13 ixodid ticks Ixodes ricinus from various populations of the Republic Moldova collected in spring of 2004. Microsporidia were detected by means of fluorescent microscopy. Intensity of infection was 3-6 spores per a micropreparate from one mite. Based on spore size, character of staining and the presence of diplocarion, these spores are referred to the Nosema-like type. Low intensity of infection probably is caused by that fact that ticks were collected in spring period and were unfed.     

Pankovaia semitubulata gen. et sp. n. (Microsporidia: Tuzetiidae) from nymphs of mayflies Cloeon dipterum L. (Insecta: Ephemeroptera) in Western Siberia

The ultrastructure of a new microsporidian, Pankovaia semitubulata gen. et sp. n. (Microsporidia: Tuzetiidae), from the fat body of Cloeon dipterum (L.) (Ephemeroptera: Baetidae) is described. The species is monokaryotic throughout the life cycle, developing in direct contact with the host cell cytoplasm. Sporogonial plasmodium divides into 2-8 sporoblasts. Each sporoblast, then spore, is enclosed in an individual sporophorous vesicle. Fixed and stained spores of the type species P. semitubulata are 3.4 x 1.9microm in size. The polaroplast is bipartite (lamellar and vesicular). The polar filament is isofilar, possessing 6 coils in one row. The following features distinguish the genus Pankovaia from other monokaryotic genera of Tuzetiidae: (a) exospore is composed of multiple irregularly laid tubules with a lengthwise opening, referred to as "semitubules"; (b) episporontal space of sporophorous vesicle (SPV) is devoid of secretory formations; (c) SPV envelope is represented by a thin fragile membrane.     

Susceptibility of spores of the microsporidian Nosema algerae to sunlight and germicidal ultraviolet radiation

Spores of the microsporidian Nosema algerae exposed to 1, 2, and 4 hr of sunlight and 121 μW/cm² of germicidal ultraviolet light were fed to first-instar Anopheles albimanus. Twenty days after feeding, the incidence and intensity of infection (spores/mosquito) were recorded from adult mosquitoes. While sunlight-treated spores showed no significant decline in incidence of infection after 1-, 2-, and 4-hr exposures, intensity of infection decreased significantly after the 2- and 4-hr exposures. Incidence of infection of mosquitoes fed bactericidal ultraviolet light-treated spores declined 48.2, 76.2, and 99.9% after 1-, 2-, and 8-min exposures, respectively. Measured by intensity of infection, activity of bactericidal light-treated spores decreased 87.2% after 1 min, 91.7% after 2 min, and 99.9% after 8 min. Levels of radiation required to inactivate spores of N. algerae fell within the range reported for other Microsporidia.     

Taxonomy of Neoperezia chironomi and Neoperezia semenovaiae comb. nov. (Microsporidia, Aquasporidia): Lessons from ultrastructure and ribosomal DNA sequence data

We did a comparative analysis of the small subunit ribosomal DNA (rDNA) for two species of Microsporidia, Semenovaia chironomi and Neoperezia chironomi, both parasites of Chironomus plumosus (Diptera, Chironomidae). These two microsporidial species have been described previously on the basis of light and electron microscopic studies. The former species is dimorphic, producing both single diplokaryotic spores and uninucleate spores in sporophorous vesicles (SPVs) in packets of 16, while the latter species is monomorphic, disporoblastic, producing only uninucleate spores in SPVs. Based on their life cycles, S. chironomi and N. chironomi were assigned to two different families, Burenellidae and Neopereziidae. However, molecular analysis shows 96.7% sequence similarity for the small subunit rDNA between these two species. Remarkable similarities of the spore ultrastructure (mainly of the extrusion apparatus) justify a transfer of S. chironomi to Neoperezia, establishing a new combination, Neoperezia semenovaiae. Neoperezia belongs to Clade V, Class Aquasporidia sensu Vossbrinck and Debrunner-Vossbrinck (2005), and is in its spore ultrastructure similar to its closest relatives, namely Bryonosema, Schroedera, Pseudonosema, Trichonosema and Janacekia. We therefore conclude that similarities in spore ultrastructure reflect the phylogenetic relatedness of these Microsporidia, as opposed to the strikingly diverse life cycles.     

Identification and Characterization of Two Subpopulations of Encephalitozoon intestinalis

Microsporidia are obligate intracellular protozoa that have been shown to be pathogenic to most living creatures. The development of in vitro cell culture propagation methods has provided researchers with large numbers of spores and facilitated the study of these organisms. Here, we describe heterogeneity within cell culture-propagated Encephalitozoon intestinalis suspensions. Flow cytometer histograms depicting the log side scatter and forward-angle light scatter of spores from nine suspensions produced over 12 months consistently showed two populations differing in size. The suspensions were composed primarily of the smaller-spore subpopulation (76.4% ± 5.1%). The presence of two subpopulations was confirmed by microscopic examination and image analysis (P < 0.001). Small subpopulation spores were noninfectious in rabbit kidney (RK13) cell culture infectivity assays, while the large spores were infectious when inocula included ≥25 spores. The small spores stained brilliantly with fluorescein isothiocyanate-conjugated monoclonal antibody against Encephalitozoon genus spore wall antigen, while the large spores stained poorly. There was no difference in staining intensities using commercial (MicroSporFA) and experimental polyclonal antibodies. Vital-dye (DAPI [4′,6′-diamidino-2-phenylindole], propidium iodide, or SYTOX Green) staining showed the spores of the small subpopulation to be permeable to all vital dyes tested, while spores of the large subpopulation were not permeable in the absence of ethanol pretreatment. PCR using primers directed to the 16S rRNA or β-tubulin genes and subsequent sequence analysis confirmed both subpopulations as E. intestinalis. Our data suggest that existing cell culture propagation methods produce two types of spores differing in infectivity, and the presence of these noninfective spores in purified spore suspensions should be considered when designing disinfection and drug treatment studies.     

Microsporidians in bloodsucking Aedes (O.) cataphylla mosquitoes in Ukraine]

The paper reports the results of studies on Microsporidia from the bloodsucking mosquito Aedes cataphylla for the period from 1974 undertaken in the Kiev and Chernigov Provinces of the Ukraine. A new species, Amblyospora cataphyllus sp. n., is described from larvae of the mosquito. Living spores oval or elongate-oval, 6.3--7.5 x 4.5--5.0 (most commonly 6.8 x 4.8) microns, fixed spores oval, 5.6--6.9 x 3.8--4.8 microns. Mucocalyx becomes distinct around spores in 10 to 15 days after the preparation is made. Spontaneously ejected polar tube 125 microns long. Exospore smooth or undulate, 170 to 310 nm thick, endospore 60 to 160 nm. Polaroplast elongated and curved, its 1/3 is composed of closely situated plates and 2/3 of more widely arranged ones. Polar tube anisophyllous, forms 18 to 20 spires in a spore, of which 3 to 5 spires form basal area and 14 to 16 form distal area (of them 1-2 most thick spires form intermediate area). Nucleus large, in a shape of half-ring. In living spores posterior vacuole crescentic, in fixed ones it is strongly deformed together with hind pole of spores. Sporogony of Microsporidia takes place in larvae of mosquitoes of both sexes. Infection extensiveness of IV stage larvae is 10%.     

A serological comparison of some species of microsporida.

Double immunodiffusion techniques were used to investigate the taxonomic relationships between six different microsporidian isolates. Microsporidia used included Nosema bombycis, N. algerae, N. plodiae, and three organisms morphologically similar to N. necatrix. Antigens were extracted from spores after disruption in an MSK Braun cell homogenizer. Cross-reactions were seen between N. plodiae and two of the N. necatrix isolates, while the third N. necatrix, N. bombycis, and N. algerae were antigenically unrelated. One of the N. necatrix isolates revealed temperature-related antigenic differences, but no antigenic differences resulted from aging spores for 5 months before disruption.     

Ultrastructural aspects of a new species,Vavraia mediterranica (Microsporidia,Pleistophoridae), parasite of the French Mediterranean shrimp,Crangon crangon (Crustacea,Decapoda)

The life cycle stages of a new species of the genus Vavraia (Microsporidia, Pleistophoridae), which parasitizes the shrimp Crangon crangon (Crustacea, Decapoda), were examined by light and electron microscopy. This parasite was monomorphic with polysporous sporogony and developed in the skeletal muscle of the host. The multinucleate sporogonial plasmodium divided by plasmotomy and multiple division into uninucleate sporoblasts. All stages were surrounded by a thick and amorphous dense coat external to the plasmalemma. This structure gradually became a merontogenetic sporophorous vacuole (MSV) where the sporonts developed into sporoblasts. The MSV was filled with episporontal granular secretory products and eventually contained up to 50 uninucleate spores. During spore morphogenesis, these episporontal granular products within the MSV became organized as episporontal tubular-like structures. In transverse sections, these structures showed a mean diameter of 1.0 microm, but disappeared during the final phase of the spore maturation. Mature spores were ellipsoidal to slightly pyriform and measured 2.30 x 1.41 microm. The polar filament was anisofilar and consisted of a single coil with six to seven turns (rarely five). This new species is named Vavraia mediterranica n. sp.     

Microsporidia-insect host interactions: teratoid sporogony at the sites of host tissue melanization

Microsporidia Paranosema locustae and Paranosema grylli infect fat bodies of orthopteran hosts Locusta migratoria and Gryllus bimaculatus, respectively, and cause formation of nodules consisting of deposits of melanin around heavily infected cells. Both species sporadically produce enlarged or malformed (teratoid) spores as a result of abnormal sporogony. Proportions of teratospores within melanized nodules were 6-10 times higher than in surrounding non-melanized tissues. The increased numbers of teratoid microsporidian spores within melanized regions may indicate the deteriorating effect of melanin metabolites on spore morphogenesis.     

Changes in the behaviour of Moina macrocopa (Crustacea: Cladocera) under the influence of Gurleya sp. (Microsporidia: Gurleyidae)

It is established, that infestation with Gurleya sp. (Microsporidia, Gurleyidae) changes the behaviour of its host Moina macrocopa (Straus, 1820), a crustacean inhabiting pools. Heavily infested host individuals attach to surface film of water before their death by senescence. As a consequence, their dead bodies filled with spores of the parasite adhere to objects dipped in water that probably facilitates the transfer of spores by birds and cattle to other pools. Weakly infested or uninfested individuals drown after the end of their ontogenesis. Distribution of the microsporidian spores by two different ways (with attached dead bodies of the hosts or with bottom sediments) makes invasion of a new host more probable.     

Crepidulospora--nomen novum for the junior generic homonym (preoccupied generic name) Crepidula

Crepidulospora nom. nov. is a replacement generic name for the genus Crepidula Simakova, Pankova et Issi, 2003 based on the type species Crepidula beklemishevi Simakova, Pankova et Issi, 2003 (Microsporida) from Anopheles beklemishevi. The name proposed by Simakova et al., 2003 is a preoccupied name, because it was already used for the gastropode Crepidula Lamarque 1899 (Echinospirida, Calibraeidae), a parasite of Mytilus. A valid name of the type species of the genus is now Crepidulospora beklemishevi (Simakova, Pankova, Issi, 2003) comb. n. Crepidulospora Simakova, Pankova et Issi nom. non. Type species: Crepidula beklemishevi Simakova, Pankova, Issi, 2003. Diagnosis. Sporogony is octosporoblastic. Sporogonal stages are in direct contact with host cell cytoplasm. 8 uninucleate spores, 4.2 x 2.2 mkm, are sandals-like. Polar tube is anisofilar, with 6-7 coils (2 + 4-5). Polaroplast is three-partite, with broad vesicular, vesicular and lamellar compartments. Microsporidia ilnfects larval adipose tissues. Type host: Anopheles beklemishevi (Diptera, Culicidae).     

A re-evaluation of Hypochnicium (Polyporales) based on morphological and molecular characters

Hypochnicium is a genus of corticioid, wood-inhabiting fungi in the Polyporales with a worldwide distribution. The genus has been characterized by the nature of the spores; they are thick-walled, smooth or ornamented, and cyanophilous. Nine new ITS nrDNA sequences from species of this genus were aligned with 32 sequences from GenBank, and phylogenetic analyses were performed. Six clades were determined within the genus; one contains taxa with smooth spores, and the other three with ornamented spores. Hypochnicium versatum must be included in Gloeohypochnicium, and the new combination Gloeohypochnicium versatum is proposed. Two new species, Hypochnicium michelii from Spain and Hypochnicium guineensis from Equatorial Guinea, are described.     

Uptake of Encephalitozoon spp. and Vittaforma corneae (Microsporidia) by different cells

Microsporidia are obligate intracellular parasites infecting a broad range of vertebrates and invertebrates. Various microsporidian species induce different clinical pictures in humans. The reason for this is not clear. It has been speculated that the different microsporidian species are transmitted by various routes, thus causing infections in different organs. Another possibility is that the diverse microsporidia have different tropisms to organ-specific cells, thus causing various diseases. In this study, we investigated the uptake of microsporidian spores by different cells with an immunofluorescence staining technique to investigate whether there is a difference between microsporidian species as well as between different cells. Using this technique, we were able to distinguish between intra- and extracellular microsporidian spores. All examined cell lines were able to internalize microsporidian spores, but the extent of internalization differed significantly between the cells. Although the results showed some patterns that correlate with the distribution of the parasites in humans, the different clinical pictures cannot be sufficiently explained by this phenomenon, so it seems more likely that the various clinical manifestations caused by the different microsporidian species are a consequence of different infection routes rather than of different affinities of the microsporidian species to different cells.