Internal ultrastructure of spores of microsporidans isolated from the Silkworm,Bombyx mori

Nosema bombycis, two Nosema spp., and a Pleistophora sp. were propagated in the silkworm and the fine structures of their spores were studied. The morphology of the polaroplast, the appearance of the nucleus, and the number of coils in the polar filament differed among the spores of the four species. The spores of the three Nosema species, however, had several identical components; e.g., the polaroplast was made up of two parts, they had two nuclei, and the ribosome arrangement was similar. On the other hand, the spore of Pleistophora sp. had a polaroplast composed of three parts, a single nucleus, and ribosomes arranged around the polar filament. Thus the fine structures of the spore differentiate microsporidan species.     

Detection of relationships among microsporidan isolates by electrophoretic analysis: hydrophobic extracts

Hydrophobic spore proteins were extracted from 11 microsporidan isolates obtained from 9 species of insects for which these microorganisms are pathogenic. Hydrophobic protein spectra were found to be stable when (1) two different genera of hosts were used for spore propagation, (2) hosts were reared at a variety of temperatures, or (3) protein was extracted from spores harvested at different stages of sporogenesis. Five consistent and distinct electrophoretic spectra were observed. Spectrum I was represented by 6 isolates including Nosema necatrix, Thelohania diazoma, Nosema plodiae, and Nosema sphingidis; spectrum II by Pleistophora sp; Spectrum III by Nosema whitei; spectrum IV by Thelohania legeri; and spectrum V by Nosema trichoplusia. The highly reproducible nature of these analyses indicated polyacrylamide gel disc electrophoresis of hydrophobic extracts can be used for the identification of Microsporida. Moreover, these analyses do not support the present classification, based mainly on the number of spores in a pansporoblast, inasfar as (1) some species of Nosema have the same pattern (I) as a species of Thelohania and (2) two species of Nosema have different patterns (III and V) in contrast to the Nosema species showing pattern I.     

Nosema blissi sp. n. (Microsporida: Nosematidae), a pathogen of the chinch bug,Blissus leucopterus hirtus (Hemiptera: Lygaeidae)

Nosema blissi sp. n. is described from the Malpighian tubules of adults of Blissus leucopterus hirtus. Spores measured 6.5 ± 0.3 × 2.5 ± 0.1 μm in Giemsa-stained preparations. The polar filament lay in 37 to 40 coils, arranged in a single layer in the posterior portion of the spore, and in several layers in the anterior portion.     

A microsporidium,Nosema pilicornis sp. n., of the purslane sawfly,Schizocerella pilicornis

A new microsporidian species, Nosema pilicornis, which infects the purslane sawfly, Schizocerella pilicornis, is described. This microsporidium infects most body tissues of the host. N. pilicornis was compared to other microsporidian species infecting Hymenoptera and to a group of similar microsporidia infecting Lepidoptera. N. pilicornis could be distinguished from all other microsporidian species on the basis of host range and ultrastructural characteristics of the spore. Spores were oval, containing 11 to 12 polar filament coils, and the polar filament had an angle of tilt of about 80°. N. pilicornis infected lepidopteran larvae, but only when heavy spore dosages were fed to early larval instars. S. pilicornis is a good but sporadic biological control agent of common purslane, Portulaca oleracea, a pernicious weed of vegetable, ornamental, and orchard crops. N. pilicornis, which is transovarially transmitted and causes high mortality in infected larvae, affects the performance of S. pilicornis as a biological control agent.     

A redescription of Nosema herpobdellae (Microspora: Nosematidae), a parasite of the leech Erpobdella octoculata (Hirudinea: Erpobdellidae)

Nosema herpobdellae was recorded in populations of the leech Erpobdella octoculata from lakes in northwest England and North Wales and is redescribed using light and transmission electron microscopy. It differes from N. glossiphoniae in the nature of the infection and tissues parasitized and from N. tractabile in its larger spore size, longer polar filament, in the angle of the anterior coils of the polar filament to the spore long axis, and apparently in its developmental cycle. The infection was found in a massive xenoma, in the connective tissue surrounding the gut, which was presumed to be formed from a single hypertrophied cell. Its developmental cycle included merogony and sporogony.     

Evaluation of some morphological characteristics of spores of two species of Microsporida by scanning electron microscope and freeze-etching techniques

Scanning electron microscopy revealed spores of Nosema apis and Thelohania fibrata to be egg-shaped, but only the mature spore of T. fibrata was shown to possess a horseshoe-like concavity at the posterior pole. Freezeetched preparations indicated that this concavity was due to a thin area of the spore coat. Freeze-etching studies also show spores of N. apis do possess an umbrella-shaped polaroplast, and a polar filament which is arranged in a double layer with over 30 coils. The spore of T. fibrata contains a pear-shaped arrangement of the polaroplast membrane, and a polar filament arranged in a single layer of 22 coils.     

Detection of relationships among microsporidan isolates by electrophoretic analysis: hydrophilic extracts

Hydrophilic spore proteins were extracted from Nosema sp. and Nosema trichoplusiae. These proteins were subjected to electrophoretic analysis. The resulting electrophoretic spectra were found to be unstable when (1) two genera of hosts were used for spore propagation, (2) hosts were reared at a variety of temperatures, (3) protein was extracted from spores stored for different periods of time, or (4) spore incubation period was varied. Comparison of the major bands obtained from spore protein of the isolates indicated no overlap in relative migration values. Although variation in spectra was observed, the use of major band patterns indicate electrophoretic analysis of hydrophilic spore protein can provide characters useful in the separation and identification of microsporidan isolates. Nosema sp. and Nosema trichoplusiae are not considered to be closely related phylogenetically.     

Effects of Fumidil B on the spore of Nosema apis and on lipids of the host cell as revealed by freeze-etching

The epithelial cells of the midgut of honey bees, Apis mellifera, infected with Nosema apis showed young and mature spores randomly distributed in the cytoplasm. In these cells, only mitochondria and protein granules were observed. After treating infected bees with Fumidil B, an ultrastructural alteration in the spore membrane, especially in the young spore, was observed. At the same time, lipid granules appeared in the cytoplasm, mostly around the spores. The number of protein granules also increased.     

Scanning electron microscope observations on the spore of Nosema apis Zander

A simple Epon block fracture technique was used to process spores of Nosema apis for scanning clectron microscope examination. The mature spore was egg-shaped with a pointed anterior pole. The young spore was more elongated. The surface of both stages was smooth. A large number of midgut epithelial cells which harbour N. apis were also observed. The cell surfaces of the epithelial cells were also smooth.     

A multiplex PCR assay to diagnose and quantify Nosema infections in honey bees (Apis mellifera)

Correct identification of the microsporidia, Nosema apis and Nosema ceranae, is key to the study and control of Nosema disease of honey bees (Apis mellifera). A rapid DNA extraction method combined with multiplex PCR to amplify the 16S rRNA gene with species-specific primers was compared with a previously published assay requiring spore-germination buffer and a DNA extraction kit. When the spore germination-extraction kit method was used, 10 or more bees were required to detect the pathogens, whereas the new extraction method made it possible to detect the pathogens in single bees. Approx. 4-8 times better detection of N. ceranae was found with the new method compared to the spore germination-extraction kit method. In addition, the time and cost required to process samples was lower with the proposed method compared to using a kit. Using the new DNA extraction method, a spore quantification procedure was developed using a triplex PCR involving co-amplifying the N. apis and N. ceranae 16S rRNA gene with the ribosomal protein gene, RpS5, from the honey bee. The accuracy of this semi-quantitative PCR was determined by comparing the relative band intensities to the number of spores per bee determined by microscopy for 23 samples, and a high correlation (R² = 0.95) was observed. This method of Nosema spore quantification revealed that spore numbers as low as 100 spores/bee could be detected by PCR. The new semi-quantitative triplex PCR assay is more sensitive, economical, rapid, simple, and reliable than previously published standard PCR-based methods for detection of Nosema and will be useful in laboratories where real-time PCR is not available.     

The fine structure of the frozen-etched spore of Nosema apis Zander

The mature spore of Nosema apis possesses a thick spore coat and a particle-bearing spore membrane. Within the spore membrane, in the anterior portion of the spore, is the highly laminated polaroplast. The fractured face of the lamella is granular. The convex face of the polar filament membrane carries few particles, while the concave face bears many densely packed particles. The nucleus of the mature spore is centrally located, and pores were observed on the nuclear envelope.     

The preservation of infective spores of Nosema necatrix (Protozoa: Microsporida) in Spodoptera exempta (Lepidoptera: Noctuidae) by lyophilization

Cadavers of Spodoptera exempta infected with Nosema necatrix were lyophilized. The lyophilized material was tested against a standard spore preparation 1 day after lyophilization and retested 2 yr later. There was some loss of spore viability. The feasibility of using dose-mortality experiments to estimate the loss in viability is discussed.     

Two-dimensional electrophoretic analysis of spore proteins of the Microsporida

Microsporida are potentially useful as biological control agents for insects of economic and medical importance. Prior to their responsible use, however, an accurate and reliable means of identification to the species and subspecies level is required. Current methods used for identification are not adequate, due to variability of identifiable characters and to the occurrence of dimorphism. Recently, progress has been made in the use of biochemical characteristics to support the more traditional methods of distinguishing between morphologically similar species. We report on an improved method of characterization of microsporidan spore proteins, using 2-dimensional polyacrylamide gel electrophoresis (2D-PAGE). This method increased the number of spore polypeptides resolved from Nosema locustae spore protein extracts 2-3-fold over 1-dimensional PAGE. Also, each of the 2D-PAGE spore protein fingerprints of the species examined, namely Nosema locustae, Nosema bombycis, and Vairimorpha necatrix, were unique and differences in their spore protein composition were easily determined. The major structural proteins of Nosema locustae spores co-electrophoresed with alpha and beta tubulin from calf brain and had similar pI and molecular weight values as reported for tubulin in other species. Each species' 2D-PAGE fingerprint contained a few polypeptides that were present in relatively high concentration and these polypeptides may represent the major proteins of the structural components of the spore.     

Nosema ceranae Escapes Fumagillin Control in Honey Bees

Fumagillin is the only antibiotic approved for control of nosema disease in honey bees and has been extensively used in United States apiculture for more than 50 years for control of Nosema apis. It is toxic to mammals and must be applied seasonally and with caution to avoid residues in honey. Fumagillin degrades or is diluted in hives over the foraging season, exposing bees and the microsporidia to declining concentrations of the drug. We showed that spore production by Nosema ceranae, an emerging microsporidian pathogen in honey bees, increased in response to declining fumagillin concentrations, up to 100% higher than that of infected bees that have not been exposed to fumagillin. N. apis spore production was also higher, although not significantly so. Fumagillin inhibits the enzyme methionine aminopeptidase2 (MetAP2) in eukaryotic cells and interferes with protein modifications necessary for normal cell function. We sequenced the MetAP2 gene for apid Nosema species and determined that, although susceptibility to fumagillin differs among species, there are no apparent differences in fumagillin binding sites. Protein assays of uninfected bees showed that fumagillin altered structural and metabolic proteins in honey bee midgut tissues at concentrations that do not suppress microsporidia reproduction. The microsporidia, particularly N. ceranae, are apparently released from the suppressive effects of fumagillin at concentrations that continue to impact honey bee physiology. The current application protocol for fumagillin may exacerbate N. ceranae infection rather than suppress it.     

Establishment of the new genus Paranosema based on the ultrastructure and molecular phylogeny of the type species Paranosema grylli Gen. Nov., Comb. Nov. (Sokolova, Selezniov, Dolgikh, Issi 1994), from the cricket Gryllus bimaculatus Deg

The ultrastructure of the microsporidian parasite Nosema grylli, which parasitizes primarily fat body cells and haemocytes of the cricket Gryllus bimaculatus (Orthoptera, Gryllidae) is described. All observed stages (meront, meront/sporont transitional stage ("second meront"), sporont, sporoblast, and spore) are found in direct contact with the host cell cytoplasm. Nuclei are diplokaryotic during almost all stages of the life cycle, but a brief stage with one nucleus containing an abundance of electron-dense material is observed during a "second merogony." Sporogony is disporous. Mature spores are ovocylindrical in shape and measure 4.5+/-0.16micromx2.2+/-0.07 microm (n=10) on fresh smears and 3.3+/-0.06 micromx1.4+/-0.07 microm (n=10) on ultrathin sections. Spores contain 15-18 coils of an isofilar polar filament arranged in one or two layers. Comparative phylogenetic analysis using rDNA shows N. grylli to be closely related to another orthopteran microsporidian, Nosema locustae, and to Nosema whitei from the confused flour beetle, Tribolium confusum. Antonospora scoticae, a parasite of the communal bee Andrena scotica, is a sister taxon to these three Nosema species. The sequence divergence and morphological traits clearly separate this group of "Nosema" parasites from the "true" Nosema clade containing Nosema bombycis. We therefore propose to change the generic name of N. grylli and its close relative N. locustae to Paranosema n. comb. We leave N. whitei in former status until more data on fine morphology of the species are obtained.     

In vivo germination and host specificity of Nosema algerae in mosquitoes.

Of five species of mosquitoes tested, Anopheles stephensi and A. albimanus were the most susceptible, A. quadrimaculatus and Culex pipiens were relatively unsusceptible and A. atroparvus was almost completely refractory to Nosema algerae. Spore germination percentages differed in the larval midguts of the five species of mosquito but not in the order which would explain the susceptibility differences. Neither midgut pH difference nor differences in passage rate through the midgut were sufficient to explain the observed differences in spore germination percentages.     

Comparative virulence of Nosema plodiae and Nosema heterosporum in the Indian meal moth, Plodia interpunctella

When larvae of the Indian meal moth, Plodia interpunctella, were fed diets containing spores of Nosema plodiae, the number that survived to the adult stage decreased and the rate of adult emergence was retarded as the concentration of spores was increased; all surviving adults were infected. Also, when larvae were reared on diets containing spores of Nosema heterosporum, the number that survived to the adult stage decreased as the concentration of spores was increased; however, no relationship was apparent between concentration of spores and the rate of adult emergence. The LC₅₀'s of N. plodiae and N. heterosporum were 8.09 × 10⁶ and 4.52 × 10³ spores/g diet, respectively, which confirmed preliminary observations regarding the relative virulence of the two species of Nosema to Indian meal moth larvae.     

Morphological and molecular studies of a microsporidium (Nosema sp.) isolated from the thee spot grass yellow butterfly, Eurema blanda arsakia (Lepidoptera: Pieridae)

A microsporidium possessing molecular and morphological characteristics of the genus Nosema was isolated from larvae of the thee-spot grass yellow butterfly, Eurema blanda arsakia. The complete rRNA gene sequences of the E. blanda isolate contained 4,428 base pairs (GenBank Accession No. EU338534). The organization of the rRNA genes is LSU rRNA-ITS-SSU rRNA-IGS-5S, which corresponds with that of Nosema species closely related to Nosema bombycis. Phylogenetic analysis based on rRNA gene sequences show that this isolate is closely related to Nosema bombycis, Nosema plutellae, Nosema spodopterae, and Nosema antheraeae. The ultrastructure of all developmental stages of this microsporidium confirmed its placement in the genus Nosema. The isolate was successfully propagated in cell lines IPLB-LD652Y (Lymantria dispar) and NTU-LY (Lymantria xylina) and, in the in vitro system, it was frequently found to develop in the nuclei of the host cells, a circumstance that seldom occurs in other Nosema species. An extra-cellular vegetative stage of this microsporidium was also observed in the culture medium after 14 days of infection. The ECMDFs might be released from disrupted host cells.     

Occurrence of Nosema oryzaephili in Cryptolestes ferrugineus and transfer to the genus Paranosema

A microsporidium that closely resembles Paranosema species at the level of the light microscope was isolated from the rusty grain beetle, Cryptolestes ferrugineus. It’s identity as Nosema oryzaephili (originally described from Oryzaephilus surinamensis) was confirmed by comparison with a known isolate of N. oryzaephili based on spore size, small subunit rDNA sequence, and relative infectivity to O. surinamensis, Tribolium castaneum, and Ephestia kuehniella. Phylogenetic analysis of the small subunit rDNA indicates clearly that this species belongs in the genus Paranosema and thus the designation Paranosema oryzaephili (Burges, Canning and Hurst) is proposed. In spite of the abundance, economic importance, and world-wide distribution of C. ferrugineus, this is the first report of a microsporidial infection in this species. This is also the first report of P. oryzaephili in the new world.     

Systematics of the genus Ceratopteris Brongn. (Parkeriaceae) II. Taxonomy

A revision of the genusCeratopteris is presented based on comparative morphology and geographical distribution. Four species are recognized:C. thalictroides, C. cornuta, C. pteridoides, andC. richardii. Characteristics of taxonomic importance include frond length, shape, and dissection; stipe width; insertion of basal pinnae; bud development; habit; annulus cell number; spore number per sporangium; spore size; and spore surface features. Evolution within species and putative hybridization between species are discussed.