Nosema takapauensis n.sp., a microsporidan parasite of larvae of Costelytra zealandica (Coleoptera: Scarabaeidae) in New Zealand

Morphological and biological features of a microsporidan protozoan parasite of larvae of Costelytra zealandica collected at Takapau, southern Hawkes Bay, are described and evaluated taxonomically. The parasite multiplies in the fat body of all larval instars, causing massive tissue disintegration in advanced infection resulting in the retardation of development and ultimately death before pupation. The microsporidan forms one spore per sporont, and therefore belongs to genus Nosema’, it is considered to be specifically distinct from its nearest congener, N. melolonthae.     

Nosema parkeri sp. n., a microsporidan from the argasid tick, Ornithodoros parkeri Cooley.

Nosema parkeri sp. n. is described from nymphs and adults of the argasid tick, Ornithodoros parkeri Cooley, from a laboratory colony. Schizogonic and sporogonic stages are described from various tick tissues. Spores are binucleate, measuring 3.2 (3-4) x 1.9 (1.8-2.5) micronm. Transmission is transovarial and transstadial. The parasite does not appear to affect adversely the development or reproduction of the tick. Dermacentor andersoni Stiles was experimentally infected. Attempts to infect Swiss mice by tick feeding or by injection of infected tick suspensions were unsuccessful. The microsporidan differs in structure from Encephalitozoon ixodis Weiser) and Nosema slovaca Weiser & Rehácek, the only other microsporidans known from ticks.     

Nosema parkeri sp. n., a Microsporidan from the Argasid Tick, Ornithodoros parkeri Cooley

SYNOPSIS. Nosema parkeri sp. n. is described from nymphs and adults of the argasid tick, Ornithodoros parkeri Cooley, from a laboratory colony. Schizogonic and sporogonic stages are described from various tick tissues. Spores are binucleate, measuring 3.2 (3–4) × 1.9 (1.8–2.5) μm. Transmission is transovarial and transstadial. The parasite does not appear to affect adversely the development or reproduction of the tick. Dermacentor andersoni Stiles was experimentally infected. Attempts to infect Swiss mice by tick feeding or by injection of infected tick suspensions were unsuccessful. The microsporidan differs in structure from Encephalitozoon ixodis Weiser) and Nosema slovaca Weiser & Reháček, the only other microsporidans known from ticks.     

Growth of Nosema algerae in pig kidney cell cultures.

Nosema algerae, a microsporidan parasite of mosquitoes, can infect pig kidney cell cultures. Sores germinated in the culture medium, infected the cells within 30 min of germination, multiplied, and produced spores. The early developmental stages in the N. algerae life cycle are discribed.     

Spore Dimorphism in a Microsporidan Isolate*

A microsporidan isolate currently considered to represent a mixed infection of Nosema necatrix Kramer, 1965 and Thelohania diazoma Kramer, 1965 was subjected to cultivation in hosts held at various temperatures. The ratio of the Nosema (monospore) to the Thelohania (octospore) forms at these temperatures was found to vary from 1:1 at 16 C to 1:0 at 32 C. Isolation technics using mechanical, temperature and temporal methods separated monosporous from octosporous forms for inoculation purposes. However, microscopic examination of hosts receiving these inocula revealed the presence of both monospores and octospores. Electrophoretic analysis of monospores and monospore-octospore mixtures indicated equivalent hydrophobic protein spectra. These observations suggest that this isolate has the ability to produce either single spores or spores in groups of eight. This microsporidan was not considered a member of the genus Stempellia since spores in groups of 2 or 4 were not observed. Retention of the name Nosema necatrix Kramer is suggested.     

Nosema algerae: Infection of the white mouse by a mosquito parasite

Spores of Nosema algerae, a microsporidan parasite of mosquitoes, were subcutaneously injected into the ears, tail, and feet of white mice. Infections were transient and localized at the injection sites. Spore germination tests in blood plasma indicated that it is unlikely that spores injected by an infected mosquito bite would result in an infection.     

Growth of Nosema algerae in Pig Kidney Cell Cultures*

SYNOPSIS. Nosema algerae, a microsporidan parasite of mosquitoes, can infect pig kidney cell cultures. Spores germinated in the culture medium, infected the cells within 30 min of germination, multiplied, and produced spores. The early developmental stages in the N. algerae life cycle are described.     

A Microsporidan Infection of Anopheles gambiae Giles, from Tanzania, Interpretation of Its Mode of Transmission and Notes on Nosema Infections in Mosquitoes

SYNOPSIS A microsporidan found parasitic in Anopheles gambiae in Tanzania was identified as Nosema algerae Vavra & Undeen, 1970. Its development was traced in laboratory-bred Anopheles stephensi. Spores were oval, 3.0-4.3 μ× 1.8-2.5 μ and had filaments 40-60 μ long; schizonts were uni-, bi- or tetranucleate; elongate sporonts gave rise to 2 sporoblasts. The parasite attacked almost every tissue of the body of the larvae, pupae and adults including the ova, but transovarial transmission was thought to be unimportant as infected ova did not develop into viable larvae. Hosts reacted to the presence of the parasite by encapsulating some spores in a coat of melanin.
The parasite was lightly infective to several species of culicine mosquitoes, but the infection was limited mainly to the nervous system, mid-gut epithelium and Malpighian tubules.
The species of Nosema parasitizing mosquitoes are reviewed.     

Fine Structure of the Sporogonic Stages of Nosema parkeri

SYNOPSIS The fine structure of sporogonic stages of Nosema parkeri Krinsky, a microsporidan from the argasid tick, Ornithodoros parkeri Cooley, is described. Developmental changes in the spore coat and cytoplasmic organelles are discussed. As a sporoblast transforms into a spore, the organelles become more compact and the membranes surrounding them appear to become more taut. It is suggested that the polaroplast complex is involved in fluid transport during development of the spore. Organelles in the mature spore include 2 contiguous nuclei enveloped in a lattice containing ribosome-like particles, a polaroplast complex composed of laminar and saccular regions, and a coiled tubular polar filament attached to a polar sac. Sporogonic stages do not appear to have mitochondria, Golgi apparatus, or a posterior vacuole. The fine structure of the spore of N. parkeri is very similar to that of species of Nosema found in insects, crustaceans, and trematodes.     

In vivo propagation of a microsporidan pathogenic to insects

Equivalent numbers of spores were produced when the microsporidan Nosema necatrix was propagated in either Trichoplusia ni or Heliothis zea. Maximum spore production was obtained at an inoculum level of 1 × 10⁵ spores/ml. Larvae inoculated 5 days post-hatching contained 1.6 × 10⁹ spores/gram larva after an incubation period of 21 days. Temperature optima for the parasite are 21–26°C in both hosts.     

Morphological and molecular investigations of Tubulinosema ratisbonensis gen. nov., sp. nov. (Microsporidia: Tubulinosematidae fam. nov.), a parasite infecting a laboratory colony of Drosophila melanogaster (Diptera: Drosophilidae)

A new species of microsporidia from Drosophila melanogaster was investigated by light and electron microscopy and by ribosomal RNA (rRNA) sequencing. This microsporidium and the previously described Nosema kingi and Nosema acridophagus have been transferred to the new genus Tubulinosema gen. nov. with the following characters: nuclei are in diplokaryotic arrangement during the life cycle. All stages are in direct contact with the host cell cytoplasm, slightly anisofilar polar tube with the last coils being smaller in diameter arranged in one or two rows on both sides of the diplokaryon and small tubuli on the surface of late meronts. Spores are oval or slightly pyriform. Thick endospore wall, thinner over anchoring disc. This new genus and the genus Brachiola have been placed in a new family Tubulinosematidae fam. nov. Phylogenetic analysis of small subunit rRNA sequences by different methods placed Tubulinosema spp. in one clade with the genus Brachiola forming its sister clade, which is distant from the clade containing the true Nosema spp. including Nosema bombycis.     

Evaluation of Nosema locustae (Microsporida) as a control agent of grasshopper populations in Saskatchewan

A quantitative study of the effect of a microsporidan, Nosema locustae, as a control agent against grasshopper populations in Saskatchewan, Canada, revealed that 50% of the populations of Melanoplus sanguinipes, M. packardii, and Camnula pellucida were infected between 4 and 5 weeks (400 to 424 degree-days) after application of the pathogen. Maxima of 95–100% infection were evident between 9 and 12 weeks (600–700 degree-days) after application. The percentage reduction in surviving populations of M. sanguinipes, i.e., those that did not die from natural causes, reached about 20% by the 4th week (400 degree-days) after inoculation, about 50% by the 9th week (600 + degree-days), and a maximum of about 60% by the 12th week (700 degree-days). An exponential relationship was obtained between percentage reduction and percentage infection in all three species. However, a similar percentage infection resulted in different percentage reduction in the populations. Results also revealed that the rate of reduction in populations reached its peak by about 40–80 degree-days before the maximum rate of infection was attained for each species. Egg production in the two Melanoplus species in treated plots was significantly lower (P < 0.05) than in the control plot.     

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 chrysorrhoeae n. sp. (Microsporidia), isolated from browntail moth (Euproctis chrysorrhoea L.) (Lepidoptera, Lymantriidae) in Bulgaria: characterization and phylogenetic relationships

A new microsporidian parasite Nosema chrysorrhoeae n. sp., isolated in Bulgaria from the browntail moth (Euproctis chrysorrhoea L.), is described. Its life cycle includes two sequential developmental cycles that are similar to the general developmental cycles of the Nosema-like microsporidia and are indistinguishable from those of two Nosema spp. from Lymantria dispar. The primary cycle takes place in the midgut tissues and produces binucleate primary spores. The secondary developmental cycle takes place exclusively in the silk glands and produces binucleate environmental spores. N. chrysorrhoeae is specific to the browntail moth. Phylogenetic analysis based on the ssu rRNA gene sequence places N. chrysorrhoeae in the Nosema/Vairimorpha clade, with the microsporidia from lymantriid and hymenopteran hosts. Partial sequences of the lsu rRNA gene and ITS of related species Nosema kovacevici (Purrini K., Weiser J., 1975. Natürliche Feinde des Goldafters, Euproctis chrysorrhoea L., im Gebiet von Kosovo, FSR Jugoslawien. Anzeiger fuer Sch?dlingskunde, Pflanzen-Umweltschutz, 48, 11-12), Nosema serbica Weiser, 1963 and Nosema sp. from Lymantria monacha was obtained and compared with N. chrysorrhoeae. The molecular data indicate the necessity of future taxonomic reevaluation of the genera Nosema and Vairimorpha.     

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.     

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.     

Cophylogeny of Nosema (Microsporidia: Nosematidae) and bees (Hymenoptera: Apidae) suggests both cospeciation and a host-switch

Some microsporidian parasites belonging to the genus Nosema infect bees. Previous phylogenies of these parasites have produced alternative, conflicting relationships. We analyzed separately, and in combination, large and small subunit ribosomal DNA sequences of Nosema species infecting bees under neighbor-joining, maximum parsimony, maximum likelihood, and Bayesian frameworks. We observed a sister relationship between Nosema ceranae and Nosema bombi, with Nosema apis as a basal member to this group. When compared to their respective hosts (Apis cerana, Bombus spp., and A. mellifera), 2 plausible evolutionary scenarios emerged. The first hypothesis involves a common ancestor of N. bombi host-switching from a historical Bombus lineage to A. cerana. The second suggests an ancestral N. ceranae host-switching to a species of Bombus. The reported events offer insight into the evolutionary history of these organisms and may explain host specificity and virulence of Nosema in these economically important insects.     

Transfer of Nosema locustae (Microsporidia) to Antonospora locustae n. comb. based on molecular and ultrastructural data

Nosema locustae is a microsporidian parasite of grasshopper pests that is used as a biological control agent, and is one of the emerging model systems for microsporidia. Due largely to its diplokaryotic nuclei, N. locustae has been classified in the genus Nosema, a large genus with members that infect a wide variety of insects. However, some molecular studies have cast doubt on the validity of certain Nosema species, and on the taxonomic position of N. locustae. To clarify the affinities of this important insect parasite we sequenced part of the rRNA operon of N. locustae and conducted a phylogenetic analysis using the complete small subunit rRNA gene. Nosema locustae is only distantly related to the nominotypic N. bombycis, and is instead closely related to Antonospora scoticae, a recently described parasite of bees. We examined the ultrastructure of mature N. locustae spores, and found the spore wall to differ from true Nosema species in having a multi-layered exospore resembling that of Antonospora (one of the distinguishing features of that genus). Based on both molecular and morphological evidence, therefore, we propose transferring N. locustae to the genus Antonospora, as Antonospora locustae n. comb.     

Replication of Nosema Algerae In Three Insect Cell Lines

SYNOPSIS Nosema algerae , a microsporidan parasite of anopheline mosquitoes, was successfully replicated in 3 insect cell culture lines: Trichoplusia ni (TN-368); Heliothis zea (IPLB-1075); and Mamestra brassicae (IZD-Mb-0503). Infectious spores were produced in vitro. Spores were observed at 48 h postinfection, and some cells were filled with sproes by 72 h.
The number of parasites per cell increased with time. At 72 h postinfection, the infection rates for the 3 cell lines ranged from 23 to 32%. Infected cell lines were subcultured, and by the 6th passage spore production had ceased.     

Observations on the Spores of Pleistophora gigantea (Thélohan, 1895) Swellengrebel, 1911, a Microsporidan Parasite of the Fish Crenilabrus melops*

SYNOPSIS. After 1914 protozoologists have generally agreed that Pleistophora gigantea (Thélohan, 1895) Swellengrebel, 1911, Ichthyosporidium giganteum (Thélohan, 1895) Swarczewsky, 1914, and I. phymogenes Caullery and Mesnil, 1905, are identical. Because no polar filament was found in the spores, however, some authors have followed Swarczewsky in considering this species to be a haplosporidan, while others have persisted in thinking it a microsporidan. Using preserved material that Swellengrebel saved from a tumor on which he based his studies, we have found a polar filament in the spores both with the PAS reaction and with the electron microscpe. This new information removes the only basis for the doubt which some authors have entertained, that Thélohan and Sweliengrebel correctly considered the parasite to belong to the Microsporida. Since Pleistophora gigantea is believed to be identical with I. phymogenes, recently selected by Sprague as type species of genus Ichthyosporidium Caullery and Mesnil, 1905, then Ichthyosporidium, originally assigned to the Haplosporida, must be regarded as a microsporidan genus. Whether it is distinct from all other microsporidan genera is a matter needing further consideration.