Interactions between Vairimorpha necatrix,Vairimorpha sp., and a nuclear polyhedrosis virus from Rachiplusia ou in Agrotis ipsilon larvae

Vairimorpha sp. and V. necatrix were assayed in combination with one another, and independently, with a nuclear polyhedrosis virus (RoMNPV) from a mint looper, Rachiplusia ou, against neonate and third-stage black cutworm larvae, Agrotis ipsilon. Initially the effect of Vairimorpha sp. was subadditive, additive, or slightly inhibiting to the V. necatrix in the dual microsporidian assays; later, V. necatrix antagonized the effect of the Vairimorpha sp. In combination with Vairimorpha sp. gradients, V. necatrix significantly (P < 0.05) reduced, in most instances, the LT₅₀ values in both neonate and third-stage larval assays. RoMNPV assayed against neonate and third instars, in combination with either Vairimorpha sp. or V. necatrix gradients, usually significantly reduced the LT₅₀ values (P < 0.05). RoMNPV, when combined with either Vairimorpha species, had varying effects on its pathology. In all assays, the particular relationship that was expressed seemed to be a function of the concentration of each pathogen, which may indicate that the two microorganisms compete for entry and/or infective sites within the larval host. Larval size, which was significantly reduced (P < 0.05) by both microsporidia, would be involved in such competition because it would limit the tissue mass available for infection. Histological examinations of larvae with dual infections revealed pathogens in the tissues that they normally infect. Vairimorpha sp. primarily infected epithelial, fat body, and Malpighian tubule tissue and, occasionally, muscle tissue. Viral polyhedral inclusion bodies were found in the same fat body tissues as the Vairimorpha spores.     

A new microsporidian species, Vairimorpha ocinarae n. sp., isolated from Ocinara lida Moore (Lepidoptera: Bombycidae) in Taiwan

A new microsporidium was isolated from Ocinara lida Moore (Lepidoptera: Bombycidae), a pest of Ficus microcarpa L. f. in Taiwan. The microsporidium produces systemic infections in O. lida larvae; the midgut epithelium, Malpighian tubules, and midgut muscle tissues were the target tissues for this isolate, and atrophied fat body tissues were found in heavily infected larvae. Two types of spores were observed, diplokaroytic spores with 11-13 coils of polar tube, and monokaryotic spores with 12 coils of the polar tube that developed within a sporophorous vesicle to form octospores. Electron-dense granules were abundant in the episporontal space of the sporophorous vesicles, and were similar to those of Vairimorpha invictae isolated from Solenopsis invicta, but different from granules or inclusions of other Vairimorpha species. Based on the phylogenetic analysis of the small subunit ribosomal DNA sequence, this isolate is unique within the Vairimorpha complex. Morphological and genetic characters showed this isolate to be a new species. It is placed in the genus Vairimorpha and is described as Vairimorpha ocinarae n. sp.     

Impact of Vairimorpha necatrix and Vairimorpha sp. (Microspora: Microsporida) on Bonnetia comta (Diptera: Tachinidae) within Agrotis ipsilon (Lepidoptera: Noctuidae) hosts

The effect of Vairimorpha necatrix and Vairimorpha sp. on Bonnetia comta developing within pathogen-treated black cutworm, Agrotis ipsilon, hosts was studied. Parasitism by B. comta did not interfere with the near 100% mortality of A. ipsilon caused by either Vairimorpha species. Both microsporidia decreased the number of B. comta able to pupate from a. ipsilon hosts, the days required for adult parasitoid eclosion, and the weights of the puparia. Only in the V. necatrix treatments, however, were these effects significant (P < 0.05) as determined by Duncan's (1955) multiple range test. The impact of each microsporidium on the parasitoid increased with an increase in the concentration of spores to which A. ipsilon was exposed. Both Vairimorpha species had a more detrimental effect on female B. comta than they did on male B. comta. Histological examination of B. comta maggots within V. necatrix- and Vairimorpha sp.-infected A. ipsilon showed the spores primarily restricted to the gut lumen. In older B. comta, dissected from dead Vairimorpha-infected hosts, the guts containing spores were much distended, some to the point that most other parasitoid tissues were absent. This suggests that the detrimental impact the host microsporidian infections had on the parasitoid were related to a nutritional deficiency caused by the accumulation of nondigestable spores in the parasitoid's gut lumen.     

Immunoblot Analysis of Exospore Polypeptides from Some Entomophilic Microsporidia12

ABSTRACT. Immunological relationships between genera and species of microsporidia were examined by immunoblot analysis. Exospore polypeptides from two Nosema spp., three Vairimorpha spp., and two undescribed Vairimorpha-like isolates were analyzed. Gel electrophoresis and immunoblot analysis revealed that a variety of polypeptides, mostly between 15,000 and 90,000 molecular weight, are present on the exospore. The three Vairimorpha spp. are closely related immunologically to each other, but less so to the two undescribed Vairimorpha-like isolates. The two Nosema spp. are immunologically distant from each other and from the Vairimorpha spp. Indirect evidence, however, indicated that many internal spore polypeptides present in both genera are similar. Cross-reactivity between exospore polypeptides from entomophilic microsporidia and antisera to a mammalian microsporidium, Encephalitozoon cuniculi, was very limited. These results indicate that immunoblot analysis of exospore polypeptides may be employed to investigate the interrelatedness of microsporidian species, and that exospore polypeptides of some microsporidia are sufficiently diverse to be of immunodiagnostic value.     

Chimerical nature of the ribosomal RNA gene of a Nosema species

Taxonomic resolution of the Nosema/Vairimorpha clade has been augmented with DNA sequences of the small subunit (SSU) and large subunit (LSU) ribosomal RNA (rRNA) and the arrangement of SSU and LSU. Based on the two characteristics, the clade is largely divided into two, i.e. ‘true’ Nosema sub-group and non-‘true’ Nosema sub-group within the clade. Our study shows that a novel Nosema species isolated from Pieris rapae has mixed characteristics of the ‘true’ and non-‘true’ Nosema sub-group based on the topology of SSU and LSU sequences. To our knowledge, this may be the first case of the incongruent phylogenetic placement of SSU and LSU in the Nosema/Vairimorpha clade. Additionally, the length of internal transcribed spacer (ITS) can be a diagnostic tool to distinguish ‘true’ Nosema from non-’true’ Nosema in the Nosema/Vairimorpha clade based on its nucleotide length as reported before.     

Specific Detection and Localization of Microsporidian Parasites in Invertebrate Hosts by Using In Situ Hybridization

We designed fluorescence in situ hybridization probes for two distinct microsporidian clades and demonstrated their application in detecting, respectively, Nosema/Vairimorpha and Dictyoceola species. We used them to study the vertical transmission of two microsporidia infecting the amphipod Gammarus duebeni.     

A new mycosis of larval lobster (Homarus americanus).

Spodoptera exempta larvae were reared on semisynthetic maize diet. Pathogenicity studies were undertaken on first- to fifth-instar larvae fed a high dosage of Nosema necatrix spores. Larvae from the earlier instars were most susceptible to the microsporidan and also developed bacteriosis. A cytoplasmic polyhedrosis virus (CPV) was evident in some infected larvae but not in controls. The development of N. necatrix is redescribed using the light microscope. A disporoblastic life cycle was evident at 25°C and both a disporoblastic and an octosporoblastic life cycle at 20°C. The implications of the occurrence of bacteriosis and CPV and the possible biological significance of the two sporogonic sequences are discussed. The taxonomic position of N.necatrix is reviewed and, after comparison with existing species of the genera Nosema and Parathelohania, it is placed in the new genus Vairimorpha. The implications of polymorphism are discussed in relation to the classification of the Microsporida.     

The phylogenetic position of Ovavesicula popilliae (Microsporidia) and its relationship to Antonospora and Paranosema based on small subunit rDNA analysis

Comparative small subunit rDNA sequence analyses, indicate that Ovavesicula popilliae, a microsporidian parasite of the Japanese beetle, Popillia japonica, represents a distant sister group to Paranosema and Antonospora. These three genera represent a second major group (the Nosema/Vairimorpha clade representing the first) of Microsopridia which infect terrestrial insects, suggesting independent origins for both groups. Phylogenetic analyses of Ovavesicula and other Microsporidia having a multi-sporous sporogony reveal that this condition is found in several unrelated taxa implying either that multi-sporous sporogony is the ancestral condition for Microsporidia or that it has multiple origins.     

Effects of temperature and dosage on Vairimorpha sp. 696 spore morphometrics,spore yield,and tissue specificity in Heliothis virescens

The effects of temperature and dosage on a new microsporidian species, Vairimorpha sp. 696, were examined in H. virescens. The pathogen was evaluated for tissue specificity, spore size, cumulative percentage mortality, and spore production. All tissues examined bore infection at 32°C. Spore length was significantly longer at 19°C (5.9 μm) than at 32°C (4.7 μm). Spore widths at these two temperatures did not differ significantly. Octospores were not found at either temperature at 8 or 12 days postinoculation. One hundred percent mortality was attained in all dosages administered, but the initial rate of mortaily was more rapid in the higher dosages. Finally, spore yield was greater in larvae administered lower dosages. Maximum spore yield at 27°C was 4.87 × 10⁹ spores/larva.     

Using the SSU,ITS, and Ribosomal DNA Operon Arrangement to Characterize Two Microsporidia Infecting Bruce Spanworm,Operophtera bruceata (Lepidoptera: Geometridae)

Research pertaining to the two closely‐related microsporidian genera Nosema and Vairimorpha is hindered by inconsistencies in species differentiation within and between the two clades. One proposal to better delimit these genera is to restructure the Nosema around a “True Nosema” clade, consisting of species that share a characteristic reversed ribosomal DNA operon arrangement and small subunit (SSU) ribosomal DNA sequences similar to that of the Nosema type species, N. bombycis. Using this framework, we assess two distinct microsporidia recovered from the forest insect Bruce spanworm (Operophtera bruceata) by sequencing their SSU and internal transcribed spacer regions. Phylogenetic analyses place one of our isolates within the proposed True Nosema clade close to N. furnacalis and place the other in the broader Nosema/Vairimorpha clade close to N. thomsoni. We found that 25% of Bruce spanworm cadavers collected over the four‐year study period were infected with microsporidia, but no infections were detected in cadavers of the Bruce spanworm's invasive congener, the winter moth (O. brumata), collected over the same period. We comment on these findings as they relate to the population dynamics of the Bruce spanworm‐winter moth system in this region, and more broadly, on the value of ribosomal DNA operon arrangement in Nosema systematics.     

Phylogenetic relationships of Heterovesicula cowani, a microsporidian pathogen of Mormon crickets, Anabrus simplex (Orthoptera: Tettigoniidae), based on SSU rDNA-sequence analyses

The microsporidium Heterovesicula cowani, discovered in 1985, was initially identified as Vairimorpha sp. because it produces two types of spores: Nosema-like diplokaryotic spores and Thelohania-like mononuclear meiospores. However, light and electron microscopy studies revealed characters that did not fit any known microsporidian genera, and a new monotypic genus Heterovesicula was erected. The goal of this study was to test the validity of the genus Heterovesicula by molecular characterization of H. cowani and to assess its phylogenetic relationships to other microsporidia from insects. DNA from spores stored at −32 °C since 1992 was isolated and PCR-amplified with V1-1492 primers to obtain a partial small subunit ribosomal RNA gene sequence of 1165 bp, which was submitted to GenBank (Accession No. EU275200). Neighbor joining, maximum parsimony and maximum likelihood analyses performed against 18 microsporidia sequences, placed H. cowani as a sister taxon to the Nosema–Vairimorpha clade. The consensus of these analyses suggests that the Heterovesicula–Nosema–Vairimorpha group forms a dichotomy with the Encephalitozoon spp. branch. Other microsporidia parasitizing Orthoptera fell into two unrelated (or distantly related) lineages of terrestrial microsporidia: the Liebermannia spp. branch forms a dichotomy with Orthosomella operophterae within the Endoreticulatus–Orthosomella–Liebermannia group; and the Paranosema spp. branch clusters together with the Tubulinosema–Systenostrema lineage. The minimum pairwise distance in Kimura-2-Parameter analysis among 18 analyzed sequences was 0.37, which supports well the generic status for Heterovesicula. The obtained phylogenetic trees suggest that H. cowani is related to the Vairimorpha necatrix group, but not to other insect microsporidia producing octospores.     

Structure of ribosomal RNA gene and phytogeny ofNosema isolates in Korea

The ribosomal RNA (rRNA) gene region of the fourNosema sp. isolates (C01, C02, C03 and C04) fromPieris rapae in Korea has been examined. Complete DNA sequence data (3779 bp) of The rRNA gene ofNosema sp. C01 are presented for the small subunit gene (SSU rRNA: 1236 bp), the internal transcribed spacer (ITS: 37 bp), and the large subunit gene (LSU rRNA 2506 bp). The secondary structures ofNosema sp. COI SSU and LSU rRNA genes are constructed and described. The SSU rRNA showed a hypervariable V4 region identified four additional stems including a pseudoknot. Phylogenetic analysis based on the SSU rRNA suggests that the four isolates belong to the ‘true’Nosema group. In contrast to theNosema/Vairimorpha clade, the members of the group are highly divergent.     

Pathogenicity of a Microsporidium Isolate from the Diamondback Moth against Noctuid Moths:Characterization and Implications for Microbiological Pest Management

Background

Due to problems with chemical control, there is increasing interest in the use of microsporidia for control of lepidopteran pests. However, there have been few studies to evaluate the susceptibility of exotic species to microsporidia from indigenous Lepidoptera.

Methodology/Principal Findings

We investigated some biological characteristics of the microsporidian parasite isolated from wild Plutella xylostella (PX) and evaluated its pathogenicity on the laboratory responses of sympatric invasive and resident noctuid moths. There were significant differences in spore size and morphology between PX and Spodoptera litura (SL) isolates. Spores of PX isolate were ovocylindrical, while those of SL were oval. PX spores were 1.05 times longer than those of SL, which in turn were 1.49 times wider than those of the PX. The timing of infection peaks was much shorter in SL and resulted in earlier larval death. There were no noticeable differences in amplicon size (two DNA fragments were each about 1200 base pairs in length). Phylogenetic analysis revealed that the small subunit (SSU) rRNA gene sequences of the two isolates shared a clade with Nosema/Vairimorpha sequences. The absence of octospores in infected spodopteran tissues suggested that PX and SL spores are closely related to Nosema plutellae and N. bombycis, respectively. Both SL and S. exigua (SE) exhibited susceptibility to the PX isolate infection, but showed different infection patterns. Tissular infection was more diverse in the former and resulted in much greater spore production and larval mortality. Microsporidium-infected larvae pupated among both infected and control larvae, but adult emergence occurred only in the second group.

Conclusion/Significance

The PX isolate infection prevented completion of development of most leafworm and beet armyworm larvae. The ability of the microsporidian isolate to severely infect and kill larvae of both native and introduced spodopterans makes it a valuable candidate for biocontrol against lepidopteran pests.     

Hemolymph melanization and alterations in hemocyte numbers in Lymantria dispar larvae following infections with different entomopathogenic microsporidia

Lymantria dispar (L.) (Lepidoptera: Lymantriidae) larvae can be infected in the laboratory with a variety of entomopathogenic microsporidia. In many cases, however, L. dispar is only a semi‐permissive host for such infections. In this study, we analyzed changes in the melanization of hemolymph and hemocyte numbers in L. dispar larvae after inoculation with various entomopathogenic microsporidia. We compared the infections produced by microsporidia isolated from L. dispar and infections produced by isolates from other Lepidoptera to which L. dispar is only a semi‐permissive host. Microsporidiosis induced a significant activation of the prophenoloxidase system leading to melanization; activation was highest when the pathogen caused heavy infections of the fat body, which was the case with two microsporidia originally isolated from L. dispar. Infection of only the silk glands or light infection of the fat body by two Vairimorpha spp. from other lepidopteran hosts elicited a lower response. Very light infections caused by a microsporidium isolated from Malacosoma americanum were not accompanied by elevated hemolymph melanization activity. Heavy infections by Endoreticulatus spec. that remained restricted to the gut tissue likewise did not elicit melanization. One Vairimorpha spec. from L. dispar induced a significant increase in total hemocyte numbers; the other infections led to temporarily decreased numbers. Microscopic examinations showed that parts of infected tissue were encapsulated by hemocytes. We conclude that measured alterations in hemolymph melanization and hemocyte numbers were likely to be induced by the damaging effects of heavy infections. Observed defense responses did not prevent the progression of infections.     

自桑兰叶甲分离出的一种微孢子虫(Mic-Ⅰ)的研究

从广州郊区罗岗的桑园及菜地捕捉到的桑兰叶甲Mimastra cyanura Hope成虫体中分离到一种卵圆形的微孢子虫（简称Mic-Ⅰ）。孢子大小为(3.35±0.46)×(1.96±0.17) μm;孢子具单核、双核两种类型;极丝10～11圈;孢子表面抗原的血清学类型与家蚕微粒子虫Nosema bombycis孢子不同;在家蚕Bombyx mori体内以两种不同的生活史发育,发育过程符合变态孢虫属Vairimorpha微孢子虫发育特征。Mic-Ⅰ微孢子虫对家蚕具强病原性,对斜纹夜蛾Prodenia litura和小菜蛾Plutella xylostella也有感染能力。     

Revision of the European species of Omphale Haliday (Hymenoptera,Chalcidoidea, Eulophidae)

The European species of Omphale Haliday (Eulophidae: Entedoninae) are revised. The revision includes 37 species, of which eleven are newly described and the remaining 26 species are redescribed. The species are classified into six species groups, with six unplaced species. All species are fully diagnosed and thoroughly illustrated. Identification keys are provided for females and males. Two new morphological features to aid classification and identification are introduced: male genitalia and wing interference patterns (WIPs). The former has been used successfully in the classification of New World Omphale and the latter is used for the first time in a taxonomic revision. Male genitalia in Omphale have considerable interspecific variation, an unusual trait among chalcidoid Hymenoptera, and are demonstrated to be useful for classification of species and species-groups, and they also possess the only autapomorphy for Omphale. WIPs are useful to help separate some species, but cannot be used to define either the genus or species groups. Distributional data are compiled for each species and suggest a pan-european distribution for most species. Gall-midges are the known hosts for 14 species, and the absence of host overlap between species suggests that host specialization is a driving force for speciation. Several Omphale species are known only from females, or have a strong female biased sex ratio, suggesting thelytokous development. Apart from the 37 species included in this revision, the status for nine additional species (names) in species group aetius remain unsolved. For nomenclatorial stability, a neotype is designated for Eulophus lugens Nees (= Omphale lugens (Nees)). Elachestus obscurus Förster and Derostenus sulciscuta Thomson are transferred from Holcopelte to Omphale comb. n. Derostenus radialis Thomson and Achrysocharella americana Girault are synonymized with Omphale theana (Walker), and Omphale teresis Askew is synonymized with Omphale phruron (Walker), syn. n. The status of genus Pholema Graham is revised as it is removed from synonymy with Omphale and instead synonymized with Neochrysocharis Kurdjumov, syn. n., and the type species for Pholema, Pholema microstoma Graham, is transferred to Neochrysocharis, comb. n. Eugerium orbatum Szelényi, previously transferred to Omphale, is synonymized with Asecodes congruens (Nees), syn. n.     

New species and records of Charisius Champion from Mexico and Central America (Coleoptera,Tenebrionidae, Alleculinae)

The species of the genus Charisius Champion, from Mexico and Central America are reviewed. The flightless genus Narses Champion, with one included species, N. subalatus Champion, is placed in synonymy with the genus Charisius. Four new species are described and illustrated, C. granulatus and C. punctatus (from Guatemala) and C. apterus and C. howdenorum (from Mexico). Charisius subalatus (Champion) is redescribed and illustrated. The species C. interstitialis Champion is placed in synonymy with C. zunilensis Champion. The genus is redescribed to include the four new species and N. subalatus. New distributional records are presented for all other species of the genus and a revised key is presented for identification of all the species of the genus.     

Annotated checklist of the leech species diversity in the Maloe More Strait of Lake Baikal,Russia

In this paper, the very first checklist of the freshwater leeches of Maloe More Strait, a special part of Lake Baikal, is presented. It includes 14 free-living and parasitic species, of which four species belong to endemic Baikal genera – two species from Baicalobdella and one species each from Baicaloclepsis and Codonobdella. The checklist highlights six potentially new morphological species recorded for the first time in the area. The exact systematic position is stated for all leech species. Each species from the list is provided with information on taxonomic synonymy, data on its geographic distribution, and ecological characteristics. New species records are additionally provided with brief morphological characteristics and photos of their external morphology.     

The New Caledonian genus Caledonotrichia Sykora (Trichoptera,Insecta) reviewed,with?descriptions?of?6?new species

The New Caledonian endemic hydroptilid genus Caledonotrichia Sykora (Trichoptera) is reviewed and 6 new species are described: Caledonotrichia bifida, Caledonotrichia capensis, Caledonotrichia minuta, Caledonotrichia ouinnica, Caledonotrichia sykorai and Caledonotrichia vexilla. Together with the established species for which revised diagnoses are given, these raise to 11 the number of species known in this genus. The new species, females of 3 species, and several unusual larval cases are examined and described for further insight into relationships of this enigmatic genus. A key to species is provided.