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.     

Mass production and storage of Vairimorpha necatrix (protozoa: Microsporida)

Mass production and storage methods were evaluated for maximization of spores of Vairimorpha necatrix, a promising protozoan for microbial control due to its virulence and prolificity in lepidopterous pests. In vivo spore production was at a maximum when 3rd instar Heliothis zea were exposed to 6.6 spores/mm² of artificial diet surface and reared for 15 days. Approximately 1.67 × 10¹⁰ spores/larva were produced, or ca. 1 × 10¹⁰ spores/larva after partial purification of the spores by homogenization of the larvae in water, filtration, and centrifugation. The spores were inactivated by relatively short exposures to several chemicals which were tested to counteract contamination of the diet surface by fungi in the spore inoculum. Spores of V. necatrix were stored at refrigerated and freezing temperatures for up to 2 years and bioassayed periodically with 2nd instar H. zea. Spores lost little infectivity after 23 months at 6°C if they were stored in a purified water suspension plus antibiotic, but they were noninfective after 18 months at 6°C if stored in host tissue. Storage at ?15°C caused little loss of infectivity whether the spores were stored in water and glycerine, in host tissue, or after lyophilization. The spores withstood lyophilization in host cadavers better than in purified water suspension. Samples of a dry V. necatrix-corn meal formulation, which was prepared for field efficacy tests and stored at ?15° and 6°C, were highly infective after 9 months. Large numbers of V. necatrix spores can thus be produced and later made available for microbial control field trials with little loss of infectivity.     

Studies onBonnetia comta [Dipt.: Tachinidae] parasitizingAgrotis ipsilon [Lep.: Noctuidae] larvae

Laboratory studies showed that 1st-instarBonnetia comta (Fallén) maggots (planidia) had a significant impact (P<0.05) on mortality of all black cutworm (BCW),Agrotis ipsilon (Hufnagel), instars, either by killing 1st- and 2nd-instar BCWs 2.3 to 9.7 days after parasitization or by producing a puparium from older host instars. Diet consumption and utilization by BCW larvae parasitized byB. comta as 4th instars were similar to those of nonparasitized larvae until 1 to 2 days before the parasitoid emerged. In a 2-year host exposure study in Iowa, it was found thatB. comta primarily parasitized released BCWs in June through September and did not seem to play a role in controlling the damaging 1st generation of BCW larvae. Techniques were developed to produce and store large numbers ofB. comta planidia.Bonnetia comta deposited large numbers of planidia on filter paper treated with a fecal supernatant. These planidia could be stored on filter paper in a covered Petri dish at 4.4°C for 5 days with minimal mortality. Preliminary field data show that planidia placed around corn seedlings infested with 4th-instar BCW larvae do parasitize the pest and reduce the hosts cutting potential.     

Larviposition response ofBonnetia comta [Dipt.: Tachinidae] to a kairomone ofAgrotis ipsilon [Lep.: Noctuidae]

A kairomone in the frass and vomitus of larvae ofAgrotis ipsilon (Hufnagel) (Lepidoptera: Noctuidae) triggered larviposition activity in its habitual parasitoidBonnetia comta (Fallen) (Diptera: Tachinidae). Laboratory bioassays showed that no measurable differences existed in the larviposition-stimulating activity of frass fromA. ipsilon larvae reared on 3 different food sources. In other tests, corn seedlings damaged by late-instar larvae ofA. ipsilon elicited strong larviposition activity inB. comta; other corn seedlings damaged with a razor blade did not elicit strong activity. Frass aged for 8-days was only slightly less effective at releasing a larviposition response when compared to fresh frass.B. comta was not stimulated to larviposit by oven dried frass or an India ink dot the color and shape of a fresh pellet from a host larva. The host habitat location and host finding process forB. comta and other tachinid species that deposit free-living maggots is discussed.     

Dissemination of the biocontrol agent Vairimorpha necatrix by the spined soldier bug, Podisus maculiventris

The ability of the spined soldier bug, Podisus maculiventris (Say) (Heteroptera: Pentatomidae), to disseminate infective forms of two lepidopteran pathogens, Vairimorpha necatrix (Kramer) (Microspora: Microsporidia) and Lacanobia oleracea granulovirus (LoGV) was investigated. Individual female P. maculiventris that had fed on Lacanobia oleracea L. (Lepidoptera: Noctuidae) larvae, infected with V. necatrix, excreted approximately 6 × 10⁸V. necatrix spores during the subsequent 7 days. Excreted spores were fed to L. oleracea larvae, causing 100% mortality, indicating that the spores remained viable after passing through the gut of the predator. Podisus maculiventris that had fed on V. necatrix or LoGV‐infected larvae were allowed to defecate on the foliage of tomato plants, prior to the infestation of the plants with L. oleracea or Spodoptera littoralis (Boisduval) (Lepidoptera: Noctuidae) larvae. This proved to be an effective way of infecting the pest larvae with the pathogens, particularly when five predatory bugs were used per plant. After 20 days, the number of S. littoralis and L. oleracea surviving on the plants was reduced by 75% and 61%, respectively. Female P. maculiventris maintained on V. necatrix‐infected prey showed reduced egg production and longevity, whilst those fed on LoGV‐infected prey showed only reduced egg production. The potential for P. maculiventris to disseminate insect pathogens is discussed in the context of improved biological control of lepidopteran pests.     

Endophyte-mediated tritrophic interactions between a grass-feeding caterpillar and two parasitoid species with different life histories

Plant secondary chemicals can alter herbivore suitability for parasitoids by weakening or stunting the host, delaying its development, or when larval parasitoids encounter ingested phytotoxins in the body of their host. Experiments with different parasitoids that exploit the same host species feeding on the same plant may provide insight about how parasitoid life history affects the strength of such interactions. The encyrtid wasp Copidosoma bakeri, a slow-developing polyembryonic egg-larval parasitoid, and the tachinid fly Linnaemya comta, a fast-developing solitary species, both parasitize Agrotis ipsilon, a generalist noctuid. We tested the hypothesis that of the two parasitoid species, the encyrtid, because of its more prolonged developmental association with the host, would suffer greater fitness costs when A. ipsilon feeds on perennial ryegrass containing an alkaloid-producing fungal endophyte. Indeed, fewer parasitized cutworms yielded C. bakeri broods, and those host mummies were smaller, formed more slowly, and contained fewer adults when the hosts fed on endophytic as opposed to endophyte-free grass. In contrast, L. comta fitness parameters were similar regardless of the type of grass upon which their host fed. Our results highlight that the outcome of endophyte-mediated tritrophic interactions may differ for different parasitoid species. Implications for integrating the use of endophytic grasses and biological control are discussed.     

Interactions between the solitary endoparasitoid, Meteorus gyrator (Hymenoptera: Braconidae) and its host, Lacanobia oleracea (Lepidoptera: Noctuidae), infected with the entomopathogenic microsporidium, Vairimorpha necatrix (Microspora: Microsporidia)

Infection of Lacanobia oleracea (Linnaeus) larvae with the microsporidium Vairimorpha necatrix (Kramer) resulted in significant effects on the survival and development of the braconid parasitoid, Meteorus gyrator (Thunberg). Female M. gyrator did not show any avoidance of V. necatrix-infected hosts when they were selecting hosts for oviposition. When parasitism occurred at the same time as infection by the pathogen, or up to four days later, no significant detrimental effects on the parasitoid were observed. However, when parasitism occurred six to eight days after infection, a greater proportion (12.5-14%) of hosts died before parasitoid larvae egressed. Successful eclosion of adult wasps was also reduced. When parasitism and infection were concurrent, parasitoid larval development was significantly faster in infected hosts, and cocoons were significantly heavier. However, as the time interval between infection and parasitism increased, parasitoid larval development was significantly extended by up to two days, and the cocoons formed were significantly (c. 20%) smaller. Vairimorpha necatrix spores were ingested by the developing parasitoid larvae, accumulated in the occluded midgut, and were excreted in the meconium upon pupation.     

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.     

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.     

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.     

Larviposition of Compsilura concinnata (meigen) (diptera: Tachinidae), a parasitoid of the gypsy moth,Lymantria dispar (L.) (lepidoptera: Lymantriidae)

Larviposition of Compsilura concinnata, a polyphagous tachinid parasitoid of Lepidoptera, is described. The conventional assessment, long‐established in the literature, places the site of larval deposition by C. concinnata as directly into the host's gut. New evidence, reported here, contradicts the earlier view. Dissection of 38 freshly parasitized gypsy moth (Lymantria dispar) larvae revealed as many maggots (n = 26) situated in the lumen of the midgut as were free in the hemocoel. Observations on maggot behavior and morphology in dissected hosts are briefly presented.     

Vairimorpha invictae N. Sp. (Microspora: Microsporida), a Parasite of the Red Imported Fire Ant,Solenopsis invicta Buren (Hymenoptera: Formicidae)12

ABSTRACT. Vairimorpha invictae n. sp. infects the red imported fire ant, Solenopsis invicta Buren, in Brazil. The parasite is dimorphic, producing two morphologically distinct types of spores, which develop sequentially in the same fat cells or oenocytes in the fat body. The binucleate free spores develop from disporous sporonts; the uninucleate octospores develop from multinucleate sporonts within a sporophorous vesicle. Infected cells are transformed into large sacs which contain both types of spores in mature adult hosts. Mature free spores are often present by the time the larvae pupate, but mature octospores are found only in adult hosts. Masses of spores may be seen through the intact cuticle by low power phase-contrast microscopy; there are no other physical signs and no behavioral signs of infection. Attempts to transmit the infection in the laboratory failed.     

Host behaviour and its influence on foraging and acceptance by the solitary parasitoid wasp,Venturia canescens (Hym: Ichneumonidae)

Behavioural interactions between the solitary koinobiont parasitoid,Venturia canescens, and two of its hosts,Plodia interpunctella andCorcyra cephalonica, were investigated. The response of both hosts to simulated antennation using a two-haired brush was examined over instars 3 (L3) to 5 (L5). YoungP. interpunctella larvae predominantly adopted escape tactics (writhe, trash) whereas L5P. interpunctella usually froze after the stimulus was applied. L3C. cephalonica larvae were more aggressive (headrear, flick) thanP. interpunctella in response to the application of the stimulus, but olderC. cephalonica responded less aggressively than in earlier instars. AlthoughV. canescens readily jabbed its ovipositor at both hosts after antennation,P. interpunctella was considerably more susceptible to parasitoid attack thanC. cephalonica, irrespective of size in the final (L5) instar.C. cephalonica, the larger, more aggressive host, actively resisted parasitism whereasP. interpunctella responded much more passively after parasitoid contact. Parasitoids examined and jabbed their ovipositors at dead hosts, but this behaviour was not sustained, implying that host movement stimulates parasitoid attack. On patches containingV. canescens, L5C. cephalonica andP. interpunctella, mostP. interpunctella larvae responded by freezing after parasitoid contact.P. interpunctella that froze usually avoided parasitism, whereas larvae that attempted to escape by crawling were pursued with vigour byV. canescens and usually parasitized. Irrespective of behaviour after parasitoid contact,C. cephalonia displayed more aggressive behaviour and had much greater success in warding off parasitoid attack. Host acceptance byV. canescens is clearly affected by the size and species of the host it attacks. The influence of host defensive behaviour is discussed in relation to the evolution of parasitoid counter-defences and oviposition strategies.     

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.     

Different course of proteolytic inhibitory activity and proteolytic activity in Galleria mellonella larvae infected by Nosema algerae and Vairimorpha heterosporum

The activity of protease inhibitors and proteases was studied in the hemolymph, gut, and fat body of 7th-instar larvae of Galleria mellonella infected by two microsporidia, Nosema algerae and Vairimorpha heterosporum. The increase in inhibitory activity in the hemolymph was substantial, and coincided with the development of the disease. The increase in inhibitory activity in the gut was almost doubled by N. algerae as compared with V. heterosporum, whereas the increase in inhibitory activity in fat body was found only in V. heterosporum-infected larvae. The course of proteolytic activity followed an inverse pattern to the elevated activity of inhibitors in the gut and the fat body, and rose only in moribund larvae at the end of the course of V. heterosporum infection. The differences in the pattern of proteases and inhibitors reflect the organ specificity of each of the microsporidia.     

Performance of Microplitis tuberculifer (Hymenoptera: Braconidae) parasitizing Mythimna separata (Lepidoptera: Noctuidae) in different larval instars

The solitary parasitoid Microplitis tuberculifer (Wesmael) is an important biological control agent of various lepidopteran pests in Asia. We examined the preference of M. tuberculifer for different instars of its common host, Mythimna separata (Walker), host instar effects on parasitoid development, and the consequences of parasitism in different stages for growth and consumption of host larvae. The wasp successfully parasitized the first four larval instars of M. separata, but not the fifth, which appeared to be behaviorally resistant. First and second instars were parasitized at higher rates compared to thirds and fourths in no-choice situations, ostensibly due to longer handling times for the latter, but second instars were most preferred in a choice test that presented all stages simultaneously. Although later instar hosts yielded heavier cocoons, the fastest parasitoid development was obtained in second instars. Lower sex ratios were obtained from first instars as females appeared to lay a smaller proportion of fertilized eggs in small hosts. Both weight gain and food consumption of parasitized larvae were reduced significantly within 24 h of parasitism, regardless of the stage parasitized, and final body weights were less than 10% those of unparasitized larvae. Thus, M. tuberculifer has good potential as a biological control agent of M. separata, successfully parasitizing the first four larval instars and dramatically reducing plant consumption by the host in all cases.     

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.     

Temperature effects during development on a polyembryonic parasitoid and its host

Ambient temperature can influence development through effects on metabolic rate and by inducing physiological stress. In this study, we assessed temperature effects on a host–parasitoid interaction and on the body size and brood size of emerging wasps. By examining the development at two different temperatures of the koinobiont parasitoid, Copidosoma bakeri, and its host, Agrotis ipsilon, we asked: (1) Does the growth response to temperature by A. ipsilon depend on whether the moth caterpillar is parasitized? (2) Does the allocation pattern of body size and brood size in C. bakeri change with temperature? To answer these questions, we exposed A. ipsilon larvae parasitized by C. bakeri to high or low non-lethal temperatures when A. ipsilon was in early or late larval stages and measured their development time and body mass for all four treatment combinations. We also examined the brood size and body mass of emerging wasps. Whether parasitized or not, A. ipsilon larvae decreased development time, but generally did not decrease final body mass, at the higher temperature. When parasitized A. ipsilon was exposed to the higher temperature only late in their development, enlargement of the host by the parasitoid was reduced. C. bakeri brood size significantly increased when the higher temperature was applied early in host development. We did not detect a shift with temperature in the allocation pattern of the size–number trade-off for wasp offspring, suggesting that this trade-off relationship may be under selection strong enough to yield insensitivity to temperature.     

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.