Interactions between a braconid,Microplitis croceipes,and a fungus,Nomuraea rileyi,in laboratory-reared bollworm larvae

The parasite Microplitis croceipes required 1.1 days longer at 26°C to complete development in Heliothis zea larvae than was required for the fungus Nomuraea rileyi to kill the host larvae and sporulate. Host larvae parasitized by M. croceipes or infected with N. rileyi failed to complete a fifth larval molt or pupate. Of the remaining healthy larvae, one-half completed six larval stadia before popation. Larvae parasitized by M. croceipes were predisposed to infection by N. rileyi, but the fungus inhibited development of M. croceipes if host larvae were infected with N. rileyi within 1 day after parasitization.     

The genus Nomuraea Maublanc

The history of Spicaria rileyi (Farlow) Charles and Spicaria prasina (Maub.) Sawada is discussed. The genus Nomuraea is resurrected and Spicaria rileyi is transferred to that genus. Spicaria prasina is placed in synonomy with Nomuraea rileyi (Farlow) Samson.     

Soybean leaf consumption by Nomuraea rileyi (Fungi: Deuteromycotina)-infected Plathypena scabra (Lepidoptera: Noctuidae) larvae

To determine the impact of Nomuraea rileyi on consumption by the green cloverworm, Plathypena scabra, larvae were reared from eggs obtained from field-collected moths, inoculated with conidia, and placed individually in separate plastic vials with a piece of surface-sterilized soybean leaflet. No significant differences in consumption rates were found between N. rileyi-inoculated and control larvae until after 144 hr post-treatment. After this period, consumption by larvae inoculated as first, second, third, or fourth instars was significantly less than that of control larvae because of mortality. First or second instars inoculated with N. rileyi conidia had significantly longer subsequent stadia than did control larvae. The average LT₅₀ of all inoculated instar groups was 6.5 days, and there was little evidence of significantly different N. rileyi susceptibility among instar groups. In general during the N. rileyi infection period leading to their deaths, inoculated P. scabra larvae had consumption patterns that were very similar to those of healthy larvae.     

MripacC regulates blastosphere budding and influences virulence of the pathogenic fungus Metarhizium rileyi

Fungal dimorphism is the ability of certain fungi to switch between two different cellular forms, yeast and mycelial forms, in response to external environmental factors. The pacC/Pal signal transduction pathway responds to neutral and alkaline environments and is also involved in the fungal dimorphic transition. In this study, we investigated the function of the pacC homolog, MripacC, which regulates the dimorphic transition and modulates virulence of the insect pathogenic fungus Metarhizium rileyi. MripacC expression was upregulated under alkaline condition, with increased number of yeast-like cells compared to the number of hyphae cells. A MripacC deletion mutant (ΔMripacC) was obtained by homologous replacement and exhibited decreased blastospore budding, with direct development of conidia into hyphae without entering the yeast-like stage when cultured on alkaline medium. Observation of host hemolymph morphology and analysis of samples to detect the main immune factors revealed a decreased ability of ΔMripacC to evade the host immune system. The results of insect bioassays showed that ΔMripacC had decreased virulence with extended median lethality time. Together, the results suggested that MripacC not only regulated adaptation to acidic and alkaline environments, but also influenced virulence by budding blastospores. This elucidation of the function of MripacC adds to our understanding of blastospore budding and virulence of this fungal pathogen.     

Laboratory studies of the entomopathogenic fungus Nomuraea rileyi: Soil-borne contamination of soybean seedlings and dispersal of diseased larvae of Trichoplusia ni

Germinating soybean seedlings were contaminated by soil-borne conidia of the entomogenous fungus Nomuraea rileyi. Although N. rileyi was detected on the unifoliate and trifoliate leaflets, most of the inoculum was found on the cotyledons. Diseased larvae of Trichoplusia ni released on the first trifoliate leaves of soybean plants dispersed to all trifoliates and died. In this way, inoculum is produced that infects other larvae feeding on these leaves.     

Susceptibility of the cabbage looper, Trichoplusia ni, and the velvetbean caterpillar, Anticarsia gemmatalis, to several isolates of the entomopathogenic fungus Nomuraea rileyi

Cabbage looper larvae, Trichoplusia ni, were equally susceptible to isolates of the entomogenous fungus Nomuraea rileyi from Missouri, Mississippi, and Brazil; an isolate from Florida was 7–17 times less active than the other isolates. Velvetbean caterpillars, Anticarsia gemmatalis, were either only slightly susceptible or not susceptible to the isolates of N. rileyi from Missouri, Florida, and Mississippi. In contrast, larvae of A. gemmatalis cultured from three locations (Missouri, Florida, and Brazil) all were equally susceptible to a Brazilian isolate of N. rileyi.     

Role of the exoprotease InA in the pathogenicity of Bacillus thuringiensis in pupae of Hyalophora cecropia

Two geographical biotypes of Nomuraea rileyi (from Ecuador and the United States) were topically bioassayed against seven lepidopteran species, i.e., Anticarsia gemmatalis, Heliothis zea, Heliothis virescens, Heliothis subflexa, Pseudoplusia includens, Spodoptera exigua, and Trichoplusia ni. There was an average difference of 1.7-fold in mortality in how cultures of the same insect species from different sources responded to topical applications of either biotype of N. rileyi. Regression equations and LC₅₀ values were obtained for each insect species and fungal biotype combination. Larvae of S. exigua were equally susceptible to both biotypes of N. rileyi. Although larvae of A. gemmatalis were moderately susceptible to the Ecuadoran biotype, they were relatively nonsusceptible to the Mississippian biotype. Species of Heliothis (H. zea, H. virescens, and H. subflexa) were about equally susceptible to the Mississippian biotype. Larvae of H. subflexa and H. virescens, however, were significantly less susceptible than H. zea to the Ecuadoran biotype. When the integumental barrier was breached via intrahemocoelic injections, larvae of H. virescens were as susceptible as H. zea larvae to blastospores of either biotype of N. rileyi.     

Pathogenicity of entomopathogenic hyphomycetes, Paecilomyces fumoso-roseus and Nomuraea rileyi, to eggs of noctuids, Mamestra brassicae and Spodoptera littoralis

Bioassays were conducted to determine the susceptibility of egg masses of Mamestra brassicae and Spodoptera littoralis to different spore doses of Paecilomyces fumoso-roseus and Nomuraea rileyi at 20° and 25°C. P. fumoso-roseus was highly virulent against eggs, whereas N. rileyi provoked only a deferred mortality of larvae hatched from treated eggs. Nevertheless, larval mortality of S. littoralis caused by N. rileyi at 25°C was more effective after first-instar larval contamination than after egg mass treatment. The duration of the egg stage could explain differences of susceptibility between the two noctuids at 25°C. Scanning electron microscopical observations suggested two ways of contamination of newly hatched larvae. First, fungal germinations on the chorion surface suggested that newly hatched larvae might be infected by penetration of the egg integument before hatching. Second, conidia on the egg cuticle could be an entomopathogenic inoculum for newly emerging larvae which fed upon chorions. Results showed that pathogenicity of Hyphomycetes to noctuid eggs might be a promising area of investigation for biological control.     

Activity of oil-formulated conidia of the fungal entomopathogens Nomuraea rileyi and Isaria tenuipes against lepidopterous larvae

The fungi Nomuraea rileyi and Isaria tenuipes (=Paecilomyces tenuipes) are ecologically obligate, widespread pathogens of lepidopterans. Bioassays were carried out to evaluate the activity of oil-suspended conidia of N. rileyi and I. tenuipes against larvae of Spodoptera frugiperda, Spodoptera exigua, Helicoverpa zea, and Heliothis virescens. The tests consisted of two bioassay sets. In the first set, conidia of N. rileyi and I. tenuipes were suspended in water + Tween 80, and in vegetable (canola, soybean) and mineral (proprietary mixture of alkanes and cyclic paraffins) oils, and tested against S. frugiperda. Both fungi were highly compatible with oils and caused mortalities near 100% in all oil treatments; the lowest LT₅₀ values were 4.7 days for N. rileyi in mineral oil and 6.0 days for I. tenuipes in soybean oil. The second set included additional fungal strains and oil formulations (mineral, canola, sunflower, olive and peanut oils) tested against larvae of S. exigua, S. frugiperda, H. zea and H. virescens. The highest activity was that of N. rileyi in mineral oil against Spodoptera spp., with LT₅₀ values of 2.5 days (strain ARSEF 135) and 3 days (strain ARSEF 762) respectively. For two different isolates of I. tenuipes the lowest LT₅₀ values (5.1-5.6 days respectively) were obtained with mineral oil formulations against Spodoptera spp. and H. zea respectively. Additionally, we tested both fungi against prepupae of all four lepidopteran species. Mortalities with I. tenuipes against S. exigua ranged from 90% to 100% (strains ARSEF 2488 and 4096); N. rileyi caused 95% mortality on S. frugiperda. The activity of formulations depended on host species and oil used; Spodoptera spp. was more susceptible to these fungi than Heliothis and Helicoverpa. The results indicate that a comprehensive evaluation of these entomopathogens in agriculture using oil application technologies is advisable, particularly, in organic and sustainable settings.     

Ultrastructural studies on the fungus,Nomuraea rileyi,infecting the velvetbean caterpillar,Anticarsia gemmatalis

Combined scanning and transmission electron microscopy was used to study the fine structure of the developmental stages of Nomuraea rileyi infecting host larvae of Anticarsia gemmatalis. Larvae were dusted with large numbers of fungal conidia, which germinated and penetrated the cuticle within 6 hr post-treatment. Within 24 hr, penetration hyphae had reached the cuticular epidermis and, via a budding process, initiated the hyphal body stage in the hemocoel. The hyphal bodies, suspended in hemolymph, multiplied and spread throughout the host larvae. By 6–7 days post-treatment, the majority of larvae were mummified. Within 12 hr postmortem numerous conidiophores emerged producing a confluent mycelial mat over the entire cuticular surface. Numerous hydrophobic conidia were formed on phialides present on the aerial conidiophores.     

Mycophenolic Acid Production by Penicillium brevicompactum on Solid Media

When grown on Czapek-Dox agar, Penicillium brevicompactum produced mycophenolic acid after a vegetative mycelium had been formed and as aerial hyphae were developing. Nutrients were still plenteous in the agar when the synthesis began. If aerial hyphal development was prevented by placing a dialysis membrane over the growing fungus, no mycophenolic acid was produced. When the dialysis membrane was peeled back and, as a consequence, production of aerial hyphae began, mycophenolic acid biosynthesis was observed. We concluded that mycophenolic acid was produced only by P. brevicompactum colonies that possessed an aerial mycelium.     

Histopathology of Nomuraea rileyi in Plathypena scabra larvae

Green cloverworm larvae. Plathypena scabra, were inoculated with Nomuraea rileyi by “tumbling” larvae in a vial of conidia. The ontogeny of the pathogen was followed by using standard histological techniques. N. rileyi conidia germinated on green cloverworm integument within 12 hr after inoculation. Germ tubes penetrated larval cuticle 36 hr after inoculation, then grew parallel to endocuticular laminae. After hyphal penetration of the epidermis ca. 4.5 days after inoculation, hyphal bodies were produced and were transported throughout the hemocoel. Hyphal bodies and hemocytes cohabited the hemocoel, but gut epithelial and muscle tissues were not invaded by Day 5. Hemocytes lysed and mycelia completely ramified throughout all larval tissues by 7 days after inoculation. Death of larvae was followed by conidiogenesis ca. 7.5 days after inoculation.     

The entomopathogenic fungus Nomuraea rileyi impairs cellular immunity of its host Helicoverpa armigera

In this study, we investigated the effect of the entomopathogenic fungus Nomuraea rileyi on Helicoverpa armigera cellular immune responses. Nomuraea rileyi infection had no effect on total hemocyte count (THC), but impaired hemocyte‐mediated phagocytosis, nodulation, and encapsulation responses. Nomuraea rileyi infection led to a significant reduction in hemocyte spreading. An in vitro assay revealed that plasma from N. rileyi infected H. armigera larvae suppressed the spreading ability of hemocytes from naïve larvae. We infer that N. rileyi suppresses the cellular immune response of its host, possibly by secreting exogenous, cytotoxic compounds into the host's hemolymph.     

Protein Profile of <Emphasis Type="Italic">Nomuraea rileyi</Emphasis> Spore Isolated from Infected Silkworm

Nomuraea rileyi (N. rileyi) is the causative agent of the silkworm, Bombyx mori, green muscardine which can cause severe worldwide economical loss in sericulture. Little is known about N. rileyi at the protein level for this entomopathogenic parasite which belongs to the Ascomycota. Here, we employed proteomic-based approach to identify proteins of N. rileyi spores collected from the dead silkworm. In all, 252 proteins were separated by two-dimensional gel electrophoresis (2-DE), and were subjected to mass spectrometry (MS) analysis, 121 proteins have good MS signal, and 24 of them were identified due to unavailability of genomic information from N. rileyi. This data will be helpful in understanding the biochemistry of N. rileyi.     

First Report of a New Isolate of <Emphasis Type="Italic">Metarhizium rileyi</Emphasis> from Maize Fields of Quivicán,Cuba

Metarhizium rileyi (Farlow) Samson is an important entomopathogenic fungus of more than 30 species of Lepidoptera larvae. The aim of this research was to characterize isolate of M. rileyi from Quivicán, Cuba on the basis of morphological and molecular approaches. The fungus was isolated from samples of S. frugiperda larvae collected from maize fields of Quivicán municipality, Mayabeque province, Cuba, and it was cultured on PDA?+?Ampicillin solid media for morphological characterization. The DNA was isolated using CTAB method and internal transcribed spacer (ITS1, ITS4) were used as the primers for the amplification. The amplified products of 1335 bp were purified and sequenced at CINVESTAV-IPN in both the directions using the above primers. A consensus sequence was obtained by alignment of the forward and reverse sequences for this region and deposited in GenBank (MG637450). The fungus produced slightly cottony colony of pale green color and dispersed conidia and septal mycelium were observed under the optical microscope. A BLAST search of the sequence in GenBank revealed a 99% of identity with several strains of N. rileyi (e.g., AF368501.1, AB268359.1 and EU553337.1) and M. rileyi (e.g., KY436756.1). This is the first report of M. rileyi isolate from maize fields of Quivicán in Cuba and this is important for biodiversity studies and is another possibility for Integrated Pest Management.     

Susceptibility of larvae of Trichoplusia ni and Anticarsia gemmatalis to intrahemocoelic injections of conidia and blastospores of Nomuraea rileyi

The LD₅₀ for larvae of Trichoplusia ni injected with blastospores of Nomuraea rileyi was 4.30 ± 1.16 hyphal bodies/larva; the LD₅₀ for injected conidia was ca. 25,000 conidia/larva. The dose-mortality regression line for blastospores was Y = 4.6504 + 0.5487 X. Larval mortalities of Anticarsia gemmatalis and T. ni at 100 blastospores/larva were 0.4 ± 0.5% and 96.7 ± 1.9%, respectively. At a dosage of 25,000 conidia/larva, larval mortalities for A. gemmatalis and T. ni were 0.4 ± 0.5% and 43.1 ± 8.7%, respectively. Thus, larvae of A. gemmatalis were > 100 times and >200 times more resistant to injected conidia and blastospores, respectively, than were larvae of T. ni. Resistance of A. gemmatalis to N. rileyi may not be solely at the integumental barrier, as is often believed, but may also be a function of an internal physiological response.     

Metarhizium (Nomuraea) rileyi as biological control agent

Metarhizium rileyi is an entomopathogenic fungus of Lepidoptera and infects many noctuids, which are key pests of agricultural crops. In this literature review, we summarise the state of art and use of this potential biological pest control agent. Pathogen–host interactions include conidial adhesion, invasion process, and enzymatic activity. Environmental factors that impact the productivity associated with this fungus such as environment temperature, humidity, and availability of spores are discussed. Recent research has focused on enzymatic aspects related to pathogenicity, in which the cause is not fully elucidated yet. More than 60 known host species, mainly lepidopterans, are listed. Non-susceptible species, including predatory insects, are also presented. The difficulty of mass production and the formulation are the principal obstacles in use of M. rileyi. We summarise the challenges necessary to better utilise this agent in biocontrol and suggest novel research approaches, including the development of commercial and technically viable formulations.     

Efficacy of an oil-based formulation combining Metarhizium rileyi and nucleopolyhedroviruses against lepidopteran pests of soybean

A biopesticide that combines Metarhizium rileyi and nucleopolyhedrovirus (NPV) in an oil dispersion (OD) was developed. Its efficacy against Anticarsia gemmatalis and Chrysodeixis includens was evaluated under laboratory and field conditions. First, each of the two selected fungal strains, combined or not in OD preparations with AgMNPV or ChinNPV, was tested in the laboratory against A. gemmatalis and C. includens, respectively. AgMNPV–fungus combinations had similar effect on overall mortality of A. gemmatalis compared to each pathogen used alone. C. includens was less susceptible to infection by M. rileyi strains, and ChinNPV became the major cause of larval death. The OD formulations with M. rileyi and/or NPV were applied in infested soybean fields. ChinNPV + M. rileyi caused 50.8% of overall mortality six days after spraying in a soybean crop infested by both pests, whereas for treatments with the fungus or the virus alone the percentages were 41.2% and 8.8%, respectively. In another field infested solely by A. gemmatalis, insect mortality was similar for the AgMNPV–fungus combination and the virus used alone. Larval parasitism by wasps and dipterans was not affected following biopesticide spraying. Our results suggest that the performance of a dual-action biopesticide is related to the NPV and fungal strains that are combined and the proportion of host populations simultaneously infesting the crop.     

Lipid composition of the entomopathogenic fungus Nomuraea rileyi

The total lipid content, neutral and polar lipid composition, and fatty acid profiles were determined for the different developmental stages of the entomopathogenic fungus, Nomuraea rileyi. In general, the lipid composition of N. rileyi was found to be very similar to that of other Fungi Imperfecti. Triacylglycerides and sterols were the major neutral lipids and phosphatidylethanolamine, phosphatidylinositol, and phosphatidylserine were the major polar lipids. Phosphatidylcholine, resolved in conidial and mycelial samples, was not detected in hyphal body samples. The major fatty acids were palmitic, oleic, and linoleic. Stearic acid was detected as a minor component of hyphal body samples. During conidiogenesis the overall lipid composition was altered in (1) a reduction in total lipid content, (2) an increase in the polar/neutral lipid ratio, and (3) an increase in the degree of fatty acid unsaturation.