Effects of mineral salts on the growth,sporulation and virulence of Esteya vermicola,an endoparasitic fungus of the pinewood nematode,Bursaphelenchus xylophilus

Esteya vermicola, an endoparasitic fungus of pinewood nematode, exhibits great potential as a biological agent against nematodes. In this study, various mineral supplements, such as chloride salts (KCl, CaCl₂, MgCl₂, FeCl₂, and FeCl₃) and calcium salts (CaCl₂, CaCO₃, and CaSO₄) were evaluated for their ability to enhance the growth, sporulation and virulence of E. vermicola. Of the cations tested, CaCl₂ provided the greatest enhancement of growth speed and sporulation. Of the anions tested, CaCO₃ produced the highest proportion of lunate conidia, and CaCl₂ produced the highest adhesive rate and mortality against the nematode, Bursaphelenchus xylophilus. The optimum concentration of CaCl₂ for optimization of sporulation and virulence was 0.4–0.6%. In conclusion, CaCl₂ is highly effective in enhancing growth, sporulation and virulence of Esteya vermicola.     

Host Deception: Predaceous Fungus,Esteya vermicola,Entices Pine Wood Nematode by Mimicking the Scent of Pine Tree for Nutrient

Background

A nematophagous fungus, Esteya vermicola, is recorded as the first endoparasitic fungus of pine wood nematode (PWN), Bursaphelenchus xylophilus, in last century. E. vermicola exhibited high infectivity toward PWN in the laboratory conditions and conidia spraying of this fungus on Japanese red pine, Pinus densiflora, seedlings in the field protected the pine trees from pine wilt disease to some extent, indicating that it is a potential bio-control agent against PWN. Previous research had demonstrated that the living fungal mycelia of E. vermicola continuously produced certain volatile organic compounds (VOCs), which were responsible for the PWN attraction. However, identity of these VOCs remains unknown.

Methodology/Principal Findings

In this study, we report the identification of α-pinene, β-pinene, and camphor produced by living mycelia of E. vermicola, the same volatile compounds emitted from PWN host pine tree, as the major VOCs for PWN attraction using gas chromatography-mass spectrometry (GC-MS). In addition, we also confirmed the host deception behavior of E. vermicola to PWN by using synthetic VOCs in a straightforward laboratory bioassay.

Conclusions/Significance

This research result has demonstrated that the endoparasitic nematophagous fungus, E. vermicola, mimics the scent of PWN host pine tree to entice PWN for the nutrient. The identification of the attractive VOCs emitted from the fungus E. vermicola is of significance in better understanding parasitic mechanism of the fungus and the co-evolution in the two organisms and will aid management of the pine wilt disease.     

Effect of Nutrition and Environmental Factors on the Endoparasitic Fungus Esteya vermicola, a Biocontrol Agent Against Pine Wilt Disease

The nematophagous fungus Esteya vermicola has tremendous potential for biological control. This species exhibits strong infectious activity against pinewood nematodes, whereas the study on the effect of nutrition and environmental factors is still of paucity. Carbon (C), nitrogen (N), pH value, temperature, and water activity have great impact on the fungal growth, sporulation, and germination. In nutrition study, the greatest number of conidia (2.36 × 10⁹ per colony) was obtained at the C:N ratio of 100:1 with a carbon concentration 32 g l^?1. In addition, the germination rate and radial growth of E. vermicola were used to evaluate the effects of environmental conditions and they were optimized as following: pH 5.5, 26 °C and water activity of 0.98. Our results also confirmed that variation of environmental factors has a detrimental influence on the efficacy of active conidia and growth of fungus. Moreover, under above optimal condition, the biocontrol efficacy was significantly improved in regard to the increase of adhesive and mortality rate, which highlight the study on the application of E. vermicola as pine wilt disease biocontrol agent.     

Viability and pathogenicity of Esteya vermicola in pine trees

Esteya vermicola, as the first reported endoparasitic fungus of pinewood nematode (PWN), exhibited high infectivity in vitro and has been patented based on its potential as a bio-control agent against PWN. The isolation substrates and taxonomic status suggested E. vermicola is associated with beetles, saprotrophic and kills nematodes in trees. However, the direct experimental evidence for this was still lacking. In the present studies, beta-tubulin gene was applied to confirm the taxonomic identification of E. vermicola. Furthermore, our results showed that E. vermicola survived resin and other chemicals secreted by pine trees, and reproduced with new lunate conidia to parasitize other migratory PWNs. In order to confirm the pathogenicity of E. vermicola, pine seedlings and large pine trees were inoculated with 300 µL and 40 mL conidia suspensions (10⁹ mL^?1). The results showed that all treated pine trees were healthy with no differences compared to the controls. Furthermore, necrosis or discoloration caused by this fungus was not observed on wood slices. Basal knowledge was provided for the application of E. vermicola to control PWN in vivo.     

High infectivity of an endoparasitic fungus strain, <Emphasis Type="Italic">Esteya vermicola</Emphasis>, against nematodes

Esteya vermicola, as the first recorded endoparasitic fungus of pinewood nematodes, exhibits great potential as a biological agent against nematodes. However, only two strains of this species have been described so far. In this study, we identified a novel endoparasitic fungal strain, CNU 120806, isolated from infected nematodes in forest soil samples during a survey of nematophagous fungi in Korea. This strain showed similar morphological characteristics and infection mode with the two previously described strains of E. vermicola. All strains are characterized by the ability to produce two types of conidiogenous cells and conidia, and to parasitize nematodes with lunate adhesive conidia. Moreover, the CNU 120806 strain showed 100% identity with E. vermicola CBS 115803 when their partial sequences of 28S rRNA gene were compared. Molecular phylogenetic analysis further identified CNU 120806 as a strain of E. vermicola, by clustering CNU 120806 and E. vermicola CBS 115803 into a single subclade. Culture medium influenced the proportion of dimorphic CNU 120806 conidia, and further changed the adhesive and mortality rates of nematodes. The CNU 120806 strain exhibits high infection activity against nematodes on nutrient-rich PDA medium. Almost all tested nematodes were killed within 8 approximately 10 days after inoculation. This study provides justification for further research of E. vermicola, and the application and formulation of this fungus as a bio-control agent against nematodes.     

Biological control of the pinewood nematode <Emphasis Type="Italic">Bursaphelenchus xylophilus</Emphasis> by application of the endoparasitic fungus <Emphasis Type="Italic">Esteya vermicola</Emphasis>

Esteya vermicola (Ophiostomataceae) is the first reported endoparasitic fungus of the pinewood nematode (PWN), Bursaphelenchus xylophilus (Nematoda: Aphelenchoidoidea). It has high in vitro infectivity. In this study, the nematocidal effect of E. vermicola in logs was investigated and evaluated. Two months after inoculation of pine wilt-killed Pinus densiflora logs with E. vermicola conidia suspensions of 3 × 10⁸ and 3 × 10⁶ ml⁻¹, the density of nematodes decreased by approximately 79% and 47%, respectively. When the fungus was sprayed on to four-year-old pine seedlings one month before PWN inoculation, the survival index of seedlings reached 0.67 compared with only 0.067 for control seedlings without fungal spraying. These results suggest that conidia spraying of E. vermicola can, to some extent, protect pine trees from wilt disease. Moreover, infected nematodes and hyphae of E. vermicola were observed in the treated wood sections.     

Orbilia blumenaviensis and its Arthrobotrys anamorph

A member of the nematophagous anamorph genus Arthrobotrys was isolated from its teleomorph Orbilia blumenaviensis comb. nov. (= Orbilia fici), a species closely related to O. auricolor but deviating in having lanceolate paraphyses. In the presence of nematodes, the anamorph forms three-dimensional adhesive networks. A trimorphism in its conidia was observed which vary in shape and number of septa. In the first isolate, two types of heteropolar conidia were obtained. These differ markedly from the type strain of A. vermicola, which forms mainly homopolar (fusoid) conidia. In a further ascospore isolate of O. blumenaviensis, however, mainly fusoid conidia referable to A. vermicola occurred. Combining morphological and phylogenetic analysis, we conclude that these isolates with differently shaped conidia and/or differences in the ITS rDNA (ca. 2–4%) belong to a single anamorph species, A. vermicola. Both teleomorph and anamorph are illustrated and described.     

Protective formula and preservation conditions for the endoparasitic fungus, <Emphasis Type="Italic">Esteya vermicola</Emphasis>

The endoparasitic nematophagous fungus, Esteya vermicola, is a bio-control agent with demonstrated ability to attack pinewood nematode (Bursaphelenchus xylophilus). An optimized solution for the protection and preservation of E. vermicola conidia is needed in order to ensure their survival during transportation, preservation, and application. Five protectants, kaolin, arabinose, sorbitol, PEG8000, and Span 80, were selected from 34 agents. These were incorporated into calcium alginate gel capsules at the following concentrations: 10% kaolin, 0.1% Span 80, 1% arabinose, 5% sorbitol, and 5% PEG8000. The improved diffluent formula contained 69.9% soluble starch, 14% wheat flour, 5% PEG8000, 0.1% span 80, 1% arabinose and 10% skim milk. The viability of E. vermicola conidia preserved in the protectant (5% sorbitol and 20% PEG8000) at six temperatures,–70,–20, 4, 26, 37°C, and room temperature (uncontrolled), was also assessed. The highest viability after storage for one month was achieved at–70°C.     

Laboratory studies on the development of a conidial formulation of Esteya vermicola

The endoparasitic nematophagous fungus, Esteya vermicola, has potential as a biocontrol agent against pinewood nematode, Bursaphelenchus xylophilus. An E. vermicola conidial formulation was developed to improve conidial resistance to ultraviolet (UV), drought and heat stress. The effective concentration of each protective additive [UV protectant [fulvic acid (FA) and skim milk (SM)]; drought protectant (sorbitol) and heat protectant (calcium chloride)] was determined based on the germination rate of E. vermicola conidia after exposure to the different stressors. A combination of 0.2% FA and 4% SM, 5% sorbitol and 0.05% calcium chloride provided the most effective protection. In addition, the concentrations of spreader–sticker and antibiotic were also decided. The final formulation could be used to improve the resistance of E. vermicola conidia to multiple stressors and to increase nematode mortality compared with unformulated conidia.     

Optimization of storage condition for maintaining long-term viability of nematophagous fungus Esteya vermicola as biocontrol agent against pinewood nematode

The fungus, Esteya vermicola has been proposed as biocontrol agent against pine wilting disease caused by Bursaphelenchus xylophilus. In this study, we reported the effects of temperature and different additives on the viability and biocontrol efficacy of E. vermicola formulated by alginate-clay. The viability of the E. vermicola formulation was determined for six consecutive months at temperature ranged from ?70 to 25 °C. The fresh conidia without any treatment were used as control. Under the optimal storage conditions with E. vermicola alginate-clay formulation, the results suggested that E. vermicola alginate-clay formulation with a long shelf life could be a non-vacuum-packed formulation that contains 2 % sodium alginate and 5 % clay at 4 °C. Three conidial formulations prepared with additives of 15 % glycerol, 0.5 % yeast extract and 0.5 % herbal extraction, respectively significantly improved the shelf life. In addition, these tested formulations retained the same biocontrol efficacy as the fresh conidial against pinewood nematode. This study provided a tractable and low-cost method to preserve the shelf life of E. vermicola.     

<Emphasis Type="Italic">Lecophagus vermicola</Emphasis> sp. nov., a nematophagous hyphomycete with an unusual hunting strategy

Lecophagus vermicola sp. nov. is described and illustrated as a predacious (carnivorous) hyphomycete living in bark fissures of living trees of Platanus and other angiosperm and gymnosperm trees, recorded in Hungary, Luxembourg and France. The fungus captures nematodes unlike other Lecophagus species, which are predators of rotifers and tardigrades. The morphology of the sessile, adhesive knobs differ from all previously described species of the genus which form adhesive pegs. Molecular data confirms that the new species belongs to the Lecophagus clade but without matching existing sequences. The fungus captures victims with adhesive knobs and colonizes its prey with a mycelium of rather broad hyphae on which, again, adhesive knobs are formed which penetrate the cuticule of the victim. Clusters of colonized nematodes form a network utilized to capture more prey. The fungus lives in the xeric, ephemerally aquatic habitat of bark fissures of standing, living or dead, corticated trunks and branches. The genus Haptocara is compared, which has similar adhesive knobs capturing nematodes and similar broad hyphae, but for which no molecular data was available.     

A NEMATODE-DESTROYING HYPHOMYCETE FORMING PARALLEL MULTISEPTATE HYALINE CONIDIA IN CIRCULAR ARRANGEMENT

In several Petri plate cultures that had been inoculated with decaying plant detritus from central Maryland, a fungus developed which attacks nematodes by extending a rather wide infection-tube either from an adhesive hyphal protuberance, or, more often, from a subglobose adhesive cell produced terminally on its elongate-ellipsoid pluriseptate hyaline conidia. A number (sometimes three) of these conidia are borne simultaneously in peripheral positions on the broadly rounded tip of the colorless condiophore, and are directed upward, parallel to the conidiophore axis. From the segment immediately below its adhesive cell, each conidium puts forth laterally a flexible unicellular tubular appendage that grows downward approximately to the level of the spore attachment. The fungus is described as Haptocara latirostrum gen. n., sp. n. Although presumably belonging in the Moniliaceae, it shows no close kinship with the numerous interrelated clampless Hyphomycetes that have been made known as subsisting through capture of nematodes.     

Comparison between conidia and blastospores of Esteya vermicola, an endoparasitic fungus of the pinewood nematode, Bursaphelenchus xylophilus

Esteya vermicola, an endoparasitic fungus of Bursaphelenchus xylophilus, the pinewood nematode (PWN), exhibits great potential as a biological control agent against this nematode. E. vermicola produces blastospores in liquid media and aerial conidia on solid media. The agent was mass-produced using two kinds of culture media: S (50 % wheat bran and 50 % pine wood powder), L (0.5 g wheat bran and 0.5 g pinewood powder in 200 ml of potato dextrose broth), and two controls: SC (potato dextrose agar), LC (potato dextrose broth). Yields, multiple stress tolerance, storage life, new generation conidial number, and PWN mortality rates of the spores were measured in each of these four media and compared. The spore yields, new generation conidial number, and nematode mortality rates of blastospores were higher than those of conidia. Nevertheless, the conidia had a higher germination rate than the blastospores during the storage process and multiple stress treatments. Considering the number of spores surviving from the process of the storage and multiple stress treatments per unit of mass media, the blastospores from L survived most. Comprehensive analysis indicates that the L culture medium is the most optimal medium for mass production relatively.     

A Staining Method for Assessing the Viability of Esteya vermicola Conidia

The viability of conidia of Esteya vermicola, a potentially important biocontrol agent against the pinewood nematode Bursaphelenchus xylophilus, is usually determined by cultivation for 18–48 h in culture medium. As an alternative to this labor-intensive method, we have developed a rapid, simple, and low-cost staining method for assessing E vermicola conidia survival rates. A mixture of neutral red and methylene blue was found to be the most optimal among several stains that also included safranin O and Janus green B. This mixture stained nonviable conidia blue, in contrast to viable conidia, which were stained red in the cytoplasm and blue in the cell wall. This method may be particularly useful for traditional research laboratories, as it provides rapid results using common, relatively inexpensive laboratory equipment.     

Population dynamics of pinewood nematode and the endoparasitic fungus Esteya vermicola: interactions under experimental conditions

Esteya vermicola (Ophiostomataceae), an endoparasitic fungus, exhibits great potential as a biological control agent against pinewood nematodes (PWNs). The present study reports the interaction between PWNs and E. vermicola at different spore concentrations, number of PWNs and the time of culture. The addition of PWNs enhanced the sporulation of E. vermicola after 10 days of culture. The 5-day-old cultures of E. vermicola prior to addition of PWNs increased the highest amount of sporulation than that of 10- or 15-day-old cultures. The PWNs were completely killed by E. vermicola in the pine tree powder culture medium at the concentrations of 10⁷ and 10⁸ colony-forming-units (CFU) per ml. The interaction of the PWNs and E. vermicola was that PWNs provide nutrition to E. vermicola, however, the PWNs can also feed on mycelium of E. vermicola. The effect of E. vermicola on control of PWNs was determined by the population size, time of pest infection and the duration of co-infection.     

Thioredoxin1 regulates conidia formation,hyphal growth,and trap formation in the nematode-trapping fungus Arthrobotrys oligospora

Arthrobotrys oligospora, a model nematophagous fungus that produces specific adhesive networks to capture nematodes, has been proposed as a potentially effective biological agent to control harmful plant-parasitic nematodes. Although thioredoxin has been characterized as playing important roles in many cellular processes in other species, its function in nematophagous fungi has not been studied. Here, the function of a thioredoxin homolog, Aotrx1, was investigated in A. oligospora. The encoding gene of Aotrx1 in the nematophagous fungus A. oligospora was knocked out by homologous recombination; strain growth was assessed. The ΔAotrx1 strain of A. oligospora showed a significant decrease in growth rate on different media (PDA, CMY, and TG), a 70% decrease of conidia production, and a lower germination rate compared with the wild type. The mutant strain was unable to form traps to capture nematodes and was more sensitive to SDS and H2O2. Thioredoxin is involved in conidia development, trap formation, normal mycelial growth, and resistance to environmental stresses in the nematode-trapping fungus A. oligospora.     

Sensitivity of the Entomogenous Fungus Beauveria bassiana to Selected Plant Growth Regulators and Spray Additives

Mefluidide was the only one of four plant growth regulators that caused little to no significant inhibition of in vitro germination and growth of the entomogenous fungus Beauveria bassiana. Silaid, paclobutrazol, and flurprimidol significantly inhibited germination and growth. Mortality of fall armyworm, Spodoptera frugiperda, resulting from B. bassiana was significantly reduced when larvae were exposed to conidia plus soil treated with paclobutrazol. Larval mortality resulting from conidia plus soil treated with mefluidide did not differ significantly from mortality resulting from untreated conidia. Triton CS-7 was the only one of eight spray adjuvants that significantly inhibited germination of B. bassiana conidia.     

Development,Distribution, and Host Studies of the Fungus Macrobiotophthoira vermicola (Entomophthorales)

The life cycle and host range of Macrobiotophthora vermicola were studied. Secondary spores produced from forcibly ejected primary spores adhered to the cuticle of Cruznema tripartitum, germinated, and penetrated the cuticle within 30 minutes. New primary spores were produced within 24 hours of initial spore adhesion. In a host range study, species of Rhabditidae, Diplogasteridae, and Aphelenchoidea were hosts, but not species of Bunonematidae, Tripylidae, Cephalobida, or Tylenchina. Numbers of second-stage Meloidogyne incognita juveniles were not decreased when added to soil seeded with infected C. tripartitum. In six Tennessee soybean fields, Macrobiotophthora vermicola was the most commonly encountered nematode-destroying fungus, followed by a sterile, nonseptate fungus and Arthrobotrys conoides. Nematophagous fungi were isolated more frequently from silt loam soils than from clay soils. Addition of C. tripartitum to soil extract plates as a bait nematode did not increase isolations of nematophagous fungi.     

Attraction of Pinewood Nematode to Endoparasitic Nematophagous Fungus Esteya vermicola

The investigations on attraction of nematodes to nematophagous fungi have mostly dealt with the nematode-trapping species. Esteya vermicola is the endoparasitic fungus of pinewood nematode (PWN) with high infection activity. In the present study, the attraction of PWNs to E. vermicola was investigated. It was confirmed that the living mycelia and exudative substances of E. vermicola were attractive to PWN. Compared with the nematode-trapping fungus A. brochopaga as well as nematode-feeding fungus B. cinerea, E. vermicola showed the significantly strongest attraction ability to nematode. It therefore appeared that the attraction ability reflects the dependence of the fungi on nematodes for nutrients. Furthermore, a new method was developed and used in the study to confirm the effect of volatile substances for the attraction of nematode to fungi. The results suggested that the attractive substances were consisted of avolatile exudative and volatile diffusing compounds.