The Role of Microbes Associated with Chicken Litter in the Suppression of Meloidogyne arenaria

The role of microbes associated with chicken litter in the suppression of Meloidogyne arenaria in amended soil was investigated. Amended soil treatments were prepared, including combinations of sterile and nonsterile chicken litter and soil. Microbial biomass in different treatments was compared by measuring carbon dioxide evolution. There was less CO₂ evolved in sterile litter than in nonsterile litter treatments. Tomato seedlings cv. Rutgers were transplanted into soil mixtures and inoculated with 2,000 M. arenaria eggs. After 10 days, fewer second-stage juveniles (J2) had penetrated the roots in soils amended with nonsterile litter than sterile litter. The effects of sterile and nonsterile litter-amended soil solutions on M. arenaria eggs and J2 were observed over a period of 6 days. A lower percentage of eggs remained apparently healthy in nonsterile than in sterile-amended soil solutions over 6 days. Microbial degradation of the egg shells was apparent. Fewer J2 survived in sterile- and nonsterile-amended-soil solutions as compared to water controls.     

Survival of Botrytis cinerea in Soil in South-Eastern Spain

The survival of Botrytis cinerea in sterile and unsterile soil at different temperatures and relative air humidities was investigated in south‐eastern Spain. Conidia survived only 7 days at 40^°C but, depending on relative humidity, for 30–90 days at 22^°C. High air humidity (95%) was needed to maintain soil humidity (8%) at a level that favoured conidial survival. Conidia survived better in sterile soil than in unsterile soil, probably because of the presence in the latter of soil microorganisms antagonistic to B. cinerea. Survival of conidia in environmental conditions simulating those in a greenhouse was less than 28 days. Results showed that B. cinerea conidia cannot survive over summer in south‐eastern Spain, and other primary sources of inocula are discussed.     

Sporulation in saprotrophic and clinical strains of <Emphasis Type="Italic">Aspergillus sydowii</Emphasis> (Bain. &; Sart.) Thom &; Church under various environmental conditions

Molecular genetic characteristics and capacity for sporulation under different levels of temperature and humidity were compared for three saprotrophic and four clinical strains of A. sydowii. Analysis of the ITS and D1/D2 loci of these A. sydowii strains revealed two clades, each including both the clinical and saprotrophic strains. The differences in sporulation in the saprotrophic and clinical strains of the potentially pathogenic microscopic fungus A. sydowii under different environmental conditions were demonstrated. In the clinical A. sydowii strains, the level of spore formation was generally higher, especially at humidity levels of 0.90 and 0.95 a_w and 20–25°C. The level of spore formation for the clinical strains inoculated into sterile soil was several times higher than for the saprotrophic ones. On the contrary, nonsterile soils (sod-podzolic and urban soils) exhibited a fungistatic effect against A. sydowii populations.     

The potential of Beauveria bassiana inoculum formulated into a polymeric matrix for a microbial control of spruce bark beetle

Two local strains of Beauveria bassiana originally isolated from naturally infected spruce bark beetles in Slovakia were tested for their virulence to Ips typographus (IT) and for their compatibility with a polymeric matrix composed of low-molecular polyethylene. Conidia could be homogenously immobilized in the low-molecular polyethylene matrix with no adverse effect on their viability and infectivity. At constant temperature (25°C), viability of immobilized conidial decreased only by 1–2% after 7 or 14 days when compared with non-formulated conidia. In field conditions, viability of conidia formulated in the matrix was even significantly higher than non-formulated conidia 35 days after their application in traps. Conidia incorporated into the polymeric matrix were infective to IT adults in laboratory bioassays. Mean values of LC₅₀ for native conidia (0.72–2.05?×?10⁶ conidia?ml^?1) and conidia immobilized in the polymeric matrix (0.64–1.03?×?10⁵ conidia?mm^?2) demonstrated high virulence. The efficacy of the local strains was significantly higher than that of B. bassiana strains from mycoinsecticides (Boverol^®, Botanigard^® ES and Naturalis-L^®). Results showed potential of this polymeric material for its use in microbial control of IT when mixed with conidia of B. bassiana.     

Distribution of the Entomopathogenic Fungus Beauveria bassiana in Rice Ecosystems and Its Effect on Soil Enzymes

Fungal entomopathogens, especially Beauveria bassiana, are often studied within the context of their use in biological pest control; however, there is limited knowledge of their distributions in host plants and soil ecosystem. We examined the distribution of B. bassiana and its influence on rice plants and paddy soils. B. bassiana could only be detected on the foliar surfaces of rice plants within 15 days under Bb-4 (7.5 × 10⁴ conidia/mL) and Bb-7 (7.5 × 10⁷ conidia/mL) treatments. The endophytic colonization of B. bassiana could not be found in stems, roots, or seeds of rice plants under Bb-4 and Bb-7 treatments. The fungus was found only in the leaves of rice plants under Bb-4 and Bb-7 treatments at 15 days after inoculation. Moreover, B. bassiana was absent from paddy soils under Bb-4 and Bb-7 treatments at all times. Enzyme activity (urease and phosphatase) in the paddy soils of Bb-4 and Bb-7 treatments showed no significant difference from the control. It is possible that B. bassiana was not able to colonize paddy soil. Detailed understanding of distribution and ecological interactions of B. bassiana is helpful for understanding and predicting the effects of fungal entomopathogens on host populations, and the interactions among fungal entomopathogens and other organisms in the community.     

Influence of whey permeate and millet as substrates on thermotolerance of Beauveria bassiana and Metarhizium anisopliae conidia during storage

Conidia from Beauveria bassiana and Metarhizium anisopliae, produced in quarter-strength Sabouraud dextrose agar amended with yeast extract, whey permeate, and millet agar, were exposed to 45°C for 90 min prior to and at 30 d post-storage at 25°C. B. bassiana produced in whey permeate or millet had better thermotolerance than the other treatments after the storage.     

Comparative laboratory studies on three fungal pathogens of the elm bark beetle Scolytus scolytus: Effect of temperature and humidity on infection by Beauveria bassiana,Metarhizium anisopliae, and Paecilomyces farinosus

Larvae of the elm bark beetle, Scolytus scolytus, were inoculated with conidia of the entomogenous fungi Beauveria bassiana (two strains), Metarhizium anisopliae (two strains), and Paecilomyces farinosus (two strains) and incubated over a range of temperatures (2°, 6°, 10°, 15°, and 20°C). One strain each of B. bassiana and P. farinosus caused infection even at 2°C, whereas the two strains of M. anisopliae caused no infection below 10°C. Infection of adult beetles by B. bassiana (one strain) and M. anisopliae (one strain) was tested at 15°, 20°, and 25°C (B. bassiana) and at 15° and 20°C (M. anisopliae). Fungal infection occurred at all three temperatures, but at 25°C beetles tended to succumb to bacterial infection. The effect of relative humidity on infection of larvae by B. bassiana (one strain), M. anisopliae (one strain), and P. farinosus (one strain) was tested at 51, 74, 86, 90, 95, 97.5, and 100% relative humidity. B. bassiana and M. anisopliae caused some infection at all humidities: with P. farinosus there was no infection at the two lowest humidities. Mortality due to infection by these fungi was most rapid at the highest humidities.     

Beauveria Bassiana Pathogenicity to the Citrus Rust Mite Phyllocoptruta Oleivora

The pathogenicity of Beauveria bassiana to one of the major pests of citrus crops, Phyllocoptruta oleivora, was assessed by inoculating mites with different concentrations of conidia (1×10⁶, 5×10⁶, 1×10⁷, 5×10⁷ and 1×10⁸). Treated mites were kept at controlled conditions (25 ± 0.5°C, 12 h photoperiod and 98% relative humidity) and mite survivorship was evaluated daily. Mortality was found to increase in time and was dependent on the conidia concentration, with values ranging from 24 to 91% for the lowest and highest conidia concentration, respectively. The calculated LC₅₀ on the fifth day was 4.23×10⁶ conidia/ml. Mean lethal time was 3.98, 9.79, 3.09 and 2.74 days for 5×10⁶, 1×10⁷, 5×10⁷ and 1×10⁸ conidia/ml, respectively. Conidia were found to adhere all over the mite body surface, especially at the anal region, where vegetative mycelium was found entering the mite body. We noticed the formation of small crystals inside the mite’s body that were produced during colonization of the body cavity by the fungus. This is the first report of B. bassiana pathogenicity for this species.     

Pathogenicity ofBeauveria bassiana for adults ofTribolium castaneum (Col.: Tenebrionidae) in stored grains

Conidia ofBeauveria bassiana were evaluated for activity against adults ofTribolium castaneum, under laboratory conditions closely resembling the stored-grain conditions. Three doses of the fungus were applied in the treatments: 0.1 g, 0.5 g and 1 g per 20 insects/dose/flask. Treated insects and untreated were incubated in broken wheat. There were 5 replications for each test. A total of 1600 treated and control insects used were kept in a climatic chamber (70±5% and 27±2°C) for 45 days. Observations were performed daily and the recording of infected cadavers began when the percentage of mortality exceeded 50%. The evaluation of the efficiency of each dose ofB. bassiana was made 14, 21, 28 and 45 days after inoculation. Mortality of adults that were exposed to the beetles treated with 0.5 g and 1 g of conidia ofB. bassiana / 20 adults was 87 and 85% respectively, within 21 days of exposure. Onset of mortality was further delayed at lower dosage of the fungus; 55% after 21 days. After 28 days there were no difference in mortality between the 0.5 g and 1 g dosages ofB. bassiana. The most efficient treatment was 0.5 g/20 insects, which resulted in a control higher than 50% 14 days post treatment.     

New Method for Extraction of Streptomycete Spores from Soil and Application to the Study of Lysogeny in Sterile Amended and Nonsterile Soil

A new method for the isolation and enumeration of streptomycete spores from soil was developed. This method makes use of a cation-exchange resin to disperse soil particles. It allowed the detection of 10 spores in 100 g of sterile soil, while ca. 10³ could be accurately enumerated in 100 g. This method was applied to studying the fate of a marked actinophage in soil. In sterile amended and nonsterile soil, relatively high numbers of actinophages were only found during the first few days of the experiment when the host streptomycete was in the mycelial form. Later, after sporulation, lysogens could be detected in sterile amended soil and could still be found 60 days after inoculation. Although no lysogens were found in nonsterile soil, the introduced phage could still be detected in the free state after 60 days, albeit at a low titer.     

Survival of Rhizobium in Acid Soils

A Rhizobium strain nodulating cowpeas did not decline in abundance after it was added to sterile soils at pH 6.9 and 4.4, and the numbers fell slowly in nonsterile soils at pH 5.5 and 4.1. A strain of R. phaseoli grew when added to sterile soils at pH 6.7 and 6.9; it maintained large, stable populations in soils of pH 4.4, 5.5, and 6.0, but the numbers fell markedly and then reached a stable population size in sterile soils at pH 4.3 and 4.4. The abundance of R. phaseoli added to nonsterile soils with pH values of 4.3 to 6.7 decreased similarly with time regardless of soil acidity, and the final numbers were less than in the comparable sterile soils. The minimum pH values for the growth of strains of R. meliloti in liquid media ranged from 5.3 to 5.9. Two R. meliloti strains, which differed in acid tolerance for growth in culture, did not differ in numbers or decline when added to sterile soils at pH 4.8, 5.2, and 6.3. The population size of these two strains was reduced after they were introduced into nonsterile soils at pH 4.8, 5.4, and 6.4, and the number of survivors was related to the soil pH. The R. meliloti strain that was more acid sensitive in culture declined more readily in sterile soil at pH 4.6 than did the less sensitive strain, and only the former strain was eliminated from nonsterile soil at pH 4.8; however, the less sensitive strain also survived better in limed soil. The cell density of the two R. meliloti strains was increased in pH 6.4 soil in the presence of growing alfalfa. The decline and elimination of the tolerant, but not the sensitive, strain was delayed in soil at pH 4.6 by roots of growing alfalfa.     

Management of entomopathogenic fungi in cultures of Tenebrio molitor (Coleoptera: Tenebrionidae)

Larvae of mealworms Tenebrio molitor L. (Coleoptera: Tenebrionidae) have been used as animal feed, but fungal pathogens rapidly downsize the populations, resulting in economic losses. In this work, we established an effective management strategy for fungal pathogens. An entomopathogenic fungus, Beauveria bassiana, was isolated from mealworm cadavers. The bioassay of some isolates of this species at >90% relative humidity revealed that the ERL1575 isolate had the highest virulence. At 20–30% RH, ERL1575 conidia when ingested produced 80% mortality but when sprayed topically produced only <10% mortality. Mealworms that had ingested conidia were exposed to 20, 25, 30 and 35°C and high humidity (>95%) for 5 days. This experiment produced about 90% mortality except at 35°C where mortality was <20%. When 40 fungicides were assayed against ERL1575, fluazinam (1000‐fold) and mancozeb (667‐fold) significantly inhibited conidial germination and/or hyphal growth. When fluazinam and mancozeb were added to the mealworm diet of conidia‐inoculated wheat bran, most were alive 3 days post application. However, 100% mortality resulted 3 days post application in the conidia‐inoculated wheat bran without any fungicides. In conclusion, B. bassiana isolates are pathogenic at <30°C when they are ingested by mealworms but fluazinam and mancozeb can be used for management to control the pathogen in their cultures.     

Selection of indigenous isolates of entomopathogenic soil fungus Metarhizium anisopliae under laboratory conditions

Eight native isolates of the entomopathogenic fungus Metarhizium anisopliae (Metschnikoff) Sorokin were obtained by monitoring soils cultivated in a conventional manner. These isolates were compared in three areas: (a) conidial germination, (b) radial growth and sporulation and (c) ability of conidia to infect Tenebrio molitor larvae. All bioassays were carried out at constant temperatures of 10, 15, and 20 °C. Conidia of individual isolates demonstrated differences in germination after a 24-h long incubation at all evaluated temperatures. At 20 °C, the germination ranged from 67 to 100 % and at 15 °C from 5.33 to 46.67 %. At 10 °C, no germination was observed after 24 h; nevertheless, it was 8.67–44.67 % after 48 h. In terms of radial growth, the culture diameters and the associated production of spores of all isolates increased with increasing temperature. At 10 °C, sporulation was observed in three isolates while all remaining cultures appeared sterile. Three weeks post-inoculation, conidia of all assessed isolates caused 100 % cumulative mortality of treated larvae of T. molitor at 15 and 20 °C with the exception of isolate 110108 that induced 81.33 % mortality at 15 °C. At 10 °C, larval cumulative mortality ranged from 6.67 to 85.33 % depending on the isolate. Isolates 110108 and 110111 showed significantly slower outset and a much lower rate of infection at all temperatures compared to other tested isolates of M. anisopliae. The bioassays were carried out with the purpose to sort and select indigenous isolates of M. anisopliae useful as biocontrol agents in their original habitat.     

Inhibition of Pseudogymnoascus destructans Growth from Conidia and Mycelial Extension by Bacterially Produced Volatile Organic Compounds

The recently identified causative agent of white-nose syndrome (WNS), Pseudogymnoascus destructans, has been implicated in the mortality of an estimated 5.5 million North American bats since its initial documentation in 2006 (Frick et al. in Science 329:679–682, 2010). In an effort to identify potential biological and chemical control options for WNS, 6 previously described bacterially produced volatile organic compounds (VOCs) were screened for anti-P. destructans activity. The compounds include decanal; 2-ethyl-1-hexanol; nonanal; benzothiazole; benzaldehyde; andN,N-dimethyloctylamine. P. destructans conidia and mycelial plugs were exposed to the VOCs in a closed air space at 15 and 4 °C and then evaluated for growth inhibition. All VOCs inhibited growth from conidia as well as inhibiting radial mycelial extension, with the greatest effect at 4 °C. Studies of the ecology of fungistatic soils and the natural abundance of the fungistatic VOCs present in these environments suggest a synergistic activity of select VOCs may occur. The evaluation of formulations of two or three VOCs at equivalent concentrations was supportive of synergistic activity in several cases. The identification of bacterially produced VOCs with anti-P. destructans activity indicates disease-suppressive and fungistatic soils as a potentially significant reservoir of biological and chemical control options for WNS and provides wildlife management personnel with tools to combat this devastating disease.     

Dry mycelium preparations of entomopathogenic fungi,Metarhizium anisopliae and Beauveria bassiana

Several different harvesting procedures were used to obtain dry mycelium preparations of the entomopathogenic fungi, Metarhizium anisopliae and Beauveria bassiana. The effects of these procedures on the survival of the fungal preparations and on their conidiation after short periods of storage at room temperature and at 4°C were examined. Harvesting procedures consisted of filtering the mycelium produced in airlift containers from the culture medium, washing with deionized water, spraying with a sugar solution, and incubating for 18 hr at 4°C before drying. Conidial production of treated mycelia stored 1.5 and 4.5 months at 4°C was not significantly different for and procedure. For dry mycelium of M. anisopliae stored 1.5 months at 4°C and then at room temperature for 3 months, maltose- and sucrose-treated preparations produced more conidia than preparations sprayed with dextrose solution, with water only, or not sprayed. B. bassiana preparations dried soon after mat formation were superior to those incubated at 4°C, and maltose-and dextrose-treated mycelia were superior to other treatments when stored at room temperature.     

Growth and patulin formation byPenicillium urticae Bainier in pure and mixed cultures

Penicillium urticae Bainier synthesized patulin in potato-dextrose medium at temperatures ranging from 5 to 30°C. Maximum patulin yield was 2700 μg/ml of culture fluid in 14 days at 25°C. Two distinctive intervals affected patulin formation: 15 to 20°C and 30 to 35°C, the former favorable and the latter detrimental. An incubation period of 11 to 14 days made a nonsterile mixture of weathered wheat straw and soil a favorable medium for patulin formation. Autoclaved weathered wheat straw, inoculated withP. urticae alone, or in combination withTrichoderma sp., was a medium comparable to nonsterile, incubated weathered wheat straw in soil. Both carbon source and accessory growth factors were important for patulin formation. Of seven media tested, potato-dextrose was superior to potatodextrose supplemented with 70 ppm Zn-ions and 16 ppm Fe-ions, potatosucrose, Raulin-Thom, autoclaved weathered wheat straw in pure culture, weathered wheat straw in nonsterile soil, and autoclaved weathered wheat straw in mixed culture, in that order. Patulin production ranged from 337.5 to 0.2 mg/g of C in the medium. Contribution from the Northern Plains Branch, Soil and Water Conservation Research Division, Agricultural Research Service, U.S. Department of Agriculture, in cooperation with the Nebraska Agricultural Experiment Station, Lincoln. Published as Paper No.2621, Journal Series, Nebraska Agricultural Experiment Station.     

Germination of the conidia of Peziza ostracoderma

Conidia ofPeziza ostracoderma Korf, washed by centrifugation and decantation, germinated in a high percentage in glass-distilled water and various nutrient solutions. They also germinated on a wide variety of agar media and in citratephosphate buffers from pH 3 through 8. The conidia first swell to twice their original size, and then emit one cylindrical germ tube. The cardinal temperatures for germination were: minimum, below 3° C; optimum, 20°–33° C; maximum, between 38° and 42° C. A liquid film of water was required for germination.     

Debilitation in conidia of the entomopathogenic fungi Beauveria bassiana and Metarhizium anisopliae and implication with respect to viability determinations and mycopesticide quality assessments

Germination of Beauveria bassiana (Bb) and Metarhizium anisopliae (Ma) conidia determined from a fast-rehydration (FR) protocol were compared to those obtained when dry conidia were subjected to slow rehydration (SR) by holding under high humidity conditions prior to aqueous suspension. Differences in viability estimates obtained using the FR vs. SR protocols increased markedly after conidia were exposed to various stress factors in storage (high a_w, temperature, and O₂ concentrations), with the SR protocol producing higher estimates of viability in all cases. After Bb conidia were stored under moist conditions for 21 days at 25 °C, the SR estimate of viability was >21% greater than the FR estimate. In jars flushed with different O₂ concentrations and stored at 50 °C for 34 days, proportional differences between protocols varied, depending on water activity, from 18-44% in jars flushed with 0% O₂ (100% N₂) to as high as 63-93% when treated with 21-22% O₂. For conidia stored over a broad range of moderate to high temperatures in the absence of O₂, SR-FR differences were ?9% at 25-40 °C but 30% at 50 °C. Germination of stressed Bb and Ma conidia increased substantially when incubation time on the germination substrate was increased from 24 to 72 h, whereas germination of non-stressed conidia showed little change. Conidia debilitated by stress were characterized by hypersensitivity to lethal imbibitional damage (damage that is mitigated by slow rehydration) and slow germination. Viability protocols that may provide more reliable assessments of overall mycopesticide quality are discussed.     

Studies on Prolonged Storage of Beauveria bassiana Conidia: Effects of Temperature and Relative Humidity on Conidial Viability and Virulence against Chickpea Borer,Helicoverpa armigera

Unformulated conidia of Beauveria bassiana were stored at five different temperatures (0°, 10°, 20°, 30° and 40°C) at six different relative humidities (RH) (0, 33, 53, 75, 85 and 98%). Conidial viabilities and virulence against third instar larvae of Helicoverpa armigera were determined over a 24‐month period. Conidia survived longest at lower temperatures (0–20°C) and lower RH levels (0–53% RH). At higher temperatures (30–40°C) conidia did not survive. When the temperature was decreased from 30°C to 0°C, at nearly all RH levels the longevity of conidia increased. Conidia remained virulent for third instar larvae of H. armigera under favourable storage conditions for 24 months.     

Influence of two formulation types and moisture levels on the storage stability and insecticidal activity of Beauveria bassiana

The formulation of mycopesticides may require a physical separation of conidia from the substrate and subsequent drying. In the present study, Beauveria bassiana conidia produced by solid-state fermentation were harvested either through a dry or washing protocol. Washed conidia were used to design a water-dispersible granule (WG) formulation, whereas sieved conidia were mixed with an emulsifiable oil to achieve an oil-based formulation (OD). Potential harmful effects caused by the formulation type on the storage stability and insecticidal activity against Hypothenemus hampei were assessed. As expected, the time for initial conidial germination to drop 50% (GT₅₀) in all treatments was deeply influenced by storage temperatures, which varied from over 180 days at 4 °C to less than 90 days at 35°C. In all four tested temperatures, GT₅₀s for unformulated dry conidia were significantly higher than for those formulated as WG, and the latter was similar to conidia formulated as OD in the two highest temperatures. Residual water content in the OD formulation (1,600 vs. 340?ppm) had a negative influence on conidial survival under storage, whereas WG granules immediately dried after the washing protocol showed conidial germination similar to granules exposed to a slower dehydration regime. Mortality of H. hampei adults exposed to different concentrations of B. bassiana formulated as WG was slightly lower (10–15%) than either the OD or the unformulated conidia. In brief, we have demonstrated that formulation type and their moisture level can affect the storage stability and insecticidal activity of B. bassiana conidia toward the coffee berry borer. Of particular importance, we have shown that drying oils prior to formulation could improve the storage of mycopesticides, an approach that may find industrial applications.