Ultra-violet radiation damage to Metarhizium flavoviride conidia and the protection given by vegetable and mineral oils and chemical sunscreens

Metarhizium flavouiride conidia formulated in oil or water were exposed to simulated solar radiation. Radiation below 320 nm killed conidia and caused delays in the germination of survivors; germination was greater after 48 h of incubation than after 24 h. UV exposure of conidia formulated in oil for 2 h reduced germination from 99% to 37.5% after incubation for 48 h. Exposure of conidia in water to UV for 1 h resulted in 4.7% germination after 24 h incubation compared with 36.5% for conidia formulated in oil. The addition of 1% oxybenzone resulted in 81.9% conidial germination after 3 h exposure and 48 h incubation compared with 28.1% in oil without the sunscreen.     

Protection of Metarhizium anisopliae conidia from ultra-violet radiation and their pathogenicity to Rhipicephalus evertsi evertsi ticks

Metarhizium anisopliae conidia were formulated in water or in olive oil containing 3% commercial sunscreens (Everysun or E45 Sun Block 50) and exposed to an artificial UV source for up to 5 hours. Survival of conidia after 5 h of exposure to UV in oil formulation was 29% when protected with Everysun, 40% when protected with E45, and 4% in control. In comparison, survival of conidia formulated in water was 13% when protected with Everysun, 24% when protected with E45, and 0% in control. Furthermore, the influence of sunscreens on conidia viability and virulence to Rhipicephalus evertsi evertsi larvae and unfed adult ticks was evaluated. Adding these compounds to the conidial formulations did not reduce the viability of the conidia. Larval mortality was 95 and 100%, while unfed adult mortality was 90 and 97% after being exposed to unprotected conidia formulated in water or in oil, respectively. Conidia protected by Everysun or E45 formulated in water, induced 88 and 83% mortality in larvae, and 92 and 90% mortality in unfed adults, respectively. Conidia suspended in oil and protected by Everysun or E45 induced 94 and 91% mortality in larvae, and 83 and 81% in unfed adults, respectively. These observations indicate that olive oil and the two sunscreens confer protection to conidia against damages by UV radiation without interfering with their pathogenicity to ticks.     

Increased heat tolerance afforded by oil-based conidial formulations of Metarhizium anisopliae and Metarhizium robertsii

The thermotolerance of oil-based conidial formulations of Metarhizium anisopliae s.l. (IP 46) and Metarhizium robertsii (ARSEF 2575) were investigated. Conidia of IP 46 or ARSEF 2575 were suspended in different adjuvants and exposed to 45?±?0.2°C for 4, 6, 8 or 24?h; their viability was then assessed after 48?h incubation at 27?±?1°C. Conidia heated in pure mineral or vegetable oil exhibited mean relative viability exceeding 70% after 8?h of heat exposure, whereas low germination (≤20%) was observed when conidia were heated in water (Tween 80^® 0.01%), carboxymethyl cellulose gel or emulsifiable oils (Graxol^® or Assist^®) and exposed to heat for 6 or 8?h. In addition, conidia of IP 46 suspended in either pure mineral or canola oil and exposed to heat for 48?h had moderate viability, 57% or 41%, respectively. Unstable oil-in-water emulsions showed a higher percentage of conidia incorporated into oil micellae, while the stable emulsions had higher percentage of conidia outside the oil micellae. The thermotolerance of conidia formulated in stable emulsions, however, did not differ from that of conidia formulated in unstable emulsions. The present study highlights possibilities to alleviate the deleterious effects of heat stress towards Metarhizium spp. conidia applied for controlling arthropod pests and vectors through oil-based formulations.     

Long-term Storage of Metarhizium flavoviride Conidia in Oil Formulations for the Control of Locusts and Grasshoppers

Freshly harvested conidia of Metarhizium flavoviride (Gams & Rozsypal) were stored in two vegetable oils, groundnut or soya, or a mineral oil, Edelex. They were diluted with either Shellsol K or deodorized kerosene, and antioxidants were added to half of the vegetable oil formulations. Dried non-indicating silica gel was added to half of the formulations before storage at 8 or 17 C. Undried conidia, those without silica gel, lost viability rapidly, with germination dropping below 40% after 9 and 32 weeks at 17 and 8 C respectively. After 127 weeks (ca. 30 months) in storage, germination remained at over 60 and 80% for the dried formulations at 17 and 8 C respectively (after an unexplained drop in germination after 16-18 months in storage). Comparable figures for 160 weeks (ca. 37 months) were 47 and 68%. These figures represented germination after 24 h of incubation; after 48 h of incubation, germination was 79 and 89% from samples stored for 160 weeks at 17 and 8 C respectively. Representative formulations of the stored conidia were tested in bioassays against the desert locust Schistocerca gregaria (Forskal) up to 30 months into the experiment, and were found to have retained full virulence compared with freshly prepared formulations.     

Characterisation of Isaria fumosorosea isolates and their virulence toward the Diamondback Moth,Plutella xylostella

Some morphological and physiological characteristics of an Isaria fumosorosea isolate with diminished virulence, IFCF01-D, and its parent isolate, IFCF01, were evaluated and laboratory bioassays were performed to assess their virulence against Plutella xylostella. The relationship among these traits and virulence against P. xylostella is discussed. There were no significant differences in conidial viability, spore production and the time required for 50% germination (GT₅₀). Spore viability after incubation for 24 h at 25°C was greater than 98% for both isolates tested. Spore production on potato dextrose agar after 14 days incubation at 25°C was 4.68 × 10⁸ and 4.59 × 10⁸ conidia/mL for IFCF01 and IFCF01-D, respectively. When exposed to high temperatures (40, 45, 50 or 55°C) through a water bath for 10 min, conidial germination ranged from 0.83% to 84.0% for IFCF01 and 0% to 86% for IFCF01-D. Germination rate showed a negative relationship with the exposure temperature for both isolates. The per cent germination of isolate IFCF01 24 h after ultraviolet (UV) radiation (18 W, 240–260 nm) varied from 0% to 92% and 0% to 81% for IFCF01-D. Germination rate and the exposure time exhibited a negative correlation for both isolates tested. Conidial surface hydrophobicity of IFCF01 (60%) was significantly higher than that of isolate IFCF01-D (53%). Subsequently, using the cicada exuviae as the substrate for enzymatic analysis, Pr1 and chitinase activity demonstrated the contrasting virulence traits: higher specific activities for the more virulent IFCF01 and lower enzymatic levels for isolate IFCF01-D.     

In vitro and in vivo evaluation of microbial-enriched compost tea on the development of powdery mildew on melon

This study evaluated the effects of microbial-enriched compost tea (CT) on the conidial germination of Golovinomyces cichoracearum DC. and development of powdery mildew on melons in a time-dependent manner. In vitro conidial germination was significantly reduced by 94?% and 85?% upon treatment with Daconil^? (fungicide) or microbial-enriched CT, respectively, 96?h after incubation (hai). Morphological analysis under light microscopy demonstrated that conidia co-incubated with microbial-enriched CT at 48?hai appeared ruptured, which contributed to higher inhibition of conidial germination, increased cell permeability and leakage of cellular contents. These observations may be explained by antibiosis. Moreover, different application time of microbial-enriched CT on melons significantly affected disease development. There was a delay in disease development by 12?days in plants treated with Daconil^?, microbial-enriched CT applied 24?h after inoculation and microbial-enriched CT applied simultaneously with inoculation when compared to the control treatment. Curative application of microbial-enriched CT (24?h after inoculation) delayed the onset of disease, and the efficiency of inhibition was comparable to a fungicidal spray (Daconil^?). Hence, microbial-enriched CT may be used to inhibit the development of powdery mildew on melons, thus reducing the dependency on chemical fertilisers.     

Persistence of <Emphasis Type="Italic">Isaria fumosorosea</Emphasis> (Hypocreales: Cordycipitaceae) SFP-198 Conidia in Corn Oil-Based Suspension

Long-term persistence of entomopathogenic fungi as biopesticides is a major requirement for successful industrialization. Corn oil carrier was superior in maintaining germination rates of Isaria fumosorosea SFP-198 conidia during exposure to 50°C for 2 h, when compared with other oils, such as soybean oil, cottonseed oil, paraffin oil, and methyl oleate. The corn oil-based conidial suspension (91.6% germination) was also better in this regard than conidial powder (28.4% germination) after 50°C for 8 h. Long-term storage stabilities of corn oil-based conidial suspension and conidial powder at 4 and 25°C for 24 months were investigated, based on the correlation of germination rate with insecticidal activity against greenhouse whiteflies, Trialeurodes vaporariorum. Viability of conidia in corn oil was more than 98.4% for up to 9 months of storage at 25°C, and followed by 23% at 21 months. However, conidial powder had only 34% viability after 3 months of storage at 25°C, after which its viability rapidly decreased. The two conidial preparations stored at 4°C had better viabilities than those at 25°C, showing the same pattern as above. These results indicate that corn oil-based conidial suspension can be used to improve conidial persistence in long-term storage and be further applied to the formulation of other thermo-susceptible biological control agents.     

Selection of surfactant compounds to enhance the dispersion of Beauveria bassiana

This study aimed to select surfactant compounds to improve the dispersion of emulsifiable conidial suspensions of Beauveria bassiana for field application while maintaining high conidia viability. Surfactant compatibility was initially evaluated by colony growth in culture media amended with increasing doses of surfactants. In a second experiment, the conidia germination rate was evaluated after temporary exposure to the compounds under laboratory conditions. The effect of the hydrophilic–lipophilic balance (HLB) of the surfactants on conidia dispersion and viability was assessed using mixtures of the most compatible products and concentration initially selected. Unitol L/20 and Ultranex NP/100 did not show deleterious effect on colony growth on culture media, while Surfom 3409 strongly inhibited conidial germination. Unitol L/20, Ultranex NP/100 and Ultratan D did not interfere in the germination of conidia during the first 10 minutes of exposure. After 120 minutes, germination was greatly reduced at a 0.5% concentration, with the exception of Ultranex NP/100. The higher conidial dispersion and germination were obtained with HLB values between 8 and 12 and lower remaining clusters at HLB 10. Moreover, there was no significant effect of HLB values on insect mortality. Unitol L/20 and Ultranex NP/100 were the most compatible surfactants in concentrations lower than 0.5%. The HLB value selected for dispersion of B. bassiana on water based formulations was 10.     

Impact of moisture and UV degradation on Beauveria bassiana (Balsamo) Vuillemin conidial viability in turfgrass

Beauveria bassiana conidial viability in turfgrass was evaluated using a two-component nucleic acid stain and fluorescence microscopy. Turfgrass samples along with the top 5 cm of soil were used for conidial extraction and viability evaluation on 1, 2, 3, 7, 14 and 21 days after treatment. There were no differences in conidial viability between two Orthoptera strains, 3622 and 5977, and both strains were able to persist in a sandy loam soil for up to three weeks after application. High and low irrigation levels were applied to each of the two strains and results show that higher irrigation (5.1 cm/week) maintains conidial viability better than a low irrigation level (2.5 cm/week). Mean conidial viability was approximately 8–12% greater in plots with the high irrigation regime. Rather than significantly increase soil moisture levels, it is hypothesized that the greater amount of irrigation helps to move the conidia deeper into the thatch layer and soil profile, an area that provides protection from damaging surface temperatures and UV exposure. Rainfall that occurred during the beginning of the 2005 test minimized the irrigation effect, and the irrigation treatment differences were more pronounced after 48 h. Four different UV protectants were evaluated for an impact on conidial viability of strain 3622. Two protectants, an optical brightener and magnesium silicate clay, when added to an emulsifiable oil formulation, significantly increased conidial viability on all evaluation dates. The clay particles act as a sunlight blocker while the optical brightener absorbs UV light. The combined protection from the oil and the additive increased conidial viability by approximately 10% on all evaluation dates. Results from this study provide insight into ways to increase entomopathogenic fungal viability under field conditions.     

Characterization of Beauveria bassiana and Metarhizium anisopliae isolates for management of tarnished plant bug,Lygus lineolaris (Hemiptera: Miridae)

Selected morphological and physiological characteristics of four Beauveria bassiana (Balsamo) Vuillemin isolates and one Metarhizium anisopliae (Metschnikoff) Sorokin isolate, which are highly pathogenic to Lygus lineolaris (Palisot de Beauvois) (Hemiptera: Miridae), were determined. There were significant differences in conidial size, viability, spore production, speed of germination, relative hyphal growth, and temperature sensitivity. Spore viability after incubation for 24h at 20 degrees C ranged from 91.4 to 98.6% for the five isolates tested. Spore production on quarter-strength Sabouraud dextrose agar plus 0.25% (w/v) yeast extract after 10 days incubation at 20 degrees C ranged from 1.6x10(6) to 15.5x10(6)conidia/cm(2). One B. bassiana isolate (ARSEF 1394) produced significantly more conidia than the others. Spore germination was temperature-dependant for both B. bassiana and M. anisopliae. The time required for 50% germination (TG(50)) ranged from 25.0 to 30.9, 14.0 to 16.6, and 14.8 to 18.0h at 15, 22, and 28 degrees C, respectively. Only the M. anisopliae isolate (ARSEF 3540) had significant spore germination at 35 degrees C with a TG(50) of 11.8h. A destructive sampling method was used to measure the relative hyphal growth rate among isolates. Exposure to high temperature (40-50 degrees C) for 10min had a negative effect on conidial viability. The importance of these characteristics in selecting fungal isolates for management of L. lineolaris is discussed.     

The effects of some storage conditions on viability of Lecanicillium lecanii conidia to whitefly (Homoptera: Trialeurodes vaporariorum)

A study on the survival of Lecanicillium lecanii conidia in storage at room temperature was carried out. Firstly, drying methods of conidia powder were compared. Vacuum-freeze drying (VFD) was more suitable for drying conidia as compared to vacuum drying (VD) at room temperature. Vacuum-freeze drying for 24-h resulted in a water content of 5.4%, and a viability, determined as germination of conidia in 2% glucose solution after16 h, was 90.3% and the infection in greenhouse whitefly, Trialeurodes vaporariorum was about 94.7% at a dose of 1×10⁸ conidia/mL. Secondly, the factors influencing viability of conidia stored at room temperature were evaluated in the laboratory. Temperature was the most critical factor influencing conidial storage stability, among the tested factors affecting survival of conidia stored at room temperature for 6 months. Both conidial germination and infection of hosts decreased with storage temperature increasing from 15 to 35°C, and at 35°C the survival of stored conidia for 6 months was near zero. The moisture content of the conidial powder was another major factor influencing viability of stored conidia at room temperature. Conidial powder dried to about 5% moisture content showed higher viability than non-dried conidial powder. For the carriers, clay and charcoal were more suitable for storage of L. lecanii conidia at room temperature. At a room temperature of 25°C, L. lecanii conidia which were dried to 5% water content and mixed with clay or charcoal could retain about 50% survival after 6 months' storage.     

Impact of moisture and UV degradation on Beauveria bassiana (Balsamo) Vuillemin conidial viability in turfgrass

Beauveria bassiana conidial viability in turfgrass was evaluated using a two-component nucleic acid stain and fluorescence microscopy. Turfgrass samples along with the top 5 cm of soil were used for conidial extraction and viability evaluation on 1, 2, 3, 7, 14 and 21 days after treatment. There were no differences in conidial viability between two Orthoptera strains, 3622 and 5977, and both strains were able to persist in a sandy loam soil for up to three weeks after application. High and low irrigation levels were applied to each of the two strains and results show that higher irrigation (5.1 cm/week) maintains conidial viability better than a low irrigation level (2.5 cm/week). Mean conidial viability was approximately 8–12% greater in plots with the high irrigation regime. Rather than significantly increase soil moisture levels, it is hypothesized that the greater amount of irrigation helps to move the conidia deeper into the thatch layer and soil profile, an area that provides protection from damaging surface temperatures and UV exposure. Rainfall that occurred during the beginning of the 2005 test minimized the irrigation effect, and the irrigation treatment differences were more pronounced after 48 h. Four different UV protectants were evaluated for an impact on conidial viability of strain 3622. Two protectants, an optical brightener and magnesium silicate clay, when added to an emulsifiable oil formulation, significantly increased conidial viability on all evaluation dates. The clay particles act as a sunlight blocker while the optical brightener absorbs UV light. The combined protection from the oil and the additive increased conidial viability by approximately 10% on all evaluation dates. Results from this study provide insight into ways to increase entomopathogenic fungal viability under field conditions.     

Effects of culture media on hydrophobicity and thermotolerance of Bb and Ma conidia, with description of a novel surfactant based hydrophobicity assay

Hypocrealean entomopathogenic fungal conidia are made up of multi-aged groups given their chronological conidiogenesis. Most thermotolerance assays have been conducted using mixed-age conidia. The present work exploited a polysiloxane polyether copolymer (siloxane) (Silwet L-77®) mediated conidial collection method, validated by a hydrophobicity assay. This was done to divide mixed-age conidia into two groups based on hydrophobicity and test their thermotolerance, relying on the relationship of conidial age with hydrophobicity. Beauveria bassiana GHA and ERL1170 and Metarhizium anisopliae ERL1171 and ERL1540 conidia, produced on millet agar, whey permeate agar, and ¼SDAY were subjected to hydrophobicity assays that included data on yield of conidia/unit of surface area. Conidia were also collected using 0.01% siloxane, and those remaining with 0.08% siloxane. Hydrophobicity was correlated with percent conidia collected in the two siloxane solutions and yield, suggesting a relationship between percent conidia collected and conidial age (maturation). The conidial suspensions were exposed to 45 °C for 45 min, and conidial germination was examined. Overall, conidia which were collected in 0.08% siloxane had lower germination after heat exposure than those collected in the 0.01% solution. Conidia of both fungi produced by incubation on millet or whey permeate for 14 d were more hydrophobic and exhibited greater thermotolerance than those produced on ¼SDAY. These results suggest that conidia can be divided into two groups with different thermotolerance by using a siloxane-mediated conidial collection method based on hydrophobicity. This depends on the types of substrates used that could influence conidial maturation.     

Delayed Germination of Beauveria bassiana Conidia after Prolonged Storage at Low, Above-freezing Temperatures

Powder formulations were prepared with conidia of the entomopathogenic fungus Beauveria bassiana strain 447 originally isolated in Brazil from the red imported fire ant, Solenopsis invicta. The carrier materials used in formulations included talc hydrous magnesium silicate , silica gel, powdered rice and cornstarch. The formulations were stored in plastic containers under three conditions: a ambient temperature 15-38 C ; b refrigerator 6 2 C ; and c freezer 10- 7 C . Formulations stored under ambient temperature conditions completely lost viability after 1-8 months. Unformulated conidia stored under ambient conditions were totally unviable after just 2 months. All formulations stored under refrigerator and freezer conditions maintained 100 viability for 7 years. The virulences of the conidial preparations against adult workers of the fire ant, S. saevissima, and the sugarcane borer, Diatraea saccharalis, were higher for fresh conidia or conidia stored in the freezer than for conidia stored in the refrigerator. After 30 months of storage, the unformulated conidia and the formulations stored in the refrigerator showed slow germination and had low virulence. There was a strong correlation between the rate of germination and the virulence toward D. saccharalis, but not toward S. saevissima.     

Effects of stabilizers on shelf-life of Epicoccum nigrum formulations and their relationship with biocontrol of postharvest brown rot by Monilinia of peaches

AIM: To find a formulation of Epicoccum nigrum conidia that maintains a high viability over time and which proves efficient to biocontrol peach rot caused by Monilinia spp. METHODS AND RESULTS: We tested the effect of stabilizers and desiccants on the shelf-life of Epicoccum nigrum conidia. Conidial samples were dried for 40 min at 40 degrees C in a fluidized bed-dryer to obtain moisture contents <15%. The toxicity of additives was tested by assaying production of conidia in fermentations and germinability of the produced conidia: 50% PEG300, 10%-5% KCl (stabilizers) and 95.24% Cl(2)Ca (desiccant) significantly (P = 0.05) reduced conidial germination. To enhance shelf-life of dried conidia, nontoxic stabilizers were added at the following different stages of the production-drying process: (i) to substrate contained in bags before production, (ii) to conidial centrifuge pellets obtained after production, before filtering and drying, (iii) to conidial centrifuge pellets obtained after production, before adding talc and drying, and (iv) to conidial centrifuge pellets obtained after production, before adding silica powder and drying. Conidial germinability was tested at 0, 180 and 365 days after storage at room temperature. Shelf-life of formulations retaining the highest viability were conidia produced with 1% KCl or 50% PEG 8000, conidia dried with 2.5% methylcellulose, and conidia dried with 1% KCl + silica powder. All these formulations improved the shelf-life of E. nigrum conidia and significantly reduced brown rot on peaches. CONCLUSIONS: Our results show that additives improve the shelf-life of E. nigrum and assist controlling brown rot on peaches. SIGNIFICANCE AND IMPACT OF THE STUDY: New improved formulations of a biocontrol agent have been obtained which will improve the control of Monilinia on peach.     

Relationship between number and type of adhesions of Penicillium oxalicum conidia to tomato roots and biological control of tomato wilt

We studied (a) the extent adhesion of Penicillium oxalicum conidia to tomato roots after application of P. oxalicum conidial formulations with or without stickers, (b) the relationship between the extent of conidial adhesion to roots and biocontrol of the conidial formulations against tomato wilt, and (c) colonisation of roots by P. oxalicum. Adhesion of P. oxalicum conidia to tomato roots occurred within the first minute of contact between the root and the conidial formulation and the bonding strength was sufficiently strong to prevent conidial removal from the roots. In addition, some formulations with stickers that increased conidial adhesion to roots improved the biocontrol of tomato wilt, when compared to that of formulations without stickers. A “dried conidia without stickers” with 0.025% Nu-Film 17 had no effect on the biocontrol of tomato wilt, despite good adherence of the conidia to the roots. The numbers of P. oxalicum conidia that adhered to the roots was constant for 60 days after application of a “dried conidia without stickers” conidial formulation. The significance of these results (speed of adhesion, number of adhered conidia, and variability of conidial external surface) are discussed in relation to the biocontrol success of tomato wilt using different types of conidial formulations with and without stickers.     

Variations in UV-B tolerance and germination speed of Metarhizium anisopliae conidia produced on insects and artificial substrates

Solar ultraviolet radiation (UV-A and UV-B) is a major factor in failure of programs using the insect pathogenic fungus Metarhizium anisopliae as a biological control agent. Studies were conducted to determine if growth conditions, viz. artificial (agar media or rice grain) or natural (infected insects) substrates for conidial production affect two traits that directly influence performance of conidia after field application: tolerance to UV-B radiation and conidial germination speed. Conidia of two isolates (ARSEF 23 and ARSEF 2575) of M. anisopliae var. anisopliae produced on potato dextrose agar plus yeast extract (PDAY) or on fungus-killed larvae of two insect species, Galleria mellonella and Zophobas morio, were inactivated by exposure to UV-B radiation. Conidia of both isolates when produced on insect cadavers were significantly more sensitive to UV-B radiation than conidia produced on PDAY. Also, conidia from insect cadavers germinated slower than those from PDAY cultures. A comparison of conidia from artificial substrates showed that conidia produced on Czapek's and Emerson's YpSs agar media or rice grains had higher tolerance to UV-B radiation and germinated faster than conidia raised on PDA and PDAY. Accordingly, the growth substrate and nutritional environment in which conidia are produced influences M. anisopliae conidial UV-B tolerance and speed of germination; and manipulation of these variables could be used to obtain conidia with increased tolerance to UV-B radiation and shorter germination times.     

Description of conidia from submerged cultivation of Thermomyces lanuginosus for use as a uniform inoculum.

Conidia produced by submerged cultivation of the thermophilic fungus Thermomyces lanuginosus were superior to conidia from agar plates when used as inoculum, due to a faster and more synchronous germination. With conidia derived from submerged liquid culture at 40-45 degrees C more than 90% germination was achieved at 50 degrees C within 3 h whereas the same percentage germination was only achieved after 5 h incubation of conidia produced on agar plates. The temperature during conidial formation, and conidial age at the time of harvesting, were factors influencing germination of the conidia.     

Effect of drying on conidial viability of Penicillium frequentans, a biological control agent against peach brown rot disease caused by Moniliniaspp

The effects of drying methods (freeze-, spray-, and fluid bed-drying) on viability of Penicillium frequentans conidia were compared. Viability, estimated by germination of fluid bed- and freeze-dried conidia, was similar to that of fresh conidia. Skimmed milk alone, or in combination with other protectants, was added to conidia before freeze-drying. After the freeze-drying process, all protectants used, except glycerol improved conidial viability. Freeze-dried P. frequentans conidia did not maintain viability after 30 days of storage at room temperature, while conidia dried by fluid bed-drying showed 28% viability following 180 days after drying. This work also demonstrated a relationship between conidial viability after 1 year of storage at room temperature, moisture content after fluid bed-drying and initial weight of sample. Conidial moisture contents must be reduced to 5-15% for optimal storage at room temperature. P. frequentans conidia dried by fluid bed-drying were as effective as fresh conidia in controlling brown rot of peaches.     

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.