Liquid production of entomopathogenic fungi and ultraviolet radiation and temperature effects on produced propagules

Ottati-de-Lima, Emma Luize; Batista Filho, Antonio; Almeida, José Eduardo Marcondes de; Gassen, Mariana Hollanda; Wenzel, Inajá Marchizeli; Almeida, Aline Maria Belasco de; Zapellini, Luciano Olmos

doi:10.1590/1808-1657001352012

Abstracts

The purpose of this paper was to evaluate the liquid culture media for the production of Metarhizium anisopliae (IBCB 425) and Beauveria bassiana (IBCB 66), as well as the tolerance of these seedlings to the ultraviolet action and to the temperature. Twelve treatments composed of combinations between carbon and nitrogen concentrations were assessed. In order to determine the effect of ultraviolet radiation, plates with blastos-pores were exposed to it for 25 and 50 seconds. To determine the temperature efect, blastospores from culture media were exposed to 20, 25, 30 and 35°. For the virulence experiments, caterpillars of Diatraea saccharalis were sprayed with 2 mL of fungal suspension with the aid of a Potter tower. Te best media for M. anisopliae are 16.00 g (carbon) + 7.00 g (nitrogen) and 14.40 g (carbon) + 7.00 g (nitrogen), whereas for B. bassiana: 20.00 g (carbon) + 6.30 g (nitrogen) and 20.00 g (carbon) + 7.00 g (nitrogen). Te longer the exposure to ultraviolet radiation, the smaller the number of colonies. At 35°, there is a significant decrease in the formation of colonies. Te produced seedlings of fungi are pathogenic to D. saccharalis.

Beauveria bassiana ; Metarhizium anisopliae ; fungi production; microbial control; sugarcane borer

O objetivo deste trabalho foi avaliar os meios de cultura líquidos para a produção de Metarhizium anisopliae (IBCB 425) e Beauveria bassiana (IBCB 66), bem como a tolerância desses propágulos à ação dos raios ultravioleta e à temperatura. Foram avaliados 12 tratamentos compostos pelas combinações entre carbono e nitrogênio. Para determinar o efeito da radiação ultravioleta, placas com blastósporos foram expostas à radiação por 25 e 50 segundos. Para conhecer o efeito da temperatura, os blastósporos de meios de cultura foram expostos a temperaturas de 20, 25, 30 e 35°. Para os experimentos de virulência, as lagartas Diatraea saccharalis foram pulverizadas com 2mL de suspensão fúngica, com o auxílio de uma torre de Potter. Os melhores meios para M. anisopliae são 16,00 g (carbono) + 7,00 g (nitrogênio) e 14,40 g (carbono) + 7,00 g (nitrogênio), e para B. bassiana, 20,00 g (carbono) + 6,30 g (nitrogênio) e 20,00 g (carbono) + 7,00 g (nitrogênio). Quanto mais tempo de exposição à radiação ultravioleta, menor o número de colônias. Aos 35°, há uma diminuição signifcativa na formação de colônias. Os propágulos produzidos pelos fungos são patogênicos a D. saccharalis.

Beauveria bassiana ; Metarhizium anisopliae ; produção de fungos; controle microbiano; broca da cana-de-açúcar

INTRODUCTION

Te liquid media have been increasingly used for the large-scale fungi production because they allow better control of physical and nutritional conditions required by the microorganism (Jackson et al. 1996JACKSON, M.A.; SCHISLER, D.A.; SLININGER, P.J.; BOYETTE, C.D.; SILMAN, R.W.; BOTHAST, R.J. Fermentation strategies for improving the fitness of a bioherbicide. Weed Technology, Kansas, v.10, p.645-650, 1996.; Jackson, 1997JACKSON, M.A. Optimizing nutritional conditions for the liquid culture production of effective fungal biological control agents. Journal of Industrial Microbiology and Biotechnology, Houndmills, v.19, p.180-187, 1997.). However, the industrial-scale entomopathogenic fungi production represents a critical and limiting step in the development of a microbial control program for a particular pest. Tus, the search for new methods of production systems is very important to control microbial pests economically feasible when applied to large areas (Tanzini, 2002TANZINI, M.R. Controle do percevejo-de-renda-da-seringueira (Leptopharsa heveae) com fungos entomopatogênicos. 2002. 140p. Tese (Doutorado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 2005.).

According to Leite et al. (2003)LEITE, L.G.; BATISTA FILHO, A.; ALMEIDA, J.E.M.; ALVES, S.B. Produção de fungos entomopatogênicos. Ribeirão Preto: Alexandre de Sene Pinto, 2003. 92p., the diversity of carbon (C) and nitrogen (N) sources has been widely exploited in the development of culture media, especially the complex one made by natural products. Nevertheless, more recent studies have shown that the ratio C : N is also an important factor to be considered in the development of culture media, especially of liquid medium that aims to produce submerged forms.

More susceptible to conditions in the field, entomopa-thogenic fungi are exposed to biotic and abiotic factors that influence their survival and propagation, as well as host infection (Goettel et al., 2000GOETTEL, M.S.; INGLIS, G.D.; WRAIGHT, S.P. Fungi. In: Lacey, L. A.; Kaya, H. K. (Eds.) Field manual of techniques in invertebrate pathology. Dordrecht: Kluver Academic Publishers, 2000. p.255-282.). Among abiotic factors, solar radiation is the most important (Fargues et al., 1996FARGUES, J.; GOETTEL, M.S.; SMITS, N.; OUEDRAOGO, A.; VIDAL, C.; LACEY, L.A.; LOMER, C.J.; ROUGIER, M. Variability in susceptibility to simulated sunlight of conidia among isolates of entomopathogenic hyphomycetes. Mycopathologia, Holanda, v.135, p.171-181, 1996.; Braga et al., 2001aBRAGA, G.U.L.; FLINT, S.D.; MESSIAS, C.L.; ANDERSON, A.J.; ROBERTS, D.W. Effects of UV-B irradiance on conidia and germinants of the entomopathogenic hyphomycete Metarhizium anisopliae: a study of reciprocity and recovery. Photochemistry and Photobiology, v.72, p.140-146, 2001a.; Cagan; Svercel, 2001CAGAN, L; SVERCEL, M. The influence of ultraviolet light on pathogenicity of entomopathogenic fungus Beauveria bassiana (Balsamo) Vuillemin to the European corn borer, Ostrinia nubilalis HBN. (Lepidoptera: Crambidae). Journal of Central European Agriculture, Croácia, v.2, n.4, p.19-125, 2001.) for being able to inactivate conidia and cause lethal damage to DNA and mutations (Nicholson et al., 2000NICHOLSON, W.L.; MUNAKATA, N.; HORNECK, G.; MELOSH, H.J.; SETLOW, P. Resistence of Bacillus endospores to extreme terrestrial and extraterrestrial environments. Microbiology and Molecular Biology Reviews, Washington, v.64, n.3, p.548-572, 2000.). In general, the efects of ultraviolet (UV) radiation reduce the fungal efficiency in the field (Braga et al., 2001bBRAGA, G.U.L.; FLINT, S.D.; MILLER, C.D.; ANDERSON, A.J.; ROBERTS, D.W. Variability in response to UV-B among species and strains of Metarhizium isolated from sites at latitudes from 61oN to 54oS. Journal of Invertebrate Pathology, Orlando, v.78, p.98-108, 2001b.). It is also worth mentioning temperature as another factor that acts on pathogens and affects the production, storage stability, and pathogenicity under field conditions. Tis factor becomes even more important in view of the pathogens inability of protecting themselves from temperature fluctuations through physiological systems (Alves, 1982ALVES, S.B. Caracterização, padronização e produção do Metarhizium anisopliae (Metsch.) Sorok. 1982. 95p. Tese (Doutorado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1982.).

Tus, the objective of this study was to evaluate the different culture media on the net production of fungal seedlings of Metarhizium anisopliae (M. anisopliae) and Beauveria bassiana (B. bassiana), and to investigate the effect of UV radiation and of different temperatures on the produced seedlings, as well as the virulence of fungi to Diatraea saccharalis (D. saccharalis).

MATERIAL AND METHODS

Te experiments were carried out at the Laboratory of Biological Control of the Biological Institute in Campinas, State of São Paulo, Brazil.

Strains of M. anisopliae (IBCB 425) and B. bassia-na (IBCB 66) are found deposited in the Collection of Entomopathogenic Microorganisms “Oldemar Cardim Abreu," held at the Laboratory of Biological Control. IBCB 425 was obtained from a soil sample from Iporanga, in São Paulo, and IBCB 66 comes from the coffee berry borer, Hypothenemus hampei (Coleoptera: Scolytidae), collected in São José do Rio Pardo, also in São Paulo. Te strains are found stored in a freezer at −20° as pure conidia, packed in plastic tubes like “Eppendorfs." For the bioassays, fungal strains were transferred in Petri dishes (9 cm in diameter) containing PDA (Potato Dextrose Agar) culture medium (200 g of potato, 20 g of agar, and 20 g of dextrose in 1,000 mL of distilled water).

In the laminar flow hood, each fungus was inoculated at three points on the plates by using a platinum loop, which was previously flambéed. Te plates were kept in a BOD (Biochemical Oxygen Demand) incubator, at 25 ± 1°, RH (Relative Humidity) 70 ± 10% and 12-hour photophase, for ten days. Te produced conidia were removed from the surface of the culture medium, with the aid of a metal spatula, which had been previously flambéed for preparing the suspension in sterile water with wetting agent (Tween® 80 − 0.1 mL^-1) containing 1 × 10⁸ conidia mL^-1. Te prepared suspensions were used for fungi net production.

A total of 12 treatments with six replicates for each was assessed, consisting of combinations between the concentrations of C in the form of D-glucose anhydrous (40% of C), and sucrose (42.11% of C) with N in the form of brewer's yeast (7.31% N) per liter of medium. Te proportions were based on the work done by Sano (2005)SANO, A.H. Dosagens de extrato de levedura e glicose para produção de Metarhizium anisopliae em meio líquido. 2005. 42p. Dissertação (Mestrado – Entomologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2005., as seen in Table 1.

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Table 1
Amounts of carbon and nitrogen sources to prepare 1.0 L of each culture medium.

Each treatment consisted of six Erlenmeyer flasks containing 100 mL of the medium, sealed with hydrophobic cotton cap covered by aluminum foil, and autoclaved at 1 atm, at 120°, for 20 minutes. With a pipette, it was added 1 mL of the suspension at a concentration of 1 × 10⁸conidia mL^-1 in each vial, in a vertical laminar flow hood. Ten, the flasks were put to continuous agitation at 40 rpm, at 26 ± 1° and in a 12-hour photoperiod, in which they remained for four, six, and eight days. Te experiments were divided into two parts, due to the capacity to accommodate Erlenmeyer shakers flasks. After statistical analysis, the best media of each part were selected.

Concentration of blastospores

Measurements of blastospores were performed at four, six, and eight days after inoculation by taking, in aseptic conditions (laminar flow), a sample of 5 mL/vial for counting the blastospores. From this sample, it was added 1 mL for 9 mL of sterile water and wetting agent (Tween 80®). Te suspension was quantified in Neubauer chamber, under microscope (400 times magnification). To assess the quality of the fungus with regard to the presence of contaminants, two samples of 0.1 mL in each flask were transferred to Petri dishes containing PDA culture medium. Te plates were kept in a BOD incubator, at 25 ± 1°, RH 60 ± 10%, and 12-hour photophase for a 7-day period. Contaminated vials were discarded.

The counting of colonies

Ultraviolet

After quantifying blastospores, the effect of UV radiation on the plants was evaluated by putting them in 9 cm plastic plates containing BDA and pentabiotic (0.5 g.L^-1) – 100 mL of each treatment/plate, with the aid of a micropipette in laminar flow. Ten, the plates were subjected to a germicidal lamp (UV radiation of 253.7 nm) — 25.0 cm far from the radiation source — and exposed to radiation for 25 and 50 seconds. A control treatment without radiation exposure was also performed. Te plates were kept in BOD incubator at 25°, for three days. After this period, the colonies of M. anisopliae and B. bassiana formed on the plates were counted.

Temperature

Te same methodology as in the previous item was used to evaluate the temperature effect. Te treatments were exposed to different ones: 20, 25, 30, and 35°C.

Virulence to D. saccharalis

Five treatments with eight replications and ten caterpillars were used, totaling 80 larvae per treatment and 400 others for the virulence experience. Te third-instar larvae of D. saccharalis were obtained from a population reared in the laboratory of São João mill in Araras, São Paulo, Brazil. Each batch of 10 larvae was placed on a Petri dish of 12 cm in diameter in order to be treated with the aid of a Potter tower. They were sprayed with 2 mL of the fungal suspension of each treatment, at a concentration of 1.0 × 10⁷ conidia mL^-1. Te insects of control treatment were sprayed with 2 mL of sterile water.

The wetting agent was added in every treatment (0.01% Tween 80®). Later, the larvae were transferred to plastic pots of 6.5 × 5.0 cm in diameter, with a screw cap, after fasting for a period of 24 hours. After such time, some sugarcane stalks of 3 cm were offered.

Each dead insect was washed in 70% alcohol and distilled water for surface disinfection. Te insects were transferred then to plastic plates containing cotton soaked in water to form a moist environment. Te plates were stored in an incubator at 25 ± 1°, with 12-hour photophase, and relative humidity of 70 ± 10%. Te confirmation of mortality caused by the pathogen was achieved with this procedure, by observing mycelial growth and conidiogenesis on insect cadaver.

Statistical analysis

A randomized experimental design was used, and the analysis was performed with the ESTAT (Statistical Analysis Systems) software, developed in FCAV/UNESP in Jaboticabal, São Paulo, Brazil. Te productivity average of blastospores was subjected to variance analysis by F test at a 5% probability, and the averages compared by Tukey's test at a significance level of 5%. Some analyses demanded data transformation.

RESULTS AND DISCUSSION

Production in net medium of M. anisopliae and B. bassiana

Concentration of blastospores, i.e. the sum of the blastospo-res production (× 10⁸ mL^-1), was made in three evaluations. Ten, the two most productive culture media of each stage were chosen (Tables 2 and 3).

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Table 2
Average concentration of Metarhizium anisopliae (IBCB 425), obtained from liquid culture medium with different concentrations of nitrogen and carbon at four, six and eight days after inoculation (at 26 ± 1°C and 12-hour photophase).

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Table 3
Average concentration of Beauveria bassiana (IBCB 66), obtained from liquid culture medium with different concentrations of nitrogen and carbon at four, six and eight days after inoculation (at 26 ± 1°C and 12-hour photophase).

Te best media of each of the two steps for M. anisopliae and Beauveria bassiana (Table 4) were selected. For the first, the best culture media showed D-glucose anhydrous (C source) in its composition, and for the latter, the best culture media presented sucrose (C source) in it. It was noticed that both treatments showed 10% more and 10% less of D-glucose anhydrous, and the same amount of brewer's yeast (Table 4).

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Table 4
Average concentration of Metarhizium anisopliae (IBCB 425) and Beauveria bassiana (IBCB 66), obtained from the liquid culture media in different concentrations of nitrogen and carbon, at four, six and eight days after inoculation (at 26 ± 1°C and 12-hour photophase).

With regard to B. bassiana productivity, it must be stated that the 11^th treatment (20.00 g C + 7.00 g N) had the greatest amount of blastospores at the 4^th day of evaluation (Table 4). Tus, the productivity was distributed throughout the analysis — except on day 4, which stood out from others. Also, both treatments selected for B. bassiana have the same amount of sucrose as well as 10% more and 10% less of brewer's yeast. Bearing in mind that the liquid media selected to M. anisopliae and B. bassiana have a larger amount (in grams) of N in its composition, this study has taken the brewer's yeast as a N source, while Sano (2005)SANO, A.H. Dosagens de extrato de levedura e glicose para produção de Metarhizium anisopliae em meio líquido. 2005. 42p. Dissertação (Mestrado – Entomologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2005. has considered the yeast extract. From an economic standpoint, the former is more advantageous than the latter, presenting itself as a viable alternative of N source.

It was assessed that the best media to produce blas-tospores are formed by a lower concentration of N and a higher one of C. Tis was also reported by Oliveira (2000)OLIVEIRA, S.M.C. Exigências físicas e nutricionais para produção de Sporothrix insectorum em meio líquido. 2000. 45p. Dissertação (Mestrado – Microbiologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2000. and Sano (2005)SANO, A.H. Dosagens de extrato de levedura e glicose para produção de Metarhizium anisopliae em meio líquido. 2005. 42p. Dissertação (Mestrado – Entomologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2005., who have added different concentrations of yeast extract to the liquid media in the production of Sporothrix insectorum and M. anisopliae, respectively, and have gotten the best yields with lower concentrations of N.

The counting of colonies

Ultraviolet

It was observed that there was no significant difference between treatments of M. anisopliae and those of B. bassiana (Table 5). However, it was seen that the longer the exposure to UV radiation, the lower the number of colonies; with a very low amount of them after 50 seconds of exposure. These results are in agreement with the comments reported in several papers related to the influence of UV radiation on sporulation (Leach, 1965LEACH, C.M. Ultraviolet-absorbing substances associated with light-induced sporulation in fungi. Canadian Journal of Botany, Ottawa, v.43, p.185-200, 1965.), germination (Zimmerman, 1982ZIMMERMANN, G. Effect of high temperatures and artificial sunlight on the viability of conidia of Metarhizium anisopliae. Journal of Invertebrate Pathology, Orlando, v.40, n.1, p.36-40, 1982.), viability (Corrêa, 1983CORRÊA, G.S. Influência da radiação ultravioleta e solar na viabilidade de conídios de Metarhizium anisopliae (Metsch) Sorokin. 1983. 84p. Dissertação (Mestrado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1983.), and inactivation of ento-mopathogens microorganisms (Ignoffo; Batzer, 1971IGNOFFO, C.M.; BATZER, O.F. Microencapsulation and ultraviolet protectants to increase sunlight stability of an insect virus. Journal of Economic Entomology, Lanham, v.64, n.1, p.850-853, 1971.; Broome et al., 1974BROOME, J.R.; SIKOROWSKI, P.P.; NELL, W.W. Effect of sunlight on the activity of Nuclear Polyhedrosis virus from Malacossoma disstria. Journal of Economic Entomology, Lanham, v.67, n.1, p.135-136, 1974.; Jaques, 1985JAQUES, R.P. Stability of insect viruses in the environment. In: MARAMOROSCH, K.; SHERMAN, K.E. (Eds.). Viral Insecticides for Biological Control. Orlando: Academic Press, 1985. p 285-360.; Griego et al., 1985GRIEGO, V.M.; MARTIGNONI, M.E.; CLAYCOMB, A.E. Inactivation of nuclear polyhedrosis virus (Baculovirus subgroup A) by monochromatic UV radiation. Applied and Environmental Microbiology, Washington, v.49, n.3, p.709-710, 1985.; Ali; Sikorowski, 1986ALI, S.; SIKOROWSKI, P.P. Effects of sunlight, cotton foliage surface, and temperature on the infectivity of citoplasmatic polyhedrosis virus to Heliothis virescens larvae (Lepidoptera: Noctuidae). Journal of Economic Entomology, Lanham, v.79, n.2, p. 364-367, 1986.).

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Table 5
Number of colonies obtained from Metarhizium anisopliae (IBCB 425) and Beauveria bassiana (IBCB 66) after exposure of blastospores to ultraviolet radiation for 25 and 50 seconds, and incubation of three days (at 25 ± 1°C and 12-hour photophase).

Temperature

Table 6 summarizes the numbers of colonies obtained after incubation at 20, 25, 30, and 35°. Fungi have germinated at 25 and 30°C, yielding the expected number of colonies. However, at a 20°C temperature, the growth of colonies was significantly lower than the one observed at 25 and 30°. It was virtually null at a 35° temperature.

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Table 6
Number of colonies of Metarhizium anisopliae (IBCB 425) and Beauveria bassiana (IBCB 66) obtained after inoculation of blastospores produced in liquid media and exposed to different temperatures.

According to Alves (1986)ALVES, S.B. Epizootiologia. In: Alves, S. B. (Ed.). Controle microbiano de insetos. Manole: São Paulo, 1986, p. 29-60., M. anisopliae and B. bassiana have favorable T ranges for development, from 24 to 30°C and 22 to 26°, respectively, while Walstad et al. (1970)WALSTAD, J.D.; ANDERSON, R.F.; STAMBAUGH, W.J. Effects of environmentalconditions on two species of muscardine fungi (Beauveria bassiana and Metarhiziumanisopliae). Journal of Invertebrate Pathology, Orlando, v.16, p.221-226, 1970. have reported that the limit from 24 to 30° is the best for germination of M. anisopliae spores. Bastos;Matta (1976)BASTOS, C.N.; MATTA, E.A.F. Influência das temperaturas e luz na esporulação do fungo Metarhizium anisopliae (Metsch.) Sorokin. Boletim do Instituto Biológico da Bahia, Salvador, v.15, n.1, p.5-8, 1976. concluded that 25° was the best temperature for sporulation of M. anisopliae.

Similar results were stated by Santos (1978)SANTOS, A.L.L. Influência de alguns fatores no crescimento, germinação e produção de conídios de Metarhizium anisopliae (Metsch.) Sorokin. 1978. 148p. Dissertação (Mestrado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1978., when the number of colonies after incubation of M. anisopliae conidia reached 98 at 28°. Te same author emphasized that 37° inhibits spore germination, with no found growth in plates at such temperature.

Among B. bassiana treatments, 20.00 g C + 6.30 g N was significantly different from 20.00 g C + 7.00 g N, when compared to the number of colonies at 35°. However, this variation was not consistent along the temperature ranges, indicating that this is only an occasional variation. For M. anisopliae, the best gradient for growth of colonies was between 25 and 30°, while for B. bassiana the optimum temperature was at 25°.

Virulence to D. saccharalis

After analyzing the confirmed mortality of infected larvae, there was no difference between treatments for both species (Table 7).

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Table 7
Confirmed mortality (%) of third-instar larvae (Diatraea saccharalis) at eight days after the application of different suspensions of Metarhizium anisopliae and Beauveria bassiana, obtained from liquid culture media (blastospores) in different concentrations of nitrogen and carbon (temperature at 26 ± 1°C, RH 70 ± 10% and 12-hour photophase).

Results point out that the blastospores have caused a D. saccharalis mortality rate between 26.00 and 29.00% for both M. anisopliae and B. bassiana on evaluated media. Te blastospore is a low-resistance structure in the environment because the cell wall has the same constitution of the hypha one (Leite et al., 2003LEITE, L.G.; BATISTA FILHO, A.; ALMEIDA, J.E.M.; ALVES, S.B. Produção de fungos entomopatogênicos. Ribeirão Preto: Alexandre de Sene Pinto, 2003. 92p.). Formation of such also makes the seedlings turn into hygroscopic ones, a fact that discourages their membership in the host (Boucias et al., 1981).

The choice for production of blastospores comes from their possibility of being produced in submerged culture medium. This facilitates the production process, reduces the time of collection or filling, and allows an increase in the number of infective units produced per average volume (Torre; Cárdenas-Cota, 1996TORRE, M.; CÁRDENAS-COTA, H.M. Production of Paecilomyces fumosoroseus conidia in submerged culture. Entomophaga, Paris, v.41, p.443-453, 1996.). Thus, the higher production of propagules may compensate for their lower pathogenicity.

CONCLUSIONS

The best media to produce blastospores are formed by a lower concentration of N and a higher one of C. The most appropriate culture media for M. ani-sopliae contain D-glucose anhydrous (C source) in its composition, where B. bassiana has sucrose (C source).

Te exposure to UV radiation and to temperatures at 35°C is detrimental to fungi growth. M. anisopliae and B. bassiana are virulent to third-instar larvae of D. saccharalis, whatever is the liquid medium in which they were produced.

REFERENCES

ALI, S.; SIKOROWSKI, P.P. Effects of sunlight, cotton foliage surface, and temperature on the infectivity of citoplasmatic polyhedrosis virus to Heliothis virescens larvae (Lepidoptera: Noctuidae). Journal of Economic Entomology, Lanham, v.79, n.2, p. 364-367, 1986.
ALVES, S.B. Epizootiologia. In: Alves, S. B. (Ed.). Controle microbiano de insetos. Manole: São Paulo, 1986, p. 29-60.
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BASTOS, C.N.; MATTA, E.A.F. Influência das temperaturas e luz na esporulação do fungo Metarhizium anisopliae (Metsch.) Sorokin. Boletim do Instituto Biológico da Bahia, Salvador, v.15, n.1, p.5-8, 1976.
BOUCIAS, D.G.; JOHNSON, D.W.; ALLEN, G.E. Effects of host age, virus dosage, and temperature on the infectivity of a nucleopolyhedrosis virus against velvetbean caterpillar, Anticarsia gemmatalis, larvae. Environmental Entomology, v.9, p.59-61, 1980.
BRAGA, G.U.L.; FLINT, S.D.; MESSIAS, C.L.; ANDERSON, A.J.; ROBERTS, D.W. Effects of UV-B irradiance on conidia and germinants of the entomopathogenic hyphomycete Metarhizium anisopliae: a study of reciprocity and recovery. Photochemistry and Photobiology, v.72, p.140-146, 2001a.
BRAGA, G.U.L.; FLINT, S.D.; MILLER, C.D.; ANDERSON, A.J.; ROBERTS, D.W. Variability in response to UV-B among species and strains of Metarhizium isolated from sites at latitudes from 61oN to 54oS. Journal of Invertebrate Pathology, Orlando, v.78, p.98-108, 2001b.
BROOME, J.R.; SIKOROWSKI, P.P.; NELL, W.W. Effect of sunlight on the activity of Nuclear Polyhedrosis virus from Malacossoma disstria Journal of Economic Entomology, Lanham, v.67, n.1, p.135-136, 1974.
CAGAN, L; SVERCEL, M. The influence of ultraviolet light on pathogenicity of entomopathogenic fungus Beauveria bassiana (Balsamo) Vuillemin to the European corn borer, Ostrinia nubilalis HBN. (Lepidoptera: Crambidae). Journal of Central European Agriculture, Croácia, v.2, n.4, p.19-125, 2001.
CORRÊA, G.S. Influência da radiação ultravioleta e solar na viabilidade de conídios de Metarhizium anisopliae (Metsch) Sorokin 1983. 84p. Dissertação (Mestrado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1983.
FARGUES, J.; GOETTEL, M.S.; SMITS, N.; OUEDRAOGO, A.; VIDAL, C.; LACEY, L.A.; LOMER, C.J.; ROUGIER, M. Variability in susceptibility to simulated sunlight of conidia among isolates of entomopathogenic hyphomycetes. Mycopathologia, Holanda, v.135, p.171-181, 1996.
GOETTEL, M.S.; INGLIS, G.D.; WRAIGHT, S.P. Fungi. In: Lacey, L. A.; Kaya, H. K. (Eds.) Field manual of techniques in invertebrate pathology. Dordrecht: Kluver Academic Publishers, 2000. p.255-282.
GRIEGO, V.M.; MARTIGNONI, M.E.; CLAYCOMB, A.E. Inactivation of nuclear polyhedrosis virus (Baculovirus subgroup A) by monochromatic UV radiation. Applied and Environmental Microbiology, Washington, v.49, n.3, p.709-710, 1985.
IGNOFFO, C.M.; BATZER, O.F. Microencapsulation and ultraviolet protectants to increase sunlight stability of an insect virus. Journal of Economic Entomology, Lanham, v.64, n.1, p.850-853, 1971.
JACKSON, M.A. Optimizing nutritional conditions for the liquid culture production of effective fungal biological control agents. Journal of Industrial Microbiology and Biotechnology, Houndmills, v.19, p.180-187, 1997.
JACKSON, M.A.; SCHISLER, D.A.; SLININGER, P.J.; BOYETTE, C.D.; SILMAN, R.W.; BOTHAST, R.J. Fermentation strategies for improving the fitness of a bioherbicide. Weed Technology, Kansas, v.10, p.645-650, 1996.
JAQUES, R.P. Stability of insect viruses in the environment. In: MARAMOROSCH, K.; SHERMAN, K.E. (Eds.). Viral Insecticides for Biological Control Orlando: Academic Press, 1985. p 285-360.
LEACH, C.M. Ultraviolet-absorbing substances associated with light-induced sporulation in fungi. Canadian Journal of Botany, Ottawa, v.43, p.185-200, 1965.
LEITE, L.G.; BATISTA FILHO, A.; ALMEIDA, J.E.M.; ALVES, S.B. Produção de fungos entomopatogênicos Ribeirão Preto: Alexandre de Sene Pinto, 2003. 92p.
NICHOLSON, W.L.; MUNAKATA, N.; HORNECK, G.; MELOSH, H.J.; SETLOW, P. Resistence of Bacillus endospores to extreme terrestrial and extraterrestrial environments. Microbiology and Molecular Biology Reviews, Washington, v.64, n.3, p.548-572, 2000.
OLIVEIRA, S.M.C. Exigências físicas e nutricionais para produção de Sporothrix insectorum em meio líquido. 2000. 45p. Dissertação (Mestrado – Microbiologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2000.
SANO, A.H. Dosagens de extrato de levedura e glicose para produção de Metarhizium anisopliae em meio líquido. 2005. 42p. Dissertação (Mestrado – Entomologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2005.
SANTOS, A.L.L. Influência de alguns fatores no crescimento, germinação e produção de conídios de Metarhizium anisopliae (Metsch.) Sorokin. 1978. 148p. Dissertação (Mestrado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1978.
TANZINI, M.R. Controle do percevejo-de-renda-da-seringueira (Leptopharsa heveae) com fungos entomopatogênicos. 2002. 140p. Tese (Doutorado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 2005.
TORRE, M.; CÁRDENAS-COTA, H.M. Production of Paecilomyces fumosoroseus conidia in submerged culture. Entomophaga, Paris, v.41, p.443-453, 1996.
WALSTAD, J.D.; ANDERSON, R.F.; STAMBAUGH, W.J. Effects of environmentalconditions on two species of muscardine fungi (Beauveria bassiana and Metarhiziumanisopliae). Journal of Invertebrate Pathology, Orlando, v.16, p.221-226, 1970.
ZIMMERMANN, G. Effect of high temperatures and artificial sunlight on the viability of conidia of Metarhizium anisopliae Journal of Invertebrate Pathology, Orlando, v.40, n.1, p.36-40, 1982.

Publication Dates

Publication in this collection
2014

History

Received
27 Dec 2012
Accepted
29 Sept 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ALI, S.; SIKOROWSKI, P.P. Effects of sunlight, cotton foliage surface, and temperature on the infectivity of citoplasmatic polyhedrosis virus to Heliothis virescens larvae (Lepidoptera: Noctuidae). Journal of Economic Entomology, Lanham, v.79, n.2, p. 364-367, 1986.

[2] ALVES, S.B. Epizootiologia. In: Alves, S. B. (Ed.). Controle microbiano de insetos. Manole: São Paulo, 1986, p. 29-60.

[3] ALVES, S.B. Caracterização, padronização e produção do Metarhizium anisopliae (Metsch.) Sorok. 1982. 95p. Tese (Doutorado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1982.

[4] BASTOS, C.N.; MATTA, E.A.F. Influência das temperaturas e luz na esporulação do fungo Metarhizium anisopliae (Metsch.) Sorokin. Boletim do Instituto Biológico da Bahia, Salvador, v.15, n.1, p.5-8, 1976.

[5] BOUCIAS, D.G.; JOHNSON, D.W.; ALLEN, G.E. Effects of host age, virus dosage, and temperature on the infectivity of a nucleopolyhedrosis virus against velvetbean caterpillar, Anticarsia gemmatalis, larvae. Environmental Entomology, v.9, p.59-61, 1980.

[6] BRAGA, G.U.L.; FLINT, S.D.; MESSIAS, C.L.; ANDERSON, A.J.; ROBERTS, D.W. Effects of UV-B irradiance on conidia and germinants of the entomopathogenic hyphomycete Metarhizium anisopliae: a study of reciprocity and recovery. Photochemistry and Photobiology, v.72, p.140-146, 2001a.

[7] BRAGA, G.U.L.; FLINT, S.D.; MILLER, C.D.; ANDERSON, A.J.; ROBERTS, D.W. Variability in response to UV-B among species and strains of Metarhizium isolated from sites at latitudes from 61oN to 54oS. Journal of Invertebrate Pathology, Orlando, v.78, p.98-108, 2001b.

[8] BROOME, J.R.; SIKOROWSKI, P.P.; NELL, W.W. Effect of sunlight on the activity of Nuclear Polyhedrosis virus from Malacossoma disstria Journal of Economic Entomology, Lanham, v.67, n.1, p.135-136, 1974.

[9] CAGAN, L; SVERCEL, M. The influence of ultraviolet light on pathogenicity of entomopathogenic fungus Beauveria bassiana (Balsamo) Vuillemin to the European corn borer, Ostrinia nubilalis HBN. (Lepidoptera: Crambidae). Journal of Central European Agriculture, Croácia, v.2, n.4, p.19-125, 2001.

[10] CORRÊA, G.S. Influência da radiação ultravioleta e solar na viabilidade de conídios de Metarhizium anisopliae (Metsch) Sorokin 1983. 84p. Dissertação (Mestrado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1983.

[11] FARGUES, J.; GOETTEL, M.S.; SMITS, N.; OUEDRAOGO, A.; VIDAL, C.; LACEY, L.A.; LOMER, C.J.; ROUGIER, M. Variability in susceptibility to simulated sunlight of conidia among isolates of entomopathogenic hyphomycetes. Mycopathologia, Holanda, v.135, p.171-181, 1996.

[12] GOETTEL, M.S.; INGLIS, G.D.; WRAIGHT, S.P. Fungi. In: Lacey, L. A.; Kaya, H. K. (Eds.) Field manual of techniques in invertebrate pathology. Dordrecht: Kluver Academic Publishers, 2000. p.255-282.

[13] GRIEGO, V.M.; MARTIGNONI, M.E.; CLAYCOMB, A.E. Inactivation of nuclear polyhedrosis virus (Baculovirus subgroup A) by monochromatic UV radiation. Applied and Environmental Microbiology, Washington, v.49, n.3, p.709-710, 1985.

[14] IGNOFFO, C.M.; BATZER, O.F. Microencapsulation and ultraviolet protectants to increase sunlight stability of an insect virus. Journal of Economic Entomology, Lanham, v.64, n.1, p.850-853, 1971.

[15] JACKSON, M.A. Optimizing nutritional conditions for the liquid culture production of effective fungal biological control agents. Journal of Industrial Microbiology and Biotechnology, Houndmills, v.19, p.180-187, 1997.

[16] JACKSON, M.A.; SCHISLER, D.A.; SLININGER, P.J.; BOYETTE, C.D.; SILMAN, R.W.; BOTHAST, R.J. Fermentation strategies for improving the fitness of a bioherbicide. Weed Technology, Kansas, v.10, p.645-650, 1996.

[17] JAQUES, R.P. Stability of insect viruses in the environment. In: MARAMOROSCH, K.; SHERMAN, K.E. (Eds.). Viral Insecticides for Biological Control Orlando: Academic Press, 1985. p 285-360.

[18] LEACH, C.M. Ultraviolet-absorbing substances associated with light-induced sporulation in fungi. Canadian Journal of Botany, Ottawa, v.43, p.185-200, 1965.

[19] LEITE, L.G.; BATISTA FILHO, A.; ALMEIDA, J.E.M.; ALVES, S.B. Produção de fungos entomopatogênicos Ribeirão Preto: Alexandre de Sene Pinto, 2003. 92p.

[20] NICHOLSON, W.L.; MUNAKATA, N.; HORNECK, G.; MELOSH, H.J.; SETLOW, P. Resistence of Bacillus endospores to extreme terrestrial and extraterrestrial environments. Microbiology and Molecular Biology Reviews, Washington, v.64, n.3, p.548-572, 2000.

[21] OLIVEIRA, S.M.C. Exigências físicas e nutricionais para produção de Sporothrix insectorum em meio líquido. 2000. 45p. Dissertação (Mestrado – Microbiologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2000.

[22] SANO, A.H. Dosagens de extrato de levedura e glicose para produção de Metarhizium anisopliae em meio líquido. 2005. 42p. Dissertação (Mestrado – Entomologia) – Faculdade de Ciências Agrárias e Veterinárias, Universidade Estadual Paulista, Jaboticabal, 2005.

[23] SANTOS, A.L.L. Influência de alguns fatores no crescimento, germinação e produção de conídios de Metarhizium anisopliae (Metsch.) Sorokin. 1978. 148p. Dissertação (Mestrado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 1978.

[24] TANZINI, M.R. Controle do percevejo-de-renda-da-seringueira (Leptopharsa heveae) com fungos entomopatogênicos. 2002. 140p. Tese (Doutorado – Entomologia) – Escola Superior de Agricultura “Luiz de Queiroz", Universidade de São Paulo, Piracicaba, 2005.

[25] TORRE, M.; CÁRDENAS-COTA, H.M. Production of Paecilomyces fumosoroseus conidia in submerged culture. Entomophaga, Paris, v.41, p.443-453, 1996.

[26] WALSTAD, J.D.; ANDERSON, R.F.; STAMBAUGH, W.J. Effects of environmentalconditions on two species of muscardine fungi (Beauveria bassiana and Metarhiziumanisopliae). Journal of Invertebrate Pathology, Orlando, v.16, p.221-226, 1970.

[27] ZIMMERMANN, G. Effect of high temperatures and artificial sunlight on the viability of conidia of Metarhizium anisopliae Journal of Invertebrate Pathology, Orlando, v.40, n.1, p.36-40, 1982.

Treatment (40% C + 7,31% N)		C source (g)	N source (g)
Treatment (40% C + 7,31% N)		D-glucose anhydrous	Brewer's yeast
1	16.00 g of C + 6.30 g of N	40.00	86.13
2	16.00 g of C + 7.00 g of N	40.00	95.70
3	16.00 g of C + 7.69 g of N	40.00	105.27
Treatment (42,11% C + 7,31% N)		C source (g)	N source (g)
Treatment (42,11% C + 7,31% N)		Sucrose	Brewer's yeast
4	20.00 g of C + 6.30 g of N	47.50	86.13
5	20.00 g of C + 7.00 g of N	47.50	95.70
6	20.00 g of C + 7.69 g of N	47.50	105.27
Treatment (40% C + 7,31% N)		C source (g)	N source (g)
Treatment (40% C + 7,31% N)		D-glycose anhydrous	Brewer's yeast
7	14.40 g of C + 7.00 g of N	36.00	95.70
8	16.00 g of C + 7.00 g of N	40.00	95.70
9	17.60 g of C +7.00 g of N	44.00	95.70
Treatment (42,11% C +7,31% N)		C source (g)	N source (g)
Treatment (42,11% C +7,31% N)		Sucrose	Brewer's yeast
10	18.00 g of C + 7.00 g of N	42.75	95.70
11	20.00 g of C + 7.00 g of N	47.50	95.70
12	22.00 g of C + 7.00 g of N	52.25	95.70

Treatment (g)	Average concentration (× 10⁸ blastospores/mL^-1)
Treatment (g)	4^th day	6^th day	8^th day	S (3 evaluations)	F test	CV (%)
16.00 C + 6.30 N	1.16 A a¹ 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	1.18 A a	1.31 A a	3.65	2.40^ns ns not significant at 5% of probability by F test;	13.42
16.00 C + 7.00 N	1.21 A b	1.22 A b	1.48 A a	3.91	9.45^* * significant at 5% of probability by F test;	11.75
16.00 C + 7.69 N	1.11 A b	1.19 A ab	1.29 A a	3.59	6.54^* * significant at 5% of probability by F test;	10.21
20.00 C + 6.30 N	1.19 A a	1.15 A ab	1.01 B b	3.35	5.65^* * significant at 5% of probability by F test;	8.65
20.00 C + 7.00 N	1.21 A a	1.16 A a	1.05 B a	3.42	1.90^ns ns not significant at 5% of probability by F test;	22.80
20.00 C + 7.69 N	1.22 A a	1.13 A ab	1.00 B b	3.35	7.50^* * significant at 5% of probability by F test;	8.67
F test	0.83^ns ns not significant at 5% of probability by F test;	0.96^ns ns not significant at 5% of probability by F test;	14.49^* * significant at 5% of probability by F test;	–	–	–
CV (%)	10.04	18.27	10.70	–	–	–
Standard error of the mean	0.0485	0.0886	0.0520	–	–	–
Treatment (g)	Average concentration (× 10⁸ blastospores/mL)
Treatment (g)	4^th day	6^th day	8^th day	S (3 evaluations)	F test	CV (%)
14.40 C + 7,00 N	1.58 A a¹ 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	1.55 A a	1.49 A a	4.62	0.36^ns ns not significant at 5% of probability by F test;	12.50
16.00 C + 7,00 N	1.30 A a	1.37 A a	1.51 A a	4.18	1.57^ns ns not significant at 5% of probability by F test;	15.13
17.60 C + 7,00 N	1.44 A a	1.51 A a	1.55 A a	4.50	0.20^ns ns not significant at 5% of probability by F test;	20.47
18.00 C + 7,00 N	1.31 A b	1.45 A ab	1.55 A a	4.31	4.03^* * significant at 5% of probability by F test;	10.18
20.00 C + 7,00 N	1.42 A a	1.44 A a	1.54 A a	4.40	1.03^ns ns not significant at 5% of probability by F test;	10.11
22.00 C + 7,00 N	1.44 A a	1.41 A a	1.38 A a	4.23	0.12^ns ns not significant at 5% of probability by F test;	14.37
F test	0.74^ns ns not significant at 5% of probability by F test;	0.89^ns ns not significant at 5% of probability by F test;	1.36^ns ns not significant at 5% of probability by F test;	–	–	–
CV (%)	18.86	9.96	12.86	–	–	–
Standard error of the mean	0.1112	0.0611	0.0752	–	–	–

Treatment (g)	Average concentration (× 10⁸ blastospores/mL)
Treatment (g)	4^th day	6^th day	8^th day	S (3 evaluations)	F test	CV (%)
16.00 C + 6.30 N	1.4 A a¹ 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	1.00 B b	0.87 C b	3.31	25.47^* * significant at 5% of probability by F test;	12.11
16.00 C + 7.00 N	1.29 A a	0.98 B b	0.81 C c	3.08	26.21^* 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	11.74
16.00 C + 7.69 N	1.24 A a	1.04 B b	0.89 C c	3.17	15.46^* 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	11.15
20.00 C + 6.30 N	1.36 A a	1.43 A a	1.74 A a	4.53	1.56^ns ns not significant at 5% of probability by F test;	26.24
20.00 C + 7.00 N	1.13 A b	1.16 BC b	1.52 A a	3.81	8.99^* * significant at 5% of probability by F test;	13.31
20.00 C + 7.69 N	1.20 A b	1.48 A a	1.48 AB a	4.16	6.46^* * significant at 5% of probability by F test;	9.92
F test	1.99^ns ns not significant at 5% of probability by F test;	20.30^* * significant at 5% of probability by F test;	12.86^* * significant at 5% of probability by F test;	–	–	–
CV (%)	14.58	11.30	22.06	–	–	–
Standard error of the mean	0.0763	0.0573	0.1057	–	–	–
Treatment (g)	Average concentration (× 10⁸ blastospores/mL)
Treatment (g)	4^th day	6^th day	8^th day	S (3 evaluations)	F test	CV (%)
14.40 C + 7.00 N	1.18 A a¹ 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	1.19 A a	1.21 AB a	3.58	0.22^ns ns not significant at 5% of probability by F test;	12.67
16.00 C + 7.00 N	1.23 A a	1.29 A a	1.16 B a	3.68	0.22^ns ns not significant at 5% of probability by F test;	13.51
17.60 C + 7.00 N	1.17 A a	1.22 A a	1.22 AB a	3.61	0.19^ns ns not significant at 5% of probability by F test;	12.15
18.00 C + 7.00 N	1.21 A a	1.24 A a	1.25 AB a	3.70	0.48^ns ns not significant at 5% of probability by F test;	7.64
20.00 C + 7.00 N	1.18 A b	1.30 A ab	1.46 A a	3.94	9.67^* * significant at 5% of probability by F test;	8.56
22.00 C + 7.00 N	1.12 A b	1.13 A a	1.13 B b	3.38	11.82^* * significant at 5% of probability by F test;	7.82
F test	0.91^ns ns not significant at 5% of probability by F test;	2.08^ns ns not significant at 5% of probability by F test;	3.30^* * significant at 5% of probability by F test;	–	–	–
CV (%)	9.08	10.32	13.10	–	–	–
Standard error of the mean	0.0440	0.0531	0.0657	–	–	–

Treatments (g)	Average concentration (× 10⁸ blastospores/mL)
	Metarhizium anisopliae					Beauveria bassiana
	4^th day	6^th day	8^th day	F test	CV (%)	4^th day	6^th day	8^th day	F test	CV (%)
2 16.00 C + 7.00 N	1.45 A a¹ 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	1.47 A a	1.50 A a	0.67^ns ns not significant at 5% of probability by F test;	10.31	–	–	–	–	–
7 14.40 C + 7.00 N	1.54 A a	1.43 A a	1.38 A a	1.31^ns ns not significant at 5% of probability by F test;	12.88	–	–	–	–	–
4 20.00 C + 6.30 N	–	–	–	–		1.34 B a	1.57 A a	1.59 A a	3.57^ns ns not significant at 5% of probability by F test;	12.08
11 20.00 C + 7.00 N	–	–	–	–		1.56 A a	1.59 A a	1.60 A a	0.54^ns ns not significant at 5% of probability by F test;	9.97
F test	0.72^ns ns not significant at 5% of probability by F test;	0.30^ns ns not significant at 5% of probability by F test;	0.11^ns ns not significant at 5% of probability by F test;	–		9.09^* * significant at 5% of probability by F test;	0.04^ns ns not significant at 5% of probability by F test;	0.62^ns ns not significant at 5% of probability by F test;	–	–
CV (%)	10.25	14.32	9.34	–		8.98	10.62	12.94	–	–
Standard error of the mean	0.0631	0.0882	0.0575	–		0.0566	0.0670	0.0816	–	–

Treatments (g)	Number of colonies (0.1 mL/ Petri's plate)
	M. anisopliae					B. bassiana
	Without exposure	25 s	50 s	F test	CV (%)	Without exposure	25 s	50 s	F test	CV (%)
2 16.00 C + 7.00 N	11.13 A a¹ 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	6.27 A b	1.11 A c	358.30^* * significant at 5% of probability by F test;	10.49	–	–	–	–	–
7 14.40 C + 7.00 N	10.64 A a	6.39 A b	1.31 A c	151.74^* * significant at 5% of probability by F test;	15.18	–	–	–	–	–
4 20.00 C + 6.30 N	–	–	–	–		10.55 A a	5.36 A b	1.95 A c	295.54^* * significant at 5% of probability by F test;	10.36
11 20.00 C + 7.00 N	–	–	–	–		10.89 A a	6.13 A b	1.83 A c	235.77^* * significant at 5% of probability by F test;	11.51
F test	1.14^ns ns not significant at 5% of probability by F test;	0.04^ns ns not significant at 5% of probability by F test;	0.83^ns ns not significant at 5% of probability by F test;	–		0.47^ns ns not significant at 5% of probability by F test;	4.36^ns ns not significant at 5% of probability by F test;	0.20^ns ns not significant at 5% of probability by F test;	–	–
CV (%)	7.33	17.06	29.51	–		8.02	11.04	24.48	–	–
Standard error of the mean	0.3259	0.4410	0.1505	–		0.3510	0.2591	0.1888	–	–

Brasil

Brasil

Liquid production of entomopathogenic fungi and ultraviolet radiation and temperature effects on produced propagules

Produção líquida de fungos entomopatogênicos e efeitos da radiação ultravioleta e da temperatura sobre os propágulos produzidos

Abstracts

INTRODUCTION

MATERIAL AND METHODS

Concentration of blastospores

The counting of colonies

Ultraviolet

Temperature

Virulence to D. saccharalis

Statistical analysis

RESULTS AND DISCUSSION

Production in net medium of M. anisopliae and B. bassiana

The counting of colonies

Ultraviolet

Temperature

Virulence to D. saccharalis

CONCLUSIONS

REFERENCES

Publication Dates

History

Treatment (g) M. anisopliae	Temperature
Treatment (g) M. anisopliae	20°	25°	30°	35°	F test	CV (%)
2 16.00 C + 7.00 N	8.87 A b	11.13 A a	10.19 A a	0.88 A c	237.87^* * significant at 5% of probability by F test;	9.58
7 14.40 C + 7.00 N	8.57 A b	10.64 A a	10.08 A a	0.79 A c	367.82^* * significant at 5% of probability by F test;	7.76
F test	0.67^ns ns not significant at 5% of probability by F test;	1.14^ns ns not significant at 5% of probability by F test;	0.05^ns ns not significant at 5% of probability by F test;	0.38^ns ns not significant at 5% of probability by F test;	–	–
CV (%)	7.26	7.33	8.21	28.80	–	–
Standard error of the mean	0.2584	0.3259	0.3397	0.0984	–	–
Treatment (g) B. bassiana	Temperature
Treatment (g) B. bassiana	20°	25°	30°	35°	F test	CV (%)
4 20.00 C + 6.30 N	8.11 A b¹ 1 capital letters for comparing averages between columns and lowercase ones for comparing averages between lines;	10.55 A a	8.90 A b	0.97 A c	245.26^* * significant at 5% of probability by F test;	9,53
11 20.00 C + 7,00 N	7.93 A c	10.89 A a	9.69 A b	0.71 B d	250.16^* * significant at 5% of probability by F test;	9.67
F test	0.14^ns ns not significant at 5% of probability by F test;	0.47^ns ns not significant at 5% of probability by F test;	4.09^ns ns not significant at 5% of probability by F test;	5.00^* * significant at 5% of probability by F test;	–	–
CV (%)	10.42	8.02	7.23	23.97	–	–
Standard error of the mean	0.3413	0.3510	0.2741	0.4851	–	–