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PCR and bioassays screening of Bacillus thuringiensis isolates from rice-fields of Rio Grande do Sul, specific to lepidopterans and coleopterans

PCR e bioensaios para triagem de isolados de Bacillus thuringiensis, proveninentes de áreas orizícolas do Rio Grande do Sul, específicos para lepidópteros e coleópteros

Abstracts

Bacillus thuringiensis (Bt) isolates from soil samples of rice-fields in Rio Grande do Sul (RS) were tested through PCR, aiming at the screening of six groups of Bt cry genes, which codify active proteins for coleopterans and lepidopterans rice pests, and their bioinsecticide potential regarding their use in IPM system, as well. Forty six Bt isolates were grown in Agar Nutrient for 12 h and submitted to total DNA extraction. The amplified fragments were analyzed in agarose gel (1-1.5%). The screening isolates showed that 56.51% were potentially lepidopterans specific (cry1, cry2 and cry9) and 21.73% were coleopteran specific (cry3 and cry7/8), with a homogeneous distribution in the rice-field areas in Rio Grande do Sul. Cry2 genes were found just once and in the Litoral area. Bioassays against Spodoptera frugiperda larvae showed the highest corrected mortality (25%) with Bt 2027-1 isolate selected by the presence of cry9 genes. The toxicity bioassays carried out with S. frugiperda using purified proteins of Bt aizawai HD68 indicated a LD50 of 0.95 µg/larvae. Two Bt isolates carrying the cry3 genes (PCR detection) caused a 100% mortality to Oryzophagus oryzae larvae. Bioassay results confirmed the prediction of Bt activity by PCR, which must have a straight relationship with the cry genes that codify those specific insecticidal proteins.

Bacillus thuringiensis; PCR; bioassay; Lepidoptera; Coleoptera


Visando a seleção de seis grupos de genes cry de Bacillus thuringiensis (Bt), que codificam proteínas ativas para coleópteros e lepidópteros pragas do arroz, 46 isolados de Bt provenientes de amostras de solos das regiões orizícolas do Rio Grande do Sul (RS), foram testados por PCR. Os isolados de Bt foram crescidos em Ágar Nutriente durante 12 h e submetidos a extração de DNA total. Os fragmentos amplificados foram analisados em géis de agarose (1-1,5%). Os resultados referentes ao total de isolados selecionados mostraram que 56,51% foram potencialmente específicos a lepidópteros (cry1, cry2 e cry9) e 21,73% a coleópteros (cry3 e cry7/8), tendo sua distribuição homogênea entre as regiões orizícolas do RS. Apenas os genes cry2 foram localizados somente na região Litoral. Nos bioensaios com lagartas de Spodoptera frugiperda o isolado Bt 2027-1 obteve a maior mortalidade corrigida (25%), o qual havia sido pré-selecionado pela presença de genes cry9. Para a mesma espécie, os testes de toxicidade através de proteínas purificadas de Bt aizawai HD68 revelaram uma DL50 de 0,95 mg/larva. Dois isolados de Bt causaram 100% de mortalidade às larvas de Oryzophagus oryzae, tendo esses sido pré-selecionados pela presença de genes cry3. Os resultados dos bioensaios confirmam a predição da atividade de Bt por PCR, a qual deve estar diretamente relacionada aos genes cry que codificam as proteínas inseticidas específicas.

Bacillus thuringiensis; PCR; bioensaios; Lepidoptera; Coleoptera


ENVIRONMENTAL AND SOIL

PCR and bioassays screening of Bacillus thuringiensis isolates from rice-fields of Rio Grande do Sul, specific to lepidopterans and coleopterans

PCR e bioensaios para triagem de isolados de Bacillus thuringiensis, proveninentes de áreas orizícolas do Rio Grande do Sul, específicos para lepidópteros e coleópteros

Laura Massochin Nunes PintoI, * * Corresponding author: Mailing address: Laboratório de Microbiologia, Centro 2, Universidade do Vale do Rio dos Sinos. Caixa Postal 275. 93001-970, São Leopoldo, RS, Brasil. Tel.: (+5551) 590-8122. E-mail: lau@pro.via-rs.com.br. ; Lidia Mariana FiuzaI, II

ILaboratório de Microbiologia, Universidade do Vale do Rio dos Sinos, São Leopoldo, RS, Brasil

IIEstação Experimental do Arroz, Instituto Riograndense do Arroz, Cachoeirinha, RS, Brasil

ABSTRACT

Bacillus thuringiensis (Bt) isolates from soil samples of rice-fields in Rio Grande do Sul (RS) were tested through PCR, aiming at the screening of six groups of Bt cry genes, which codify active proteins for coleopterans and lepidopterans rice pests, and their bioinsecticide potential regarding their use in IPM system, as well. Forty six Bt isolates were grown in Agar Nutrient for 12 h and submitted to total DNA extraction. The amplified fragments were analyzed in agarose gel (1-1.5%). The screening isolates showed that 56.51% were potentially lepidopterans specific (cry1, cry2 and cry9) and 21.73% were coleopteran specific (cry3 and cry7/8), with a homogeneous distribution in the rice-field areas in Rio Grande do Sul. Cry2 genes were found just once and in the Litoral area. Bioassays against Spodoptera frugiperda larvae showed the highest corrected mortality (25%) with Bt 2027-1 isolate selected by the presence of cry9 genes. The toxicity bioassays carried out with S. frugiperda using purified proteins of Bt aizawai HD68 indicated a LD50 of 0.95 µg/larvae. Two Bt isolates carrying the cry3 genes (PCR detection) caused a 100% mortality to Oryzophagus oryzae larvae. Bioassay results confirmed the prediction of Bt activity by PCR, which must have a straight relationship with the cry genes that codify those specific insecticidal proteins.

Key words:Bacillus thuringiensis, PCR, bioassay, Lepidoptera, Coleoptera.

RESUMO

Visando a seleção de seis grupos de genes cry de Bacillus thuringiensis (Bt), que codificam proteínas ativas para coleópteros e lepidópteros pragas do arroz, 46 isolados de Bt provenientes de amostras de solos das regiões orizícolas do Rio Grande do Sul (RS), foram testados por PCR. Os isolados de Bt foram crescidos em Ágar Nutriente durante 12 h e submetidos a extração de DNA total. Os fragmentos amplificados foram analisados em géis de agarose (1-1,5%). Os resultados referentes ao total de isolados selecionados mostraram que 56,51% foram potencialmente específicos a lepidópteros (cry1, cry2 e cry9) e 21,73% a coleópteros (cry3 e cry7/8), tendo sua distribuição homogênea entre as regiões orizícolas do RS. Apenas os genes cry2 foram localizados somente na região Litoral. Nos bioensaios com lagartas de Spodoptera frugiperda o isolado Bt 2027-1 obteve a maior mortalidade corrigida (25%), o qual havia sido pré-selecionado pela presença de genes cry9. Para a mesma espécie, os testes de toxicidade através de proteínas purificadas de Bt aizawai HD68 revelaram uma DL50 de 0,95 mg/larva. Dois isolados de Bt causaram 100% de mortalidade às larvas de Oryzophagus oryzae, tendo esses sido pré-selecionados pela presença de genes cry3. Os resultados dos bioensaios confirmam a predição da atividade de Bt por PCR, a qual deve estar diretamente relacionada aos genes cry que codificam as proteínas inseticidas específicas.

Palavras-chave:Bacillus thuringiensis, PCR, bioensaios, Lepidoptera, Coleoptera.

INTRODUCTION

Nowadays, due to risks to the man and the ecosystem, several studies are seeking to decrease chemicals usage against agricultural insect pests (19). Thus, the microbial control represents an alternative in the Integrated Pest Management (IPM), with low environmental impact. Among the entomopathogenic microorganisms the Bacillus thuringiensis (Bt) bacterium stands out. It produces parasporal bodies, also called crystals, composed by insecticide proteins which are coded by cry genes (17).

Screening of the cry genes was done through Polimerase Chain Reaction (PCR), which is a powerful tool for the identification of specific insecticidal genes from new Bt isolates (15,18,23).

The irrigated rice fields in Southern Brazil have great economic importance, but they have had losses by insect attacks, mainly Lepidoptera and Coleoptera orders (9,10,14). Among the coleopterans, Oryzophagus oryzae is considered the most important rice pest, because it is endophytic and difficult to control. These insect pests can cause yield decrease from 10 to 30% (22). Of the Lepidoptera order, the Spodoptera frugiperda larvae cause great damage, from the emergency of plants until the flooding of fields (27).

The aim of this work was to screening the Bt isolates carrying cry genes that code active delta-endotoxins for coleopterans and lepidopterans that are harmful to rice plants grown in the field. The bioinsecticide potential of the isolates regarding their use in IPM system was also evaluated.

MATERIALS AND METHODS

Bacillus thuringiensis isolates

46 Bt isolates from soil samples collected in irrigated rice areas of Rio Grande do Sul (RS) were used in this study. These isolates belong to the bacterial entomopathogenic collection of the UNISINOS Microbiology Laboratory and the IRGA (Instituto Riograndense do Arroz). The International Entomopathogenic Bacillus Center (Institute Pasteur, Paris) and the Bacillus Genetic Stock Center (Columbus, Ohio) kindly supplied Bt tenebrionis and Bt aizawai used as positive controls.

PCR analysis

The Bt isolates were cultivated for 12h at 30ºC in nutrient agar (OXOID, UK). Next, the isolates were submitted to total DNA extraction according to the method described by Hansen and Hendriksen (16). Six pairs of universal primers designed by Ben-Dov et al. (5,6) (cry1, cry2, cry3, cry7/8 and cry9) and Bravo et al. (8) (cry9). The cry1, cry2 and cry9 primers identify genes that code insecticide proteins against Lepidoptera, and the cry3, cry7/8 and cry8 primers against Coleoptera. Each reaction of PCR was run with a final volume of 25 µL with 1 µL of DNA template mixed with reaction buffer, 0.2 mM of each dNTP, 0.2 at 0.5 mM of each primer and 0.5 U of Taq DNA polimerase (GIBCO, BRL). Amplification was done in a DNA termocycler (PTC-100, MJ Research, Inc.) regulated for 35 reaction cycles each. All DNA templates were denatured for 1 min at 94ºC, annealed to the primers for 40-50 s at 60ºC, and extended (PCR) for 50-90 s at 72ºC. Bt strains were used as positive control and reactions with no addition of DNA as negative controls. Amplified PCR products were analyzed in agarose gel (1-1.5%) and compared with the 100 bp molecular marker (GIBCO, BRL).

Insects

2nd instar larvae of S. frugiperda were obtained from colonies grown in the insect's chamber of the Center 2/UNISINOS, maintained at 25 ± 2ºC, 80% Relative Humidity (RH) and for a 12-hour photoperiod. O. oryzae larvae were collected between October/2000 to May/2001, from roots obtained from rice fields at EEA-IRGA (Cachoeirinha, RS).

Bioassays

The bioassays were conducted in Biological Oxygen Demand (B.O.D.) chambers, at 25 ± 2ºC, 80% RH and for a 12-hour photoperiod. The bacterial isolates were grown in Usual Glicosed Medium (12) at 28ºC and 180 rpm for 48 h. Cultures were centrifuged at 4.500 rpm for 15 min and the supernatant was discarded. The pellet was suspended in sterile distilled water. The bacterial concentration was determined with a Neubauer chamber and an optical microscope. All bioassay data were corrected by the Abbott's formula (1).

Spodoptera frugiperda

The isolates showing PCR products corresponding to cry1, cry2 and cry9 genes were tested in vivo against S. frugiperda. The culture corresponding to 1 x 109 cells/mL was added to the Bowling diet (4), previously organized in mini-plates (30 mm of diameter), where 20 larvae of 2nd instar were individualized for each isolate. In the control group, the culture was substituted by sterile distilled water. Mortality was observed until de 7th day after treatment application. Bt aizawai HD68 strain was used as positive control in bioassays (21) and its toxicity was also determined through the Medium Lethal Dose (LD50) using purified protein by means of the method described by Fiuza et al. (13). Insects were individualized as mentioned above, and the Bowling diet was substituted by disks of fresh corn leaf, where the protein was applied at 0.4, 2.0 concentrations and 10 µg/cm2. In the control group protein was replaced by sterile distilled water. Thirty insects were evaluated and each treatment was repeated three times summing up to 90 insects by treatment. With the READ-COLOR (LI-3100, USA) area meter foliate, the foliate consumption mean was verified for each treatment. Mortality was observed until the seventh day after the application of the treatments. Data were analyzed with the POLO-PC LeOra Software, 1987 (2).

Oryzophagus oryzae

It is an aquatic coleopteran, whose larvae live in the root system of the rice plants. Bioassays were conducted according to the method described by Steffens et al. (24). In the evaluation of the 6 Bt new isolates, that revealed the presence of cry3 or cry7 genes by PCR, each bacterial suspension was added at the final concentration of 8.1010 cells/mL, in assay tubes with two rice plants, and 8 mL of rice fields water. There was no addition of bacterial suspension to the control group. Larval mortality was assessed on day 7 for all treatments. Twenty larvae of 3rd and 4th instars of O. oryzae were evaluated for each treatment.

RESULTS

The PCR amplification analysis of the isolates revealed the presence of amplified fragments characteristic of cry genes when compared to Bt tenebrionis and Bt aizawai strains, used as reference. Results in Fig. 1 show the expected sizes of PCR products of cry1, cry2, cry3, cry7/cry8, and cry9 genes ranging from 147 to 290, 689 to 701, 285 to 769, 420 to 916 and 351 to 354 bp, respectively (5,6,10). Out of all the cry genes investigated, only cry8 genes were not found in our isolates.


Among the 46 new Bt isolates (Fig. 2A) from soil samples of rice field areas in RS cry9 genes were the most frequent ones, followed by cry3 genes, cry1 and cry7 genes equally represented, and cry2 genes with the lowest frequency. A total of 36.95% of Bt isolates were not amplified by the primers used in this work. Most of the cry genes were identified in all rice areas of RS areas (Fig. 2B), however, cry2 genes were only located in the Litoral area.


The 24 isolates carrying the cry1 , cry2 and cry9 genes, known to code active proteins for lepidopterans, were tested in the in vivo bioassay with S. frugiperda larvae. Those isolates showed less insecticide activity than the reference strain, Bt aizawai HD68, that caused 100% mortality at the same concentration (1 x 109 cells/mL). Only 48% of the isolates caused mortality. The cry9 and cry1 genes were detected in 91% and 9% of isolates, respectively (Table 1). Bt 2027-1 isolate, that amplified the cry9 genes, showed the highest mortality (25%) in bioassays with S. frugiperda larvae (Table 1).

Regarding the low activity of the new isolates, the toxicity of the Bt aizawai HD68 purified proteins was carried out through determination of LD50. The results of the Probit's Analysis revealed a LD50 equivalent to 0.95 µg/larvae, with trust intervals from 0.55 to 1.75 at 95% probability.

For the bioassays with the coleopteran O. oryzae, 6 Bt isolates were selected, which amplified DNA fragments by PCR characteristic of cry7 (Fig. 1) and cry3 (Fig. 3) genes, respectively.


Regarding the in vivo bioassay with O. oryzae larvae, the mortality was verified and corrected according to Abbott's formula (1) seven days after treatment application. The 2017-9 and 1610-6 Bt isolates caused 100% mortality of O. oryzae larvae (Table 1). These results revealed the pathogenicity of Bt isolates to O. oryzae larvae by the first time.

DISCUSSION

The 46 isolates analyzed showed great diversity and distribution of cry genes throughout RS areas (Fig. 2B). The cry9 genes were the most frequent ones present in 47.8% of the analyzed isolates. This frequency differed from the one found by Bravo et al. (8) in Mexico that summed up only 2.6% and of Ben-Dov et al. (5) with 10.2%, in Israel, Kazakhstan, and Uzbekistan. The cry1 genes were prevalent in the results obtained by Bravo et al. (8), with 49.5% of presence in the isolates, while in this study the cry1 genes were identified in only 6.5% of the isolates. The cry3 genes reached the second highest frequency in this study - results similar to Bravo et al. (8), who also found a high frequency for these genes (21.7%). The differences among the frequencies obtained in this study and those described by Ben-Dov et al. (5,6) become interesting when compared to each other, due the fact that the primers are identical. These data suggest a difference in the diversity of Bt isolates when geographically compared.

The distribution of the cry genes showed to be homogeneous in the different rice field areas of RS, and only one isolate with cry2 genes from the Litoral area was identified (Fig. 2B).

Due to its high diversity and toxins spectrum of action, Bt has been collected and characterized from worldwide sources (7). Nowadays, several bioassays using Bt isolates have been preceded by molecular characterization, aiming to the identification of cry genes that code specific proteins against several insect species (26). This analysis in vitro of isolates, which precedes in vivo bioassay with insects, showed satisfactory results and stimulated more studies.

In this work, bioassays with S. frugiperda were carried out using the culture of Bt isolates evaluated by PCR. These isolates, positive for cry1, cry2 and cry9 genes showed low insecticide activity. Out of the total tested isolates, 54.1% have not caused mortality to insects (Table 1). These data can be compared to the ones found in Brazil by Valicente (26) that obtained no activity to S. frugiperda by 51.5% of his Bt isolates. This author states that 30.5% of the tested isolates caused up to 20% mortality. These results differed from the present study that identified 95.8% of the isolates with that mortality (Table 1). Valicente et al. (25) using isolates selected by PCR with general primers for cry1 identified that 65.2% had potential to kill 75% of S. frugiperda larvae. The data of the present work differ from Valicente et al. (26), but confirm the results described by Loguercio et al. (20) also in Brazil who tested 60 Bt isolates positive to cry1 genes, of which 52.1% caused up to 10% mortality.

Bioassay results with bacterial culture, as well as with Cry1 and other purified proteins of Bt aizawai HD68, confirm its highly insecticide action against S. frugiperda, corresponding to a LD50 of 0.95µg/larvae. Aranda et al. (3) evaluated Cry1Aa, Cry1Ab, Cry1Ac, Cry1B, and Cry1E delta-endotoxins separatedly for S. Frugiperda, showing LC50 values higher than 2 µg/cm2, even after purification and enzymatic activation. Despite the value obtained in this study higher than the one described by Aranda et al. (3), it should be noticed that the proteins used by these authors had been in vitro activated in to toxic fragments. This process increases the delta-endotoxins activity and toxicity and reduces its losses in the midgut of the insect (28).

A bioassay method was adapted with the Bt culture from the experiment carried out by Steffens et al. (24), which demonstrated that the larvae ingest the water where they are submerged. The Bt bioassay with O. oryzae showed highly satisfactory results considering that there was no available data about that entomopathogen against this insect pest. The new Bt isolates evaluated in the present work caused from 53.4 to 100% mortality. These results confirm the prediction of Bt isolates activity by PCR (Fig. 3), possibly due to the presence of cry3 and cry7 genes, which code delta endotoxins specific to coleopterans (17). Other bioassays against O. oryzae will be conducted with the isolates that were positive in PCR but have not been tested in vivo yet, because that species only occurs during the irrigated rice crop and it does not multiply itself under laboratory conditions. Thus, 6 isolates were tested in this study, corresponding to the field insect availability during the 2000/01 and 20002/02 crops.

Our screening identified new Bt isolates that can be available in experimental fields, and subsequently used in biopesticide formulation; as for the identified cry genes, they can be used in plants resistant to O. oryzae and S. frugiperda larvae, through genetic engineering of plants. These new isolates may be used as potential entomopathogens in biological control and applied to the Integrated Pest Management of rice culture.

ACKNOWLEDGEMENTS

This work was supported by EEA/IRGA and UNISINOS. Authors thanks to IRGA researches, especially to Jaime V. de Oliveira and to the research group from UNISINOS.

Submitted: August 02, 2002; Returned to Authors for corrections: January 13, 2003; Approved: October 01, 2003

  • 1. Abbott, W.S. A method of computing the effectiveness insecticide. J. Econ. Entomol., 18:265-267, 1925.
  • 2. Alves, S.B. Controle Microbiano de Insetos 2. ed. Piracicaba. FEALQ, 1998, 1163p.
  • 3. Aranda, E.; Sanchez, J.; Peferoen, M.; Güereca, L.; Bravo, A. Interactions of Bacillus thuringiensis crystal proteins with the midgut epithelial cells of Spodoptera frugiperda (Lepidoptera: Noctuidae). J. Invertebr. Pathol., 68:203-212, 1996.
  • 4. Bowling, C.C. Rearing of two lepidopterous pests of rice on a common artificial diet. Ann. Entomol. Soc. Am., 60:1215-1216, 1967.
  • 5. Ben-Dov, E.; Wang, Q.; Zaritsky, A.; Manasherob, R.; Barak, Z.; Schneider, B.; Khamraev, A.; Baizhanov, M.; Glupov, V.; Margalith, Y. Multiplex PCR screening to detect cry9 genes in Bacillus thuringiensis strains. Appl. Environ. Microbiol, 65:3714-3716, 1999.
  • 6. Ben-Dov, E.; Zaritski, A.; Dahan, E.; Barak, Z.; Sinai, R.; Manasherob, R.; Khamraev, A.; Troitskaya, E.; Dubitsky, A.; Berezina, N.; Margalith, Y. Extended screening by PCR for seven cry-group genes from field-collected strains of Bacillus thuringiensis Appl. Environ. Microbiol, 63:4883-4890, 1997.
  • 7. Bernhard, K.; Jarret, P.; Meadows, M.; Butt, J.; Ellis, D.J.; Roberts, G.M.; Pauli, S.; Rodgers, P.; Burges, H.D. Natural isolates of Bacillus thuringiensis: worldwide distribuction, characterization, and activity against insect pests. J. Invertebr. Pathol., 70:59-68, 1997.
  • 8. Bravo, A.; Sarabia, S.; Lopez, L.; Ontiveros, H.; Abarca, C.; Ortiz, A.; Ortiz, M.; Lina, L.; Villalobos, F.J.; Peña, G.; Nuñez-Valdez, M.; Soberón, M.; Quintero, R. Characterization of cry genes in a Mexican Bacillus thuringiensis strain collection. Appl. Environ. Microbiol, 64:4965-4972, 1998.
  • 9. Busato, G.R.; Grützmacher, A.D.; Garcia, M.S.; Giolo, F.B.; Stefanello Junior, G.J. Preferência alimentar a arroz, milho e capim-arroz por Spodoptera frugiperda (J.E. Smith, 1797) (Lepidoptera: Noctuidae) oriundas das culturas do arroz irrigado e milho do município de Pelotas, Rio Grande do Sul. II Congresso Brasileiro de Arroz Irrigado - XXIV Reunião da Cultura do Arroz Irrigado, Porto Alegre, 2001, p.445-447.
  • 10. Cerón, J.; Ortíz, A.; Quintero, R.; Güereca, L.; Bravo, A. Specific PCR primers directed to identify cryI and cryIII genes within a Bacillus thuringiensis strain collection. Appl. Environ. Microbiol, 61:3826-3831, 1995.
  • 11. Costa, E.L.N.; Oliveira, J.V.; Cruz, F.Z.; Dias, R.B.; Silva, R.F.P.; Fiuza, L.M. Controle de adultos de Oryzophagus oryzae (Col., Curculionidae) com formulações comerciais de fungos entomopatogênicos II Congresso Brasileiro de Arroz Irrigado - XXIV Reunião da Cultura do Arroz Irrigado, Porto Alegre, 2001, p.357-359.
  • 12. De Barjac, H.; Lecadet, M.M. Dosage biochimique d'exotoxine thermostable de. Bacillus thuringiensis d'après l'inhibition d'ARN-polymerases bacteriennes. C.R. Acad. Sci., 282:2119-2122, 1976.
  • 13. Fiuza, L.M.; Nielsen-Leroux, C.; Goze, E.; Frutos, R.; Charles, J.F. Binding of Bacillus thuringiensis Cry1 toxins to the midgut brush border membrane vesicles of Chilo suppressalis (Lepidoptera, Pyralidae): evidence of shared binding sites. Appl. Environ. Microbiol, 62:1544-1549, 1996.
  • 14. Gallo, D.; Nakano, O.; Neto, S.S.; Carvalho, R.P.L.; Batista, G.C.; Filho, E.B.; Parra, J.R.P.; Zucchi, R.A.; Alves, S.B.; Vendramim, J.D. Manual de Entomologia Agrícola Editora Agronômica Ceres. 2. ed. São Paulo, SP, 1998, p.649.
  • 15. Hansen, B.M.; Damgaard, P.H.; Eilenberg, J.; Pedersen, J.C. Molecular and Phenotypic characterization of Bacillus thuringiensis isolated from leaves and insects. J. Invertebr. Pathol., 71:106-114, 1998.
  • 16. Hansen, B.M.; Hendriksen, N.B. Detection of enterotoxic Bacillus cereus and Bacillus thuringiensis strains by PCR analysis. Appl. Environ. Microbiol, 67:185-189, 2001.
  • 17. Höfte, H.; Whiteley, H.R. Insecticidal crystal proteins of Bacillus thuringiensis Microbiol. Rev., 53:242-255, 1989.
  • 18. Juárez-Pérez, V.M.; Ferrandis, M.D.; Frutos, R. PCR-based approach for detection of novel Bacillus thuringiensis cry genes. Appl. Environ. Microbiol., 63:2997-3002, 1997.
  • 19. Lacey, L.A.; Lacey, C.M. The medical importance of riceland mosquitoes and their control using alternatives to chemical inseticides. J. Am. Mosq. Control Assoc., 6:1-93, 1990.
  • 20. Loguercio, L.L.; Santos, C.G.; Barreto, M.R.; Guimaraes, C.T.; Paiva, E. Association of PCR and feeding bioassays as a large-scale method to screen tropical Bacillus thuringiensis isolates for a cry constitution with higher insecticidal effect against Spodoptera frugiperda (Lepidoptera: Noctuidae) larvae. Lett. App. Microbiol, 32:1-6, 2001.
  • 21. Polanczyk, R.A.; Silva, R.F.P. da; Fiuza, L.M. Effectiveness of Bacillus thuringiensis strains against Spodoptera frugiperda (Lepidoptera: Noctuidae). Braz. J. Microbiol., 31:165-167, 2000.
  • 22. Prando, H.F. Aspectos bioecológicos e de controle de Oryzophagus oryzae (Costa Lima, 1936) (Coleoptera, Curculionidae) em arroz irrigado, sistema de cultivo pré-germinado. Curitiba, 1999, 100p. (Ph.D. Thesis. PPGCB. UFPR)
  • 23. Schnepf, E.; Crickmore, N.; Vanrie, J.; Lereclus, D.; Baum, J.; Feitelson, J.; Zeigler, D.R.; Dean, D.H. Bacillus thuringiensis and its Pesticidal Crystal Proteins. Microbiol. Mol. Biol. Rev., 62:775-806, 1998.
  • 24. Steffens, C.; Oliveira, J.V.; Fiuza, L.M. Método de bioensaio de Bacillus thuringiensis com larvas de Oryzophagus oryzae (Coleoptera, Curculionidae). Semana de Pesquisa e Iniciação Científica da UNISINOS - Exponha-se, São Leopoldo, RS, 2000, p.192.
  • 25. Valicente, F.H. Estado da arte de Bacillus thuringiensis/Spodoptera frugiperda. VII Simpósio de Controle Biológico, Poços de Caldas, MG, 2001, 1 CD.
  • 26. Valicente, F.H.; Barreto, M.R.; Vasconcelos, M.J.V.; Figueiredo, J.E.F.; Paiva, E. Identificação através de PCR dos genes cry1 de cepas de Bacillus thuringiensis Berliner eficientes contra a lagarta do cartucho, Spodoptera frugiperda (J.E. Smith) (Lepidoptera: Noctuidae). An. Soc. Entomol. Brasil, 29:147-153, 2000.
  • 27. Vieira, N.R.A.; Santos, A.B.; Sant'Ana, E.P. A cultura do arroz no Brasil EMBRAPA - Arroz e Feijão, GO. 1999, 633p.
  • 28. Visser, B.; Bosch, D.; Honée, G. Domain-function studies of Bacillus thuringiensis crystal proteins: a genetic approach. In: P. Entwistle; J.S. Cory; M.J. Baley; S. Higgs (eds.) Bacillus thuringiensis, an environmental biopesticide: theory and practice, John Wiley & Sons, Ltda., Chichester, U.K., 1993, p.37-69.
  • *
    Corresponding author: Mailing address: Laboratório de Microbiologia, Centro 2, Universidade do Vale do Rio dos Sinos. Caixa Postal 275. 93001-970, São Leopoldo, RS, Brasil. Tel.: (+5551) 590-8122. E-mail:
  • Publication Dates

    • Publication in this collection
      13 Aug 2004
    • Date of issue
      Dec 2003

    History

    • Received
      02 Aug 2002
    • Reviewed
      13 Jan 2003
    • Accepted
      01 Oct 2003
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