Bacillus thuringiensis (Bt) is widely used as an environmentally friendly insecticide compared to chemical insecticides. However, challenges such as difficulty in direct practical application, limited efficacy duration, and stability have been identified. To solve these issues, formulation-based research is being extensively conducted. In this study, the high insecticidal activity strain Bt IMBL-B9, identified in previous research, was subjected to large-scale cultivation using a fermentor. Subsequently, various formulations were developed through formulation processes. and characteristics such as their wettability, suspensibility and particle size were assessed to select the optimized formulation.
Bacillus thuringiensis (Bt) is currently the most commonly used microbial pesticide. In the previous study, Bt IMBL-B9 known for its high toxicity against Spodoptera exigua, S. frugiperda and Plutella xylostella was characterized. To develop novel biopesticide, optimization of culture medium is required for the cost-effective mass production for toxin production of IMBL-B9. Through experimental design by Plackett-Burman design, ingredients that significantly influenced the production of IMBL-B9's toxin were selected. Using these results, the novel culture medium for IMBL-B9 was developed and the toxin yield of IMBL-B9 was significantly increased than conventional media by using this medium. These results could be useful for the development of biopesticides.
The insecticidal activity of Bacillus thuringiensis subsp. israelensis (Bti) is due to synergistic interactions among its four major proteins (Cry4Aa, Cry4Ba, Cry11Aa, Cyt1Aa), while the activity of Lysinibacillus sphaericus (Ls) is due to a binary toxin (Bin) consisting of a toxin domain, BinA, and a midgut receptor-binding domain, BinB. Although used commercially for almost three decades, reports of mosquito resistance to Bti have been rare. However, levels of resistance greater than 10,000-fold to Bin have been reported where Ls has been used intensively for mosquito control. Cyt1Aa is a lipophilic protein, and in previous studies we showed it delays the evolution of resistance to the Cry proteins of Bti, and can overcome high levels of resistance Bin. In a previous study, we fused Cyt1Aa to BinA, using the lipophile as a broad-spectrum binding domain and showed that the Cyt1Aa-BinA chimera was remarkably toxic to five major vector species of mosquitoes, Anopheles gambiae, An. stephensi, An. quadrimaculatus, Bin-sensitive and Bin-resistant strains of Culex quinquifasciatus, and Aedes aegypti, the latter not normally sensitive to Ls. However, toxicity against Aedes aegypti was not as high as against other mosquito species. Here we show that introducing another highly mosquitocidal protein, Cry11B from B. thuringiensis subsp. jegathesan, enhances the chimera’s toxicity against Ae. aegypti significantly but not against Cx. quinquefasciatus.
Plasmids from Bacillus thuringiensis have been implicated in pathogenicity as they carry the genes responsible for different types of diseases in mammals and insects. B. thuringiensis serovar mogi of a novel serogroup (H3a3b3d), which showed mosquitocidal activity against Anopheles sinensis and Culex pipiens pallens, was isolated from fallen leaves in Mungyeong city, Republic of Korea. In contrast to the complicated plasmid profiles of B. thuringiensis H3 serotype strains, the B. thuringiensis serovar mogi contained only megaplasmid (> 30 MDa) on which the toxin genes were occasionally located. Sequence analysis using 454-pyrosequencing revealed that the megaplasmid harbored at least seven putative cry genes, showing about 84%, 75%, 73%, 58%, 84%, 39% and 75% similarities in amino acid sequences with Cry27Aa, Cry19Ba, Cry20-like, Cry56Aa, Cry39ORF2, Cry8Ba and Cry40ORF2, respectively. These cry genes were cloned to the Escherichia coli-B. thuringiensis shuttle vector, pHT1K, and then introduced into an acrystalliferous B. thuringiensis Cry-B strain for further molecular characterization. This novel 3a3b3d type strain, B. thuringiensis serovar mogi, could be used as a good resource for studying unknown mosquitocidal cry genes.
Plasmids from Bacillus thuringiensis have been implicated in pathogenicity as they carry the genes responsible for different types of diseases that in mammals and insects. A novel serogroup (H3a3b3d), B. thuringiensis strain K4 which showed mosquitocidal activity against Anopheles sinensis and Culex pipiens pallens, was isolated from fallen leaves in Mungyeong city, Republic of Korea. In contrast to the complicated plasmid profiles of B. thuringiensis H3 serotype strains, the strain K4 (designated as serovar mogi) had only one large plasmid (>200kb) on which the toxin genes were occasionally located. A 454 pyrosequencing was used for the complete sequencing of the large plasmid. The sequence analysis showed that k4 plasmid had at least seven putative cry genes, ending up to showing 84%, 75%, 73%, 58%, 84%, 39% and 75% homology with Cry27Aa, Cry19Ba, Cry20-like, Cry56Aa, Cry39ORF2, Cry8Ba and Cry40ORF2 toxins in amino acids, respectively. This novel 3a3b3d type strain, B. thuringiensis serovar mogi, can be used as a good resource for studying unknown mosquitocidal cry genes. The E. coli-B. thuringiensis shuttle vector, pHT1K was used to clone these cry genes for characterization. In each clone, the level of transcription and production of crystal proteins will be investigated in near the future.
Bacillus thuringiensis (Bt) strain K4 was isolated from fallen leaves which had been collected at a forest stand in Mungyeong city, Republic of Korea. The flagellated vegetative cells of Bt K4 were agglutinated with the H3 reference antiserum among 55 reference H-antisera. In a further test to identify subfactors, 3b and 3d monospecific antisera were reactive to the cells, followed up with introducing a novel serogroup of 3a3b3d, designated as serovar mogi. The strain K4 had mosquitocidal activity against Dipteran larvae, Anopheles sinensis and Culex pipiens pallens, with no Lepidopteran toxicity observed. The SDS-PAGE profile of K4 crystal protein, ovoidal-shaped, included several bands ranging from 30-75 kDa. Four putative peptides, Cry19Ba, Cry40ORF2, Cry27Aa and Cry20Aa were detected from the bands by a nano-LC-ESI-IT MS analysis. Through a thermal asymmetric interlaced PCR, cry19Ba, cry40ORF2 and cry27Aa genes were partially cloned from K4 strain. Three cry genes were further found in the strain by a 454 pyrosequencing, ending up to showing 58%, 39% and 84% homology in amino acids with Cry56Aa, Cry8Ba and Cry39ORF2 toxins, respectively. This novel 3a3b3d type strain, B. thuringiensis subsp. mogi, can be used as a good resource for studying unknown mosquitocidal cry genes.
The Bacillus thuringiensis strain K4 was isolated from fallen leaves, sampled in a forest region of the city of Mungyeong, Korea. The flagellated vegetative cells of B. thuringiensis strain K4 were agglutinated with the H3 reference antiserum and further, agglutinated with 3b and 3d monospecific antisera but non-reactive for 3c and 3e factor sera. These results create a new serogroup with flagellar antigenic structure of 3a3b3d, designated serovar mogi. The strain K4 showed high activity against dipteran larvae, Anopheles sinensis and Culex pipiens pallens while no lepidopteran toxicity. It produced a single ovoidal-shaped parasporal crystal whose SDS-PAGE protein profile consisted of several bands ranging from 75 to 30 kDa. Through the protein identification by nano-LC-ESI-IT MS analysis, the putative peptides of Cry19Ba, Cry40ORF2, Cry27Aa and Cry20Aa were detected. In contrast to the plasmid profile of B. thuringiensis H3 serotype strains, the strain K4 contained only a large plasmid (~100 kb) and we cloned partial cry27Aa, cry19Ba and cry40ORF2 genes from it by thermal asymmetric interlaced PCR. Sequencing analysis showed 87%, 88% and 88% homologous with known cry27Aa, cry19Ba and cry40ORF2 genes, respectively. The new type strain, B. thuringiensis subsp. mogi (H3a3b3d) will be a good resource for new mosquitocidal cry genes.
Bacillus thuringiensis 1-3 (Bt 1-3), belonging to subsp. aizawai (H7), showed different characteristics in plasmid profiles from type strain and had cry2A gene in addition to cry1Aa, cry1Ab, cry1C and cry1D. To clone its plasmids and construct E.coli-Bt shuttle vector, we constructed the plasmid capture system (PCS) by inserting attB sites including lacZ between transposable elements (designated as pPCS-Troy). Through in vitro transposition with total plasmids DNA of Bt 1-3, 53 clones were acquired and their sizes were approximately 10 kb. Based on the sequence analysis, they were classified in four groups showing similarities with four known Bt plasmids, pGI3, pBMB175, pGI1 and pGI2, respectively. One of pGI3-like clones, named as pBt1-3, was fully sequenced and its putative open reading frames (ORFs), Rep-protein, double-strand origin of replication (dso), single-strand origin of replication (sso), have been identified. The structure of pBt1-3 showed high similarity with pGI3 which is one of rolling-circle replication (RCR) group VI family. As a donor for construction of shuttle vector, pDonr-attPEm vector harboring erythromycin resistant gene between attP sites was constructed. Through BP recombination with pPCS-Troy-cloned Bt plasmids and pDonr-attPEm, erythromycin resistant gene was transposed to Bt plasmids. This scheme proposes that in vitro transposition using pPCS-Troy and BP recombination using pDonr-attPEm can easily clone Bt plasmids and construct novel shuttle vectors.
Bacillus thuringiensis 1-3 (Bt 1-3), belonging to subsp. aizawai (H7), showed different characteristics in plasmid profiles and had cry2A gene in addition to cry1Aa, cry1Ab, cry1C and cry1D. This strain exhibited dual insecticidal activity against Aedes aegypti as well as Plutella xylostella. Recently, we improved the donor-s of plasmid capture system (PCS) by inserting attB sites including lacZ between transposable elements (designated as pPCS-Troy), to construct E.coli-Bt shuttle vector. Through in vitro transposition with total plasmids DNA of Bt 1-3, 53 clones were acquired and their range of sizes were approximately 10 kb. Based on the sequence analysis, they were classified in 4 groups showing similarity with 4 known plasmids, pGI1, pGI2, pGI3 and pBMB175, respectively. One of pGI3-like clones was fully sequenced and its open reading frames were analyzed. As a donor for construction of shuttle vector, pDonr-attPEm vector harboring erythromycin resistant gene between attP sites was constructed. Through BP recombination with pPCS-Troy-cloned Bt plasmids and pDonr-attPEm, erythromycin resistant gene was transposed to Bt plasmids. This scheme proposes that in vitro transposition using pPCS-Troy and BP recombination using pDonr-attPEm can easily construct novel shuttle vectors with any Bt plasmids and this combined procedure can introduce foreign gengs into various circular DNA molecular.