ABSTRACT
Both, the tobacco caterpillar Spodoptera litura (Fabricius) and the cotton bollworm Helicoverpa armigera (Hübner), are serious polyphagous pests causing considerable loss to crops. Indiscriminate use of chemical pesticides for controlling them has rather resulted in their resistance development. Microbial pesticides, Bacillus thuringiensis in particular, play an important role in pest management. Here, we isolated Bacillus thuringiensis-like bacteria from the soil samples primarily collected from North East region of India along with some states viz., Haryana, Punjab, Maharashtra, West Bengal and Uttarakhand and studied their toxicity against the above two insect pests at 10 µg/g along with standard strain B. thuringiensis subsp. kurstaki HD-1 and at 1 µg/g Pseudomonas fluorescens based MVPII expressing Cry1Ac toxin and AUG-5. Isolates AUG-5 and GTG-7 proved toxic to more than 75% larvae on the 4th as well as 7th day of the treatment of the neonates of H. armigera. The AUG-5 isolate was also effective against S. litura. Ten effective isolates (AUG-5, GTG-4, GTG-7, GTG-9, GTG-42, GTG-64, GTG-70, GTG-3S, GTG-4S and GTG-6S) were characterized using biochemical and 16S rDNA analysis. Nearly, all the isolates tested positive for utilizing monosaccharides. All selected B. thuringiensis isolates showed resistance to ampicillin and co-trimoxazole except AUG-5 to co-trimoxazole. AUG-5 and GTG-7 were highly toxic to both insects, and possessed cry1, cry1A and cry2 genes. These isolates AUG-5 and GTG-7 also contained high Cry1Ac (104.8 and 88.32 ng/mg) and Cry2Ab (3792 and 1305.9 ng/mg), respectively in their spore-crystal complex. Both, AUG-5 and GTG-7 isolates, could be considered for further development as bioinsecticides. The present study has established the diversity and richness of B. thuringiensis-like isolates in soils collected from north-eastern region of India.
ABSTRACT
Adequate expression of Bt (Bacillus thuringiensis) toxins and purity of seeds of Bt-transgenic cottons are important for controlling bollworms, and thereby increasing the cotton productivity. Therefore, we examined the variability in expression of Bt toxin proteins in the seeds and in leaves of different cotton (Gossypium hirsutum (L.) hybrids (JKCH 226, JKCH 1947, JKCH Durga, JKCH Ishwar, JKCH Varun KDCHH 441 and KDCHH 621) expressing Bt toxins in F1 and F2 generations, using bioassays against the cotton bollworm, Helicoverpa armigera (Hübner), and the lateral flow strip (LFS) test. Toxicity of Bt toxin proteins in the seeds of Bt-transgenic cottons to H. armigera correlated with their toxicity in the leaves in one-toxin Bt cotton hybrids. The Bt-F1 and Bt-F2 seeds of JKCH 1947 were more toxic to H. armigera than those of JKCH Varun seeds. The seeds and leaves of F1s showed greater toxicity than the F2 seeds or leaves of one-toxin (cry1Ac) Bt cotton hybrids. However, no significant differences were observed for the two-toxin (cry1Ac and cry2Ab) hybrid, KDCHH 621. Toxicity of leaves to H. armigera increased with crop age, until 112 days after seedling emergence. The Bt trait purity in F1 seeds of four two-toxin Bt cotton hybrids ranged from 86.7 to 100%. The present study emphasizes the necessity of 95% Bt trait purity in seeds of transgenic cotton for sustainable crop production.
ABSTRACT
Helicoverpa armigera, a polyphagous lepidopteron insect pest causes severe yield loss in cotton, legumes, tomato, okra and other crops. Application of chemical pesticides although effective, has human health and environmental safety concerns. Moreover, development of resistance against most of the available pesticides is compelling to look for alternative strategies. Adoption of Bt transgenic crops have resulted in reduction in pesticide consumption and increasing crop productivity. However, sustainability of Bt transgenic crops is threatened by the emergence of insect resistance. In the present study potential insecticidal siRNA were identified in six H. armigera hormonal pathway genes. Out of over 2000 computationally identified siRNA, 16 most promising siRNA were selected that address the biosafety concerns and have high potential of targeted gene silencing. These siRNA will be useful for chemical synthesis, in insect feeding assays and knockdown the target H. armigera hormone biosynthesis, consequently obstructing the completion of insect life cycle. The siRNA have a great potential of deployment to control H. armigera alone as well as with Bt for insect resistance management.