The chronicle of the ups and downs that made Bacillus thuringiensis a natural insecticide

Bacillus thuringiensis is a worldwide known bacterium for its capacity to control insect pests thanks to the action of its parasporal crystal. The objective of this paper deals with the history, in some cases unknown, of the study of Bacillus thuringiensis that led it to be a crucial biological alternative in controlling pest insects. How the mode of action for killing insects was understood, as well as the field tests that were carried out to evaluate its effectiveness and to develop the first commercial products, are reflected in this review that presents and discusses the scientific successes and failures that marked the course of B. thuringiensis.

Bacillus thuringiensis es una bacteria conocida mundialmente por su capacidad para controlar insectos plaga, gracias a la acción de su cristal parasporal. El objetivo de esta revisión trata de la historia, en algunos casos desconocida, del estudio de Bacillus thuringiensis que la llevó a ser una importante alternativa biológica en el control de insectos plaga. Cómo se llegó a comprender el modo de acción para matar insectos, así como las pruebas de campo que se realizaron para evaluar su efectividad y lograr desarrollar los primeros productos comerciales están plasmados en esta revisión que presenta y discute los aciertos y desaciertos científicos que marcaron el rumbo de B. thuringiensis.

Agriculture wastes conversion for biofertilizer production using beneficial microorganisms for sustainable agriculture applications

Aims: The emphasis of this study is to generate new valuable bioproducts from non-toxic cleaning waste for environmental healing technology. Methodology and Results: Comparisons between different types of biofertilizer formulations and the field trial effectiveness were done. Results indicated that biofertilizer C contained the highest N value (1.8%) when compared with biofertilizers B and A, which only contained 1.7% and 1.4%, respectively. Biofertilizer A showed significant difference in the total count of yeast, mould, ammonia oxidizing bacteria and nitrate oxidizing bacteria compared to biofertilizer B and C. Meanwhile, biofertilizer C was found to be significantly different from others in Lactobacillus sp. and nitrogen-fixing bacteria count. Photosynthetic total count and Actinomycetes sp. were not noticed in all formulations tested. Conclusion, significance and impact of study: The findings of this study suggest that biofertilizer A is suitable to be used as a promotional biofertilizer in flower and fruit production, biofertilizer B can be used for a leafy crop, while biofertilizer C is good for the growth of roots and stem of plants.

Efficacy of pirimiphos-methyl (50% EC), as a larvicide for the control of Culex quinquefasciatus.

Background & objectives: Pirimiphos-methyl, an organophosphorus insecticide is known to overcome resistance mechanisms of mosquitoes to other organophosphates. Information on the duration of efficacy of pirimiphos-methyl (50% emulsifiable concentrate) for the control of immatures of Culex quinquefasciatus, the vector of bancroftian filariasis, is scanty and hence site specific field trials are necessary to determine the field dosage. Pirimiphos-methyl (50% EC) was tested for its efficacy in cesspits and drains against the immatures of Cx. quinquefasciatus at Puducherry, an endemic area for filariasis, south India. Methods: In cesspits, Pirimiphos-methyl (50% EC) was tested at the dosage of 25, 50, 100 and 200 g(ai)/ ha and in drains at 50, 100 and 200 g(ai)/ha. Immature density during pre-treatment and post-treatment periods was recorded and the efficacy was determined by calculating percentage reduction in larval and pupal densities for a period of about one month. Results: In cesspits, application of the insecticide at 25 and 50 g(ai)/ha reduced the density of larvae by >80 per cent for 2-4 days only, whereas at 100 and 200 g(ai)/ha, the efficacy lasted for 7-8 days. More than 80 per cent reduction was observed in pupal density for 4 days at 50 g(ai)/ha and for 10-12 days at 100 and 200 g(ai)/ha respectively. In drains treated with 50 g (ai)/ha, >80 per cent reduction in larval density was recorded up to 3rd day post-treatment. The efficacy showing >80 per cent reduction in larval density lasted for 12-13 days and the same in pupal density lasted for 10-12 days at 100 and 200 g(ai)/ha. Interpretation & conclusions: At the dosages of 100 and 200 g(ai)/ha, pirimiphos-methyl (50% EC) showed no difference in the control of larvae of Cx. quinquefasciatus in cesspits and drains. Pirimiphosmethyl may be applied at the field dosage of 100 g (ai)/ha at 10 day-intervals in the larval habitats of Cx. quinquefasciatus to achieve >80 per cent reduction in immature density.

Insufficient regulatory supervision prior to release of genetically modified crops for commercial cultivation in India.

(1) Do we need GM crops? No. We have far better alternatives such as integrated pest management (IPM), biopesticides and appropriate agro-practices including organic farming for almost all crops. IPM is a part of the country’s stated national agriculture policy. It has been shown to be effective but is not being used. (2) Was appropriate risk assessment carried out in the case of the Bt-cotton crops that have been released? No. For example, our present system of testing for allergenicity does not take into account recent work (e.g., papers in this area – a paper titled “Allergic potential of novel foods” in the Proceedings of the Nutrition Society, volume 64, issue No.4, pp 487–490 of November 2005; a paper titled “Allergenicity Assessment of Genetically Modifi ed Crops – What makes sense?” in Nature Biotechnology of January 2008, volume 26, pp 73–81; a paper titled “Transgenic expression of bean alpha-amylase inhibitor in peas results in altered structure and immunogenecity” in Journal of Agricultural Food Chemistry, 2005, volume 53, pp 9023–9030). The Annexure lists 29 tests relevant to the release of GM crops. Only a few have been done for Bt-cotton and GM crops in the pipeline, and that too inadequately (see item 5 below).

Field Trials of CpGV Virus Isolates Overcoming Resistance to CpGV-M / 中国病毒学·英文版

The Cydia pomonella granulovirus (CpGV) has been used for many years as biological agent for codling moth control in apple orchards. Resistance to the Mexican strain of CpGV was detected in orchards in Germany, France and Italy. A laboratory insect colony was started from insects collected in a French resistant orchard. It was named RGV. Various virus isolates were identified as active against this resistant insect colony. Field tests were carried out in 2007 to test if the two virus isolates CpGV-I12 and NPP-R1 were effective in the field. Although these virus isolates were not able to reduce insect caused fruit damages, they significantly reduced the overwintering insect populations. NPP-R1 was subjected to eight passages on RGV larvae (NPP-R1.8) that improved its biological activity on RGV larvae. 2008 field trials were set up to test this improved virus strain, compared to CpGV-I12 and Madex plus active on RGV. These tests confirmed the ability to control both in susceptible and resistant insect populations.

Insect resistance and risk assessment studies of advanced generations of basmati rice expressing two genes of Bacillus thuringiensis

Advanced generations of different transgenic lines of indica basmati rice (Basmati-370) expressing two unrelated Bt genes, cry1Ac and cry2A were evaluated for resistance to Yellow Stem Borer (YSB) and Rice Leaf Folder (RLF) under field conditions compared to control lines over three years (2003-2005). Homozygous lines were selected and analyzed for insect resistance, morphological, physiochemical properties and risk assessment studies. After artificial infestation of target insects, the transgenic plants showed significant resistance. Data were recorded in terms of dead hearts and white heads at vegetative and flowering stage respectively. Transgenic lines showed up to 100 and 96 percent resistance against yellow stem borer at vegetative and flowering stages, respectively. Natural damage of rice leaf folder was also observed during the year 2005. The transgenic plants were 98 percent more resistant as compared to untransformed control plants. Variations in some morphological characteristics, e.g., the average number of tillers, plant height and maturity were also observed. Transgenic lines produced 40 percent more grains than control plants. All these characteristics were stably inherited in advanced generations. The transgenic lines had no significant effect on non-target insects (insects belonging to orders other than Lepidoptera and Diptera) in field or under storage conditions. Chances of pollen-mediated gene flow were recorded at a rate of 0.14 percent.