Authors:M. W. Abbasi, M. Q. Khan, M. J. Zaki, S. S. Shaukat, A. Rauf, N. Ahmed, M. Azeem, and M. Tariq
Bernhard , K. , Jarrett , P. , Meadows , M. , Butt , J. , Ellis , D. , Roberts , G. , Pauli , S. , Rodgers , P. and Burges , H. ( 1997 ): Natural isolates of Bacillusthuringiensis: worldwide distribution, characterization, and activity
Authors:J. Yao, Y. Liu, Z. Gao, P. Liu, M. Sun, S. Qu, and Z. Yu
A microcalorimetric technique based on the bacterial heat-output was explored to evaluate the effect of Mn(II) on Bacillus thuringiensis. The power-time curves of the growth metabolism of B. thuringiensis and the effect of Mn(II) on it were studied using an LKB-2277 BioActivity Monitor, ampoules method, at 28C. For evaluation
of the results, the maximum peak-heat output power (Pmax) in the growth phase, the growth rate constants (k), the log phase heat effects (Qlog ), and the total heat effect in 23 h (QT) for B. thuringiensis were determined. Manganese has been regarded as the essential biological trace element. Mn(II) of different concentration
have different effects on B. thuringiensis growth metabolism. High concentration (800-1600 μg mL-1) of Mn(II) can promote the growth of B. thuringiensis; low concentration (500-800 μg mL-1) can inhabit its growth.
Bacillusthuringiensis to Colorado potato beetle (Coleoptera: Chrysomelidae). J. Econ. Entomol. 82, 750-755.
Toxicity of a new strain of Bacillusthuringiensis to Colorado potato beetle (Coleoptera: Chrysomelidae
-Rivera, A., Benintende, G., Cozzi, J., Baizabal-Aguirre, V. M., Valdez-Alarcon, J. J., Lopez-Meza, J. E. (2004) Molecular characterization of
strains from Argentina.
Antonie Van Leeuwenhoek 86
Authors:P. Duraimurugan, A. Regupathy, and P. Shanmugam
Duraimurugan, P. and Regupathy, A. (2004): Biological suppression of synthetic pyrethroids resistance in
. International Symposium, Strategies for Sustainable Cotton
Authors:L. Ruan, Y. Liu, Z. Gao, P. Shen, and Q. Sheng
The thermogenic curves of the aerobic metabolism of the three strains of Bacillus thuringiensisB.t. A, B.t. B and B.t. C have been determined by using an LKB-2277 BioActivity Monitor. B.t. A was the host bacterium without foreign gene. B.t. B and B.t. C were constructed by transforming different foreign genes into the host B.t. A, respectively. B.t. B expressed erythromycin resistant gene, while B.t. C expressed both erythromycin resistant gene and tyrosinase gene. The heat flow rate of these strains is B.t. A> B.t. B >B.t. C. These results indicated that there is obvious interrelation between expression of foreign genes and heat flow rate of