Additional discoveries include a cr

Additional discoveries include a crystal protein gene, cry51Aa1, (GenBank DQ836184) that was isolated from Bt strain F14-1, which had very low identity to known cry genes (e.g., the maximum identity is 22% tocry15Aa). When cloned in an acrystalliferous Bt strain BMB171, crystals formed, and the protein showed toxicity to Bombyx mori larvae (Sun et al., unpublished). The crystal protein gene cry7Ba1 (GenBank DQ242516) was cloned from Bt strain YBT-978. When the gene was expressed in the acrystalliferous strain BMB171, crystals were formed. These could be solubilized at high pH values and were highly toxic toPlutella xylostella larvae.
3.2. Engineered Bt insecticides
To enhance the toxicity and/or broaden the insecticidal spectrum of Bt to insect pests, a number of molecular techniques have been used. These include plasmid deletion, conjugation transfer and genetic engineering. For example, a cry1Ac10 gene in conjunction with a chaperone gene p20 was transferred to Bt strain YBT1520 ( Yu et al., 2001). The resulting engineered Bt strain WG-001 significantly increased the production of crystal protein and enhanced insecticidal activity against the cotton boll worm, H. armigera, diamond back moth, P. xylostella, and beet armyworm, Spodoptera exigua. This is the first approved recombinant Bt strain in China, and commercial production and application of WG-001 in China is now underway ( Zhang et al., 2005).
For the effective control of lepidopteran and coleopteran pests occurring simultaneously, a cry3Aa7 gene was transferred into Bt strain G03 harboring the cry1Ca7 gene, and Bt strain UV17 harboring the cry1Ba3gene. The recombinant plasmid was stably maintained in both of the new recombinant bacteria for at least 180 generations in culture media containing no antibiotics. Large-scale experimental production was begun using both engineered strains, G033A and UV173A. Results show these strains were highly effective against various pests, such as cotton bollworm, H. armigera, beet armyworm S. exigua, Colorado potato beetle, Leptinotarsa decemlineata, and striped flea beetle, Phyllotreta striolata ( Wang et al., 2006).
Using similar strategies, a number of Bt strains engineered with different recombinant Bt genes are being tested in field trials. These include strains Bt-Tny, Bt-YPF22, LCj-12, Pro3A-Vip and Lgcj-10 against lepidopteran pests (Yu et al., 2001). A recombinant baculovirus, rAc11 (AcMNPV with a truncated cry1Abgene of Bt) has proved to be much more effective against the beet armyworm, S. exigua, than the virus used alone (Qi et al., unpublished).
3.3. Development of transgenic Bt crops
3.3.1. Bt cotton
The research and development of Bt cotton is one of the typical examples of advances in agricultural biotechnology in China. For control of cotton bollworm, H. armigera, the cry1A gene (modified cry1Ab andcry1Ac) and trypsin inhibitor gene (CpTI) were synthesized, and then used to construct a highly efficient expression plasmid (pGBI4A2B). This plasmid was then used to transform the two genes, Cry1A and CpTIinto a number of cotton varieties by a unique method (via pollen tube pathway). The first Bt cotton variety, GK-1, was approved for commercialization in 1997, and the whole set of techniques was patented in 1998 (Jia et al., 2004). Continuous monitoring showed that field population samples of cotton bollworm were still susceptible to Cry1Ac protein after 8 years of Bt cotton use in the field. It appears that a Chinese inter-cropping system consisting of wheat, soybean, peanut, corn and cotton, provides an efficient mechanism of natural refuges for pest resistance prevention ( Wu and Guo, 2005). By 2005, 64 Bt cotton varieties with high toxicity, high yield and good fiber quality had been bred. The total cultivated area of Bt cotton in 2005 was 3.3 million hectares. This represents an area covering 66% of the national cotton area in China. Planting Bt cotton has consistently delivered significant economic, ecological, and environmental benefits. The reduction in chemical pesticides was over 260,000 tons of active ingredients. This is equivalent to a 21% reduction in the associated environmental impact of pesticide use on cotton. Together with the labor saved and the increase in yield, Chinese farmers have reaped more than $4.2 billion in profits from the use of Bt cotton since 1997 ( Huang et al., 2002 and James, 2005).
3.3.2. Bt rice
Rice is the most important food grain crop in China but it is consistently attacked by various species of lepidopteran pests, such as striped borer, Chilo suppressalis, yellow stem borer, Tryporyza incertulas, and leaf folder, Cnaphalocrocis medinalis. As shown in Fig. 2, Bt rice transformed with modified cry1A, cry1Abor cry1Ac and stacked with CpTi genes has shown excellent resistance to these insect pests ( Huang, 2004 and Shu et al., 2000).