Metabolism and deposition of exogenous gene and protein from transgenic glyphosate herbicide-tolerant soybean meal in SD rats were studied in the experiment. The transgenic soybean GTS40-3-2 meal and its non-transgenic counterpart (parent A5403) were fed to the generation and the second generation Sprague-Dawley (SD) rats (Rattus norvegicus). The study added the genetically modified (GM) soybean meal and its non-transgenic control soybean meal (parent A5403) in a ratio of 20% respectively to the feeds. By using qualitative, quantitative PCR and ELISA methods to detect transgenic soybean residues of metabolism ingredients in rats, the safety and influence of GM soybean were evaluated. The results showed that the intestinal fecal and cecum contents of rats were detected with residues of GM ingredients, intestinal flora and organs were not found related genes and protein. These results indicated that transgenic glyphosate herbicide-tolerant soybean GTS40-3-2 meal was as safe as its non-GM soybean meal in long-term feeding study.
Animal Feed ; Animal Nutritional Physiological Phenomena ; Animals ; Digestion ; Glycine ; analogs & derivatives ; Herbicide Resistance ; Herbicides ; Plants, Genetically Modified ; Proteolysis ; Rats ; Rats, Sprague-Dawley ; Soybean Proteins ; Soybeans

Acetohydroxyacid synthase (AHAS) catalyses the first reaction in the pathway for synthesis of the branched-chain amino acids. AHAS is the target for sulfonylurea, imidazolinone and other AHAS-inhibitor herbicides. Herbicides-resistant AHAS genes have potential application in plant transgenetic engineering and development of new generation herbicide. The AHAS isozyme genes ilvBN, ilvGM and ilvIH were cloned from metsulfuron-methyl resistant strain Klebsiella sp. HR11 and metsulfuron-methyl sensitive strain Klebsiella pneumoniae MGH 78578. Homologous sequences comparison indicated that the differences in AHAS isozyme genes at amino acid levels between strain HR11 and strain MGH 78578 were mainly on the large subunits of ilvBN and ilvGM. The three AHAS isozyme genes from HR11 and MGH 78578 were ligated into the expression vector pET29a(+) and expressed in Escherichia coli BL21, respectively. The results of enzyme inhibition assay showed that only ilvBN and ilvGM from strain HR11 showed strong resistance to AHAS-inhibitor herbicides, while ilvIH from strain HR11 and ilvBN, ilvGM and ilvIH from strain MGH78578 were sensitive to AHAS-inhibitor herbicides.
Acetolactate Synthase ; chemistry ; genetics ; Escherichia coli ; genetics ; metabolism ; Gene Expression ; Genes, Bacterial ; drug effects ; Herbicide Resistance ; genetics ; Herbicides ; pharmacology ; Imidazolines ; pharmacology ; Isoenzymes ; genetics ; Klebsiella ; genetics ; Sulfonylurea Compounds ; pharmacology

Obtaining marker-free plants with high efficiency will benefit the environmental release of transgenic crops. To achieve this point, a binary vector pNB35SVIP1 with three T-DNAs was constructed by using several mediate plasmids, in which one copy of bar gene expression cassette and two copies of VIP1 gene expression cassette were included. EHA101 Agrobacterium strain harboring the final construct was applied to transform soybean (Glycine max) cotyledon nodes. Through 2 - 3 months regeneration and selection on 3 - 5mg/L glufosinate containing medium, transgenic soybean plants were confirmed to be obtained at 0.83% - 3.16%, and co-transformation efficiency of both gene in the same individual reached up to 86.4%, based on southern blot test. By the analysis of PCR, southern blot and northern blot combining with leaf painting of herbicide in T1 progenies, 41 plants were confirmed to be eliminated of bar gene with the frequency of 7.6% . Among the T1 populations tested, the loss of the alien genes happened in 22.7% lines, the silence of bar gene took place in 27.3% lines, and VIP1 gene silence existed in 37.1% marker-free plants. The result also suggested that the plasmid with three T-DNAs might be an ideal vector to generate maker-free genetic modified organism.
Aminobutyrates ; pharmacology ; Blotting, Northern ; Blotting, Southern ; Cotyledon ; drug effects ; genetics ; physiology ; DNA, Bacterial ; genetics ; Gene Expression Regulation, Plant ; Genes, Plant ; genetics ; Genetic Vectors ; genetics ; Herbicide Resistance ; genetics ; Herbicides ; pharmacology ; Plant Leaves ; drug effects ; genetics ; physiology ; Plants, Genetically Modified ; drug effects ; genetics ; physiology ; Regeneration ; drug effects ; genetics ; physiology ; Rhizobium ; genetics ; Soybeans ; drug effects ; genetics ; physiology ; Transformation, Genetic