Abstract
Advances in genetic engineering permit the modification of plants to be tolerant to certain herbicides that are usually not selective. For practical and commercial purposes, it is important to be able to detect the presence or absence of these traits in genotypes. The objective of this research was to develop a procedure for identifying genetically modified soybean (Glycine max L. Merr.) with resistance to the herbicide glyphosate. Two studies were conducted based on germination test. In the first study, soybean seeds were pre-imbibed in paper towel with the herbicide solutions, then transferred to moist paper towel for the germination test. In the second study, seeds were placed directly in herbicide solutions in plastic cups and tested for germination using the paper towel method. Eight soybean genotypes were compared: four Roundup Ready, that contained the gene resistant to the herbicide (G99-G725, Prichard RR, G99-G6682, and H7242 RR) and four non-transgenic parental cultivars (Boggs, Haskell, Benning, and Prichard). In the first study, the seeds were imbibed for 16 hours at 25°C in herbicide concentrations between 0.0 and 1.5% of the glyphosate active ingredient. In the second, seeds were subjected to concentrations between 0.0 and 0.48%, for one hour, at 30°C. The evaluation parameters were: germination, hypocotyl length, root length and total length of the seedlings. Both methods are efficient in identifying glyphosate-resistant soybean genotypes. It is possible to identify the genetically modified soybean genotypes after three days, by imbibing the seed in 0.12% herbicide solution, and after six days if the substrate is pre-imbibed in a 0.6% herbicide solution. The resistance trait was identified in all cultivars, independent of the initial physiological quality of the seed.
Highlights
Transgenic plants, usually called geneticallymodified organisms (GMOs), represent a promising technology that could give vital contribution to the global security of food and fiber
Agrochemical research, especially with glyphosate, has been at the forefront of these biotechnological advances, and some success has been achieved in the engineering of herbicide resistance in transgenic crop plants
The seeds were placed on paper towels pre-imbibed in solutions containing either 0.0, 0.6, 0.82, 1.2 or 1.5% of the active ingredient of the herbicide glyphosate (Nphosphonomethyl glycine, 600 g L-1 formulated product), for 16 hours in a chamber maintained at 25°C
Summary
Transgenic plants, usually called geneticallymodified organisms (GMOs), represent a promising technology that could give vital contribution to the global security of food and fiber. The total area of genetically modified crops has increased more than 35 times, from 1.7 million hectares in 1996 to 58.7 million hectares in 2002 (James, 2002). This high level of adoption reflects the increasing acceptance of genetically modified cultivars among the farmers using this technology in developed and developing countries. Glyphosate (N-phosphonomethyl-glycine) is the active ingredient in the nonselective herbicide Roundup (Cobb, 1992). This herbicide is highly effective against the majority of weeds
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