Herbicide resistance in plants

Multicellular living organisms and unmodified parts thereof and – Plant – seedling – plant seed – or plant part – per se – Higher plant – seedling – plant seed – or plant part

Reexamination Certificate

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C800S270000, C800S320000, C800S320100, C800S320200, C800S320300

Reexamination Certificate

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06211438

ABSTRACT:

1. FIELD OF THE INVENTION
This invention relates to genes and enzymes which confer resistance to herbicides in plants, plant tissues and seeds. In particular, the invention involves agronomically important crops which are resistant to herbicides, and which genetically transmit this characteristic to their progeny.
2. BACKGROUND OF THE INVENTION
2.1. WEED CONTROL
The use of herbicides for controlling weeds or plants in crops has become almost a universal practice. The market for these herbicides approaches a billion dollars annually. Even with this extensive use, weed control remains a significant and costly problem for the farmer.
Present day herbicides used singly or in so-called tank mixes require good management to be effective. Time and method of application and stage of weed plant development are critical to getting good weed control with herbicides. Some weed species are simply resistant to today's herbicides. Therefore, the production of effective herbicides increases in importance every year, especially as other weeds are controlled and thus reduce competition. Application of large amounts of marginally effective herbicides on these weeds can result in a commitment to grow the same crop in subsequent years because of chemical persistence in the soil which prevents rotation with a crop sensitive to that herbicide.
Other herbicides, while not used directly to control weeds in field crops, are used as “total vegetation control agents” to entirely eliminate weeds in certain railroad and industrial situations. These herbicides may be deposited on areas where crops are planted by water run-off, or other natural means. Thus, in fields affected by run-off from land on which total vegetation control agents have been used, sensitive field crops may be killed or their growth seriously inhibited.
Herbicides with greater potency, broader weed spectrum and more rapid degradation in the soil would have a significant impact on these problems. Unfortunately, these compounds also have greater crop phytotoxicity. Crop hybrids or varieties with resistance to the compounds would provide an attractive solution by allowing the compounds to be used without risk of damage to the crop.
2.2. TISSUE CULTURE OF MAIZE
Irrespective of the plant species, there are a number of common features that apply to most tissue culture programs. The technique of cell and tissue culture has been widely developed, and much work has been done on growth, metabolism and differentiation of tissue culture of dicotyledons (Yamada, 1977, in Plant Cell, Tissue and Organ Culture, eds. Reinert and Bajaj, pp. 144-159, Springer-Verlag, Berlin). However, successful tissue culture studies with monocotyledons (e.g., the cereal crops such as maize, rice, wheat, barley, sorghum, oats, rye and millet) leading to plant regeneration are not as well documented as with dicotyledons. Success is frequently dependent on choosing donor tissues for culture initiation which come from plants of appropriate genotype as well as physiological and development states. Other features which are obviously also important include the organic and inorganic composition of the growth medium and the physical environment in which the cultures are grown.
In maize, the development of tissue cultures capable of plant regeneration was accomplished after the identification of appropriate genotypes and donor tissues (Green and Rhodes, 1982 in Maize for Biological Research, ed. W. F. Sheridan, pp. 367-371, Plant Molecular Biology Associates, Charlottesville, Va.). The first method developed which regenerated plants from tissue cultures of maize used immature embryos as donor tissues. With N6 or MS growth media (defined below in Section 6) and a synthetic auxin, such as 2,4-dichlorophenoxyacetic acid (2,4-D), tissue cultures develop rapidly from the scutellum of the embryos. The resulting cultures are developmentally heterogeneous and contain a variety of tissue types. Removal of the 2,4-D from the growth medium permits these cultures to produce large numbers of regenerated plants. Cultures of this type have proved capable of regenerating plants for up to three years.
Another donor tissue from which regenerable tissue cultures of maize have been initiated are immature tassels. This tissue is the male flower and as it matures it is responsible for pollen production. Immature embryos, inflorescences, and the few other tissues in cereals from which regenerating cultures have been initiated all have the common characteristic of juvenility. Regenerated plants obtained from tissue cultures are grown to maturity in a glasshouse, growth chamber, or field. The progeny seed produced in crosses with regenerated plants permits the evaluation of subsequent generations. The basic tissue culture methods developed for corn have been extended to many other cereal species.
An interesting development in recent years has been the occurrence of somatic embryogenesis in tissue cultures of maize. Somatic embryogenesis is the process where cells from callus, suspension, or protoplast cultures develop into complete embryos similar to zygotic embryos produced in seeds. It is now possible to reliably initiate cultures of corn which have two important characteristics. One is that the callus cultures are friable, meaning that they are soft and loose in texture. This property is important because cultures of this type exhibit rapid growth and it facilitates the initiation of suspension cell cultures. The other valuable attribute of these friable cultures is their ability to form very large numbers of somatic embryos. Microscopic examination reveals the presence of many small, organized structures on the surface of the callus. These structures are young somatic embryos at various developmental stages. These friable cultures will retain their embryogenic potential for as long as two years and have shown the capacity to produce extremely large numbers of somatic embryos.
The somatic embryos in these friable calli develop to maturity when the cultures are transferred to medium containing 5 to 6 percent sucrose and no hormones. After approximately two weeks of growth on this medium, many embryos have become quite mature. They germinate rapidly and grow into plants when placed on MS or N6 medium containing 2% sucrose. The plants are then established in soil and are grown to maturity.
It is now well-documented that a high level of genetic variability can be recovered from plant tissue culture. It is well documented that spontaneous genetic variability in cultured plant cells may be the result of mutation (Meredith and Carlson, 1982, in Herbicide Resistance in Plants, eds. Lebaron and Gressel, pp. 275-291, John Wiley and Sons, NY). The frequency of mutants can also be increased by the use of chemical or physical mutagens. Some of this variability is of agronomic importance. Mutants for disease resistance have been obtained in sugarcane for Fiji disease, early and late blight in potato, and southern corn leaf blight in maize. In rice, maize, and wheat considerable variability for traits inherited as single genes of plant breeding interest have been recovered, including time of seed set and maturation, seed color and development, plant height, plant morphology, and fertility.
Tissue cultures of maize have been used to recover mutants for disease resistance and amino acid overproduction as described below.
Texas male sterile cytoplasm (cms-T) genotypes of maize are susceptible to the pathotoxin produced by the fungus
Helminthosporium maydis
race T while normal cytoplasm (N) genotypes are resistant (Gengenbach et al., 1977, Proc. Natl. Acad. Sci. USA 74: 5113-5117). Similarly, tissue cultures obtained from cms-T genotypes are susceptible to the pathotoxin while N genotype cultures are resistant. The pathotoxin from
H. maydis
race T was used to select resistant cell lines from susceptible cms-T cultures using a sublethal enrichment selection procedure. After five cycles of increasing selection pressure, cell lines were recovered which were resistant to lethal levels of the pathotoxin. Plants rege

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