The present embodiments provide a novel DPA-producing Brassica juncea (DPA juncea) line designated as NUBJ1207. The embodiments also provide the seeds, the plants, and the plant parts (including DNA) of DPA juncea line NUBJ1207, as well as to methods for producing a Brassica plant produced by crossing DPA juncea line NUBJ1207 with itself or another Brassica line. These embodiments also provide methods for producing a DPA-producing Brassica plant containing in its genetic material one or more transgenes, and to the transgenic plants and plant parts produced by those methods. These embodiments further provide DPA production lines or breeding lines and plant parts derived from DPA juncea line NUBJ1207, to methods for producing canola lines or plant parts derived from line NUBJ1207, and to the DPA-producing Brassica plants, varieties, and their parts derived from use of those methods. These embodiments also provide hybrid seeds, plants, and plant parts produced by crossing the DPA juncea line NUBJ1207 with another Brassica or canola line.

The present invention relates to Brassica juncea ROD1 nucleic acid sequences and proteins and the use thereof to create plants with increased levels of C18:1 and reduced levels of saturated fatty acids in the seeds.

The invention relates to improved Brassica species, including Brassica juncea, improved oil and meal from Brassica juncea, methods for generation of such improved Brassica species, and methods for selection of Brassica lines. Further embodiments relate to seeds of Brassica juncea comprising an endogenous oil having increased oleic acid content and decreased linolenic acid content relative to presently existing commercial cultivars of Brassica juncea, seeds of Brassica juncea having traits for increased oleic acid content and decreased linolenic acid content in seed oil stably incorporated therein, and one or more generations of progeny plants produced from said seeds.

The present invention relates to a novel Brassica juncea varieties designated PWRG-1, PWRG-2, and PWSGC, which have a reduced pungent flavor and/or odor traits. The invention provides seeds of the varieties PWRG-1, PWRG-2, and PWSGC, plants and parts thereof of the varieties, a tissue culture derived from the varieties, hybrids produced from varieties, and lines derived from varieties, as well as genetically modified forms of the foregoing plants and tissue culture. Also provided are methods of producing PWRG-1, PWRG-2, and PWSGC plants, hybrid plants, and lines derived from varieties PWRG-1, PWRG-2, and PWSGC. In addition, products produced from the plants of the present invention are provided.

The present invention relates to Brassica juncea ROD1 nucleic acid sequences and proteins and the use thereof to create plants with increased levels of C18:1 and reduced levels of saturated fatty acids in the seeds.

Plants, plant parts and plant seeds that are resistant to imidazolinone herbicides are provided. Plants are disclosed that contain a mutation in an AHAS gene. Specifically, plants are disclosed that contain a mutant AHAS gene allele of the Brassica juncea B genome. Two B. juncea AHAS gene sequences (BjAHAS-a and BjAHAS-b) and one B. nigra AHAS gene sequence (BngrAHAS) are disclosed. The sequence of the mutant allele, BjAHAS-bR, is also disclosed. Various methods are disclosed that include creation of mutant B. juncea lines, selection for herbicide resistant lines and determining the presence of the BjAHAS-bR mutant allele after crosses.

The present invention relates to Brassica juncea ROD1 nucleic acid sequences and proteins and the use thereof to create plants with increased levels of C18:1 and reduced levels of saturated fatty acids in the seeds.

The present invention relates to a novel Brassica juncea varieties designated PWRG-1, PWRG-2, and PWSGC, which have a reduced pungent flavor and/or odor traits. The invention provides seeds of the varieties PWRG-1, PWRG-2, and PWSGC, plants and parts thereof of the varieties, a tissue culture derived from the varieties, hybrids produced from varieties, and lines derived from varieties, as well as genetically modified forms of the foregoing plants and tissue culture. Also provided are methods of producing PWRG-1, PWRG-2, and PWSGC plants, hybrid plants, and lines derived from varieties PWRG-1, PWRG-2, and PWSGC. In addition, products produced from the plants of the present invention are provided.

Plants, plant parts and plant seeds that are resistant to imidazolinone herbicides are provided. Plants are disclosed that contain a mutation in an AHAS gene. Specifically, plants are disclosed that contain a mutant AHAS gene allele of the Brassica juncea B genome. Two B. juncea AHAS gene sequences (BjAHAS-a and BjAHAS-b) and one B. nigra AHAS gene sequence (BngrAHAS) are disclosed. The sequence of the mutant allele, BjAHAS-bR, is also disclosed. Various methods are disclosed that include creation of mutant B. juncea lines, selection for herbicide resistant lines and determining the presence of the BjAHAS-bR mutant allele after crosses.

The present embodiments provide a novel DPA-producing Brassica juncea (DPA juncea) line designated as NUBJ1207. The embodiments also provide the seeds, the plants, and the plant parts (including DNA) of DPA juncea line NUBJ1207, as well as to methods for producing a Brassica plant produced by crossing DPA juncea line NUBJ1207 with itself or another Brassica line. These embodiments also provide methods for producing a DPA-producing Brassica plant containing in its genetic material one or more transgenes, and to the transgenic plants and plant parts produced by those methods. These embodiments further provide DPA production lines or breeding lines and plant parts derived from DPA juncea line NUBJ1207, to methods for producing canola lines or plant parts derived from line NUBJ1207, and to the DPA-producing Brassica plants, varieties, and their parts derived from use of those methods. These embodiments also provide hybrid seeds, plants, and plant parts produced by crossing the DPA juncea line NUBJ1207 with another Brassica or canola line.