The present invention discloses a method for breeding Brassica napus varieties and materials with a double haploid induction line of rapeseed, including: 1) determining target traits of breeding restorer lines, maintainer lines and conventional varieties of Brassica napus; 2) crossing or convergently crossing two or more Brassica napus with the target traits; 3) pollinating the cross or back-cross progenies with the double haploid induction line of rapeseed; 4) identifying the stability of the induced progenies; 5) performing test-cross identification or yield and resistance identification on the stable progenies; and 6) forming stable restorer lines and maintainer lines for cross breeding combination or for forming conventional varieties. The present invention can quickly and efficiently obtain rapeseed materials or conventional varieties with application value in breeding on a large scale, and lays a solid foundation for genetic breeding of Brassica napus, innovation of breeding resources, breeding of conventional rapeseed varieties, and breeding of new varieties of hybrid rapeseed. The method of the present invention can greatly improve the breeding speed and efficiency of hybrid or conventional varieties of Brassica napus, and reduce the human and material resources.

Provided herein are various aspects related to increasing the proportion of omega-3 fatty acid in seed oil produced by a plurality of Brassica plants, which have been modified to produce seed oil comprising at least one of EPA, DHA and DPA. It relates to a method to increase the proportion of long-chain omega-3 fatty acid in seed oil produced by a plurality of Brassica oilseed plants comprising growing the Brassica oilseed plants in the presence of an increased amount of nitrogen as compared to a standard amount of nitrogen, wherein the Brassica oilseed plants have been modified to produce seed oil with at least one of EPA, DHA and DPA.

Provided herein are various aspects related to increasing the proportion of omega-3 fatty acid in seed oil produced by a plurality of Brassica plants, which have been modified to produce seed oil comprising at least one of EPA, DHA and DPA. It relates to a method to increase the proportion of long-chain omega-3 fatty acid in seed oil produced by a plurality of Brassica oilseed plants comprising growing the Brassica oilseed plants in the presence of an increased amount of nitrogen as compared to a standard amount of nitrogen, wherein the Brassica oilseed plants have been modified to produce seed oil with at least one of EPA, DHA and DPA.

Provided is a canola variety designated 18GN0695L and seed, plants and plant parts thereof produced from a cross of inbred varieties. Methods for producing a canola variety comprise crossing canola variety 18GN0695L with another canola plant. Methods for producing a canola plant containing in its genetic material one or more traits introgressed into 18GN0695L through backcross conversion and/or transformation, and to the canola seed, plant and plant part produced thereby are described. Canola variety, the seed, the plant produced from the seed, plant parts and variants, mutants, and minor modifications of canola variety are disclosed.

Provided herein are materials and methods for developing elite or elite commercial varieties using the Thlaspi arvense cultivar 2032 and variety 182002-B-B-31, which demonstrate an improved shatter resistance trait and/or an early maturation trait. The use of these cultivars together with other plants and plant materials in the Brassicaceae family to develop additional varieties having the shatter resistance trait and/or early maturation trait are provided. Methods of gene editing, breeding, and using the same in breeding program are also provided.

Provided herein are materials and methods for developing elite or elite commercial varieties using the Thlaspi arvense cultivar 2032 and variety 182002-B-B-31, which demonstrate an improved shatter resistance trait and/or an early maturation trait. The use of these cultivars together with other plants and plant materials in the Brassicaceae family to develop additional varieties having the shatter resistance trait and/or early maturation trait are provided. Methods of gene editing, breeding, and using the same in breeding program are also provided.

The invention provides recombinant DNA molecules that are unique to Brassica Event MON94100 and transgenic Brassica plants, Brassica plant parts, Brassica seeds, Brassica cells, and agricultural products containing Brassica Event MON94100 as well as methods of using and detecting Brassica Event MON94100. Transgenic Brassica plants containing Brassica Event MON94100 exhibit tolerance to dicamba.

The invention provides recombinant DNA molecules that are unique to Brassica Event MON94100 and transgenic Brassica plants, Brassica plant parts, Brassica seeds, Brassica cells, and agricultural products containing Brassica Event MON94100 as well as methods of using and detecting Brassica Event MON94100. Transgenic Brassica plants containing Brassica Event MON94100 exhibit tolerance to dicamba.

The present invention includes broccoli plants with curds having detached florets and methods for obtaining such broccoli plants. The present invention also provides reagents that can be used in methods for obtaining such broccoli plants.

Pennycress (Thlaspi arvense) seed, seed lots, seed meal, and compositions with reduced glucosinolate content as well as plants that yield such seed, seed lots, seed meal, and compositions are provided. Methods of making and using the pennycress plants and/or seed that provide such seed, seed lots, seed meal, and compositions are also provided.