The present invention relates to excision of explant material comprising meristematic tissue from seeds, and storage of such material prior to subsequent use in plant tissue culture and genetic transformation. Methods for tissue preparation, storage, and transformation are disclosed, as is transformable meristem tissue produced by such methods, and apparati for tissue preparation.

Compositions and methods for improving plastid transformation in difficult to transform plants are disclosed.

The subject invention provides novel plants that are not only resistant to 2,4-D and other phenoxy auxin herbicides, but also to aryloxyphenoxypropionate herbicides. Heretofore, there was no expectation or suggestion that a plant with both of these advantageous properties could be produced by the introduction of a single gene. The subject invention also includes plants that produce one or more enzymes of the subject invention alone or “stacked” together with another herbicide resistance gene, preferably a glyphosate resistance gene, so as to provide broader and more robust weed control, increased treatment flexibility, and improved herbicide resistance management options. More specifically, preferred enzymes and genes for use according to the subject invention are referred to herein as AAD (aryloxyalkanoate dioxygenase) genes and proteins. No α-ketoglutarate-dependent dioxygenase enzyme has previously been reported to have the ability to degrade herbicides of different chemical classes and modes of action. This highly novel discovery is the basis of significant herbicide tolerant crop trait opportunities as well as development of selectable marker technology. The subject invention also includes related methods of controlling weeds. The subject invention enables novel combinations of herbicides to be used in new ways. Furthermore, the subject invention provides novel methods of preventing the formation of, and controlling, weeds that are resistant (or naturally more tolerant) to one or more herbicides such as glyphosate.

The subject invention provides novel plants that are not only resistant to 2,4-D and other phenoxy auxin herbicides, but also to aryloxyphenoxypropionate herbicides. Heretofore, there was no expectation or suggestion that a plant with both of these advantageous properties could be produced by the introduction of a single gene. The subject invention also includes plants that produce one or more enzymes of the subject invention alone or “stacked” together with another herbicide resistance gene, preferably a glyphosate resistance gene, so as to provide broader and more robust weed control, increased treatment flexibility, and improved herbicide resistance management options. More specifically, preferred enzymes and genes for use according to the subject invention are referred to herein as AAD (aryloxyalkanoate dioxygenase) genes and proteins. No α-ketoglutarate-dependent dioxygenase enzyme has previously been reported to have the ability to degrade herbicides of different chemical classes and modes of action. This highly novel discovery is the basis of significant herbicide tolerant crop trait opportunities as well as development of selectable marker technology. The subject invention also includes related methods of controlling weeds. The subject invention enables novel combinations of herbicides to be used in new ways. Furthermore, the subject invention provides novel methods of preventing the formation of, and controlling, weeds that are resistant (or naturally more tolerant) to one or more herbicides such as glyphosate.

It is an object of the present invention to provide a method for introducing a protein into a plant, which is simple and extensively applicable to various types of plant cells and proteins. The above object is achieved by the present invention to provide a complex comprising a protein of interest to be introduced into a target plant cell and a carrier peptide, a method for introducing a protein of interest into a target plant cell using the complex, and a kit comprising a protein of interest to be introduced into a target plant cell and a carrier peptide.

The present invention relates to an expression control element and expression system comprising same, particularly to an expression control element regulated by a polyamine or polyamine analogue, host cells and eukaryotic organisms comprising same and methods of use thereof.

This invention provides a method for generating transgenic plants with a low copy number. Plant cells are transformed with polynucleotides containing transcriptional cassettes designed to trigger silencing of a gene which is essential for the plant cell to survive the transformation and regeneration process. The present invention enables the recovery of an increased number of transgenic plants which have only one copy of each desired transcriptional cassette.

A fertility restoration gene in wheat and uses thereof, belonging to the field of plant biotechnology, specifically relating to the cloning of a recessive nuclear male sterility gene and a promoter thereof, and uses thereof in hybrid breeding. The fertility restoration gene FRG1 was successfully cloned by flow cytometry and high-throughput sequencing. The FRG1 gene can completely restore the male fertility of a Lanzhou genic male sterile mutant or allelic mutants thereof, which lays a foundation for the construction of a new wheat hybrid breeding technology system, meanwhile, which provides more possibilities to solve the technical bottlenecks of “three lines” and “two lines” hybridization technology of wheat, such as unstable fertility of sterile lines, limited resources for hybrid variety, the complexity of seed production technology and the high cost of seed production. The provided gene and method for propagation and maintenance of the sterile line have important significance and application value for hybrid breeding in wheat.

A method for site-specific mutagenesis of Medicago sativa genes by using a CRISPR/Cas9 system. The method comprises: first constructing a binary expression vector MsCRISPR/Cas9 that can be used for transforming Medicago sativa by Agrobacterium tumefaciens; then designing a target site for a target gene, and ligating the DNA fragment containing the guide sequence of the target site into MsCRISPR/Cas9 to construct a vector MsCRISPR/Cas9::target; and then transforming the Medicago sativa by Agrobacterium tumefaciens, and generating, by screening, a mutant transformed plant with the target gene mutated. According to the method, an MtU6 promoter is used for driving sgRNA transcription in the Medicago sativa.

Spectinomycin resistant or streptomycin resistant transgenic plants and methods of making such plants are provided.