The present invention belongs to the field of plant genetic engineering. Specifically, the invention relates to a method for base editing in plants. More particularly, the invention relates to a method for performing efficient base editing to a target sequence in the genome of a plant (such as a crop plant) by a Cas9-cytidine deaminase fusion protein, as well as plants produced through said method and progenies thereof.

The invention provides methods and compositions for identifying transgenic seed that contain a transgene of interest, but lack a marker gene. Use of an identification sequence that results in a detectable phenotype increases the efficiency of screening for seed and plants in which transgene sequences not linked to a gene of interest have segregated from the sequence encoding a gene of interest.

This disclosure describes, in one aspect, a cell that includes a biocontainment system. Generally, the biocontainment system includes a coding region whose overexpression decreases growth of the cell, a transcription regulatory region that includes a silent mutation and is operably linked upstream of the coding region, and a polynucleotide that encodes a programmable transcription activator engineered to bind to the transcription regulatory region in the absence of the silent mutation. Thus, in the absence of the silent mutation, the programmable transcription activator induces overexpression of the coding region; in the presence of the silent mutation, the programmable transcription activator does not initiate overexpression of the coding region.

The invention provides methods and compositions for identifying transgenic seed that contain a transgene of interest, but lack a marker gene. Use of an identification sequence that results in a detectable phenotype increases the efficiency of screening for seed and plants in which transgene sequences not linked to a gene of interest have segregated from the sequence encoding a gene of interest.

The present invention provides plant virus vectors developed from the Foxtail mosaic virus (FoMV). The vectors include a nucleic acid sequence encoding an infectious Foxtail mosaic virus (FoMV) with a functional movement encoding sequence operably linked to one or more regulatory elements functional in a plant. The plant virus vectors may be used to infect monocot plants, such as maize and can be used for VIGS, gene editing, gene expression or other transgenic protocols.

Methods and compositions for improving plant resistance by expression of NPR homolog 3 (NH3) polypeptides are provided.

Described are synthetic promoters capable of mediating gene expression in plants upon pathogen infection. Furthermore, recombinant genes and vectors comprising said chimeric promoters as well as host cells transformed with such chimeric promoters, recombinant genes, or vectors are provided. Additionally, diagnostic compositions and kits comprising such chimeric promoters, recombinant genes, vectors or cells are described. Provided are further methods for the identification of compounds being capable of activating or inhibiting genes that are specifically expressed in plants upon pathogen infection employing the above described means. Furthermore, transgenic plant cells, plant tissue, and plants containing the above-described chimeric promoters, recombinant genes, and vectors as well as the use of the aforementioned chimeric promoters, recombinant genes, vectors and/or compounds identified by the method of the invention in plant cell and tissue culture, plant breeding, and/or agriculture are described.

The invention provides methods and compositions for identifying transgenic seed that contain a transgene of interest, but lack a marker gene. Use of an identification sequence that results in a detectable phenotype increases the efficiency of screening for seed and plants in which transgene sequences not linked to a gene of interest have segregated from the sequence encoding a gene of interest.

This disclosure describes, in one aspect, a cell that includes a biocontainment system. Generally, the biocontainment system includes a coding region whose overexpression decreases growth of the cell, a transcription regulatory region that includes a silent mutation and is operably linked upstream of the coding region, and a polynucleotide that encodes a programmable transcription activator engineered to bind to the transcription regulatory region in the absence of the silent mutation. Thus, in the absence of the silent mutation, the programmable transcription activator induces overexpression of the coding region; in the presence of the silent mutation, the programmable transcription activator does not initiate overexpression of the coding region.

In one aspect, a transgenic plant cell includes a biocontainment system that includes: a coding region whose overexpression alters growth of the cell or impairs cell division; a transcription regulatory region operably linked upstream of the coding region, and including a mutation; and a polynucleotide that encodes a programmable transcription activator engineered to bind to the transcription regulatory region in the absence of the mutation after sexual reproduction, thereby overexpressing the coding region in the absence of the mutation, but does not initiate overexpression of the coding region when the transcription regulatory region includes the mutation.