The present invention pertains to the field of agriculture. The invention relates to a method to inhibit gene expression in bacteria, which is referred to here as Antibacterial Gene Silencing (AGS). In particular embodiments, the method is used to protect plants against pathogenic bacteria by targeting pathogenicity factors and/or essential genes in a sequence-specific manner via small non-coding RNAs. The method can also be used to enhance beneficial effects and/or growth of plant-associated symbiotic or commensal bacteria. The invention involves either the generation of stable transgenic plants that constitutively express antibacterial small RNAs or, alternatively, the exogenous delivery of these small RNA entities onto plants, either in the form of RNA extracts or embedded into plant extracellular vesicles (EVs), which were found to be effective in reducing bacterial pathogenicity. The invention also describes a method to identify in a rapid, reliable and cost-effective manner, small RNAs that possess antibacterial activity and that can be further exploited for RNA-based biocontrol applications to confer plant protection against pathogenic bacteria. In addition, the latter approach is instrumental to rapidly characterize any genes from any bacterial species.

The invention relates to a method to inhibit gene expression in bacteria, which is referred to here as Antibacterial Gene Silencing (AGS). In particular embodiments, the method is used to protect plants and animals against pathogenic bacteria by targeting pathogenicity factors and/or essential genes in a sequence-specific manner via small non-coding RNAs. The method can also be used to enhance beneficial effects and/or growth of symbiotic or commensal bacteria. The invention involves the exogenous delivery of small RNA entities onto bacteria, either in the form of RNA extracts or embedded into plant extracellular vesicles (EVs), so as to reduce bacterial growth, survival and/or pathogenicity. The invention also describes a method to identify in a rapid, reliable and cost-effective manner, small RNAs that possess antibacterial activity and that have the potential to be further developed as anti-infective agents. In addition, the latter method is instrumental to rapidly characterize any gene from any bacterial species.

Provided herein is a plant comprising an exogenous polynucleotide encoding a JIM2 polypeptide. In some embodiments, the plants have enhanced resistance to at least one species of Xanthomonas.

Compositions and methods for enhancing disease resistance in plants are disclosed.

The present invention relates to methods and compositions for transforming soybean, corn, cotton, or canola explants using spectinomycin as a selective agent for transformation of the explants. The method may further comprise treatment of the explants with cytokinin during the transformation and regeneration process.

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.

The invention relates to a method for increasing the yield and biomass of a plant, by means of an increase in the expression of the L-aspartate oxidase in the plant. The method according to the invention allows an increase in the photosynthetic capacities of the plants as a result of an increase in the quantities of NAO and the derivatives thereof in said plants. The invention relates to the plants produced by such a method.

The disclosure provides stable antimicrobial (e.g., antibacterial or antifungal or both) peptides (SAMPs) that may be used in methods of preventing or treating a bacterial disease (e.g., a Liberibacter disease, such as citrus greening disease (also called Huanglongbing (HLB)) or potato Zebra Chip disease, and other bacterial diseases such as those caused by Agrobacterium tumefaciens (also known as Rhizobium radiobacter) and Pseudomonas syringae) in plants (e.g., citrus plants or potato plants). SAMPs disclosed herein may be heat stable, as well as stable in plant extracts and/or in plant lysates (e.g., citrus lysates).

Disclosed herein our novel methods of increasing resistance of Citrus plants to diseases, in particular, citrus canker disease caused by Xanthomonas citri ssp. citri and Huanglongbing disease. Some embodiments relate to novel methods of altering gene sequence, structure and expression of certain disease susceptibility genes in the Citrus plant. Other embodiments relate to gene constructs equipped to be introduced into Citrus cells and direct modifications to target gene sequences.

The invention relates to a method for increasing the yield and biomass of a plant, by means of an increase in the expression of the L-aspartate oxidase in the plant. The method according to the invention allows an increase in the photosynthetic capacities of the plants as a result of an increase in the quantities of NAD and the derivatives thereof in said plants. The invention relates to the plants produced by such a method.