The A method of modifying a glycosylation pattern of a polypeptide-of-interest in a plant or plant cell is provided. The method comprising expressing in a plant or plant cell transformed to express at least one glycosidase in a subcellular compartment, a nucleic acid sequence encoding the polypeptide-of-interest, such that the at least one glycosidase and the polypeptide-of-interest are co-localized to the subcellular compartment of the plant or plant cell, thereby modifying the glycosylation pattern of the polypeptide-of-interest in the plant or plant cell.

The present invention describes the plant-based production of a therapeutic anti-virus antibody.

Methods for preserving viability of plant tissues such as plant embryos are provided herein. Also included are methods for storing genomic DNA and/or molecular marker assay materials in an oil bilayer as part of a high-throughput molecular characterization system. Moreover, plant embryos may be treated while in an oil matrix. The treatment may include chromosome doubling, Agrobacterium-mediated transformation, or herbicide selection as part of an embryo rescue process.

Methods and compositions for targeting the insertion of a polynucleotide of interest into a specific chromosomal site in the genome of a plant cell using bacteria-mediated transformation methods are provided. The methods include providing a plant cell with at least one Transfer Cassette comprising in operable linkage a least one polynucleotide construct and at least one recombinase construct, and optionally at least one cell proliferation factor construct. Compositions provided include plant cells, plants or seeds having a polynucleotide of interest inserted at a specific chromosomal site.

Cosmos Bipinnatus cotyledons are isolated as explants, and the isolated explants are cultured onto a regeneration medium to obtain regenerated Cosmos Bipinnatus shoots. The regeneration medium optionally includes a basal medium, a cytokinin, an ethylene action inhibitor, and a nitrogen source.

Example embodiments in accordance with the present disclosure are directed to methods comprising contacting a plant part with a nucleotide sequence encoding a gene that induces plant cell matrix (PCM) formation, and culturing the plant part under growth conditions to enhance PCM formation.

This invention relates to methods for the transformation of Setaria species such as Setaria viridis and transformed plants produced according to the method. Specifically, this invention relates to direct transformation of callus derived from mature embryos using Agrobacterium-mediated transformation, and plants regenerated from the transformed callus tissue. The methods comprise utilizing Setaria mature embryos as the source of plant material for callus induction; induced calli can be infected by Agrobacterium hosting an appropriate vector. Transgenic plants are regenerated from transgenic calli grown under conditions favoring growth of transformed cells while substantially inhibiting growth of non-transformed cells. These methods provide for significantly increased plant transformation efficiency with minimal ratio of escapes.

Improved methods of producing nucleic acid molecules, proteins and peptides in host cells and genetically engineered plants, vectors and constructs therefor.

Compositions and methods and for enhancing the resistance of wheat plants to wheat stem rust caused by Puccinia graminis f. sp. tritici are provided. The compositions comprise nucleic acid molecules encoding resistance (R) gene products and variants thereof and plants, seeds, and plant cells comprising such nucleic acid molecules. The methods for enhancing the resistance of a wheat plant to wheat stem rust comprise introducing a nucleic acid molecule encoding an R gene product into a wheat plant cell. Additionally provided are methods for using the wheat plants in agriculture to limit wheat stem rust.

Methods and compositions for Ochrobactrum-mediated transformation of plants are provided. Methods include but are not limited to using an Ochrobactrum strain to transfer a polynucleotide of interest to a plant cell. These include VirD2-dependent methods. Compositions include an Ochrobactrum strain, transfer DNAs, constructs and/or plasmids. These include Ochrobactrum strains having a plasmid comprising one or more virulence gene(s), border region, and/or origin of replication. Plant cells, tissues, plants, and seeds comprising a polynucleotide of interest produced by the methods are also provided.