The present invention provides methods and compositions for protein delivery. The invention features virus like particles, methods of making virus like particles and methods of using virus like particles to deliver proteins to a cell, to provide protein therapy and to treat diseases or disorders. The invention also features methods of targeting a protein to a cell, methods of protein therapy and methods of treating diseases or disorders using a TUS protein, a NLS or NES identified from full length TUS.

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 disclosure is generally directed to an anucleated cell-based platforms for encapsulation and delivery of agricultural compounds. Disclosed herein are compositions for the stable and targeted delivery of agricultural compounds within achromosomal and/or anucleated cells. The present disclosure also provides methods of improving encapsulation and retention of agricultural compounds in achromosomal and/or anucleated cells.

A series of protein A mutants having high alkali resistance, and methods of using the protein A mutants are provided. The protein A mutants have a high binding affinity for regions of immunoglobulin proteins other than the complementarity determining regions. The protein A mutants can be coupled to a solid support for immunoglobulin isolation, or conjugated to a label for immunoglobulin detection. This series of protein A mutants have high chemical stability under alkaline conditions of pH 13-14, and can also be used as chromatography ligands for purification procedures that use alkaline solutions under harsh conditions, such as Clean-In-Place (CIP). Also provided are methods of immunoglobulin separation and purification, and alkali regeneration of affinity chromatography medium that uses protein A as a ligand.

Compositions and methods are provided for producing materials having increased immunoglobulin binding capacities, the materials including full-length or truncated forms of protein A, protein G, protein A/G, protein L and other immunoglobulin-binding proteins or peptides, which moieties contain polypeptide domains, or polypeptide-oligopeptide combinations. Also provided are separation matrices containing the moieties and methods of using the separation matrices for separation of immunoglobulins or immunoglobulin containing proteins.

The present invention pertains to affinity chromatography isolation and purification of extracellular vesicles (EVs). The EVs of the present invention are engineered to enable highly specific binding to e.g. chromatography matrices, which is highly useful for affinity-based isolation and purification of EVs from complex biological fluids such as cell culture medium or biological fluids.

The present invention is within the field of protein engineering and purification. The invention relates to a target-binding polypeptide mutant of an IgG binding polypeptide, such as Protein A, Protein G, Protein L or Protein M, comprising a metal binding motif. More closely the invention relates to an Fc binding ligand comprising an engineered protein based on the Protein A derived Z domain, to which a calcium binding EF-loop has been introduced.

A series of protein A mutants having high alkali resistance, and methods of using the protein A mutants are provided. The protein A mutants have a high binding affinity for regions of immunoglobulin proteins other than the complementarity determining regions. The protein A mutants can be coupled to a solid support for immunoglobulin isolation, or conjugated to a label for immunoglobulin detection. This series of protein A mutants has high chemical stability under alkaline conditions of pH 13-14, and can also be used as chromatography ligands for purification procedures that use alkaline solutions under harsh conditions, such as Clean-In-Place (CIP). Also provided are methods of immunoglobulin separation and purification, and alkali regeneration of affinity chromatography medium that uses protein A as a ligand.

The present invention provides methods and compositions for protein delivery. The invention features virus like particles, methods of making virus like particles and methods of using virus like particles to deliver proteins to a cell, to provide protein therapy and to treat diseases or disorders. The invention also features methods of targeting a protein to a cell, methods of protein therapy and methods of treating diseases or disorders using a TUS protein, a NLS or NES identified from full length TUS.

The present disclosure provides compositions and methods for site-specific labeling of antibodies by proximity-based sortase-mediated ligation. The ligation method utilizes a non-canonical isopeptide ligation reaction catalyzed by newly identified variants of S. aureus sortase A. An antibody binding domain (e.g., protein A or protein G) is fused to the variants of SrtA to bring the enzyme into close proximity of an antibody, thereby significantly increases the efficiency of isopeptide bond formation.