The disclosure provides a modified protein that is a combination of (i) an L-asparaginase and (ii) one or more (poly)peptide(s), wherein the (poly)peptide consists solely of proline and alanine amino acid residues, and methods of preparation and use thereof.

The disclosure provides a modified protein that is a combination of (i) an L-asparaginase and (ii) one or more (poly)peptide(s), wherein the (poly)peptide consists solely of proline and alanine amino acid residues, and methods of preparation and use thereof.

Disclosed is a conjugate of a protein having substantial L-asparagine aminohydrolase activity and polyethylene glycol. In particular, the polyethylene glycol has a molecular weight less than or equal to about 5000 Da and the protein is an L-asparaginase from Erwinia. The conjugate of the invention has shown superior properties such as maintenance of a high level of in vitro activity and an unexpected increase in half-life in vivo. Also disclosed are methods of producing the conjugate and use of the conjugate in therapy. In particular, a method is disclosed for use of the conjugate in the treatment of cancer, particularly Acute Lymphoblastic Leukemia (ALL). More specifically, a method is disclosed for use of the conjugate as a second line therapy for patients who have developed hypersensitivity or have had a disease relapse after treatment with other L-asparaginase preparations.

Disclosed is a conjugate of a protein having substantial L-asparagine aminohydrolase activity and polyethylene glycol. In particular, the polyethylene glycol has a molecular weight less than or equal to about 5000 Da and the protein is an L-asparaginase from Erwinia. The conjugate of the invention has shown superior properties such as maintenance of a high level of in vitro activity and an unexpected increase in half-life in vivo. Also disclosed are methods of producing the conjugate and use of the conjugate in therapy. In particular, a method is disclosed for use of the conjugate in the treatment of cancer, particularly Acute Lymphoblastic Leukemia (ALL). More specifically, a method is disclosed for use of the conjugate as a second line therapy for patients who have developed hypersensitivity or have had a disease relapse after treatment with other L-asparaginase preparations.

Provided herein are methods of production of recombinant Erwinia asparaginase. Methods herein produce asparaginase having high expression levels in the periplasm or the cytoplasm of the host cell having activity comparable to commercially available asparaginase preparations.

Provided herein are methods of production of recombinant Erwinia asparaginase. Methods herein produce asparaginase having high expression levels in the periplasm or the cytoplasm of the host cell having activity comparable to commercially available asparaginase preparations.

The present invention relates to a novel, economically viable, storage stable, lyophilized composition of pegaspargase. The composition comprises pegaspargase, a cryoprotectant, a bulking agent, a buffer and may optionally contain other pharmaceutically acceptable excipients including but not limited to a salt. The composition of the present invention is stable for extended periods over significant range of temperatures, without the presence of any significant amount of impurities. The present invention also relates to an economically viable and scalable lyophilization process for the production of the storage stable composition of pegaspargase.

Described are a genetically modified microorganism and corresponding methods and products. The genetically modified microorganism may include a first gene that encodes an acyl transferase and a second gene that encodes a peptide or protein. One or both of the first and second gene may be heterologous. The genetically modified microorganism may include a modified acyl-CoA biosynthetic pathway configured for one or more of: inducible biosynthesis of an acyl-CoA and over-accumulation of the acyl-CoA. The genetically modified microorganism may be effective upon fermentation to cause acylation of the peptide or protein by the acyl transferase using the acyl-CoA to provide a N-acylated peptide or protein product.

Described are a genetically modified microorganism and corresponding methods and products. The genetically modified microorganism may include a first gene that encodes an acyl transferase and a second gene that encodes a peptide or protein. One or both of the first and second gene may be heterologous. The genetically modified microorganism may include a modified acyl-CoA biosynthetic pathway configured for one or more of: inducible biosynthesis of an acyl-CoA and over-accumulation of the acyl-CoA. The genetically modified microorganism may be effective upon fermentation to cause acylation of the peptide or protein by the acyl transferase using the acyl-CoA to provide a N-acylated peptide or protein product.

The present application discloses a PEGylated asparaginase and use thereof. In this application, the polyethylene glycol (PEG) is coupled to the N-terminal amino of 1 or 2 subunits of L-asparaginase, and the molecular weight of the PEG is 30-40 KDa. The PEG is preferably branched and has an aldehyde serving as an activating group. The PEGylated asparaginase is useful in the preparation of anti-tumor drugs.