The invention provides compositions and methods for engineering bacteria to produce sialylated and N-acetylglucosamine-containing oligosaccharides, and the use thereof in the prevention or treatment of infection.

The present invention is in the field of a method for production of biomedical compounds by enrichment cultures of microorganisms, and a product obtainable by said methods. The microorganisms are grown in a batch reactor, a continuous reactor, a semi-continuous reactor, such as a Nereda® reactor.

The present invention is directed to a cell-free system for producing a glycosylated protein. This system comprises an isolated oligosaccharyltransferase capable of transferring a glycan from a lipid carrier molecule to a glycoprotein target, one or more isolated glycans, where each glycan is linked to a lipid carrier molecule, and a glycoprotein target comprising one or more glycan acceptor amino acid residues or a nucleic acid molecule encoding said glycoprotein target. The present invention further relates to kits and methods for producing a glycosylated protein in this cell-free system.

The present invention relates to methods for reducing antennary fucosylation of complex N-glycans in recombinantly expressed glycoproteins, cell lines that can be used in said methods, respective recombinant glycoproteins, and methods for expressing the same in said cell lines.

Disclosed are components, systems, and methods for glycoprotein protein synthesis in vitro and in vivo. In particular, the disclosed components, systems, and methods relate to modular platforms for producing glycoproteins. The components, systems, and methods disclosed herein may be used in synthesizing glycoproteins and recombinant glycoproteins in cell-free protein synthesis (CFPS) and in modified cells.

The present invention relates to the finding of methods to shift the glycosylation profile of recombinant produced serum glycoproteins to the predominant bi-antennary form found in human plasma. This is accomplished by providing a mammalian cell line according to the invention with a series of gene disruptions and/or gene insertions that facilitate this shift.

Aspects of the disclosure relate to compositions and methods for expressing one or more Ganglioside GM3 synthase (GM3S) isoforms in a cell or subject. In some aspects, the disclosure relates to methods for treating GM3 synthase deficiency in a subject in need thereof.

α2-6-Sialyltransferase (2,6ST) variants having improved α2-6-specific sialidase activity as compared to the native 2,6ST enzymes are described. The variants include GT80 sialyltransferases such as P. damselae Pd2,6ST. Methods for making de-sialylated products and screening sialidase activity are also described.

Herein is reported a method for the enzymatic production of an antibody with a modified glycosylation in the Fc-region comprising the steps of incubating the antibody light chain affinity ligand-bound monoclonal antibody with a glycosylation in the Fc-region with a first enzyme for a time sufficient and under conditions suitable to modify the glycosylation of the Fc-region, recovering the antibody from the antibody light chain affinity ligand, incubating the recovered antibody in solution with a second enzyme for a time sufficient and under conditions suitable to modify the glycosylation of the Fc-region to a defined form, separating the antibody with the modified glycosylation in the Fc-region from the second enzyme in a cation exchange chromatography, and thereby producing the antibody with a modified glycosylation in the Fc-region.

The present disclosure is directed to the properties of certain glycosyltransferase variants having N-terminal truncation deletions or internal deletions. Any of the mutants disclosed in here exhibit α-2,6-sialyltransferase enzymatic activity in the presence of CMP-activated sialic acid as co-substrate, and in the presence of a suitable acceptor site. A fundamental finding documented in the present disclosure is that such enzyme are not only capable of catalyzing transfer of a sialidyl moiety but they are also capable of catalyzing hydrolytic cleavage of terminally bound sialic acid from a glycan.