A dual approach for improving homogeneity of a human-type N-glycan structure in Saccharomyces cerevisiae

Keyphrases

• Saccharomyces Cerevisiae 100%
• Dual Approach 100%
• N-glycan Structure 100%
• Complex Type 100%
• Glycans 60%
• Glycoengineering 60%
• Golgi Apparatus 40%
• N-glycosylation 40%
• UDP-N-acetylglucosamine Pyrophosphorylase 40%
• Host Organisms 20%
• Relative Abundance 20%
• High Homogeneity 20%
• Glycosylation 20%
• Glycoprotein 20%
• Expression System 20%
• Lipooligosaccharide 20%
• UDP-GlcNAc 20%
• N-acetylglucosamine 20%
• Humanized 20%
• Glycan Pattern 20%
• Non-mammalian 20%
• Therapeutic Protein Production 20%
• Glycoform 20%
• Glycoprotein Expression 20%
• N-glycosylation Pathway 20%
• Kluyveromyces Lactis 20%
• Humanization 20%
• N-glycan 20%
• Transferases 20%
• Relevant Protein 20%

INIS

• saccharomyces cerevisiae 100%
• strains 100%
• humans 100%
• proteins 60%
• host 40%
• glycoproteins 40%
• golgi apparatus 40%
• efficiency 20%
• yeasts 20%
• engineering 20%
• production 20%
• lipids 20%
• genes 20%
• imports 20%
• abundance 20%
• oligosaccharides 20%
• transferases 20%

Biochemistry, Genetics and Molecular Biology

• Polysaccharides 100%
• Saccharomyces cerevisiae 100%
• Glycosylation 66%
• N-Acetylglucosamine 66%
• Uridine Diphosphate 50%
• Glycoprotein 33%
• Golgi Apparatus 33%
• Glycoengineering 16%
• Lipid 16%
• Complex Formation 16%
• Gene Expression System 16%
• Kluyveromyces Lactis 16%
• Oligosaccharide 16%
• Transferase 16%