1. Site-Specific Synthesis of Cysteine-Bridged Glycoproteins via Expressed Protein Glycoligation
- Author
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Philip Garner, Nicholas Holloran, Minseob Koh, Upendra A. Rathnayake, Daniel Collins, ChulHee Kang, and Bixia Zhang
- Subjects
Models, Molecular ,Glycan ,Glycosylation ,Biomedical Engineering ,Pharmaceutical Science ,Bioengineering ,02 engineering and technology ,Thioester ,01 natural sciences ,chemistry.chemical_compound ,Affinity chromatography ,Escherichia coli ,Cysteine ,Solid-Phase Synthesis Techniques ,Glycoproteins ,Pharmacology ,Gel electrophoresis ,chemistry.chemical_classification ,biology ,010405 organic chemistry ,Chemistry ,Organic Chemistry ,021001 nanoscience & nanotechnology ,Native chemical ligation ,0104 chemical sciences ,Biochemistry ,Biocatalysis ,biology.protein ,0210 nano-technology ,Glycoprotein ,Biotechnology - Abstract
Site-specific glycosylation of a functional recombinant protein thioester is reported. The thioester functionalized protein sfGFP-Y151ThioD, prepared by genetic code expansion, underwent native chemical ligation with the cysteine-conjugated glycans H-Cys-NH-GlcNAc and H-Cys-NH-(GlcNAc)2(Man)3 to give the corresponding cysteine-bridged glycoproteins. The intact glycoproteins, which retained their fluorescence, were characterized by top-down mass spectrometry and gel electrophoresis. The bridging cysteine provided a convenient handle for affinity chromatography purification of the glycoproteins via a removable biotin tag. Given the influence that specific glycoforms can have on a protein's function, the ability to attach a homogeneous glycan to an intact protein in a functional group controlled yet sequon-independent manner could find widespread application. These preliminary results set the stage for development of the expressed protein glycoligation (EPG) concept.
- Published
- 2020