Chemistry-enabled glycoscience
University Of Southern California, Los Angeles CA
Investigators
Abstract
ABSTRACT - âChemistry-Enabled Glycoscienceâ Overall changes in glycosylation are associated with many human diseases. Cancer cells increase the levels of speciï¬c capping sugars on their surfaces, while levels of the intracellular glycan O-GlcNAc are lower in Alzheimer's disease. Some of these associative changes are being exploited as potential therapies. However, a deeper understanding of what glycosylation is doing to the biochemistry and function of the underlying proteins is still largely lacking. For example, thousands of proteins are modiï¬ed by O-GlcNAc but the eï¬ects of the vast majority of these modiï¬cations are completely unknown. For several reasons - heterogeneity, multiple modiï¬cation sites, low immunogenicity, etc. - traditional biological tools have limitations for glycosylation. We have built a research program centered around the development and application of chemistry-enabled approaches aimed at unanswered questions in glycoscience. For example, we have played an important role improving and applying bioorthogonal reporters of glycans in living systems. We are also leaders in the application of protein synthesis to generate site-speciï¬cally glycosylated proteins for for in vitro and even in vivo characterization. We plan to build upon these successes to a) generate and apply cell/ tissue-selective reporters and inhibitors of glycosylation, b) create activity based probes of monosaccharide biosynthesis, c & d) further understand the eï¬ects of O-GlcNAc on pathogenic protein-aggregation, and e) investigate the consequences of mucin glycans on apolipoproteins. In the next ï¬ve years, we will have created and used new tools for glycoscience in living systems and further unraveled the mechanisms by which glycosylation changes the biology of important proteins in human diseases.
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