Herein, we applied PmST1 (a sialyltransferase) to achieve acceptor-mediated regioselective sialylation (AMRS) on the nonreducing end GalNH2 or GalAz (N-azidogalactosamine). Thus, C5 and C8-modified sialic acid was efficiently assembled on...
Enzymes are important catalysts in biochemical reactions with superior regio, stereo, and substrate selectivity. However, enzymatic reaction systems have drawbacks including product inhibition, difficulty recycling, and poor stability. Importantly, the rate of an enzyme catalyzed reaction diminishes rapidly due to product inhibition and substrate depletion, making it difficult for many enzymes to catalyze a reaction to completion. The outcome is a mixture of unreacted substrates being present in the final reaction, necessitating additional separation steps that increase costs. This study presents a microfluidic reactor for accelerating enzyme catalyzed reactions using a countercurrent design that continuously removes products and adds fresh substrate into the reaction, allowing enzymes to operate under better reaction conditions. It demonstrates that countercurrent flow accelerates enzymatic reactions in our system up to 36 % for horseradish peroxidase and 21 % for β‐glucosidase compared to cocurrent flow, and the resulting reaction solution contains highly pure product with minimal substrate contamination.
Glycosphingolipids (GSLs) play essential roles in many important biological processes, making them attractive synthetic targets. In this paper, a viable chemoenzymatic method is described for the synthesis of globo-series GSLs, namely, Gb4, Gb5, SSEA-4, and Globo H. The strategy uses a chemically synthesized lactoside acceptor equipped with a partial ceramide structure that is uniquely extended by glycosyltransferases in a highly efficient one-pot multiple enzyme (OPME) procedure. A direct and quantitative conversion of Gb4 sphingosine to Globo H sphingosine is achieved by performing two-sequential OPME glycosylations. A reduction and N-acylation protocol allows facile incorporation of various fatty acids into the lipid portions of the GSLs. The chemically well-defined lipid-modified Globo H-GSLs displayed some differences in their immunosuppressive activities, which may benefit the structural modifications of Globo H ceramides in finding new types of immunosuppressive agents. The strategy outlined in this work should be applicable to the rapid access to other complex GSLs.
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