Phosphates are regularly incorporated into bioactive small molecules, for example in sugar-1-phosphate derivatives that are used for metabolic oligosaccharide engineering. To enable efficient cellular uptake, the phosphate groups are commonly masked with biolabile S-acyl-2-thioethyl (SATE) protecting groups that are removed once the molecule is inside the cell. Typically, SATE-protected monophosphates are synthesised through phosphoramidite chemistry, which suffers from issues with hazardous and unstable reagents and can give unreliable yields. Here, we report the development of an alternative approach that makes use of an easy to synthesise tri(2-bromoethyl)phosphotriester precursor, providing access to bis-SATE-protected mixed phosphotriesters in two steps. We demonstrate the viability of our strategy on tetrabenzylated glucose as a model monosaccharide, onto which a bis-SATE-protected phosphate is introduced at either the anomeric position or at C6. We also show compability with various protecting groups and further explore the scope and limitations of the approach on different substrates, including N-acetylhexosamines and amino acid derivatives.
Robust methods for the synthesis of mixed phosphotriesters are essential to accelerate the development of novel phosphate-containing bioactive molecules. To enable efficient cellular uptake, phosphate groups are commonly masked with...
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