Dynamics and Hydration Properties of Small Antifreeze-Like Glycopeptides Containing Non-Natural Amino Acids

Novel studies on the synthesis and conformation in aqueous solution of three antifreeze‐like glycopeptides containing the sequence Xaa(α‐GalNAc)‐Ala‐Ala, with Xaa being threonine (Thr) or the non‐natural amino acids α‐methylserine (MeSer) or α‐methylthreonine (MeThr), are reported. The study has combined NMR experiments with molecular dynamics simulations. Whereas the Thr derivative is rather rigid in solution and exhibits an extended conformation for the backbone, the non‐natural glycopeptides are fairly flexible and show random coil structures for the peptide sequence. On the other hand, only those glycopeptides with a methyl group at Cβ of the underlying amino acid show perpendicular orientation of the sugar with respect to the peptide moiety. This structural feature, together with the rigidity of the Thr‐containing glycopeptide, makes this system unique to structure the water molecules of its first hydration shell. In addition, despite its chemical similarity, the different observed conformational behaviors of all these molecules, as well as the differences in their dynamics and hydration properties, make them suitable systems to shed light on the key factors that govern antifreeze activity. The synthesis and the conformational analysis of three antifreeze‐like glycopeptides containing a threonine (Thr) or the non‐natural amino acids α‐methylserine or α‐methylthreonine are reported. The different behaviors of these molecules in both dynamics and hydration properties makes them suitable systems to shed light on the key factors that govern antifreeze activity.