Abstract
X-ray crystallographic studies have shown that C-H groups of saccharides interact with aromatic amino acid residues in binding sites in proteins. Such C-H … pi interactions have been shown to be dominated by Londons dispersion interactions. The strength of interaction depends on a number of factors: (i) the nature of aromatic residue and saccharide, (ii) the form (acyclic, pyranose or furanose) and conformation of the saccharide, (iii) the functional groups present in modified saccharides (e.g., N-acetyl group), and (iv) the mutual position-orientation of the interacting moieties; this, in turn, determines the number of interacting C-H groups and the geometry of interaction. The strength of interaction also depends on the surrounding medium and on the microenvironment in a proteins binding sites. A variety of experimental techniques such as isothermal titration calorimetry, turbidity measurements, NMR spectroscopy, infrared ion depletion spectroscopy and fluorescence spectroscopy have been used to investigate C-H … pi interactions. Quantum chemical calculations of saccharide - aromatic systems have shown that their interaction is stabilizing. The interaction energy ranges between 1 and 12 kcal/mol and is thus comparable in strength to a conventional hydrogen bond. However, experiments that mimic double mutant cycles are needed to be designed, and performed, to determine the contribution of C-H … pi interactions to the affinity of glycans to proteins and the glycan specificity of proteins.
Keywords: Pyranose, furanose, dispersion interaction, apolar patch, stacking, X-ray crystallography, NMR spectroscopy
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