Solid-state NMR combined with sample deuteration was used to probe the proximity of the low-affinity substrate D-glucose to its binding site within the Escherichia coli sugar transport protein GalP. Samples of E. coli inner membranes with amplified expression of GalP were incubated in D(2)O with D-[(13)C(6)]glucose and (13)C NMR signals from the substrate were assigned in two-dimensional dipolar-assisted rotational resonance (DARR) spectra. The signals were confirmed as representing D-glucose bound to GalP as the peaks were abolished after the substrate was displaced from the specific site with the inhibitor forskolin. The (13)C chemical shift values for D-[(13)C(6)]glucose in solution revealed some differences compared to those for ligand bound to GalP, the differences being most pronounced for positions C1 and C2, and especially for C1 in the α-anomer. (13)C cross-polarization build-up was measured for C1 and C2 of D-[(13)C(6)]glucose and D-[(2)H(7), (13)C(6)]glucose in GalP membranes suspended in D(2)O. The build-up curves for the deuterated substrate reflect intermolecular (1)H-(13)C interactions between the protein and the fully deuterated substrate; the signal build-up suggests that the α-anomer is situated closer to the protein binding site than is the β-anomer, consistent with its relatively high signal intensities and more pronounced chemical shift changes in the 2D-correlation spectra. These results demonstrate the utility of solid-state NMR combined with sample deuteration for mapping the binding interface of low affinity ligands with membrane proteins.