Selective Interface Detection: Mapping Binding Site Contacts in Membrane Proteins by NMR Spectroscopy

Abstract

Intermolecular contact surfaces are important regions where specific interactions mediate biological function. We introduce a new magic angle spinning solid state NMR technique, dubbed “selective interface detection spectroscopy” (SIDY). In this technique, ¹³C-attached protons (¹H_lig) are dephased by ¹H−¹³C REDOR. A spin diffusion period is then used to enhance long distance ¹H− ¹H correlations, and the results are detected by a short period of cross polarization to the ¹³C isotope labels. This SIDY approach allows selective observation of the interface between ¹³C-labeled and unlabeled moieties. We have used SIDY to probe the ligand−protein binding surface between a uniformly isotopically labeled ligand cofactor, U-¹³C₂₀-11-cis-retinal, and its binding site in rhodopsin (Rho), an unlabeled, membrane-embedded G-protein coupled receptor (GPCR). The observed ¹H_GPCR−¹³C_lig correlations indicate multiple close contacts between the protein and the ionone ring of the ligand, in agreement with binding studies. The polyene tail of the ligand displays fewer strong correlations in the SIDY spectrum. Some correlations can be assigned to the protein side chains lining the ligand binding site, in agreement with the crystal structure.