Double-Arm Lanthanide Tags Deliver Narrow Gd3+ -Gd3+ Distance Distributions in Double Electron-Electron Resonance (DEER) Measurements.

Abstract

Double-arm cyclen-based Gd3+ tags are shown to produce accurate nanometer scale Gd3+ -Gd3+ distance measurements in double electron-electron resonance (DEER) experiments by confining the space accessible to the metal ion. The results show excellent agreement with predictions both for the maximum and width of the measured distance distributions. For distance measurements in proteins, the tags can be attached to two cysteine residues located in positions i and i+4, or i and i+8, of an α-helix. In the latter case, an additional mutation introducing an aspartic acid at position i+4 achieves particularly narrow distribution widths. The concept is demonstrated with cysteine mutants of T4 lysozyme and maltose binding protein. We report the narrowest Gd3+ -Gd3+ distance distributions observed to date for a protein. By limiting the contribution of tag mobility to the distances measured, double-arm Gd3+ tags open new opportunities to study the conformational landscape of proteins in solution with high sensitivity.