W-Band pulse EPR distance measurements in peptides using Gd3+–dipicolinic acid derivatives as spin labels

Abstract

We present high field DEER (double electron–electron resonance) distance measurements using Gd³⁺ (S = 7/2) spin labels for probing peptides' conformations in solution. The motivation for using Gd³⁺ spin labels as an alternative for the standard nitroxide spin labels is the sensitivity improvement they offer because of their very intense EPR signal at high magnetic fields. Gd³⁺ was coordinated by dipicolinic acid derivative (4MMDPA) tags that were covalently attached to two cysteine thiol groups. Cysteines were introduced in positions 15 and 27 of the peptide melittin and then two types of spin labeled melittins were prepared, one labeled with two nitroxide spin labels and the other with two 4MMDPA–Gd³⁺ labels. Both types were subjected to W-band (95 GHz, 3.5 T) DEER measurements. For the Gd³⁺ labeled peptide we explored the effect of the solution molar ratio of Gd³⁺ and the labeled peptide, the temperature, and the maximum dipolar evolution time T on the DEER modulation depth. We found that the optimization of the [Gd³⁺]/[Tag] ratio is crucial because excess Gd³⁺ masked the DEER effect and too little Gd³⁺ resulted in the formation of Gd³⁺-tag₂ complexes, generating peptide dimers. In addition, we observed that the DEER modulation depth is sensitive to spectral diffusion processes even at Gd³⁺ concentrations as low as 0.2 mM and therefore experimental conditions should be chosen to minimize it as it decreases the DEER effect. Finally, the distance between the two Gd³⁺ ions, 3.4 nm, was found to be longer by 1.2 nm than the distance between the two nitroxides. The origin and implications of this difference are discussed.