Abstract
Pulsed electron paramagnetic resonance dipolar spectroscopy (PDS) allows to measure the distances between electron spin centers and, in favorable cases, their relative orientation. This data is frequently used in structural biology for studying biomolecular structures, following their conformational changes and localizing paramagnetic centers within them. In order to extract the inter-spin distances and the relative orientation of spin centers from the primary, time-domain PDS signals, a specialized data analysis is required. So far, the software to do such analysis was available only for isotropic S = 1/2 spin centers, such as nitroxide and trityl radicals, as well as for high-spin Gd3+ and Mn2+ ions. Here, a new data analysis program, called AnisoDipFit, was introduced for spin systems consisting of one isotropic and one anisotropic S = 1/2 spin centers. The program was successfully tested on the PDS data corresponding to the spin systems Cu2+/organic radical, low-spin Fe3+/organic radical, and high-spin Fe3+/organic radical. For all tested spin systems, AnisoDipFit allowed determining the inter-spin distance distribution with a sub-angstrom precision. In addition, the spatial orientation of the inter-spin vector with respect to the g-frame of the metal center was determined for the last two spin systems. Thus, this study expands the arsenal of the PDS data analysis programs and facilitates the PDS-based distance and angle measurements on the highly relevant class of metolloproteins.
Highlights
Electron paramagnetic resonance spectroscopy (EPR) offers several pulsed techniques to measure nanometer-scale distances in condensed matter
In order to be applicable, paramagnetic resonance dipolar spectroscopy (PDS) requires that a biomolecule or a biomolecular complex contains at least two electron spin centers
The time traces that are obtained from these measurements can be usually translated into distance distributions by means of the programs such as DeerAnalysis [29], LongDistances [30], and DD [31]. These programs use the assumption that that the dipolar coupling between the electron spin centers is averaged over all possible orientations of the inter-spin vector ⃗r with respect to the applied static magnetic field B ⃗0 and, the dipolar spectrum, which is obtained from the Fourier transform of the PDS time trace, has the shape of a Pake doublet
Summary
Electron paramagnetic resonance spectroscopy (EPR) offers several pulsed techniques to measure nanometer-scale distances in condensed matter These techniques include pulsed electron–electron double resonance (PELDOR or DEER) [1, 2], double quantum coherence EPR (DQC) [3], single-frequency technique for refocusing dipolar couplings (SIFTER) [4], and relaxation induced dipolar modulation enhancement (RIDME) [5, 6].
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