1. Structural origin of weakly ordered nitroxide motion in spin-labeled proteins.
- Author
-
Fleissner MR, Cascio D, and Hubbell WL
- Subjects
- Bacteriophage T4 enzymology, Crystallography, X-Ray, Disulfides chemistry, Electron Spin Resonance Spectroscopy, Models, Molecular, Muramidase chemistry, Protein Conformation, Protein Interaction Domains and Motifs, Temperature, Viral Proteins chemistry, Nitrogen Oxides chemistry, Proteins chemistry, Spin Labels
- Abstract
A disulfide-linked nitroxide side chain (R1) used in site-directed spin labeling of proteins often exhibits an EPR spectrum characteristic of a weakly ordered z-axis anisotropic motion at topographically diverse surface sites, including those on helices, loops and edge strands of beta-sheets. To elucidate the origin of this motion, the first crystal structures of R1 that display simple z-axis anisotropic motion at solvent-exposed helical sites (131 and 151) and a loop site (82) in T4 lysozyme have been determined. Structures of 131R1 and 151R1 determined at cryogenic or ambient temperature reveal an intraresidue C(alpha)--H...S(delta) interaction that immobilizes the disulfide group, consistent with a model in which the internal motions of R1 are dominated by rotations about the two terminal bonds (Columbus, Kálai, Jeko, Hideg, and Hubbell, Biochemistry 2001;40:3828-3846). Remarkably, the 131R1 side chain populates two rotamers equally, but the EPR spectrum reflects a single dominant dynamic population, showing that the two rotamers have similar internal motion determined by the common disulfide-backbone interaction. The anisotropic motion for loop residue 82R1 is also accounted for by a common disulfide-backbone interaction, showing that the interaction does not require a specific secondary structure. If the above observations prove to be general, then significant variations in order and rate for R1 at noninteracting solvent-exposed helical and loop sites can be assigned to backbone motion because the internal motion is essentially constant.
- Published
- 2009
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