Site-direct spin labeling combined with electron paramagnetic resonance (EPR) spectroscopy is a powerful tool for detecting structural changes in proteins. This review provides examples that illustrate strategies for interpreting the data in terms of specific rearrangements in secondary and tertiary structure. The changes in the mobility and solvent accessibility of the spin label side chains, and in the distances between spin labels, report (i) rigid body motions of -helices and -strands (ii) relative movements of domains and (iii) changes in secondary structure. Such events can be monitored in the millisecond timescale, making it possible to follow structural changes during function. There is no upper limit to the size of proteins that can be investigated, and only 50−100 picomoles of protein are required. These features make site-directed spin labeling an attractive approach for the study of structure and dynamics in a wide range of systems.
-helices and 
-strands (ii) relative movements of domains and (iii) changes in secondary structure. Such events can be monitored in the millisecond timescale, making it possible to follow structural changes during function. There is no upper limit to the size of proteins that can be investigated, and only 50−100 picomoles of protein are required. These features make site-directed spin labeling an attractive approach for the study of structure and dynamics in a wide range of systems.
