Abstract
The zero- and double-quantum methyl TROSY Hahn-echo and the methyl 1H-1H dipole- dipole cross-correlation nuclear magnetic resonance experiments enable estimation of multiple quantum chemical exchange broadening in methyl groups in proteins. The two relaxation rate constants are established to be linearly dependent using molecular dynamics simulations and empirical analysis of experimental data. This relationship allows chemical exchange broadening to be recognized as an increase in the Hahn-echo relaxation rate constant. The approach is illustrated by analyzing relaxation data collected at three temperatures for E. coli ribonclease HI and by analyzing relaxation data collected for different cofactor and substrate complexes of E. coli AlkB.