Protein Backbone Dynamics through 13 C‘− 13 C α Cross-Relaxation in NMR Spectroscopy

## Abstract Carbonyl ^13^C relaxation experiments to study protein backbone dynamics have recently been developed. However, the effect of three‐bond ^13^C′–^13^C′ couplings on transverse relaxation measurements appears not to have been considered, and the potential to detect and quantify motions on

Internal motions play an important role in the biological function of proteins and NMR relaxation studies may characterize them over a wide range of frequencies. An experimental pulse scheme is proposed for the measurement of the 13C0-13C ~ cross-relaxation rate. For sensitivity reasons, this measur

Enantiomers and chira which differ clearly in their i3relaxation reagents (CRR) afford diastereomeric complexes, C spin-lattice relaxation times. Chiral lanthanide complexes and enantiomers are well known to form diastereomeric complexes

In principle, the relaxation of any proton ( 1 H ) , carbon carbon ( 13 C) relaxation in a 13 C, 15 N-doubly enriched sample ( 13 C ) , or nitrogen ( 15 N ) spin in a protein will contain of the thermostable Sso7d protein have been investigated. Pulse information about dynamics. The most common appl