Direct 13C-detection for carbonyl relaxation studies of protein dynamics

## 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

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

## Abstract RNA and DNA molecules experience motions on a wide range of time scales, ranging from rapid localized motions to much slower collective motions of entire helical domains. The many functions of RNA in biology very often require this molecule to change its conformation in response to biol

13CC(-13C0 homonuclear NOE and 13CO T~ relaxation were measured for a 20 kDa protein using tripleresonance pulse sequences. The experiments were sufficiently sensitive to obtain statistically significant differences in relaxation parameters over the molecule. The 13C%13C0 cross-relaxation rate, obta