Backbone dynamics of barstar: A 15N NMR relaxation study

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 We have investigated slow correlated motions of neighboring carbonyl and nitrogen nuclei in the backbone of chicken villin headpiece subdomain. Cross‐correlated chemical shift modulation experiments were performed at three temperatures where the protein remains in its folded state. The

3 NMR data are reported for 42 szoles, taken mostly at a standard concentration and in a common solvent (0.5 M dimethyl sulfoxide with a 0.01 M increment of Cr(acac), for each nitrogen atom present). Signal assignments were assisted by comparison witb ' " N line widths, the use of zJ(15N'H) coupling

## Synopsis Spin-spin and spin-lattice 'H-nmr relaxation times of the sea anemone polypeptide anthopleurin-A were measured at frequencies of 200, 300, 400, and 500 MHz. Relaxation times were fitted iteratively by least squares regression to the isotropic tumbling model, Woessner's model for anisot

## Abstract The ^15^N‐labelled iron dinitrogen complexes __trans__‐[FeH(N~2~)(PP)~2~]^+^[BPh~4~]^−^ (PP = dppe, depe, dmpe) and __cis__‐[FeH(N~2~)(PP~3~)]^+^[BPh~4~]^−^ were prepared __in situ__ by exchange of unlabelled coordinated dinitrogen with ^15^N~2~. ^15^N NMR chemical shifts and coupling c

In the work reported herein we define a structure validation factor that depends on protein backbone 15 N relaxation rates. This is an alternative method to the previously defined quality factors derived from anisotropic chemical shifts or residual dipolar couplings. We have used the structure depen