Field-cycling NMR relaxometry is a well-established technique that can give information on molecular structure and dynamics of biological systems. It provides the nuclear relaxation rates as a function of the applied magnetic field, starting from fields as low as ~ 10−4 T up to about 1–3 T. The profiles so collected, called nuclear magnetic relaxation dispersion (NMRD) profiles, can be extended to include the relaxation rates at the largest fields achievable with high resolution NMR spectrometers. By exploiting this wide range of frequencies, the NMRD profiles can provide information on motions occurring on time scales from 10−6 to 10−9 s. 1H NMRD measurements have proved very useful also for the characterization of paramagnetic proteins, because they can help characterise a number of parameters including the number, distance and residence time of water molecules coordinated to the paramagnetic center, the reorientation correlation times and the electron spin relaxation time, and the electronic structure at the metal site.
Unveiling protein dynamics in solution with field-cycling NMR relaxometry / Parigi G.; Ravera E.; Fragai M.; Luchinat C.. - In: PROGRESS IN NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY. - ISSN 0079-6565. - STAMPA. - 124-125:(2021), pp. 85-98. [10.1016/j.pnmrs.2021.05.001]
Unveiling protein dynamics in solution with field-cycling NMR relaxometry
Parigi G.
;Ravera E.;Fragai M.;Luchinat C.
2021
Abstract
Field-cycling NMR relaxometry is a well-established technique that can give information on molecular structure and dynamics of biological systems. It provides the nuclear relaxation rates as a function of the applied magnetic field, starting from fields as low as ~ 10−4 T up to about 1–3 T. The profiles so collected, called nuclear magnetic relaxation dispersion (NMRD) profiles, can be extended to include the relaxation rates at the largest fields achievable with high resolution NMR spectrometers. By exploiting this wide range of frequencies, the NMRD profiles can provide information on motions occurring on time scales from 10−6 to 10−9 s. 1H NMRD measurements have proved very useful also for the characterization of paramagnetic proteins, because they can help characterise a number of parameters including the number, distance and residence time of water molecules coordinated to the paramagnetic center, the reorientation correlation times and the electron spin relaxation time, and the electronic structure at the metal site.I documenti in FLORE sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.