Abstract
Signal-enhancement techniques for NMR spectroscopy are important to amplify the weak resonances provided by nuclear spins. Recently, ‘hyperpolarization’ techniques have been intensively investigated. These provide nuclear spin states far from equilibrium yielding strong signal boosts up to four orders of magnitude. Here we propose a method for real-time NMR of ‘hyperpolarized’ proteins at residue resolution. The approach is based on dissolution dynamic nuclear polarization (d-DNP), which enables the use of hyperpolarized buffers that selectively boost NMR signals of solvent-exposed protein residues. The resulting spectral sparseness and signal enhancements enable recording of residue-resolved spectra at a 2 Hz sampling rate. Thus, we monitor the hyperpolarization level of different protein residues simultaneously under near-physiological conditions. We aim to address two points: 1) NMR experiments are often performed under conditions that increase sensitivity but are physiologically irrelevant; 2) long signal accumulation impedes fast real-time monitoring. Both limitations are of fundamental relevance to ascertain pharmacological relevance and study protein kinetics.
Highlights
Signal-enhancement techniques for nuclear magnetic resonance (NMR) spectroscopy are important to amplify the weak resonances provided by nuclear spins
To adequately describe processes that evolve over time, methods are required that improve NMR signal intensities and, at the same time, capitalize on the method’s intrinsically high resolution
We here propose such a method based on dissolution dynamic nuclear polarization-boosted NMR and spin hyperpolarization[12,13,14]
Summary
Signal-enhancement techniques for NMR spectroscopy are important to amplify the weak resonances provided by nuclear spins. This is not least because nuclear magnetic resonance (NMR) spectroscopy, the central method to access protein structures in solution, typically focuses on systems in chemical equilibrium[10,11] This limitation is imposed by weak signal intensities that necessitate long signal averaging periods and impede time-resolved studies. To adequately describe processes that evolve over time, methods are required that improve NMR signal intensities and, at the same time, capitalize on the method’s intrinsically high (atomistic) resolution We here propose such a method based on dissolution dynamic nuclear polarization (dDNP)-boosted NMR and spin hyperpolarization[12,13,14].
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
