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Toward protein NMR at physiological concentrations by hyperpolarized water—Finding and mapping uncharted conformational spaces

Ludovica M. Epasto, Kateryna Che, Fanny Kozak, Albina Selimović, Pavel Kadeřávek, Dennis Kurzbach

2022Science Advances22 citationsDOIOpen Access PDF

Abstract

Nuclear magnetic resonance (NMR) spectroscopy is a key method for determining the structural dynamics of proteins in their native solution state. However, the low sensitivity of NMR typically necessitates nonphysiologically high sample concentrations, which often limit the relevance of the recorded data. We show how to use hyperpolarized water by dissolution dynamic nuclear polarization (DDNP) to acquire protein spectra at concentrations of 1 μM within seconds and with a high signal-to-noise ratio. The importance of approaching physiological concentrations is demonstrated for the vital MYC-associated factor X, which we show to switch conformations when diluted. While in vitro conditions lead to a population of the well-documented dimer, concentrations lowered by more than two orders of magnitude entail dimer dissociation and formation of a globularly folded monomer. We identified this structure by integrating DDNP with computational techniques to overcome the often-encountered constraint of DDNP of limited structural information provided by the typically detected one-dimensional spectra.

Topics & Concepts

Nuclear magnetic resonance spectroscopyDimerNMR spectra databaseNuclear magnetic resonanceChemistryPopulationTwo-dimensional nuclear magnetic resonance spectroscopyDissociation (chemistry)DissolutionSpectral lineChemical physicsBiophysicsPhysicsBiologyPhysical chemistryDemographyAstronomySociologyAdvanced NMR Techniques and ApplicationsSolid-state spectroscopy and crystallographyDNA and Nucleic Acid Chemistry
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