NMR spectroscopy is a pivotal technique to measure hydrogen exchange rates in proteins. However, currently available NMR methods to measure backbone exchange are limited to rates of up to a few per second. To raise this limit, we have developed an approach that is capable of measuring proton exchange rates up to approximately 104 s-1 . Our method relies on the detection of signal loss due to the decorrelation of antiphase operators 2Nx Hz by exchange events that occur during a series of pi pulses on the 15 N channel. In practice, signal attenuation was monitored in a series of 2D H(CACO)N spectra, recorded with varying pi-pulse spacing, and the exchange rate was obtained by numerical fitting to the evolution of the density matrix. The method was applied to the small calcium-binding protein Calbindin D9k , where exchange rates up to 600 s-1 were measured for amides, where no signal was detectable in 15 N-1 H HSQC spectra. A temperature variation study allowed us to determine apparent activation energies in the range 47-69 kJ mol-1 for these fast exchanging amide protons, consistent with hydroxide-catalyzed exchange.
Keywords: NMR spectroscopy; hydrogen exchange; kinetics; protein folding; spin−spin decorrelation.
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