Journal
JOURNAL OF BIOMOLECULAR NMR
Volume 74, Issue 1, Pages 95-109Publisher
SPRINGER
DOI: 10.1007/s10858-019-00297-7
Keywords
Chemical exchange; Double-quantum; Lineshape analysis; Multiple-quantum; Titrations; Two-dimensional NMR; Zero-quantum
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Funding
- Arthritis Research UK [FC001029] Funding Source: Medline
- Cancer Research UK [FC001029] Funding Source: Medline
- Medical Research Council [MC_U117533887, FC001029] Funding Source: Medline
- Wellcome Trust [FC001029, 206409/Z/17/Z] Funding Source: Medline
- Wellcome Trust [206409/Z/17/Z] Funding Source: Wellcome Trust
- MRC [MC_U117533887] Funding Source: UKRI
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NMR spectroscopy provides a powerful approach for the characterisation of chemical exchange and molecular interactions by analysis of series of experiments acquired over the course of a titration measurement. The appearance of NMR resonances undergoing chemical exchange depends on the frequency difference relative to the rate of exchange, and in the case of one-dimensional experiments chemical exchange regimes are well established and well known. However, two-dimensional experiments present additional complexity, as at least one additional frequency difference must be considered. Here we provide a systematic classification of chemical exchange regimes in two-dimensional NMR spectra. We highlight important differences between exchange in HSQC and HMQC experiments, that on a practical level result in more severe exchange broadening in HMQC spectra, but show that complementary alternatives to the HMQC are available in the form of HZQC and HDQC experiments. We present the longitudinal relaxation optimised SOFAST-H(Z/D)QC experiment for the simultaneous acquisition of sensitivity-enhanced HZQC and HDQC spectra, and the longitudinal and transverse relaxation optimised BEST-ZQ-TROSY for analysis of large molecular weight systems. We describe the application of these experiments to the characterisation of the interaction between the Hsp90 N-terminal domain and a small molecule ligand, and show that the independent analysis of HSQC, HMQC, HZQC and HDQC experiments provides improved confidence in the fitted dissociation constant and dissociation rate. Joint analysis of such data may provide improved sensitivity to detect and analyse more complex multi-state interaction mechanisms such as induced fit or conformational selection.
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