Abstract

Here we report two phase modulated NMR experiments: PM-2D HN(CACBHB) and PM-2D HN(HB), that use 1Hβ chemical shifts to rapidly identify amino acid type in proteins. The magnetization on the 1Hβ spins during the experiments is allowed to evolve for a fixed evolution period that results in phase modulation (positive or negative) of the cross peaks corresponding to various amino acid residues on their 2D HN projections, resembling a typical 2D [1H–15N]-HSQC spectrum. All amino acids except glycine can be categorized into three discernible groups based on their 1Hβ chemical shifts, resulting in unique phase patterns at different fixed evolution periods for 1Hβ, thus facilitating their identification. Remarkably, the PM-2D HN(HB) stands out among all amino acid type identification NMR techniques for its applicability with cost-effective and most routinely employed 15N-labeled protein samples for NMR studies. Furthermore, when combined effectively with the 13Cβ chemical shift-based phase modulated NMR method (PM-2D HN(CACB)), these methods resolved the identification of large groups of amino acids into relatively smaller groups. Moreover, these techniques can accelerate the sequence-specific sequential resonance assignment (SSRA) process and would help in fast tracking of assigned NMR signals exhibiting chemical shift perturbation on the 2D [1H–15N]-HSQC spectrum of proteins during various experiments (e.g., temperature change, pH change, and protein or ligand or cofactor binding) as well as in site-directed mutagenesis.

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