Speeding up direct 15N detection: hCaN 2D NMR experiment

Experiments detecting low gyromagnetic nuclei have recently been proposed to utilize the relatively slow relaxation properties of these nuclei in comparison to ¹H. Here we present a new type of ¹⁵N direct-detection experiment. Like the previously proposed CaN experiment (Takeuchi et al. in J Biomol NMR 47:271–282, 2010), the hCaN experiment described here sequentially connects amide ¹⁵N resonances, but utilizes the initial high polarization and the faster recovery of the ¹H nucleus to shorten the recycling delay. This allows recording 2D ¹⁵N-detected NMR experiments on proteins within a few hours, while still obtaining superior resolution for ¹³C and ¹⁵N, establishing sequential assignments through prolines, and at conditions where amide protons exchange rapidly. The experiments are demonstrated on various biomolecules, including the small globular protein GB1, the 22 kDa HEAT2 domain of eIF4G, and an unstructured polypeptide fragment of NFAT1, which contains many SerPro sequence repeats.