Abstract
We present a strategy for stereospecific NMR assignment of Hβ2 and Hβ3 protons in mid-size proteins (~150 residues). For such proteins, resonance overlap in standard experiments is severe, thereby preventing unambiguous assignment of a large fraction of β-methylenes. To alleviate this limitation, assignment experiments may be run in high static fields, where higher decoupling power is required. Three-bond Hα–Hβ J-couplings (3JHα–Hβ) are critical for stereospecific assignments of β-methylene protons, and for determining rotameric χ1 states. Therefore, we modified a pulse sequence designed to measure accurate 3JHα–Hβ couplings such that probe heating was reduced, while the decoupling performance was improved. To further increase the resolution, we applied non-uniform sampling (NUS) schemes in the indirect 1H and 13C dimensions. The approach was applied to two medium-sized proteins, odorant binding protein 22 (OBP22; 14.4 kDa) and Pin1 (18.2 kDa), at 900 MHz polarizing fields. The coupling values obtained from NUS and linear sampling were extremely well correlated. However, NUS decreased the overlap of Hβ2/3 protons, thus supplying a higher yield of extracted 3JHα-Hβ coupling values when compared with linear sampling. A similar effect could be achieved with linear prediction applied to the linearly sampled data prior to the Fourier transformation. Finally, we used 3JHα–Hβ couplings from Pin1 in combination with either conventional or exact nuclear Overhauser enhancement (eNOE) restraints to determine the stereospecific assignments of β-methylene protons. The use of eNOEs further increased the fraction of unambiguously assigned resonances when compared with procedures using conventional NOEs.
Highlights
Stereospecific assignment of methylene protons is a prerequisite for detailed structural and dynamic NMR studies of proteins [1]
For the comparison of the linear and non-uniform sampling (NUS) sampling schemes, we recorded the HACAHB-COSY with identical overall running times, but sampled only 50% of the points, resulting in ca. 60% and 25% extensioMnasgnoetfocthhemeismtrya2x01im8, 4u, xmFOeRvPoElEuRtRioEnVIEtiWmes in the indirect 1H and 13C dimensions, respec6tiovf e14ly
We tested an efficient strategy for the assignment of Hβ2 and Hβ3 chemical shifts for proteins larger than 150 residues
Summary
Stereospecific assignment of methylene protons is a prerequisite for detailed structural and dynamic NMR studies of proteins [1]. Assignments of Hβ2 and Hβ3 are usually achieved from a combined use of three-bond Hα–Hβ J-couplings (3JHα–Hβ), and nuclear Overhauser enhancement (NOE) intensities [2]. In addition to stereospecific assignments of methylene-proton resonances in NOESY spectra, accurate measurement of 3JHα–Hβ couplings may be directly used for χ1 dihedral angle determination via Karplus relationships [1]. We modified a previously described pulse sequence designed for accurate measurement of 3JHα–Hβ couplings such that a substantial increase in spectral resolution was achieved. While Pin is a mitotic regulator of phosphoproteins, it is involved in many other functions including protein folding, intracellular signaling, and transcription [17] It is often overexpressed in cancer, yet has reduced activity in Alzheimer’s disease. Combining these constraints with eNOEs aided in solving a high-quality, multi-state ensemble
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