International audienceSolid-state NMR spectroscopy can provide site-resolved information about protein dynamics over many time scales. Here we combine protein deuteration, fast magic-angle spinning (~45-60kHz) and proton detection to study dynamics of ubiquitin in microcrystals, and in particular a mutant in a region that undergoes microsecond motions in a β-turn region in the wild-type protein. We use (15)N R1ρ relaxation measurements as a function of the radio-frequency (RF) field strength, i.e. relaxation dispersion, to probe how the G53A mutation alters these dynamics. We report a population-inversion of conformational states: the conformation that in the wild-type protein is populated only sparsely becomes the predominant state. We furthermore explore the potential to use amide-(1)H R1ρ relaxation to obtain insight into dynamics. We show that while quantitative interpretation of (1)H relaxation remains beyond reach under the experimental conditions, due to coherent contributions to decay, one may extract qualitative information about flexibility

Gauto, Diego

Hessel, Audrey

Kurauskas, Vilius

Linser, Rasmus

Rovó, Petra

Schanda, Paul

Solid State Nuclear Magnetic Resonance

Diego F. Gauto

Audrey Hessel

Petra Rovó

Vilius Kurauskas

Rasmus Linser

Paul Schanda

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Protein conformational dynamics studied by 15 N and 1 H R 1ρ relaxation dispersion: Application to wild-type and G53A ubiquitin crystals

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Protein conformational dynamics studied by (15)N and (1)H R1ρ relaxation dispersion: Application to wild-type and G53A ubiquitin crystals.

Archive Ouverte en Sciences de l'Information et de la Communication

Hal - Université Grenoble Alpes

Solid-state NMR spectroscopy can provide site-resolved information about protein dynamics over many time scales. Here we combine protein deuteration, fast magic-angle spinning (~45–60 kHz) and proton detection to study dynamics of ubiquitin in microcrystals, and in particular a mutant in a region that undergoes microsecond motions in a β-turn region in the wild-type protein. We use 15N R1ρ relaxation measurements as a function of the radio-frequency (RF) field strength, i.e. relaxation dispersion, to probe how the G53A mutation alters these dynamics. We report a population-inversion of conformational states: the conformation that in the wild-type protein is populated only sparsely becomes the predominant state. We furthermore explore the potential to use amide-1H R1ρ relaxation to obtain insight into dynamics. We show that while quantitative interpretation of 1H relaxation remains beyond reach under the experimental conditions, due to coherent contributions to decay, one may extract qualitative information about flexibility

Gauto, D.

Hessel, A.

Kurauskas, V.

Linser, R.

Schanda, P.

MPG.PuRe

Figure S1. 2D HN correlation spectrum of G53A MPD-ub with resonance assignments. We were unable to unambiguously assign the cross-peaks of several residues, noted below. Unless stated otherwise the reason why these residues were not assigned was that the corresponding cross-peaks in the 3D experiments were either too weak for detection or the corresponding 13C frequencies did not allow unambiguous assignment.M1: presumably due to fast solvent exchange also invisible in solutionL8, T9: due to fast transverse relaxation induced by the loop motion (note the fast relaxation of the neighboring G10 and K11.E16, I23, Q31, Q40.The cross-peak of residue V5 is overlapped with T66, and H68 overlaps with T7 (not labeled here).Figure S2. Comparison of HN correlation spectra of WT ubiquitin (black) and G53A ubiquitin (red;the latter is the same as in Figure S1.). The correlation peaks labeled with an asterisk at a 1Hfrequency of 7.25 ppm are aliased in the 15N dimension.Figure S3. HN correlation spectrum of wild-type ubiquitin, recorded under different conditions (45kHz MAS, 850 MHz 1H Larmor frequency, 301 K sample temperature) and using a different samplethan used in this study, as reported in reference:Schanda, P., Meier, B. H. & Ernst, M. Quantitative Analysis of Protein Backbone Dynamics inMicrocrystalline Ubiquitin by Solid-State NMR Spectroscopy. J. Am. Chem. Soc. 132, 15957–15967 (2010).Figure S4, shown on the next ten pages: 15N R1ρ relaxation-dispersion profiles of G53A ubiquitincrystals. See Figure 5 and the main text for details. In addition to the data shown in the main paper (Figure 5, shown here in red), we have performedanother independent experiment, at the same MAS frequency but at a slightly different temperature(ca. 3-5 degrees lower). This experiment was motivated by the realization that there was a small butdetectable fluctuation in the R1ρ data point of some residues (a “dip” around 3 kHz, see Figure 5).Although this effect is small and of no practical relevance for the conclusions made in this study,and we wanted to investigate whether this was a reproducible effect. This additional data set, shownas green data points, does not show any sign of fluctuation, excluding any relevant systematiceffect. The new data set differs primarily for those residues which undergo conformationalexchange, and this finding further confirms the dynamic (and therefore temperature-dependent)origin of these relaxation dispersion profiles.Figure S5. 1H R1ρ relaxation data obtained with a sample of wild-type ubiquitin which was re-protonated at exchangeable sites to 35% and deuterated otherwise, performed at a MAS frequencyof 35 kHz and a 1H Larmor frequency of 800 MHz. This figure is the equivalent of Figure 8 of themain paper, at a different B0 field strength. (a) Example relaxation dispersion profiles, i.e.1H R1ρ asa function of the applied RF field strength, for four selected residues (all residues are shown inFigure S6). (b) Residue-wise values of 1H R1ρ rate constants obtained using a1H RF spin-lock fieldstrength of 8 kHz. (c) Difference of the rate constants obtained with 34 kHz RF field strength and 8kHz RF field strength, providing a rapid qualitative view which residues show the largest dispersioneffects. As expected from the known microsecond mobility in this region, residues in the β-turnshow the largest effects.Figure S6 and Figure S7, both of which span two pages, are shown on the next four pages:Figure S6. All 1H R1ρ relaxation data obtained with wild-type ubiquitin crystals at 44.053 kHz and600 MHz 1H Larmor frequency. See Figure 8 text for details.Figure S7. All 1H R1ρ relaxation data obtained with wild-type ubiquitin crystals at 35  kHz and 800MHz 1H Larmor frequency. This figure extends on the data shown in Figure S4.0 10 20 30 40050100150200Q20 10 20 30 40050100150200I30 10 20 30 40050100150200F40 10 20 30 40050100150200V50 10 20 30 40050100150200K60 10 20 30 40050100150200T70 10 20 30 40050100150200G100 10 20 30 40050100150200T120 10 20 30 40050100150200T140 10 20 30 40050100150200L150 10 20 30 40050100150200E160 10 20 30 40050100150200V170 10 20 30 40050100150200E180 10 20 30 40050100150200S200 10 20 30 40050100150200D210 10 20 30 40050100150200T220 10 20 30 40050100150200I230 10 20 30 40050100150200V260 10 20 30 40050100150200K270 10 20 30 40050100150200A280 10 20 30 40050100150200K290 10 20 30 40050100150200I300 10 20 30 40050100150200Q310 10 20 30 40050100150200D320 10 20 30 40050100150200K330 10 20 30 40050100150200E340 10 20 30 40050100150200G350 10 20 30 40050100150200D391H spin-lock field strength (kHz)1 HR1ρdecayrateconstant(s-1)0 10 20 30 40050100150200Q400 10 20 30 40050100150200Q410 10 20 30 40050100150200R420 10 20 30 40050100150200L430 10 20 30 40050100150200I440 10 20 30 40050100150200F450 10 20 30 40050100150200A460 10 20 30 40050100150200G470 10 20 30 40050100150200K480 10 20 30 40050100150200Q490 10 20 30 40050100150200L500 10 20 30 40050100150200E510 10 20 30 40050100150200D520 10 20 30 40050100150200G530 10 20 30 40050100150200R540 10 20 30 40050100150200T550 10 20 30 40050100150200L560 10 20 30 40050100150200S570 10 20 30 40050100150200D580 10 20 30 40050100150200Y590 10 20 30 40050100150200N600 10 20 30 40050100150200I610 10 20 30 40050100150200Q620 10 20 30 40050100150200K630 10 20 30 40050100150200E640 10 20 30 40050100150200S650 10 20 30 40050100150200T660 10 20 30 40050100150200L670 10 20 30 40050100150200H680 10 20 30 40050100150200L690 10 20 30 40050100150200V701H spin-lock field strength (kHz)1 HR1ρdecayrateconstant(s-1)0 10 20 30 40 50050100150200Q20 10 20 30 40 50050100150200I30 10 20 30 40 50050100150200F40 10 20 30 40 50050100150200V50 10 20 30 40 50050100150200K60 10 20 30 40 50050100150200T70 10 20 30 40 50050100150200G100 10 20 30 40 50050100150200T120 10 20 30 40 50050100150200T140 10 20 30 40 50050100150200L150 10 20 30 40 50050100150200E160 10 20 30 40 50050100150200V170 10 20 30 40 50050100150200E180 10 20 30 40 50050100150200S200 10 20 30 40 50050100150200D210 10 20 30 40 50050100150200T220 10 20 30 40 50050100150200I230 10 20 30 40 50050100150200V260 10 20 30 40 50050100150200K270 10 20 30 40 50050100150200A280 10 20 30 40 50050100150200K290 10 20 30 40 50050100150200I300 10 20 30 40 50050100150200Q310 10 20 30 40 50050100150200D320 10 20 30 40 50050100150200K330 10 20 30 40 50050100150200E340 10 20 30 40 50050100150200G350 10 20 30 40 50050100150200D391H spin-lock field strength (kHz)1 HR1ρdecayrateconstant(s-1)0 10 20 30 40 50050100150200Q400 10 20 30 40 50050100150200Q410 10 20 30 40 50050100150200R420 10 20 30 40 50050100150200L430 10 20 30 40 50050100150200I440 10 20 30 40 50050100150200F450 10 20 30 40 50050100150200A460 10 20 30 40 50050100150200G470 10 20 30 40 50050100150200K480 10 20 30 40 50050100150200Q490 10 20 30 40 50050100150200L500 10 20 30 40 50050100150200E510 10 20 30 40 50050100150200D520 10 20 30 40 50050100150200G530 10 20 30 40 50050100150200R540 10 20 30 40 50050100150200T550 10 20 30 40 50050100150200L560 10 20 30 40 50050100150200S570 10 20 30 40 50050100150200D580 10 20 30 40 50050100150200Y590 10 20 30 40 50050100150200N600 10 20 30 40 50050100150200I610 10 20 30 40 50050100150200Q620 10 20 30 40 50050100150200K630 10 20 30 40 50050100150200E640 10 20 30 40 50050100150200S650 10 20 30 40 50050100150200T660 10 20 30 40 50050100150200L670 10 20 30 40 50050100150200H680 10 20 30 40 50050100150200L690 10 20 30 40 50050100150200V701H spin-lock field strength (kHz)1 HR1ρdecayrateconstant(s-1)

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Protein conformational dynamics studied by 15N and 1H R1ρ relaxation dispersion: Application to wild-type and G53A ubiquitin crystals.

Protein conformational dynamics studied by (15)N and (1)H R1ρ relaxation dispersion: Application to wild-type and G53A ubiquitin crystals.

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