Domain Flexibility in Ligand-Free and Inhibitor-Bound<i>Escherichia coli</i>Adenylate Kinase Based on a Mode-Coupling Analysis of<sup>15</sup>N Spin Relaxation

Shapiro, Yury E.; Kahana, Edith; Tugarinov, Vitali; Liang, Zhichun; Freed, Jack H.; Meirovitch, Eva

doi:10.1021/bi012132q

Cited by 71 publications

(257 citation statements)

References 50 publications

(200 reference statements)

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“…The parameters of the ITS model were obtained by minimizing the following target function: (16) where for each of the N residues included in the sum, is the value of ρ derived directly from the experimental data according to the first equality in Eq. 13 and is obtained by substituting into the second equality in Eq.…”

Section: Fitting Procedures and Parametersmentioning

confidence: 99%

A Model of Interdomain Mobility in a Multidomain Protein

2007

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Domain mobility plays essential role in the biological function of multidomain systems. The characteristic times of domain motions fall into the interval from nano-to milliseconds, amenable to NMR studies. Proper analysis of NMR relaxation data for these systems in solution has to account for interdomain motions, in addition to the overall tumbling and local intradomain dynamics. Here we propose a model of interdomain mobility in a multi-domain protein, which considers domain reorientations as exchange/interconversion between two distinct conformational states of the molecule, combined with fully anisotropic overall tumbling. Analysis of 15 N-relaxation data for Lys48-linked di-ubiquitin at pH4.5 and 6.8 showed that this model adequately fits the experimental data and allows characterization of both structural and motional properties of di-ubiquitin, thus providing information about the relative orientation of ubiquitin domains in both interconverting states. The analysis revealed that the two domains reorient on a time scale of 9-30 ns, with the amplitudes sufficient for allowing a protein ligand access to the binding sites sequestered at the interface in the closed conformation. The analysis of possible mechanism controlling the equilibrium between the interconverting states in di-ubiquitin points toward protonation of His68, which results in three different charged states of the molecule, with zero, +e, and +2e net charge. Only two of the three states are noticeably populated at pH4.5 or 6.8, which assures applicability of the two-state model to di-ubiquitin at these conditions. We also compare our model with the "extended modelfree" approach and discuss possible future developments of the model.

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Section: Fitting Procedures and Parametersmentioning

confidence: 99%

A Model of Interdomain Mobility in a Multidomain Protein

2007

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“…[16][17][18][19][20][21][22][23] Two rotators, representing the global motion of the protein, R C , and the local motion of the probe (C-D bond in this case), R L , are treated. The motions of the protein and the probe are coupled by a local potential, U(Ω C'M ), where C' denotes the local director fixed in the protein, and M the local ordering/local diffusion frame fixed in the probe.…”

Section: The Slowly Relaxing Local Structure (Srls) Modelmentioning

confidence: 99%

“…[16][17][18][19][20][21][22][23] This has been accomplished by applying to NMR spin relaxation in proteins 16 the Slowly Relaxing Local Structure (SRLS) approach of Freed and co-workers. [24][25][26] SRLS can be considered the generalization of MF, yielding the latter in asymptotic limits.…”

Section: Introductionmentioning

confidence: 99%

“…It features explicitly local motional modes parallel and perpendicular to the methyl rotation axis. [16][17][18][19][20][21][22][23]25,26 and accounts rigorously for the tilt between a rhombic local ordering frame, M, and the magnetic frame, Q. The Euler angles Ω C'M , which relate the M frame to a local director frame, C' (e.g., the equilibrium C-CH 3 orientation), are governed by the coupling/ ordering potential.…”

Section: Introductionmentioning

confidence: 99%

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An Improved Picture of Methyl Dynamics in Proteins from Slowly Relaxing Local Structure Analysis of ²H Spin Relaxation

et al. 2007

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Protein dynamics is intimately related to biological function. Core dynamics is usually studied with 2 H spin relaxation of the 13 CDH 2 group, analyzed traditionally with the model-free (MF) approach. We showed recently that MF is oversimplified in several respects. This includes the assumption that the local motion of the dynamic probe and the global motion of the protein are decoupled, the local geometry is simple, and the local ordering has axial symmetry. Because of these simplifications MF has yielded a puzzling picture where the methyl rotation axis is moving rapidly with amplitudes ranging from nearly complete disorder to nearly complete order in tightly packed protein cores. Our conclusions emerged from applying to methyl dynamics in proteins the slowly relaxing local structure (SRLS) approach of Polimeno and Freed (J. Phys. Chem. 1995, 99, 1099), which can be considered the generalization of MF, with all the simplifications mentioned above removed. The SRLS picture derived here for the B1 immunoglobulin binding domain of peptostreptococcal protein L, studied over the temperature range of 15 − 45 °C, is fundamentally different from the MF picture. Thus, methyl dynamics is characterized structurally by rhombic local potentials with varying symmetries, and dynamically by tenfold slower rates of local motion. On average potential rhombicity decreases, mode-coupling increases and the rate of local motion increases with increasing temperature. The average activation energy for local motion is 2.0 ± 0.2 kcal/mol. Mode-coupling affects the analysis even at 15 o C. The accuracy of the results is improved by including in the experimental data set relaxation rates associated with rank 2 coherences. Keywords slowly relaxing local structure; methyl dynamics in proteins; NMR spin relaxation in proteins

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“…Nuclear Magnetic Resonance (NMR) is a powerful tool to study protein dynamics over a wide range of timescales [1,2]. Hydrodynamic properties of proteins in solution and dynamics occurring faster than a few nanoseconds are usually measured by the quantitative analysis of 15 N relaxation rates [2][3][4][5]. These rates depend both on the overall rotational diffusion in solution as well as fast backbone motions on a subnanosecond timescale through their effects on the spectral density functions [6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

On the measurement of 15N–{1H} nuclear Overhauser effects

Ferrage

Piserchio

Cowburn

et al. 2008

Journal of Magnetic Resonance

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Accurate quantification of the 15 N-{ 1 H} steady-state NOE is central to current methods for the elucidation of protein backbone dynamics on the fast, sub-nanosecond timescale. This experiment is highly susceptible to systematic errors arising from multiple sources. The nature of these errors and their effects on the determined NOE ratio is evaluated by a detailed analysis of the spin dynamics during the pair of experiments used to measure this ratio and possible improvements suggested. The experiment that includes 1 H irradiation, is analyzed in the framework of Average Liouvillian Theory and a modified saturation scheme that generates a stable steady state and eliminates the need to completely saturate 1 H nuclei, is presented. The largest source of error, however, in 1 H-dilute systems at ultra-high fields is found to be an overestimation of the steadystate NOE value as a consequence of the incomplete equilibration of the magnetization in the socalled "reference experiment". The use of very long relaxation delays is usually an effective, but time consuming, solution. Here, we introduce an alternative reference experiment, designed for larger, deuterated systems, that uses the fastest relaxing component of the longitudinal magnetization a closer approximation to the equilibrium state for shorter relaxation delays. The utility of the modified approach is illustrated through simulations on realistic spin-systems over a wide range of timescales and experimentally verified using a perdeuterated sample of human ubiquitin.

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Domain Flexibility in Ligand-Free and Inhibitor-BoundEscherichia coliAdenylate Kinase Based on a Mode-Coupling Analysis of¹⁵N Spin Relaxation

Cited by 71 publications

References 50 publications

A Model of Interdomain Mobility in a Multidomain Protein

A Model of Interdomain Mobility in a Multidomain Protein

An Improved Picture of Methyl Dynamics in Proteins from Slowly Relaxing Local Structure Analysis of ²H Spin Relaxation

On the measurement of 15N–{1H} nuclear Overhauser effects

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Domain Flexibility in Ligand-Free and Inhibitor-BoundEscherichia coliAdenylate Kinase Based on a Mode-Coupling Analysis of15N Spin Relaxation

Cited by 71 publications

References 50 publications

A Model of Interdomain Mobility in a Multidomain Protein

A Model of Interdomain Mobility in a Multidomain Protein

An Improved Picture of Methyl Dynamics in Proteins from Slowly Relaxing Local Structure Analysis of 2H Spin Relaxation

On the measurement of 15N–{1H} nuclear Overhauser effects

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Product

Resources

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Domain Flexibility in Ligand-Free and Inhibitor-BoundEscherichia coliAdenylate Kinase Based on a Mode-Coupling Analysis of¹⁵N Spin Relaxation

An Improved Picture of Methyl Dynamics in Proteins from Slowly Relaxing Local Structure Analysis of ²H Spin Relaxation