Rapid Determination of Fast Protein Dynamics from NMR Chemical Exchange Saturation Transfer Data

Gu, Yina; Hansen, Alexandar L.; Peng, Yi; Brüschweiler, Rafael

doi:10.1002/anie.201511711

Cited by 15 publications

(14 citation statements)

References 37 publications

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“…k ex = 50–150 s −1 ). The CEST experiment can also simultaneously take advantage of the CEST-derived R 1 and R 2 data to extract S 2 order parameters reporting on the ps-ns time scale 30 . In spin-relaxation NMR, the order parameter S 2 is typically extracted from the model-free approach using experimental R 1 , R 2 , and hNOE NMR data 31–33 .…”

Section: Investigating the Microsecond To Millisecond Time Frame Tmentioning

confidence: 99%

Applications of NMR and computational methodologies to study protein dynamics

Narayanan

Bafna

Roux

et al. 2017

Archives of Biochemistry and Biophysics

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Overwhelming evidence now illustrates the defining role of atomic-scale protein flexibility in biological events such as allostery, cell signaling, and enzyme catalysis. Over the years, spin relaxation nuclear magnetic resonance (NMR) has provided significant insights on the structural motions occurring on multiple time frames over the course of a protein life span. The present review article aims to illustrate to the broader community how this technique continues to shape many areas of protein science and engineering, in addition to being an indispensable tool for studying atomic-scale motions and functional characterization. Continuing developments in underlying NMR technology alongside software and hardware developments for complementary computational approaches now enable methodologies to routinely provide spatial directionality and structural representations traditionally harder to achieve solely using NMR spectroscopy. In addition to its well-established role in structural elucidation, we present recent examples that illustrate the combined power of selective isotope labeling, relaxation dispersion experiments, chemical shift analyses, and computational approaches for the characterization of conformational sub-states in proteins and enzymes.

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Section: Investigating the Microsecond To Millisecond Time Frame Tmentioning

confidence: 99%

Applications of NMR and computational methodologies to study protein dynamics

Narayanan

Bafna

Roux

et al. 2017

Archives of Biochemistry and Biophysics

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“…Recent advances employing saturation transfer, such as chemical exchange saturation transfer (CEST) and dark-state exchange saturation transfer (DEST), have enabled the detection of these previously invisible protein states [7, 8]. Several studies have already reported the use of CEST to study the invisible conformers of slowly exchanging proteins on the millisecond to second timescale [1, 9–12]. Additionally, the fitting of CEST profiles have been shown to reliably extract R 1 and R 2 parameters that can be used for modelfree analysis of fast timescale dynamics (ps to ns).…”

Section: Introductionmentioning

confidence: 99%

“…To date, however, no study has combined CEST-derived R 1 and R 2 parameters with 1 H- 15 N NOE data to establish the picosecond to nanosecond dynamics of a protein. Instead, leaner versions of modelfree have been applied without the NOE data [1].…”

Section: Introductionmentioning

confidence: 99%

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15N CEST data and traditional model-free analysis capture fast internal dynamics of DJ-1

Catazaro

Andrews

Milkovic

et al. 2018

Analytical Biochemistry

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Previous studies have shown that relaxation parameters and fast protein dynamics can be quickly elucidated from N-CEST experiments [1]. Longitudinal R and transverse R values were reliably derived from fitting of CEST profiles. Herein we show that N-CEST experiments and traditional modelfree analysis provide the internal dynamics of three states of human protein DJ-1 at physiological temperature. The chemical exchange profiles show the absence of a minor state conformation and, in conjunction withH-N NOEs, show increased mobility. R and R values remained relatively unchanged at the three naturally occurring oxidation states of DJ-1, but exhibit striking NOE differences. The NOE data was, therefore, essential in determining the internal motions of the DJ-1 proteins. To the authors' knowledge, we present the first study that combines N CEST data with traditional model-free analyses in the study of a biological system and affirm that more 'lean' model-free approaches should be used cautiously.

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“…Sometimes, an additional local R ex parameter is also fit to obtain information about slower timescale dynamics arising from conformational exchange which increases the minimum number of necessary experimental observables to 3 n +1 for the case of isotropic tumbling. So-called “lean” approaches (Gu, Hansen, Peng, & Bruschweiler, 2016) can be used to reduce data collection and a recent publication has provided a systematic and quantitative evaluation of using a reduced number of 15 N relaxation observables in the quantification of internal motion (Jaremko, Jaremko, Ejchart, & Nowakowski, 2018). Alternative methods utilizing cross correlated relaxation have also been introduced but will not be discussed further here (Pelupessy, Espallargas, & Bodenhausen, 2003; Reif, Diener, Hennig, Maurer, & Griesinger, 2000; Weaver, & Zuiderweg, 2008; Weaver, & Zuiderweg, 2009).…”

Section: Nmr Spin Relaxation Methodsmentioning

confidence: 99%

Characterization of Internal Protein Dynamics and Conformational Entropy by NMR Relaxation

Stetz

José

Kotaru

et al. 2019

Methods in Enzymology

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Recent studies suggest that the fast timescale motion of methyl-bearing side chains may play an important role in mediating protein activity. These motions have been shown to encapsulate the residual conformational entropy of the folded state that can potentially contribute to the energetics of protein function. Here, we provide an overview of how to characterize these motions using nuclear magnetic resonance (NMR) spin relaxation methods. The strengths and limitations of several techniques are highlighted in order to assist with experimental design. Particular emphasis is placed on the practical aspects of sample preparation, data collection, data fitting, and statistical analysis. Additionally, discussion of the recently refined “entropy meter” is presented and its use in converting NMR observables to conformational entropy is illustrated. Taken together, these methods should yield new insights into the complex interplay between structure and dynamics in protein function.

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Rapid Determination of Fast Protein Dynamics from NMR Chemical Exchange Saturation Transfer Data

Cited by 15 publications

References 37 publications

Applications of NMR and computational methodologies to study protein dynamics

Applications of NMR and computational methodologies to study protein dynamics

15N CEST data and traditional model-free analysis capture fast internal dynamics of DJ-1

Characterization of Internal Protein Dynamics and Conformational Entropy by NMR Relaxation

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