Protein dynamics and function from solution state NMR spectroscopy

Kovermann, Michael; Rogne, Per; Wolf‐Watz, Magnus

doi:10.1017/s0033583516000019

Cited by 143 publications

(147 citation statements)

References 474 publications

(743 reference statements)

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“…Protein function is dependent on an intricate interplay among protein structure, stability, and dynamics where stability refers to the difference in free energy between the structural microstates that are dynamically sampled (37). Protein folding dynamics can be perturbed by addition of chaotropic denaturants such as urea and guanidinium hydrochloride, which stabilize the states in a dynamic ensemble with the largest SAS areas (unfolded states in protein folding reactions).…”

Section: Resultsmentioning

confidence: 99%

Urea-Dependent Adenylate Kinase Activation following Redistribution of Structural States

Rogne

Wolf‐Watz

2016

Biophysical Journal

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Proteins are often functionally dependent on conformational changes that allow them to sample structural states that are sparsely populated in the absence of a substrate or binding partner. The distribution of such structural microstates is governed by their relative stability, and the kinetics of their interconversion is governed by the magnitude of associated activation barriers. Here, we have explored the interplay among structure, stability, and function of a selected enzyme, adenylate kinase (Adk), by monitoring changes in its enzymatic activity in response to additions of urea. For this purpose we used a 31 P NMR assay that was found useful for heterogeneous sample compositions such as presence of urea. It was found that Adk is activated at low urea concentrations whereas higher urea concentrations unfolds and thereby deactivates the enzyme. From a quantitative analysis of chemical shifts, it was found that urea redistributes preexisting structural microstates, stabilizing a substrate-bound open state at the expense of a substrate-bound closed state. Adk is rate-limited by slow opening of substrate binding domains and the urea-dependent redistribution of structural states is consistent with a model where the increased activity results from an increased rate-constant for domain opening. In addition, we also detected a strong correlation between the catalytic free energy and free energy of substrate (ATP) binding, which is also consistent with the catalytic model for Adk. From a general perspective, it appears that urea can be used to modulate conformational equilibria of folded proteins toward more expanded states for cases where a sizeable difference in solvent-accessible surface area exists between the states involved. This effect complements the action of osmolytes, such as trimethylamine N-oxide, that favor more compact protein states.

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Section: Resultsmentioning

confidence: 99%

Urea-Dependent Adenylate Kinase Activation following Redistribution of Structural States

Rogne

Wolf‐Watz

2016

Biophysical Journal

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“…Proteins are complex and highly dynamic entities attaining a myriad of different conformations in solution 1–5 that are often related to the protein function. Indeed, they can resemble bound states to a biological partner 6–10 , active states of enzymes 11–14 , or conformations that are stabilized by a post-translational modification (PTM) 6, 11 , as well as altered by a disease-related mutation 15 .…”

Section: Introductionmentioning

confidence: 99%

An optimal distance cutoff for contact-based Protein Structure Networks using side-chain centers of mass

Viloria

Allega

Lambrughi

et al. 2017

Sci Rep

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Proteins are highly dynamic entities attaining a myriad of different conformations. Protein side chains change their states during dynamics, causing clashes that are propagated at distal sites. A convenient formalism to analyze protein dynamics is based on network theory using Protein Structure Networks (PSNs). Despite their broad applicability, few efforts have been devoted to benchmarking PSN methods and to provide the community with best practices. In many applications, it is convenient to use the centers of mass of the side chains as nodes. It becomes thus critical to evaluate the minimal distance cutoff between the centers of mass which will provide stable network properties. Moreover, when the PSN is derived from a structural ensemble collected by molecular dynamics (MD), the impact of the MD force field has to be evaluated. We selected a dataset of proteins with different fold and size and assessed the two fundamental properties of the PSN, i.e. hubs and connected components. We identified an optimal cutoff of 5 Å that is robust to changes in the force field and the proteins. Our study builds solid foundations for the harmonization and standardization of the PSN approach.

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“…The subjects for which three-dimensional structures have been determined with high resolution are typically small proteins (<20 kDa); however, in some cases protein structures as large as 50 kDa have been determined with reasonable accuracy (Serrano, Aubol et al, 2016;Serrano, Dutta et al, 2016). NMR spectroscopy is used to characterize protein dynamics over a variety of time ranges from picoseconds to hours (Lange et al, 2008;Kovermann et al, 2016). On the other hand, the latter is a limitation of NMR because of the difficulty in quantifying dynamic motions that occur over wide ranges.…”

Section: Introductionmentioning

confidence: 99%

Protein crystal lattices are dynamic assemblies: the role of conformational entropy in the protein condensed phase

Dimova

Devedjiev

2018

Int Union Crystallogr J

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Until recently, the occurrence of conformational entropy in protein crystal contacts was considered to be a very unlikely event. A study based on the most accurately refined protein structures demonstrated that side-chain conformational entropy and static disorder might be common in protein crystal lattices. The present investigation uses structures refined using ensemble refinement to show that although paradoxical, conformational entropy is likely to be the major factor in the emergence and integrity of the protein condensed phase. This study reveals that the role of shape entropy and local entropic forces expands beyond the onset of crystallization. For the first time, the complete pattern of intermolecular interactions by protein atoms in crystal lattices is presented, which shows that van der Waals interactions dominate in crystal formation.

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Protein dynamics and function from solution state NMR spectroscopy

Cited by 143 publications

References 474 publications

Urea-Dependent Adenylate Kinase Activation following Redistribution of Structural States

Urea-Dependent Adenylate Kinase Activation following Redistribution of Structural States

An optimal distance cutoff for contact-based Protein Structure Networks using side-chain centers of mass

Protein crystal lattices are dynamic assemblies: the role of conformational entropy in the protein condensed phase

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