Dynamics of well-folded and natively disordered proteins in solution: a time-of-flight neutron scattering study

Gaspar, Ana Maria Minarelli; Appavou, Marie‐Sousai; Büsch, Sebastian; Unruh, Tobias; Doster, Wolfgang

doi:10.1007/s00249-008-0266-3

Cited by 64 publications

(93 citation statements)

References 35 publications

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“…The scattering signal, however, stems from protons of the protein and thus indicates the presence of dangling (side) groups. The results are in some variance to findings from TOF experiments on small globular proteins (lysozyme and concanavalin A) and disordered proteins (caseins) [9]. For those besides diffusion a Q-independent local fast component with a width of 0.15 meV (τ 4 ps) was found virtually independent of the protein type.…”

Section: Discussion and Outlooksupporting

confidence: 58%

Neutron Spin-Echo and TOF Reveals Protein Dynamics in Solution

et al. 2013

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The ps to ns dynamics of the protein alcohol dehydrogenase (ADH) has been measured in dilute solution by time-of-flight (TOF) neutron spectroscopy. The investigation extends previous experiments on ADH solutions with neutron-spin-echo spectroscopy. The interpretation of TOF experiments used the diffusion data from NSE as input to decribe the observed slow component of the quasielastic spectra, in addition a fast component to be associated to mobile groups in the protein could be observed. The description within a simple model for translational and rotational diffusion and a fraction of protons with confined local mobility is given together with a novel method to accurately and efficiently account for the instrumental resolution.

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Section: Discussion and Outlooksupporting

confidence: 58%

Neutron Spin-Echo and TOF Reveals Protein Dynamics in Solution

et al. 2013

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“…These results show that RPs are torsionally stiffer than SFPs. Our findings are consistent with the higher conformational displacements of α-helices compared to β-sheets [11,27]. In all of our simulations, the effect of hydrophobic mismatch is neutralized, ∆r = 0.01, by using the HT 5 H model proteins.…”

Section: Resultssupporting

confidence: 90%

Rigidity of transmembrane proteins determines their cluster shape

2016

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Protein aggregation in cell membrane is vital for the majority of biological functions. Recent experimental results suggest that transmembrane domains of proteins such as α-helices and β-sheets have different structural rigidities. We use molecular dynamics simulation of a coarse-grained model of protein-embedded lipid membranes to investigate the mechanisms of protein clustering. For a variety of protein concentrations, our simulations under thermal equilibrium conditions reveal that the structural rigidity of transmembrane domains dramatically affects interactions and changes the shape of the cluster. We have observed stable large aggregates even in the absence of hydrophobic mismatch, which has been previously proposed as the mechanism of protein aggregation. According to our results, semi-flexible proteins aggregate to form two-dimensional clusters, while rigid proteins, by contrast, form one-dimensional string-like structures. By assuming two probable scenarios for the formation of a two-dimensional triangular structure, we calculate the lipid density around protein clusters and find that the difference in lipid distribution around rigid and semiflexible proteins determines the one-or two-dimensional nature of aggregates. It is found that lipids move faster around semiflexible proteins than rigid ones. The aggregation mechanism suggested in this paper can be tested by current state-of-the-art experimental facilities.

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“…Gaspar et al [44] investigated the interplay between structure and dynamics of different proteins using TOF-techniques. They scrutinized casein proteins (belonging to the class of natively disordered proteins) and in addition three wellfolded proteins with distinct secondary structures (myoglobin, lysozyme and concanavalin A).…”

Section: Bio Systemsmentioning

confidence: 99%

Introduction to Quasielastic Neutron Scattering

Embs

Jurányi²,

Hempelmann³

2010

Zeitschrift Für Physikalische Chemie

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This tutorial introduction has been written for people who are not specialized in neutron scattering or in other scattering methods but who are interested and would like to get an impression and learn about the method of Quasielastic Neutron Scattering (QENS). The theoretical (scattering process) as well as the experimental basics (neutron sources, neutron scattering instruments, experimental periphery) are explained in a generally understandable way, with only the most essential formulas. QENS addresses the stochastic dynamics in condensed matter, and it is pointed out for which problems and for which systems in condensed matter research QENS is a powerful method. Thus sufficient information is provided to enable non-experts to think about their own QENS experiment and to understand related literature in this area of research.

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Dynamics of well-folded and natively disordered proteins in solution: a time-of-flight neutron scattering study

Cited by 64 publications

References 35 publications

Neutron Spin-Echo and TOF Reveals Protein Dynamics in Solution

Neutron Spin-Echo and TOF Reveals Protein Dynamics in Solution

Rigidity of transmembrane proteins determines their cluster shape

Introduction to Quasielastic Neutron Scattering

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