Dynamic personalities of proteins

Henzler-Wildman, Katherine A.; Kern, Dorothee

doi:10.1038/nature06522

Cited by 2,153 publications

(2,335 citation statements)

References 105 publications

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“…2), into the Nterminal region of BtuB (see Methods). The X-band EPR spectra from spin labels placed at positions [1][2][3][4][5] in BtuB are shown in Figure 3, along with the position of these sites in the BtuB meso structure. These spectra are similar to those published previously, 22 and are composed of two components resulting from populations of spin labels that have different dynamics.…”

Section: Resultsmentioning

confidence: 99%

“…Proteins do not assume one unique structure but sample a range of conformational states over a wide range of timescales 1,2 ; furthermore, protein dynamics underlies function and is a key to enzyme activity and allosteric regulation. [3][4][5] Dynamics also underlies protein-protein recognition, which is often mediated by conserved and highly dynamic or unstructured regions of proteins.…”

Section: Introductionmentioning

confidence: 99%

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Osmolytes modulate conformational exchange in solvent‐exposed regions of membrane proteins

Jiménez¹,

Cao²,

Kim³

et al. 2010

Protein Science

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Site-directed spin labeling (SDSL) was used to investigate local structure and conformational exchange in two bacterial outer-membrane TonB-dependent transporters, BtuB and FecA. Protecting osmolytes, such as polyethylene glycols (PEGs) are known to modulate a substrate-dependent conformational equilibrium in the energy coupling motif (Ton box) of BtuB. Here, we demonstrate that a segment that is N-terminal to the Ton box in BtuB, is in conformational exchange between ordered and disordered states with or without substrate. Protecting osmolytes shift this equilibrium to favor the more ordered, folded state. However, a segment of BtuB that is C-terminal to the Ton box that is not solvent exposed is insensitive to PEGs. Protecting osmolytes also modulate a conformational equilibrium in the Ton box of FecA, with larger molecular weight PEGs producing the largest shifts in the conformational free energy. These data indicate that solvent-exposed regions of these transporters undergo conformational exchange and that regions of these transporters that are involved in protein-protein interactions sample multiple conformational substates. The sensitivity to solute provides an explanation for differences seen between two high-resolution structures of BtuB, which each likely represent one conformation from a subset of states that are normally sampled by the protein. This work also illustrates how SDSL and osmolytes may be used to characterize and quantitate conformational equilibria in membrane proteins.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Osmolytes modulate conformational exchange in solvent‐exposed regions of membrane proteins

Jiménez¹,

Cao²,

Kim³

et al. 2010

Protein Science

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“…In this sense, any protein could be allosteric 5 , and the perturbation could be anything that changes the free-energy landscape of the protein (including perturbations which do not induce a visible conformational change 6,7 ). This perspective views proteins as highly dynamic, with the ability to sample their active (i.e., less populated) state even in the absence of a ligand or substrate 8 .…”

Section: Introductionmentioning

confidence: 99%

Uncovering allosteric pathways in caspase-1 using Markov transient analysis and multiscale community detection

et al. 2014

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Allosteric regulation at distant sites is central to many cellular processes. In particular, allosteric sites in proteins are a major target to increase the range and selectivity of new drugs, and there is a need for methods capable of identifying intra-molecular signalling pathways leading to allosteric effects. Here, we use an atomistic graph-theoretical approach that exploits Markov transients to extract such pathways and exemplify our results in an important allosteric protein, caspase-1. Firstly, we use Markov Stability community detection to perform a multiscale analysis of the structure of caspase-1 which reveals that the active conformation has a weaker, less compartmentalised large-scale structure as compared to the inactive conformation, resulting in greater intra-protein coherence and signal propagation. We also carry out a full computational point mutagenesis and identify that only a few residues are critical to such structural coherence. Secondly, we characterise explicitly the transients of random walks originating at the active site and predict the location of a known allosteric site in this protein quantifying the contribution of individual bonds to the communication pathway between the active and allosteric sites. Several of the bonds we find have been shown experimentally to be functionally critical, but we also predict a number of as yet unidentified bonds which may contribute to the pathway. Our approach offers a computationally inexpensive method for the identification of allosteric sites and communication pathways in proteins using a fully atomistic description.

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“…Over the recent years, the view and understanding of the fundamental principles underlying allostery have been enriched and often utterly reshaped as techniques such as NMR spectroscopy has been offering insights complementary to those provided by static structures. [6][7][8][9][10][11] The early crystallographic work on allosteric systems helped to advance and establish a purely structural, ''mechanical'' view. 12 Nevertheless, because allostery is fundamentally thermodynamic in nature, long-range communication may be mediated not only by changes in the mean conformation (enthalpic contribution) but also by changes in the dynamic fluctuations about the mean conformation (entropic contribution).…”

Section: Introductionmentioning

confidence: 99%

NMR reveals novel mechanisms of protein activity regulation

Kalodimos

2011

Protein Science

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NMR spectroscopy is one of the most powerful tools for the characterization of biomolecular systems. A unique aspect of NMR is its capacity to provide an integrated insight into both the structure and intrinsic dynamics of biomolecules. In addition, NMR can provide siteresolved information about the conformation entropy of binding, as well as about energetically excited conformational states. Recent advances have enabled the application of NMR for the characterization of supramolecular systems. A summary of mechanisms underpinning protein activity regulation revealed by the application of NMR spectroscopy in a number of biological systems studied in the lab is provided.

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Dynamic personalities of proteins

Cited by 2,153 publications

References 105 publications

Osmolytes modulate conformational exchange in solvent‐exposed regions of membrane proteins

Osmolytes modulate conformational exchange in solvent‐exposed regions of membrane proteins

Uncovering allosteric pathways in caspase-1 using Markov transient analysis and multiscale community detection

NMR reveals novel mechanisms of protein activity regulation

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