MD Simulations and FRET Reveal an Environment-Sensitive Conformational Plasticity of Importin-β

Halder, Kangkan; Dölker, Nicole; Van, Qui; Gregor, Ingo; Dickmanns, Achim; Baade, Imke; Kehlenbach, Ralph H.; Ficner, Ralf; Grubmüller, Helmut; Neumann, Heinz

doi:10.1016/j.bpj.2015.06.014

Cited by 24 publications

(23 citation statements)

References 58 publications

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“…In this study, we show that dArmRPs adopt different curvature parameters in different crystal structures, sometimes even within the same AU. This demonstrates an intrinsic flexibility of the scaffold which was also observed for nArmRP (Huber et al, 1997) and importin-β, belonging to the closely related family of HEAT repeat proteins (Halder et al, 2015;Tauchert et al, 2016;Zachariae and Grubmüller, 2008). However, we expect the flexibility to be smaller in dArmRPs since the scaffold is more regular and stable compared to nArmRP (Madhurantakam et al, 2012;Parmeggiani et al, 2008;Reichen et al, 2016b).…”

Section: Discussionmentioning

confidence: 54%

Curvature of designed armadillo repeat proteins allows modular peptide binding

Hansen

Erñst

König

et al. 2018

Journal of Structural Biology

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Designed armadillo repeat proteins (dArmRPs) were developed to create a modular peptide binding technology where each of the structural repeats binds two residues of the target peptide. An essential prerequisite for such a technology is a dArmRP geometry that matches the peptide bond length. To this end, we determined a large set (n=27) of dArmRP X-ray structures, of which 12 were previously unpublished, to calculate curvature parameters that define their geometry. Our analysis shows that consensus dArmRPs exhibit curvatures close to the optimal range for modular peptide recognition. Binding of peptide ligands can induce a curvature within the desired range, as confirmed by single-molecule FRET experiments in solution. On the other hand, computationally designed ArmRPs, where side chains have been chosen with the intention to optimally fit into a geometrically optimized backbone, turned out to be more divergent in reality, and thus not suitable for continuous peptide binding. Furthermore, we show that the formation of a crystal lattice can induce small but significant deviations from the curvature adopted in solution, which can interfere with the evaluation of repeat protein scaffolds when high accuracy is required. This study corroborates the suitability of consensus dArmRPs as a scaffold for the development of modular peptide binders.

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Section: Discussionmentioning

confidence: 54%

Curvature of designed armadillo repeat proteins allows modular peptide binding

Hansen

Erñst

König

et al. 2018

Journal of Structural Biology

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“…Further optimization of the procedures will be necessary to extend this approach to more challenging targets. The combination of labelling via UAAs with conventional cysteine chemistry, native chemical ligation or fluorescent tags is technically less demanding and has been used to study, for example, the dynamics of nucleoporins (Figure 4a) [64 ] and nuclear transport receptors [65].…”

Section: Spectroscopic Analyses Of Protein Structure and Dynamicsmentioning

confidence: 99%

The use of unnatural amino acids to study and engineer protein function

Neumann‐Staubitz¹,

Neumann

2016

Current Opinion in Structural Biology

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“…These binding areas might extend in the presence of PEG, which releases strain from the hydrophobic binding pockets of Imp and thereby affects its extension, which results in the opposite effect for Imp during SAXS, namely its spatial expansion in the hydrophobic environment. Recently, a study was published which also deals with the adaptation of Imp to its environment but resulted in the opposite findings (Halder et al, 2015). Halder and coworkers examined the conformational changes of Imp with the environment via MD simulations and FRET.…”

Section: Small-angle X-ray Scattering Of Ctimpbmentioning

confidence: 99%

Impact of the crystallization condition on importin-β conformation

Tauchert

Hémonnot

Neumann

et al. 2016

Acta Cryst Sect D Struct Biol

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In eukaryotic cells, the exchange of macromolecules between the nucleus and cytoplasm is highly selective and requires specialized soluble transport factors. Many of them belong to the importin-β superfamily, the members of which share an overall superhelical structure owing to the tandem arrangement of a specific motif, the HEAT repeat. This structural organization leads to great intrinsic flexibility, which in turn is a prerequisite for the interaction with a variety of proteins and for its transport function. During the passage from the aqueous cytosol into the nucleus, the receptor passes the gated channel of the nuclear pore complex filled with a protein meshwork of unknown organization, which seems to be highly selective owing to the presence of FG-repeats, which are peptides with hydrophobic patches. Here, the structural changes of free importin-β from a single organism, crystallized in polar (salt) or apolar (PEG) buffer conditions, are reported. This allowed analysis of the structural changes, which are attributable to the surrounding milieu and are not affected by bound interaction partners. The importin-β structures obtained exhibit significant conformational changes and suggest an influence of the polarity of the environment, resulting in an extended conformation in the PEG condition. The significance of this observation is supported by SAXS experiments and the analysis of other crystal structures of importin-β deposited in the Protein Data Bank.

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MD Simulations and FRET Reveal an Environment-Sensitive Conformational Plasticity of Importin-β

Cited by 24 publications

References 58 publications

Curvature of designed armadillo repeat proteins allows modular peptide binding

Curvature of designed armadillo repeat proteins allows modular peptide binding

The use of unnatural amino acids to study and engineer protein function

Impact of the crystallization condition on importin-β conformation

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