Christoph Gmeiner scite author profile

A combined method, employing NMR and EPR spectroscopies, has demonstrated its strength in solving structures of protein/RNA and other types of biomolecular complexes. This method works particularly well when the large biomolecular complex consists of a limited number of rigid building blocks, such as RNA-binding protein domains (RBDs). A variety of spin labels is available for such studies, allowing for conventional as well as spectroscopically orthogonal double electron-electron resonance (DEER) measurements in EPR. In this work, we compare different types of nitroxide-based and Gd(iii)-based spin labels attached to isolated RBDs of the polypyrimidine-tract binding protein 1 (PTBP1) and to short RNA fragments. In particular, we demonstrate experiments on spectroscopically orthogonal labelled RBD/RNA complexes. For all experiments we analyse spin labelling, DEER method performance, resulting distance distributions, and their consistency with the predictions from the spin label rotamers analysis. This work provides a set of intra-domain calibration DEER data, which can serve as a basis to start structure determination of the full length PTBP1 complex with an RNA derived from encephalomycarditis virus (EMCV) internal ribosomal entry site (IRES). For a series of tested labelling sites, we discuss their particular advantages and drawbacks in such a structure determination approach.

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Intermolecular background decay in RIDME experiments

Keller

Gmeiner

et al. 2019

Phys. Chem. Chem. Phys.

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Resolving distance variations by single-molecule FRET and EPR spectroscopy using rotamer libraries

Klose

Holla

Gmeiner

et al. 2021

Biophysical Journal

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Fo ¨rster resonance energy transfer (FRET) and electron paramagnetic resonance (EPR) spectroscopy are complementary techniques for quantifying distances in the nanometer range. Both approaches are commonly employed for probing the conformations and conformational changes of biological macromolecules based on site-directed fluorescent or paramagnetic labeling. FRET can be applied in solution at ambient temperature and thus provides direct access to dynamics, especially if used at the single-molecule level, whereas EPR requires immobilization or work at cryogenic temperatures but provides data that can be more reliably used to extract distance distributions. However, a combined analysis of the complementary data from the two techniques has been complicated by the lack of a common modeling framework. Here, we demonstrate a systematic analysis approach based on rotamer libraries for both FRET and EPR labels to predict distance distributions between two labels from a structural model. Dynamics of the fluorophores within these distance distributions are taken into account by diffusional averaging, which improves the agreement with experiment. Benchmarking this methodology with a series of surface-exposed pairs of sites in a structured protein domain reveals that the lowest resolved distance differences can be as small as $0.25 nm for both techniques, with quantitative agreement between experimental and simulated transfer efficiencies within a range of 50.045. Rotamer library analysis thus establishes a coherent way of treating experimental data from EPR and FRET and provides a basis for integrative structural modeling, including studies of conformational distributions and dynamics of biological macromolecules using both techniques.

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Orthogonal Tyrosine and Cysteine Site-Directed Spin Labeling for Dipolar Pulse EPR Spectroscopy on Proteins

Gmeiner

Klose

Mileo

et al. 2017

J. Phys. Chem. Lett.

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Site-directed spin labeling of native tyrosine residues in isolated domains of the protein PTBP1, using a Mannich-type reaction, was combined with conventional spin labeling of cysteine residues. Double electron-electron resonance (DEER) EPR measurements were performed for both the nitroxide-nitroxide and Gd(III)-nitroxide label combinations within the same protein molecule. For the prediction of distance distributions from a structure model, rotamer libraries were generated for the two linker forms of the tyrosine-reactive isoindoline-based nitroxide radical Nox. Only moderate differences exist between the spatial spin distributions for the two linker forms of Nox. This strongly simplifies DEER data analysis, in particular, if only mean distances need to be predicted.

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Integrative solution structure of a PTBP1-viral IRES complex reveals strong compaction and ordering with residual conformational flexibility

Dorn

Gmeiner

Vries

et al. 2022

Preprint

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RNA-binding proteins (RBPs) are crucial regulators of gene expression and often comprise well-defined domains interspersed by flexible, intrinsically disordered regions. The structure determination of ribonucleoprotein complexes involving such RBPs is not common practice and requires integrative structural modeling approaches due to the fact that they often do not form a single stable globular state. Here, we integrate data from magnetic resonance, mass spectrometry, and small angle scattering to determine the solution structure of the polypyrimidine-tract binding protein 1 (PTBP1 also called hnRNP I) bound to an RNA which is part of the internal ribosome entry site (IRES) of the encephalomyocarditis virus (EMCV). PTBP1 binding to this IRES element enhances translation of the viral RNA. The determined structural ensemble reveals that both RNA and protein experience a strong compaction upon complex formation, get ordered but still maintain a substantial conformational flexibility. The C-terminal RNA recognition motif (RRM4) of PTBP1 rigidifies the complex by binding a single-strand RNA linker and, in turn, is essential for IRES-mediated translation. PTBP1 acts as an RNA chaperone for the IRES, by ordering the RNA into a few discrete conformations that expose the RNA stems to the outer surface of the RNP complex for subsequent interactions with the translation machinery. The conformational diversity within this structural ensemble is likely common among RNP complexes and important for their functionality. The presented approach opens the possibility to characterize heterogeneous RNP structures at atomic level.

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