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Abstract
Intrinsically disordered proteins (IDPs) rapidly interconvert between conformers, requiring an ensemble description. This complicates their experimental characterization, and force field limitations pose challenges for their simulation. Here, we use isotope-labeled and unlabeled infrared (IR) spectra to reweight simulated ensembles of the elastin-like peptide GVGVPGVG, a paradigmatic disordered peptide. By comparing the results obtained with different spectra, we explicitly show that the weights are underdetermined by the ensemble averaged data. We identify which labels and frequency regions maximize structural information while minimizing sensitivity to simulation error and show that these regions report on whether the peptide makes specific interactions. Our work shows the importance of incorporating simulations and simulated spectra at the planning stages of isotope-labeled IR experiments and more generally provides a framework for interpreting IR data for IDPs.
Supplementary materials
Title
Supplementary Information
Description
Preprocessing of experimental data; spectral ensembles for all isotope labels; state selection with Integrated Variational Approach for Conformational Dynamics; conformational substates and 12- state model; selection of optimal 𝜃; histogram of state populations for segments; competition between states in posterior distribution; error distributions for the nine isotopologues; state spectra for CHARMM36m; equally weighted ensemble refinement without inclusion of the main band; determination of informative frequency regions and quantification of distinguishability between state spectra.
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Supplementary weblinks
Title
ELP 2025
Description
Code needed to reproduce computational results in Bongalonta et al. 2025
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