EMD-46599

Helical reconstruction
3.3 Å
EMD-46599 Deposition: 16/08/2024
Map released: 22/01/2025
Last modified: 12/02/2025
Overview 3D View Sample Experiment Validation Volume Browser Additional data Links
Overview 3D View Sample Experiment Validation Volume Browser Additional data Links

EMD-46599

Cryo-EM of helical fibers formed by two peptides Pyn-K6 and Pyn-(EY)3

EMD-46599

Helical reconstruction
3.3 Å
EMD-46599 Deposition: 16/08/2024
Map released: 22/01/2025
Last modified: 12/02/2025
Overview 3D View Sample Experiment Validation Volume Browser Additional data Links
Sample Organism: synthetic construct
Sample: Pyn-K6 + Pyn-EY3 fiber
Fitted models: 9d70 (Avg. Q-score: 0.39)

Deposition Authors: Zia A, Qiao Y, Xu B , Wang F
Context-Dependent Heterotypic Assemblies of Intrinsically Disordered Peptides.
Qiao Y, Zia A, Wu G, Liu Z, Guo J , Chu M , He H, Wang F, Xu B
(2025) J Am Chem Soc , 147 , 2978 - 2983
PUBMED: 39808585
DOI: doi:10.1021/jacs.4c12150
ISSN: 1520-5126
ASTM: JACSAT
Abstract:
Despite their critical role in context-dependent interactions for protein functions, intrinsically disordered regions (IDRs) are often overlooked for designing peptide assemblies. Here, we exploit IDRs to enable context-dependent heterotypic assemblies of intrinsically disordered peptides, where "context-dependent" refers to assembly behavior driven by interactions with other molecules. By attaching an aromatic segment to oppositely charged intrinsically disordered peptides, we achieve a nanofiber formation. Although the same-charged peptides cannot self-assemble, oppositely charged peptides form heterotypic nanofibers. Cryo-EM analysis reveals a β-sheet arrangement within the ordered core of these nanofibers, conformational heterogeneity, and a disorder-to-order continuum and shows a high number of hydrogen bonds between tyrosine and lysine ε-amine. Additionally, this work demonstrates a post-assembly morphological change resulting from local conformational flexibility. While equal molar mixtures of the charged intrinsically disordered peptides yield nanofibers, doubling the positively charged peptides after assembly produces bundles of nanofibers. Furthermore, reducing the number of aromatic amino acid residues reduces bundle formation. Demonstrating context-dependent self-assembly of intrinsically disordered peptides and revealing atomistic insights into heterotypic assemblies of intrinsically disordered peptides for the first time, this work illustrates a straightforward approach to enable heterotypic intrinsically disordered peptides to self-assemble for the design of adaptive, multifunctional peptide nanomaterials.