9GZG | pdb_00009gzg

Crystal structure of CTPR4E4 mutant

Experimental Data Snapshot

  • Method: X-RAY DIFFRACTION
  • Resolution: 1.47 Å
  • R-Value Free: 
    0.231 (Depositor), 0.244 (DCC) 
  • R-Value Work: 
    0.196 (Depositor), 0.205 (DCC) 
  • R-Value Observed: 
    0.198 (Depositor) 

Starting Model: experimental
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wwPDB Validation   3D Report Full Report


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Literature

Engineered Protein-Based Ionic Conductors for Sustainable Energy Storage Applications.

Cortes-Ossa, J.D.Blesio, P.Fernandez-Castro, M.Almonte, L.Fernandez, M.Liutkus, M.Pandurangan, P.Sabater, C.Villaverde, A.Melle-Franco, M.Ashkenazy, N.Jimenez-Angeles, F.Morant-Minana, M.C.Calvo, M.R.Cortajarena, A.L.

(2025) Adv Mater : e08838-e08838

  • DOI: https://doi.org/10.1002/adma.202508838
  • Primary Citation of Related Structures:  
    9GZG

  • PubMed Abstract: 

    Protein-based biomaterials offer sustainable and biocompatible alternatives to traditional ionic conductors, essential for advancing green energy storage and bioelectronic applications. In this work, a robust, intrinsically self-assembling repeat protein scaffold to enhance ionic conductivity through the selective incorporation of glutamic acids is engineered. These mutations increase the number of available protonation sites and promote the formation of well-defined charge pathways. The self-assembly properties of the system enable the propagation of molecular-level modifications to the macroscopic scale, yielding self-standing protein films with significantly improved ionic conductivity. Specifically, engineered protein-based films exhibit an order of magnitude higher conductivity than their unmodified counterparts, with a further ten-fold enhancement through controlled addition of salt ions. Mechanistic analysis shows that the conductivity enhancement originates from the intertwined contributions of proton transport, hydration, and ion diffusion, all promoted by engineered charged residues. Finally, films of the best-performing variant are integrated, as both separator and electrolyte, into a supercapacitor device with competitive energy storage performance. These findings highlight the potential of rational protein design to create biocompatible, sustainable, and efficient ionic conductors with the stability and processability required to be successfully integrated into the next generation of energy storage and bioelectronic devices.

    • Organizational Affiliation
    • BCMaterials, Basque Center for Materials, Applications and Nanostructures, UPV/EHU Science Park, Leioa, Vizcaya, 48940, Spain.

Macromolecules
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(by identity cutoff)  |  3D Structure
Entity ID: 1
MoleculeChains Sequence LengthOrganismDetailsImage
Engineered CTPR protein with glutamic acids for conductivity
A, B
154synthetic constructMutation(s): 0 
Entity Groups  
Sequence Clusters30% Identity50% Identity70% Identity90% Identity95% Identity100% Identity
Sequence Annotations
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  • Reference Sequence
Experimental Data & Validation

Experimental Data

  • Method: X-RAY DIFFRACTION
  • Resolution: 1.47 Å
  • R-Value Free:  0.231 (Depositor), 0.244 (DCC) 
  • R-Value Work:  0.196 (Depositor), 0.205 (DCC) 
  • R-Value Observed: 0.198 (Depositor) 
Space Group: C 1 2 1
Unit Cell:
Length ( Å )Angle ( ˚ )
a = 105.915α = 90
b = 73.514β = 98.41
c = 40.778γ = 90
Software Package:
Software NamePurpose
REFMACrefinement
autoPROCdata scaling
MOLREPphasing
XDSdata reduction

Structure Validation

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Entry History & Funding Information

Deposition Data

Funding OrganizationLocationGrant Number
European Research Council (ERC)European Union964593

Revision History  (Full details and data files)

  • Version 1.0: 2025-10-15
    Type: Initial release
  • Version 1.1: 2025-11-19
    Changes: Database references