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Structure of a designed protein cage that self-assembles into a highly porous cube

Structure of a designed protein cage that self-assembles into a highly porous cube
Structure of a designed protein cage that self-assembles into a highly porous cube
Natural proteins can be versatile building blocks for multimeric, self-assembling structures. Yet, creating protein-based assemblies with specific geometries and chemical properties remains challenging. Highly porous materials represent particularly interesting targets for designed assembly. Here, we utilize a strategy of fusing two natural protein oligomers using a continuous alpha-helical linker to design a novel protein that self assembles into a 750 kDa, 225 Å diameter, cube-shaped cage with large openings into a 130 Å diameter inner cavity. A crystal structure of the cage showed atomic-level agreement with the designed model, while electron microscopy, native mass spectrometry and small angle X-ray scattering revealed alternative assembly forms in solution. These studies show that accurate design of large porous assemblies with specific shapes is feasible, while further specificity improvements will probably require limiting flexibility to select against alternative forms. These results provide a foundation for the design of advanced materials with applications in bionanotechnology, nanomedicine and material sciences.
1755-4330
1065-1071
Lai, YT
32e651f8-e21e-4367-a14b-1655165f6e0d
Reading, E
62fed933-f867-4c72-89e7-83aea573a836
Hura, GL
032b9e2f-7ab7-4f6b-9dcc-b206c78deeda
Tsai, K-L
e2c457c7-8e09-4cfb-8e3c-86a98398e775
Laganowsky, A
617ddba0-5815-4e28-9234-ba6f238fa153
Asturias, FJ
3dbb3fd8-5418-426c-a914-46e3557873ea
Tainer, JA
267c4301-a35c-4b6c-9725-55cdc285acd1
Robinson, CV
b1d0d9be-b0ce-4a5e-966a-0e6357ef4fef
Yeates, TO
73f9fb98-461d-43f1-b93b-964242c514d8
Lai, YT
32e651f8-e21e-4367-a14b-1655165f6e0d
Reading, E
62fed933-f867-4c72-89e7-83aea573a836
Hura, GL
032b9e2f-7ab7-4f6b-9dcc-b206c78deeda
Tsai, K-L
e2c457c7-8e09-4cfb-8e3c-86a98398e775
Laganowsky, A
617ddba0-5815-4e28-9234-ba6f238fa153
Asturias, FJ
3dbb3fd8-5418-426c-a914-46e3557873ea
Tainer, JA
267c4301-a35c-4b6c-9725-55cdc285acd1
Robinson, CV
b1d0d9be-b0ce-4a5e-966a-0e6357ef4fef
Yeates, TO
73f9fb98-461d-43f1-b93b-964242c514d8

Lai, YT, Reading, E, Hura, GL, Tsai, K-L, Laganowsky, A, Asturias, FJ, Tainer, JA, Robinson, CV and Yeates, TO (2014) Structure of a designed protein cage that self-assembles into a highly porous cube. Nature Chemistry, 6, 1065-1071. (doi:10.1038/nchem.2107).

Record type: Article

Abstract

Natural proteins can be versatile building blocks for multimeric, self-assembling structures. Yet, creating protein-based assemblies with specific geometries and chemical properties remains challenging. Highly porous materials represent particularly interesting targets for designed assembly. Here, we utilize a strategy of fusing two natural protein oligomers using a continuous alpha-helical linker to design a novel protein that self assembles into a 750 kDa, 225 Å diameter, cube-shaped cage with large openings into a 130 Å diameter inner cavity. A crystal structure of the cage showed atomic-level agreement with the designed model, while electron microscopy, native mass spectrometry and small angle X-ray scattering revealed alternative assembly forms in solution. These studies show that accurate design of large porous assemblies with specific shapes is feasible, while further specificity improvements will probably require limiting flexibility to select against alternative forms. These results provide a foundation for the design of advanced materials with applications in bionanotechnology, nanomedicine and material sciences.

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More information

Accepted/In Press date: 1 October 2014
e-pub ahead of print date: 10 November 2014
Published date: December 2014

Identifiers

Local EPrints ID: 479133
URI: http://eprints.soton.ac.uk/id/eprint/479133
DOI: doi:10.1038/nchem.2107
ISSN: 1755-4330
PURE UUID: c9a9d987-716f-4f2e-8c4a-6b259fa8e96c
ORCID for E Reading: ORCID iD orcid.org/0000-0001-8219-0052

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Date deposited: 20 Jul 2023 16:37
Last modified: 17 Mar 2024 04:19

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Contributors

Author: YT Lai
Author: E Reading ORCID iD
Author: GL Hura
Author: K-L Tsai
Author: A Laganowsky
Author: FJ Asturias
Author: JA Tainer
Author: CV Robinson
Author: TO Yeates

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