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From sequence to scaffold: computational design of protein nanoparticle vaccines from AlphaFold2-predicted building blocks

From sequence to scaffold: computational design of protein nanoparticle vaccines from AlphaFold2-predicted building blocks
From sequence to scaffold: computational design of protein nanoparticle vaccines from AlphaFold2-predicted building blocks

Self-assembling protein nanoparticles are being increasingly utilized in the design of next-generation vaccines due to their ability to induce antibody responses of superior magnitude, breadth, and durability. Computational protein design offers a route to nanoparticle scaffolds with structural and biochemical features tailored to specific vaccine applications. Although strategies for designing self-assembling proteins have been established, the recent development of powerful machine learning (ML)–based tools for protein structure prediction and design provides an opportunity to overcome several of their limitations. Here, we leveraged these tools to develop a generalizable method for designing self-assembling proteins starting from AlphaFold2 predictions of oligomeric protein building blocks. We used the method to generate six 60-subunit protein nanoparticles with icosahedral symmetry, and single-particle cryoelectron microscopy reconstructions of three of them revealed that they were designed with atomic-level accuracy. To transform one of these nanoparticles into a functional immunogen, we reoriented its termini through circular permutation, added a genetically encoded oligomannose-type glycan, and displayed a stabilized trimeric variant of the influenza hemagglutinin receptor-binding domain through a rigid de novo linker. The resultant immunogen elicited potent receptor-blocking and neutralizing antibody responses in mice. Our results demonstrate the practical utility of ML–based protein modeling tools in the design of nanoparticle vaccines. More broadly, by eliminating the requirement for experimentally determined structures of protein building blocks, our method dramatically expands the number of starting points available for designing self-assembling proteins.

influenza, machine learning, nanoparticles, protein design, vaccines
0027-8424
Haas, Cyrus M.
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Jasti, Naveen
d977f083-a09a-4ca2-aaf3-d11d6ce67d95
Dosey, Annie
d8b74cff-f449-4924-9a32-09a53cbec229
Allen, Joel D.
c873d886-2a66-475b-ae04-57a10b37e716
Gillespie, Rebecca
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McGowan, Jackson
f25d9869-eeef-4172-9de5-f21384bce226
Leaf, Elizabeth M.
027100d7-f4a1-4f63-adec-1f7ba688b741
Crispin, Max
cd980957-0943-4b89-b2b2-710f01f33bc9
DeForest, Cole A.
7638a0b3-35a4-4d69-8b0c-d249cf6e02a3
Kanekiyo, Masaru
fe51922d-356e-48c9-9457-e4b7b0858fb1
King, Neil P.
19437abf-1af8-4243-975f-0f4cbfeda355
Haas, Cyrus M.
56ae71dd-6b8e-45c0-8937-4417d09f233b
Jasti, Naveen
d977f083-a09a-4ca2-aaf3-d11d6ce67d95
Dosey, Annie
d8b74cff-f449-4924-9a32-09a53cbec229
Allen, Joel D.
c873d886-2a66-475b-ae04-57a10b37e716
Gillespie, Rebecca
9a583397-48f0-489b-8411-6b93f0db6e0e
McGowan, Jackson
f25d9869-eeef-4172-9de5-f21384bce226
Leaf, Elizabeth M.
027100d7-f4a1-4f63-adec-1f7ba688b741
Crispin, Max
cd980957-0943-4b89-b2b2-710f01f33bc9
DeForest, Cole A.
7638a0b3-35a4-4d69-8b0c-d249cf6e02a3
Kanekiyo, Masaru
fe51922d-356e-48c9-9457-e4b7b0858fb1
King, Neil P.
19437abf-1af8-4243-975f-0f4cbfeda355

Haas, Cyrus M., Jasti, Naveen, Dosey, Annie, Allen, Joel D., Gillespie, Rebecca, McGowan, Jackson, Leaf, Elizabeth M., Crispin, Max, DeForest, Cole A., Kanekiyo, Masaru and King, Neil P. (2025) From sequence to scaffold: computational design of protein nanoparticle vaccines from AlphaFold2-predicted building blocks. Proceedings of the National Academy of Sciences of the United States of America, 122 (45), [e2409566122]. (doi:10.1073/pnas.2409566122).

Record type: Article

Abstract

Self-assembling protein nanoparticles are being increasingly utilized in the design of next-generation vaccines due to their ability to induce antibody responses of superior magnitude, breadth, and durability. Computational protein design offers a route to nanoparticle scaffolds with structural and biochemical features tailored to specific vaccine applications. Although strategies for designing self-assembling proteins have been established, the recent development of powerful machine learning (ML)–based tools for protein structure prediction and design provides an opportunity to overcome several of their limitations. Here, we leveraged these tools to develop a generalizable method for designing self-assembling proteins starting from AlphaFold2 predictions of oligomeric protein building blocks. We used the method to generate six 60-subunit protein nanoparticles with icosahedral symmetry, and single-particle cryoelectron microscopy reconstructions of three of them revealed that they were designed with atomic-level accuracy. To transform one of these nanoparticles into a functional immunogen, we reoriented its termini through circular permutation, added a genetically encoded oligomannose-type glycan, and displayed a stabilized trimeric variant of the influenza hemagglutinin receptor-binding domain through a rigid de novo linker. The resultant immunogen elicited potent receptor-blocking and neutralizing antibody responses in mice. Our results demonstrate the practical utility of ML–based protein modeling tools in the design of nanoparticle vaccines. More broadly, by eliminating the requirement for experimentally determined structures of protein building blocks, our method dramatically expands the number of starting points available for designing self-assembling proteins.

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haas-et-al-2025-from-sequence-to-scaffold-computational-design-of-protein-nanoparticle-vaccines-from-alphafold2 - Version of Record
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More information

Accepted/In Press date: 10 December 2024
e-pub ahead of print date: 3 November 2025
Published date: 11 November 2025
Keywords: influenza, machine learning, nanoparticles, protein design, vaccines

Identifiers

Local EPrints ID: 511275
URI: http://eprints.soton.ac.uk/id/eprint/511275
DOI: doi:10.1073/pnas.2409566122
ISSN: 0027-8424
PURE UUID: c66aa4dc-99c3-4a08-bb6e-4f7b0fa5434d
ORCID for Max Crispin: ORCID iD orcid.org/0000-0002-1072-2694

Catalogue record

Date deposited: 11 May 2026 16:41
Last modified: 14 May 2026 01:53

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Contributors

Author: Cyrus M. Haas
Author: Naveen Jasti
Author: Annie Dosey
Author: Joel D. Allen
Author: Rebecca Gillespie
Author: Jackson McGowan
Author: Elizabeth M. Leaf
Author: Max Crispin ORCID iD
Author: Cole A. DeForest
Author: Masaru Kanekiyo
Author: Neil P. King

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