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Integrating linear optimization with structural modeling to increase HIV neutralization breadth

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  • Alexander M Sevy
  • Swetasudha Panda
  • James E Crowe Jr
  • Jens Meiler
  • Yevgeniy Vorobeychik

Abstract

Computational protein design has been successful in modeling fixed backbone proteins in a single conformation. However, when modeling large ensembles of flexible proteins, current methods in protein design have been insufficient. Large barriers in the energy landscape are difficult to traverse while redesigning a protein sequence, and as a result current design methods only sample a fraction of available sequence space. We propose a new computational approach that combines traditional structure-based modeling using the Rosetta software suite with machine learning and integer linear programming to overcome limitations in the Rosetta sampling methods. We demonstrate the effectiveness of this method, which we call BROAD, by benchmarking the performance on increasing predicted breadth of anti-HIV antibodies. We use this novel method to increase predicted breadth of naturally-occurring antibody VRC23 against a panel of 180 divergent HIV viral strains and achieve 100% predicted binding against the panel. In addition, we compare the performance of this method to state-of-the-art multistate design in Rosetta and show that we can outperform the existing method significantly. We further demonstrate that sequences recovered by this method recover known binding motifs of broadly neutralizing anti-HIV antibodies. Finally, our approach is general and can be extended easily to other protein systems. Although our modeled antibodies were not tested in vitro, we predict that these variants would have greatly increased breadth compared to the wild-type antibody.Author summary: In this article, we report a new approach for protein design, which combines traditional structural modeling with machine learning and integer programming. Using this method, we are able to design antibodies that are predicted to bind large panels of antigenically diverse HIV variants. The combination of methods from these fields allows us to surpass protein design limitations that have been seen up to this point. We predict that if we tested these modified antibodies against HIV variants they would have greater neutralization breadth than any antibodies seen to this point.

Suggested Citation

  • Alexander M Sevy & Swetasudha Panda & James E Crowe Jr & Jens Meiler & Yevgeniy Vorobeychik, 2018. "Integrating linear optimization with structural modeling to increase HIV neutralization breadth," PLOS Computational Biology, Public Library of Science, vol. 14(2), pages 1-18, February.
    • Handle: RePEc:plo:pcbi00:1005999
    DOI: 10.1371/journal.pcbi.1005999
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    References listed on IDEAS

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    1. Jordan R Willis & Bryan S Briney & Samuel L DeLuca & James E Crowe Jr & Jens Meiler, 2013. "Human Germline Antibody Gene Segments Encode Polyspecific Antibodies," PLOS Computational Biology, Public Library of Science, vol. 9(4), pages 1-14, April.
    2. Andrew Leaver-Fay & Ron Jacak & P Benjamin Stranges & Brian Kuhlman, 2011. "A Generic Program for Multistate Protein Design," PLOS ONE, Public Library of Science, vol. 6(7), pages 1-17, July.
    3. Jinghe Huang & Gilad Ofek & Leo Laub & Mark K. Louder & Nicole A. Doria-Rose & Nancy S. Longo & Hiromi Imamichi & Robert T. Bailer & Bimal Chakrabarti & Shailendra K. Sharma & S. Munir Alam & Tao Wang, 2012. "Broad and potent neutralization of HIV-1 by a gp41-specific human antibody," Nature, Nature, vol. 491(7424), pages 406-412, November.
    4. Robert P. King, 2012. "The Science of Design," American Journal of Agricultural Economics, Agricultural and Applied Economics Association, vol. 94(2), pages 275-284.
    5. Alexander M Sevy & Tim M Jacobs & James E Crowe Jr. & Jens Meiler, 2015. "Design of Protein Multi-specificity Using an Independent Sequence Search Reduces the Barrier to Low Energy Sequences," PLOS Computational Biology, Public Library of Science, vol. 11(7), pages 1-23, July.
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